/* @internal */
namespace ts {
    const ambientModuleSymbolRegex = /^".+"$/;
    const anon = '(anonymous)' as __String & string;

    let nextSymbolId = 1;
    let nextNodeId = 1;
    let nextMergeId = 1;
    let nextFlowId = 1;

    const enum IterationUse {
        AllowsSyncIterablesFlag = 1 << 0,
        AllowsAsyncIterablesFlag = 1 << 1,
        AllowsStringInputFlag = 1 << 2,
        ForOfFlag = 1 << 3,
        YieldStarFlag = 1 << 4,
        SpreadFlag = 1 << 5,
        DestructuringFlag = 1 << 6,

        // Spread, Destructuring, Array element assignment
        Element = AllowsSyncIterablesFlag,
        Spread = AllowsSyncIterablesFlag | SpreadFlag,
        Destructuring = AllowsSyncIterablesFlag | DestructuringFlag,

        ForOf = AllowsSyncIterablesFlag | AllowsStringInputFlag | ForOfFlag,
        ForAwaitOf = AllowsSyncIterablesFlag | AllowsAsyncIterablesFlag
            | AllowsStringInputFlag | ForOfFlag,

        YieldStar = AllowsSyncIterablesFlag | YieldStarFlag,
        AsyncYieldStar = AllowsSyncIterablesFlag | AllowsAsyncIterablesFlag
            | YieldStarFlag,

        GeneratorReturnType = AllowsSyncIterablesFlag,
        AsyncGeneratorReturnType = AllowsAsyncIterablesFlag
    }

    const enum IterationTypeKind {
        Yield,
        Return,
        Next
    }

    interface IterationTypesResolver {
        iterableCacheKey: 'iterationTypesOfAsyncIterable'
            | 'iterationTypesOfIterable';
        iteratorCacheKey: 'iterationTypesOfAsyncIterator'
            | 'iterationTypesOfIterator';
        iteratorSymbolName: 'asyncIterator' | 'iterator';
        getGlobalIteratorType: (reportErrors: boolean) => GenericType;
        getGlobalIterableType: (reportErrors: boolean) => GenericType;
        getGlobalIterableIteratorType: (reportErrors: boolean) => GenericType;
        getGlobalGeneratorType: (reportErrors: boolean) => GenericType;
        resolveIterationType: (
            type: Type,
            errorNode: Node | undefined
        ) => Type | undefined;
        mustHaveANextMethodDiagnostic: DiagnosticMessage;
        mustBeAMethodDiagnostic: DiagnosticMessage;
        mustHaveAValueDiagnostic: DiagnosticMessage;
    }

    const enum WideningKind {
        Normal,
        GeneratorYield
    }

    const enum TypeFacts {
        None = 0,
        TypeofEQString = 1 << 0, // typeof x === "string"
        TypeofEQNumber = 1 << 1, // typeof x === "number"
        TypeofEQBigInt = 1 << 2, // typeof x === "bigint"
        TypeofEQBoolean = 1 << 3, // typeof x === "boolean"
        TypeofEQSymbol = 1 << 4, // typeof x === "symbol"
        TypeofEQObject = 1 << 5, // typeof x === "object"
        TypeofEQFunction = 1 << 6, // typeof x === "function"
        TypeofEQHostObject = 1 << 7, // typeof x === "xxx"
        TypeofNEString = 1 << 8, // typeof x !== "string"
        TypeofNENumber = 1 << 9, // typeof x !== "number"
        TypeofNEBigInt = 1 << 10, // typeof x !== "bigint"
        TypeofNEBoolean = 1 << 11, // typeof x !== "boolean"
        TypeofNESymbol = 1 << 12, // typeof x !== "symbol"
        TypeofNEObject = 1 << 13, // typeof x !== "object"
        TypeofNEFunction = 1 << 14, // typeof x !== "function"
        TypeofNEHostObject = 1 << 15, // typeof x !== "xxx"
        EQUndefined = 1 << 16, // x === undefined
        EQNull = 1 << 17, // x === null
        EQUndefinedOrNull = 1 << 18, // x === undefined / x === null
        NEUndefined = 1 << 19, // x !== undefined
        NENull = 1 << 20, // x !== null
        NEUndefinedOrNull = 1 << 21, // x != undefined / x != null
        Truthy = 1 << 22, // x
        Falsy = 1 << 23, // !x
        All = (1 << 24) - 1,
        // The following members encode facts about particular kinds of types for use in the getTypeFacts function.
        // The presence of a particular fact means that the given test is true for some (and possibly all) values
        // of that kind of type.
        BaseStringStrictFacts = TypeofEQString | TypeofNENumber
            | TypeofNEBigInt | TypeofNEBoolean | TypeofNESymbol
            | TypeofNEObject | TypeofNEFunction | TypeofNEHostObject
            | NEUndefined | NENull | NEUndefinedOrNull,
        BaseStringFacts = BaseStringStrictFacts | EQUndefined | EQNull
            | EQUndefinedOrNull | Falsy,
        StringStrictFacts = BaseStringStrictFacts | Truthy | Falsy,
        StringFacts = BaseStringFacts | Truthy,
        EmptyStringStrictFacts = BaseStringStrictFacts | Falsy,
        EmptyStringFacts = BaseStringFacts,
        NonEmptyStringStrictFacts = BaseStringStrictFacts | Truthy,
        NonEmptyStringFacts = BaseStringFacts | Truthy,
        BaseNumberStrictFacts = TypeofEQNumber | TypeofNEString
            | TypeofNEBigInt | TypeofNEBoolean | TypeofNESymbol
            | TypeofNEObject | TypeofNEFunction | TypeofNEHostObject
            | NEUndefined | NENull | NEUndefinedOrNull,
        BaseNumberFacts = BaseNumberStrictFacts | EQUndefined | EQNull
            | EQUndefinedOrNull | Falsy,
        NumberStrictFacts = BaseNumberStrictFacts | Truthy | Falsy,
        NumberFacts = BaseNumberFacts | Truthy,
        ZeroNumberStrictFacts = BaseNumberStrictFacts | Falsy,
        ZeroNumberFacts = BaseNumberFacts,
        NonZeroNumberStrictFacts = BaseNumberStrictFacts | Truthy,
        NonZeroNumberFacts = BaseNumberFacts | Truthy,
        BaseBigIntStrictFacts = TypeofEQBigInt | TypeofNEString
            | TypeofNENumber | TypeofNEBoolean | TypeofNESymbol
            | TypeofNEObject | TypeofNEFunction | TypeofNEHostObject
            | NEUndefined | NENull | NEUndefinedOrNull,
        BaseBigIntFacts = BaseBigIntStrictFacts | EQUndefined | EQNull
            | EQUndefinedOrNull | Falsy,
        BigIntStrictFacts = BaseBigIntStrictFacts | Truthy | Falsy,
        BigIntFacts = BaseBigIntFacts | Truthy,
        ZeroBigIntStrictFacts = BaseBigIntStrictFacts | Falsy,
        ZeroBigIntFacts = BaseBigIntFacts,
        NonZeroBigIntStrictFacts = BaseBigIntStrictFacts | Truthy,
        NonZeroBigIntFacts = BaseBigIntFacts | Truthy,
        BaseBooleanStrictFacts = TypeofEQBoolean | TypeofNEString
            | TypeofNENumber | TypeofNEBigInt | TypeofNESymbol | TypeofNEObject
            | TypeofNEFunction | TypeofNEHostObject | NEUndefined | NENull
            | NEUndefinedOrNull,
        BaseBooleanFacts = BaseBooleanStrictFacts | EQUndefined | EQNull
            | EQUndefinedOrNull | Falsy,
        BooleanStrictFacts = BaseBooleanStrictFacts | Truthy | Falsy,
        BooleanFacts = BaseBooleanFacts | Truthy,
        FalseStrictFacts = BaseBooleanStrictFacts | Falsy,
        FalseFacts = BaseBooleanFacts,
        TrueStrictFacts = BaseBooleanStrictFacts | Truthy,
        TrueFacts = BaseBooleanFacts | Truthy,
        SymbolStrictFacts = TypeofEQSymbol | TypeofNEString | TypeofNENumber
            | TypeofNEBigInt | TypeofNEBoolean | TypeofNEObject
            | TypeofNEFunction | TypeofNEHostObject | NEUndefined | NENull
            | NEUndefinedOrNull | Truthy,
        SymbolFacts = SymbolStrictFacts | EQUndefined | EQNull
            | EQUndefinedOrNull | Falsy,
        ObjectStrictFacts = TypeofEQObject | TypeofEQHostObject
            | TypeofNEString | TypeofNENumber | TypeofNEBigInt
            | TypeofNEBoolean | TypeofNESymbol | TypeofNEFunction | NEUndefined
            | NENull | NEUndefinedOrNull | Truthy,
        ObjectFacts = ObjectStrictFacts | EQUndefined | EQNull
            | EQUndefinedOrNull | Falsy,
        FunctionStrictFacts = TypeofEQFunction | TypeofEQHostObject
            | TypeofNEString | TypeofNENumber | TypeofNEBigInt
            | TypeofNEBoolean | TypeofNESymbol | TypeofNEObject | NEUndefined
            | NENull | NEUndefinedOrNull | Truthy,
        FunctionFacts = FunctionStrictFacts | EQUndefined | EQNull
            | EQUndefinedOrNull | Falsy,
        UndefinedFacts = TypeofNEString | TypeofNENumber | TypeofNEBigInt
            | TypeofNEBoolean | TypeofNESymbol | TypeofNEObject
            | TypeofNEFunction | TypeofNEHostObject | EQUndefined
            | EQUndefinedOrNull | NENull | Falsy,
        NullFacts = TypeofEQObject | TypeofNEString | TypeofNENumber
            | TypeofNEBigInt | TypeofNEBoolean | TypeofNESymbol
            | TypeofNEFunction | TypeofNEHostObject | EQNull
            | EQUndefinedOrNull | NEUndefined | Falsy,
        EmptyObjectStrictFacts = All
            & ~(EQUndefined | EQNull | EQUndefinedOrNull),
        EmptyObjectFacts = All
    }

    const typeofEQFacts: ReadonlyMap<TypeFacts> = createMapFromTemplate(
        {
            string: TypeFacts.TypeofEQString,
            number: TypeFacts.TypeofEQNumber,
            bigint: TypeFacts.TypeofEQBigInt,
            boolean: TypeFacts.TypeofEQBoolean,
            symbol: TypeFacts.TypeofEQSymbol,
            undefined: TypeFacts.EQUndefined,
            object: TypeFacts.TypeofEQObject,
            function: TypeFacts.TypeofEQFunction
        }
    );

    const typeofNEFacts: ReadonlyMap<TypeFacts> = createMapFromTemplate(
        {
            string: TypeFacts.TypeofNEString,
            number: TypeFacts.TypeofNENumber,
            bigint: TypeFacts.TypeofNEBigInt,
            boolean: TypeFacts.TypeofNEBoolean,
            symbol: TypeFacts.TypeofNESymbol,
            undefined: TypeFacts.NEUndefined,
            object: TypeFacts.TypeofNEObject,
            function: TypeFacts.TypeofNEFunction
        }
    );

    type TypeSystemEntity = Node | Symbol | Type | Signature;

    const enum TypeSystemPropertyName {
        Type,
        ResolvedBaseConstructorType,
        DeclaredType,
        ResolvedReturnType,
        ImmediateBaseConstraint,
        EnumTagType,
        JSDocTypeReference,
        ResolvedTypeArguments
    }

    const enum CheckMode {
        Normal = 0, // Normal type checking
        Contextual = 1
            << 0, // Explicitly assigned contextual type, therefore not cacheable
        Inferential = 1 << 1, // Inferential typing
        SkipContextSensitive = 1
            << 2, // Skip context sensitive function expressions
        SkipGenericFunctions = 1
            << 3, // Skip single signature generic functions
        IsForSignatureHelp = 1
            << 4 // Call resolution for purposes of signature help
    }

    const enum AccessFlags {
        None = 0,
        NoIndexSignatures = 1 << 0,
        Writing = 1 << 1,
        CacheSymbol = 1 << 2,
        NoTupleBoundsCheck = 1 << 3
    }

    const enum SignatureCheckMode {
        BivariantCallback = 1 << 0,
        StrictCallback = 1 << 1,
        IgnoreReturnTypes = 1 << 2,
        StrictArity = 1 << 3,
        Callback = BivariantCallback | StrictCallback
    }

    const enum MappedTypeModifiers {
        IncludeReadonly = 1 << 0,
        ExcludeReadonly = 1 << 1,
        IncludeOptional = 1 << 2,
        ExcludeOptional = 1 << 3
    }

    const enum ExpandingFlags {
        None = 0,
        Source = 1,
        Target = 1 << 1,
        Both = Source | Target
    }

    const enum MembersOrExportsResolutionKind {
        resolvedExports = 'resolvedExports',
        resolvedMembers = 'resolvedMembers'
    }

    const enum UnusedKind {
        Local,
        Parameter
    }

    /** @param containingNode Node to check for parse error */
    type AddUnusedDiagnostic = (
        containingNode: Node,
        type: UnusedKind,
        diagnostic: DiagnosticWithLocation
    ) => void;

    const isNotOverloadAndNotAccessor = and(isNotOverload, isNotAccessor);

    const enum DeclarationMeaning {
        GetAccessor = 1,
        SetAccessor = 2,
        PropertyAssignment = 4,
        Method = 8,
        GetOrSetAccessor = GetAccessor | SetAccessor,
        PropertyAssignmentOrMethod = PropertyAssignment | Method
    }

    const enum DeclarationSpaces {
        None = 0,
        ExportValue = 1 << 0,
        ExportType = 1 << 1,
        ExportNamespace = 1 << 2
    }

    export function getNodeId(node: Node): number {
        if (!node.id) {
            node.id = nextNodeId;
            nextNodeId++;
        }
        return node.id;
    }

    export function getSymbolId(symbol: Symbol): number {
        if (!symbol.id) {
            symbol.id = nextSymbolId;
            nextSymbolId++;
        }

        return symbol.id;
    }

    export function isInstantiatedModule(
        node: ModuleDeclaration,
        preserveConstEnums: boolean
    ) {
        const moduleState = getModuleInstanceState(node);
        return moduleState === ModuleInstanceState.Instantiated
            || (preserveConstEnums
                && moduleState === ModuleInstanceState.ConstEnumOnly);
    }

    export function createTypeChecker(
        host: TypeCheckerHost,
        produceDiagnostics: boolean
    ): TypeChecker {
        const getPackagesSet: () => Map<true> = memoize(() => {
            const set = createMap<true>();
            host.getSourceFiles().forEach(sf => {
                if (!sf.resolvedModules) return;

                forEachEntry(
                    sf.resolvedModules,
                    r => {
                        if (r && r.packageId) set.set(r.packageId.name, true);
                    }
                );
            });
            return set;
        });

        // Cancellation that controls whether or not we can cancel in the middle of type checking.
        // In general cancelling is *not* safe for the type checker.  We might be in the middle of
        // computing something, and we will leave our internals in an inconsistent state.  Callers
        // who set the cancellation token should catch if a cancellation exception occurs, and
        // should throw away and create a new TypeChecker.
        //
        // Currently we only support setting the cancellation token when getting diagnostics.  This
        // is because diagnostics can be quite expensive, and we want to allow hosts to bail out if
        // they no longer need the information (for example, if the user started editing again).
        let cancellationToken: CancellationToken | undefined;
        let requestedExternalEmitHelpers: ExternalEmitHelpers;
        let externalHelpersModule: Symbol;

        const Symbol = objectAllocator.getSymbolConstructor();
        const Type = objectAllocator.getTypeConstructor();
        const Signature = objectAllocator.getSignatureConstructor();

        let typeCount = 0;
        let symbolCount = 0;
        let enumCount = 0;
        let instantiationCount = 0;
        let instantiationDepth = 0;
        let constraintDepth = 0;
        let currentNode: Node | undefined;

        const emptySymbols = createSymbolTable();
        const identityMapper: (type: Type) => Type = identity;

        const compilerOptions = host.getCompilerOptions();
        const languageVersion = getEmitScriptTarget(compilerOptions);
        const moduleKind = getEmitModuleKind(compilerOptions);
        const allowSyntheticDefaultImports = getAllowSyntheticDefaultImports(compilerOptions);
        const strictNullChecks = getStrictOptionValue(
            compilerOptions,
            'strictNullChecks'
        );
        const strictFunctionTypes = getStrictOptionValue(
            compilerOptions,
            'strictFunctionTypes'
        );
        const strictBindCallApply = getStrictOptionValue(
            compilerOptions,
            'strictBindCallApply'
        );
        const strictPropertyInitialization = getStrictOptionValue(
            compilerOptions,
            'strictPropertyInitialization'
        );
        const noImplicitAny = getStrictOptionValue(
            compilerOptions,
            'noImplicitAny'
        );
        const noImplicitThis = getStrictOptionValue(
            compilerOptions,
            'noImplicitThis'
        );
        const keyofStringsOnly = !!compilerOptions.keyofStringsOnly;
        const freshObjectLiteralFlag = compilerOptions
            .suppressExcessPropertyErrors
            ? 0
            : ObjectFlags.FreshLiteral;

        const emitResolver = createResolver();
        const nodeBuilder = createNodeBuilder();

        const globals = createSymbolTable();
        const undefinedSymbol = createSymbol(
            SymbolFlags.Property,
            'undefined' as __String
        );
        undefinedSymbol.declarations = [];

        const globalThisSymbol = createSymbol(
            SymbolFlags.Module,
            'globalThis' as __String,
            CheckFlags.Readonly
        );
        globalThisSymbol.exports = globals;
        globalThisSymbol.declarations = [];
        globals.set(globalThisSymbol.escapedName, globalThisSymbol);

        const argumentsSymbol = createSymbol(
            SymbolFlags.Property,
            'arguments' as __String
        );
        const requireSymbol = createSymbol(
            SymbolFlags.Property,
            'require' as __String
        );

        /** This will be set during calls to `getResolvedSignature` where services determines an apparent number of arguments greater than what is actually provided. */
        let apparentArgumentCount: number | undefined;

        // for public members that accept a Node or one of its subtypes, we must guard against
        // synthetic nodes created during transformations by calling `getParseTreeNode`.
        // for most of these, we perform the guard only on `checker` to avoid any possible
        // extra cost of calling `getParseTreeNode` when calling these functions from inside the
        // checker.
        const checker: TypeChecker = {
            getNodeCount: () => sum(host.getSourceFiles(), 'nodeCount'),
            getIdentifierCount: () => sum(
                host.getSourceFiles(),
                'identifierCount'
            ),
            getSymbolCount: () => sum(host.getSourceFiles(), 'symbolCount')
                + symbolCount,
            getTypeCount: () => typeCount,
            getRelationCacheSizes: () => ({
                assignable: assignableRelation.size,
                identity: identityRelation.size,
                subtype: subtypeRelation.size,
                strictSubtype: strictSubtypeRelation.size
            }),
            isUndefinedSymbol: symbol => symbol === undefinedSymbol,
            isArgumentsSymbol: symbol => symbol === argumentsSymbol,
            isUnknownSymbol: symbol => symbol === unknownSymbol,
            getMergedSymbol,
            getDiagnostics,
            getGlobalDiagnostics,
            getTypeOfSymbolAtLocation: (symbol, location) => {
                location = getParseTreeNode(location);
                return location
                    ? getTypeOfSymbolAtLocation(symbol, location)
                    : errorType;
            },
            getSymbolsOfParameterPropertyDeclaration: (
                parameterIn,
                parameterName
            ) => {
                const parameter = getParseTreeNode(parameterIn, isParameter);
                if (parameter === undefined) {
                    return Debug
                        .fail('Cannot get symbols of a synthetic parameter that cannot be resolved to a parse-tree node.');
                }
                return getSymbolsOfParameterPropertyDeclaration(
                    parameter,
                    escapeLeadingUnderscores(parameterName)
                );
            },
            getDeclaredTypeOfSymbol,
            getPropertiesOfType,
            getPropertyOfType: (type, name) => getPropertyOfType(
                type,
                escapeLeadingUnderscores(name)
            ),
            getPrivateIdentifierPropertyOfType: (
                leftType: Type,
                name: string,
                location: Node
            ) => {
                const node = getParseTreeNode(location);
                if (!node) {
                    return undefined;
                }
                const propName = escapeLeadingUnderscores(name);
                const lexicallyScopedIdentifier = lookupSymbolForPrivateIdentifierDeclaration(
                    propName,
                    node
                );
                return lexicallyScopedIdentifier
                    ? getPrivateIdentifierPropertyOfType(
                        leftType,
                        lexicallyScopedIdentifier
                    )
                    : undefined;
            },
            getTypeOfPropertyOfType: (type,
                name) =>
            getTypeOfPropertyOfType(type, escapeLeadingUnderscores(name)),
            getIndexInfoOfType,
            getSignaturesOfType,
            getIndexTypeOfType,
            getBaseTypes,
            getBaseTypeOfLiteralType,
            getWidenedType,
            getTypeFromTypeNode: nodeIn => {
                const node = getParseTreeNode(nodeIn, isTypeNode);
                return node ? getTypeFromTypeNode(node) : errorType;
            },
            getParameterType: getTypeAtPosition,
            getPromisedTypeOfPromise,
            getReturnTypeOfSignature,
            isNullableType,
            getNullableType,
            getNonNullableType,
            getNonOptionalType: removeOptionalTypeMarker,
            getTypeArguments,
            typeToTypeNode: nodeBuilder.typeToTypeNode,
            indexInfoToIndexSignatureDeclaration: nodeBuilder
                .indexInfoToIndexSignatureDeclaration,
            signatureToSignatureDeclaration: nodeBuilder
                .signatureToSignatureDeclaration,
            symbolToEntityName: nodeBuilder.symbolToEntityName,
            symbolToExpression: nodeBuilder.symbolToExpression,
            symbolToTypeParameterDeclarations: nodeBuilder
                .symbolToTypeParameterDeclarations,
            symbolToParameterDeclaration: nodeBuilder
                .symbolToParameterDeclaration,
            typeParameterToDeclaration: nodeBuilder.typeParameterToDeclaration,
            getSymbolsInScope: (location, meaning) => {
                location = getParseTreeNode(location);
                return location ? getSymbolsInScope(location, meaning) : [];
            },
            getSymbolAtLocation: node => {
                node = getParseTreeNode(node);
                return node ? getSymbolAtLocation(node) : undefined;
            },
            getShorthandAssignmentValueSymbol: node => {
                node = getParseTreeNode(node);
                return node
                    ? getShorthandAssignmentValueSymbol(node)
                    : undefined;
            },
            getExportSpecifierLocalTargetSymbol: nodeIn => {
                const node = getParseTreeNode(nodeIn, isExportSpecifier);
                return node
                    ? getExportSpecifierLocalTargetSymbol(node)
                    : undefined;
            },
            getExportSymbolOfSymbol(symbol) {
                return getMergedSymbol(symbol.exportSymbol || symbol);
            },
            getTypeAtLocation: node => {
                node = getParseTreeNode(node);
                return node ? getTypeOfNode(node) : errorType;
            },
            getTypeOfAssignmentPattern: nodeIn => {
                const node = getParseTreeNode(nodeIn, isAssignmentPattern);
                return node && getTypeOfAssignmentPattern(node) || errorType;
            },
            getPropertySymbolOfDestructuringAssignment: locationIn => {
                const location = getParseTreeNode(locationIn, isIdentifier);
                return location
                    ? getPropertySymbolOfDestructuringAssignment(location)
                    : undefined;
            },
            signatureToString: (signature, enclosingDeclaration, flags,
                kind) =>
            {
                return signatureToString(
                    signature,
                    getParseTreeNode(enclosingDeclaration),
                    flags,
                    kind
                );
            },
            typeToString: (type, enclosingDeclaration, flags) => {
                return typeToString(
                    type,
                    getParseTreeNode(enclosingDeclaration),
                    flags
                );
            },
            symbolToString: (symbol, enclosingDeclaration, meaning, flags) => {
                return symbolToString(
                    symbol,
                    getParseTreeNode(enclosingDeclaration),
                    meaning,
                    flags
                );
            },
            typePredicateToString: (predicate, enclosingDeclaration,
                flags) =>
            {
                return typePredicateToString(
                    predicate,
                    getParseTreeNode(enclosingDeclaration),
                    flags
                );
            },
            writeSignature: (
                signature,
                enclosingDeclaration,
                flags,
                kind,
                writer
            ) => {
                return signatureToString(
                    signature,
                    getParseTreeNode(enclosingDeclaration),
                    flags,
                    kind,
                    writer
                );
            },
            writeType: (type, enclosingDeclaration, flags, writer) => {
                return typeToString(
                    type,
                    getParseTreeNode(enclosingDeclaration),
                    flags,
                    writer
                );
            },
            writeSymbol: (symbol, enclosingDeclaration, meaning, flags,
                writer) =>
            {
                return symbolToString(
                    symbol,
                    getParseTreeNode(enclosingDeclaration),
                    meaning,
                    flags,
                    writer
                );
            },
            writeTypePredicate: (
                predicate,
                enclosingDeclaration,
                flags,
                writer
            ) => {
                return typePredicateToString(
                    predicate,
                    getParseTreeNode(enclosingDeclaration),
                    flags,
                    writer
                );
            },
            getAugmentedPropertiesOfType,
            getRootSymbols,
            getContextualType: (
                nodeIn: Expression,
                contextFlags?: ContextFlags
            ) => {
                const node = getParseTreeNode(nodeIn, isExpression);
                return node
                    ? getContextualType(node, contextFlags)
                    : undefined;
            },
            getContextualTypeForObjectLiteralElement: nodeIn => {
                const node = getParseTreeNode(
                    nodeIn,
                    isObjectLiteralElementLike
                );
                return node
                    ? getContextualTypeForObjectLiteralElement(node)
                    : undefined;
            },
            getContextualTypeForArgumentAtIndex: (nodeIn, argIndex) => {
                const node = getParseTreeNode(nodeIn, isCallLikeExpression);
                return node
                    && getContextualTypeForArgumentAtIndex(node, argIndex);
            },
            getContextualTypeForJsxAttribute: (nodeIn) => {
                const node = getParseTreeNode(nodeIn, isJsxAttributeLike);
                return node && getContextualTypeForJsxAttribute(node);
            },
            isContextSensitive,
            getFullyQualifiedName,
            getResolvedSignature: (node, candidatesOutArray,
                argumentCount) =>
            getResolvedSignatureWorker(
                node,
                candidatesOutArray,
                argumentCount,
                CheckMode.Normal
            ),
            getResolvedSignatureForSignatureHelp: (
                node,
                candidatesOutArray,
                argumentCount
            ) => getResolvedSignatureWorker(
                node,
                candidatesOutArray,
                argumentCount,
                CheckMode.IsForSignatureHelp
            ),
            getExpandedParameters,
            hasEffectiveRestParameter,
            getConstantValue: nodeIn => {
                const node = getParseTreeNode(nodeIn, canHaveConstantValue);
                return node ? getConstantValue(node) : undefined;
            },
            isValidPropertyAccess: (nodeIn, propertyName) => {
                const node = getParseTreeNode(
                    nodeIn,
                    isPropertyAccessOrQualifiedNameOrImportTypeNode
                );
                return !!node
                    && isValidPropertyAccess(
                        node,
                        escapeLeadingUnderscores(propertyName)
                    );
            },
            isValidPropertyAccessForCompletions: (nodeIn, type, property) => {
                const node = getParseTreeNode(
                    nodeIn,
                    isPropertyAccessExpression
                );
                return !!node
                    && isValidPropertyAccessForCompletions(
                        node,
                        type,
                        property
                    );
            },
            getSignatureFromDeclaration: declarationIn => {
                const declaration = getParseTreeNode(
                    declarationIn,
                    isFunctionLike
                );
                return declaration
                    ? getSignatureFromDeclaration(declaration)
                    : undefined;
            },
            isImplementationOfOverload: node => {
                const parsed = getParseTreeNode(node, isFunctionLike);
                return parsed ? isImplementationOfOverload(parsed) : undefined;
            },
            getImmediateAliasedSymbol,
            getAliasedSymbol: resolveAlias,
            getEmitResolver,
            getExportsOfModule: getExportsOfModuleAsArray,
            getExportsAndPropertiesOfModule,
            getSymbolWalker: createGetSymbolWalker(
                getRestTypeOfSignature,
                getTypePredicateOfSignature,
                getReturnTypeOfSignature,
                getBaseTypes,
                resolveStructuredTypeMembers,
                getTypeOfSymbol,
                getResolvedSymbol,
                getIndexTypeOfStructuredType,
                getConstraintOfTypeParameter,
                getFirstIdentifier,
                getTypeArguments
            ),
            getAmbientModules,
            getJsxIntrinsicTagNamesAt,
            isOptionalParameter: nodeIn => {
                const node = getParseTreeNode(nodeIn, isParameter);
                return node ? isOptionalParameter(node) : false;
            },
            tryGetMemberInModuleExports: (name,
                symbol) =>
            tryGetMemberInModuleExports(escapeLeadingUnderscores(name),
                symbol),
            tryGetMemberInModuleExportsAndProperties: (name,
                symbol) =>
            tryGetMemberInModuleExportsAndProperties(
                escapeLeadingUnderscores(name),
                symbol
            ),
            tryFindAmbientModuleWithoutAugmentations: moduleName => {
                // we deliberately exclude augmentations
                // since we are only interested in declarations of the module itself
                return tryFindAmbientModule(
                    moduleName, /*withAugmentations*/
                    false
                );
            },
            getApparentType,
            getUnionType,
            isTypeAssignableTo: (source, target) => {
                return isTypeAssignableTo(source, target);
            },
            createAnonymousType,
            createSignature,
            createSymbol,
            createIndexInfo,
            getAnyType: () => anyType,
            getStringType: () => stringType,
            getNumberType: () => numberType,
            createPromiseType,
            createArrayType,
            getElementTypeOfArrayType,
            getBooleanType: () => booleanType,
            getFalseType: (fresh?) => fresh ? falseType : regularFalseType,
            getTrueType: (fresh?) => fresh ? trueType : regularTrueType,
            getVoidType: () => voidType,
            getUndefinedType: () => undefinedType,
            getNullType: () => nullType,
            getESSymbolType: () => esSymbolType,
            getNeverType: () => neverType,
            getOptionalType: () => optionalType,
            isSymbolAccessible,
            isArrayType,
            isTupleType,
            isArrayLikeType,
            isTypeInvalidDueToUnionDiscriminant,
            getAllPossiblePropertiesOfTypes,
            getSuggestionForNonexistentProperty: (node,
                type) =>
            getSuggestionForNonexistentProperty(node, type),
            getSuggestionForNonexistentSymbol: (location, name,
                meaning) =>
            getSuggestionForNonexistentSymbol(
                location,
                escapeLeadingUnderscores(name),
                meaning
            ),
            getSuggestionForNonexistentExport: (node,
                target) =>
            getSuggestionForNonexistentExport(node, target),
            getBaseConstraintOfType,
            getDefaultFromTypeParameter:
                type => type && type.flags & TypeFlags.TypeParameter
                    ? getDefaultFromTypeParameter(type as TypeParameter)
                    : undefined,
            resolveName(name, location, meaning, excludeGlobals) {
                return resolveName(
                    location,
                    escapeLeadingUnderscores(name),
                    meaning, /*nameNotFoundMessage*/
                    undefined, /*nameArg*/
                    undefined, /*isUse*/
                    false,
                    excludeGlobals
                );
            },
            getJsxNamespace:
                n => unescapeLeadingUnderscores(getJsxNamespace(n)),
            getAccessibleSymbolChain,
            getTypePredicateOfSignature,
            resolveExternalModuleSymbol,
            tryGetThisTypeAt: (node, includeGlobalThis) => {
                node = getParseTreeNode(node);
                return node && tryGetThisTypeAt(node, includeGlobalThis);
            },
            getTypeArgumentConstraint: nodeIn => {
                const node = getParseTreeNode(nodeIn, isTypeNode);
                return node && getTypeArgumentConstraint(node);
            },
            getSuggestionDiagnostics: (file, ct) => {
                if (skipTypeChecking(file, compilerOptions, host)) {
                    return emptyArray;
                }

                let diagnostics: DiagnosticWithLocation[] | undefined;
                try {
                    // Record the cancellation token so it can be checked later on during checkSourceElement.
                    // Do this in a finally block so we can ensure that it gets reset back to nothing after
                    // this call is done.
                    cancellationToken = ct;

                    // Ensure file is type checked
                    checkSourceFile(file);
                    Debug
                        .assert(
                            !!(getNodeLinks(file).flags
                                & NodeCheckFlags.TypeChecked)
                        );

                    diagnostics = addRange(
                        diagnostics,
                        suggestionDiagnostics.getDiagnostics(file.fileName)
                    );
                    checkUnusedIdentifiers(
                        getPotentiallyUnusedIdentifiers(file),
                        (containingNode, kind, diag) => {
                            if (!containsParseError(containingNode)
                                && !unusedIsError(
                                    kind,
                                    !!(containingNode.flags
                                        & NodeFlags.Ambient)
                                ))
                            {
                                (diagnostics || (diagnostics = [])).push(
                                    { ...diag,
                                        category: DiagnosticCategory
                                            .Suggestion }
                                );
                            }
                        }
                    );

                    return diagnostics || emptyArray;
                } finally {
                    cancellationToken = undefined;
                }
            },

            runWithCancellationToken: (token, callback) => {
                try {
                    cancellationToken = token;
                    return callback(checker);
                } finally {
                    cancellationToken = undefined;
                }
            },

            getLocalTypeParametersOfClassOrInterfaceOrTypeAlias,
            isDeclarationVisible
        };

        function getResolvedSignatureWorker(
            nodeIn: CallLikeExpression,
            candidatesOutArray: Signature[] | undefined,
            argumentCount: number | undefined,
            checkMode: CheckMode
        ): Signature | undefined {
            const node = getParseTreeNode(nodeIn, isCallLikeExpression);
            apparentArgumentCount = argumentCount;
            const res = node
                ? getResolvedSignature(node, candidatesOutArray, checkMode)
                : undefined;
            apparentArgumentCount = undefined;
            return res;
        }

        const tupleTypes = createMap<GenericType>();
        const unionTypes = createMap<UnionType>();
        const intersectionTypes = createMap<Type>();
        const literalTypes = createMap<LiteralType>();
        const indexedAccessTypes = createMap<IndexedAccessType>();
        const substitutionTypes = createMap<SubstitutionType>();
        const evolvingArrayTypes: EvolvingArrayType[] = [];
        const undefinedProperties = createMap<Symbol>() as UnderscoreEscapedMap<Symbol>;

        const unknownSymbol = createSymbol(
            SymbolFlags.Property,
            'unknown' as __String
        );
        const resolvingSymbol = createSymbol(0, InternalSymbolName.Resolving);

        const anyType = createIntrinsicType(TypeFlags.Any, 'any');
        const autoType = createIntrinsicType(TypeFlags.Any, 'any');
        const wildcardType = createIntrinsicType(TypeFlags.Any, 'any');
        const errorType = createIntrinsicType(TypeFlags.Any, 'error');
        const nonInferrableAnyType = createIntrinsicType(
            TypeFlags.Any,
            'any',
            ObjectFlags.ContainsWideningType
        );
        const unknownType = createIntrinsicType(TypeFlags.Unknown, 'unknown');
        const undefinedType = createIntrinsicType(
            TypeFlags.Undefined,
            'undefined'
        );
        const undefinedWideningType = strictNullChecks
            ? undefinedType
            : createIntrinsicType(
                TypeFlags.Undefined,
                'undefined',
                ObjectFlags.ContainsWideningType
            );
        const optionalType = createIntrinsicType(
            TypeFlags.Undefined,
            'undefined'
        );
        const nullType = createIntrinsicType(TypeFlags.Null, 'null');
        const nullWideningType = strictNullChecks
            ? nullType
            : createIntrinsicType(
                TypeFlags.Null,
                'null',
                ObjectFlags.ContainsWideningType
            );
        const stringType = createIntrinsicType(TypeFlags.String, 'string');
        const numberType = createIntrinsicType(TypeFlags.Number, 'number');
        const bigintType = createIntrinsicType(TypeFlags.BigInt, 'bigint');
        const falseType = createIntrinsicType(
            TypeFlags.BooleanLiteral,
            'false'
        ) as FreshableIntrinsicType;
        const regularFalseType = createIntrinsicType(
            TypeFlags.BooleanLiteral,
            'false'
        ) as FreshableIntrinsicType;
        const trueType = createIntrinsicType(TypeFlags.BooleanLiteral,
            'true') as FreshableIntrinsicType;
        const regularTrueType = createIntrinsicType(
            TypeFlags.BooleanLiteral,
            'true'
        ) as FreshableIntrinsicType;
        trueType.regularType = regularTrueType;
        trueType.freshType = trueType;
        regularTrueType.regularType = regularTrueType;
        regularTrueType.freshType = trueType;
        falseType.regularType = regularFalseType;
        falseType.freshType = falseType;
        regularFalseType.regularType = regularFalseType;
        regularFalseType.freshType = falseType;
        const booleanType = createBooleanType(
            [regularFalseType, regularTrueType]
        );
        // Also mark all combinations of fresh/regular booleans as "Boolean" so they print as `boolean` instead of `true | false`
        // (The union is cached, so simply doing the marking here is sufficient)
        createBooleanType([regularFalseType, trueType]);
        createBooleanType([falseType, regularTrueType]);
        createBooleanType([falseType, trueType]);
        const esSymbolType = createIntrinsicType(TypeFlags.ESSymbol, 'symbol');
        const voidType = createIntrinsicType(TypeFlags.Void, 'void');
        const neverType = createIntrinsicType(TypeFlags.Never, 'never');
        const silentNeverType = createIntrinsicType(TypeFlags.Never, 'never');
        const nonInferrableType = createIntrinsicType(
            TypeFlags.Never,
            'never',
            ObjectFlags.NonInferrableType
        );
        const implicitNeverType = createIntrinsicType(TypeFlags.Never,
            'never');
        const unreachableNeverType = createIntrinsicType(
            TypeFlags.Never,
            'never'
        );
        const nonPrimitiveType = createIntrinsicType(
            TypeFlags.NonPrimitive,
            'object'
        );
        const stringNumberSymbolType = getUnionType(
            [stringType, numberType, esSymbolType]
        );
        const keyofConstraintType = keyofStringsOnly
            ? stringType
            : stringNumberSymbolType;
        const numberOrBigIntType = getUnionType([numberType, bigintType]);

        const emptyObjectType = createAnonymousType(
            undefined,
            emptySymbols,
            emptyArray,
            emptyArray,
            undefined,
            undefined
        );
        const emptyJsxObjectType = createAnonymousType(
            undefined,
            emptySymbols,
            emptyArray,
            emptyArray,
            undefined,
            undefined
        );
        emptyJsxObjectType.objectFlags |= ObjectFlags.JsxAttributes;

        const emptyTypeLiteralSymbol = createSymbol(
            SymbolFlags.TypeLiteral,
            InternalSymbolName.Type
        );
        emptyTypeLiteralSymbol.members = createSymbolTable();
        const emptyTypeLiteralType = createAnonymousType(
            emptyTypeLiteralSymbol,
            emptySymbols,
            emptyArray,
            emptyArray,
            undefined,
            undefined
        );

        const emptyGenericType = <GenericType> <ObjectType> createAnonymousType(
            undefined,
            emptySymbols,
            emptyArray,
            emptyArray,
            undefined,
            undefined
        );
        emptyGenericType.instantiations = createMap<TypeReference>();

        const anyFunctionType = createAnonymousType(
            undefined,
            emptySymbols,
            emptyArray,
            emptyArray,
            undefined,
            undefined
        );
        // The anyFunctionType contains the anyFunctionType by definition. The flag is further propagated
        // in getPropagatingFlagsOfTypes, and it is checked in inferFromTypes.
        anyFunctionType.objectFlags |= ObjectFlags.NonInferrableType;

        const noConstraintType = createAnonymousType(
            undefined,
            emptySymbols,
            emptyArray,
            emptyArray,
            undefined,
            undefined
        );
        const circularConstraintType = createAnonymousType(
            undefined,
            emptySymbols,
            emptyArray,
            emptyArray,
            undefined,
            undefined
        );
        const resolvingDefaultType = createAnonymousType(
            undefined,
            emptySymbols,
            emptyArray,
            emptyArray,
            undefined,
            undefined
        );

        const markerSuperType = createTypeParameter();
        const markerSubType = createTypeParameter();
        markerSubType.constraint = markerSuperType;
        const markerOtherType = createTypeParameter();

        const noTypePredicate = createTypePredicate(
            TypePredicateKind.Identifier,
            '<<unresolved>>',
            0,
            anyType
        );

        const anySignature = createSignature(
            undefined,
            undefined,
            undefined,
            emptyArray,
            anyType, /*resolvedTypePredicate*/
            undefined,
            0,
            SignatureFlags.None
        );
        const unknownSignature = createSignature(
            undefined,
            undefined,
            undefined,
            emptyArray,
            errorType, /*resolvedTypePredicate*/
            undefined,
            0,
            SignatureFlags.None
        );
        const resolvingSignature = createSignature(
            undefined,
            undefined,
            undefined,
            emptyArray,
            anyType, /*resolvedTypePredicate*/
            undefined,
            0,
            SignatureFlags.None
        );
        const silentNeverSignature = createSignature(
            undefined,
            undefined,
            undefined,
            emptyArray,
            silentNeverType, /*resolvedTypePredicate*/
            undefined,
            0,
            SignatureFlags.None
        );

        const enumNumberIndexInfo = createIndexInfo(
            stringType, /*isReadonly*/
            true
        );

        const iterationTypesCache = createMap<IterationTypes>(); // cache for common IterationTypes instances
        const noIterationTypes: IterationTypes = {
            get yieldType(): Type {
                throw new Error('Not supported');
            },
            get returnType(): Type {
                throw new Error('Not supported');
            },
            get nextType(): Type {
                throw new Error('Not supported');
            }
        };
        const anyIterationTypes = createIterationTypes(
            anyType,
            anyType,
            anyType
        );
        const anyIterationTypesExceptNext = createIterationTypes(
            anyType,
            anyType,
            unknownType
        );
        const defaultIterationTypes = createIterationTypes(
            neverType,
            anyType,
            undefinedType
        ); // default iteration types for `Iterator`.

        const asyncIterationTypesResolver: IterationTypesResolver = {
            iterableCacheKey: 'iterationTypesOfAsyncIterable',
            iteratorCacheKey: 'iterationTypesOfAsyncIterator',
            iteratorSymbolName: 'asyncIterator',
            getGlobalIteratorType: getGlobalAsyncIteratorType,
            getGlobalIterableType: getGlobalAsyncIterableType,
            getGlobalIterableIteratorType: getGlobalAsyncIterableIteratorType,
            getGlobalGeneratorType: getGlobalAsyncGeneratorType,
            resolveIterationType: getAwaitedType,
            mustHaveANextMethodDiagnostic: Diagnostics
                .An_async_iterator_must_have_a_next_method,
            mustBeAMethodDiagnostic: Diagnostics
                .The_0_property_of_an_async_iterator_must_be_a_method,
            mustHaveAValueDiagnostic: Diagnostics
                .The_type_returned_by_the_0_method_of_an_async_iterator_must_be_a_promise_for_a_type_with_a_value_property
        };

        const syncIterationTypesResolver: IterationTypesResolver = {
            iterableCacheKey: 'iterationTypesOfIterable',
            iteratorCacheKey: 'iterationTypesOfIterator',
            iteratorSymbolName: 'iterator',
            getGlobalIteratorType,
            getGlobalIterableType,
            getGlobalIterableIteratorType,
            getGlobalGeneratorType,
            resolveIterationType: (type, _errorNode) => type,
            mustHaveANextMethodDiagnostic: Diagnostics
                .An_iterator_must_have_a_next_method,
            mustBeAMethodDiagnostic: Diagnostics
                .The_0_property_of_an_iterator_must_be_a_method,
            mustHaveAValueDiagnostic: Diagnostics
                .The_type_returned_by_the_0_method_of_an_iterator_must_have_a_value_property
        };

        interface DuplicateInfoForSymbol {
            readonly firstFileLocations: Node[];
            readonly secondFileLocations: Node[];
            readonly isBlockScoped: boolean;
        }
        interface DuplicateInfoForFiles {
            readonly firstFile: SourceFile;
            readonly secondFile: SourceFile;
            /** Key is symbol name. */
            readonly conflictingSymbols: Map<DuplicateInfoForSymbol>;
        }
        /** Key is "/path/to/a.ts|/path/to/b.ts". */
        let amalgamatedDuplicates: Map<DuplicateInfoForFiles> | undefined;
        const reverseMappedCache = createMap<Type | undefined>();
        let ambientModulesCache: Symbol[] | undefined;
        /**
         * List of every ambient module with a "*" wildcard.
         * Unlike other ambient modules, these can't be stored in `globals` because symbol tables only deal with exact matches.
         * This is only used if there is no exact match.
         */
        let patternAmbientModules: PatternAmbientModule[];
        let patternAmbientModuleAugmentations: Map<Symbol> | undefined;

        let globalObjectType: ObjectType;
        let globalFunctionType: ObjectType;
        let globalCallableFunctionType: ObjectType;
        let globalNewableFunctionType: ObjectType;
        let globalArrayType: GenericType;
        let globalReadonlyArrayType: GenericType;
        let globalStringType: ObjectType;
        let globalNumberType: ObjectType;
        let globalBooleanType: ObjectType;
        let globalRegExpType: ObjectType;
        let globalThisType: GenericType;
        let anyArrayType: Type;
        let autoArrayType: Type;
        let anyReadonlyArrayType: Type;
        let deferredGlobalNonNullableTypeAlias: Symbol;

        // The library files are only loaded when the feature is used.
        // This allows users to just specify library files they want to used through --lib
        // and they will not get an error from not having unrelated library files
        let deferredGlobalESSymbolConstructorSymbol: Symbol | undefined;
        let deferredGlobalESSymbolType: ObjectType;
        let deferredGlobalTypedPropertyDescriptorType: GenericType;
        let deferredGlobalPromiseType: GenericType;
        let deferredGlobalPromiseLikeType: GenericType;
        let deferredGlobalPromiseConstructorSymbol: Symbol | undefined;
        let deferredGlobalPromiseConstructorLikeType: ObjectType;
        let deferredGlobalIterableType: GenericType;
        let deferredGlobalIteratorType: GenericType;
        let deferredGlobalIterableIteratorType: GenericType;
        let deferredGlobalGeneratorType: GenericType;
        let deferredGlobalIteratorYieldResultType: GenericType;
        let deferredGlobalIteratorReturnResultType: GenericType;
        let deferredGlobalAsyncIterableType: GenericType;
        let deferredGlobalAsyncIteratorType: GenericType;
        let deferredGlobalAsyncIterableIteratorType: GenericType;
        let deferredGlobalAsyncGeneratorType: GenericType;
        let deferredGlobalTemplateStringsArrayType: ObjectType;
        let deferredGlobalImportMetaType: ObjectType;
        let deferredGlobalExtractSymbol: Symbol;
        let deferredGlobalOmitSymbol: Symbol;
        let deferredGlobalBigIntType: ObjectType;

        const allPotentiallyUnusedIdentifiers = createMap<PotentiallyUnusedIdentifier[]>(); // key is file name

        let flowLoopStart = 0;
        let flowLoopCount = 0;
        let sharedFlowCount = 0;
        let flowAnalysisDisabled = false;
        let flowInvocationCount = 0;
        let lastFlowNode: FlowNode | undefined;
        let lastFlowNodeReachable: boolean;
        let flowTypeCache: Type[] | undefined;

        const emptyStringType = getLiteralType('');
        const zeroType = getLiteralType(0);
        const zeroBigIntType = getLiteralType(
            { negative: false, base10Value: '0' }
        );

        const resolutionTargets: TypeSystemEntity[] = [];
        const resolutionResults: boolean[] = [];
        const resolutionPropertyNames: TypeSystemPropertyName[] = [];

        let suggestionCount = 0;
        const maximumSuggestionCount = 10;
        const mergedSymbols: Symbol[] = [];
        const symbolLinks: SymbolLinks[] = [];
        const nodeLinks: NodeLinks[] = [];
        const flowLoopCaches: Map<Type>[] = [];
        const flowLoopNodes: FlowNode[] = [];
        const flowLoopKeys: string[] = [];
        const flowLoopTypes: Type[][] = [];
        const sharedFlowNodes: FlowNode[] = [];
        const sharedFlowTypes: FlowType[] = [];
        const flowNodeReachable: (boolean | undefined)[] = [];
        const potentialThisCollisions: Node[] = [];
        const potentialNewTargetCollisions: Node[] = [];
        const potentialWeakMapCollisions: Node[] = [];
        const awaitedTypeStack: number[] = [];

        const diagnostics = createDiagnosticCollection();
        const suggestionDiagnostics = createDiagnosticCollection();

        const typeofTypesByName:
            ReadonlyMap<Type> = createMapFromTemplate<Type>(
                {
                    string: stringType,
                    number: numberType,
                    bigint: bigintType,
                    boolean: booleanType,
                    symbol: esSymbolType,
                    undefined: undefinedType
                }
            );
        const typeofType = createTypeofType();

        let _jsxNamespace: __String;
        let _jsxFactoryEntity: EntityName | undefined;
        let outofbandVarianceMarkerHandler: ((onlyUnreliable: boolean) => void)
            | undefined;

        const subtypeRelation = createMap<RelationComparisonResult>();
        const strictSubtypeRelation = createMap<RelationComparisonResult>();
        const assignableRelation = createMap<RelationComparisonResult>();
        const comparableRelation = createMap<RelationComparisonResult>();
        const identityRelation = createMap<RelationComparisonResult>();
        const enumRelation = createMap<RelationComparisonResult>();

        const builtinGlobals = createSymbolTable();
        builtinGlobals.set(undefinedSymbol.escapedName, undefinedSymbol);

        initializeTypeChecker();

        return checker;

        function getJsxNamespace(location: Node | undefined): __String {
            if (location) {
                const file = getSourceFileOfNode(location);
                if (file) {
                    if (file.localJsxNamespace) {
                        return file.localJsxNamespace;
                    }
                    const jsxPragma = file.pragmas.get('jsx');
                    if (jsxPragma) {
                        const chosenpragma = isArray(jsxPragma)
                            ? jsxPragma[0]
                            : jsxPragma;
                        file
                            .localJsxFactory = parseIsolatedEntityName(
                                chosenpragma.arguments.factory,
                                languageVersion
                            );
                        if (file.localJsxFactory) {
                            return file
                                .localJsxNamespace = getFirstIdentifier(
                                    file.localJsxFactory
                                ).escapedText;
                        }
                    }
                }
            }
            if (!_jsxNamespace) {
                _jsxNamespace = 'React' as __String;
                if (compilerOptions.jsxFactory) {
                    _jsxFactoryEntity = parseIsolatedEntityName(
                        compilerOptions.jsxFactory,
                        languageVersion
                    );
                    if (_jsxFactoryEntity) {
                        _jsxNamespace = getFirstIdentifier(_jsxFactoryEntity)
                            .escapedText;
                    }
                } else if (compilerOptions.reactNamespace) {
                    _jsxNamespace = escapeLeadingUnderscores(
                        compilerOptions.reactNamespace
                    );
                }
            }
            return _jsxNamespace;
        }

        function getEmitResolver(
            sourceFile: SourceFile,
            cancellationToken: CancellationToken
        ) {
            // Ensure we have all the type information in place for this file so that all the
            // emitter questions of this resolver will return the right information.
            getDiagnostics(sourceFile, cancellationToken);
            return emitResolver;
        }

        function lookupOrIssueError(
            location: Node | undefined,
            message: DiagnosticMessage,
            arg0?: string | number,
            arg1?: string | number,
            arg2?: string | number,
            arg3?: string | number
        ): Diagnostic {
            const diagnostic = location
                ? createDiagnosticForNode(
                    location,
                    message,
                    arg0,
                    arg1,
                    arg2,
                    arg3
                )
                : createCompilerDiagnostic(message, arg0, arg1, arg2, arg3);
            const existing = diagnostics.lookup(diagnostic);
            if (existing) {
                return existing;
            } else {
                diagnostics.add(diagnostic);
                return diagnostic;
            }
        }

        function error(
            location: Node | undefined,
            message: DiagnosticMessage,
            arg0?: string | number,
            arg1?: string | number,
            arg2?: string | number,
            arg3?: string | number
        ): Diagnostic {
            const diagnostic = location
                ? createDiagnosticForNode(
                    location,
                    message,
                    arg0,
                    arg1,
                    arg2,
                    arg3
                )
                : createCompilerDiagnostic(message, arg0, arg1, arg2, arg3);
            diagnostics.add(diagnostic);
            return diagnostic;
        }

        function addErrorOrSuggestion(
            isError: boolean,
            diagnostic: DiagnosticWithLocation
        ) {
            if (isError) {
                diagnostics.add(diagnostic);
            } else {
                suggestionDiagnostics
                    .add(
                        { ...diagnostic,
                            category: DiagnosticCategory.Suggestion }
                    );
            }
        }
        function errorOrSuggestion(
            isError: boolean,
            location: Node,
            message: DiagnosticMessage | DiagnosticMessageChain,
            arg0?: string | number,
            arg1?: string | number,
            arg2?: string | number,
            arg3?: string | number
        ): void {
            addErrorOrSuggestion(
                isError,
                'message' in message
                    ? createDiagnosticForNode(
                        location,
                        message,
                        arg0,
                        arg1,
                        arg2,
                        arg3
                    )
                    : createDiagnosticForNodeFromMessageChain(
                        location,
                        message
                    )
            ); // eslint-disable-line no-in-operator
        }

        function errorAndMaybeSuggestAwait(
            location: Node,
            maybeMissingAwait: boolean,
            message: DiagnosticMessage,
            arg0?: string | number | undefined,
            arg1?: string | number | undefined,
            arg2?: string | number | undefined,
            arg3?: string | number | undefined
        ): Diagnostic {
            const diagnostic = error(location, message, arg0, arg1, arg2,
                arg3);
            if (maybeMissingAwait) {
                const related = createDiagnosticForNode(
                    location,
                    Diagnostics.Did_you_forget_to_use_await
                );
                addRelatedInfo(diagnostic, related);
            }
            return diagnostic;
        }

        function createSymbol(
            flags: SymbolFlags,
            name: __String,
            checkFlags?: CheckFlags
        ) {
            symbolCount++;
            const symbol = <TransientSymbol> (new Symbol(
                flags | SymbolFlags.Transient,
                name
            ));
            symbol.checkFlags = checkFlags || 0;
            return symbol;
        }

        function getExcludedSymbolFlags(flags: SymbolFlags): SymbolFlags {
            let result: SymbolFlags = 0;
            if (flags & SymbolFlags.BlockScopedVariable) {
                result |= SymbolFlags.BlockScopedVariableExcludes;
            }
            if (flags
                & SymbolFlags.FunctionScopedVariable)
                result |= SymbolFlags.FunctionScopedVariableExcludes;
            if (flags & SymbolFlags.Property) {
                result |= SymbolFlags.PropertyExcludes;
            }
            if (flags & SymbolFlags.EnumMember) {
                result |= SymbolFlags.EnumMemberExcludes;
            }
            if (flags & SymbolFlags.Function) {
                result |= SymbolFlags.FunctionExcludes;
            }
            if (flags & SymbolFlags.Class) result |= SymbolFlags.ClassExcludes;
            if (flags & SymbolFlags.Interface) {
                result |= SymbolFlags.InterfaceExcludes;
            }
            if (flags & SymbolFlags.RegularEnum) {
                result |= SymbolFlags.RegularEnumExcludes;
            }
            if (flags & SymbolFlags.ConstEnum) {
                result |= SymbolFlags.ConstEnumExcludes;
            }
            if (flags & SymbolFlags.ValueModule) {
                result |= SymbolFlags.ValueModuleExcludes;
            }
            if (flags & SymbolFlags.Method) {
                result |= SymbolFlags.MethodExcludes;
            }
            if (flags & SymbolFlags.GetAccessor) {
                result |= SymbolFlags.GetAccessorExcludes;
            }
            if (flags & SymbolFlags.SetAccessor) {
                result |= SymbolFlags.SetAccessorExcludes;
            }
            if (flags & SymbolFlags.TypeParameter) {
                result |= SymbolFlags.TypeParameterExcludes;
            }
            if (flags & SymbolFlags.TypeAlias) {
                result |= SymbolFlags.TypeAliasExcludes;
            }
            if (flags & SymbolFlags.Alias) result |= SymbolFlags.AliasExcludes;
            return result;
        }

        function recordMergedSymbol(target: Symbol, source: Symbol) {
            if (!source.mergeId) {
                source.mergeId = nextMergeId;
                nextMergeId++;
            }
            mergedSymbols[source.mergeId] = target;
        }

        function cloneSymbol(symbol: Symbol): Symbol {
            const result = createSymbol(symbol.flags, symbol.escapedName);
            result.declarations = symbol.declarations
                ? symbol.declarations.slice()
                : [];
            result.parent = symbol.parent;
            if (symbol.valueDeclaration) {
                result.valueDeclaration = symbol.valueDeclaration;
            }
            if (symbol.constEnumOnlyModule) result.constEnumOnlyModule = true;
            if (symbol.members) result.members = cloneMap(symbol.members);
            if (symbol.exports) result.exports = cloneMap(symbol.exports);
            recordMergedSymbol(result, symbol);
            return result;
        }

        /**
         * Note: if target is transient, then it is mutable, and mergeSymbol with both mutate and return it.
         * If target is not transient, mergeSymbol will produce a transient clone, mutate that and return it.
         */
        function mergeSymbol(
            target: Symbol,
            source: Symbol,
            unidirectional = false
        ): Symbol {
            if (!(target.flags & getExcludedSymbolFlags(source.flags))
                || (source.flags | target.flags) & SymbolFlags.Assignment)
            {
                if (source === target) {
                    // This can happen when an export assigned namespace exports something also erroneously exported at the top level
                    // See `declarationFileNoCrashOnExtraExportModifier` for an example
                    return target;
                }
                if (!(target.flags & SymbolFlags.Transient)) {
                    const resolvedTarget = resolveSymbol(target);
                    if (resolvedTarget === unknownSymbol) {
                        return source;
                    }
                    target = cloneSymbol(resolvedTarget);
                }
                // Javascript static-property-assignment declarations always merge, even though they are also values
                if (source.flags & SymbolFlags.ValueModule
                    && target.flags & SymbolFlags.ValueModule
                    && target.constEnumOnlyModule
                    && !source.constEnumOnlyModule)
                {
                    // reset flag when merging instantiated module into value module that has only const enums
                    target.constEnumOnlyModule = false;
                }
                target.flags |= source.flags;
                if (source.valueDeclaration
                    && (!target.valueDeclaration
                        || isAssignmentDeclaration(target.valueDeclaration)
                        && !isAssignmentDeclaration(source.valueDeclaration)
                        || isEffectiveModuleDeclaration(
                            target.valueDeclaration
                        )
                        && !isEffectiveModuleDeclaration(
                            source.valueDeclaration
                        )))
                {
                    // other kinds of value declarations take precedence over modules and assignment declarations
                    target.valueDeclaration = source.valueDeclaration;
                }
                addRange(target.declarations, source.declarations);
                if (source.members) {
                    if (!target.members) target.members = createSymbolTable();
                    mergeSymbolTable(
                        target.members,
                        source.members,
                        unidirectional
                    );
                }
                if (source.exports) {
                    if (!target.exports) target.exports = createSymbolTable();
                    mergeSymbolTable(
                        target.exports,
                        source.exports,
                        unidirectional
                    );
                }
                if (!unidirectional) {
                    recordMergedSymbol(target, source);
                }
            } else if (target.flags & SymbolFlags.NamespaceModule) {
                // Do not report an error when merging `var globalThis` with the built-in `globalThis`,
                // as we will already report a "Declaration name conflicts..." error, and this error
                // won't make much sense.
                if (target !== globalThisSymbol) {
                    error(
                        getNameOfDeclaration(source.declarations[0]),
                        Diagnostics
                            .Cannot_augment_module_0_with_value_exports_because_it_resolves_to_a_non_module_entity,
                        symbolToString(target)
                    );
                }
            } else { // error
                const isEitherEnum = !!(target.flags & SymbolFlags.Enum
                    || source.flags & SymbolFlags.Enum);
                const isEitherBlockScoped = !!(target.flags
                    & SymbolFlags.BlockScopedVariable
                    || source.flags & SymbolFlags.BlockScopedVariable);
                const message = isEitherEnum
                    ? Diagnostics
                        .Enum_declarations_can_only_merge_with_namespace_or_other_enum_declarations
                    : isEitherBlockScoped
                        ? Diagnostics.Cannot_redeclare_block_scoped_variable_0
                        : Diagnostics.Duplicate_identifier_0;
                const sourceSymbolFile = source.declarations
                    && getSourceFileOfNode(source.declarations[0]);
                const targetSymbolFile = target.declarations
                    && getSourceFileOfNode(target.declarations[0]);
                const symbolName = symbolToString(source);

                // Collect top-level duplicate identifier errors into one mapping, so we can then merge their diagnostics if there are a bunch
                if (sourceSymbolFile && targetSymbolFile
                    && amalgamatedDuplicates && !isEitherEnum
                    && sourceSymbolFile !== targetSymbolFile)
                {
                    const firstFile = comparePaths(
                        sourceSymbolFile.path,
                        targetSymbolFile.path
                    ) === Comparison.LessThan
                        ? sourceSymbolFile
                        : targetSymbolFile;
                    const secondFile = firstFile === sourceSymbolFile
                        ? targetSymbolFile
                        : sourceSymbolFile;
                    const filesDuplicates = getOrUpdate<DuplicateInfoForFiles>(
                        amalgamatedDuplicates,
                        `${firstFile.path}|${secondFile.path}`,
                        () => ({ firstFile, secondFile,
                            conflictingSymbols: createMap() })
                    );
                    const conflictingSymbolInfo = getOrUpdate<DuplicateInfoForSymbol>(
                        filesDuplicates.conflictingSymbols,
                        symbolName,
                        () => ({ isBlockScoped: isEitherBlockScoped,
                            firstFileLocations: [], secondFileLocations: [] })
                    );
                    addDuplicateLocations(
                        conflictingSymbolInfo.firstFileLocations,
                        source
                    );
                    addDuplicateLocations(
                        conflictingSymbolInfo.secondFileLocations,
                        target
                    );
                } else {
                    addDuplicateDeclarationErrorsForSymbols(
                        source,
                        message,
                        symbolName,
                        target
                    );
                    addDuplicateDeclarationErrorsForSymbols(
                        target,
                        message,
                        symbolName,
                        source
                    );
                }
            }
            return target;

            function addDuplicateLocations(locs: Node[],
                symbol: Symbol): void
            {
                for (const decl of symbol.declarations) {
                    pushIfUnique(
                        locs,
                        (getExpandoInitializer(
                            decl, /*isPrototypeAssignment*/
                            false
                        )
                            ? getNameOfExpando(decl)
                            : getNameOfDeclaration(decl)) || decl
                    );
                }
            }
        }

        function addDuplicateDeclarationErrorsForSymbols(
            target: Symbol,
            message: DiagnosticMessage,
            symbolName: string,
            source: Symbol
        ) {
            forEach(
                target.declarations,
                node => {
                    const errorNode = (getExpandoInitializer(
                        node, /*isPrototypeAssignment*/
                        false
                    )
                        ? getNameOfExpando(node)
                        : getNameOfDeclaration(node)) || node;
                    addDuplicateDeclarationError(
                        errorNode,
                        message,
                        symbolName,
                        source.declarations
                    );
                }
            );
        }

        function addDuplicateDeclarationError(
            errorNode: Node,
            message: DiagnosticMessage,
            symbolName: string,
            relatedNodes: readonly Node[] | undefined
        ) {
            const err = lookupOrIssueError(errorNode, message, symbolName);
            for (const relatedNode of relatedNodes || emptyArray) {
                err.relatedInformation = err.relatedInformation || [];
                if (length(err.relatedInformation) >= 5) continue;
                addRelatedInfo(
                    err,
                    !length(err.relatedInformation)
                        ? createDiagnosticForNode(
                            relatedNode,
                            Diagnostics._0_was_also_declared_here,
                            symbolName
                        )
                        : createDiagnosticForNode(
                            relatedNode,
                            Diagnostics.and_here
                        )
                );
            }
        }

        function combineSymbolTables(
            first: SymbolTable | undefined,
            second: SymbolTable | undefined
        ): SymbolTable | undefined {
            if (!hasEntries(first)) return second;
            if (!hasEntries(second)) return first;
            const combined = createSymbolTable();
            mergeSymbolTable(combined, first);
            mergeSymbolTable(combined, second);
            return combined;
        }

        function mergeSymbolTable(
            target: SymbolTable,
            source: SymbolTable,
            unidirectional = false
        ) {
            source.forEach((sourceSymbol, id) => {
                const targetSymbol = target.get(id);
                target.set(
                    id,
                    targetSymbol
                        ? mergeSymbol(
                            targetSymbol,
                            sourceSymbol,
                            unidirectional
                        )
                        : sourceSymbol
                );
            });
        }

        function mergeModuleAugmentation(
            moduleName: StringLiteral | Identifier
        ): void {
            const moduleAugmentation = <ModuleDeclaration> moduleName.parent;
            if (moduleAugmentation.symbol.declarations[0]
                !== moduleAugmentation)
            {
                // this is a combined symbol for multiple augmentations within the same file.
                // its symbol already has accumulated information for all declarations
                // so we need to add it just once - do the work only for first declaration
                Debug
                    .assert(moduleAugmentation.symbol.declarations.length > 1);
                return;
            }

            if (isGlobalScopeAugmentation(moduleAugmentation)) {
                mergeSymbolTable(globals, moduleAugmentation.symbol.exports!);
            } else {
                // find a module that about to be augmented
                // do not validate names of augmentations that are defined in ambient context
                const moduleNotFoundError = !(moduleName.parent.parent.flags
                    & NodeFlags.Ambient)
                    ? Diagnostics
                        .Invalid_module_name_in_augmentation_module_0_cannot_be_found
                    : undefined;
                let mainModule = resolveExternalModuleNameWorker(
                    moduleName,
                    moduleName,
                    moduleNotFoundError, /*isForAugmentation*/
                    true
                );
                if (!mainModule) {
                    return;
                }
                // obtain item referenced by 'export='
                mainModule = resolveExternalModuleSymbol(mainModule);
                if (mainModule.flags & SymbolFlags.Namespace) {
                    // If we're merging an augmentation to a pattern ambient module, we want to
                    // perform the merge unidirectionally from the augmentation ('a.foo') to
                    // the pattern ('*.foo'), so that 'getMergedSymbol()' on a.foo gives you
                    // all the exports both from the pattern and from the augmentation, but
                    // 'getMergedSymbol()' on *.foo only gives you exports from *.foo.
                    if (some(
                        patternAmbientModules,
                        module => mainModule === module.symbol
                    )) {
                        const merged = mergeSymbol(
                            moduleAugmentation.symbol,
                            mainModule, /*unidirectional*/
                            true
                        );
                        if (!patternAmbientModuleAugmentations) {
                            patternAmbientModuleAugmentations = createMap();
                        }
                        // moduleName will be a StringLiteral since this is not `declare global`.
                        patternAmbientModuleAugmentations
                            .set((moduleName as StringLiteral).text, merged);
                    } else {
                        mergeSymbol(mainModule, moduleAugmentation.symbol);
                    }
                } else {
                    // moduleName will be a StringLiteral since this is not `declare global`.
                    error(
                        moduleName,
                        Diagnostics
                            .Cannot_augment_module_0_because_it_resolves_to_a_non_module_entity,
                        (moduleName as StringLiteral).text
                    );
                }
            }
        }

        function addToSymbolTable(
            target: SymbolTable,
            source: SymbolTable,
            message: DiagnosticMessage
        ) {
            source.forEach((sourceSymbol, id) => {
                const targetSymbol = target.get(id);
                if (targetSymbol) {
                    // Error on redeclarations
                    forEach(
                        targetSymbol.declarations,
                        addDeclarationDiagnostic(
                            unescapeLeadingUnderscores(id),
                            message
                        )
                    );
                } else {
                    target.set(id, sourceSymbol);
                }
            });

            function addDeclarationDiagnostic(
                id: string,
                message: DiagnosticMessage
            ) {
                return (declaration: Declaration) => diagnostics
                    .add(createDiagnosticForNode(declaration, message, id));
            }
        }

        function getSymbolLinks(symbol: Symbol): SymbolLinks {
            if (symbol.flags
                & SymbolFlags.Transient)
                return <TransientSymbol> symbol;
            const id = getSymbolId(symbol);
            return symbolLinks[id] || (symbolLinks[id] = {});
        }

        function getNodeLinks(node: Node): NodeLinks {
            const nodeId = getNodeId(node);
            return nodeLinks[nodeId]
                || (nodeLinks[nodeId] = { flags: 0 } as NodeLinks);
        }

        function isGlobalSourceFile(node: Node) {
            return node.kind === SyntaxKind.SourceFile
                && !isExternalOrCommonJsModule(<SourceFile> node);
        }

        function getSymbol(
            symbols: SymbolTable,
            name: __String,
            meaning: SymbolFlags
        ): Symbol | undefined {
            if (meaning) {
                const symbol = symbols.get(name);
                if (symbol) {
                    Debug
                        .assert(
                            (getCheckFlags(symbol) & CheckFlags.Instantiated)
                                === 0,
                            'Should never get an instantiated symbol here.'
                        );
                    if (symbol.flags & meaning) {
                        return symbol;
                    }
                    if (symbol.flags & SymbolFlags.Alias) {
                        const target = resolveAlias(symbol);
                        // Unknown symbol means an error occurred in alias resolution, treat it as positive answer to avoid cascading errors
                        if (target === unknownSymbol
                            || target.flags & meaning)
                        {
                            return symbol;
                        }
                    }
                }
            }
            // return undefined if we can't find a symbol.
        }

        /**
         * Get symbols that represent parameter-property-declaration as parameter and as property declaration
         * @param parameter a parameterDeclaration node
         * @param parameterName a name of the parameter to get the symbols for.
         * @return a tuple of two symbols
         */
        function getSymbolsOfParameterPropertyDeclaration(
            parameter: ParameterDeclaration,
            parameterName: __String
        ): [Symbol, Symbol] {
            const constructorDeclaration = parameter.parent;
            const classDeclaration = parameter.parent.parent;

            const parameterSymbol = getSymbol(
                constructorDeclaration.locals!,
                parameterName,
                SymbolFlags.Value
            );
            const propertySymbol = getSymbol(
                getMembersOfSymbol(
                    classDeclaration.symbol
                ),
                parameterName,
                SymbolFlags.Value
            );

            if (parameterSymbol && propertySymbol) {
                return [parameterSymbol, propertySymbol];
            }

            return Debug
                .fail('There should exist two symbols, one as property declaration and one as parameter declaration');
        }

        function isBlockScopedNameDeclaredBeforeUse(
            declaration: Declaration,
            usage: Node
        ): boolean {
            const declarationFile = getSourceFileOfNode(declaration);
            const useFile = getSourceFileOfNode(usage);
            if (declarationFile !== useFile) {
                if ((moduleKind
                    && (declarationFile.externalModuleIndicator
                        || useFile.externalModuleIndicator))
                    || (!compilerOptions.outFile && !compilerOptions.out)
                    || isInTypeQuery(usage)
                    || declaration.flags & NodeFlags.Ambient)
                {
                    // nodes are in different files and order cannot be determined
                    return true;
                }
                // declaration is after usage
                // can be legal if usage is deferred (i.e. inside function or in initializer of instance property)
                if (isUsedInFunctionOrInstanceProperty(usage, declaration)) {
                    return true;
                }
                const sourceFiles = host.getSourceFiles();
                return sourceFiles.indexOf(declarationFile)
                    <= sourceFiles.indexOf(useFile);
            }

            if (declaration.pos <= usage.pos) {
                // declaration is before usage
                if (declaration.kind === SyntaxKind.BindingElement) {
                    // still might be illegal if declaration and usage are both binding elements (eg var [a = b, b = b] = [1, 2])
                    const errorBindingElement = getAncestor(
                        usage,
                        SyntaxKind.BindingElement
                    ) as BindingElement;
                    if (errorBindingElement) {
                        return findAncestor(
                            errorBindingElement,
                            isBindingElement
                        ) !== findAncestor(declaration, isBindingElement)
                            || declaration.pos < errorBindingElement.pos;
                    }
                    // or it might be illegal if usage happens before parent variable is declared (eg var [a] = a)
                    return isBlockScopedNameDeclaredBeforeUse(
                        getAncestor(
                            declaration,
                            SyntaxKind.VariableDeclaration
                        ) as Declaration,
                        usage
                    );
                } else if (declaration.kind
                    === SyntaxKind.VariableDeclaration)
                {
                    // still might be illegal if usage is in the initializer of the variable declaration (eg var a = a)
                    return !isImmediatelyUsedInInitializerOfBlockScopedVariable(
                        declaration as VariableDeclaration,
                        usage
                    );
                } else if (isClassDeclaration(declaration)) {
                    // still might be illegal if the usage is within a computed property name in the class (eg class A { static p = "a"; [A.p]() {} })
                    return !findAncestor(
                        usage,
                        n => isComputedPropertyName(n)
                            && n.parent.parent === declaration
                    );
                } else if (isPropertyDeclaration(declaration)) {
                    // still might be illegal if a self-referencing property initializer (eg private x = this.x)
                    return !isPropertyImmediatelyReferencedWithinDeclaration(
                        declaration,
                        usage
                    );
                }
                return true;
            }

            // declaration is after usage, but it can still be legal if usage is deferred:
            // 1. inside an export specifier
            // 2. inside a function
            // 3. inside an instance property initializer, a reference to a non-instance property
            // 4. inside a static property initializer, a reference to a static method in the same class
            // 5. inside a TS export= declaration (since we will move the export statement during emit to avoid TDZ)
            // or if usage is in a type context:
            // 1. inside a type query (typeof in type position)
            // 2. inside a jsdoc comment
            if (usage.parent.kind === SyntaxKind.ExportSpecifier
                || (usage.parent.kind === SyntaxKind.ExportAssignment
                    && (usage.parent as ExportAssignment).isExportEquals))
            {
                // export specifiers do not use the variable, they only make it available for use
                return true;
            }
            // When resolving symbols for exports, the `usage` location passed in can be the export site directly
            if (usage.kind === SyntaxKind.ExportAssignment
                && (usage as ExportAssignment).isExportEquals)
            {
                return true;
            }

            const container = getEnclosingBlockScopeContainer(declaration);
            return !!(usage.flags & NodeFlags.JSDoc) || isInTypeQuery(usage)
                || isUsedInFunctionOrInstanceProperty(
                    usage,
                    declaration,
                    container
                );

            function isImmediatelyUsedInInitializerOfBlockScopedVariable(
                declaration: VariableDeclaration,
                usage: Node
            ): boolean {
                const container = getEnclosingBlockScopeContainer(declaration);

                switch (declaration.parent.parent.kind) {
                    case SyntaxKind.VariableStatement:
                    case SyntaxKind.ForStatement:
                    case SyntaxKind.ForOfStatement:
                        // variable statement/for/for-of statement case,
                        // use site should not be inside variable declaration (initializer of declaration or binding element)
                        if (isSameScopeDescendentOf(
                            usage,
                            declaration,
                            container
                        )) {
                            return true;
                        }
                        break;
                }

                // ForIn/ForOf case - use site should not be used in expression part
                const grandparent = declaration.parent.parent;
                return isForInOrOfStatement(grandparent)
                    && isSameScopeDescendentOf(
                        usage,
                        grandparent.expression,
                        container
                    );
            }

            function isUsedInFunctionOrInstanceProperty(
                usage: Node,
                declaration: Node,
                container?: Node
            ): boolean {
                return !!findAncestor(
                    usage,
                    current => {
                        if (current === container) {
                            return 'quit';
                        }
                        if (isFunctionLike(current)) {
                            return true;
                        }

                        const initializerOfProperty = current.parent
                            && current.parent.kind
                            === SyntaxKind.PropertyDeclaration
                            && (<PropertyDeclaration> current.parent)
                                .initializer === current;

                        if (initializerOfProperty) {
                            if (hasModifier(current.parent,
                                ModifierFlags.Static))
                            {
                                if (declaration.kind
                                    === SyntaxKind.MethodDeclaration)
                                {
                                    return true;
                                }
                            } else {
                                const isDeclarationInstanceProperty = declaration
                                    .kind === SyntaxKind.PropertyDeclaration
                                    && !hasModifier(
                                        declaration,
                                        ModifierFlags.Static
                                    );
                                if (!isDeclarationInstanceProperty
                                    || getContainingClass(usage)
                                    !== getContainingClass(declaration))
                                {
                                    return true;
                                }
                            }
                        }
                        return false;
                    }
                );
            }

            function isPropertyImmediatelyReferencedWithinDeclaration(
                declaration: PropertyDeclaration,
                usage: Node
            ) {
                // always legal if usage is after declaration
                if (usage.end > declaration.end) {
                    return false;
                }

                // still might be legal if usage is deferred (e.g. x: any = () => this.x)
                // otherwise illegal if immediately referenced within the declaration (e.g. x: any = this.x)
                const ancestorChangingReferenceScope = findAncestor(
                    usage,
                    (node: Node) => {
                        if (node === declaration) {
                            return 'quit';
                        }

                        switch (node.kind) {
                            case SyntaxKind.ArrowFunction:
                            case SyntaxKind.PropertyDeclaration:
                                return true;
                            case SyntaxKind.Block:
                                switch (node.parent.kind) {
                                    case SyntaxKind.GetAccessor:
                                    case SyntaxKind.MethodDeclaration:
                                    case SyntaxKind.SetAccessor:
                                        return true;
                                    default:
                                        return false;
                                }
                            default:
                                return false;
                        }
                    }
                );

                return ancestorChangingReferenceScope === undefined;
            }
        }

        /**
         * Resolve a given name for a given meaning at a given location. An error is reported if the name was not found and
         * the nameNotFoundMessage argument is not undefined. Returns the resolved symbol, or undefined if no symbol with
         * the given name can be found.
         *
         * @param isUse If true, this will count towards --noUnusedLocals / --noUnusedParameters.
         */
        function resolveName(
            location: Node | undefined,
            name: __String,
            meaning: SymbolFlags,
            nameNotFoundMessage: DiagnosticMessage | undefined,
            nameArg: __String | Identifier | undefined,
            isUse: boolean,
            excludeGlobals = false,
            suggestedNameNotFoundMessage?: DiagnosticMessage
        ): Symbol | undefined {
            return resolveNameHelper(
                location,
                name,
                meaning,
                nameNotFoundMessage,
                nameArg,
                isUse,
                excludeGlobals,
                getSymbol,
                suggestedNameNotFoundMessage
            );
        }

        function resolveNameHelper(
            location: Node | undefined,
            name: __String,
            meaning: SymbolFlags,
            nameNotFoundMessage: DiagnosticMessage | undefined,
            nameArg: __String | Identifier | undefined,
            isUse: boolean,
            excludeGlobals: boolean,
            lookup: typeof getSymbol,
            suggestedNameNotFoundMessage?: DiagnosticMessage
        ): Symbol | undefined {
            const originalLocation = location; // needed for did-you-mean error reporting, which gathers candidates starting from the original location
            let result: Symbol | undefined;
            let lastLocation: Node | undefined;
            let lastSelfReferenceLocation: Node | undefined;
            let propertyWithInvalidInitializer: Node | undefined;
            let associatedDeclarationForContainingInitializer:
                ParameterDeclaration | BindingElement | undefined;
            let withinDeferredContext = false;
            const errorLocation = location;
            let grandparent: Node;
            let isInExternalModule = false;

            loop:
            while (location) {
                // Locals of a source file are not in scope (because they get merged into the global symbol table)
                if (location.locals && !isGlobalSourceFile(location)) {
                    if (result = lookup(location.locals, name, meaning)) {
                        let useResult = true;
                        if (isFunctionLike(location) && lastLocation
                            && lastLocation
                            !== (<FunctionLikeDeclaration> location).body)
                        {
                            // symbol lookup restrictions for function-like declarations
                            // - Type parameters of a function are in scope in the entire function declaration, including the parameter
                            //   list and return type. However, local types are only in scope in the function body.
                            // - parameters are only in the scope of function body
                            // This restriction does not apply to JSDoc comment types because they are parented
                            // at a higher level than type parameters would normally be
                            if (meaning & result.flags & SymbolFlags.Type
                                && lastLocation.kind
                                !== SyntaxKind.JSDocComment)
                            {
                                useResult = result.flags
                                    & SymbolFlags.TypeParameter
                                    ? // type parameters are visible in parameter list, return type and type parameter list
                                    lastLocation
                                        === (<FunctionLikeDeclaration> location)
                                            .type
                                        || lastLocation.kind
                                        === SyntaxKind.Parameter
                                        || lastLocation.kind
                                        === SyntaxKind.TypeParameter
                                    : // local types not visible outside the function body
                                    false;
                            }
                            if (meaning & result.flags
                                & SymbolFlags.Variable)
                            {
                                // expression inside parameter will lookup as normal variable scope when targeting es2015+
                                const functionLocation = <FunctionLikeDeclaration> location;
                                if (compilerOptions.target
                                    && compilerOptions.target
                                    >= ScriptTarget.ES2015
                                    && isParameter(lastLocation)
                                    && functionLocation.body
                                    && result.valueDeclaration.pos
                                    >= functionLocation.body.pos
                                    && result.valueDeclaration.end
                                    <= functionLocation.body.end)
                                {
                                    useResult = false;
                                } else if (result.flags
                                    & SymbolFlags.FunctionScopedVariable)
                                {
                                    // parameters are visible only inside function body, parameter list and return type
                                    // technically for parameter list case here we might mix parameters and variables declared in function,
                                    // however it is detected separately when checking initializers of parameters
                                    // to make sure that they reference no variables declared after them.
                                    useResult = lastLocation.kind
                                        === SyntaxKind.Parameter
                                        || (
                                            lastLocation
                                            === (<FunctionLikeDeclaration> location)
                                                .type
                                            && !!findAncestor(
                                                result.valueDeclaration,
                                                isParameter
                                            )
                                        );
                                }
                            }
                        } else if (location.kind
                            === SyntaxKind.ConditionalType)
                        {
                            // A type parameter declared using 'infer T' in a conditional type is visible only in
                            // the true branch of the conditional type.
                            useResult = lastLocation
                                === (<ConditionalTypeNode> location).trueType;
                        }

                        if (useResult) {
                            break loop;
                        } else {
                            result = undefined;
                        }
                    }
                }
                withinDeferredContext = withinDeferredContext
                    || getIsDeferredContext(location, lastLocation);
                switch (location.kind) {
                    case SyntaxKind.SourceFile:
                        if (!isExternalOrCommonJsModule(<SourceFile> location)) break;
                        isInExternalModule = true;
                        // falls through
                    case SyntaxKind.ModuleDeclaration:
                        const moduleExports = getSymbolOfNode(
                            location as SourceFile | ModuleDeclaration
                        ).exports || emptySymbols;
                        if (location.kind === SyntaxKind.SourceFile
                            || (isModuleDeclaration(location)
                                && location.flags & NodeFlags.Ambient
                                && !isGlobalScopeAugmentation(location)))
                        {
                            // It's an external module. First see if the module has an export default and if the local
                            // name of that export default matches.
                            if (result = moduleExports
                                .get(InternalSymbolName.Default))
                            {
                                const localSymbol = getLocalSymbolForExportDefault(result);
                                if (localSymbol && (result.flags & meaning)
                                    && localSymbol.escapedName === name)
                                {
                                    break loop;
                                }
                                result = undefined;
                            }

                            // Because of module/namespace merging, a module's exports are in scope,
                            // yet we never want to treat an export specifier as putting a member in scope.
                            // Therefore, if the name we find is purely an export specifier, it is not actually considered in scope.
                            // Two things to note about this:
                            //     1. We have to check this without calling getSymbol. The problem with calling getSymbol
                            //        on an export specifier is that it might find the export specifier itself, and try to
                            //        resolve it as an alias. This will cause the checker to consider the export specifier
                            //        a circular alias reference when it might not be.
                            //     2. We check === SymbolFlags.Alias in order to check that the symbol is *purely*
                            //        an alias. If we used &, we'd be throwing out symbols that have non alias aspects,
                            //        which is not the desired behavior.
                            const moduleExport = moduleExports.get(name);
                            if (moduleExport
                                && moduleExport.flags === SymbolFlags.Alias
                                && (getDeclarationOfKind(
                                    moduleExport,
                                    SyntaxKind.ExportSpecifier
                                )
                                    || getDeclarationOfKind(
                                        moduleExport,
                                        SyntaxKind.NamespaceExport
                                    )))
                            {
                                break;
                            }
                        }

                        // ES6 exports are also visible locally (except for 'default'), but commonjs exports are not (except typedefs)
                        if (name !== InternalSymbolName.Default
                            && (result = lookup(
                                moduleExports,
                                name,
                                meaning & SymbolFlags.ModuleMember
                            )))
                        {
                            if (isSourceFile(location)
                                && location.commonJsModuleIndicator
                                && !result.declarations.some(isJSDocTypeAlias))
                            {
                                result = undefined;
                            } else {
                                break loop;
                            }
                        }
                        break;
                    case SyntaxKind.EnumDeclaration:
                        if (result = lookup(
                            getSymbolOfNode(location)!.exports!,
                            name,
                            meaning & SymbolFlags.EnumMember
                        )) {
                            break loop;
                        }
                        break;
                    case SyntaxKind.PropertyDeclaration:
                        // TypeScript 1.0 spec (April 2014): 8.4.1
                        // Initializer expressions for instance member variables are evaluated in the scope
                        // of the class constructor body but are not permitted to reference parameters or
                        // local variables of the constructor. This effectively means that entities from outer scopes
                        // by the same name as a constructor parameter or local variable are inaccessible
                        // in initializer expressions for instance member variables.
                        if (!hasModifier(location, ModifierFlags.Static)) {
                            const ctor = findConstructorDeclaration(
                                location.parent as ClassLikeDeclaration
                            );
                            if (ctor && ctor.locals) {
                                if (lookup(
                                    ctor.locals,
                                    name,
                                    meaning & SymbolFlags.Value
                                )) {
                                    // Remember the property node, it will be used later to report appropriate error
                                    propertyWithInvalidInitializer = location;
                                }
                            }
                        }
                        break;
                    case SyntaxKind.ClassDeclaration:
                    case SyntaxKind.ClassExpression:
                    case SyntaxKind.InterfaceDeclaration:
                        // The below is used to lookup type parameters within a class or interface, as they are added to the class/interface locals
                        // These can never be latebound, so the symbol's raw members are sufficient. `getMembersOfNode` cannot be used, as it would
                        // trigger resolving late-bound names, which we may already be in the process of doing while we're here!
                        if (result = lookup(
                            getSymbolOfNode(
                                location as ClassLikeDeclaration
                                    | InterfaceDeclaration
                            ).members || emptySymbols,
                            name,
                            meaning & SymbolFlags.Type
                        )) {
                            if (!isTypeParameterSymbolDeclaredInContainer(
                                result,
                                location
                            )) {
                                // ignore type parameters not declared in this container
                                result = undefined;
                                break;
                            }
                            if (lastLocation
                                && hasModifier(
                                    lastLocation,
                                    ModifierFlags.Static
                                ))
                            {
                                // TypeScript 1.0 spec (April 2014): 3.4.1
                                // The scope of a type parameter extends over the entire declaration with which the type
                                // parameter list is associated, with the exception of static member declarations in classes.
                                error(
                                    errorLocation,
                                    Diagnostics
                                        .Static_members_cannot_reference_class_type_parameters
                                );
                                return undefined;
                            }
                            break loop;
                        }
                        if (location.kind === SyntaxKind.ClassExpression
                            && meaning & SymbolFlags.Class)
                        {
                            const className = (<ClassExpression> location)
                                .name;
                            if (className && name === className.escapedText) {
                                result = location.symbol;
                                break loop;
                            }
                        }
                        break;
                    case SyntaxKind.ExpressionWithTypeArguments:
                        // The type parameters of a class are not in scope in the base class expression.
                        if (lastLocation
                            === (<ExpressionWithTypeArguments> location)
                                .expression
                            && (<HeritageClause> location.parent).token
                            === SyntaxKind.ExtendsKeyword)
                        {
                            const container = location.parent.parent;
                            if (isClassLike(container)
                                && (result = lookup(
                                    getSymbolOfNode(container).members!,
                                    name,
                                    meaning & SymbolFlags.Type
                                )))
                            {
                                if (nameNotFoundMessage) {
                                    error(
                                        errorLocation,
                                        Diagnostics
                                            .Base_class_expressions_cannot_reference_class_type_parameters
                                    );
                                }
                                return undefined;
                            }
                        }
                        break;
                    // It is not legal to reference a class's own type parameters from a computed property name that
                    // belongs to the class. For example:
                    //
                    //   function foo<T>() { return '' }
                    //   class C<T> { // <-- Class's own type parameter T
                    //       [foo<T>()]() { } // <-- Reference to T from class's own computed property
                    //   }
                    //
                    case SyntaxKind.ComputedPropertyName:
                        grandparent = location.parent.parent;
                        if (isClassLike(grandparent)
                            || grandparent.kind
                            === SyntaxKind.InterfaceDeclaration)
                        {
                            // A reference to this grandparent's type parameters would be an error
                            if (result = lookup(
                                getSymbolOfNode(
                                    grandparent as ClassLikeDeclaration
                                        | InterfaceDeclaration
                                ).members!,
                                name,
                                meaning & SymbolFlags.Type
                            )) {
                                error(
                                    errorLocation,
                                    Diagnostics
                                        .A_computed_property_name_cannot_reference_a_type_parameter_from_its_containing_type
                                );
                                return undefined;
                            }
                        }
                        break;
                    case SyntaxKind.ArrowFunction:
                        // when targeting ES6 or higher there is no 'arguments' in an arrow function
                        // for lower compile targets the resolved symbol is used to emit an error
                        if (compilerOptions.target! >= ScriptTarget.ES2015) {
                            break;
                        }
                        // falls through
                    case SyntaxKind.MethodDeclaration:
                    case SyntaxKind.Constructor:
                    case SyntaxKind.GetAccessor:
                    case SyntaxKind.SetAccessor:
                    case SyntaxKind.FunctionDeclaration:
                        if (meaning & SymbolFlags.Variable
                            && name === 'arguments')
                        {
                            result = argumentsSymbol;
                            break loop;
                        }
                        break;
                    case SyntaxKind.FunctionExpression:
                        if (meaning & SymbolFlags.Variable
                            && name === 'arguments')
                        {
                            result = argumentsSymbol;
                            break loop;
                        }

                        if (meaning & SymbolFlags.Function) {
                            const functionName = (<FunctionExpression> location)
                                .name;
                            if (functionName
                                && name === functionName.escapedText)
                            {
                                result = location.symbol;
                                break loop;
                            }
                        }
                        break;
                    case SyntaxKind.Decorator:
                        // Decorators are resolved at the class declaration. Resolving at the parameter
                        // or member would result in looking up locals in the method.
                        //
                        //   function y() {}
                        //   class C {
                        //       method(@y x, y) {} // <-- decorator y should be resolved at the class declaration, not the parameter.
                        //   }
                        //
                        if (location.parent
                            && location.parent.kind === SyntaxKind.Parameter)
                        {
                            location = location.parent;
                        }
                        //
                        //   function y() {}
                        //   class C {
                        //       @y method(x, y) {} // <-- decorator y should be resolved at the class declaration, not the method.
                        //   }
                        //

                        // class Decorators are resolved outside of the class to avoid referencing type parameters of that class.
                        //
                        //   type T = number;
                        //   declare function y(x: T): any;
                        //   @param(1 as T) // <-- T should resolve to the type alias outside of class C
                        //   class C<T> {}
                        if (location.parent
                            && (isClassElement(location.parent)
                                || location.parent.kind
                                === SyntaxKind.ClassDeclaration))
                        {
                            location = location.parent;
                        }
                        break;
                    case SyntaxKind.JSDocTypedefTag:
                    case SyntaxKind.JSDocCallbackTag:
                    case SyntaxKind.JSDocEnumTag:
                        // js type aliases do not resolve names from their host, so skip past it
                        location = getJSDocHost(location);
                        break;
                    case SyntaxKind.Parameter:
                        if (lastLocation
                            && lastLocation
                            === (location as ParameterDeclaration).initializer)
                        {
                            associatedDeclarationForContainingInitializer = location as ParameterDeclaration;
                        }
                        break;
                    case SyntaxKind.BindingElement:
                        if (lastLocation
                            && lastLocation
                            === (location as BindingElement).initializer)
                        {
                            const root = getRootDeclaration(location);
                            if (root.kind === SyntaxKind.Parameter) {
                                associatedDeclarationForContainingInitializer = location as BindingElement;
                            }
                        }
                        break;
                }
                if (isSelfReferenceLocation(location)) {
                    lastSelfReferenceLocation = location;
                }
                lastLocation = location;
                location = location.parent;
            }

            // We just climbed up parents looking for the name, meaning that we started in a descendant node of `lastLocation`.
            // If `result === lastSelfReferenceLocation.symbol`, that means that we are somewhere inside `lastSelfReferenceLocation` looking up a name, and resolving to `lastLocation` itself.
            // That means that this is a self-reference of `lastLocation`, and shouldn't count this when considering whether `lastLocation` is used.
            if (isUse && result
                && (!lastSelfReferenceLocation
                    || result !== lastSelfReferenceLocation.symbol))
            {
                result.isReferenced! |= meaning;
            }

            if (!result) {
                if (lastLocation) {
                    Debug.assert(lastLocation.kind === SyntaxKind.SourceFile);
                    if ((lastLocation as SourceFile).commonJsModuleIndicator
                        && name === 'exports'
                        && meaning & lastLocation.symbol.flags)
                    {
                        return lastLocation.symbol;
                    }
                }

                if (!excludeGlobals) {
                    result = lookup(globals, name, meaning);
                }
            }
            if (!result) {
                if (originalLocation && isInJSFile(originalLocation)
                    && originalLocation.parent)
                {
                    if (isRequireCall(
                        originalLocation
                            .parent, /*checkArgumentIsStringLiteralLike*/
                        false
                    )) {
                        return requireSymbol;
                    }
                }
            }
            if (!result) {
                if (nameNotFoundMessage) {
                    if (!errorLocation
                        || !checkAndReportErrorForMissingPrefix(
                            errorLocation,
                            name,
                            nameArg!
                        ) // TODO: GH#18217
                        && !checkAndReportErrorForExtendingInterface(errorLocation)
                        && !checkAndReportErrorForUsingTypeAsNamespace(
                            errorLocation,
                            name,
                            meaning
                        )
                        && !checkAndReportErrorForUsingTypeAsValue(
                            errorLocation,
                            name,
                            meaning
                        )
                        && !checkAndReportErrorForUsingNamespaceModuleAsValue(
                            errorLocation,
                            name,
                            meaning
                        )
                        && !checkAndReportErrorForUsingValueAsType(
                            errorLocation,
                            name,
                            meaning
                        ))
                    {
                        let suggestion: Symbol | undefined;
                        if (suggestedNameNotFoundMessage
                            && suggestionCount < maximumSuggestionCount)
                        {
                            suggestion = getSuggestedSymbolForNonexistentSymbol(
                                originalLocation,
                                name,
                                meaning
                            );
                            if (suggestion) {
                                const suggestionName = symbolToString(suggestion);
                                const diagnostic = error(
                                    errorLocation,
                                    suggestedNameNotFoundMessage,
                                    diagnosticName(nameArg!),
                                    suggestionName
                                );
                                if (suggestion.valueDeclaration) {
                                    addRelatedInfo(
                                        diagnostic,
                                        createDiagnosticForNode(
                                            suggestion.valueDeclaration,
                                            Diagnostics._0_is_declared_here,
                                            suggestionName
                                        )
                                    );
                                }
                            }
                        }
                        if (!suggestion) {
                            error(
                                errorLocation,
                                nameNotFoundMessage,
                                diagnosticName(nameArg!)
                            );
                        }
                        suggestionCount++;
                    }
                }
                return undefined;
            }

            // Perform extra checks only if error reporting was requested
            if (nameNotFoundMessage) {
                if (propertyWithInvalidInitializer) {
                    // We have a match, but the reference occurred within a property initializer and the identifier also binds
                    // to a local variable in the constructor where the code will be emitted.
                    const propertyName = (<PropertyDeclaration> propertyWithInvalidInitializer)
                        .name;
                    error(
                        errorLocation,
                        Diagnostics
                            .Initializer_of_instance_member_variable_0_cannot_reference_identifier_1_declared_in_the_constructor,
                        declarationNameToString(propertyName),
                        diagnosticName(nameArg!)
                    );
                    return undefined;
                }

                // Only check for block-scoped variable if we have an error location and are looking for the
                // name with variable meaning
                //      For example,
                //          declare module foo {
                //              interface bar {}
                //          }
                //      const foo/*1*/: foo/*2*/.bar;
                // The foo at /*1*/ and /*2*/ will share same symbol with two meanings:
                // block-scoped variable and namespace module. However, only when we
                // try to resolve name in /*1*/ which is used in variable position,
                // we want to check for block-scoped
                if (errorLocation
                    && (meaning & SymbolFlags.BlockScopedVariable
                        || ((meaning & SymbolFlags.Class
                            || meaning & SymbolFlags.Enum)
                            && (meaning & SymbolFlags.Value)
                            === SymbolFlags.Value)))
                {
                    const exportOrLocalSymbol = getExportSymbolOfValueSymbolIfExported(result);
                    if (exportOrLocalSymbol.flags
                        & SymbolFlags.BlockScopedVariable
                        || exportOrLocalSymbol.flags & SymbolFlags.Class
                        || exportOrLocalSymbol.flags & SymbolFlags.Enum)
                    {
                        checkResolvedBlockScopedVariable(
                            exportOrLocalSymbol,
                            errorLocation
                        );
                    }
                }

                // If we're in an external module, we can't reference value symbols created from UMD export declarations
                if (result && isInExternalModule
                    && (meaning & SymbolFlags.Value) === SymbolFlags.Value
                    && !(originalLocation!.flags & NodeFlags.JSDoc))
                {
                    const merged = getMergedSymbol(result);
                    if (length(merged.declarations)
                        && every(
                            merged.declarations,
                            d => isNamespaceExportDeclaration(d)
                                || isSourceFile(d) && !!d.symbol.globalExports
                        ))
                    {
                        errorOrSuggestion(
                            !compilerOptions.allowUmdGlobalAccess,
                            errorLocation!,
                            Diagnostics
                                ._0_refers_to_a_UMD_global_but_the_current_file_is_a_module_Consider_adding_an_import_instead,
                            unescapeLeadingUnderscores(name)
                        );
                    }
                }

                // If we're in a parameter initializer, we can't reference the values of the parameter whose initializer we're within or parameters to the right
                if (result && associatedDeclarationForContainingInitializer
                    && !withinDeferredContext
                    && (meaning & SymbolFlags.Value) === SymbolFlags.Value)
                {
                    const candidate = getMergedSymbol(getLateBoundSymbol(result));
                    const root = (getRootDeclaration(associatedDeclarationForContainingInitializer) as ParameterDeclaration);
                    // A parameter initializer or binding pattern initializer within a parameter cannot refer to itself
                    if (candidate
                        === getSymbolOfNode(associatedDeclarationForContainingInitializer))
                    {
                        error(
                            errorLocation,
                            Diagnostics
                                .Parameter_0_cannot_be_referenced_in_its_initializer,
                            declarationNameToString(
                                associatedDeclarationForContainingInitializer
                                    .name
                            )
                        );
                    } // And it cannot refer to any declarations which come after it
                    else if (candidate.valueDeclaration
                        && candidate.valueDeclaration.pos
                        > associatedDeclarationForContainingInitializer.pos
                        && root.parent.locals
                        && lookup(
                            root.parent.locals,
                            candidate.escapedName,
                            meaning
                        ) === candidate)
                    {
                        error(
                            errorLocation,
                            Diagnostics
                                .Initializer_of_parameter_0_cannot_reference_identifier_1_declared_after_it,
                            declarationNameToString(
                                associatedDeclarationForContainingInitializer
                                    .name
                            ),
                            declarationNameToString(<Identifier> errorLocation)
                        );
                    }
                }
            }
            return result;
        }

        function getIsDeferredContext(
            location: Node,
            lastLocation: Node | undefined
        ): boolean {
            if (location.kind !== SyntaxKind.ArrowFunction
                && location.kind !== SyntaxKind.FunctionExpression)
            {
                // initializers in instance property declaration of class like entities are executed in constructor and thus deferred
                return isTypeQueryNode(location) || ((
                    isFunctionLikeDeclaration(location)
                    || (location.kind === SyntaxKind.PropertyDeclaration
                        && !hasModifier(location, ModifierFlags.Static))
                )
                    && (!lastLocation
                        || lastLocation
                        !== (location as FunctionLike | PropertyDeclaration)
                            .name)); // A name is evaluated within the enclosing scope - so it shouldn't count as deferred
            }
            if (lastLocation
                && lastLocation
                === (location as FunctionExpression | ArrowFunction).name)
            {
                return false;
            }
            // generator functions and async functions are not inlined in control flow when immediately invoked
            if ((location as FunctionExpression | ArrowFunction).asteriskToken
                || hasModifier(location, ModifierFlags.Async))
            {
                return true;
            }
            return !getImmediatelyInvokedFunctionExpression(location);
        }

        function isSelfReferenceLocation(node: Node): boolean {
            switch (node.kind) {
                case SyntaxKind.FunctionDeclaration:
                case SyntaxKind.ClassDeclaration:
                case SyntaxKind.InterfaceDeclaration:
                case SyntaxKind.EnumDeclaration:
                case SyntaxKind.TypeAliasDeclaration:
                case SyntaxKind.ModuleDeclaration: // For `namespace N { N; }`
                    return true;
                default:
                    return false;
            }
        }

        function diagnosticName(
            nameArg: __String | Identifier | PrivateIdentifier
        ) {
            return isString(nameArg)
                ? unescapeLeadingUnderscores(nameArg as __String)
                : declarationNameToString(nameArg as Identifier);
        }

        function isTypeParameterSymbolDeclaredInContainer(
            symbol: Symbol,
            container: Node
        ) {
            for (const decl of symbol.declarations) {
                if (decl.kind === SyntaxKind.TypeParameter) {
                    const parent = isJSDocTemplateTag(decl.parent)
                        ? getJSDocHost(decl.parent)
                        : decl.parent;
                    if (parent === container) {
                        return !(isJSDocTemplateTag(decl.parent)
                            && find(
                                (decl.parent.parent as JSDoc).tags!,
                                isJSDocTypeAlias
                            )); // TODO: GH#18217
                    }
                }
            }

            return false;
        }

        function checkAndReportErrorForMissingPrefix(
            errorLocation: Node,
            name: __String,
            nameArg: __String | Identifier
        ): boolean {
            if (!isIdentifier(errorLocation)
                || errorLocation.escapedText !== name
                || isTypeReferenceIdentifier(errorLocation)
                || isInTypeQuery(errorLocation))
            {
                return false;
            }

            const container = getThisContainer(
                errorLocation, /*includeArrowFunctions*/
                false
            );
            let location = container;
            while (location) {
                if (isClassLike(location.parent)) {
                    const classSymbol = getSymbolOfNode(location.parent);
                    if (!classSymbol) {
                        break;
                    }

                    // Check to see if a static member exists.
                    const constructorType = getTypeOfSymbol(classSymbol);
                    if (getPropertyOfType(constructorType, name)) {
                        error(
                            errorLocation,
                            Diagnostics
                                .Cannot_find_name_0_Did_you_mean_the_static_member_1_0,
                            diagnosticName(nameArg),
                            symbolToString(classSymbol)
                        );
                        return true;
                    }

                    // No static member is present.
                    // Check if we're in an instance method and look for a relevant instance member.
                    if (location === container
                        && !hasModifier(location, ModifierFlags.Static))
                    {
                        const instanceType = (<InterfaceType> getDeclaredTypeOfSymbol(classSymbol))
                            .thisType!; // TODO: GH#18217
                        if (getPropertyOfType(instanceType, name)) {
                            error(
                                errorLocation,
                                Diagnostics
                                    .Cannot_find_name_0_Did_you_mean_the_instance_member_this_0,
                                diagnosticName(nameArg)
                            );
                            return true;
                        }
                    }
                }

                location = location.parent;
            }
            return false;
        }

        function checkAndReportErrorForExtendingInterface(
            errorLocation: Node
        ): boolean {
            const expression = getEntityNameForExtendingInterface(errorLocation);
            if (expression
                && resolveEntityName(
                    expression,
                    SymbolFlags.Interface, /*ignoreErrors*/
                    true
                ))
            {
                error(
                    errorLocation,
                    Diagnostics
                        .Cannot_extend_an_interface_0_Did_you_mean_implements,
                    getTextOfNode(expression)
                );
                return true;
            }
            return false;
        }
        /**
         * Climbs up parents to an ExpressionWithTypeArguments, and returns its expression,
         * but returns undefined if that expression is not an EntityNameExpression.
         */
        function getEntityNameForExtendingInterface(
            node: Node
        ): EntityNameExpression | undefined {
            switch (node.kind) {
                case SyntaxKind.Identifier:
                case SyntaxKind.PropertyAccessExpression:
                    return node.parent
                        ? getEntityNameForExtendingInterface(node.parent)
                        : undefined;
                case SyntaxKind.ExpressionWithTypeArguments:
                    if (isEntityNameExpression(
                        (<ExpressionWithTypeArguments> node).expression
                    )) {
                        return <EntityNameExpression> (<ExpressionWithTypeArguments> node)
                            .expression;
                    }
                    // falls through
                default:
                    return undefined;
            }
        }

        function checkAndReportErrorForUsingTypeAsNamespace(
            errorLocation: Node,
            name: __String,
            meaning: SymbolFlags
        ): boolean {
            const namespaceMeaning = SymbolFlags.Namespace
                | (isInJSFile(errorLocation) ? SymbolFlags.Value : 0);
            if (meaning === namespaceMeaning) {
                const symbol = resolveSymbol(
                    resolveName(
                        errorLocation,
                        name,
                        SymbolFlags.Type
                            & ~namespaceMeaning, /*nameNotFoundMessage*/
                        undefined, /*nameArg*/
                        undefined, /*isUse*/
                        false
                    )
                );
                const parent = errorLocation.parent;
                if (symbol) {
                    if (isQualifiedName(parent)) {
                        Debug.assert(
                            parent.left === errorLocation,
                            'Should only be resolving left side of qualified name as a namespace'
                        );
                        const propName = parent.right.escapedText;
                        const propType = getPropertyOfType(
                            getDeclaredTypeOfSymbol(symbol),
                            propName
                        );
                        if (propType) {
                            error(
                                parent,
                                Diagnostics
                                    .Cannot_access_0_1_because_0_is_a_type_but_not_a_namespace_Did_you_mean_to_retrieve_the_type_of_the_property_1_in_0_with_0_1,
                                unescapeLeadingUnderscores(name),
                                unescapeLeadingUnderscores(propName)
                            );
                            return true;
                        }
                    }
                    error(
                        errorLocation,
                        Diagnostics
                            ._0_only_refers_to_a_type_but_is_being_used_as_a_namespace_here,
                        unescapeLeadingUnderscores(name)
                    );
                    return true;
                }
            }

            return false;
        }

        function checkAndReportErrorForUsingValueAsType(
            errorLocation: Node,
            name: __String,
            meaning: SymbolFlags
        ): boolean {
            if (meaning & (SymbolFlags.Type & ~SymbolFlags.Namespace)) {
                const symbol = resolveSymbol(
                    resolveName(
                        errorLocation,
                        name,
                        ~SymbolFlags.Type
                            & SymbolFlags.Value, /*nameNotFoundMessage*/
                        undefined, /*nameArg*/
                        undefined, /*isUse*/
                        false
                    )
                );
                if (symbol && !(symbol.flags & SymbolFlags.Namespace)) {
                    error(
                        errorLocation,
                        Diagnostics
                            ._0_refers_to_a_value_but_is_being_used_as_a_type_here,
                        unescapeLeadingUnderscores(name)
                    );
                    return true;
                }
            }
            return false;
        }

        function checkAndReportErrorForUsingTypeAsValue(
            errorLocation: Node,
            name: __String,
            meaning: SymbolFlags
        ): boolean {
            if (meaning & (SymbolFlags.Value & ~SymbolFlags.NamespaceModule)) {
                if (name === 'any' || name === 'string' || name === 'number'
                    || name === 'boolean' || name === 'never')
                {
                    error(
                        errorLocation,
                        Diagnostics
                            ._0_only_refers_to_a_type_but_is_being_used_as_a_value_here,
                        unescapeLeadingUnderscores(name)
                    );
                    return true;
                }
                const symbol = resolveSymbol(
                    resolveName(
                        errorLocation,
                        name,
                        SymbolFlags.Type
                            & ~SymbolFlags.Value, /*nameNotFoundMessage*/
                        undefined, /*nameArg*/
                        undefined, /*isUse*/
                        false
                    )
                );
                if (symbol && !(symbol.flags & SymbolFlags.NamespaceModule)) {
                    const message = isES2015OrLaterConstructorName(name)
                        ? Diagnostics
                            ._0_only_refers_to_a_type_but_is_being_used_as_a_value_here_Do_you_need_to_change_your_target_library_Try_changing_the_lib_compiler_option_to_es2015_or_later
                        : Diagnostics
                            ._0_only_refers_to_a_type_but_is_being_used_as_a_value_here;
                    error(
                        errorLocation,
                        message,
                        unescapeLeadingUnderscores(name)
                    );
                    return true;
                }
            }
            return false;
        }

        function isES2015OrLaterConstructorName(n: __String) {
            switch (n) {
                case 'Promise':
                case 'Symbol':
                case 'Map':
                case 'WeakMap':
                case 'Set':
                case 'WeakSet':
                    return true;
            }
            return false;
        }

        function checkAndReportErrorForUsingNamespaceModuleAsValue(
            errorLocation: Node,
            name: __String,
            meaning: SymbolFlags
        ): boolean {
            if (meaning
                & (SymbolFlags.Value & ~SymbolFlags.NamespaceModule
                    & ~SymbolFlags.Type))
            {
                const symbol = resolveSymbol(
                    resolveName(
                        errorLocation,
                        name,
                        SymbolFlags.NamespaceModule
                            & ~SymbolFlags.Value, /*nameNotFoundMessage*/
                        undefined, /*nameArg*/
                        undefined, /*isUse*/
                        false
                    )
                );
                if (symbol) {
                    error(
                        errorLocation,
                        isTypeOnlyEnumAlias(symbol)
                            ? Diagnostics
                                .Enum_0_cannot_be_used_as_a_value_because_only_its_type_has_been_imported
                            : Diagnostics.Cannot_use_namespace_0_as_a_value,
                        unescapeLeadingUnderscores(name)
                    );
                    return true;
                }
            } else if (meaning
                & (SymbolFlags.Type & ~SymbolFlags.NamespaceModule
                    & ~SymbolFlags.Value))
            {
                const symbol = resolveSymbol(
                    resolveName(
                        errorLocation,
                        name,
                        (SymbolFlags.ValueModule | SymbolFlags.NamespaceModule)
                            & ~SymbolFlags.Type, /*nameNotFoundMessage*/
                        undefined, /*nameArg*/
                        undefined, /*isUse*/
                        false
                    )
                );
                if (symbol) {
                    error(
                        errorLocation,
                        Diagnostics.Cannot_use_namespace_0_as_a_type,
                        unescapeLeadingUnderscores(name)
                    );
                    return true;
                }
            }
            return false;
        }

        function checkResolvedBlockScopedVariable(
            result: Symbol,
            errorLocation: Node
        ): void {
            Debug
                .assert(
                    !!(result.flags & SymbolFlags.BlockScopedVariable
                        || result.flags & SymbolFlags.Class
                        || result.flags & SymbolFlags.Enum)
                );
            if (result.flags
                & (SymbolFlags.Function | SymbolFlags.FunctionScopedVariable
                    | SymbolFlags.Assignment)
                && result.flags & SymbolFlags.Class)
            {
                // constructor functions aren't block scoped
                return;
            }
            // Block-scoped variables cannot be used before their definition
            const declaration = find(
                result.declarations,
                d => isBlockOrCatchScoped(d) || isClassLike(d)
                    || (d.kind === SyntaxKind.EnumDeclaration)
            );

            if (declaration === undefined) {
                return Debug
                    .fail('checkResolvedBlockScopedVariable could not find block-scoped declaration');
            }

            if (!(declaration.flags & NodeFlags.Ambient)
                && !isBlockScopedNameDeclaredBeforeUse(
                    declaration,
                    errorLocation
                ))
            {
                let diagnosticMessage;
                const declarationName = declarationNameToString(getNameOfDeclaration(declaration));
                if (result.flags & SymbolFlags.BlockScopedVariable) {
                    diagnosticMessage = error(
                        errorLocation,
                        Diagnostics
                            .Block_scoped_variable_0_used_before_its_declaration,
                        declarationName
                    );
                } else if (result.flags & SymbolFlags.Class) {
                    diagnosticMessage = error(
                        errorLocation,
                        Diagnostics.Class_0_used_before_its_declaration,
                        declarationName
                    );
                } else if (result.flags & SymbolFlags.RegularEnum) {
                    diagnosticMessage = error(
                        errorLocation,
                        Diagnostics.Enum_0_used_before_its_declaration,
                        declarationName
                    );
                } else {
                    Debug.assert(!!(result.flags & SymbolFlags.ConstEnum));
                    if (compilerOptions.preserveConstEnums) {
                        diagnosticMessage = error(
                            errorLocation,
                            Diagnostics.Class_0_used_before_its_declaration,
                            declarationName
                        );
                    }
                }

                if (diagnosticMessage) {
                    addRelatedInfo(
                        diagnosticMessage,
                        createDiagnosticForNode(
                            declaration,
                            Diagnostics._0_is_declared_here,
                            declarationName
                        )
                    );
                }
            }
        }

        /* Starting from 'initial' node walk up the parent chain until 'stopAt' node is reached.
         * If at any point current node is equal to 'parent' node - return true.
         * Return false if 'stopAt' node is reached or isFunctionLike(current) === true.
         */
        function isSameScopeDescendentOf(
            initial: Node,
            parent: Node | undefined,
            stopAt: Node
        ): boolean {
            return !!parent
                && !!findAncestor(
                    initial,
                    n => n === stopAt || isFunctionLike(n)
                        ? 'quit'
                        : n === parent
                );
        }

        function getAnyImportSyntax(node: Node): AnyImportSyntax | undefined {
            switch (node.kind) {
                case SyntaxKind.ImportEqualsDeclaration:
                    return node as ImportEqualsDeclaration;
                case SyntaxKind.ImportClause:
                    return (node as ImportClause).parent;
                case SyntaxKind.NamespaceImport:
                    return (node as NamespaceImport).parent.parent;
                case SyntaxKind.ImportSpecifier:
                    return (node as ImportSpecifier).parent.parent.parent;
                default:
                    return undefined;
            }
        }

        function getDeclarationOfAliasSymbol(
            symbol: Symbol
        ): Declaration | undefined {
            return find<Declaration>(
                symbol.declarations,
                isAliasSymbolDeclaration
            );
        }

        function getTargetOfImportEqualsDeclaration(
            node: ImportEqualsDeclaration,
            dontResolveAlias: boolean
        ): Symbol | undefined {
            if (node.moduleReference.kind
                === SyntaxKind.ExternalModuleReference)
            {
                return resolveExternalModuleSymbol(
                    resolveExternalModuleName(
                        node,
                        getExternalModuleImportEqualsDeclarationExpression(node)
                    )
                );
            }
            return getSymbolOfPartOfRightHandSideOfImportEquals(
                node.moduleReference,
                dontResolveAlias
            );
        }

        function resolveExportByName(
            moduleSymbol: Symbol,
            name: __String,
            dontResolveAlias: boolean
        ) {
            const exportValue = moduleSymbol.exports!
                .get(InternalSymbolName.ExportEquals);
            return exportValue
                ? getPropertyOfType(getTypeOfSymbol(exportValue), name)
                : resolveSymbol(
                    moduleSymbol.exports!.get(name),
                    dontResolveAlias
                );
        }

        function isSyntacticDefault(node: Node) {
            return ((isExportAssignment(node) && !node.isExportEquals)
                || hasModifier(node, ModifierFlags.Default)
                || isExportSpecifier(node));
        }

        function canHaveSyntheticDefault(
            file: SourceFile | undefined,
            moduleSymbol: Symbol,
            dontResolveAlias: boolean
        ) {
            if (!allowSyntheticDefaultImports) {
                return false;
            }
            // Declaration files (and ambient modules)
            if (!file || file.isDeclarationFile) {
                // Definitely cannot have a synthetic default if they have a syntactic default member specified
                const defaultExportSymbol = resolveExportByName(
                    moduleSymbol,
                    InternalSymbolName.Default, /*dontResolveAlias*/
                    true
                ); // Dont resolve alias because we want the immediately exported symbol's declaration
                if (defaultExportSymbol
                    && some(
                        defaultExportSymbol.declarations,
                        isSyntacticDefault
                    ))
                {
                    return false;
                }
                // It _might_ still be incorrect to assume there is no __esModule marker on the import at runtime, even if there is no `default` member
                // So we check a bit more,
                if (resolveExportByName(
                    moduleSymbol,
                    escapeLeadingUnderscores('__esModule'),
                    dontResolveAlias
                )) {
                    // If there is an `__esModule` specified in the declaration (meaning someone explicitly added it or wrote it in their code),
                    // it definitely is a module and does not have a synthetic default
                    return false;
                }
                // There are _many_ declaration files not written with esmodules in mind that still get compiled into a format with __esModule set
                // Meaning there may be no default at runtime - however to be on the permissive side, we allow access to a synthetic default member
                // as there is no marker to indicate if the accompanying JS has `__esModule` or not, or is even native esm
                return true;
            }
            // TypeScript files never have a synthetic default (as they are always emitted with an __esModule marker) _unless_ they contain an export= statement
            if (!isSourceFileJS(file)) {
                return hasExportAssignmentSymbol(moduleSymbol);
            }
            // JS files have a synthetic default if they do not contain ES2015+ module syntax (export = is not valid in js) _and_ do not have an __esModule marker
            return !file.externalModuleIndicator
                && !resolveExportByName(
                    moduleSymbol,
                    escapeLeadingUnderscores('__esModule'),
                    dontResolveAlias
                );
        }

        function getTargetOfImportClause(
            node: ImportClause,
            dontResolveAlias: boolean
        ): Symbol | undefined {
            const moduleSymbol = resolveExternalModuleName(
                node,
                node.parent.moduleSpecifier
            );

            if (moduleSymbol) {
                let exportDefaultSymbol: Symbol | undefined;
                if (isShorthandAmbientModuleSymbol(moduleSymbol)) {
                    exportDefaultSymbol = moduleSymbol;
                } else {
                    exportDefaultSymbol = resolveExportByName(
                        moduleSymbol,
                        InternalSymbolName.Default,
                        dontResolveAlias
                    );
                }

                const file = find(moduleSymbol.declarations, isSourceFile);
                const hasSyntheticDefault = canHaveSyntheticDefault(
                    file,
                    moduleSymbol,
                    dontResolveAlias
                );
                if (!exportDefaultSymbol && !hasSyntheticDefault) {
                    if (hasExportAssignmentSymbol(moduleSymbol)) {
                        const compilerOptionName = moduleKind
                            >= ModuleKind.ES2015
                            ? 'allowSyntheticDefaultImports'
                            : 'esModuleInterop';
                        const exportEqualsSymbol = moduleSymbol.exports!
                            .get(InternalSymbolName.ExportEquals);
                        const exportAssignment = exportEqualsSymbol!
                            .valueDeclaration;
                        const err = error(
                            node.name,
                            Diagnostics
                                .Module_0_can_only_be_default_imported_using_the_1_flag,
                            symbolToString(moduleSymbol),
                            compilerOptionName
                        );

                        addRelatedInfo(
                            err,
                            createDiagnosticForNode(
                                exportAssignment,
                                Diagnostics
                                    .This_module_is_declared_with_using_export_and_can_only_be_used_with_a_default_import_when_using_the_0_flag,
                                compilerOptionName
                            )
                        );
                    } else {
                        if (moduleSymbol.exports
                            && moduleSymbol.exports
                                .has(node.symbol.escapedName))
                        {
                            error(
                                node.name,
                                Diagnostics
                                    .Module_0_has_no_default_export_Did_you_mean_to_use_import_1_from_0_instead,
                                symbolToString(moduleSymbol),
                                symbolToString(node.symbol)
                            );
                        } else {
                            error(
                                node.name,
                                Diagnostics.Module_0_has_no_default_export,
                                symbolToString(moduleSymbol)
                            );
                        }
                    }
                } else if (hasSyntheticDefault) {
                    // per emit behavior, a synthetic default overrides a "real" .default member if `__esModule` is not present
                    return maybeTypeOnly(
                        resolveExternalModuleSymbol(
                            moduleSymbol,
                            dontResolveAlias
                        )
                            || resolveSymbol(moduleSymbol, dontResolveAlias)
                    );
                }
                return maybeTypeOnly(exportDefaultSymbol);
            }

            function maybeTypeOnly(symbol: Symbol | undefined) {
                if (symbol && node.isTypeOnly && node.name) {
                    return createTypeOnlyImportOrExport(node.name, symbol);
                }
                return symbol;
            }
        }

        function getTargetOfNamespaceImport(
            node: NamespaceImport,
            dontResolveAlias: boolean
        ): Symbol | undefined {
            const moduleSpecifier = node.parent.parent.moduleSpecifier;
            const moduleSymbol = resolveESModuleSymbol(
                resolveExternalModuleName(
                    node,
                    moduleSpecifier
                ),
                moduleSpecifier,
                dontResolveAlias, /*suppressUsageError*/
                false
            );
            return moduleSymbol && node.parent.isTypeOnly
                ? createTypeOnlySymbol(moduleSymbol)
                : moduleSymbol;
        }

        function getTargetOfNamespaceExport(
            node: NamespaceExport,
            dontResolveAlias: boolean
        ): Symbol | undefined {
            const moduleSpecifier = node.parent.moduleSpecifier;
            return moduleSpecifier
                && resolveESModuleSymbol(
                    resolveExternalModuleName(
                        node,
                        moduleSpecifier
                    ),
                    moduleSpecifier,
                    dontResolveAlias, /*suppressUsageError*/
                    false
                );
        }

        // This function creates a synthetic symbol that combines the value side of one symbol with the
        // type/namespace side of another symbol. Consider this example:
        //
        //   declare module graphics {
        //       interface Point {
        //           x: number;
        //           y: number;
        //       }
        //   }
        //   declare var graphics: {
        //       Point: new (x: number, y: number) => graphics.Point;
        //   }
        //   declare module "graphics" {
        //       export = graphics;
        //   }
        //
        // An 'import { Point } from "graphics"' needs to create a symbol that combines the value side 'Point'
        // property with the type/namespace side interface 'Point'.
        function combineValueAndTypeSymbols(
            valueSymbol: Symbol,
            typeSymbol: Symbol
        ): Symbol {
            if (valueSymbol === unknownSymbol
                && typeSymbol === unknownSymbol)
            {
                return unknownSymbol;
            }
            if (valueSymbol.flags
                & (SymbolFlags.Type | SymbolFlags.Namespace))
            {
                return valueSymbol;
            }
            const result = createSymbol(
                valueSymbol.flags | typeSymbol.flags,
                valueSymbol.escapedName
            );
            result
                .declarations = deduplicate(
                    concatenate(
                        valueSymbol.declarations,
                        typeSymbol.declarations
                    ),
                    equateValues
                );
            result.parent = valueSymbol.parent || typeSymbol.parent;
            if (valueSymbol.valueDeclaration) {
                result.valueDeclaration = valueSymbol.valueDeclaration;
            }
            if (typeSymbol.members) result.members = typeSymbol.members;
            if (valueSymbol.exports) result.exports = valueSymbol.exports;
            return result;
        }

        function getExportOfModule(
            symbol: Symbol,
            name: __String,
            dontResolveAlias: boolean
        ): Symbol | undefined {
            if (symbol.flags & SymbolFlags.Module) {
                return resolveSymbol(
                    getExportsOfSymbol(symbol).get(name)!,
                    dontResolveAlias
                );
            }
        }

        function getPropertyOfVariable(
            symbol: Symbol,
            name: __String
        ): Symbol | undefined {
            if (symbol.flags & SymbolFlags.Variable) {
                const typeAnnotation = (<VariableDeclaration> symbol
                    .valueDeclaration).type;
                if (typeAnnotation) {
                    return resolveSymbol(
                        getPropertyOfType(
                            getTypeFromTypeNode(typeAnnotation),
                            name
                        )
                    );
                }
            }
        }

        function getExternalModuleMember(
            node: ImportDeclaration | ExportDeclaration,
            specifier: ImportOrExportSpecifier,
            dontResolveAlias = false
        ): Symbol | undefined {
            const moduleSymbol = resolveExternalModuleName(
                node,
                node.moduleSpecifier!
            )!; // TODO: GH#18217
            const name = specifier.propertyName || specifier.name;
            const suppressInteropError = name.escapedText
                === InternalSymbolName.Default
                && !!(compilerOptions.allowSyntheticDefaultImports
                    || compilerOptions.esModuleInterop);
            const targetSymbol = resolveESModuleSymbol(
                moduleSymbol,
                node.moduleSpecifier!,
                dontResolveAlias,
                suppressInteropError
            );
            if (targetSymbol) {
                if (name.escapedText) {
                    if (isShorthandAmbientModuleSymbol(moduleSymbol)) {
                        return moduleSymbol;
                    }

                    let symbolFromVariable: Symbol | undefined;
                    // First check if module was specified with "export=". If so, get the member from the resolved type
                    if (moduleSymbol && moduleSymbol.exports
                        && moduleSymbol.exports
                            .get(InternalSymbolName.ExportEquals))
                    {
                        symbolFromVariable = getPropertyOfType(
                            getTypeOfSymbol(targetSymbol),
                            name.escapedText
                        );
                    } else {
                        symbolFromVariable = getPropertyOfVariable(
                            targetSymbol,
                            name.escapedText
                        );
                    }
                    // if symbolFromVariable is export - get its final target
                    symbolFromVariable = resolveSymbol(
                        symbolFromVariable,
                        dontResolveAlias
                    );
                    let symbolFromModule = getExportOfModule(
                        targetSymbol,
                        name.escapedText,
                        dontResolveAlias
                    );
                    // If the export member we're looking for is default, and there is no real default but allowSyntheticDefaultImports is on, return the entire module as the default
                    if (!symbolFromModule && allowSyntheticDefaultImports
                        && name.escapedText === InternalSymbolName.Default)
                    {
                        symbolFromModule = resolveExternalModuleSymbol(
                            moduleSymbol,
                            dontResolveAlias
                        ) || resolveSymbol(moduleSymbol, dontResolveAlias);
                    }
                    const symbol = symbolFromModule && symbolFromVariable
                        && symbolFromModule !== symbolFromVariable
                        ? combineValueAndTypeSymbols(
                            symbolFromVariable,
                            symbolFromModule
                        )
                        : symbolFromModule || symbolFromVariable;
                    if (!symbol) {
                        const moduleName = getFullyQualifiedName(
                            moduleSymbol,
                            node
                        );
                        const declarationName = declarationNameToString(name);
                        const suggestion = getSuggestedSymbolForNonexistentModule(
                            name,
                            targetSymbol
                        );
                        if (suggestion !== undefined) {
                            const suggestionName = symbolToString(suggestion);
                            const diagnostic = error(
                                name,
                                Diagnostics
                                    .Module_0_has_no_exported_member_1_Did_you_mean_2,
                                moduleName,
                                declarationName,
                                suggestionName
                            );
                            if (suggestion.valueDeclaration) {
                                addRelatedInfo(
                                    diagnostic,
                                    createDiagnosticForNode(
                                        suggestion.valueDeclaration,
                                        Diagnostics._0_is_declared_here,
                                        suggestionName
                                    )
                                );
                            }
                        } else {
                            if (moduleSymbol.exports
                                && moduleSymbol.exports
                                    .has(InternalSymbolName.Default))
                            {
                                error(
                                    name,
                                    Diagnostics
                                        .Module_0_has_no_exported_member_1_Did_you_mean_to_use_import_1_from_0_instead,
                                    moduleName,
                                    declarationName
                                );
                            } else {
                                error(
                                    name,
                                    Diagnostics
                                        .Module_0_has_no_exported_member_1,
                                    moduleName,
                                    declarationName
                                );
                            }
                        }
                    }
                    return symbol;
                }
            }
        }

        function getTargetOfImportSpecifier(
            node: ImportSpecifier,
            dontResolveAlias: boolean
        ): Symbol | undefined {
            const resolved = getExternalModuleMember(
                node.parent.parent.parent,
                node,
                dontResolveAlias
            );
            if (resolved && node.parent.parent.isTypeOnly) {
                return createTypeOnlyImportOrExport(node.name, resolved);
            }
            return resolved;
        }

        function getTargetOfNamespaceExportDeclaration(
            node: NamespaceExportDeclaration,
            dontResolveAlias: boolean
        ): Symbol {
            return resolveExternalModuleSymbol(
                node.parent.symbol,
                dontResolveAlias
            );
        }

        /**
         * Creates a type alias symbol with a target symbol for type-only imports and exports.
         * The symbol for `A` in `export type { A }` or `export type { A } from "./mod"` has
         * `TypeFlags.Alias` so that alias resolution works as usual, but once the target `A`
         * has been resolved, we essentially want to pretend we have a type alias to that target.
         */
        function createTypeOnlyImportOrExport(
            sourceNode: ExportSpecifier | Identifier,
            target: Symbol
        ) {
            const symbol = createTypeOnlySymbol(target);
            if (!symbol && target !== unknownSymbol) {
                const identifier = isExportSpecifier(sourceNode)
                    ? sourceNode.name
                    : sourceNode;
                const nameText = idText(identifier);
                const diagnostic = error(
                    identifier,
                    Diagnostics
                        .Type_only_0_must_reference_a_type_but_1_is_a_value,
                    isExportSpecifier(sourceNode) ? 'export' : 'import',
                    nameText
                );
                const targetDeclaration = target.valueDeclaration
                    ?? target.declarations?.[0];
                if (targetDeclaration) {
                    addRelatedInfo(
                        diagnostic,
                        createDiagnosticForNode(
                            targetDeclaration,
                            Diagnostics._0_is_declared_here,
                            nameText
                        )
                    );
                }
            }

            return symbol;
        }

        function createTypeOnlySymbol(target: Symbol): Symbol | undefined {
            if (target.flags & SymbolFlags.ValueModule) {
                return createNamespaceModuleForModule(target);
            }
            if (target.flags & SymbolFlags.Enum) {
                return createNamespaceModuleForEnum(target);
            }
            if (!(target.flags & SymbolFlags.Value)) {
                return target;
            }
            if (target.flags & SymbolFlags.Type) {
                const alias = createSymbol(
                    SymbolFlags.TypeAlias,
                    target.escapedName
                );
                alias.declarations = emptyArray;
                alias.immediateTarget = target;
                return alias;
            }
        }

        function createNamespaceModuleForEnum(enumSymbol: Symbol) {
            Debug.assert(!!(enumSymbol.flags & SymbolFlags.Enum));
            const symbol = createSymbol(
                SymbolFlags.NamespaceModule | SymbolFlags.TypeAlias,
                enumSymbol.escapedName
            );
            symbol.immediateTarget = enumSymbol;
            symbol.declarations = enumSymbol.declarations;
            if (enumSymbol.exports) {
                symbol.exports = createSymbolTable();
                enumSymbol.exports.forEach((exportSymbol, key) => {
                    symbol.exports!.set(
                        key,
                        Debug.assertDefined(createTypeOnlySymbol(exportSymbol))
                    );
                });
            }
            return symbol;
        }

        function createNamespaceModuleForModule(moduleSymbol: Symbol) {
            Debug.assert(!!(moduleSymbol.flags & SymbolFlags.ValueModule));
            const filtered = createSymbol(
                SymbolFlags.NamespaceModule,
                moduleSymbol.escapedName
            );
            filtered.declarations = moduleSymbol.declarations;
            if (moduleSymbol.exports) {
                filtered.exports = createSymbolTable();
                moduleSymbol.exports.forEach((exportSymbol, key) => {
                    const typeOnlyExport = createTypeOnlySymbol(exportSymbol);
                    if (typeOnlyExport) {
                        filtered.exports!.set(key, typeOnlyExport);
                    }
                });
            }
            return filtered;
        }

        function getTargetOfExportSpecifier(
            node: ExportSpecifier,
            meaning: SymbolFlags,
            dontResolveAlias?: boolean
        ) {
            const target = node.parent.parent.moduleSpecifier
                ? getExternalModuleMember(
                    node.parent.parent,
                    node,
                    dontResolveAlias
                )
                : resolveEntityName(
                    node.propertyName || node.name,
                    meaning, /*ignoreErrors*/
                    false,
                    dontResolveAlias
                );
            return target && node.parent.parent.isTypeOnly
                ? createTypeOnlyImportOrExport(node, target)
                : target;
        }

        function getTargetOfExportAssignment(
            node: ExportAssignment | BinaryExpression,
            dontResolveAlias: boolean
        ): Symbol | undefined {
            const expression = (isExportAssignment(node)
                ? node.expression
                : node.right) as EntityNameExpression | ClassExpression;
            return getTargetOfAliasLikeExpression(expression,
                dontResolveAlias);
        }

        function getTargetOfAliasLikeExpression(
            expression: Expression,
            dontResolveAlias: boolean
        ) {
            if (isClassExpression(expression)) {
                return checkExpressionCached(expression).symbol;
            }
            if (!isEntityName(expression)
                && !isEntityNameExpression(expression))
            {
                return undefined;
            }
            const aliasLike = resolveEntityName(
                expression,
                SymbolFlags.Value | SymbolFlags.Type
                    | SymbolFlags.Namespace, /*ignoreErrors*/
                true,
                dontResolveAlias
            );
            if (aliasLike) {
                return aliasLike;
            }
            checkExpressionCached(expression);
            return getNodeLinks(expression).resolvedSymbol;
        }

        function getTargetOfPropertyAssignment(
            node: PropertyAssignment,
            dontRecursivelyResolve: boolean
        ): Symbol | undefined {
            const expression = node.initializer;
            return getTargetOfAliasLikeExpression(
                expression,
                dontRecursivelyResolve
            );
        }

        function getTargetOfPropertyAccessExpression(
            node: PropertyAccessExpression,
            dontRecursivelyResolve: boolean
        ): Symbol | undefined {
            if (!(isBinaryExpression(node.parent) && node.parent.left === node
                && node.parent.operatorToken.kind === SyntaxKind.EqualsToken))
            {
                return undefined;
            }

            return getTargetOfAliasLikeExpression(
                node.parent.right,
                dontRecursivelyResolve
            );
        }

        function getTargetOfAliasDeclaration(
            node: Declaration,
            dontRecursivelyResolve = false
        ): Symbol | undefined {
            switch (node.kind) {
                case SyntaxKind.ImportEqualsDeclaration:
                    return getTargetOfImportEqualsDeclaration(
                        <ImportEqualsDeclaration> node,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.ImportClause:
                    return getTargetOfImportClause(
                        <ImportClause> node,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.NamespaceImport:
                    return getTargetOfNamespaceImport(
                        <NamespaceImport> node,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.NamespaceExport:
                    return getTargetOfNamespaceExport(
                        <NamespaceExport> node,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.ImportSpecifier:
                    return getTargetOfImportSpecifier(
                        <ImportSpecifier> node,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.ExportSpecifier:
                    return getTargetOfExportSpecifier(
                        <ExportSpecifier> node,
                        SymbolFlags.Value | SymbolFlags.Type
                            | SymbolFlags.Namespace,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.ExportAssignment:
                case SyntaxKind.BinaryExpression:
                    return getTargetOfExportAssignment(
                        (<ExportAssignment | BinaryExpression> node),
                        dontRecursivelyResolve
                    );
                case SyntaxKind.NamespaceExportDeclaration:
                    return getTargetOfNamespaceExportDeclaration(
                        <NamespaceExportDeclaration> node,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.ShorthandPropertyAssignment:
                    return resolveEntityName(
                        (node as ShorthandPropertyAssignment).name,
                        SymbolFlags.Value | SymbolFlags.Type
                            | SymbolFlags.Namespace, /*ignoreErrors*/
                        true,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.PropertyAssignment:
                    return getTargetOfPropertyAssignment(
                        node as PropertyAssignment,
                        dontRecursivelyResolve
                    );
                case SyntaxKind.PropertyAccessExpression:
                    return getTargetOfPropertyAccessExpression(
                        node as PropertyAccessExpression,
                        dontRecursivelyResolve
                    );
                default:
                    return Debug.fail();
            }
        }

        /**
         * Indicates that a symbol is an alias that does not merge with a local declaration.
         * OR Is a JSContainer which may merge an alias with a local declaration
         */
        function isNonLocalAlias(
            symbol: Symbol | undefined,
            excludes
                = SymbolFlags.Value | SymbolFlags.Type | SymbolFlags.Namespace
        ): symbol is Symbol {
            if (!symbol) return false;
            return (symbol.flags & (SymbolFlags.Alias | excludes))
                === SymbolFlags.Alias
                || !!(symbol.flags & SymbolFlags.Alias
                    && symbol.flags & SymbolFlags.Assignment);
        }

        function resolveSymbol(
            symbol: Symbol,
            dontResolveAlias?: boolean
        ): Symbol;
        function resolveSymbol(
            symbol: Symbol | undefined,
            dontResolveAlias?: boolean
        ): Symbol | undefined;
        function resolveSymbol(
            symbol: Symbol | undefined,
            dontResolveAlias?: boolean
        ): Symbol | undefined {
            return !dontResolveAlias && isNonLocalAlias(symbol)
                ? resolveAlias(symbol)
                : symbol;
        }

        function resolveAlias(symbol: Symbol): Symbol {
            Debug.assert(
                (symbol.flags & SymbolFlags.Alias) !== 0,
                'Should only get Alias here.'
            );
            const links = getSymbolLinks(symbol);
            if (!links.target) {
                links.target = resolvingSymbol;
                const node = getDeclarationOfAliasSymbol(symbol);
                if (!node) return Debug.fail();
                const target = getTargetOfAliasDeclaration(node);
                if (links.target === resolvingSymbol) {
                    links.target = target || unknownSymbol;
                } else {
                    error(
                        node,
                        Diagnostics.Circular_definition_of_import_alias_0,
                        symbolToString(symbol)
                    );
                }
            } else if (links.target === resolvingSymbol) {
                links.target = unknownSymbol;
            }
            return links.target;
        }

        function markExportAsReferenced(
            node: ImportEqualsDeclaration | ExportSpecifier
        ) {
            const symbol = getSymbolOfNode(node);
            const target = resolveAlias(symbol);
            if (target) {
                const markAlias = target === unknownSymbol
                    || ((target.flags & SymbolFlags.Value)
                        && !isConstEnumOrConstEnumOnlyModule(target));

                if (markAlias) {
                    markAliasSymbolAsReferenced(symbol);
                }
            }
        }

        // When an alias symbol is referenced, we need to mark the entity it references as referenced and in turn repeat that until
        // we reach a non-alias or an exported entity (which is always considered referenced). We do this by checking the target of
        // the alias as an expression (which recursively takes us back here if the target references another alias).
        function markAliasSymbolAsReferenced(symbol: Symbol) {
            const links = getSymbolLinks(symbol);
            if (!links.referenced) {
                links.referenced = true;
                const node = getDeclarationOfAliasSymbol(symbol);
                if (!node) return Debug.fail();
                // We defer checking of the reference of an `import =` until the import itself is referenced,
                // This way a chain of imports can be elided if ultimately the final input is only used in a type
                // position.
                if (isInternalModuleImportEqualsDeclaration(node)) {
                    const target = resolveSymbol(symbol);
                    if (target === unknownSymbol
                        || target.flags & SymbolFlags.Value)
                    {
                        // import foo = <symbol>
                        checkExpressionCached(
                            <Expression> node.moduleReference
                        );
                    }
                }
            }
        }

        // This function is only for imports with entity names
        function getSymbolOfPartOfRightHandSideOfImportEquals(
            entityName: EntityName,
            dontResolveAlias?: boolean
        ): Symbol | undefined {
            // There are three things we might try to look for. In the following examples,
            // the search term is enclosed in |...|:
            //
            //     import a = |b|; // Namespace
            //     import a = |b.c|; // Value, type, namespace
            //     import a = |b.c|.d; // Namespace
            if (entityName.kind === SyntaxKind.Identifier
                && isRightSideOfQualifiedNameOrPropertyAccess(entityName))
            {
                entityName = <QualifiedName> entityName.parent;
            }
            // Check for case 1 and 3 in the above example
            if (entityName.kind === SyntaxKind.Identifier
                || entityName.parent.kind === SyntaxKind.QualifiedName)
            {
                return resolveEntityName(
                    entityName,
                    SymbolFlags.Namespace, /*ignoreErrors*/
                    false,
                    dontResolveAlias
                );
            } else {
                // Case 2 in above example
                // entityName.kind could be a QualifiedName or a Missing identifier
                Debug
                    .assert(
                        entityName.parent.kind
                            === SyntaxKind.ImportEqualsDeclaration
                    );
                return resolveEntityName(
                    entityName,
                    SymbolFlags.Value | SymbolFlags.Type
                        | SymbolFlags.Namespace, /*ignoreErrors*/
                    false,
                    dontResolveAlias
                );
            }
        }

        function getFullyQualifiedName(
            symbol: Symbol,
            containingLocation?: Node
        ): string {
            return symbol.parent
                ? getFullyQualifiedName(symbol.parent, containingLocation)
                    + '.' + symbolToString(symbol)
                : symbolToString(
                    symbol,
                    containingLocation, /*meaning*/
                    undefined,
                    SymbolFormatFlags.DoNotIncludeSymbolChain
                        | SymbolFormatFlags.AllowAnyNodeKind
                );
        }

        /**
         * Resolves a qualified name and any involved aliases.
         */
        function resolveEntityName(
            name: EntityNameOrEntityNameExpression,
            meaning: SymbolFlags,
            ignoreErrors?: boolean,
            dontResolveAlias?: boolean,
            location?: Node
        ): Symbol | undefined {
            if (nodeIsMissing(name)) {
                return undefined;
            }

            const namespaceMeaning = SymbolFlags.Namespace
                | (isInJSFile(name) ? meaning & SymbolFlags.Value : 0);
            let symbol: Symbol | undefined;
            if (name.kind === SyntaxKind.Identifier) {
                const message = meaning === namespaceMeaning
                    ? Diagnostics.Cannot_find_namespace_0
                    : getCannotFindNameDiagnosticForName(getFirstIdentifier(name));
                const symbolFromJSPrototype = isInJSFile(name)
                    ? resolveEntityNameFromAssignmentDeclaration(name, meaning)
                    : undefined;
                symbol = resolveName(
                    location || name,
                    name.escapedText,
                    meaning,
                    ignoreErrors || symbolFromJSPrototype
                        ? undefined
                        : message,
                    name, /*isUse*/
                    true
                );
                if (!symbol) {
                    return symbolFromJSPrototype;
                }
            } else if (name.kind === SyntaxKind.QualifiedName
                || name.kind === SyntaxKind.PropertyAccessExpression)
            {
                const left = name.kind === SyntaxKind.QualifiedName
                    ? name.left
                    : name.expression;
                const right = name.kind === SyntaxKind.QualifiedName
                    ? name.right
                    : name.name;
                let namespace = resolveEntityName(
                    left,
                    namespaceMeaning,
                    ignoreErrors, /*dontResolveAlias*/
                    false,
                    location
                );
                if (!namespace || nodeIsMissing(right)) {
                    return undefined;
                } else if (namespace === unknownSymbol) {
                    return namespace;
                }
                if (isInJSFile(name)) {
                    if (namespace.valueDeclaration
                        && isVariableDeclaration(namespace.valueDeclaration)
                        && namespace.valueDeclaration.initializer
                        && isCommonJsRequire(
                            namespace.valueDeclaration.initializer
                        ))
                    {
                        const moduleName = (namespace.valueDeclaration
                            .initializer as CallExpression).arguments
                            [0] as StringLiteral;
                        const moduleSym = resolveExternalModuleName(
                            moduleName,
                            moduleName
                        );
                        if (moduleSym) {
                            const resolvedModuleSymbol = resolveExternalModuleSymbol(moduleSym);
                            if (resolvedModuleSymbol) {
                                namespace = resolvedModuleSymbol;
                            }
                        }
                    }
                }
                symbol = getSymbol(
                    getExportsOfSymbol(namespace),
                    right.escapedText,
                    meaning
                );
                if (!symbol) {
                    if (!ignoreErrors) {
                        error(
                            right,
                            Diagnostics.Namespace_0_has_no_exported_member_1,
                            getFullyQualifiedName(namespace),
                            declarationNameToString(right)
                        );
                    }
                    return undefined;
                }
            } else {
                throw Debug.assertNever(name, 'Unknown entity name kind.');
            }
            Debug
                .assert(
                    (getCheckFlags(symbol) & CheckFlags.Instantiated) === 0,
                    'Should never get an instantiated symbol here.'
                );
            return (symbol.flags & meaning) || dontResolveAlias
                ? symbol
                : resolveAlias(symbol);
        }

        /**
         * 1. For prototype-property methods like `A.prototype.m = function () ...`, try to resolve names in the scope of `A` too.
         * Note that prototype-property assignment to locations outside the current file (eg globals) doesn't work, so
         * name resolution won't work either.
         * 2. For property assignments like `{ x: function f () { } }`, try to resolve names in the scope of `f` too.
         */
        function resolveEntityNameFromAssignmentDeclaration(
            name: Identifier,
            meaning: SymbolFlags
        ) {
            if (isJSDocTypeReference(name.parent)) {
                const secondaryLocation = getAssignmentDeclarationLocation(
                    name.parent
                );
                if (secondaryLocation) {
                    return resolveName(
                        secondaryLocation,
                        name.escapedText,
                        meaning, /*nameNotFoundMessage*/
                        undefined,
                        name, /*isUse*/
                        true
                    );
                }
            }
        }

        function getAssignmentDeclarationLocation(
            node: TypeReferenceNode
        ): Node | undefined {
            const typeAlias = findAncestor(
                node,
                node => !(isJSDocNode(node) || node.flags & NodeFlags.JSDoc)
                    ? 'quit'
                    : isJSDocTypeAlias(node)
            );
            if (typeAlias) {
                return;
            }
            const host = getJSDocHost(node);
            if (isExpressionStatement(host)
                && isBinaryExpression(host.expression)
                && getAssignmentDeclarationKind(host.expression)
                === AssignmentDeclarationKind.PrototypeProperty)
            {
                // X.prototype.m = /** @param {K} p */ function () { } <-- look for K on X's declaration
                const symbol = getSymbolOfNode(host.expression.left);
                if (symbol) {
                    return getDeclarationOfJSPrototypeContainer(symbol);
                }
            }
            if ((isObjectLiteralMethod(host) || isPropertyAssignment(host))
                && isBinaryExpression(host.parent.parent)
                && getAssignmentDeclarationKind(host.parent.parent)
                === AssignmentDeclarationKind.Prototype)
            {
                // X.prototype = { /** @param {K} p */m() { } } <-- look for K on X's declaration
                const symbol = getSymbolOfNode(host.parent.parent.left);
                if (symbol) {
                    return getDeclarationOfJSPrototypeContainer(symbol);
                }
            }
            const sig = getHostSignatureFromJSDocHost(host);
            if (sig) {
                const symbol = getSymbolOfNode(sig);
                return symbol && symbol.valueDeclaration;
            }
        }

        function getDeclarationOfJSPrototypeContainer(symbol: Symbol) {
            const decl = symbol.parent!.valueDeclaration;
            if (!decl) {
                return undefined;
            }
            const initializer = isAssignmentDeclaration(decl)
                ? getAssignedExpandoInitializer(decl)
                : hasOnlyExpressionInitializer(decl)
                    ? getDeclaredExpandoInitializer(decl)
                    : undefined;
            return initializer || decl;
        }

        /**
         * Get the real symbol of a declaration with an expando initializer.
         *
         * Normally, declarations have an associated symbol, but when a declaration has an expando
         * initializer, the expando's symbol is the one that has all the members merged into it.
         */
        function getExpandoSymbol(symbol: Symbol): Symbol | undefined {
            const decl = symbol.valueDeclaration;
            if (!decl || !isInJSFile(decl)
                || symbol.flags & SymbolFlags.TypeAlias)
            {
                return undefined;
            }
            const init = isVariableDeclaration(decl)
                ? getDeclaredExpandoInitializer(decl)
                : getAssignedExpandoInitializer(decl);
            if (init) {
                const initSymbol = getSymbolOfNode(init);
                if (initSymbol) {
                    return mergeJSSymbols(initSymbol, symbol);
                }
            }
        }

        function resolveExternalModuleName(
            location: Node,
            moduleReferenceExpression: Expression,
            ignoreErrors?: boolean
        ): Symbol | undefined {
            return resolveExternalModuleNameWorker(
                location,
                moduleReferenceExpression,
                ignoreErrors ? undefined : Diagnostics.Cannot_find_module_0
            );
        }

        function resolveExternalModuleNameWorker(
            location: Node,
            moduleReferenceExpression: Expression,
            moduleNotFoundError: DiagnosticMessage | undefined,
            isForAugmentation = false
        ): Symbol | undefined {
            return isStringLiteralLike(moduleReferenceExpression)
                ? resolveExternalModule(
                    location,
                    moduleReferenceExpression.text,
                    moduleNotFoundError,
                    moduleReferenceExpression,
                    isForAugmentation
                )
                : undefined;
        }

        function resolveExternalModule(
            location: Node,
            moduleReference: string,
            moduleNotFoundError: DiagnosticMessage | undefined,
            errorNode: Node,
            isForAugmentation = false
        ): Symbol | undefined {
            if (startsWith(moduleReference, '@types/')) {
                const diag = Diagnostics
                    .Cannot_import_type_declaration_files_Consider_importing_0_instead_of_1;
                const withoutAtTypePrefix = removePrefix(
                    moduleReference,
                    '@types/'
                );
                error(errorNode, diag, withoutAtTypePrefix, moduleReference);
            }

            const ambientModule = tryFindAmbientModule(
                moduleReference, /*withAugmentations*/
                true
            );
            if (ambientModule) {
                return ambientModule;
            }
            const currentSourceFile = getSourceFileOfNode(location);
            const resolvedModule = getResolvedModule(
                currentSourceFile,
                moduleReference
            )!; // TODO: GH#18217
            const resolutionDiagnostic = resolvedModule
                && getResolutionDiagnostic(compilerOptions, resolvedModule);
            const sourceFile = resolvedModule && !resolutionDiagnostic
                && host.getSourceFile(resolvedModule.resolvedFileName);
            if (sourceFile) {
                if (sourceFile.symbol) {
                    if (resolvedModule.isExternalLibraryImport
                        && !resolutionExtensionIsTSOrJson(
                            resolvedModule.extension
                        ))
                    {
                        errorOnImplicitAnyModule(
                            /*isError*/ false,
                            errorNode,
                            resolvedModule,
                            moduleReference
                        );
                    }
                    // merged symbol is module declaration symbol combined with all augmentations
                    return getMergedSymbol(sourceFile.symbol);
                }
                if (moduleNotFoundError) {
                    // report errors only if it was requested
                    error(
                        errorNode,
                        Diagnostics.File_0_is_not_a_module,
                        sourceFile.fileName
                    );
                }
                return undefined;
            }

            if (patternAmbientModules) {
                const pattern = findBestPatternMatch(
                    patternAmbientModules,
                    _ => _.pattern,
                    moduleReference
                );
                if (pattern) {
                    // If the module reference matched a pattern ambient module ('*.foo') but there's also a
                    // module augmentation by the specific name requested ('a.foo'), we store the merged symbol
                    // by the augmentation name ('a.foo'), because asking for *.foo should not give you exports
                    // from a.foo.
                    const augmentation = patternAmbientModuleAugmentations
                        && patternAmbientModuleAugmentations
                            .get(moduleReference);
                    if (augmentation) {
                        return getMergedSymbol(augmentation);
                    }
                    return getMergedSymbol(pattern.symbol);
                }
            }

            // May be an untyped module. If so, ignore resolutionDiagnostic.
            if (resolvedModule
                && !resolutionExtensionIsTSOrJson(resolvedModule.extension)
                && resolutionDiagnostic === undefined
                || resolutionDiagnostic
                === Diagnostics
                    .Could_not_find_a_declaration_file_for_module_0_1_implicitly_has_an_any_type)
            {
                if (isForAugmentation) {
                    const diag = Diagnostics
                        .Invalid_module_name_in_augmentation_Module_0_resolves_to_an_untyped_module_at_1_which_cannot_be_augmented;
                    error(
                        errorNode,
                        diag,
                        moduleReference,
                        resolvedModule.resolvedFileName
                    );
                } else {
                    errorOnImplicitAnyModule(
                        /*isError*/ noImplicitAny && !!moduleNotFoundError,
                        errorNode,
                        resolvedModule,
                        moduleReference
                    );
                }
                // Failed imports and untyped modules are both treated in an untyped manner; only difference is whether we give a diagnostic first.
                return undefined;
            }

            if (moduleNotFoundError) {
                // See if this was possibly a projectReference redirect
                if (resolvedModule) {
                    const redirect = host
                        .getProjectReferenceRedirect(
                            resolvedModule.resolvedFileName
                        );
                    if (redirect) {
                        error(
                            errorNode,
                            Diagnostics
                                .Output_file_0_has_not_been_built_from_source_file_1,
                            redirect,
                            resolvedModule.resolvedFileName
                        );
                        return undefined;
                    }
                }

                if (resolutionDiagnostic) {
                    error(
                        errorNode,
                        resolutionDiagnostic,
                        moduleReference,
                        resolvedModule.resolvedFileName
                    );
                } else {
                    const tsExtension = tryExtractTSExtension(moduleReference);
                    if (tsExtension) {
                        const diag = Diagnostics
                            .An_import_path_cannot_end_with_a_0_extension_Consider_importing_1_instead;
                        error(
                            errorNode,
                            diag,
                            tsExtension,
                            removeExtension(moduleReference, tsExtension)
                        );
                    } else if (!compilerOptions.resolveJsonModule
                        && fileExtensionIs(moduleReference, Extension.Json)
                        && getEmitModuleResolutionKind(compilerOptions)
                        === ModuleResolutionKind.NodeJs
                        && hasJsonModuleEmitEnabled(compilerOptions))
                    {
                        error(
                            errorNode,
                            Diagnostics
                                .Cannot_find_module_0_Consider_using_resolveJsonModule_to_import_module_with_json_extension,
                            moduleReference
                        );
                    } else {
                        error(errorNode, moduleNotFoundError, moduleReference);
                    }
                }
            }
            return undefined;
        }

        function errorOnImplicitAnyModule(
            isError: boolean,
            errorNode: Node,
            { packageId, resolvedFileName }ResolvedModuleFull,
            moduleReference: string
        ): void {
            const errorInfo = !isExternalModuleNameRelative(moduleReference)
                && packageId
                ? typesPackageExists(packageId.name)
                    ? chainDiagnosticMessages(
                        /*details*/ undefined,
                        Diagnostics
                            .If_the_0_package_actually_exposes_this_module_consider_sending_a_pull_request_to_amend_https_Colon_Slash_Slashgithub_com_SlashDefinitelyTyped_SlashDefinitelyTyped_Slashtree_Slashmaster_Slashtypes_Slash_1,
                        packageId.name,
                        mangleScopedPackageName(packageId.name)
                    )
                    : chainDiagnosticMessages(
                        /*details*/ undefined,
                        Diagnostics
                            .Try_npm_install_types_Slash_1_if_it_exists_or_add_a_new_declaration_d_ts_file_containing_declare_module_0,
                        moduleReference,
                        mangleScopedPackageName(packageId.name)
                    )
                : undefined;
            errorOrSuggestion(
                isError,
                errorNode,
                chainDiagnosticMessages(
                    errorInfo,
                    Diagnostics
                        .Could_not_find_a_declaration_file_for_module_0_1_implicitly_has_an_any_type,
                    moduleReference,
                    resolvedFileName
                )
            );
        }
        function typesPackageExists(packageName: string): boolean {
            return getPackagesSet().has(getTypesPackageName(packageName));
        }

        function resolveExternalModuleSymbol(
            moduleSymbol: Symbol,
            dontResolveAlias?: boolean
        ): Symbol;
        function resolveExternalModuleSymbol(
            moduleSymbol: Symbol | undefined,
            dontResolveAlias?: boolean
        ): Symbol | undefined;
        function resolveExternalModuleSymbol(
            moduleSymbol: Symbol,
            dontResolveAlias?: boolean
        ): Symbol {
            if (moduleSymbol) {
                const exportEquals = resolveSymbol(
                    moduleSymbol.exports!.get(InternalSymbolName.ExportEquals),
                    dontResolveAlias
                );
                const exported = getCommonJsExportEquals(
                    getMergedSymbol(exportEquals),
                    getMergedSymbol(moduleSymbol)
                );
                return getMergedSymbol(exported) || moduleSymbol;
            }
            return undefined!;
        }

        function getCommonJsExportEquals(
            exported: Symbol | undefined,
            moduleSymbol: Symbol
        ): Symbol | undefined {
            if (!exported || exported === unknownSymbol
                || exported === moduleSymbol
                || moduleSymbol.exports!.size === 1
                || exported.flags & SymbolFlags.Alias)
            {
                return exported;
            }
            const links = getSymbolLinks(exported);
            if (links.cjsExportMerged) {
                return links.cjsExportMerged;
            }
            const merged = exported.flags & SymbolFlags.Transient
                ? exported
                : cloneSymbol(exported);
            merged.flags = merged.flags | SymbolFlags.ValueModule;
            if (merged.exports === undefined) {
                merged.exports = createSymbolTable();
            }
            moduleSymbol.exports!.forEach((s, name) => {
                if (name === InternalSymbolName.ExportEquals) return;
                merged.exports!.set(
                    name,
                    merged.exports!.has(name)
                        ? mergeSymbol(merged.exports!.get(name)!, s)
                        : s
                );
            });
            getSymbolLinks(merged).cjsExportMerged = merged;
            return links.cjsExportMerged = merged;
        }

        // An external module with an 'export =' declaration may be referenced as an ES6 module provided the 'export ='
        // references a symbol that is at least declared as a module or a variable. The target of the 'export =' may
        // combine other declarations with the module or variable (e.g. a class/module, function/module, interface/variable).
        function resolveESModuleSymbol(
            moduleSymbol: Symbol | undefined,
            referencingLocation: Node,
            dontResolveAlias: boolean,
            suppressInteropError: boolean
        ): Symbol | undefined {
            const symbol = resolveExternalModuleSymbol(
                moduleSymbol,
                dontResolveAlias
            );

            if (!dontResolveAlias && symbol) {
                if (!suppressInteropError
                    && !(symbol.flags
                        & (SymbolFlags.Module | SymbolFlags.Variable))
                    && !getDeclarationOfKind(symbol, SyntaxKind.SourceFile))
                {
                    const compilerOptionName = moduleKind >= ModuleKind.ES2015
                        ? 'allowSyntheticDefaultImports'
                        : 'esModuleInterop';

                    error(
                        referencingLocation,
                        Diagnostics
                            .This_module_can_only_be_referenced_with_ECMAScript_imports_Slashexports_by_turning_on_the_0_flag_and_referencing_its_default_export,
                        compilerOptionName
                    );

                    return symbol;
                }

                if (compilerOptions.esModuleInterop) {
                    const referenceParent = referencingLocation.parent;
                    if (
                        (isImportDeclaration(referenceParent)
                            && getNamespaceDeclarationNode(referenceParent))
                        || isImportCall(referenceParent)
                    ) {
                        const type = getTypeOfSymbol(symbol);
                        let sigs = getSignaturesOfStructuredType(
                            type,
                            SignatureKind.Call
                        );
                        if (!sigs || !sigs.length) {
                            sigs = getSignaturesOfStructuredType(
                                type,
                                SignatureKind.Construct
                            );
                        }
                        if (sigs && sigs.length) {
                            const moduleType = getTypeWithSyntheticDefaultImportType(
                                type,
                                symbol,
                                moduleSymbol!
                            );
                            // Create a new symbol which has the module's type less the call and construct signatures
                            const result = createSymbol(
                                symbol.flags,
                                symbol.escapedName
                            );
                            result.declarations = symbol.declarations
                                ? symbol.declarations.slice()
                                : [];
                            result.parent = symbol.parent;
                            result.target = symbol;
                            result.originatingImport = referenceParent;
                            if (symbol.valueDeclaration) {
                                result.valueDeclaration = symbol
                                    .valueDeclaration;
                            }
                            if (symbol.constEnumOnlyModule) {
                                result.constEnumOnlyModule = true;
                            }
                            if (symbol.members) {
                                result.members = cloneMap(symbol.members);
                            }
                            if (symbol.exports) {
                                result.exports = cloneMap(symbol.exports);
                            }
                            const resolvedModuleType = resolveStructuredTypeMembers(moduleType as StructuredType); // Should already be resolved from the signature checks above
                            result.type = createAnonymousType(
                                result,
                                resolvedModuleType.members,
                                emptyArray,
                                emptyArray,
                                resolvedModuleType.stringIndexInfo,
                                resolvedModuleType.numberIndexInfo
                            );
                            return result;
                        }
                    }
                }
            }
            return symbol;
        }

        function hasExportAssignmentSymbol(moduleSymbol: Symbol): boolean {
            return moduleSymbol.exports!.get(InternalSymbolName.ExportEquals)
                !== undefined;
        }

        function getExportsOfModuleAsArray(moduleSymbol: Symbol): Symbol[] {
            return symbolsToArray(getExportsOfModule(moduleSymbol));
        }

        function getExportsAndPropertiesOfModule(
            moduleSymbol: Symbol
        ): Symbol[] {
            const exports = getExportsOfModuleAsArray(moduleSymbol);
            const exportEquals = resolveExternalModuleSymbol(moduleSymbol);
            if (exportEquals !== moduleSymbol) {
                addRange(
                    exports,
                    getPropertiesOfType(getTypeOfSymbol(exportEquals))
                );
            }
            return exports;
        }

        function tryGetMemberInModuleExports(
            memberName: __String,
            moduleSymbol: Symbol
        ): Symbol | undefined {
            const symbolTable = getExportsOfModule(moduleSymbol);
            if (symbolTable) {
                return symbolTable.get(memberName);
            }
        }

        function tryGetMemberInModuleExportsAndProperties(
            memberName: __String,
            moduleSymbol: Symbol
        ): Symbol | undefined {
            const symbol = tryGetMemberInModuleExports(
                memberName,
                moduleSymbol
            );
            if (symbol) {
                return symbol;
            }

            const exportEquals = resolveExternalModuleSymbol(moduleSymbol);
            if (exportEquals === moduleSymbol) {
                return undefined;
            }

            const type = getTypeOfSymbol(exportEquals);
            return type.flags & TypeFlags.Primitive
                || getObjectFlags(type) & ObjectFlags.Class
                || isArrayOrTupleLikeType(type)
                ? undefined
                : getPropertyOfType(type, memberName);
        }

        function getExportsOfSymbol(symbol: Symbol): SymbolTable {
            return symbol.flags & SymbolFlags.LateBindingContainer
                ? getResolvedMembersOrExportsOfSymbol(
                    symbol,
                    MembersOrExportsResolutionKind.resolvedExports
                )
                : symbol.flags & SymbolFlags.Module
                    ? getExportsOfModule(symbol)
                    : symbol.exports || emptySymbols;
        }

        function getExportsOfModule(moduleSymbol: Symbol): SymbolTable {
            const links = getSymbolLinks(moduleSymbol);
            return links.resolvedExports
                || (links
                    .resolvedExports = getExportsOfModuleWorker(moduleSymbol));
        }

        interface ExportCollisionTracker {
            specifierText: string;
            exportsWithDuplicate: ExportDeclaration[];
        }

        type ExportCollisionTrackerTable = UnderscoreEscapedMap<ExportCollisionTracker>;

        /**
         * Extends one symbol table with another while collecting information on name collisions for error message generation into the `lookupTable` argument
         * Not passing `lookupTable` and `exportNode` disables this collection, and just extends the tables
         */
        function extendExportSymbols(
            target: SymbolTable,
            source: SymbolTable | undefined,
            lookupTable?: ExportCollisionTrackerTable,
            exportNode?: ExportDeclaration
        ) {
            if (!source) return;
            source.forEach((sourceSymbol, id) => {
                if (id === InternalSymbolName.Default) return;

                const targetSymbol = target.get(id);
                if (!targetSymbol) {
                    target.set(id, sourceSymbol);
                    if (lookupTable && exportNode) {
                        lookupTable.set(
                            id,
                            {
                                specifierText:
                                    getTextOfNode(exportNode.moduleSpecifier!)
                            } as ExportCollisionTracker
                        );
                    }
                } else if (lookupTable && exportNode && targetSymbol
                    && resolveSymbol(targetSymbol)
                    !== resolveSymbol(sourceSymbol))
                {
                    const collisionTracker = lookupTable.get(id)!;
                    if (!collisionTracker.exportsWithDuplicate) {
                        collisionTracker.exportsWithDuplicate = [exportNode];
                    } else {
                        collisionTracker.exportsWithDuplicate.push(exportNode);
                    }
                }
            });
        }

        function getExportsOfModuleWorker(moduleSymbol: Symbol): SymbolTable {
            const visitedSymbols: Symbol[] = [];

            // A module defined by an 'export=' consists of one export that needs to be resolved
            moduleSymbol = resolveExternalModuleSymbol(moduleSymbol);

            return visit(moduleSymbol) || emptySymbols;

            // The ES6 spec permits export * declarations in a module to circularly reference the module itself. For example,
            // module 'a' can 'export * from "b"' and 'b' can 'export * from "a"' without error.
            function visit(symbol: Symbol | undefined): SymbolTable
                | undefined
            {
                if (!(symbol && symbol.exports
                    && pushIfUnique(visitedSymbols, symbol)))
                {
                    return;
                }
                const symbols = cloneMap(symbol.exports);
                // All export * declarations are collected in an __export symbol by the binder
                const exportStars = symbol.exports
                    .get(InternalSymbolName.ExportStar);
                if (exportStars) {
                    const nestedSymbols = createSymbolTable();
                    const lookupTable = createMap<ExportCollisionTracker>() as ExportCollisionTrackerTable;
                    for (const node of exportStars.declarations) {
                        const resolvedModule = resolveExternalModuleName(
                            node,
                            (node as ExportDeclaration).moduleSpecifier!
                        );
                        const exportedSymbols = visit(resolvedModule);
                        extendExportSymbols(
                            nestedSymbols,
                            exportedSymbols,
                            lookupTable,
                            node as ExportDeclaration
                        );
                    }
                    lookupTable.forEach(({ exportsWithDuplicate }, id) => {
                        // It's not an error if the file with multiple `export *`s with duplicate names exports a member with that name itself
                        if (id === 'export='
                            || !(exportsWithDuplicate
                                && exportsWithDuplicate.length)
                            || symbols.has(id))
                        {
                            return;
                        }
                        for (const node of exportsWithDuplicate) {
                            diagnostics.add(
                                createDiagnosticForNode(
                                    node,
                                    Diagnostics
                                        .Module_0_has_already_exported_a_member_named_1_Consider_explicitly_re_exporting_to_resolve_the_ambiguity,
                                    lookupTable.get(id)!.specifierText,
                                    unescapeLeadingUnderscores(id)
                                )
                            );
                        }
                    });
                    extendExportSymbols(symbols, nestedSymbols);
                }
                return symbols;
            }
        }

        function getMergedSymbol(symbol: Symbol): Symbol;
        function getMergedSymbol(
            symbol: Symbol | undefined
        ): Symbol | undefined;
        function getMergedSymbol(
            symbol: Symbol | undefined
        ): Symbol | undefined {
            let merged: Symbol;
            return symbol && symbol.mergeId
                && (merged = mergedSymbols[symbol.mergeId])
                ? merged
                : symbol;
        }

        function getSymbolOfNode(node: Declaration): Symbol;
        function getSymbolOfNode(node: Node): Symbol | undefined;
        function getSymbolOfNode(node: Node): Symbol | undefined {
            return getMergedSymbol(
                node.symbol && getLateBoundSymbol(node.symbol)
            );
        }

        function getParentOfSymbol(symbol: Symbol): Symbol | undefined {
            return getMergedSymbol(
                symbol.parent && getLateBoundSymbol(symbol.parent)
            );
        }

        function getAlternativeContainingModules(
            symbol: Symbol,
            enclosingDeclaration: Node
        ): Symbol[] {
            const containingFile = getSourceFileOfNode(enclosingDeclaration);
            const id = '' + getNodeId(containingFile);
            const links = getSymbolLinks(symbol);
            let results: Symbol[] | undefined;
            if (links.extendedContainersByFile
                && (results = links.extendedContainersByFile.get(id)))
            {
                return results;
            }
            if (containingFile && containingFile.imports) {
                // Try to make an import using an import already in the enclosing file, if possible
                for (const importRef of containingFile.imports) {
                    if (nodeIsSynthesized(importRef)) continue; // Synthetic names can't be resolved by `resolveExternalModuleName` - they'll cause a debug assert if they error
                    const resolvedModule = resolveExternalModuleName(
                        enclosingDeclaration,
                        importRef, /*ignoreErrors*/
                        true
                    );
                    if (!resolvedModule) continue;
                    const ref = getAliasForSymbolInContainer(
                        resolvedModule,
                        symbol
                    );
                    if (!ref) continue;
                    results = append(results, resolvedModule);
                }
                if (length(results)) {
                    (links.extendedContainersByFile
                        || (links.extendedContainersByFile = createMap()))
                        .set(id, results!);
                    return results!;
                }
            }
            if (links.extendedContainers) {
                return links.extendedContainers;
            }
            // No results from files already being imported by this file - expand search (expensive, but not location-specific, so cached)
            const otherFiles = host.getSourceFiles();
            for (const file of otherFiles) {
                if (!isExternalModule(file)) continue;
                const sym = getSymbolOfNode(file);
                const ref = getAliasForSymbolInContainer(sym, symbol);
                if (!ref) continue;
                results = append(results, sym);
            }
            return links.extendedContainers = results || emptyArray;
        }

        /**
         * Attempts to find the symbol corresponding to the container a symbol is in - usually this
         * is just its' `.parent`, but for locals, this value is `undefined`
         */
        function getContainersOfSymbol(
            symbol: Symbol,
            enclosingDeclaration: Node | undefined
        ): Symbol[] | undefined {
            const container = getParentOfSymbol(symbol);
            // Type parameters end up in the `members` lists but are not externally visible
            if (container && !(symbol.flags & SymbolFlags.TypeParameter)) {
                const additionalContainers = mapDefined(
                    container.declarations,
                    fileSymbolIfFileSymbolExportEqualsContainer
                );
                const reexportContainers = enclosingDeclaration
                    && getAlternativeContainingModules(
                        symbol,
                        enclosingDeclaration
                    );
                if (enclosingDeclaration
                    && getAccessibleSymbolChain(
                        container,
                        enclosingDeclaration,
                        SymbolFlags.Namespace, /*externalOnly*/
                        false
                    ))
                {
                    return concatenate(
                        concatenate(
                            [container],
                            additionalContainers
                        ),
                        reexportContainers
                    ); // This order expresses a preference for the real container if it is in scope
                }
                const res = append(additionalContainers, container);
                return concatenate(res, reexportContainers);
            }
            const candidates = mapDefined(
                symbol.declarations,
                d => {
                    if (!isAmbientModule(d) && d.parent
                        && hasNonGlobalAugmentationExternalModuleSymbol(d
                            .parent))
                    {
                        return getSymbolOfNode(d.parent);
                    }
                    if (isClassExpression(d) && isBinaryExpression(d.parent)
                        && d.parent.operatorToken.kind
                        === SyntaxKind.EqualsToken
                        && isAccessExpression(d.parent.left)
                        && isEntityNameExpression(d.parent.left.expression))
                    {
                        if (isModuleExportsAccessExpression(d.parent.left)
                            || isExportsIdentifier(d.parent.left.expression))
                        {
                            return getSymbolOfNode(getSourceFileOfNode(d));
                        }
                        checkExpressionCached(d.parent.left.expression);
                        return getNodeLinks(d.parent.left.expression)
                            .resolvedSymbol;
                    }
                }
            );
            if (!length(candidates)) {
                return undefined;
            }
            return mapDefined(
                candidates,
                candidate => getAliasForSymbolInContainer(candidate, symbol)
                    ? candidate
                    : undefined
            );

            function fileSymbolIfFileSymbolExportEqualsContainer(
                d: Declaration
            ) {
                const fileSymbol = getExternalModuleContainer(d);
                const exported = fileSymbol && fileSymbol.exports
                    && fileSymbol.exports.get(InternalSymbolName.ExportEquals);
                return exported && container
                    && getSymbolIfSameReference(exported, container)
                    ? fileSymbol
                    : undefined;
            }
        }

        function getAliasForSymbolInContainer(
            container: Symbol,
            symbol: Symbol
        ) {
            if (container === getParentOfSymbol(symbol)) {
                // fast path, `symbol` is either already the alias or isn't aliased
                return symbol;
            }
            // Check if container is a thing with an `export=` which points directly at `symbol`, and if so, return
            // the container itself as the alias for the symbol
            const exportEquals = container.exports
                && container.exports.get(InternalSymbolName.ExportEquals);
            if (exportEquals
                && getSymbolIfSameReference(exportEquals, symbol))
            {
                return container;
            }
            const exports = getExportsOfSymbol(container);
            const quick = exports.get(symbol.escapedName);
            if (quick && getSymbolIfSameReference(quick, symbol)) {
                return quick;
            }
            return forEachEntry(
                exports,
                exported => {
                    if (getSymbolIfSameReference(exported, symbol)) {
                        return exported;
                    }
                }
            );
        }

        /**
         * Checks if two symbols, through aliasing and/or merging, refer to the same thing
         */
        function getSymbolIfSameReference(s1: Symbol, s2: Symbol) {
            if (getMergedSymbol(resolveSymbol(getMergedSymbol(s1)))
                === getMergedSymbol(resolveSymbol(getMergedSymbol(s2))))
            {
                return s1;
            }
        }

        function getExportSymbolOfValueSymbolIfExported(symbol:
            Symbol): Symbol;
        function getExportSymbolOfValueSymbolIfExported(
            symbol: Symbol | undefined
        ): Symbol | undefined;
        function getExportSymbolOfValueSymbolIfExported(
            symbol: Symbol | undefined
        ): Symbol | undefined {
            return getMergedSymbol(
                symbol && (symbol.flags & SymbolFlags.ExportValue) !== 0
                    ? symbol.exportSymbol
                    : symbol
            );
        }

        function symbolIsValue(symbol: Symbol): boolean {
            return !!(symbol.flags & SymbolFlags.Value
                || symbol.flags & SymbolFlags.Alias
                && resolveAlias(symbol).flags & SymbolFlags.Value);
        }

        function findConstructorDeclaration(
            node: ClassLikeDeclaration
        ): ConstructorDeclaration | undefined {
            const members = node.members;
            for (const member of members) {
                if (member.kind === SyntaxKind.Constructor
                    && nodeIsPresent((<ConstructorDeclaration> member).body))
                {
                    return <ConstructorDeclaration> member;
                }
            }
        }

        function createType(flags: TypeFlags): Type {
            const result = new Type(checker, flags);
            typeCount++;
            result.id = typeCount;
            return result;
        }

        function createIntrinsicType(
            kind: TypeFlags,
            intrinsicName: string,
            objectFlags: ObjectFlags = 0
        ): IntrinsicType {
            const type = <IntrinsicType> createType(kind);
            type.intrinsicName = intrinsicName;
            type.objectFlags = objectFlags;
            return type;
        }

        function createBooleanType(
            trueFalseTypes: readonly Type[]
        ): IntrinsicType & UnionType {
            const type = <IntrinsicType
                & UnionType> getUnionType(trueFalseTypes);
            type.flags |= TypeFlags.Boolean;
            type.intrinsicName = 'boolean';
            return type;
        }

        function createObjectType(
            objectFlags: ObjectFlags,
            symbol?: Symbol
        ): ObjectType {
            const type = <ObjectType> createType(TypeFlags.Object);
            type.objectFlags = objectFlags;
            type.symbol = symbol!;
            type.members = undefined;
            type.properties = undefined;
            type.callSignatures = undefined;
            type.constructSignatures = undefined;
            type.stringIndexInfo = undefined;
            type.numberIndexInfo = undefined;
            return type;
        }

        function createTypeofType() {
            return getUnionType(
                arrayFrom(typeofEQFacts.keys(), getLiteralType)
            );
        }

        function createTypeParameter(symbol?: Symbol) {
            const type = <TypeParameter> createType(TypeFlags.TypeParameter);
            if (symbol) type.symbol = symbol;
            return type;
        }

        // A reserved member name starts with two underscores, but the third character cannot be an underscore,
        // @, or #. A third underscore indicates an escaped form of an identifier that started
        // with at least two underscores. The @ character indicates that the name is denoted by a well known ES
        // Symbol instance and the # character indicates that the name is a PrivateIdentifier.
        function isReservedMemberName(name: __String) {
            return (name as string).charCodeAt(0) === CharacterCodes._
                && (name as string).charCodeAt(1) === CharacterCodes._
                && (name as string).charCodeAt(2) !== CharacterCodes._
                && (name as string).charCodeAt(2) !== CharacterCodes.at
                && (name as string).charCodeAt(2) !== CharacterCodes.hash;
        }

        function getNamedMembers(members: SymbolTable): Symbol[] {
            let result: Symbol[] | undefined;
            members.forEach((symbol, id) => {
                if (!isReservedMemberName(id) && symbolIsValue(symbol)) {
                    (result || (result = [])).push(symbol);
                }
            });
            return result || emptyArray;
        }

        function setStructuredTypeMembers(
            type: StructuredType,
            members: SymbolTable,
            callSignatures: readonly Signature[],
            constructSignatures: readonly Signature[],
            stringIndexInfo: IndexInfo | undefined,
            numberIndexInfo: IndexInfo | undefined
        ): ResolvedType {
            (<ResolvedType> type).members = members;
            (<ResolvedType> type).properties = members === emptySymbols
                ? emptyArray
                : getNamedMembers(members);
            (<ResolvedType> type).callSignatures = callSignatures;
            (<ResolvedType> type).constructSignatures = constructSignatures;
            (<ResolvedType> type).stringIndexInfo = stringIndexInfo;
            (<ResolvedType> type).numberIndexInfo = numberIndexInfo;
            return <ResolvedType> type;
        }

        function createAnonymousType(
            symbol: Symbol | undefined,
            members: SymbolTable,
            callSignatures: readonly Signature[],
            constructSignatures: readonly Signature[],
            stringIndexInfo: IndexInfo | undefined,
            numberIndexInfo: IndexInfo | undefined
        ): ResolvedType {
            return setStructuredTypeMembers(
                createObjectType(
                    ObjectFlags.Anonymous,
                    symbol
                ),
                members,
                callSignatures,
                constructSignatures,
                stringIndexInfo,
                numberIndexInfo
            );
        }

        function forEachSymbolTableInScope<T>(
            enclosingDeclaration: Node | undefined,
            callback: (symbolTable: SymbolTable) => T
        ): T {
            let result: T;
            for (let location = enclosingDeclaration; location;
                location = location.parent)
            {
                // Locals of a source file are not in scope (because they get merged into the global symbol table)
                if (location.locals && !isGlobalSourceFile(location)) {
                    if (result = callback(location.locals)) {
                        return result;
                    }
                }
                switch (location.kind) {
                    case SyntaxKind.SourceFile:
                        if (!isExternalOrCommonJsModule(<SourceFile> location)) {
                            break;
                        }
                        // falls through
                    case SyntaxKind.ModuleDeclaration:
                        const sym = getSymbolOfNode(location as ModuleDeclaration);
                        // `sym` may not have exports if this module declaration is backed by the symbol for a `const` that's being rewritten
                        // into a namespace - in such cases, it's best to just let the namespace appear empty (the const members couldn't have referred
                        // to one another anyway)
                        if (result = callback(sym.exports || emptySymbols)) {
                            return result;
                        }
                        break;
                    case SyntaxKind.ClassDeclaration:
                    case SyntaxKind.ClassExpression:
                    case SyntaxKind.InterfaceDeclaration:
                        // Type parameters are bound into `members` lists so they can merge across declarations
                        // This is troublesome, since in all other respects, they behave like locals :cries:
                        // TODO: the below is shared with similar code in `resolveName` - in fact, rephrasing all this symbol
                        // lookup logic in terms of `resolveName` would be nice
                        // The below is used to lookup type parameters within a class or interface, as they are added to the class/interface locals
                        // These can never be latebound, so the symbol's raw members are sufficient. `getMembersOfNode` cannot be used, as it would
                        // trigger resolving late-bound names, which we may already be in the process of doing while we're here!
                        let table: UnderscoreEscapedMap<Symbol> | undefined;
                        // TODO: Should this filtered table be cached in some way?
                        (getSymbolOfNode(
                            location as ClassLikeDeclaration
                                | InterfaceDeclaration
                        ).members || emptySymbols)
                            .forEach((memberSymbol, key) => {
                                if (memberSymbol.flags
                                    & (SymbolFlags.Type
                                        & ~SymbolFlags.Assignment))
                                {
                                    (table || (table = createSymbolTable()))
                                        .set(key, memberSymbol);
                                }
                            });
                        if (table && (result = callback(table))) {
                            return result;
                        }
                        break;
                }
            }

            return callback(globals);
        }

        function getQualifiedLeftMeaning(rightMeaning: SymbolFlags) {
            // If we are looking in value space, the parent meaning is value, other wise it is namespace
            return rightMeaning === SymbolFlags.Value
                ? SymbolFlags.Value
                : SymbolFlags.Namespace;
        }

        function getAccessibleSymbolChain(
            symbol: Symbol | undefined,
            enclosingDeclaration: Node | undefined,
            meaning: SymbolFlags,
            useOnlyExternalAliasing: boolean,
            visitedSymbolTablesMap: Map<SymbolTable[]> = createMap()
        ): Symbol[] | undefined {
            if (!(symbol && !isPropertyOrMethodDeclarationSymbol(symbol))) {
                return undefined;
            }

            const id = '' + getSymbolId(symbol);
            let visitedSymbolTables = visitedSymbolTablesMap.get(id);
            if (!visitedSymbolTables) {
                visitedSymbolTablesMap.set(id, visitedSymbolTables = []);
            }
            return forEachSymbolTableInScope(
                enclosingDeclaration,
                getAccessibleSymbolChainFromSymbolTable
            );

            /**
             * @param {ignoreQualification} boolean Set when a symbol is being looked for through the exports of another symbol (meaning we have a route to qualify it already)
             */
            function getAccessibleSymbolChainFromSymbolTable(
                symbols: SymbolTable,
                ignoreQualification?: boolean
            ): Symbol[] | undefined {
                if (!pushIfUnique(visitedSymbolTables!, symbols)) {
                    return undefined;
                }

                const result = trySymbolTable(symbols, ignoreQualification);
                visitedSymbolTables!.pop();
                return result;
            }

            function canQualifySymbol(
                symbolFromSymbolTable: Symbol,
                meaning: SymbolFlags
            ) {
                // If the symbol is equivalent and doesn't need further qualification, this symbol is accessible
                return !needsQualification(
                    symbolFromSymbolTable,
                    enclosingDeclaration,
                    meaning
                )
                    // If symbol needs qualification, make sure that parent is accessible, if it is then this symbol is accessible too
                    || !!getAccessibleSymbolChain(
                        symbolFromSymbolTable.parent,
                        enclosingDeclaration,
                        getQualifiedLeftMeaning(meaning),
                        useOnlyExternalAliasing,
                        visitedSymbolTablesMap
                    );
            }

            function isAccessible(
                symbolFromSymbolTable: Symbol,
                resolvedAliasSymbol?: Symbol,
                ignoreQualification?: boolean
            ) {
                return (symbol
                    === (resolvedAliasSymbol || symbolFromSymbolTable)
                    || getMergedSymbol(symbol)
                    === getMergedSymbol(
                        resolvedAliasSymbol || symbolFromSymbolTable
                    ))
                    // if the symbolFromSymbolTable is not external module (it could be if it was determined as ambient external module and would be in globals table)
                    // and if symbolFromSymbolTable or alias resolution matches the symbol,
                    // check the symbol can be qualified, it is only then this symbol is accessible
                    && !some(
                        symbolFromSymbolTable.declarations,
                        hasNonGlobalAugmentationExternalModuleSymbol
                    )
                    && (ignoreQualification
                        || canQualifySymbol(
                            getMergedSymbol(symbolFromSymbolTable),
                            meaning
                        ));
            }

            function trySymbolTable(
                symbols: SymbolTable,
                ignoreQualification: boolean | undefined
            ): Symbol[] | undefined {
                // If symbol is directly available by its name in the symbol table
                if (isAccessible(
                    symbols.get(symbol!.escapedName)!, /*resolvedAliasSymbol*/
                    undefined,
                    ignoreQualification
                )) {
                    return [symbol!];
                }

                // Check if symbol is any of the aliases in scope
                const result = forEachEntry(
                    symbols,
                    symbolFromSymbolTable => {
                        if (symbolFromSymbolTable.flags & SymbolFlags.Alias
                            && symbolFromSymbolTable.escapedName
                            !== InternalSymbolName.ExportEquals
                            && symbolFromSymbolTable.escapedName
                            !== InternalSymbolName.Default
                            && !(isUMDExportSymbol(symbolFromSymbolTable)
                                && enclosingDeclaration
                                && isExternalModule(getSourceFileOfNode(enclosingDeclaration)))
                            // If `!useOnlyExternalAliasing`, we can use any type of alias to get the name
                            && (!useOnlyExternalAliasing || some(
                                symbolFromSymbolTable.declarations,
                                isExternalModuleImportEqualsDeclaration
                            ))
                            // While exports are generally considered to be in scope, export-specifier declared symbols are _not_
                            // See similar comment in `resolveName` for details
                            && (ignoreQualification || !getDeclarationOfKind(
                                symbolFromSymbolTable,
                                SyntaxKind.ExportSpecifier
                            )))
                        {
                            const resolvedImportedSymbol = resolveAlias(symbolFromSymbolTable);
                            const candidate = getCandidateListForSymbol(
                                symbolFromSymbolTable,
                                resolvedImportedSymbol,
                                ignoreQualification
                            );
                            if (candidate) {
                                return candidate;
                            }
                        }
                        if (symbolFromSymbolTable.escapedName
                            === symbol!.escapedName
                            && symbolFromSymbolTable.exportSymbol)
                        {
                            if (isAccessible(
                                getMergedSymbol(
                                    symbolFromSymbolTable.exportSymbol
                                ), /*aliasSymbol*/
                                undefined,
                                ignoreQualification
                            )) {
                                return [symbol!];
                            }
                        }
                    }
                );

                // If there's no result and we're looking at the global symbol table, treat `globalThis` like an alias and try to lookup thru that
                return result
                    || (symbols === globals
                        ? getCandidateListForSymbol(
                            globalThisSymbol,
                            globalThisSymbol,
                            ignoreQualification
                        )
                        : undefined);
            }

            function getCandidateListForSymbol(
                symbolFromSymbolTable: Symbol,
                resolvedImportedSymbol: Symbol,
                ignoreQualification: boolean | undefined
            ) {
                if (isAccessible(
                    symbolFromSymbolTable,
                    resolvedImportedSymbol,
                    ignoreQualification
                )) {
                    return [symbolFromSymbolTable];
                }

                // Look in the exported members, if we can find accessibleSymbolChain, symbol is accessible using this chain
                // but only if the symbolFromSymbolTable can be qualified
                const candidateTable = getExportsOfSymbol(resolvedImportedSymbol);
                const accessibleSymbolsFromExports = candidateTable
                    && getAccessibleSymbolChainFromSymbolTable(
                        candidateTable, /*ignoreQualification*/
                        true
                    );
                if (accessibleSymbolsFromExports
                    && canQualifySymbol(
                        symbolFromSymbolTable,
                        getQualifiedLeftMeaning(meaning)
                    ))
                {
                    return [symbolFromSymbolTable]
                        .concat(accessibleSymbolsFromExports);
                }
            }
        }

        function needsQualification(
            symbol: Symbol,
            enclosingDeclaration: Node | undefined,
            meaning: SymbolFlags
        ) {
            let qualify = false;
            forEachSymbolTableInScope(
                enclosingDeclaration,
                symbolTable => {
                    // If symbol of this name is not available in the symbol table we are ok
                    let symbolFromSymbolTable = getMergedSymbol(symbolTable
                        .get(symbol.escapedName));
                    if (!symbolFromSymbolTable) {
                        // Continue to the next symbol table
                        return false;
                    }
                    // If the symbol with this name is present it should refer to the symbol
                    if (symbolFromSymbolTable === symbol) {
                        // No need to qualify
                        return true;
                    }

                    // Qualify if the symbol from symbol table has same meaning as expected
                    symbolFromSymbolTable = (symbolFromSymbolTable.flags
                        & SymbolFlags.Alias && !getDeclarationOfKind(
                            symbolFromSymbolTable,
                            SyntaxKind.ExportSpecifier
                        ))
                        ? resolveAlias(symbolFromSymbolTable)
                        : symbolFromSymbolTable;
                    if (symbolFromSymbolTable.flags & meaning) {
                        qualify = true;
                        return true;
                    }

                    // Continue to the next symbol table
                    return false;
                }
            );

            return qualify;
        }

        function isPropertyOrMethodDeclarationSymbol(symbol: Symbol) {
            if (symbol.declarations && symbol.declarations.length) {
                for (const declaration of symbol.declarations) {
                    switch (declaration.kind) {
                        case SyntaxKind.PropertyDeclaration:
                        case SyntaxKind.MethodDeclaration:
                        case SyntaxKind.GetAccessor:
                        case SyntaxKind.SetAccessor:
                            continue;
                        default:
                            return false;
                    }
                }
                return true;
            }
            return false;
        }

        function isTypeSymbolAccessible(
            typeSymbol: Symbol,
            enclosingDeclaration: Node | undefined
        ): boolean {
            const access = isSymbolAccessible(
                typeSymbol,
                enclosingDeclaration,
                SymbolFlags.Type, /*shouldComputeAliasesToMakeVisible*/
                false
            );
            return access.accessibility === SymbolAccessibility.Accessible;
        }

        function isValueSymbolAccessible(
            typeSymbol: Symbol,
            enclosingDeclaration: Node | undefined
        ): boolean {
            const access = isSymbolAccessible(
                typeSymbol,
                enclosingDeclaration,
                SymbolFlags.Value, /*shouldComputeAliasesToMakeVisible*/
                false
            );
            return access.accessibility === SymbolAccessibility.Accessible;
        }

        function isAnySymbolAccessible(
            symbols: Symbol[] | undefined,
            enclosingDeclaration: Node | undefined,
            initialSymbol: Symbol,
            meaning: SymbolFlags,
            shouldComputeAliasesToMakeVisible: boolean
        ): SymbolAccessibilityResult | undefined {
            if (!length(symbols)) return;

            let hadAccessibleChain: Symbol | undefined;
            for (const symbol of symbols!) {
                // Symbol is accessible if it by itself is accessible
                const accessibleSymbolChain = getAccessibleSymbolChain(
                    symbol,
                    enclosingDeclaration,
                    meaning, /*useOnlyExternalAliasing*/
                    false
                );
                if (accessibleSymbolChain) {
                    hadAccessibleChain = symbol;
                    const hasAccessibleDeclarations = hasVisibleDeclarations(
                        accessibleSymbolChain[0],
                        shouldComputeAliasesToMakeVisible
                    );
                    if (hasAccessibleDeclarations) {
                        return hasAccessibleDeclarations;
                    }
                } else {
                    if (some(
                        symbol.declarations,
                        hasNonGlobalAugmentationExternalModuleSymbol
                    )) {
                        // Any meaning of a module symbol is always accessible via an `import` type
                        return {
                            accessibility: SymbolAccessibility.Accessible
                        };
                    }
                }

                // If we haven't got the accessible symbol, it doesn't mean the symbol is actually inaccessible.
                // It could be a qualified symbol and hence verify the path
                // e.g.:
                // module m {
                //     export class c {
                //     }
                // }
                // const x: typeof m.c
                // In the above example when we start with checking if typeof m.c symbol is accessible,
                // we are going to see if c can be accessed in scope directly.
                // But it can't, hence the accessible is going to be undefined, but that doesn't mean m.c is inaccessible
                // It is accessible if the parent m is accessible because then m.c can be accessed through qualification

                let containers = getContainersOfSymbol(
                    symbol,
                    enclosingDeclaration
                );
                // If we're trying to reference some object literal in, eg `var a = { x: 1 }`, the symbol for the literal, `__object`, is distinct
                // from the symbol of the declaration it is being assigned to. Since we can use the declaration to refer to the literal, however,
                // we'd like to make that connection here - potentially causing us to paint the declaration's visibility, and therefore the literal.
                const firstDecl: Node = first(symbol.declarations);
                if (!length(containers) && meaning & SymbolFlags.Value
                    && firstDecl && isObjectLiteralExpression(firstDecl))
                {
                    if (firstDecl.parent
                        && isVariableDeclaration(firstDecl.parent)
                        && firstDecl === firstDecl.parent.initializer)
                    {
                        containers = [getSymbolOfNode(firstDecl.parent)];
                    }
                }
                const parentResult = isAnySymbolAccessible(
                    containers,
                    enclosingDeclaration,
                    initialSymbol,
                    initialSymbol === symbol
                        ? getQualifiedLeftMeaning(meaning)
                        : meaning,
                    shouldComputeAliasesToMakeVisible
                );
                if (parentResult) {
                    return parentResult;
                }
            }

            if (hadAccessibleChain) {
                return {
                    accessibility: SymbolAccessibility.NotAccessible,
                    errorSymbolName: symbolToString(
                        initialSymbol,
                        enclosingDeclaration,
                        meaning
                    ),
                    errorModuleName: hadAccessibleChain !== initialSymbol
                        ? symbolToString(
                            hadAccessibleChain,
                            enclosingDeclaration,
                            SymbolFlags.Namespace
                        )
                        : undefined
                };
            }
        }

        /**
         * Check if the given symbol in given enclosing declaration is accessible and mark all associated alias to be visible if requested
         *
         * @param symbol a Symbol to check if accessible
         * @param enclosingDeclaration a Node containing reference to the symbol
         * @param meaning a SymbolFlags to check if such meaning of the symbol is accessible
         * @param shouldComputeAliasToMakeVisible a boolean value to indicate whether to return aliases to be mark visible in case the symbol is accessible
         */
        function isSymbolAccessible(
            symbol: Symbol | undefined,
            enclosingDeclaration: Node | undefined,
            meaning: SymbolFlags,
            shouldComputeAliasesToMakeVisible: boolean
        ): SymbolAccessibilityResult {
            if (symbol && enclosingDeclaration) {
                const result = isAnySymbolAccessible(
                    [symbol],
                    enclosingDeclaration,
                    symbol,
                    meaning,
                    shouldComputeAliasesToMakeVisible
                );
                if (result) {
                    return result;
                }

                // This could be a symbol that is not exported in the external module
                // or it could be a symbol from different external module that is not aliased and hence cannot be named
                const symbolExternalModule = forEach(
                    symbol.declarations,
                    getExternalModuleContainer
                );
                if (symbolExternalModule) {
                    const enclosingExternalModule = getExternalModuleContainer(enclosingDeclaration);
                    if (symbolExternalModule !== enclosingExternalModule) {
                        // name from different external module that is not visible
                        return {
                            accessibility: SymbolAccessibility.CannotBeNamed,
                            errorSymbolName: symbolToString(
                                symbol,
                                enclosingDeclaration,
                                meaning
                            ),
                            errorModuleName:
                                symbolToString(symbolExternalModule)
                        };
                    }
                }

                // Just a local name that is not accessible
                return {
                    accessibility: SymbolAccessibility.NotAccessible,
                    errorSymbolName: symbolToString(
                        symbol,
                        enclosingDeclaration,
                        meaning
                    )
                };
            }

            return { accessibility: SymbolAccessibility.Accessible };
        }

        function getExternalModuleContainer(declaration: Node) {
            const node = findAncestor(declaration, hasExternalModuleSymbol);
            return node && getSymbolOfNode(node);
        }

        function hasExternalModuleSymbol(declaration: Node) {
            return isAmbientModule(declaration)
                || (declaration.kind === SyntaxKind.SourceFile
                    && isExternalOrCommonJsModule(<SourceFile> declaration));
        }

        function hasNonGlobalAugmentationExternalModuleSymbol(
            declaration: Node
        ) {
            return isModuleWithStringLiteralName(declaration)
                || (declaration.kind === SyntaxKind.SourceFile
                    && isExternalOrCommonJsModule(<SourceFile> declaration));
        }

        function hasVisibleDeclarations(
            symbol: Symbol,
            shouldComputeAliasToMakeVisible: boolean
        ): SymbolVisibilityResult | undefined {
            let aliasesToMakeVisible: LateVisibilityPaintedStatement[]
                | undefined;
            if (!every(
                filter(
                    symbol.declarations,
                    d => d.kind !== SyntaxKind.Identifier
                ),
                getIsDeclarationVisible
            )) {
                return undefined;
            }
            return { accessibility: SymbolAccessibility.Accessible,
                aliasesToMakeVisible };

            function getIsDeclarationVisible(declaration: Declaration) {
                if (!isDeclarationVisible(declaration)) {
                    // Mark the unexported alias as visible if its parent is visible
                    // because these kind of aliases can be used to name types in declaration file

                    const anyImportSyntax = getAnyImportSyntax(declaration);
                    if (anyImportSyntax
                        && !hasModifier(anyImportSyntax,
                            ModifierFlags
                                .Export) // import clause without export
                        && isDeclarationVisible(anyImportSyntax.parent))
                    {
                        return addVisibleAlias(declaration, anyImportSyntax);
                    } else if (isVariableDeclaration(declaration)
                        && isVariableStatement(declaration.parent.parent)
                        && !hasModifier(
                            declaration.parent.parent,
                            ModifierFlags.Export
                        ) // unexported variable statement
                        && isDeclarationVisible(
                            declaration.parent.parent.parent
                        ))
                    {
                        return addVisibleAlias(
                            declaration,
                            declaration.parent.parent
                        );
                    } else if (isLateVisibilityPaintedStatement(declaration) // unexported top-level statement
                        && !hasModifier(declaration, ModifierFlags.Export)
                        && isDeclarationVisible(declaration.parent))
                    {
                        return addVisibleAlias(declaration, declaration);
                    }

                    // Declaration is not visible
                    return false;
                }

                return true;
            }

            function addVisibleAlias(
                declaration: Declaration,
                aliasingStatement: LateVisibilityPaintedStatement
            ) {
                // In function "buildTypeDisplay" where we decide whether to write type-alias or serialize types,
                // we want to just check if type- alias is accessible or not but we don't care about emitting those alias at that time
                // since we will do the emitting later in trackSymbol.
                if (shouldComputeAliasToMakeVisible) {
                    getNodeLinks(declaration).isVisible = true;
                    aliasesToMakeVisible = appendIfUnique(
                        aliasesToMakeVisible,
                        aliasingStatement
                    );
                }
                return true;
            }
        }

        function isEntityNameVisible(
            entityName: EntityNameOrEntityNameExpression,
            enclosingDeclaration: Node
        ): SymbolVisibilityResult {
            // get symbol of the first identifier of the entityName
            let meaning: SymbolFlags;
            if (entityName.parent.kind === SyntaxKind.TypeQuery
                || isExpressionWithTypeArgumentsInClassExtendsClause(
                    entityName.parent
                )
                || entityName.parent.kind === SyntaxKind.ComputedPropertyName)
            {
                // Typeof value
                meaning = SymbolFlags.Value | SymbolFlags.ExportValue;
            } else if (entityName.kind === SyntaxKind.QualifiedName
                || entityName.kind === SyntaxKind.PropertyAccessExpression
                || entityName.parent.kind
                === SyntaxKind.ImportEqualsDeclaration)
            {
                // Left identifier from type reference or TypeAlias
                // Entity name of the import declaration
                meaning = SymbolFlags.Namespace;
            } else {
                // Type Reference or TypeAlias entity = Identifier
                meaning = SymbolFlags.Type;
            }

            const firstIdentifier = getFirstIdentifier(entityName);
            const symbol = resolveName(
                enclosingDeclaration,
                firstIdentifier.escapedText,
                meaning, /*nodeNotFoundErrorMessage*/
                undefined, /*nameArg*/
                undefined, /*isUse*/
                false
            );

            // Verify if the symbol is accessible
            return (symbol
                && hasVisibleDeclarations(
                    symbol, /*shouldComputeAliasToMakeVisible*/
                    true
                )) || {
                accessibility: SymbolAccessibility.NotAccessible,
                errorSymbolName: getTextOfNode(firstIdentifier),
                errorNode: firstIdentifier
            };
        }

        function symbolToString(
            symbol: Symbol,
            enclosingDeclaration?: Node,
            meaning?: SymbolFlags,
            flags: SymbolFormatFlags = SymbolFormatFlags.AllowAnyNodeKind,
            writer?: EmitTextWriter
        ): string {
            let nodeFlags = NodeBuilderFlags.IgnoreErrors;
            if (flags & SymbolFormatFlags.UseOnlyExternalAliasing) {
                nodeFlags |= NodeBuilderFlags.UseOnlyExternalAliasing;
            }
            if (flags & SymbolFormatFlags.WriteTypeParametersOrArguments) {
                nodeFlags |= NodeBuilderFlags
                    .WriteTypeParametersInQualifiedName;
            }
            if (flags & SymbolFormatFlags.UseAliasDefinedOutsideCurrentScope) {
                nodeFlags |= NodeBuilderFlags
                    .UseAliasDefinedOutsideCurrentScope;
            }
            if (flags & SymbolFormatFlags.DoNotIncludeSymbolChain) {
                nodeFlags |= NodeBuilderFlags.DoNotIncludeSymbolChain;
            }
            const builder = flags & SymbolFormatFlags.AllowAnyNodeKind
                ? nodeBuilder.symbolToExpression
                : nodeBuilder.symbolToEntityName;
            return writer
                ? symbolToStringWorker(writer).getText()
                : usingSingleLineStringWriter(symbolToStringWorker);

            function symbolToStringWorker(writer: EmitTextWriter) {
                const entity = builder(
                    symbol,
                    meaning!,
                    enclosingDeclaration,
                    nodeFlags
                )!; // TODO: GH#18217
                const printer = createPrinter({ removeComments: true });
                const sourceFile = enclosingDeclaration
                    && getSourceFileOfNode(enclosingDeclaration);
                printer.writeNode(
                    EmitHint.Unspecified,
                    entity, /*sourceFile*/
                    sourceFile,
                    writer
                );
                return writer;
            }
        }

        function signatureToString(
            signature: Signature,
            enclosingDeclaration?: Node,
            flags = TypeFormatFlags.None,
            kind?: SignatureKind,
            writer?: EmitTextWriter
        ): string {
            return writer
                ? signatureToStringWorker(writer).getText()
                : usingSingleLineStringWriter(signatureToStringWorker);

            function signatureToStringWorker(writer: EmitTextWriter) {
                let sigOutput: SyntaxKind;
                if (flags & TypeFormatFlags.WriteArrowStyleSignature) {
                    sigOutput = kind === SignatureKind.Construct
                        ? SyntaxKind.ConstructorType
                        : SyntaxKind.FunctionType;
                } else {
                    sigOutput = kind === SignatureKind.Construct
                        ? SyntaxKind.ConstructSignature
                        : SyntaxKind.CallSignature;
                }
                const sig = nodeBuilder
                    .signatureToSignatureDeclaration(
                        signature,
                        sigOutput,
                        enclosingDeclaration,
                        toNodeBuilderFlags(flags)
                            | NodeBuilderFlags.IgnoreErrors
                            | NodeBuilderFlags
                                .WriteTypeParametersInQualifiedName
                    );
                const printer = createPrinter(
                    { removeComments: true, omitTrailingSemicolon: true }
                );
                const sourceFile = enclosingDeclaration
                    && getSourceFileOfNode(enclosingDeclaration);
                printer.writeNode(
                    EmitHint.Unspecified,
                    sig!, /*sourceFile*/
                    sourceFile,
                    getTrailingSemicolonDeferringWriter(writer)
                ); // TODO: GH#18217
                return writer;
            }
        }

        function typeToString(
            type: Type,
            enclosingDeclaration?: Node,
            flags: TypeFormatFlags
                = TypeFormatFlags.AllowUniqueESSymbolType
                    | TypeFormatFlags.UseAliasDefinedOutsideCurrentScope,
            writer: EmitTextWriter = createTextWriter('')
        ): string {
            const noTruncation = compilerOptions.noErrorTruncation
                || flags & TypeFormatFlags.NoTruncation;
            const typeNode = nodeBuilder.typeToTypeNode(
                type,
                enclosingDeclaration,
                toNodeBuilderFlags(flags) | NodeBuilderFlags.IgnoreErrors
                    | (noTruncation ? NodeBuilderFlags.NoTruncation : 0),
                writer
            );
            if (typeNode === undefined) {
                return Debug.fail('should always get typenode');
            }
            const options = { removeComments: true };
            const printer = createPrinter(options);
            const sourceFile = enclosingDeclaration
                && getSourceFileOfNode(enclosingDeclaration);
            printer.writeNode(
                EmitHint.Unspecified,
                typeNode, /*sourceFile*/
                sourceFile,
                writer
            );
            const result = writer.getText();

            const maxLength = noTruncation
                ? undefined
                : defaultMaximumTruncationLength * 2;
            if (maxLength && result && result.length >= maxLength) {
                return result.substr(0, maxLength - '...'.length) + '...';
            }
            return result;
        }

        function getTypeNamesForErrorDisplay(
            left: Type,
            right: Type
        ): [string, string] {
            let leftStr = symbolValueDeclarationIsContextSensitive(left.symbol)
                ? typeToString(left, left.symbol.valueDeclaration)
                : typeToString(left);
            let rightStr = symbolValueDeclarationIsContextSensitive(
                right.symbol
            )
                ? typeToString(right, right.symbol.valueDeclaration)
                : typeToString(right);
            if (leftStr === rightStr) {
                leftStr = typeToString(
                    left, /*enclosingDeclaration*/
                    undefined,
                    TypeFormatFlags.UseFullyQualifiedType
                );
                rightStr = typeToString(
                    right, /*enclosingDeclaration*/
                    undefined,
                    TypeFormatFlags.UseFullyQualifiedType
                );
            }
            return [leftStr, rightStr];
        }

        function symbolValueDeclarationIsContextSensitive(
            symbol: Symbol
        ): boolean {
            return symbol && symbol.valueDeclaration
                && isExpression(symbol.valueDeclaration)
                && !isContextSensitive(symbol.valueDeclaration);
        }

        function toNodeBuilderFlags(
            flags = TypeFormatFlags.None
        ): NodeBuilderFlags {
            return flags & TypeFormatFlags.NodeBuilderFlagsMask;
        }

        function createNodeBuilder() {
            return {
                typeToTypeNode: (
                    type: Type,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => typeToTypeNodeHelper(type, context)
                ),
                indexInfoToIndexSignatureDeclaration: (
                    indexInfo: IndexInfo,
                    kind: IndexKind,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => indexInfoToIndexSignatureDeclarationHelper(
                        indexInfo,
                        kind,
                        context
                    )
                ),
                signatureToSignatureDeclaration: (
                    signature: Signature,
                    kind: SyntaxKind,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => signatureToSignatureDeclarationHelper(
                        signature,
                        kind,
                        context
                    )
                ),
                symbolToEntityName: (
                    symbol: Symbol,
                    meaning: SymbolFlags,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => symbolToName(
                        symbol,
                        context,
                        meaning, /*expectsIdentifier*/
                        false
                    )
                ),
                symbolToExpression: (
                    symbol: Symbol,
                    meaning: SymbolFlags,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => symbolToExpression(symbol, context, meaning)
                ),
                symbolToTypeParameterDeclarations: (
                    symbol: Symbol,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => typeParametersToTypeParameterDeclarations(symbol,
                        context)
                ),
                symbolToParameterDeclaration: (
                    symbol: Symbol,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => symbolToParameterDeclaration(symbol, context)
                ),
                typeParameterToDeclaration: (
                    parameter: TypeParameter,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => typeParameterToDeclaration(parameter, context)
                ),
                symbolTableToDeclarationStatements: (
                    symbolTable: SymbolTable,
                    enclosingDeclaration?: Node,
                    flags?: NodeBuilderFlags,
                    tracker?: SymbolTracker,
                    bundled?: boolean
                ) => withContext(
                    enclosingDeclaration,
                    flags,
                    tracker,
                    context => symbolTableToDeclarationStatements(
                        symbolTable,
                        context,
                        bundled
                    )
                )
            };

            function withContext<T>(
                enclosingDeclaration: Node | undefined,
                flags: NodeBuilderFlags | undefined,
                tracker: SymbolTracker | undefined,
                cb: (context: NodeBuilderContext) => T
            ): T | undefined {
                Debug
                    .assert(
                        enclosingDeclaration === undefined
                            || (enclosingDeclaration.flags
                                & NodeFlags.Synthesized) === 0
                    );
                const context: NodeBuilderContext = {
                    enclosingDeclaration,
                    flags: flags || NodeBuilderFlags.None,
                    // If no full tracker is provided, fake up a dummy one with a basic limited-functionality moduleResolverHost
                    tracker: tracker && tracker.trackSymbol
                        ? tracker
                        : { trackSymbol: noop,
                            moduleResolverHost:
                                flags!
                                    & NodeBuilderFlags.DoNotIncludeSymbolChain
                                    ? {
                                        getCommonSourceDirectory:
                                            (host as Program)
                                                .getCommonSourceDirectory
                                                ? () => (host as Program)
                                                    .getCommonSourceDirectory()
                                                : () => '',
                                        getSourceFiles: () => host
                                            .getSourceFiles(),
                                        getCurrentDirectory: maybeBind(
                                            host,
                                            host.getCurrentDirectory
                                        ),
                                        getProbableSymlinks: maybeBind(
                                            host,
                                            host.getProbableSymlinks
                                        )
                                    }
                                    : undefined },
                    encounteredError: false,
                    visitedTypes: undefined,
                    symbolDepth: undefined,
                    inferTypeParameters: undefined,
                    approximateLength: 0
                };
                const resultingNode = cb(context);
                return context.encounteredError ? undefined : resultingNode;
            }

            function checkTruncationLength(
                context: NodeBuilderContext
            ): boolean {
                if (context.truncating) return context.truncating;
                return context
                    .truncating = !(context.flags
                        & NodeBuilderFlags.NoTruncation)
                        && context.approximateLength
                        > defaultMaximumTruncationLength;
            }

            function typeToTypeNodeHelper(
                type: Type,
                context: NodeBuilderContext
            ): TypeNode {
                if (cancellationToken
                    && cancellationToken.throwIfCancellationRequested)
                {
                    cancellationToken.throwIfCancellationRequested();
                }
                const inTypeAlias = context.flags
                    & NodeBuilderFlags.InTypeAlias;
                context.flags &= ~NodeBuilderFlags.InTypeAlias;

                if (!type) {
                    context.encounteredError = true;
                    return undefined!; // TODO: GH#18217
                }

                if (type.flags & TypeFlags.Any) {
                    context.approximateLength += 3;
                    return createKeywordTypeNode(SyntaxKind.AnyKeyword);
                }
                if (type.flags & TypeFlags.Unknown) {
                    return createKeywordTypeNode(SyntaxKind.UnknownKeyword);
                }
                if (type.flags & TypeFlags.String) {
                    context.approximateLength += 6;
                    return createKeywordTypeNode(SyntaxKind.StringKeyword);
                }
                if (type.flags & TypeFlags.Number) {
                    context.approximateLength += 6;
                    return createKeywordTypeNode(SyntaxKind.NumberKeyword);
                }
                if (type.flags & TypeFlags.BigInt) {
                    context.approximateLength += 6;
                    return createKeywordTypeNode(SyntaxKind.BigIntKeyword);
                }
                if (type.flags & TypeFlags.Boolean) {
                    context.approximateLength += 7;
                    return createKeywordTypeNode(SyntaxKind.BooleanKeyword);
                }
                if (type.flags & TypeFlags.EnumLiteral
                    && !(type.flags & TypeFlags.Union))
                {
                    const parentSymbol = getParentOfSymbol(type.symbol)!;
                    const parentName = symbolToTypeNode(
                        parentSymbol,
                        context,
                        SymbolFlags.Type
                    );
                    const enumLiteralName = getDeclaredTypeOfSymbol(parentSymbol)
                        === type
                        ? parentName
                        : appendReferenceToType(
                            parentName as TypeReferenceNode | ImportTypeNode,
                            createTypeReferenceNode(
                                symbolName(type.symbol), /*typeArguments*/
                                undefined
                            )
                        );
                    return enumLiteralName;
                }
                if (type.flags & TypeFlags.EnumLike) {
                    return symbolToTypeNode(
                        type.symbol,
                        context,
                        SymbolFlags.Type
                    );
                }
                if (type.flags & TypeFlags.StringLiteral) {
                    context
                        .approximateLength += ((<StringLiteralType> type).value
                            .length + 2);
                    return createLiteralTypeNode(
                        setEmitFlags(
                            createLiteral(
                                (<StringLiteralType> type).value
                            ),
                            EmitFlags.NoAsciiEscaping
                        )
                    );
                }
                if (type.flags & TypeFlags.NumberLiteral) {
                    const value = (<NumberLiteralType> type).value;
                    context.approximateLength += ('' + value).length;
                    return createLiteralTypeNode(
                        value < 0
                            ? createPrefix(
                                SyntaxKind.MinusToken,
                                createLiteral(-value)
                            )
                            : createLiteral(value)
                    );
                }
                if (type.flags & TypeFlags.BigIntLiteral) {
                    context
                        .approximateLength += (pseudoBigIntToString(
                            (<BigIntLiteralType> type).value
                        ).length) + 1;
                    return createLiteralTypeNode(
                        (createLiteral(
                            (<BigIntLiteralType> type).value
                        ))
                    );
                }
                if (type.flags & TypeFlags.BooleanLiteral) {
                    context.approximateLength += (<IntrinsicType> type)
                        .intrinsicName.length;
                    return (<IntrinsicType> type).intrinsicName === 'true'
                        ? createTrue()
                        : createFalse();
                }
                if (type.flags & TypeFlags.UniqueESSymbol) {
                    if (!(context.flags
                        & NodeBuilderFlags.AllowUniqueESSymbolType))
                    {
                        if (isValueSymbolAccessible(
                            type.symbol,
                            context.enclosingDeclaration
                        )) {
                            context.approximateLength += 6;
                            return symbolToTypeNode(
                                type.symbol,
                                context,
                                SymbolFlags.Value
                            );
                        }
                        if (context.tracker
                            .reportInaccessibleUniqueSymbolError)
                        {
                            context.tracker
                                .reportInaccessibleUniqueSymbolError();
                        }
                    }
                    context.approximateLength += 13;
                    return createTypeOperatorNode(
                        SyntaxKind.UniqueKeyword,
                        createKeywordTypeNode(SyntaxKind.SymbolKeyword)
                    );
                }
                if (type.flags & TypeFlags.Void) {
                    context.approximateLength += 4;
                    return createKeywordTypeNode(SyntaxKind.VoidKeyword);
                }
                if (type.flags & TypeFlags.Undefined) {
                    context.approximateLength += 9;
                    return createKeywordTypeNode(SyntaxKind.UndefinedKeyword);
                }
                if (type.flags & TypeFlags.Null) {
                    context.approximateLength += 4;
                    return createKeywordTypeNode(SyntaxKind.NullKeyword);
                }
                if (type.flags & TypeFlags.Never) {
                    context.approximateLength += 5;
                    return createKeywordTypeNode(SyntaxKind.NeverKeyword);
                }
                if (type.flags & TypeFlags.ESSymbol) {
                    context.approximateLength += 6;
                    return createKeywordTypeNode(SyntaxKind.SymbolKeyword);
                }
                if (type.flags & TypeFlags.NonPrimitive) {
                    context.approximateLength += 6;
                    return createKeywordTypeNode(SyntaxKind.ObjectKeyword);
                }
                if (isThisTypeParameter(type)) {
                    if (context.flags & NodeBuilderFlags.InObjectTypeLiteral) {
                        if (!context.encounteredError
                            && !(context.flags
                                & NodeBuilderFlags.AllowThisInObjectLiteral))
                        {
                            context.encounteredError = true;
                        }
                        if (context.tracker.reportInaccessibleThisError) {
                            context.tracker.reportInaccessibleThisError();
                        }
                    }
                    context.approximateLength += 4;
                    return createThis();
                }

                if (!inTypeAlias && type.aliasSymbol
                    && (context.flags
                        & NodeBuilderFlags.UseAliasDefinedOutsideCurrentScope
                        || isTypeSymbolAccessible(
                            type.aliasSymbol,
                            context.enclosingDeclaration
                        )))
                {
                    const typeArgumentNodes = mapToTypeNodes(
                        type.aliasTypeArguments,
                        context
                    );
                    if (isReservedMemberName(type.aliasSymbol.escapedName)
                        && !(type.aliasSymbol.flags & SymbolFlags.Class))
                    {
                        return createTypeReferenceNode(
                            createIdentifier(''),
                            typeArgumentNodes
                        );
                    }
                    return symbolToTypeNode(
                        type.aliasSymbol,
                        context,
                        SymbolFlags.Type,
                        typeArgumentNodes
                    );
                }

                const objectFlags = getObjectFlags(type);

                if (objectFlags & ObjectFlags.Reference) {
                    Debug.assert(!!(type.flags & TypeFlags.Object));
                    return (<TypeReference> type).node
                        ? visitAndTransformType(type, typeReferenceToTypeNode)
                        : typeReferenceToTypeNode(<TypeReference> type);
                }
                if (type.flags & TypeFlags.TypeParameter
                    || objectFlags & ObjectFlags.ClassOrInterface)
                {
                    if (type.flags & TypeFlags.TypeParameter
                        && contains(context.inferTypeParameters, type))
                    {
                        context
                            .approximateLength += (symbolName(type.symbol)
                                .length + 6);
                        return createInferTypeNode(
                            typeParameterToDeclarationWithConstraint(
                                type as TypeParameter,
                                context, /*constraintNode*/
                                undefined
                            )
                        );
                    }
                    if (context.flags
                        & NodeBuilderFlags.GenerateNamesForShadowedTypeParams
                        && type.flags & TypeFlags.TypeParameter
                        && !isTypeSymbolAccessible(
                            type.symbol,
                            context.enclosingDeclaration
                        ))
                    {
                        const name = typeParameterToName(type, context);
                        context.approximateLength += idText(name).length;
                        return createTypeReferenceNode(
                            createIdentifier(idText(name)), /*typeArguments*/
                            undefined
                        );
                    }
                    // Ignore constraint/default when creating a usage (as opposed to declaration) of a type parameter.
                    return type.symbol
                        ? symbolToTypeNode(
                            type.symbol,
                            context,
                            SymbolFlags.Type
                        )
                        : createTypeReferenceNode(
                            createIdentifier('?'), /*typeArguments*/
                            undefined
                        );
                }
                if (type.flags & (TypeFlags.Union | TypeFlags.Intersection)) {
                    const types = type.flags & TypeFlags.Union
                        ? formatUnionTypes((<UnionType> type).types)
                        : (<IntersectionType> type).types;
                    if (length(types) === 1) {
                        return typeToTypeNodeHelper(types[0], context);
                    }
                    const typeNodes = mapToTypeNodes(
                        types,
                        context, /*isBareList*/
                        true
                    );
                    if (typeNodes && typeNodes.length > 0) {
                        const unionOrIntersectionTypeNode = createUnionOrIntersectionTypeNode(
                            type.flags & TypeFlags.Union
                                ? SyntaxKind.UnionType
                                : SyntaxKind.IntersectionType,
                            typeNodes
                        );
                        return unionOrIntersectionTypeNode;
                    } else {
                        if (!context.encounteredError
                            && !(context.flags
                                & NodeBuilderFlags
                                    .AllowEmptyUnionOrIntersection))
                        {
                            context.encounteredError = true;
                        }
                        return undefined!; // TODO: GH#18217
                    }
                }
                if (objectFlags
                    & (ObjectFlags.Anonymous | ObjectFlags.Mapped))
                {
                    Debug.assert(!!(type.flags & TypeFlags.Object));
                    // The type is an object literal type.
                    return createAnonymousTypeNode(<ObjectType> type);
                }
                if (type.flags & TypeFlags.Index) {
                    const indexedType = (<IndexType> type).type;
                    context.approximateLength += 6;
                    const indexTypeNode = typeToTypeNodeHelper(
                        indexedType,
                        context
                    );
                    return createTypeOperatorNode(indexTypeNode);
                }
                if (type.flags & TypeFlags.IndexedAccess) {
                    const objectTypeNode = typeToTypeNodeHelper(
                        (<IndexedAccessType> type).objectType,
                        context
                    );
                    const indexTypeNode = typeToTypeNodeHelper(
                        (<IndexedAccessType> type).indexType,
                        context
                    );
                    context.approximateLength += 2;
                    return createIndexedAccessTypeNode(
                        objectTypeNode,
                        indexTypeNode
                    );
                }
                if (type.flags & TypeFlags.Conditional) {
                    const checkTypeNode = typeToTypeNodeHelper(
                        (<ConditionalType> type).checkType,
                        context
                    );
                    const saveInferTypeParameters = context
                        .inferTypeParameters;
                    context.inferTypeParameters = (<ConditionalType> type).root
                        .inferTypeParameters;
                    const extendsTypeNode = typeToTypeNodeHelper(
                        (<ConditionalType> type).extendsType,
                        context
                    );
                    context.inferTypeParameters = saveInferTypeParameters;
                    const trueTypeNode = typeToTypeNodeHelper(
                        getTrueTypeFromConditionalType(<ConditionalType> type),
                        context
                    );
                    const falseTypeNode = typeToTypeNodeHelper(
                        getFalseTypeFromConditionalType(<ConditionalType> type),
                        context
                    );
                    context.approximateLength += 15;
                    return createConditionalTypeNode(
                        checkTypeNode,
                        extendsTypeNode,
                        trueTypeNode,
                        falseTypeNode
                    );
                }
                if (type.flags & TypeFlags.Substitution) {
                    return typeToTypeNodeHelper(
                        (<SubstitutionType> type).typeVariable,
                        context
                    );
                }

                return Debug.fail('Should be unreachable.');

                function createMappedTypeNodeFromType(type: MappedType) {
                    Debug.assert(!!(type.flags & TypeFlags.Object));
                    const readonlyToken = type.declaration.readonlyToken
                        ? <ReadonlyToken | PlusToken | MinusToken> createToken(
                            type.declaration.readonlyToken.kind
                        )
                        : undefined;
                    const questionToken = type.declaration.questionToken
                        ? <QuestionToken | PlusToken | MinusToken> createToken(
                            type.declaration.questionToken.kind
                        )
                        : undefined;
                    let appropriateConstraintTypeNode: TypeNode;
                    if (isMappedTypeWithKeyofConstraintDeclaration(type)) {
                        // We have a { [P in keyof T]: X }
                        // We do this to ensure we retain the toplevel keyof-ness of the type which may be lost due to keyof distribution during `getConstraintTypeFromMappedType`
                        appropriateConstraintTypeNode = createTypeOperatorNode(
                            typeToTypeNodeHelper(
                                getModifiersTypeFromMappedType(type),
                                context
                            )
                        );
                    } else {
                        appropriateConstraintTypeNode = typeToTypeNodeHelper(
                            getConstraintTypeFromMappedType(type),
                            context
                        );
                    }
                    const typeParameterNode = typeParameterToDeclarationWithConstraint(
                        getTypeParameterFromMappedType(type),
                        context,
                        appropriateConstraintTypeNode
                    );
                    const templateTypeNode = typeToTypeNodeHelper(
                        getTemplateTypeFromMappedType(type),
                        context
                    );
                    const mappedTypeNode = createMappedTypeNode(
                        readonlyToken,
                        typeParameterNode,
                        questionToken,
                        templateTypeNode
                    );
                    context.approximateLength += 10;
                    return setEmitFlags(mappedTypeNode, EmitFlags.SingleLine);
                }

                function createAnonymousTypeNode(type: ObjectType): TypeNode {
                    const typeId = '' + type.id;
                    const symbol = type.symbol;
                    if (symbol) {
                        if (isJSConstructor(symbol.valueDeclaration)) {
                            // Instance and static types share the same symbol; only add 'typeof' for the static side.
                            const isInstanceType = type
                                === getDeclaredTypeOfClassOrInterface(symbol)
                                ? SymbolFlags.Type
                                : SymbolFlags.Value;
                            return symbolToTypeNode(
                                symbol,
                                context,
                                isInstanceType
                            );
                        } // Always use 'typeof T' for type of class, enum, and module objects
                        else if (symbol.flags & SymbolFlags.Class
                            && !getBaseTypeVariableOfClass(symbol)
                            && !(symbol.valueDeclaration.kind
                                === SyntaxKind.ClassExpression
                                && context.flags
                                & NodeBuilderFlags
                                    .WriteClassExpressionAsTypeLiteral)
                            || symbol.flags
                            & (SymbolFlags.Enum | SymbolFlags.ValueModule)
                            || shouldWriteTypeOfFunctionSymbol())
                        {
                            return symbolToTypeNode(
                                symbol,
                                context,
                                SymbolFlags.Value
                            );
                        } else if (context.visitedTypes
                            && context.visitedTypes.has(typeId))
                        {
                            // If type is an anonymous type literal in a type alias declaration, use type alias name
                            const typeAlias = getTypeAliasForTypeLiteral(type);
                            if (typeAlias) {
                                // The specified symbol flags need to be reinterpreted as type flags
                                return symbolToTypeNode(
                                    typeAlias,
                                    context,
                                    SymbolFlags.Type
                                );
                            } else {
                                return createElidedInformationPlaceholder(context);
                            }
                        } else {
                            return visitAndTransformType(
                                type,
                                createTypeNodeFromObjectType
                            );
                        }
                    } else {
                        // Anonymous types without a symbol are never circular.
                        return createTypeNodeFromObjectType(type);
                    }
                    function shouldWriteTypeOfFunctionSymbol() {
                        const isStaticMethodSymbol = !!(symbol.flags
                            & SymbolFlags.Method) // typeof static method
                            && some(
                                symbol.declarations,
                                declaration => hasModifier(
                                    declaration,
                                    ModifierFlags.Static
                                )
                            );
                        const isNonLocalFunctionSymbol = !!(symbol.flags
                            & SymbolFlags.Function)
                            && (symbol.parent // is exported function symbol
                                || forEach(
                                    symbol.declarations,
                                    declaration => declaration.parent.kind
                                        === SyntaxKind.SourceFile
                                        || declaration.parent.kind
                                        === SyntaxKind.ModuleBlock
                                ));
                        if (isStaticMethodSymbol || isNonLocalFunctionSymbol) {
                            // typeof is allowed only for static/non local functions
                            return (!!(context.flags
                                & NodeBuilderFlags.UseTypeOfFunction)
                                || (context.visitedTypes
                                    && context.visitedTypes
                                        .has(typeId))) // it is type of the symbol uses itself recursively
                                && (!(context.flags
                                    & NodeBuilderFlags.UseStructuralFallback)
                                    || isValueSymbolAccessible(
                                        symbol,
                                        context.enclosingDeclaration
                                    )); // And the build is going to succeed without visibility error or there is no structural fallback allowed
                        }
                    }
                }

                function visitAndTransformType<T>(
                    type: Type,
                    transform: (type: Type) => T
                ) {
                    const typeId = '' + type.id;
                    const isConstructorObject = getObjectFlags(type)
                        & ObjectFlags.Anonymous && type.symbol
                        && type.symbol.flags & SymbolFlags.Class;
                    const id = getObjectFlags(type) & ObjectFlags.Reference
                        && (<TypeReference> type).node
                        ? 'N' + getNodeId((<TypeReference> type).node!)
                        : type.symbol
                            ? (isConstructorObject ? '+' : '') + getSymbolId(
                                type.symbol
                            )
                            : undefined;
                    // Since instantiations of the same anonymous type have the same symbol, tracking symbols instead
                    // of types allows us to catch circular references to instantiations of the same anonymous type
                    if (!context.visitedTypes) {
                        context.visitedTypes = createMap<true>();
                    }
                    if (id && !context.symbolDepth) {
                        context.symbolDepth = createMap<number>();
                    }

                    let depth: number | undefined;
                    if (id) {
                        depth = context.symbolDepth!.get(id) || 0;
                        if (depth > 10) {
                            return createElidedInformationPlaceholder(context);
                        }
                        context.symbolDepth!.set(id, depth + 1);
                    }
                    context.visitedTypes.set(typeId, true);
                    const result = transform(type);
                    context.visitedTypes.delete(typeId);
                    if (id) {
                        context.symbolDepth!.set(id, depth!);
                    }
                    return result;
                }

                function createTypeNodeFromObjectType(
                    type: ObjectType
                ): TypeNode {
                    if (isGenericMappedType(type)) {
                        return createMappedTypeNodeFromType(type);
                    }

                    const resolved = resolveStructuredTypeMembers(type);
                    if (!resolved.properties.length
                        && !resolved.stringIndexInfo
                        && !resolved.numberIndexInfo)
                    {
                        if (!resolved.callSignatures.length
                            && !resolved.constructSignatures.length)
                        {
                            context.approximateLength += 2;
                            return setEmitFlags(
                                createTypeLiteralNode(/*members*/ undefined),
                                EmitFlags.SingleLine
                            );
                        }

                        if (resolved.callSignatures.length === 1
                            && !resolved.constructSignatures.length)
                        {
                            const signature = resolved.callSignatures[0];
                            const signatureNode = <FunctionTypeNode> signatureToSignatureDeclarationHelper(
                                signature,
                                SyntaxKind.FunctionType,
                                context
                            );
                            return signatureNode;
                        }

                        if (resolved.constructSignatures.length === 1
                            && !resolved.callSignatures.length)
                        {
                            const signature = resolved.constructSignatures[0];
                            const signatureNode = <ConstructorTypeNode> signatureToSignatureDeclarationHelper(
                                signature,
                                SyntaxKind.ConstructorType,
                                context
                            );
                            return signatureNode;
                        }
                    }

                    const savedFlags = context.flags;
                    context.flags |= NodeBuilderFlags.InObjectTypeLiteral;
                    const members = createTypeNodesFromResolvedType(resolved);
                    context.flags = savedFlags;
                    const typeLiteralNode = createTypeLiteralNode(members);
                    context.approximateLength += 2;
                    return setEmitFlags(
                        typeLiteralNode,
                        (context.flags
                            & NodeBuilderFlags.MultilineObjectLiterals)
                            ? 0
                            : EmitFlags.SingleLine
                    );
                }

                function typeReferenceToTypeNode(type: TypeReference) {
                    const typeArguments:
                        readonly Type[] = getTypeArguments(type);
                    if (type.target === globalArrayType
                        || type.target === globalReadonlyArrayType)
                    {
                        if (context.flags
                            & NodeBuilderFlags.WriteArrayAsGenericType)
                        {
                            const typeArgumentNode = typeToTypeNodeHelper(
                                typeArguments[0],
                                context
                            );
                            return createTypeReferenceNode(
                                type.target === globalArrayType
                                    ? 'Array'
                                    : 'ReadonlyArray',
                                [typeArgumentNode]
                            );
                        }
                        const elementType = typeToTypeNodeHelper(
                            typeArguments[0],
                            context
                        );
                        const arrayType = createArrayTypeNode(elementType);
                        return type.target === globalArrayType
                            ? arrayType
                            : createTypeOperatorNode(
                                SyntaxKind.ReadonlyKeyword,
                                arrayType
                            );
                    } else if (type.target.objectFlags & ObjectFlags.Tuple) {
                        if (typeArguments.length > 0) {
                            const arity = getTypeReferenceArity(type);
                            const tupleConstituentNodes = mapToTypeNodes(
                                typeArguments.slice(0, arity),
                                context
                            );
                            const hasRestElement = (<TupleType> type.target)
                                .hasRestElement;
                            if (tupleConstituentNodes) {
                                for (let i = (<TupleType> type.target)
                                    .minLength;
                                    i
                                        < Math.min(
                                            arity,
                                            tupleConstituentNodes.length
                                        ); i++)
                                {
                                    tupleConstituentNodes
                                        [i] = hasRestElement && i === arity - 1
                                            ? createRestTypeNode(
                                                createArrayTypeNode(
                                                    tupleConstituentNodes[i]
                                                )
                                            )
                                            : createOptionalTypeNode(
                                                tupleConstituentNodes[i]
                                            );
                                }
                                const tupleTypeNode = createTupleTypeNode(tupleConstituentNodes);
                                return (<TupleType> type.target).readonly
                                    ? createTypeOperatorNode(
                                        SyntaxKind.ReadonlyKeyword,
                                        tupleTypeNode
                                    )
                                    : tupleTypeNode;
                            }
                        }
                        if (context.encounteredError
                            || (context.flags
                                & NodeBuilderFlags.AllowEmptyTuple))
                        {
                            const tupleTypeNode = createTupleTypeNode([]);
                            return (<TupleType> type.target).readonly
                                ? createTypeOperatorNode(
                                    SyntaxKind.ReadonlyKeyword,
                                    tupleTypeNode
                                )
                                : tupleTypeNode;
                        }
                        context.encounteredError = true;
                        return undefined!; // TODO: GH#18217
                    } else if (context.flags
                        & NodeBuilderFlags.WriteClassExpressionAsTypeLiteral
                        && type.symbol.valueDeclaration
                        && isClassLike(type.symbol.valueDeclaration)
                        && !isValueSymbolAccessible(
                            type.symbol,
                            context.enclosingDeclaration
                        ))
                    {
                        return createAnonymousTypeNode(type);
                    } else {
                        const outerTypeParameters = type.target
                            .outerTypeParameters;
                        let i = 0;
                        let resultType: TypeReferenceNode | ImportTypeNode
                            | undefined;
                        if (outerTypeParameters) {
                            const length = outerTypeParameters.length;
                            while (i < length) {
                                // Find group of type arguments for type parameters with the same declaring container.
                                const start = i;
                                const parent = getParentSymbolOfTypeParameter(
                                    outerTypeParameters[i]
                                )!;
                                do {
                                    i++;
                                } while (i < length
                                    && getParentSymbolOfTypeParameter(
                                        outerTypeParameters[i]
                                    ) === parent);
                                // When type parameters are their own type arguments for the whole group (i.e. we have
                                // the default outer type arguments), we don't show the group.
                                if (!rangeEquals(
                                    outerTypeParameters,
                                    typeArguments,
                                    start,
                                    i
                                )) {
                                    const typeArgumentSlice = mapToTypeNodes(
                                        typeArguments.slice(start, i),
                                        context
                                    );
                                    const flags = context.flags;
                                    context.flags |= NodeBuilderFlags
                                        .ForbidIndexedAccessSymbolReferences;
                                    const ref = symbolToTypeNode(
                                        parent,
                                        context,
                                        SymbolFlags.Type,
                                        typeArgumentSlice
                                    ) as TypeReferenceNode | ImportTypeNode;
                                    context.flags = flags;
                                    resultType = !resultType
                                        ? ref
                                        : appendReferenceToType(
                                            resultType,
                                            ref as TypeReferenceNode
                                        );
                                }
                            }
                        }
                        let typeArgumentNodes: readonly TypeNode[] | undefined;
                        if (typeArguments.length > 0) {
                            const typeParameterCount = (type.target
                                .typeParameters || emptyArray).length;
                            typeArgumentNodes = mapToTypeNodes(
                                typeArguments.slice(i, typeParameterCount),
                                context
                            );
                        }
                        const flags = context.flags;
                        context.flags |= NodeBuilderFlags
                            .ForbidIndexedAccessSymbolReferences;
                        const finalRef = symbolToTypeNode(
                            type.symbol,
                            context,
                            SymbolFlags.Type,
                            typeArgumentNodes
                        );
                        context.flags = flags;
                        return !resultType
                            ? finalRef
                            : appendReferenceToType(
                                resultType,
                                finalRef as TypeReferenceNode
                            );
                    }
                }

                function appendReferenceToType(
                    root: TypeReferenceNode | ImportTypeNode,
                    ref: TypeReferenceNode
                ): TypeReferenceNode | ImportTypeNode {
                    if (isImportTypeNode(root)) {
                        // first shift type arguments
                        const innerParams = root.typeArguments;
                        if (root.qualifier) {
                            (isIdentifier(root.qualifier)
                                ? root.qualifier
                                : root.qualifier.right)
                                .typeArguments = innerParams;
                        }
                        root.typeArguments = ref.typeArguments;
                        // then move qualifiers
                        const ids = getAccessStack(ref);
                        for (const id of ids) {
                            root.qualifier = root.qualifier
                                ? createQualifiedName(root.qualifier, id)
                                : id;
                        }
                        return root;
                    } else {
                        // first shift type arguments
                        const innerParams = root.typeArguments;
                        (isIdentifier(root.typeName)
                            ? root.typeName
                            : root.typeName.right).typeArguments = innerParams;
                        root.typeArguments = ref.typeArguments;
                        // then move qualifiers
                        const ids = getAccessStack(ref);
                        for (const id of ids) {
                            root.typeName = createQualifiedName(
                                root.typeName,
                                id
                            );
                        }
                        return root;
                    }
                }

                function getAccessStack(ref: TypeReferenceNode): Identifier[] {
                    let state = ref.typeName;
                    const ids = [];
                    while (!isIdentifier(state)) {
                        ids.unshift(state.right);
                        state = state.left;
                    }
                    ids.unshift(state);
                    return ids;
                }

                function createTypeNodesFromResolvedType(
                    resolvedType: ResolvedType
                ): TypeElement[] | undefined {
                    if (checkTruncationLength(context)) {
                        return [createPropertySignature(
                            /*modifiers*/ undefined,
                            '...', /*questionToken*/
                            undefined, /*type*/
                            undefined, /*initializer*/
                            undefined
                        )];
                    }
                    const typeElements: TypeElement[] = [];
                    for (const signature of resolvedType.callSignatures) {
                        typeElements
                            .push(
                                <CallSignatureDeclaration> signatureToSignatureDeclarationHelper(
                                    signature,
                                    SyntaxKind.CallSignature,
                                    context
                                )
                            );
                    }
                    for (const signature of resolvedType.constructSignatures) {
                        typeElements
                            .push(
                                <ConstructSignatureDeclaration> signatureToSignatureDeclarationHelper(
                                    signature,
                                    SyntaxKind.ConstructSignature,
                                    context
                                )
                            );
                    }
                    if (resolvedType.stringIndexInfo) {
                        let indexSignature: IndexSignatureDeclaration;
                        if (resolvedType.objectFlags
                            & ObjectFlags.ReverseMapped)
                        {
                            indexSignature = indexInfoToIndexSignatureDeclarationHelper(
                                createIndexInfo(
                                    anyType,
                                    resolvedType.stringIndexInfo.isReadonly,
                                    resolvedType.stringIndexInfo.declaration
                                ),
                                IndexKind.String,
                                context
                            );
                            indexSignature
                                .type = createElidedInformationPlaceholder(context);
                        } else {
                            indexSignature = indexInfoToIndexSignatureDeclarationHelper(
                                resolvedType.stringIndexInfo,
                                IndexKind.String,
                                context
                            );
                        }
                        typeElements.push(indexSignature);
                    }
                    if (resolvedType.numberIndexInfo) {
                        typeElements
                            .push(
                                indexInfoToIndexSignatureDeclarationHelper(
                                    resolvedType.numberIndexInfo,
                                    IndexKind.Number,
                                    context
                                )
                            );
                    }

                    const properties = resolvedType.properties;
                    if (!properties) {
                        return typeElements;
                    }

                    let i = 0;
                    for (const propertySymbol of properties) {
                        i++;
                        if (context.flags
                            & NodeBuilderFlags
                                .WriteClassExpressionAsTypeLiteral)
                        {
                            if (propertySymbol.flags & SymbolFlags.Prototype) {
                                continue;
                            }
                            if (getDeclarationModifierFlagsFromSymbol(propertySymbol)
                                & (ModifierFlags.Private
                                    | ModifierFlags.Protected)
                                && context.tracker
                                    .reportPrivateInBaseOfClassExpression)
                            {
                                context.tracker
                                    .reportPrivateInBaseOfClassExpression(
                                        unescapeLeadingUnderscores(
                                            propertySymbol.escapedName
                                        )
                                    );
                            }
                        }
                        if (checkTruncationLength(context)
                            && (i + 2 < properties.length - 1))
                        {
                            typeElements
                                .push(
                                    createPropertySignature(
                                        /*modifiers*/ undefined,
                                        `... ${properties.length - i
                                            } more ...`, /*questionToken*/
                                        undefined, /*type*/
                                        undefined, /*initializer*/
                                        undefined
                                    )
                                );
                            addPropertyToElementList(
                                properties[properties.length - 1],
                                context,
                                typeElements
                            );
                            break;
                        }
                        addPropertyToElementList(
                            propertySymbol,
                            context,
                            typeElements
                        );
                    }
                    return typeElements.length ? typeElements : undefined;
                }
            }

            function createElidedInformationPlaceholder(
                context: NodeBuilderContext
            ) {
                context.approximateLength += 3;
                if (!(context.flags & NodeBuilderFlags.NoTruncation)) {
                    return createTypeReferenceNode(
                        createIdentifier('...'), /*typeArguments*/
                        undefined
                    );
                }
                return createKeywordTypeNode(SyntaxKind.AnyKeyword);
            }

            function addPropertyToElementList(
                propertySymbol: Symbol,
                context: NodeBuilderContext,
                typeElements: TypeElement[]
            ) {
                const propertyIsReverseMapped = !!(getCheckFlags(propertySymbol)
                    & CheckFlags.ReverseMapped);
                const propertyType = propertyIsReverseMapped
                    && context.flags & NodeBuilderFlags.InReverseMappedType
                    ? anyType
                    : getTypeOfSymbol(propertySymbol);
                const saveEnclosingDeclaration = context.enclosingDeclaration;
                context.enclosingDeclaration = undefined;
                if (context.tracker.trackSymbol
                    && getCheckFlags(propertySymbol) & CheckFlags.Late)
                {
                    const decl = first(propertySymbol.declarations);
                    if (hasLateBindableName(decl)) {
                        if (isBinaryExpression(decl)) {
                            const name = getNameOfDeclaration(decl);
                            if (name && isElementAccessExpression(name)
                                && isPropertyAccessEntityNameExpression(
                                    name.argumentExpression
                                ))
                            {
                                trackComputedName(
                                    name.argumentExpression,
                                    saveEnclosingDeclaration,
                                    context
                                );
                            }
                        } else {
                            trackComputedName(
                                decl.name.expression,
                                saveEnclosingDeclaration,
                                context
                            );
                        }
                    }
                }
                context.enclosingDeclaration = saveEnclosingDeclaration;
                const propertyName = getPropertyNameNodeForSymbol(
                    propertySymbol,
                    context
                );
                context
                    .approximateLength += (symbolName(propertySymbol).length
                        + 1);
                const optionalToken = propertySymbol.flags
                    & SymbolFlags.Optional
                    ? createToken(SyntaxKind.QuestionToken)
                    : undefined;
                if (propertySymbol.flags
                    & (SymbolFlags.Function | SymbolFlags.Method)
                    && !getPropertiesOfObjectType(propertyType).length
                    && !isReadonlySymbol(propertySymbol))
                {
                    const signatures = getSignaturesOfType(
                        filterType(
                            propertyType,
                            t => !(t.flags & TypeFlags.Undefined)
                        ),
                        SignatureKind.Call
                    );
                    for (const signature of signatures) {
                        const methodDeclaration = <MethodSignature> signatureToSignatureDeclarationHelper(
                            signature,
                            SyntaxKind.MethodSignature,
                            context
                        );
                        methodDeclaration.name = propertyName;
                        methodDeclaration.questionToken = optionalToken;
                        typeElements
                            .push(preserveCommentsOn(methodDeclaration));
                    }
                } else {
                    const savedFlags = context.flags;
                    context.flags |= propertyIsReverseMapped
                        ? NodeBuilderFlags.InReverseMappedType
                        : 0;
                    let propertyTypeNode: TypeNode;
                    if (propertyIsReverseMapped
                        && !!(savedFlags
                            & NodeBuilderFlags.InReverseMappedType))
                    {
                        propertyTypeNode = createElidedInformationPlaceholder(context);
                    } else {
                        propertyTypeNode = propertyType
                            ? typeToTypeNodeHelper(propertyType, context)
                            : createKeywordTypeNode(SyntaxKind.AnyKeyword);
                    }
                    context.flags = savedFlags;

                    const modifiers = isReadonlySymbol(propertySymbol)
                        ? [createToken(SyntaxKind.ReadonlyKeyword)]
                        : undefined;
                    if (modifiers) {
                        context.approximateLength += 9;
                    }
                    const propertySignature = createPropertySignature(
                        modifiers,
                        propertyName,
                        optionalToken,
                        propertyTypeNode,
                        /*initializer*/ undefined
                    );

                    typeElements.push(preserveCommentsOn(propertySignature));
                }

                function preserveCommentsOn<T extends Node>(node: T) {
                    if (some(
                        propertySymbol.declarations,
                        d => d.kind === SyntaxKind.JSDocPropertyTag
                    )) {
                        const d = find(
                            propertySymbol.declarations,
                            d => d.kind === SyntaxKind.JSDocPropertyTag
                        )! as JSDocPropertyTag;
                        const commentText = d.comment;
                        if (commentText) {
                            setSyntheticLeadingComments(
                                node,
                                [{ kind: SyntaxKind.MultiLineCommentTrivia,
                                    text: '*\n * '
                                        + commentText.replace(/\n/g, '\n * ')
                                        + '\n ', pos: -1, end: -1,
                                    hasTrailingNewLine: true }]
                            );
                        }
                    } else if (propertySymbol.valueDeclaration) {
                        // Copy comments to node for declaration emit
                        setCommentRange(node, propertySymbol.valueDeclaration);
                    }
                    return node;
                }
            }

            function mapToTypeNodes(
                types: readonly Type[] | undefined,
                context: NodeBuilderContext,
                isBareList?: boolean
            ): TypeNode[] | undefined {
                if (some(types)) {
                    if (checkTruncationLength(context)) {
                        if (!isBareList) {
                            return [createTypeReferenceNode(
                                '...', /*typeArguments*/
                                undefined
                            )];
                        } else if (types.length > 2) {
                            return [
                                typeToTypeNodeHelper(types[0], context),
                                createTypeReferenceNode(
                                    `... ${types.length - 2
                                        } more ...`, /*typeArguments*/
                                    undefined
                                ),
                                typeToTypeNodeHelper(
                                    types[types.length - 1],
                                    context
                                )
                            ];
                        }
                    }
                    const result = [];
                    let i = 0;
                    for (const type of types) {
                        i++;
                        if (checkTruncationLength(context)
                            && (i + 2 < types.length - 1))
                        {
                            result
                                .push(
                                    createTypeReferenceNode(
                                        `... ${types.length - i
                                            } more ...`, /*typeArguments*/
                                        undefined
                                    )
                                );
                            const typeNode = typeToTypeNodeHelper(
                                types[types.length - 1],
                                context
                            );
                            if (typeNode) {
                                result.push(typeNode);
                            }
                            break;
                        }
                        context
                            .approximateLength += 2; // Account for whitespace + separator
                        const typeNode = typeToTypeNodeHelper(type, context);
                        if (typeNode) {
                            result.push(typeNode);
                        }
                    }

                    return result;
                }
            }

            function indexInfoToIndexSignatureDeclarationHelper(
                indexInfo: IndexInfo,
                kind: IndexKind,
                context: NodeBuilderContext
            ): IndexSignatureDeclaration {
                const name = getNameFromIndexInfo(indexInfo) || 'x';
                const indexerTypeNode = createKeywordTypeNode(
                    kind === IndexKind.String
                        ? SyntaxKind.StringKeyword
                        : SyntaxKind.NumberKeyword
                );

                const indexingParameter = createParameter(
                    /*decorators*/ undefined,
                    /*modifiers*/ undefined,
                    /*dotDotDotToken*/ undefined,
                    name,
                    /*questionToken*/ undefined,
                    indexerTypeNode,
                    /*initializer*/ undefined
                );
                const typeNode = typeToTypeNodeHelper(
                    indexInfo.type || anyType,
                    context
                );
                if (!indexInfo.type
                    && !(context.flags
                        & NodeBuilderFlags.AllowEmptyIndexInfoType))
                {
                    context.encounteredError = true;
                }
                context.approximateLength += (name.length + 4);
                return createIndexSignature(
                    /*decorators*/ undefined,
                    indexInfo.isReadonly
                        ? [createToken(SyntaxKind.ReadonlyKeyword)]
                        : undefined,
                    [indexingParameter],
                    typeNode
                );
            }

            function signatureToSignatureDeclarationHelper(
                signature: Signature,
                kind: SyntaxKind,
                context: NodeBuilderContext
            ): SignatureDeclaration {
                let typeParameters: TypeParameterDeclaration[] | undefined;
                let typeArguments: TypeNode[] | undefined;
                if (context.flags
                    & NodeBuilderFlags.WriteTypeArgumentsOfSignature
                    && signature.target && signature.mapper
                    && signature.target.typeParameters)
                {
                    typeArguments = signature.target.typeParameters
                        .map(parameter => typeToTypeNodeHelper(
                            instantiateType(
                                parameter,
                                signature.mapper
                            ),
                            context
                        ));
                } else {
                    typeParameters = signature.typeParameters
                        && signature.typeParameters
                            .map(parameter => typeParameterToDeclaration(
                                parameter,
                                context
                            ));
                }

                const parameters = getExpandedParameters(signature)
                    .map(parameter => symbolToParameterDeclaration(
                        parameter,
                        context,
                        kind === SyntaxKind.Constructor
                    ));
                if (signature.thisParameter) {
                    const thisParameter = symbolToParameterDeclaration(
                        signature.thisParameter,
                        context
                    );
                    parameters.unshift(thisParameter);
                }

                let returnTypeNode: TypeNode | undefined;
                const typePredicate = getTypePredicateOfSignature(signature);
                if (typePredicate) {
                    const assertsModifier = typePredicate.kind
                        === TypePredicateKind.AssertsThis
                        || typePredicate.kind
                        === TypePredicateKind.AssertsIdentifier
                        ? createToken(SyntaxKind.AssertsKeyword)
                        : undefined;
                    const parameterName = typePredicate.kind
                        === TypePredicateKind.Identifier
                        || typePredicate.kind
                        === TypePredicateKind.AssertsIdentifier
                        ? setEmitFlags(
                            createIdentifier(
                                typePredicate.parameterName
                            ),
                            EmitFlags.NoAsciiEscaping
                        )
                        : createThisTypeNode();
                    const typeNode = typePredicate.type
                        && typeToTypeNodeHelper(typePredicate.type, context);
                    returnTypeNode = createTypePredicateNodeWithModifier(
                        assertsModifier,
                        parameterName,
                        typeNode
                    );
                } else {
                    const returnType = getReturnTypeOfSignature(signature);
                    returnTypeNode = returnType
                        && typeToTypeNodeHelper(returnType, context);
                }
                if (context.flags & NodeBuilderFlags.SuppressAnyReturnType) {
                    if (returnTypeNode
                        && returnTypeNode.kind === SyntaxKind.AnyKeyword)
                    {
                        returnTypeNode = undefined;
                    }
                } else if (!returnTypeNode) {
                    returnTypeNode = createKeywordTypeNode(
                        SyntaxKind.AnyKeyword
                    );
                }
                context
                    .approximateLength += 3; // Usually a signature contributes a few more characters than this, but 3 is the minimum
                return createSignatureDeclaration(
                    kind,
                    typeParameters,
                    parameters,
                    returnTypeNode,
                    typeArguments
                );
            }

            function typeParameterToDeclarationWithConstraint(
                type: TypeParameter,
                context: NodeBuilderContext,
                constraintNode: TypeNode | undefined
            ): TypeParameterDeclaration {
                const savedContextFlags = context.flags;
                context.flags &= ~NodeBuilderFlags
                    .WriteTypeParametersInQualifiedName; // Avoids potential infinite loop when building for a claimspace with a generic
                const name = typeParameterToName(type, context);
                const defaultParameter = getDefaultFromTypeParameter(type);
                const defaultParameterNode = defaultParameter
                    && typeToTypeNodeHelper(defaultParameter, context);
                context.flags = savedContextFlags;
                return createTypeParameterDeclaration(
                    name,
                    constraintNode,
                    defaultParameterNode
                );
            }

            function typeParameterToDeclaration(
                type: TypeParameter,
                context: NodeBuilderContext,
                constraint = getConstraintOfTypeParameter(type)
            ): TypeParameterDeclaration {
                const constraintNode = constraint
                    && typeToTypeNodeHelper(constraint, context);
                return typeParameterToDeclarationWithConstraint(
                    type,
                    context,
                    constraintNode
                );
            }

            function symbolToParameterDeclaration(
                parameterSymbol: Symbol,
                context: NodeBuilderContext,
                preserveModifierFlags?: boolean
            ): ParameterDeclaration {
                let parameterDeclaration: ParameterDeclaration
                    | JSDocParameterTag
                    | undefined = getDeclarationOfKind<ParameterDeclaration>(
                        parameterSymbol,
                        SyntaxKind.Parameter
                    );
                if (!parameterDeclaration
                    && !isTransientSymbol(parameterSymbol))
                {
                    parameterDeclaration = getDeclarationOfKind<JSDocParameterTag>(
                        parameterSymbol,
                        SyntaxKind.JSDocParameterTag
                    );
                }

                let parameterType = getTypeOfSymbol(parameterSymbol);
                if (parameterDeclaration
                    && isRequiredInitializedParameter(parameterDeclaration))
                {
                    parameterType = getOptionalType(parameterType);
                }
                const parameterTypeNode = typeToTypeNodeHelper(
                    parameterType,
                    context
                );

                const modifiers = !(context.flags
                    & NodeBuilderFlags.OmitParameterModifiers)
                    && preserveModifierFlags && parameterDeclaration
                    && parameterDeclaration.modifiers
                    ? parameterDeclaration.modifiers.map(getSynthesizedClone)
                    : undefined;
                const isRest = parameterDeclaration
                    && isRestParameter(parameterDeclaration)
                    || getCheckFlags(parameterSymbol)
                    & CheckFlags.RestParameter;
                const dotDotDotToken = isRest
                    ? createToken(SyntaxKind.DotDotDotToken)
                    : undefined;
                const name = parameterDeclaration
                    ? parameterDeclaration.name
                        ? parameterDeclaration.name.kind
                            === SyntaxKind.Identifier
                            ? setEmitFlags(
                                getSynthesizedClone(
                                    parameterDeclaration.name
                                ),
                                EmitFlags.NoAsciiEscaping
                            )
                            : parameterDeclaration.name.kind
                                === SyntaxKind.QualifiedName
                                ? setEmitFlags(
                                    getSynthesizedClone(
                                        parameterDeclaration.name.right
                                    ),
                                    EmitFlags.NoAsciiEscaping
                                )
                                : cloneBindingName(parameterDeclaration.name)
                        : symbolName(parameterSymbol)
                    : symbolName(parameterSymbol);
                const isOptional = parameterDeclaration
                    && isOptionalParameter(parameterDeclaration)
                    || getCheckFlags(parameterSymbol)
                    & CheckFlags.OptionalParameter;
                const questionToken = isOptional
                    ? createToken(SyntaxKind.QuestionToken)
                    : undefined;
                const parameterNode = createParameter(
                    /*decorators*/ undefined,
                    modifiers,
                    dotDotDotToken,
                    name,
                    questionToken,
                    parameterTypeNode,
                    /*initializer*/ undefined
                );
                context.approximateLength += symbolName(parameterSymbol).length
                    + 3;
                return parameterNode;

                function cloneBindingName(node: BindingName): BindingName {
                    return <BindingName> elideInitializerAndSetEmitFlags(node);
                    function elideInitializerAndSetEmitFlags(node:
                        Node): Node
                    {
                        if (context.tracker.trackSymbol
                            && isComputedPropertyName(node)
                            && isLateBindableName(node))
                        {
                            trackComputedName(
                                node.expression,
                                context.enclosingDeclaration,
                                context
                            );
                        }
                        const visited = visitEachChild(
                            node,
                            elideInitializerAndSetEmitFlags,
                            nullTransformationContext, /*nodesVisitor*/
                            undefined,
                            elideInitializerAndSetEmitFlags
                        )!;
                        const clone = nodeIsSynthesized(visited)
                            ? visited
                            : getSynthesizedClone(visited);
                        if (clone.kind === SyntaxKind.BindingElement) {
                            (<BindingElement> clone).initializer = undefined;
                        }
                        return setEmitFlags(
                            clone,
                            EmitFlags.SingleLine | EmitFlags.NoAsciiEscaping
                        );
                    }
                }
            }

            function trackComputedName(
                accessExpression: EntityNameOrEntityNameExpression,
                enclosingDeclaration: Node | undefined,
                context: NodeBuilderContext
            ) {
                if (!context.tracker.trackSymbol) return;
                // get symbol of the first identifier of the entityName
                const firstIdentifier = getFirstIdentifier(accessExpression);
                const name = resolveName(
                    firstIdentifier,
                    firstIdentifier.escapedText,
                    SymbolFlags.Value
                        | SymbolFlags.ExportValue, /*nodeNotFoundErrorMessage*/
                    undefined, /*nameArg*/
                    undefined, /*isUse*/
                    true
                );
                if (name) {
                    context.tracker.trackSymbol(
                        name,
                        enclosingDeclaration,
                        SymbolFlags.Value
                    );
                }
            }

            function lookupSymbolChain(
                symbol: Symbol,
                context: NodeBuilderContext,
                meaning: SymbolFlags,
                yieldModuleSymbol?: boolean
            ) {
                context.tracker.trackSymbol!(
                    symbol,
                    context.enclosingDeclaration,
                    meaning
                ); // TODO: GH#18217
                return lookupSymbolChainWorker(
                    symbol,
                    context,
                    meaning,
                    yieldModuleSymbol
                );
            }

            function lookupSymbolChainWorker(
                symbol: Symbol,
                context: NodeBuilderContext,
                meaning: SymbolFlags,
                yieldModuleSymbol?: boolean
            ) {
                // Try to get qualified name if the symbol is not a type parameter and there is an enclosing declaration.
                let chain: Symbol[];
                const isTypeParameter = symbol.flags
                    & SymbolFlags.TypeParameter;
                if (!isTypeParameter
                    && (context.enclosingDeclaration
                        || context.flags
                        & NodeBuilderFlags.UseFullyQualifiedType)
                    && !(context.flags
                        & NodeBuilderFlags.DoNotIncludeSymbolChain))
                {
                    chain = Debug
                        .assertDefined(
                            getSymbolChain(
                                symbol,
                                meaning, /*endOfChain*/
                                true
                            )
                        );
                    Debug.assert(chain && chain.length > 0);
                } else {
                    chain = [symbol];
                }
                return chain;

                /** @param endOfChain Set to false for recursive calls; non-recursive calls should always output something. */
                function getSymbolChain(
                    symbol: Symbol,
                    meaning: SymbolFlags,
                    endOfChain: boolean
                ): Symbol[] | undefined {
                    let accessibleSymbolChain = getAccessibleSymbolChain(
                        symbol,
                        context.enclosingDeclaration,
                        meaning,
                        !!(context.flags
                            & NodeBuilderFlags.UseOnlyExternalAliasing)
                    );
                    let parentSpecifiers: (string | undefined)[];
                    if (!accessibleSymbolChain
                        || needsQualification(
                            accessibleSymbolChain[0],
                            context.enclosingDeclaration,
                            accessibleSymbolChain.length === 1
                                ? meaning
                                : getQualifiedLeftMeaning(meaning)
                        ))
                    {
                        // Go up and add our parent.
                        const parents = getContainersOfSymbol(
                            accessibleSymbolChain
                                ? accessibleSymbolChain[0]
                                : symbol,
                            context.enclosingDeclaration
                        );
                        if (length(parents)) {
                            parentSpecifiers = parents!.map(symbol => some(
                                symbol.declarations,
                                hasNonGlobalAugmentationExternalModuleSymbol
                            )
                                ? getSpecifierForModuleSymbol(
                                    symbol,
                                    context
                                )
                                : undefined);
                            const indices = parents!.map((_, i) => i);
                            indices.sort(sortByBestName);
                            const sortedParents = indices
                                .map(i => parents![i]);
                            for (const parent of sortedParents) {
                                const parentChain = getSymbolChain(
                                    parent,
                                    getQualifiedLeftMeaning(meaning), /*endOfChain*/
                                    false
                                );
                                if (parentChain) {
                                    if (parent.exports && parent.exports.get(
                                        InternalSymbolName.ExportEquals
                                    )
                                        && getSymbolIfSameReference(
                                            parent.exports.get(
                                                InternalSymbolName.ExportEquals
                                            )!,
                                            symbol
                                        ))
                                    {
                                        // parentChain root _is_ symbol - symbol is a module export=, so it kinda looks like it's own parent
                                        // No need to lookup an alias for the symbol in itself
                                        accessibleSymbolChain = parentChain;
                                        break;
                                    }
                                    accessibleSymbolChain = parentChain.concat(
                                        accessibleSymbolChain
                                            || [getAliasForSymbolInContainer(
                                                parent,
                                                symbol
                                            ) || symbol]
                                    );
                                    break;
                                }
                            }
                        }
                    }

                    if (accessibleSymbolChain) {
                        return accessibleSymbolChain;
                    }
                    if (
                        // If this is the last part of outputting the symbol, always output. The cases apply only to parent symbols.
                        endOfChain
                        // If a parent symbol is an anonymous type, don't write it.
                        || !(symbol.flags
                            & (SymbolFlags.TypeLiteral
                                | SymbolFlags.ObjectLiteral))
                    ) {
                        // If a parent symbol is an external module, don't write it. (We prefer just `x` vs `"foo/bar".x`.)
                        if (!endOfChain && !yieldModuleSymbol
                            && !!forEach(
                                symbol.declarations,
                                hasNonGlobalAugmentationExternalModuleSymbol
                            ))
                        {
                            return;
                        }
                        return [symbol];
                    }

                    function sortByBestName(a: number, b: number) {
                        const specifierA = parentSpecifiers[a];
                        const specifierB = parentSpecifiers[b];
                        if (specifierA && specifierB) {
                            const isBRelative = pathIsRelative(specifierB);
                            if (pathIsRelative(specifierA) === isBRelative) {
                                // Both relative or both non-relative, sort by number of parts
                                return moduleSpecifiers
                                    .countPathComponents(specifierA)
                                    - moduleSpecifiers
                                        .countPathComponents(specifierB);
                            }
                            if (isBRelative) {
                                // A is non-relative, B is relative: prefer A
                                return -1;
                            }
                            // A is relative, B is non-relative: prefer B
                            return 1;
                        }
                        return 0;
                    }
                }
            }

            function typeParametersToTypeParameterDeclarations(
                symbol: Symbol,
                context: NodeBuilderContext
            ) {
                let typeParameterNodes: NodeArray<TypeParameterDeclaration>
                    | undefined;
                const targetSymbol = getTargetSymbol(symbol);
                if (targetSymbol.flags
                    & (SymbolFlags.Class | SymbolFlags.Interface
                        | SymbolFlags.TypeAlias))
                {
                    typeParameterNodes = createNodeArray(
                        map(
                            getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol),
                            tp => typeParameterToDeclaration(tp, context)
                        )
                    );
                }
                return typeParameterNodes;
            }

            function lookupTypeParameterNodes(
                chain: Symbol[],
                index: number,
                context: NodeBuilderContext
            ) {
                Debug.assert(chain && 0 <= index && index < chain.length);
                const symbol = chain[index];
                const symbolId = '' + getSymbolId(symbol);
                if (context.typeParameterSymbolList
                    && context.typeParameterSymbolList.get(symbolId))
                {
                    return undefined;
                }
                (context.typeParameterSymbolList
                    || (context.typeParameterSymbolList = createMap()))
                    .set(symbolId, true);
                let typeParameterNodes: readonly TypeNode[]
                    | readonly TypeParameterDeclaration[] | undefined;
                if (context.flags
                    & NodeBuilderFlags.WriteTypeParametersInQualifiedName
                    && index < (chain.length - 1))
                {
                    const parentSymbol = symbol;
                    const nextSymbol = chain[index + 1];
                    if (getCheckFlags(nextSymbol) & CheckFlags.Instantiated) {
                        const params = getTypeParametersOfClassOrInterface(
                            parentSymbol.flags & SymbolFlags.Alias
                                ? resolveAlias(parentSymbol)
                                : parentSymbol
                        );
                        typeParameterNodes = mapToTypeNodes(
                            map(
                                params,
                                (nextSymbol as TransientSymbol).mapper!
                            ),
                            context
                        );
                    } else {
                        typeParameterNodes = typeParametersToTypeParameterDeclarations(
                            symbol,
                            context
                        );
                    }
                }
                return typeParameterNodes;
            }

            /**
             * Given A[B][C][D], finds A[B]
             */
            function getTopmostIndexedAccessType(
                top: IndexedAccessTypeNode
            ): IndexedAccessTypeNode {
                if (isIndexedAccessTypeNode(top.objectType)) {
                    return getTopmostIndexedAccessType(top.objectType);
                }
                return top;
            }

            function getSpecifierForModuleSymbol(
                symbol: Symbol,
                context: NodeBuilderContext
            ) {
                const file = getDeclarationOfKind<SourceFile>(
                    symbol,
                    SyntaxKind.SourceFile
                );
                if (file && file.moduleName !== undefined) {
                    // Use the amd name if it is available
                    return file.moduleName;
                }
                if (!file) {
                    if (context.tracker.trackReferencedAmbientModule) {
                        const ambientDecls = filter(
                            symbol.declarations,
                            isAmbientModule
                        );
                        if (length(ambientDecls)) {
                            for (const decl of ambientDecls) {
                                context.tracker
                                    .trackReferencedAmbientModule(decl,
                                        symbol);
                            }
                        }
                    }
                    if (ambientModuleSymbolRegex
                        .test(symbol.escapedName as string))
                    {
                        return (symbol.escapedName as string).substring(
                            1,
                            (symbol.escapedName as string).length - 1
                        );
                    }
                }
                if (!context.enclosingDeclaration
                    || !context.tracker.moduleResolverHost)
                {
                    // If there's no context declaration, we can't lookup a non-ambient specifier, so we just use the symbol name
                    if (ambientModuleSymbolRegex
                        .test(symbol.escapedName as string))
                    {
                        return (symbol.escapedName as string).substring(
                            1,
                            (symbol.escapedName as string).length - 1
                        );
                    }
                    return getSourceFileOfNode(getNonAugmentationDeclaration(symbol)!)
                        .fileName; // A resolver may not be provided for baselines and errors - in those cases we use the fileName in full
                }
                const contextFile = getSourceFileOfNode(
                    getOriginalNode(
                        context.enclosingDeclaration
                    )
                );
                const links = getSymbolLinks(symbol);
                let specifier = links.specifierCache
                    && links.specifierCache.get(contextFile.path);
                if (!specifier) {
                    const isBundle = (compilerOptions.out
                        || compilerOptions.outFile);
                    // For declaration bundles, we need to generate absolute paths relative to the common source dir for imports,
                    // just like how the declaration emitter does for the ambient module declarations - we can easily accomplish this
                    // using the `baseUrl` compiler option (which we would otherwise never use in declaration emit) and a non-relative
                    // specifier preference
                    const { moduleResolverHost } = context.tracker;
                    const specifierCompilerOptions = isBundle
                        ? { ...compilerOptions,
                            baseUrl: moduleResolverHost
                                .getCommonSourceDirectory() }
                        : compilerOptions;
                    specifier = first(
                        moduleSpecifiers.getModuleSpecifiers(
                            symbol,
                            specifierCompilerOptions,
                            contextFile,
                            moduleResolverHost,
                            host.getSourceFiles(),
                            { importModuleSpecifierPreference: isBundle
                                ? 'non-relative'
                                : 'relative' },
                            host.redirectTargetsMap
                        )
                    );
                    links.specifierCache = links.specifierCache || createMap();
                    links.specifierCache.set(contextFile.path, specifier);
                }
                return specifier;
            }

            function symbolToTypeNode(
                symbol: Symbol,
                context: NodeBuilderContext,
                meaning: SymbolFlags,
                overrideTypeArguments?: readonly TypeNode[]
            ): TypeNode {
                const chain = lookupSymbolChain(
                    symbol,
                    context,
                    meaning,
                    !(context.flags
                        & NodeBuilderFlags.UseAliasDefinedOutsideCurrentScope)
                ); // If we're using aliases outside the current scope, dont bother with the module

                const isTypeOf = meaning === SymbolFlags.Value;
                if (some(
                    chain[0].declarations,
                    hasNonGlobalAugmentationExternalModuleSymbol
                )) {
                    // module is root, must use `ImportTypeNode`
                    const nonRootParts = chain.length > 1
                        ? createAccessFromSymbolChain(
                            chain,
                            chain.length - 1,
                            1
                        )
                        : undefined;
                    const typeParameterNodes = overrideTypeArguments
                        || lookupTypeParameterNodes(chain, 0, context);
                    const specifier = getSpecifierForModuleSymbol(
                        chain[0],
                        context
                    );
                    if (!(context.flags
                        & NodeBuilderFlags.AllowNodeModulesRelativePaths)
                        && getEmitModuleResolutionKind(compilerOptions)
                        === ModuleResolutionKind.NodeJs
                        && specifier.indexOf('/node_modules/') >= 0)
                    {
                        // If ultimately we can only name the symbol with a reference that dives into a `node_modules` folder, we should error
                        // since declaration files with these kinds of references are liable to fail when published :(
                        context.encounteredError = true;
                        if (context.tracker
                            .reportLikelyUnsafeImportRequiredError)
                        {
                            context.tracker
                                .reportLikelyUnsafeImportRequiredError(specifier);
                        }
                    }
                    const lit = createLiteralTypeNode(createLiteral(specifier));
                    if (context.tracker
                        .trackExternalModuleSymbolOfImportTypeNode)
                    {
                        context.tracker
                            .trackExternalModuleSymbolOfImportTypeNode(
                                chain[0]
                            );
                    }
                    context.approximateLength += specifier.length
                        + 10; // specifier + import("")
                    if (!nonRootParts || isEntityName(nonRootParts)) {
                        if (nonRootParts) {
                            const lastId = isIdentifier(nonRootParts)
                                ? nonRootParts
                                : nonRootParts.right;
                            lastId.typeArguments = undefined;
                        }
                        return createImportTypeNode(
                            lit,
                            nonRootParts as EntityName,
                            typeParameterNodes as readonly TypeNode[],
                            isTypeOf
                        );
                    } else {
                        const splitNode = getTopmostIndexedAccessType(nonRootParts);
                        const qualifier = (splitNode
                            .objectType as TypeReferenceNode).typeName;
                        return createIndexedAccessTypeNode(
                            createImportTypeNode(
                                lit,
                                qualifier,
                                typeParameterNodes as readonly TypeNode[],
                                isTypeOf
                            ),
                            splitNode.indexType
                        );
                    }
                }

                const entityName = createAccessFromSymbolChain(
                    chain,
                    chain.length - 1,
                    0
                );
                if (isIndexedAccessTypeNode(entityName)) {
                    return entityName; // Indexed accesses can never be `typeof`
                }
                if (isTypeOf) {
                    return createTypeQueryNode(entityName);
                } else {
                    const lastId = isIdentifier(entityName)
                        ? entityName
                        : entityName.right;
                    const lastTypeArgs = lastId.typeArguments;
                    lastId.typeArguments = undefined;
                    return createTypeReferenceNode(
                        entityName,
                        lastTypeArgs as NodeArray<TypeNode>
                    );
                }

                function createAccessFromSymbolChain(
                    chain: Symbol[],
                    index: number,
                    stopper: number
                ): EntityName | IndexedAccessTypeNode {
                    const typeParameterNodes = index === (chain.length - 1)
                        ? overrideTypeArguments
                        : lookupTypeParameterNodes(chain, index, context);
                    const symbol = chain[index];

                    const parent = chain[index - 1];
                    let symbolName: string | undefined;
                    if (index === 0) {
                        context.flags |= NodeBuilderFlags.InInitialEntityName;
                        symbolName = getNameOfSymbolAsWritten(symbol, context);
                        context
                            .approximateLength += (symbolName
                                ? symbolName.length
                                : 0) + 1;
                        context.flags ^= NodeBuilderFlags.InInitialEntityName;
                    } else {
                        if (parent && getExportsOfSymbol(parent)) {
                            const exports = getExportsOfSymbol(parent);
                            forEachEntry(
                                exports,
                                (ex, name) => {
                                    if (getSymbolIfSameReference(ex, symbol)
                                        && !isLateBoundName(name)
                                        && name
                                        !== InternalSymbolName.ExportEquals)
                                    {
                                        symbolName = unescapeLeadingUnderscores(name);
                                        return true;
                                    }
                                }
                            );
                        }
                    }
                    if (!symbolName) {
                        symbolName = getNameOfSymbolAsWritten(symbol, context);
                    }
                    context.approximateLength += symbolName.length + 1;

                    if (!(context.flags
                        & NodeBuilderFlags.ForbidIndexedAccessSymbolReferences)
                        && parent
                        && getMembersOfSymbol(parent)
                        && getMembersOfSymbol(parent).get(symbol.escapedName)
                        && getSymbolIfSameReference(
                            getMembersOfSymbol(parent)
                                .get(symbol.escapedName)!,
                            symbol
                        ))
                    {
                        // Should use an indexed access
                        const LHS = createAccessFromSymbolChain(
                            chain,
                            index - 1,
                            stopper
                        );
                        if (isIndexedAccessTypeNode(LHS)) {
                            return createIndexedAccessTypeNode(
                                LHS,
                                createLiteralTypeNode(createLiteral(symbolName))
                            );
                        } else {
                            return createIndexedAccessTypeNode(
                                createTypeReferenceNode(
                                    LHS,
                                    typeParameterNodes as readonly TypeNode[]
                                ),
                                createLiteralTypeNode(createLiteral(symbolName))
                            );
                        }
                    }

                    const identifier = setEmitFlags(
                        createIdentifier(
                            symbolName,
                            typeParameterNodes
                        ),
                        EmitFlags.NoAsciiEscaping
                    );
                    identifier.symbol = symbol;

                    if (index > stopper) {
                        const LHS = createAccessFromSymbolChain(
                            chain,
                            index - 1,
                            stopper
                        );
                        if (!isEntityName(LHS)) {
                            return Debug
                                .fail('Impossible construct - an export of an indexed access cannot be reachable');
                        }
                        return createQualifiedName(LHS, identifier);
                    }
                    return identifier;
                }
            }

            function typeParameterShadowsNameInScope(
                escapedName: __String,
                context: NodeBuilderContext
            ) {
                return !!resolveName(
                    context.enclosingDeclaration,
                    escapedName,
                    SymbolFlags.Type, /*nameNotFoundArg*/
                    undefined,
                    escapedName, /*isUse*/
                    false
                );
            }

            function typeParameterToName(
                type: TypeParameter,
                context: NodeBuilderContext
            ) {
                if (context.flags
                    & NodeBuilderFlags.GenerateNamesForShadowedTypeParams
                    && context.typeParameterNames)
                {
                    const cached = context.typeParameterNames
                        .get('' + getTypeId(type));
                    if (cached) {
                        return cached;
                    }
                }
                let result = symbolToName(
                    type.symbol,
                    context,
                    SymbolFlags.Type, /*expectsIdentifier*/
                    true
                );
                if (!(result.kind & SyntaxKind.Identifier)) {
                    return createIdentifier('(Missing type parameter)');
                }
                if (context.flags
                    & NodeBuilderFlags.GenerateNamesForShadowedTypeParams)
                {
                    const rawtext = result.escapedText as string;
                    let i = 0;
                    let text = rawtext;
                    while ((context.typeParameterNamesByText
                        && context.typeParameterNamesByText.get(text))
                        || typeParameterShadowsNameInScope(
                            text as __String,
                            context
                        ))
                    {
                        i++;
                        text = `${rawtext}_${i}`;
                    }
                    if (text !== rawtext) {
                        result = createIdentifier(text, result.typeArguments);
                    }
                    (context.typeParameterNames
                        || (context.typeParameterNames = createMap()))
                        .set('' + getTypeId(type), result);
                    (context.typeParameterNamesByText
                        || (context.typeParameterNamesByText = createMap()))
                        .set(result.escapedText as string, true);
                }
                return result;
            }

            function symbolToName(
                symbol: Symbol,
                context: NodeBuilderContext,
                meaning: SymbolFlags,
                expectsIdentifier: true
            ): Identifier;
            function symbolToName(
                symbol: Symbol,
                context: NodeBuilderContext,
                meaning: SymbolFlags,
                expectsIdentifier: false
            ): EntityName;
            function symbolToName(
                symbol: Symbol,
                context: NodeBuilderContext,
                meaning: SymbolFlags,
                expectsIdentifier: boolean
            ): EntityName {
                const chain = lookupSymbolChain(symbol, context, meaning);

                if (expectsIdentifier && chain.length !== 1
                    && !context.encounteredError
                    && !(context.flags
                        & NodeBuilderFlags
                            .AllowQualifedNameInPlaceOfIdentifier))
                {
                    context.encounteredError = true;
                }
                return createEntityNameFromSymbolChain(chain,
                    chain.length - 1);

                function createEntityNameFromSymbolChain(
                    chain: Symbol[],
                    index: number
                ): EntityName {
                    const typeParameterNodes = lookupTypeParameterNodes(
                        chain,
                        index,
                        context
                    );
                    const symbol = chain[index];

                    if (index === 0) {
                        context.flags |= NodeBuilderFlags.InInitialEntityName;
                    }
                    const symbolName = getNameOfSymbolAsWritten(
                        symbol,
                        context
                    );
                    if (index === 0) {
                        context.flags ^= NodeBuilderFlags.InInitialEntityName;
                    }

                    const identifier = setEmitFlags(
                        createIdentifier(
                            symbolName,
                            typeParameterNodes
                        ),
                        EmitFlags.NoAsciiEscaping
                    );
                    identifier.symbol = symbol;

                    return index > 0
                        ? createQualifiedName(
                            createEntityNameFromSymbolChain(
                                chain,
                                index - 1
                            ),
                            identifier
                        )
                        : identifier;
                }
            }

            function symbolToExpression(
                symbol: Symbol,
                context: NodeBuilderContext,
                meaning: SymbolFlags
            ) {
                const chain = lookupSymbolChain(symbol, context, meaning);

                return createExpressionFromSymbolChain(chain,
                    chain.length - 1);

                function createExpressionFromSymbolChain(
                    chain: Symbol[],
                    index: number
                ): Expression {
                    const typeParameterNodes = lookupTypeParameterNodes(
                        chain,
                        index,
                        context
                    );
                    const symbol = chain[index];

                    if (index === 0) {
                        context.flags |= NodeBuilderFlags.InInitialEntityName;
                    }
                    let symbolName = getNameOfSymbolAsWritten(symbol, context);
                    if (index === 0) {
                        context.flags ^= NodeBuilderFlags.InInitialEntityName;
                    }
                    let firstChar = symbolName.charCodeAt(0);

                    if (isSingleOrDoubleQuote(firstChar)
                        && some(
                            symbol.declarations,
                            hasNonGlobalAugmentationExternalModuleSymbol
                        ))
                    {
                        return createLiteral(
                            getSpecifierForModuleSymbol(
                                symbol,
                                context
                            )
                        );
                    }
                    const canUsePropertyAccess = firstChar
                        === CharacterCodes.hash
                        ? symbolName.length > 1 && isIdentifierStart(
                            symbolName.charCodeAt(
                                1
                            ),
                            languageVersion
                        )
                        : isIdentifierStart(firstChar, languageVersion);
                    if (index === 0 || canUsePropertyAccess) {
                        const identifier = setEmitFlags(
                            createIdentifier(
                                symbolName,
                                typeParameterNodes
                            ),
                            EmitFlags.NoAsciiEscaping
                        );
                        identifier.symbol = symbol;

                        return index > 0
                            ? createPropertyAccess(
                                createExpressionFromSymbolChain(
                                    chain,
                                    index - 1
                                ),
                                identifier
                            )
                            : identifier;
                    } else {
                        if (firstChar === CharacterCodes.openBracket) {
                            symbolName = symbolName.substring(
                                1,
                                symbolName.length - 1
                            );
                            firstChar = symbolName.charCodeAt(0);
                        }
                        let expression: Expression | undefined;
                        if (isSingleOrDoubleQuote(firstChar)) {
                            expression = createLiteral(
                                symbolName.substring(
                                    1,
                                    symbolName.length - 1
                                ).replace(/\\./g, s => s.substring(1))
                            );
                            (expression as StringLiteral)
                                .singleQuote = firstChar
                                    === CharacterCodes.singleQuote;
                        } else if (('' + +symbolName) === symbolName) {
                            expression = createLiteral(+symbolName);
                        }
                        if (!expression) {
                            expression = setEmitFlags(
                                createIdentifier(
                                    symbolName,
                                    typeParameterNodes
                                ),
                                EmitFlags.NoAsciiEscaping
                            );
                            expression.symbol = symbol;
                        }
                        return createElementAccess(
                            createExpressionFromSymbolChain(
                                chain,
                                index - 1
                            ),
                            expression
                        );
                    }
                }
            }

            function isSingleQuotedStringNamed(d: Declaration) {
                const name = getNameOfDeclaration(d);
                if (name && isStringLiteral(name) && (
                    name.singleQuote
                    || (!nodeIsSynthesized(name)
                        && startsWith(
                            getTextOfNode(
                                name, /*includeTrivia*/
                                false
                            ),
                            '\''
                        ))
                )) {
                    return true;
                }
                return false;
            }

            function getPropertyNameNodeForSymbol(
                symbol: Symbol,
                context: NodeBuilderContext
            ) {
                const singleQuote = !!length(symbol.declarations)
                    && every(symbol.declarations, isSingleQuotedStringNamed);
                const fromNameType = getPropertyNameNodeForSymbolFromNameType(
                    symbol,
                    context,
                    singleQuote
                );
                if (fromNameType) {
                    return fromNameType;
                }
                if (isKnownSymbol(symbol)) {
                    return createComputedPropertyName(
                        createPropertyAccess(
                            createIdentifier('Symbol'),
                            (symbol.escapedName as string).substr(3)
                        )
                    );
                }
                const rawName = unescapeLeadingUnderscores(symbol.escapedName);
                return createPropertyNameNodeForIdentifierOrLiteral(
                    rawName,
                    singleQuote
                );
            }

            // See getNameForSymbolFromNameType for a stringy equivalent
            function getPropertyNameNodeForSymbolFromNameType(
                symbol: Symbol,
                context: NodeBuilderContext,
                singleQuote?: boolean
            ) {
                const nameType = symbol.nameType;
                if (nameType) {
                    if (nameType.flags & TypeFlags.StringOrNumberLiteral) {
                        const name = ''
                            + (<StringLiteralType
                                | NumberLiteralType> nameType).value;
                        if (!isIdentifierText(name, compilerOptions.target)
                            && !isNumericLiteralName(name))
                        {
                            return createLiteral(name, !!singleQuote);
                        }
                        if (isNumericLiteralName(name)
                            && startsWith(name, '-'))
                        {
                            return createComputedPropertyName(createLiteral(+name));
                        }
                        return createPropertyNameNodeForIdentifierOrLiteral(name);
                    }
                    if (nameType.flags & TypeFlags.UniqueESSymbol) {
                        return createComputedPropertyName(
                            symbolToExpression(
                                (<UniqueESSymbolType> nameType).symbol,
                                context,
                                SymbolFlags.Value
                            )
                        );
                    }
                }
            }

            function createPropertyNameNodeForIdentifierOrLiteral(
                name: string,
                singleQuote?: boolean
            ) {
                return isIdentifierText(name, compilerOptions.target)
                    ? createIdentifier(name)
                    : createLiteral(
                        isNumericLiteralName(name) ? +name : name,
                        !!singleQuote
                    );
            }

            function cloneNodeBuilderContext(
                context: NodeBuilderContext
            ): NodeBuilderContext {
                const initial: NodeBuilderContext = { ...context };
                // Make type parameters created within this context not consume the name outside this context
                // The symbol serializer ends up creating many sibling scopes that all need "separate" contexts when
                // it comes to naming things - within a normal `typeToTypeNode` call, the node builder only ever descends
                // through the type tree, so the only cases where we could have used distinct sibling scopes was when there
                // were multiple generic overloads with similar generated type parameter names
                // The effect:
                // When we write out
                // export const x: <T>(x: T) => T
                // export const y: <T>(x: T) => T
                // we write it out like that, rather than as
                // export const x: <T>(x: T) => T
                // export const y: <T_1>(x: T_1) => T_1
                if (initial.typeParameterNames) {
                    initial
                        .typeParameterNames = cloneMap(
                            initial.typeParameterNames
                        );
                }
                if (initial.typeParameterNamesByText) {
                    initial
                        .typeParameterNamesByText = cloneMap(
                            initial.typeParameterNamesByText
                        );
                }
                if (initial.typeParameterSymbolList) {
                    initial
                        .typeParameterSymbolList = cloneMap(
                            initial.typeParameterSymbolList
                        );
                }
                return initial;
            }

            function symbolTableToDeclarationStatements(
                symbolTable: SymbolTable,
                context: NodeBuilderContext,
                bundled?: boolean
            ): Statement[] {
                const serializePropertySymbolForClass = makeSerializePropertySymbol<ClassElement>(
                    createProperty,
                    SyntaxKind.MethodDeclaration, /*useAcessors*/
                    true
                );
                const serializePropertySymbolForInterfaceWorker = makeSerializePropertySymbol<TypeElement>(
                    (
                        _decorators,
                        mods,
                        name,
                        question,
                        type,
                        initializer
                    ) => createPropertySignature(
                        mods,
                        name,
                        question,
                        type,
                        initializer
                    ),
                    SyntaxKind.MethodSignature, /*useAcessors*/
                    false
                );

                // TODO: Use `setOriginalNode` on original declaration names where possible so these declarations see some kind of
                // declaration mapping

                // We save the enclosing declaration off here so it's not adjusted by well-meaning declaration
                // emit codepaths which want to apply more specific contexts (so we can still refer to the root real declaration
                // we're trying to emit from later on)
                const enclosingDeclaration = context.enclosingDeclaration!;
                let results: Statement[] = [];
                const visitedSymbols: Map<true> = createMap();
                let deferredPrivates: Map<Symbol> | undefined;
                const oldcontext = context;
                context = {
                    ...oldcontext,
                    usedSymbolNames: createMap(),
                    remappedSymbolNames: createMap(),
                    tracker: {
                        ...oldcontext.tracker,
                        trackSymbol: (sym, decl, meaning) => {
                            const accessibleResult = isSymbolAccessible(
                                sym,
                                decl,
                                meaning, /*computeALiases*/
                                false
                            );
                            if (accessibleResult.accessibility
                                === SymbolAccessibility.Accessible)
                            {
                                // Lookup the root symbol of the chain of refs we'll use to access it and serialize it
                                const chain = lookupSymbolChainWorker(
                                    sym,
                                    context,
                                    meaning
                                );
                                if (!(sym.flags & SymbolFlags.Property)) {
                                    includePrivateSymbol(chain[0]);
                                }
                            } else if (oldcontext.tracker
                                && oldcontext.tracker.trackSymbol)
                            {
                                oldcontext.tracker.trackSymbol(
                                    sym,
                                    decl,
                                    meaning
                                );
                            }
                        }
                    }
                };
                if (oldcontext.usedSymbolNames) {
                    oldcontext.usedSymbolNames.forEach((_, name) => {
                        context.usedSymbolNames!.set(name, true);
                    });
                }
                forEachEntry(
                    symbolTable,
                    (symbol, name) => {
                        const baseName = unescapeLeadingUnderscores(name);
                        void getInternalSymbolName(symbol,
                            baseName); // Called to cache values into `usedSymbolNames` and `remappedSymbolNames`
                    }
                );
                let addingDeclare = !bundled;
                const exportEquals = symbolTable
                    .get(InternalSymbolName.ExportEquals);
                if (exportEquals && symbolTable.size > 1
                    && exportEquals.flags & SymbolFlags.Alias)
                {
                    symbolTable = createSymbolTable();
                    // Remove extraneous elements from root symbol table (they'll be mixed back in when the target of the `export=` is looked up)
                    symbolTable.set(
                        InternalSymbolName.ExportEquals,
                        exportEquals
                    );
                }

                visitSymbolTable(symbolTable);
                return mergeRedundantStatements(results);

                function isIdentifierAndNotUndefined(
                    node: Node | undefined
                ): node is Identifier {
                    return !!node && node.kind === SyntaxKind.Identifier;
                }

                function getNamesOfDeclaration(
                    statement: Statement
                ): Identifier[] {
                    if (isVariableStatement(statement)) {
                        return filter(
                            map(
                                statement.declarationList.declarations,
                                getNameOfDeclaration
                            ),
                            isIdentifierAndNotUndefined
                        );
                    }
                    return filter(
                        [getNameOfDeclaration(statement as DeclarationStatement)],
                        isIdentifierAndNotUndefined
                    );
                }

                function flattenExportAssignedNamespace(
                    statements: Statement[]
                ) {
                    const exportAssignment = find(
                        statements,
                        isExportAssignment
                    );
                    const ns = find(statements, isModuleDeclaration);
                    if (ns && exportAssignment
                        && exportAssignment.isExportEquals
                        && isIdentifier(exportAssignment.expression)
                        && isIdentifier(ns.name)
                        && idText(ns.name)
                        === idText(exportAssignment.expression)
                        && ns.body && isModuleBlock(ns.body))
                    {
                        // Pass 0: Correct situations where a module has both an `export = ns` and multiple top-level exports by stripping the export modifiers from
                        //  the top-level exports and exporting them in the targeted ns, as can occur when a js file has both typedefs and `module.export` assignments
                        const excessExports = filter(
                            statements,
                            s => !!(getModifierFlags(s) & ModifierFlags.Export)
                        );
                        if (length(excessExports)) {
                            ns.body
                                .statements = createNodeArray(
                                    [...ns.body.statements,
                                        createExportDeclaration(
                                            /*decorators*/ undefined,
                                            /*modifiers*/ undefined,
                                            createNamedExports(
                                                map(
                                                    flatMap(
                                                        excessExports,
                                                        e => getNamesOfDeclaration(e)
                                                    ),
                                                    id => createExportSpecifier(
                                                        /*alias*/ undefined,
                                                        id
                                                    )
                                                )
                                            ),
                                            /*moduleSpecifier*/ undefined
                                        )]
                                );
                        }

                        // Pass 1: Flatten `export namespace _exports {} export = _exports;` so long as the `export=` only points at a single namespace declaration
                        if (!find(
                            statements,
                            s => s !== ns
                                && nodeHasName(s, ns.name as Identifier)
                        )) {
                            results = [];
                            forEach(
                                ns.body.statements,
                                s => {
                                    addResult(s,
                                        ModifierFlags
                                            .None); // Recalculates the ambient (and export, if applicable from above) flag
                                }
                            );
                            statements = [...filter(
                                statements,
                                s => s !== ns && s !== exportAssignment
                            ), ...results];
                        }
                    }
                    return statements;
                }

                function mergeExportDeclarations(statements: Statement[]) {
                    // Pass 2: Combine all `export {}` declarations
                    const exports = filter(
                        statements,
                        d => isExportDeclaration(d) && !d.moduleSpecifier
                            && !!d.exportClause
                            && isNamedExports(d.exportClause)
                    ) as ExportDeclaration[];
                    if (length(exports) > 1) {
                        const nonExports = filter(
                            statements,
                            d => !isExportDeclaration(d) || !!d.moduleSpecifier
                                || !d.exportClause
                        );
                        statements = [...nonExports, createExportDeclaration(
                            /*decorators*/ undefined,
                            /*modifiers*/ undefined,
                            createNamedExports(
                                flatMap(
                                    exports,
                                    e => cast(e.exportClause, isNamedExports)
                                        .elements
                                )
                            ),
                            /*moduleSpecifier*/ undefined
                        )];
                    }
                    // Pass 2b: Also combine all `export {} from "..."` declarations as needed
                    const reexports = filter(
                        statements,
                        d => isExportDeclaration(d) && !!d.moduleSpecifier
                            && !!d.exportClause
                            && isNamedExports(d.exportClause)
                    ) as ExportDeclaration[];
                    if (length(reexports) > 1) {
                        const groups = group(
                            reexports,
                            decl => isStringLiteral(decl.moduleSpecifier!)
                                ? '>' + decl.moduleSpecifier.text
                                : '>'
                        );
                        if (groups.length !== reexports.length) {
                            for (const group of groups) {
                                if (group.length > 1) {
                                    // remove group members from statements and then merge group members and add back to statements
                                    statements = [
                                        ...filter(
                                            statements,
                                            s => group
                                                .indexOf(s as ExportDeclaration)
                                                === -1
                                        ),
                                        createExportDeclaration(
                                            /*decorators*/ undefined,
                                            /*modifiers*/ undefined,
                                            createNamedExports(
                                                flatMap(
                                                    group,
                                                    e => cast(
                                                        e.exportClause,
                                                        isNamedExports
                                                    ).elements
                                                )
                                            ),
                                            group[0].moduleSpecifier
                                        )
                                    ];
                                }
                            }
                        }
                    }
                    return statements;
                }

                function inlineExportModifiers(statements: Statement[]) {
                    // Pass 3: Move all `export {}`'s to `export` modifiers where possible
                    const exportDecl = find(
                        statements,
                        d => isExportDeclaration(d) && !d.moduleSpecifier
                            && !!d.exportClause
                    ) as ExportDeclaration | undefined;
                    if (exportDecl && exportDecl.exportClause
                        && isNamedExports(exportDecl.exportClause))
                    {
                        const replacements = mapDefined(
                            exportDecl.exportClause.elements,
                            e => {
                                if (!e.propertyName) {
                                    // export {name} - look thru `statements` for `name`, and if all results can take an `export` modifier, do so and filter it
                                    const associated = filter(
                                        statements,
                                        s => nodeHasName(s, e.name)
                                    );
                                    if (length(associated) && every(
                                        associated,
                                        canHaveExportModifier
                                    )) {
                                        forEach(associated, addExportModifier);
                                        return undefined;
                                    }
                                }
                                return e;
                            }
                        );
                        if (!length(replacements)) {
                            // all clauses removed, filter the export declaration
                            statements = filter(
                                statements,
                                s => s !== exportDecl
                            );
                        } else {
                            // some items filtered, others not - update the export declaration
                            // (mutating because why not, we're building a whole new tree here anyway)
                            exportDecl.exportClause
                                .elements = createNodeArray(replacements);
                        }
                    }
                    return statements;
                }

                function mergeRedundantStatements(statements: Statement[]) {
                    statements = flattenExportAssignedNamespace(statements);
                    statements = mergeExportDeclarations(statements);
                    statements = inlineExportModifiers(statements);

                    // Not a cleanup, but as a final step: If there is a mix of `export` and non-`export` declarations, but no `export =` or `export {}` add a `export {};` so
                    // declaration privacy is respected.
                    if (enclosingDeclaration
                        && ((isSourceFile(enclosingDeclaration)
                            && isExternalOrCommonJsModule(enclosingDeclaration))
                            || isModuleDeclaration(enclosingDeclaration))
                        && (!some(statements, isExternalModuleIndicator)
                            || (!hasScopeMarker(statements)
                                && some(statements, needsScopeMarker))))
                    {
                        statements.push(createEmptyExports());
                    }
                    return statements;
                }

                function canHaveExportModifier(node: Statement) {
                    return isEnumDeclaration(node)
                        || isVariableStatement(node)
                        || isFunctionDeclaration(node)
                        || isClassDeclaration(node)
                        || (isModuleDeclaration(node)
                            && !isExternalModuleAugmentation(node)
                            && !isGlobalScopeAugmentation(node))
                        || isInterfaceDeclaration(node)
                        || isTypeDeclaration(node);
                }

                function addExportModifier(statement: Statement) {
                    const flags = (getModifierFlags(statement)
                        | ModifierFlags.Export) & ~ModifierFlags.Ambient;
                    statement
                        .modifiers = createNodeArray(createModifiersFromModifierFlags(flags));
                    statement.modifierFlagsCache = 0;
                }

                function visitSymbolTable(
                    symbolTable: SymbolTable,
                    suppressNewPrivateContext?: boolean,
                    propertyAsAlias?: boolean
                ) {
                    const oldDeferredPrivates = deferredPrivates;
                    if (!suppressNewPrivateContext) {
                        deferredPrivates = createMap();
                    }
                    symbolTable.forEach((symbol: Symbol) => {
                        serializeSymbol(
                            symbol, /*isPrivate*/
                            false,
                            !!propertyAsAlias
                        );
                    });
                    if (!suppressNewPrivateContext) {
                        // deferredPrivates will be filled up by visiting the symbol table
                        // And will continue to iterate as elements are added while visited `deferredPrivates`
                        // (As that's how a map iterator is defined to work)
                        deferredPrivates!.forEach((symbol: Symbol) => {
                            serializeSymbol(
                                symbol, /*isPrivate*/
                                true,
                                !!propertyAsAlias
                            );
                        });
                    }
                    deferredPrivates = oldDeferredPrivates;
                }

                function serializeSymbol(
                    symbol: Symbol,
                    isPrivate: boolean,
                    propertyAsAlias: boolean
                ) {
                    // cache visited list based on merged symbol, since we want to use the unmerged top-level symbol, but
                    // still skip reserializing it if we encounter the merged product later on
                    const visitedSym = getMergedSymbol(symbol);
                    if (visitedSymbols.has('' + getSymbolId(visitedSym))) {
                        return; // Already printed
                    }
                    visitedSymbols.set('' + getSymbolId(visitedSym), true);
                    // Only actually serialize symbols within the correct enclosing declaration, otherwise do nothing with the out-of-context symbol
                    const skipMembershipCheck = !isPrivate; // We only call this on exported symbols when we know they're in the correct scope
                    if (skipMembershipCheck
                        || (!!length(symbol.declarations)
                            && some(
                                symbol.declarations,
                                d => !!findAncestor(
                                    d,
                                    n => n === enclosingDeclaration
                                )
                            )))
                    {
                        const oldContext = context;
                        context = cloneNodeBuilderContext(context);
                        const result = serializeSymbolWorker(
                            symbol,
                            isPrivate,
                            propertyAsAlias
                        );
                        context = oldContext;
                        return result;
                    }
                }

                // Synthesize declarations for a symbol - might be an Interface, a Class, a Namespace, a Type, a Variable (const, let, or var), an Alias
                // or a merge of some number of those.
                // An interesting challenge is ensuring that when classes merge with namespaces and interfaces, is keeping
                // each symbol in only one of the representations
                // Also, synthesizing a default export of some kind
                // If it's an alias: emit `export default ref`
                // If it's a property: emit `export default _default` with a `_default` prop
                // If it's a class/interface/function: emit a class/interface/function with a `default` modifier
                // These forms can merge, eg (`export default 12; export default interface A {}`)
                function serializeSymbolWorker(
                    symbol: Symbol,
                    isPrivate: boolean,
                    propertyAsAlias: boolean
                ) {
                    const symbolName = unescapeLeadingUnderscores(
                        symbol.escapedName
                    );
                    const isDefault = symbol.escapedName
                        === InternalSymbolName.Default;
                    if (isStringANonContextualKeyword(symbolName)
                        && !isDefault)
                    {
                        // Oh no. We cannot use this symbol's name as it's name... It's likely some jsdoc had an invalid name like `export` or `default` :(
                        context.encounteredError = true;
                        // TODO: Issue error via symbol tracker?
                        return; // If we need to emit a private with a keyword name, we're done for, since something else will try to refer to it by that name
                    }
                    const needsPostExportDefault = isDefault && !!(
                        symbol.flags
                        & SymbolFlags.ExportDoesNotSupportDefaultModifier
                        || (symbol.flags & SymbolFlags.Function
                            && length(getPropertiesOfType(getTypeOfSymbol(symbol))))
                    )
                        && !(symbol.flags
                            & SymbolFlags
                                .Alias); // An alias symbol should preclude needing to make an alias ourselves
                    if (needsPostExportDefault) {
                        isPrivate = true;
                    }
                    const modifierFlags = (!isPrivate
                        ? ModifierFlags.Export
                        : 0) | (isDefault && !needsPostExportDefault
                            ? ModifierFlags.Default
                            : 0);
                    const isConstMergedWithNS = symbol.flags
                        & SymbolFlags.Module
                        && symbol.flags
                        & (SymbolFlags.BlockScopedVariable
                            | SymbolFlags.FunctionScopedVariable
                            | SymbolFlags.Property)
                        && symbol.escapedName
                        !== InternalSymbolName.ExportEquals;
                    const isConstMergedWithNSPrintableAsSignatureMerge = isConstMergedWithNS
                        && isTypeRepresentableAsFunctionNamespaceMerge(
                            getTypeOfSymbol(symbol),
                            symbol
                        );
                    if (symbol.flags & SymbolFlags.Function
                        || isConstMergedWithNSPrintableAsSignatureMerge)
                    {
                        serializeAsFunctionNamespaceMerge(
                            getTypeOfSymbol(symbol),
                            symbol,
                            getInternalSymbolName(symbol, symbolName),
                            modifierFlags
                        );
                    }
                    if (symbol.flags & SymbolFlags.TypeAlias) {
                        serializeTypeAlias(symbol, symbolName, modifierFlags);
                    }
                    // Need to skip over export= symbols below - json source files get a single `Property` flagged
                    // symbol of name `export=` which needs to be handled like an alias. It's not great, but it is what it is.
                    if (symbol.flags
                        & (SymbolFlags.BlockScopedVariable
                            | SymbolFlags.FunctionScopedVariable
                            | SymbolFlags.Property)
                        && symbol.escapedName
                        !== InternalSymbolName.ExportEquals
                        && !(symbol.flags & SymbolFlags.Prototype)
                        && !(symbol.flags & SymbolFlags.Class)
                        && !isConstMergedWithNSPrintableAsSignatureMerge)
                    {
                        serializeVariableOrProperty(
                            symbol,
                            symbolName,
                            isPrivate,
                            needsPostExportDefault,
                            propertyAsAlias,
                            modifierFlags
                        );
                    }
                    if (symbol.flags & SymbolFlags.Enum) {
                        serializeEnum(symbol, symbolName, modifierFlags);
                    }
                    if (symbol.flags & SymbolFlags.Class) {
                        if (symbol.flags & SymbolFlags.Property) {
                            // Looks like a `module.exports.Sub = class {}` - if we serialize `symbol` as a class, the result will have no members,
                            // since the classiness is actually from the target of the effective alias the symbol is. yes. A BlockScopedVariable|Class|Property
                            // _really_ acts like an Alias, and none of a BlockScopedVariable, Class, or Property. This is the travesty of JS binding today.
                            serializeAsAlias(
                                symbol,
                                getInternalSymbolName(symbol, symbolName),
                                modifierFlags
                            );
                        } else {
                            serializeAsClass(
                                symbol,
                                getInternalSymbolName(symbol, symbolName),
                                modifierFlags
                            );
                        }
                    }
                    if ((symbol.flags
                        & (SymbolFlags.ValueModule
                            | SymbolFlags.NamespaceModule)
                        && (!isConstMergedWithNS
                            || isTypeOnlyNamespace(symbol)))
                        || isConstMergedWithNSPrintableAsSignatureMerge)
                    {
                        serializeModule(symbol, symbolName, modifierFlags);
                    }
                    if (symbol.flags & SymbolFlags.Interface) {
                        serializeInterface(symbol, symbolName, modifierFlags);
                    }
                    if (symbol.flags & SymbolFlags.Alias) {
                        serializeAsAlias(
                            symbol,
                            getInternalSymbolName(symbol, symbolName),
                            modifierFlags
                        );
                    }
                    if (symbol.flags & SymbolFlags.Property
                        && symbol.escapedName
                        === InternalSymbolName.ExportEquals)
                    {
                        serializeMaybeAliasAssignment(symbol);
                    }
                    if (symbol.flags & SymbolFlags.ExportStar) {
                        // synthesize export * from "moduleReference"
                        // Straightforward - only one thing to do - make an export declaration
                        for (const node of symbol.declarations) {
                            const resolvedModule = resolveExternalModuleName(
                                node,
                                (node as ExportDeclaration).moduleSpecifier!
                            );
                            if (!resolvedModule) continue;
                            addResult(
                                createExportDeclaration(
                                    /*decorators*/ undefined, /*modifiers*/
                                    undefined, /*exportClause*/
                                    undefined,
                                    createLiteral(
                                        getSpecifierForModuleSymbol(
                                            resolvedModule,
                                            context
                                        )
                                    )
                                ),
                                ModifierFlags.None
                            );
                        }
                    }
                    if (needsPostExportDefault) {
                        addResult(
                            createExportAssignment(
                                /*decorators*/ undefined, /*modifiers*/
                                undefined, /*isExportAssignment*/
                                false,
                                createIdentifier(
                                    getInternalSymbolName(
                                        symbol,
                                        symbolName
                                    )
                                )
                            ),
                            ModifierFlags.None
                        );
                    }
                }

                function includePrivateSymbol(symbol: Symbol) {
                    if (some(symbol.declarations,
                        isParameterDeclaration))
                        return;
                    Debug.assertDefined(deferredPrivates);
                    getUnusedName(
                        unescapeLeadingUnderscores(
                            symbol.escapedName
                        ),
                        symbol
                    ); // Call to cache unique name for symbol
                    deferredPrivates!.set('' + getSymbolId(symbol), symbol);
                }

                function isExportingScope(enclosingDeclaration: Node) {
                    return ((isSourceFile(enclosingDeclaration)
                        && (isExternalOrCommonJsModule(enclosingDeclaration)
                            || isJsonSourceFile(enclosingDeclaration)))
                        || (isAmbientModule(enclosingDeclaration)
                            && !isGlobalScopeAugmentation(enclosingDeclaration)));
                }

                // Prepends a `declare` and/or `export` modifier if the context requires it, and then adds `node` to `result` and returns `node`
                // Note: This _mutates_ `node` without using `updateNode` - the assumption being that all nodes should be manufactured fresh by the node builder
                function addResult(
                    node: Statement,
                    additionalModifierFlags: ModifierFlags
                ) {
                    let newModifierFlags: ModifierFlags = ModifierFlags.None;
                    if (additionalModifierFlags & ModifierFlags.Export
                        && enclosingDeclaration
                        && isExportingScope(enclosingDeclaration)
                        && canHaveExportModifier(node))
                    {
                        // Classes, namespaces, variables, functions, interfaces, and types should all be `export`ed in a module context if not private
                        newModifierFlags |= ModifierFlags.Export;
                    }
                    if (addingDeclare
                        && !(newModifierFlags & ModifierFlags.Export)
                        && (!enclosingDeclaration
                            || !(enclosingDeclaration.flags
                                & NodeFlags.Ambient))
                        && (isEnumDeclaration(node)
                            || isVariableStatement(node)
                            || isFunctionDeclaration(node)
                            || isClassDeclaration(node)
                            || isModuleDeclaration(node)))
                    {
                        // Classes, namespaces, variables, enums, and functions all need `declare` modifiers to be valid in a declaration file top-level scope
                        newModifierFlags |= ModifierFlags.Ambient;
                    }
                    if ((additionalModifierFlags & ModifierFlags.Default)
                        && (isClassDeclaration(node)
                            || isInterfaceDeclaration(node)
                            || isFunctionDeclaration(node)))
                    {
                        newModifierFlags |= ModifierFlags.Default;
                    }
                    if (newModifierFlags) {
                        node
                            .modifiers = createNodeArray(
                                createModifiersFromModifierFlags(
                                    newModifierFlags | getModifierFlags(node)
                                )
                            );
                        node
                            .modifierFlagsCache = 0; // Reset computed flags cache
                    }
                    results.push(node);
                }

                function serializeTypeAlias(
                    symbol: Symbol,
                    symbolName: string,
                    modifierFlags: ModifierFlags
                ) {
                    const aliasType = getDeclaredTypeOfTypeAlias(symbol);
                    const typeParams = getSymbolLinks(symbol).typeParameters;
                    const typeParamDecls = map(
                        typeParams,
                        p => typeParameterToDeclaration(p, context)
                    );
                    const jsdocAliasDecl = find(
                        symbol.declarations,
                        isJSDocTypeAlias
                    );
                    const commentText = jsdocAliasDecl
                        ? jsdocAliasDecl.comment
                            || jsdocAliasDecl.parent.comment
                        : undefined;
                    const oldFlags = context.flags;
                    context.flags |= NodeBuilderFlags.InTypeAlias;
                    addResult(
                        setSyntheticLeadingComments(
                            createTypeAliasDeclaration(
                                /*decorators*/ undefined, /*modifiers*/
                                undefined,
                                getInternalSymbolName(symbol, symbolName),
                                typeParamDecls,
                                typeToTypeNodeHelper(aliasType, context)
                            ),
                            !commentText
                                ? []
                                : [{ kind: SyntaxKind.MultiLineCommentTrivia,
                                    text: '*\n * '
                                        + commentText.replace(/\n/g, '\n * ')
                                        + '\n ', pos: -1, end: -1,
                                    hasTrailingNewLine: true }]
                        ),
                        modifierFlags
                    );
                    context.flags = oldFlags;
                }

                function serializeInterface(
                    symbol: Symbol,
                    symbolName: string,
                    modifierFlags: ModifierFlags
                ) {
                    const interfaceType = getDeclaredTypeOfClassOrInterface(symbol);
                    const localParams = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol);
                    const typeParamDecls = map(
                        localParams,
                        p => typeParameterToDeclaration(p, context)
                    );
                    const baseTypes = getBaseTypes(interfaceType);
                    const baseType = length(baseTypes)
                        ? getIntersectionType(baseTypes)
                        : undefined;
                    const members = flatMap<Symbol,
                        TypeElement>(
                            getPropertiesOfType(interfaceType),
                            p => serializePropertySymbolForInterface(
                                p,
                                baseType
                            )
                        );
                    const callSignatures = serializeSignatures(
                        SignatureKind.Call,
                        interfaceType,
                        baseType,
                        SyntaxKind.CallSignature
                    ) as CallSignatureDeclaration[];
                    const constructSignatures = serializeSignatures(
                        SignatureKind.Construct,
                        interfaceType,
                        baseType,
                        SyntaxKind.ConstructSignature
                    ) as ConstructSignatureDeclaration[];
                    const indexSignatures = serializeIndexSignatures(
                        interfaceType,
                        baseType
                    );

                    const heritageClauses = !length(baseTypes)
                        ? undefined
                        : [createHeritageClause(
                            SyntaxKind.ExtendsKeyword,
                            mapDefined(
                                baseTypes,
                                b => trySerializeAsTypeReference(b)
                            )
                        )];
                    addResult(
                        createInterfaceDeclaration(
                            /*decorators*/ undefined,
                            /*modifiers*/ undefined,
                            getInternalSymbolName(symbol, symbolName),
                            typeParamDecls,
                            heritageClauses,
                            [...indexSignatures, ...constructSignatures,
                                ...callSignatures, ...members]
                        ),
                        modifierFlags
                    );
                }

                function getNamespaceMembersForSerialization(symbol: Symbol) {
                    return !symbol.exports
                        ? []
                        : filter(
                            arrayFrom((symbol.exports).values()),
                            p => !((p.flags & SymbolFlags.Prototype)
                                || (p.escapedName === 'prototype'))
                        );
                }

                function isTypeOnlyNamespace(symbol: Symbol) {
                    return every(
                        getNamespaceMembersForSerialization(symbol),
                        m => !(resolveSymbol(m).flags & SymbolFlags.Value)
                    );
                }

                function serializeModule(
                    symbol: Symbol,
                    symbolName: string,
                    modifierFlags: ModifierFlags
                ) {
                    const members = getNamespaceMembersForSerialization(symbol);
                    // Split NS members up by declaration - members whose parent symbol is the ns symbol vs those whose is not (but were added in later via merging)
                    const locationMap = arrayToMultiMap(
                        members,
                        m => m.parent && m.parent === symbol
                            ? 'real'
                            : 'merged'
                    );
                    const realMembers = locationMap.get('real') || emptyArray;
                    const mergedMembers = locationMap.get('merged')
                        || emptyArray;
                    // TODO: `suppressNewPrivateContext` is questionable -we need to simply be emitting privates in whatever scope they were declared in, rather
                    // than whatever scope we traverse to them in. That's a bit of a complex rewrite, since we're not _actually_ tracking privates at all in advance,
                    // so we don't even have placeholders to fill in.
                    if (length(realMembers)) {
                        const localName = getInternalSymbolName(
                            symbol,
                            symbolName
                        );
                        serializeAsNamespaceDeclaration(
                            realMembers,
                            localName,
                            modifierFlags,
                            !!(symbol.flags
                                & (SymbolFlags.Function
                                    | SymbolFlags.Assignment))
                        );
                    }
                    if (length(mergedMembers)) {
                        const localName = getInternalSymbolName(
                            symbol,
                            symbolName
                        );
                        const nsBody = createModuleBlock(
                            [createExportDeclaration(
                                /*decorators*/ undefined,
                                /*modifiers*/ undefined,
                                createNamedExports(
                                    map(
                                        filter(
                                            mergedMembers,
                                            n => n.escapedName
                                                !== InternalSymbolName
                                                    .ExportEquals
                                        ),
                                        s => {
                                            const name = unescapeLeadingUnderscores(s
                                                .escapedName);
                                            const localName = getInternalSymbolName(
                                                s,
                                                name
                                            );
                                            const aliasDecl = s.declarations
                                                && getDeclarationOfAliasSymbol(s);
                                            const target = aliasDecl
                                                && getTargetOfAliasDeclaration(
                                                    aliasDecl, /*dontRecursivelyResolve*/
                                                    true
                                                );
                                            includePrivateSymbol(target || s);
                                            const targetName = target
                                                ? getInternalSymbolName(
                                                    target,
                                                    unescapeLeadingUnderscores(target
                                                        .escapedName)
                                                )
                                                : localName;
                                            return createExportSpecifier(
                                                name === targetName
                                                    ? undefined
                                                    : targetName,
                                                name
                                            );
                                        }
                                    )
                                )
                            )]
                        );
                        addResult(
                            createModuleDeclaration(
                                /*decorators*/ undefined,
                                /*modifiers*/ undefined,
                                createIdentifier(localName),
                                nsBody,
                                NodeFlags.Namespace
                            ),
                            ModifierFlags.None
                        );
                    }
                }

                function serializeEnum(
                    symbol: Symbol,
                    symbolName: string,
                    modifierFlags: ModifierFlags
                ) {
                    addResult(
                        createEnumDeclaration(
                            /*decorators*/ undefined,
                            createModifiersFromModifierFlags(
                                isConstEnumSymbol(symbol)
                                    ? ModifierFlags.Const
                                    : 0
                            ),
                            getInternalSymbolName(symbol, symbolName),
                            map(
                                filter(
                                    getPropertiesOfType(getTypeOfSymbol(symbol)),
                                    p => !!(p.flags & SymbolFlags.EnumMember)
                                ),
                                p => {
                                    // TODO: Handle computed names
                                    // I hate that to get the initialized value we need to walk back to the declarations here; but there's no
                                    // other way to get the possible const value of an enum member that I'm aware of, as the value is cached
                                    // _on the declaration_, not on the declaration's symbol...
                                    const initializedValue = p.declarations
                                        && p.declarations[0] && isEnumMember(
                                            p.declarations[0]
                                        ) && getConstantValue(
                                            p.declarations[0] as EnumMember
                                        );
                                    return createEnumMember(
                                        unescapeLeadingUnderscores(
                                            p.escapedName
                                        ),
                                        initializedValue === undefined
                                            ? undefined
                                            : createLiteral(initializedValue)
                                    );
                                }
                            )
                        ),
                        modifierFlags
                    );
                }

                function serializeVariableOrProperty(
                    symbol: Symbol,
                    symbolName: string,
                    isPrivate: boolean,
                    needsPostExportDefault: boolean,
                    propertyAsAlias: boolean | undefined,
                    modifierFlags: ModifierFlags
                ) {
                    if (propertyAsAlias) {
                        serializeMaybeAliasAssignment(symbol);
                    } else {
                        const type = getTypeOfSymbol(symbol);
                        const localName = getInternalSymbolName(
                            symbol,
                            symbolName
                        );
                        if (!(symbol.flags & SymbolFlags.Function)
                            && isTypeRepresentableAsFunctionNamespaceMerge(
                                type,
                                symbol
                            ))
                        {
                            // If the type looks like a function declaration + ns could represent it, and it's type is sourced locally, rewrite it into a function declaration + ns
                            serializeAsFunctionNamespaceMerge(
                                type,
                                symbol,
                                localName,
                                modifierFlags
                            );
                        } else {
                            // A Class + Property merge is made for a `module.exports.Member = class {}`, and it doesn't serialize well as either a class _or_ a property symbol - in fact, _it behaves like an alias!_
                            // `var` is `FunctionScopedVariable`, `const` and `let` are `BlockScopedVariable`, and `module.exports.thing =` is `Property`
                            const flags = !(symbol.flags
                                & SymbolFlags.BlockScopedVariable)
                                ? undefined
                                : isConstVariable(symbol)
                                    ? NodeFlags.Const
                                    : NodeFlags.Let;
                            const name = (needsPostExportDefault
                                || !(symbol.flags & SymbolFlags.Property))
                                ? localName
                                : getUnusedName(localName, symbol);
                            let textRange: Node
                                | undefined = symbol.declarations
                                && find(
                                    symbol.declarations,
                                    d => isVariableDeclaration(d)
                                );
                            if (textRange
                                && isVariableDeclarationList(textRange.parent)
                                && textRange.parent.declarations.length === 1)
                            {
                                textRange = textRange.parent.parent;
                            }
                            const statement = setTextRange(
                                createVariableStatement(
                                    /*modifiers*/ undefined,
                                    createVariableDeclarationList(
                                        [
                                            createVariableDeclaration(
                                                name,
                                                serializeTypeForDeclaration(
                                                    type,
                                                    symbol
                                                )
                                            )
                                        ],
                                        flags
                                    )
                                ),
                                textRange
                            );
                            addResult(
                                statement,
                                name !== localName
                                    ? modifierFlags & ~ModifierFlags.Export
                                    : modifierFlags
                            );
                            if (name !== localName && !isPrivate) {
                                // We rename the variable declaration we generate for Property symbols since they may have a name which
                                // conflicts with a local declaration. For example, given input:
                                // ```
                                // function g() {}
                                // module.exports.g = g
                                // ```
                                // In such a situation, we have a local variable named `g`, and a seperate exported variable named `g`.
                                // Naively, we would emit
                                // ```
                                // function g() {}
                                // export const g: typeof g;
                                // ```
                                // That's obviously incorrect - the `g` in the type annotation needs to refer to the local `g`, but
                                // the export declaration shadows it.
                                // To work around that, we instead write
                                // ```
                                // function g() {}
                                // const g_1: typeof g;
                                // export { g_1 as g };
                                // ```
                                // To create an export named `g` that does _not_ shadow the local `g`
                                addResult(
                                    createExportDeclaration(
                                        /*decorators*/ undefined,
                                        /*modifiers*/ undefined,
                                        createNamedExports(
                                            [createExportSpecifier(
                                                name,
                                                localName
                                            )]
                                        )
                                    ),
                                    ModifierFlags.None
                                );
                            }
                        }
                    }
                }

                function serializeAsFunctionNamespaceMerge(
                    type: Type,
                    symbol: Symbol,
                    localName: string,
                    modifierFlags: ModifierFlags
                ) {
                    const signatures = getSignaturesOfType(
                        type,
                        SignatureKind.Call
                    );
                    for (const sig of signatures) {
                        // Each overload becomes a separate function declaration, in order
                        const decl = signatureToSignatureDeclarationHelper(
                            sig,
                            SyntaxKind.FunctionDeclaration,
                            context
                        ) as FunctionDeclaration;
                        decl.name = createIdentifier(localName);
                        addResult(
                            setTextRange(decl, sig.declaration),
                            modifierFlags
                        );
                    }
                    // Module symbol emit will take care of module-y members, provided it has exports
                    if (!(symbol.flags
                        & (SymbolFlags.ValueModule
                            | SymbolFlags.NamespaceModule) && !!symbol.exports
                        && !!symbol.exports.size))
                    {
                        const props = filter(
                            getPropertiesOfType(type),
                            p => !((p.flags & SymbolFlags.Prototype)
                                || (p.escapedName === 'prototype'))
                        );
                        serializeAsNamespaceDeclaration(
                            props,
                            localName,
                            modifierFlags, /*suppressNewPrivateContext*/
                            true
                        );
                    }
                }

                function serializeAsNamespaceDeclaration(
                    props: readonly Symbol[],
                    localName: string,
                    modifierFlags: ModifierFlags,
                    suppressNewPrivateContext: boolean
                ) {
                    if (length(props)) {
                        const localVsRemoteMap = arrayToMultiMap(
                            props,
                            p => !length(p.declarations) || some(
                                p.declarations,
                                d => getSourceFileOfNode(d)
                                    === getSourceFileOfNode(
                                        context.enclosingDeclaration!
                                    )
                            )
                                ? 'local'
                                : 'remote'
                        );
                        const localProps = localVsRemoteMap.get('local')
                            || emptyArray;
                        // handle remote props first - we need to make an `import` declaration that points at the module containing each remote
                        // prop in the outermost scope (TODO: a namespace within a namespace would need to be appropriately handled by this)
                        // Example:
                        // import Foo_1 = require("./exporter");
                        // export namespace ns {
                        //     import Foo = Foo_1.Foo;
                        //     export { Foo };
                        //     export const c: number;
                        // }
                        // This is needed because in JS, statements like `const x = require("./f")` support both type and value lookup, even if they're
                        // normally just value lookup (so it functions kinda like an alias even when it's not an alias)
                        // _Usually_, we'll simply print the top-level as an alias instead of a `var` in such situations, however is is theoretically
                        // possible to encounter a situation where a type has members from both the current file and other files - in those situations,
                        // emit akin to the above would be needed.

                        // Add a namespace
                        const fakespace = createModuleDeclaration(
                            /*decorators*/ undefined, /*modifiers*/
                            undefined,
                            createIdentifier(localName),
                            createModuleBlock([]),
                            NodeFlags.Namespace
                        );
                        fakespace.flags ^= NodeFlags
                            .Synthesized; // unset synthesized so it is usable as an enclosing declaration
                        fakespace.parent = enclosingDeclaration as SourceFile
                            | NamespaceDeclaration;
                        fakespace.locals = createSymbolTable(props);
                        fakespace.symbol = props[0].parent!;
                        const oldResults = results;
                        results = [];
                        const oldAddingDeclare = addingDeclare;
                        addingDeclare = false;
                        const subcontext = { ...context,
                            enclosingDeclaration: fakespace };
                        const oldContext = context;
                        context = subcontext;
                        // TODO: implement handling for the localVsRemoteMap.get("remote") - should be difficult to trigger (see comment above), as only interesting cross-file js merges should make this possible
                        visitSymbolTable(
                            createSymbolTable(localProps),
                            suppressNewPrivateContext, /*propertyAsAlias*/
                            true
                        );
                        context = oldContext;
                        addingDeclare = oldAddingDeclare;
                        const declarations = results;
                        results = oldResults;
                        fakespace.flags ^= NodeFlags
                            .Synthesized; // reset synthesized
                        fakespace.parent = undefined!;
                        fakespace.locals = undefined!;
                        fakespace.symbol = undefined!;
                        fakespace.body = createModuleBlock(declarations);
                        addResult(fakespace,
                            modifierFlags); // namespaces can never be default exported
                    }
                }

                function serializeAsClass(
                    symbol: Symbol,
                    localName: string,
                    modifierFlags: ModifierFlags
                ) {
                    const localParams = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol);
                    const typeParamDecls = map(
                        localParams,
                        p => typeParameterToDeclaration(p, context)
                    );
                    const classType = getDeclaredTypeOfClassOrInterface(symbol);
                    const baseTypes = getBaseTypes(classType);
                    const staticType = getTypeOfSymbol(symbol);
                    const staticBaseType = getBaseConstructorTypeOfClass(staticType as InterfaceType);
                    const heritageClauses = !length(baseTypes)
                        ? undefined
                        : [createHeritageClause(
                            SyntaxKind.ExtendsKeyword,
                            map(
                                baseTypes,
                                b => serializeBaseType(
                                    b,
                                    staticBaseType,
                                    localName
                                )
                            )
                        )];
                    const symbolProps = getPropertiesOfType(classType);
                    const publicSymbolProps = filter(
                        symbolProps,
                        s => {
                            const valueDecl = s.valueDeclaration;
                            Debug.assertDefined(valueDecl);
                            return !(isNamedDeclaration(valueDecl)
                                && isPrivateIdentifier(valueDecl.name));
                        }
                    );
                    const hasPrivateIdentifier = some(
                        symbolProps,
                        s => {
                            const valueDecl = s.valueDeclaration;
                            Debug.assertDefined(valueDecl);
                            return isNamedDeclaration(valueDecl)
                                && isPrivateIdentifier(valueDecl.name);
                        }
                    );
                    // Boil down all private properties into a single one.
                    const privateProperties = hasPrivateIdentifier
                        ? [createProperty(
                            /*decorators*/ undefined,
                            /*modifiers*/ undefined,
                            createPrivateIdentifier('#private'),
                            /*questionOrExclamationToken*/ undefined,
                            /*type*/ undefined,
                            /*initializer*/ undefined
                        )]
                        : emptyArray;
                    const publicProperties = flatMap<Symbol,
                        ClassElement>(
                            publicSymbolProps,
                            p => serializePropertySymbolForClass(
                                p, /*isStatic*/
                                false,
                                baseTypes[0]
                            )
                        );
                    // Consider static members empty if symbol also has function or module meaning - function namespacey emit will handle statics
                    const staticMembers = symbol.flags
                        & (SymbolFlags.Function | SymbolFlags.ValueModule)
                        ? []
                        : flatMap(
                            filter(
                                getPropertiesOfType(staticType),
                                p => !(p.flags & SymbolFlags.Prototype)
                                    && p.escapedName !== 'prototype'
                            ),
                            p => serializePropertySymbolForClass(
                                p, /*isStatic*/
                                true,
                                staticBaseType
                            )
                        );
                    const constructors = serializeSignatures(
                        SignatureKind.Construct,
                        staticType,
                        baseTypes[0],
                        SyntaxKind.Constructor
                    ) as ConstructorDeclaration[];
                    for (const c of constructors) {
                        // A constructor's return type and type parameters are supposed to be controlled by the enclosing class declaration
                        // `signatureToSignatureDeclarationHelper` appends them regardless, so for now we delete them here
                        c.type = undefined;
                        c.typeParameters = undefined;
                    }
                    const indexSignatures = serializeIndexSignatures(
                        classType,
                        baseTypes[0]
                    );
                    addResult(
                        setTextRange(
                            createClassDeclaration(
                                /*decorators*/ undefined,
                                /*modifiers*/ undefined,
                                localName,
                                typeParamDecls,
                                heritageClauses,
                                [...indexSignatures, ...staticMembers,
                                    ...constructors, ...publicProperties,
                                    ...privateProperties]
                            ),
                            symbol.declarations && filter(
                                symbol.declarations,
                                d => isClassDeclaration(d)
                                    || isClassExpression(d)
                            )[0]
                        ),
                        modifierFlags
                    );
                }

                function serializeAsAlias(
                    symbol: Symbol,
                    localName: string,
                    modifierFlags: ModifierFlags
                ) {
                    // synthesize an alias, eg `export { symbolName as Name }`
                    // need to mark the alias `symbol` points
                    // at as something we need to serialize as a private declaration as well
                    const node = getDeclarationOfAliasSymbol(symbol);
                    if (!node) return Debug.fail();
                    const target = getMergedSymbol(
                        getTargetOfAliasDeclaration(
                            node, /*dontRecursivelyResolve*/
                            true
                        )
                    );
                    if (!target) {
                        return;
                    }
                    let verbatimTargetName = unescapeLeadingUnderscores(
                        target.escapedName
                    );
                    if (verbatimTargetName === InternalSymbolName.ExportEquals
                        && (compilerOptions.esModuleInterop
                            || compilerOptions.allowSyntheticDefaultImports))
                    {
                        // target refers to an `export=` symbol that was hoisted into a synthetic default - rename here to match
                        verbatimTargetName = InternalSymbolName.Default;
                    }
                    const targetName = getInternalSymbolName(
                        target,
                        verbatimTargetName
                    );
                    includePrivateSymbol(target); // the target may be within the same scope - attempt to serialize it first
                    switch (node.kind) {
                        case SyntaxKind.ImportEqualsDeclaration:
                            // Could be a local `import localName = ns.member` or
                            // an external `import localName = require("whatever")`
                            const isLocalImport = !(target.flags
                                & SymbolFlags.ValueModule);
                            addResult(
                                createImportEqualsDeclaration(
                                    /*decorators*/ undefined,
                                    /*modifiers*/ undefined,
                                    createIdentifier(localName),
                                    isLocalImport
                                        ? symbolToName(
                                            target,
                                            context,
                                            SymbolFlags
                                                .All, /*expectsIdentifier*/
                                            false
                                        )
                                        : createExternalModuleReference(
                                            createLiteral(
                                                getSpecifierForModuleSymbol(
                                                    symbol,
                                                    context
                                                )
                                            )
                                        )
                                ),
                                isLocalImport
                                    ? modifierFlags
                                    : ModifierFlags.None
                            );
                            break;
                        case SyntaxKind.NamespaceExportDeclaration:
                            // export as namespace foo
                            // TODO: Not part of a file's local or export symbol tables
                            // Is bound into file.symbol.globalExports instead, which we don't currently traverse
                            addResult(
                                createNamespaceExportDeclaration(
                                    idText(
                                        (node as NamespaceExportDeclaration)
                                            .name
                                    )
                                ),
                                ModifierFlags.None
                            );
                            break;
                        case SyntaxKind.ImportClause:
                            addResult(
                                createImportDeclaration(
                                    /*decorators*/ undefined,
                                    /*modifiers*/ undefined,
                                    createImportClause(
                                        createIdentifier(localName), /*namedBindings*/
                                        undefined
                                    ),
                                    // We use `target.parent || target` below as `target.parent` is unset when the target is a module which has been export assigned
                                    // And then made into a default by the `esModuleInterop` or `allowSyntheticDefaultImports` flag
                                    // In such cases, the `target` refers to the module itself already
                                    createLiteral(
                                        getSpecifierForModuleSymbol(
                                            target.parent || target,
                                            context
                                        )
                                    )
                                ),
                                ModifierFlags.None
                            );
                            break;
                        case SyntaxKind.NamespaceImport:
                            addResult(
                                createImportDeclaration(
                                    /*decorators*/ undefined,
                                    /*modifiers*/ undefined,
                                    createImportClause(
                                        /*importClause*/ undefined,
                                        createNamespaceImport(createIdentifier(localName))
                                    ),
                                    createLiteral(
                                        getSpecifierForModuleSymbol(
                                            target,
                                            context
                                        )
                                    )
                                ),
                                ModifierFlags.None
                            );
                            break;
                        case SyntaxKind.NamespaceExport:
                            addResult(
                                createExportDeclaration(
                                    /*decorators*/ undefined,
                                    /*modifiers*/ undefined,
                                    createNamespaceExport(createIdentifier(localName)),
                                    createLiteral(
                                        getSpecifierForModuleSymbol(
                                            target,
                                            context
                                        )
                                    )
                                ),
                                ModifierFlags.None
                            );
                            break;
                        case SyntaxKind.ImportSpecifier:
                            addResult(
                                createImportDeclaration(
                                    /*decorators*/ undefined,
                                    /*modifiers*/ undefined,
                                    createImportClause(
                                        /*importClause*/ undefined,
                                        createNamedImports(
                                            [
                                                createImportSpecifier(
                                                    localName
                                                        !== verbatimTargetName
                                                        ? createIdentifier(verbatimTargetName)
                                                        : undefined,
                                                    createIdentifier(localName)
                                                )
                                            ]
                                        )
                                    ),
                                    createLiteral(
                                        getSpecifierForModuleSymbol(
                                            target.parent || target,
                                            context
                                        )
                                    )
                                ),
                                ModifierFlags.None
                            );
                            break;
                        case SyntaxKind.ExportSpecifier:
                            // does not use localName because the symbol name in this case refers to the name in the exports table,
                            // which we must exactly preserve
                            const specifier = (node.parent
                                .parent as ExportDeclaration).moduleSpecifier;
                            // targetName is only used when the target is local, as otherwise the target is an alias that points at
                            // another file
                            serializeExportSpecifier(
                                unescapeLeadingUnderscores(symbol.escapedName),
                                specifier ? verbatimTargetName : targetName,
                                specifier && isStringLiteralLike(specifier)
                                    ? createLiteral(specifier.text)
                                    : undefined
                            );
                            break;
                        case SyntaxKind.ExportAssignment:
                            serializeMaybeAliasAssignment(symbol);
                            break;
                        case SyntaxKind.BinaryExpression:
                        case SyntaxKind.PropertyAccessExpression:
                            // Could be best encoded as though an export specifier or as though an export assignment
                            // If name is default or export=, do an export assignment
                            // Otherwise do an export specifier
                            if (symbol.escapedName
                                === InternalSymbolName.Default
                                || symbol.escapedName
                                === InternalSymbolName.ExportEquals)
                            {
                                serializeMaybeAliasAssignment(symbol);
                            } else {
                                serializeExportSpecifier(localName,
                                    targetName);
                            }
                            break;
                        default:
                            return Debug.failBadSyntaxKind(
                                node,
                                'Unhandled alias declaration kind in symbol serializer!'
                            );
                    }
                }

                function serializeExportSpecifier(
                    localName: string,
                    targetName: string,
                    specifier?: Expression
                ) {
                    addResult(
                        createExportDeclaration(
                            /*decorators*/ undefined,
                            /*modifiers*/ undefined,
                            createNamedExports(
                                [createExportSpecifier(
                                    localName !== targetName
                                        ? targetName
                                        : undefined,
                                    localName
                                )]
                            ),
                            specifier
                        ),
                        ModifierFlags.None
                    );
                }

                function serializeMaybeAliasAssignment(symbol: Symbol) {
                    if (symbol.flags & SymbolFlags.Prototype) {
                        return;
                    }
                    const name = unescapeLeadingUnderscores(symbol
                        .escapedName);
                    const isExportEquals = name
                        === InternalSymbolName.ExportEquals;
                    const isDefault = name === InternalSymbolName.Default;
                    const isExportAssignment = isExportEquals || isDefault;
                    // synthesize export = ref
                    // ref should refer to either be a locally scoped symbol which we need to emit, or
                    // a reference to another namespace/module which we may need to emit an `import` statement for
                    const aliasDecl = symbol.declarations
                        && getDeclarationOfAliasSymbol(symbol);
                    // serialize what the alias points to, preserve the declaration's initializer
                    const target = aliasDecl
                        && getTargetOfAliasDeclaration(
                            aliasDecl, /*dontRecursivelyResolve*/
                            true
                        );
                    // If the target resolves and resolves to a thing defined in this file, emit as an alias, otherwise emit as a const
                    if (target && length(target.declarations)
                        && some(
                            target.declarations,
                            d => getSourceFileOfNode(d)
                                === getSourceFileOfNode(enclosingDeclaration)
                        ))
                    {
                        // In case `target` refers to a namespace member, look at the declaration and serialize the leftmost symbol in it
                        // eg, `namespace A { export class B {} }; exports = A.B;`
                        // Technically, this is all that's required in the case where the assignment is an entity name expression
                        const expr = isExportAssignment
                            ? getExportAssignmentExpression(
                                aliasDecl as ExportAssignment
                                    | BinaryExpression
                            )
                            : getPropertyAssignmentAliasLikeExpression(
                                aliasDecl as ShorthandPropertyAssignment
                                    | PropertyAssignment
                                    | PropertyAccessExpression
                            );
                        const first = isEntityNameExpression(expr)
                            ? getFirstNonModuleExportsIdentifier(expr)
                            : undefined;
                        const referenced = first
                            && resolveEntityName(
                                first,
                                SymbolFlags.All, /*ignoreErrors*/
                                true, /*dontResolveAlias*/
                                true,
                                enclosingDeclaration
                            );
                        if (referenced || target) {
                            includePrivateSymbol(referenced || target);
                        }

                        // We disable the context's symbol traker for the duration of this name serialization
                        // as, by virtue of being here, the name is required to print something, and we don't want to
                        // issue a visibility error on it. Only anonymous classes that an alias points at _would_ issue
                        // a visibility error here (as they're not visible within any scope), but we want to hoist them
                        // into the containing scope anyway, so we want to skip the visibility checks.
                        const oldTrack = context.tracker.trackSymbol;
                        context.tracker.trackSymbol = noop;
                        if (isExportAssignment) {
                            results.push(
                                createExportAssignment(
                                    /*decorators*/ undefined,
                                    /*modifiers*/ undefined,
                                    isExportEquals,
                                    symbolToExpression(
                                        target,
                                        context,
                                        SymbolFlags.All
                                    )
                                )
                            );
                        } else {
                            if (first === expr) {
                                // serialize as `export {target as name}`
                                serializeExportSpecifier(name, idText(first));
                            } else if (isClassExpression(expr)) {
                                serializeExportSpecifier(
                                    name,
                                    getInternalSymbolName(
                                        target,
                                        symbolName(target)
                                    )
                                );
                            } else {
                                // serialize as `import _Ref = t.arg.et; export { _Ref as name }`
                                const varName = getUnusedName(name, symbol);
                                addResult(
                                    createImportEqualsDeclaration(
                                        /*decorators*/ undefined,
                                        /*modifiers*/ undefined,
                                        createIdentifier(varName),
                                        symbolToName(
                                            target,
                                            context,
                                            SymbolFlags
                                                .All, /*expectsIdentifier*/
                                            false
                                        )
                                    ),
                                    ModifierFlags.None
                                );
                                serializeExportSpecifier(name, varName);
                            }
                        }
                        context.tracker.trackSymbol = oldTrack;
                    } else {
                        // serialize as an anonymous property declaration
                        const varName = getUnusedName(name, symbol);
                        // We have to use `getWidenedType` here since the object within a json file is unwidened within the file
                        // (Unwidened types can only exist in expression contexts and should never be serialized)
                        const typeToSerialize = getWidenedType(getTypeOfSymbol(symbol));
                        if (isTypeRepresentableAsFunctionNamespaceMerge(
                            typeToSerialize,
                            symbol
                        )) {
                            // If there are no index signatures and `typeToSerialize` is an object type, emit as a namespace instead of a const
                            serializeAsFunctionNamespaceMerge(
                                typeToSerialize,
                                symbol,
                                varName,
                                isExportAssignment
                                    ? ModifierFlags.None
                                    : ModifierFlags.Export
                            );
                        } else {
                            const statement = createVariableStatement(
                                /*modifiers*/ undefined,
                                createVariableDeclarationList(
                                    [
                                        createVariableDeclaration(
                                            varName,
                                            serializeTypeForDeclaration(
                                                typeToSerialize,
                                                symbol
                                            )
                                        )
                                    ],
                                    NodeFlags.Const
                                )
                            );
                            addResult(
                                statement,
                                name === varName
                                    ? ModifierFlags.Export
                                    : ModifierFlags.None
                            );
                        }
                        if (isExportAssignment) {
                            results.push(
                                createExportAssignment(
                                    /*decorators*/ undefined,
                                    /*modifiers*/ undefined,
                                    isExportEquals,
                                    createIdentifier(varName)
                                )
                            );
                        } else if (name !== varName) {
                            serializeExportSpecifier(name, varName);
                        }
                    }
                }

                function isTypeRepresentableAsFunctionNamespaceMerge(
                    typeToSerialize: Type,
                    hostSymbol: Symbol
                ) {
                    // Only object types which are not constructable, or indexable, whose members all come from the
                    // context source file, and whose property names are all valid identifiers and not late-bound, _and_
                    // whose input is not type annotated (if the input symbol has an annotation we can reuse, we should prefer it)
                    const ctxSrc = getSourceFileOfNode(
                        context.enclosingDeclaration
                    );
                    return getObjectFlags(typeToSerialize)
                        & (ObjectFlags.Anonymous | ObjectFlags.Mapped)
                        && !getIndexInfoOfType(
                            typeToSerialize,
                            IndexKind.String
                        )
                        && !getIndexInfoOfType(
                            typeToSerialize,
                            IndexKind.Number
                        )
                        && !!(length(getPropertiesOfType(typeToSerialize))
                            || length(
                                getSignaturesOfType(
                                    typeToSerialize,
                                    SignatureKind.Call
                                )
                            ))
                        && !length(
                            getSignaturesOfType(
                                typeToSerialize,
                                SignatureKind.Construct
                            )
                        ) // TODO: could probably serialize as function + ns + class, now that that's OK
                        && !getDeclarationWithTypeAnnotation(hostSymbol)
                        && !(typeToSerialize.symbol
                            && some(
                                typeToSerialize.symbol.declarations,
                                d => getSourceFileOfNode(d) !== ctxSrc
                            ))
                        && !some(
                            getPropertiesOfType(typeToSerialize),
                            p => isLateBoundName(p.escapedName)
                        )
                        && !some(
                            getPropertiesOfType(typeToSerialize),
                            p => some(
                                p.declarations,
                                d => getSourceFileOfNode(d) !== ctxSrc
                            )
                        )
                        && every(
                            getPropertiesOfType(typeToSerialize),
                            p => isIdentifierText(
                                symbolName(p),
                                languageVersion
                            ) && !isStringAKeyword(symbolName(p))
                        );
                }

                function makeSerializePropertySymbol<T
                    extends Node>(
                    createProperty: (
                        decorators: readonly Decorator[] | undefined,
                        modifiers: readonly Modifier[] | undefined,
                        name: string | PropertyName,
                        questionOrExclamationToken: QuestionToken | undefined,
                        type: TypeNode | undefined,
                        initializer: Expression | undefined
                    ) => T,
                    methodKind: SyntaxKind,
                    useAccessors: true
                ): (
                    p: Symbol,
                    isStatic: boolean,
                    baseType: Type | undefined
                ) => (T | AccessorDeclaration | (T | AccessorDeclaration)[]);
                function makeSerializePropertySymbol<T
                    extends Node>(
                    createProperty: (
                        decorators: readonly Decorator[] | undefined,
                        modifiers: readonly Modifier[] | undefined,
                        name: string | PropertyName,
                        questionOrExclamationToken: QuestionToken | undefined,
                        type: TypeNode | undefined,
                        initializer: Expression | undefined
                    ) => T,
                    methodKind: SyntaxKind,
                    useAccessors: false
                ): (
                    p: Symbol,
                    isStatic: boolean,
                    baseType: Type | undefined
                ) => (T | T[]);
                function makeSerializePropertySymbol<T
                    extends Node>(
                    createProperty: (
                        decorators: readonly Decorator[] | undefined,
                        modifiers: readonly Modifier[] | undefined,
                        name: string | PropertyName,
                        questionOrExclamationToken: QuestionToken | undefined,
                        type: TypeNode | undefined,
                        initializer: Expression | undefined
                    ) => T,
                    methodKind: SyntaxKind,
                    useAccessors: boolean
                ): (
                    p: Symbol,
                    isStatic: boolean,
                    baseType: Type | undefined
                ) => (T | AccessorDeclaration | (T | AccessorDeclaration)[]) {
                    return function serializePropertySymbol(
                        p: Symbol,
                        isStatic: boolean,
                        baseType: Type | undefined
                    ) {
                        const modifierFlags = getDeclarationModifierFlagsFromSymbol(p);
                        const isPrivate = !!(modifierFlags
                            & ModifierFlags.Private);
                        if (isStatic
                            && (p.flags
                                & (SymbolFlags.Type | SymbolFlags.Namespace
                                    | SymbolFlags.Alias)))
                        {
                            // Only value-only-meaning symbols can be correctly encoded as class statics, type/namespace/alias meaning symbols
                            // need to be merged namespace members
                            return [];
                        }
                        if (p.flags & SymbolFlags.Prototype
                            || (baseType
                                && getPropertyOfType(baseType, p.escapedName)
                                && isReadonlySymbol(
                                    getPropertyOfType(
                                        baseType,
                                        p.escapedName
                                    )!
                                ) === isReadonlySymbol(p)
                                && (p.flags & SymbolFlags.Optional)
                                === (getPropertyOfType(baseType,
                                    p.escapedName)!.flags
                                    & SymbolFlags.Optional)
                                && isTypeIdenticalTo(
                                    getTypeOfSymbol(p),
                                    getTypeOfPropertyOfType(
                                        baseType,
                                        p.escapedName
                                    )!
                                )))
                        {
                            return [];
                        }
                        const flag = modifierFlags
                            | (isStatic ? ModifierFlags.Static : 0);
                        const name = getPropertyNameNodeForSymbol(p, context);
                        const firstPropertyLikeDecl = find(
                            p.declarations,
                            or(
                                isPropertyDeclaration,
                                isAccessor,
                                isVariableDeclaration,
                                isPropertySignature,
                                isBinaryExpression,
                                isPropertyAccessExpression
                            )
                        );
                        if (p.flags & SymbolFlags.Accessor && useAccessors) {
                            const result: AccessorDeclaration[] = [];
                            if (p.flags & SymbolFlags.SetAccessor) {
                                result.push(
                                    setTextRange(
                                        createSetAccessor(
                                            /*decorators*/ undefined,
                                            createModifiersFromModifierFlags(flag),
                                            name,
                                            [createParameter(
                                                /*decorators*/ undefined,
                                                /*modifiers*/ undefined,
                                                /*dotDotDotToken*/ undefined,
                                                'arg',
                                                /*questionToken*/ undefined,
                                                isPrivate
                                                    ? undefined
                                                    : serializeTypeForDeclaration(
                                                        getTypeOfSymbol(p),
                                                        p
                                                    )
                                            )],
                                            /*body*/ undefined
                                        ),
                                        find(p.declarations, isSetAccessor)
                                            || firstPropertyLikeDecl
                                    )
                                );
                            }
                            if (p.flags & SymbolFlags.GetAccessor) {
                                const isPrivate = modifierFlags
                                    & ModifierFlags.Private;
                                result.push(
                                    setTextRange(
                                        createGetAccessor(
                                            /*decorators*/ undefined,
                                            createModifiersFromModifierFlags(flag),
                                            name,
                                            [],
                                            isPrivate
                                                ? undefined
                                                : serializeTypeForDeclaration(
                                                    getTypeOfSymbol(p),
                                                    p
                                                ),
                                            /*body*/ undefined
                                        ),
                                        find(p.declarations, isGetAccessor)
                                            || firstPropertyLikeDecl
                                    )
                                );
                            }
                            return result;
                        } // This is an else/if as accessors and properties can't merge in TS, but might in JS
                        // If this happens, we assume the accessor takes priority, as it imposes more constraints
                        else if (p.flags
                            & (SymbolFlags.Property | SymbolFlags.Variable))
                        {
                            return setTextRange(
                                createProperty(
                                    /*decorators*/ undefined,
                                    createModifiersFromModifierFlags(
                                        (isReadonlySymbol(p)
                                            ? ModifierFlags.Readonly
                                            : 0) | flag
                                    ),
                                    name,
                                    p.flags & SymbolFlags.Optional
                                        ? createToken(SyntaxKind.QuestionToken)
                                        : undefined,
                                    isPrivate
                                        ? undefined
                                        : serializeTypeForDeclaration(
                                            getTypeOfSymbol(p),
                                            p
                                        ),
                                    // TODO: https://github.com/microsoft/TypeScript/pull/32372#discussion_r328386357
                                    // interface members can't have initializers, however class members _can_
                                    /*initializer*/ undefined
                                ),
                                find(
                                    p.declarations,
                                    or(
                                        isPropertyDeclaration,
                                        isVariableDeclaration
                                    )
                                ) || firstPropertyLikeDecl
                            );
                        }
                        if (p.flags
                            & (SymbolFlags.Method | SymbolFlags.Function))
                        {
                            const type = getTypeOfSymbol(p);
                            const signatures = getSignaturesOfType(
                                type,
                                SignatureKind.Call
                            );
                            if (flag & ModifierFlags.Private) {
                                return setTextRange(
                                    createProperty(
                                        /*decorators*/ undefined,
                                        createModifiersFromModifierFlags(
                                            (isReadonlySymbol(p)
                                                ? ModifierFlags.Readonly
                                                : 0) | flag
                                        ),
                                        name,
                                        p.flags & SymbolFlags.Optional
                                            ? createToken(
                                                SyntaxKind.QuestionToken
                                            )
                                            : undefined,
                                        /*type*/ undefined,
                                        /*initializer*/ undefined
                                    ),
                                    find(
                                        p.declarations,
                                        isFunctionLikeDeclaration
                                    ) || signatures[0]
                                        && signatures[0].declaration
                                        || p.declarations[0]
                                );
                            }

                            const results = [];
                            for (const sig of signatures) {
                                // Each overload becomes a separate method declaration, in order
                                const decl = signatureToSignatureDeclarationHelper(
                                    sig,
                                    methodKind,
                                    context
                                ) as MethodDeclaration;
                                decl.name = name; // TODO: Clone
                                if (flag) {
                                    decl
                                        .modifiers = createNodeArray(createModifiersFromModifierFlags(flag));
                                }
                                if (p.flags & SymbolFlags.Optional) {
                                    decl
                                        .questionToken = createToken(
                                            SyntaxKind.QuestionToken
                                        );
                                }
                                results
                                    .push(setTextRange(decl, sig.declaration));
                            }
                            return results as unknown as T[];
                        }
                        // The `Constructor`'s symbol isn't in the class's properties lists, obviously, since it's a signature on the static
                        return Debug
                            .fail(
                                `Unhandled class member kind! ${
                                    (p as any).__debugFlags || p.flags}`
                            );
                    };
                }

                function serializePropertySymbolForInterface(
                    p: Symbol,
                    baseType: Type | undefined
                ) {
                    return serializePropertySymbolForInterfaceWorker(
                        p, /*isStatic*/
                        false,
                        baseType
                    );
                }

                function getDeclarationWithTypeAnnotation(symbol: Symbol) {
                    return find(
                        symbol.declarations,
                        s => !!getEffectiveTypeAnnotationNode(s)
                            && !!findAncestor(
                                s,
                                n => n === enclosingDeclaration
                            )
                    );
                }

                /**
                 * Unlike `typeToTypeNodeHelper`, this handles setting up the `AllowUniqueESSymbolType` flag
                 * so a `unique symbol` is returned when appropriate for the input symbol, rather than `typeof sym`
                 */
                function serializeTypeForDeclaration(
                    type: Type,
                    symbol: Symbol
                ) {
                    const declWithExistingAnnotation = getDeclarationWithTypeAnnotation(symbol);
                    if (declWithExistingAnnotation
                        && !isFunctionLikeDeclaration(declWithExistingAnnotation))
                    {
                        // try to reuse the existing annotation
                        const existing = getEffectiveTypeAnnotationNode(declWithExistingAnnotation)!;
                        const transformed = visitNode(
                            existing,
                            visitExistingNodeTreeSymbols
                        );
                        return transformed === existing
                            ? getMutableClone(existing)
                            : transformed;
                    }
                    const oldFlags = context.flags;
                    if (type.flags & TypeFlags.UniqueESSymbol
                        && type.symbol === symbol)
                    {
                        context.flags |= NodeBuilderFlags
                            .AllowUniqueESSymbolType;
                    }
                    const result = typeToTypeNodeHelper(type, context);
                    context.flags = oldFlags;
                    return result;

                    function visitExistingNodeTreeSymbols<T extends Node>(
                        node: T
                    ): Node {
                        if (isJSDocAllType(node)) {
                            return createKeywordTypeNode(SyntaxKind
                                .AnyKeyword);
                        }
                        if (isJSDocUnknownType(node)) {
                            return createKeywordTypeNode(
                                SyntaxKind.UnknownKeyword
                            );
                        }
                        if (isJSDocNullableType(node)) {
                            return createUnionTypeNode(
                                [visitNode(
                                    node.type,
                                    visitExistingNodeTreeSymbols
                                ),
                                    createKeywordTypeNode(SyntaxKind
                                        .NullKeyword)]
                            );
                        }
                        if (isJSDocOptionalType(node)) {
                            return createUnionTypeNode(
                                [visitNode(
                                    node.type,
                                    visitExistingNodeTreeSymbols
                                ), createKeywordTypeNode(
                                    SyntaxKind.UndefinedKeyword
                                )]
                            );
                        }
                        if (isJSDocNonNullableType(node)) {
                            return visitNode(
                                node.type,
                                visitExistingNodeTreeSymbols
                            );
                        }
                        if ((isExpressionWithTypeArguments(node)
                            || isTypeReferenceNode(node))
                            && isJSDocIndexSignature(node))
                        {
                            return createTypeLiteralNode(
                                [createIndexSignature(
                                    /*decorators*/ undefined,
                                    /*modifiers*/ undefined,
                                    [createParameter(
                                        /*decorators*/ undefined,
                                        /*modifiers*/ undefined,
                                        /*dotdotdotToken*/ undefined,
                                        'x',
                                        /*questionToken*/ undefined,
                                        visitNode(
                                            node.typeArguments![0],
                                            visitExistingNodeTreeSymbols
                                        )
                                    )],
                                    visitNode(
                                        node.typeArguments![1],
                                        visitExistingNodeTreeSymbols
                                    )
                                )]
                            );
                        }
                        if (isJSDocFunctionType(node)) {
                            if (isJSDocConstructSignature(node)) {
                                let newTypeNode: TypeNode | undefined;
                                return createConstructorTypeNode(
                                    visitNodes(
                                        node.typeParameters,
                                        visitExistingNodeTreeSymbols
                                    ),
                                    mapDefined(
                                        node.parameters,
                                        (p, i) => p.name && isIdentifier(
                                            p.name
                                        ) && p.name.escapedText === 'new'
                                            ? (newTypeNode = p.type, undefined)
                                            : createParameter(
                                                /*decorators*/ undefined,
                                                /*modifiers*/ undefined,
                                                p.dotDotDotToken,
                                                p.name || p.dotDotDotToken
                                                    ? `args`
                                                    : `arg${i}`,
                                                p.questionToken,
                                                visitNode(
                                                    p.type,
                                                    visitExistingNodeTreeSymbols
                                                ),
                                                /*initializer*/ undefined
                                            )
                                    ),
                                    visitNode(
                                        newTypeNode || node.type,
                                        visitExistingNodeTreeSymbols
                                    )
                                );
                            } else {
                                return createFunctionTypeNode(
                                    visitNodes(
                                        node.typeParameters,
                                        visitExistingNodeTreeSymbols
                                    ),
                                    map(
                                        node.parameters,
                                        (p, i) => createParameter(
                                            /*decorators*/ undefined,
                                            /*modifiers*/ undefined,
                                            p.dotDotDotToken,
                                            p.name || p.dotDotDotToken
                                                ? `args`
                                                : `arg${i}`,
                                            p.questionToken,
                                            visitNode(
                                                p.type,
                                                visitExistingNodeTreeSymbols
                                            ),
                                            /*initializer*/ undefined
                                        )
                                    ),
                                    visitNode(
                                        node.type,
                                        visitExistingNodeTreeSymbols
                                    )
                                );
                            }
                        }
                        if (isLiteralImportTypeNode(node)) {
                            return updateImportTypeNode(
                                node,
                                updateLiteralTypeNode(
                                    node.argument,
                                    rewriteModuleSpecifier(
                                        node,
                                        node.argument.literal
                                    )
                                ),
                                node.qualifier,
                                visitNodes(
                                    node.typeArguments,
                                    visitExistingNodeTreeSymbols,
                                    isTypeNode
                                ),
                                node.isTypeOf
                            );
                        }

                        if (isEntityName(node)
                            || isEntityNameExpression(node))
                        {
                            const leftmost = getFirstIdentifier(node);
                            const sym = resolveEntityName(
                                leftmost,
                                SymbolFlags.All, /*ignoreErrors*/
                                true, /*dontResolveALias*/
                                true
                            );
                            if (sym) {
                                includePrivateSymbol(sym);
                                if (isIdentifier(node)
                                    && sym.flags & SymbolFlags.TypeParameter)
                                {
                                    const name = typeParameterToName(
                                        getDeclaredTypeOfSymbol(sym),
                                        context
                                    );
                                    if (idText(name) !== idText(node)) {
                                        return name;
                                    }
                                    return node;
                                }
                            }
                        }

                        return visitEachChild(
                            node,
                            visitExistingNodeTreeSymbols,
                            nullTransformationContext
                        );
                    }

                    function rewriteModuleSpecifier(
                        parent: ImportTypeNode,
                        lit: StringLiteral
                    ) {
                        if (bundled) {
                            if (context.tracker
                                && context.tracker.moduleResolverHost)
                            {
                                const targetFile = getExternalModuleFileFromDeclaration(parent);
                                if (targetFile) {
                                    const getCanonicalFileName = createGetCanonicalFileName(
                                        !!host.useCaseSensitiveFileNames
                                    );
                                    const resolverHost = {
                                        getCanonicalFileName,
                                        getCurrentDirectory:
                                            context.tracker.moduleResolverHost
                                                .getCurrentDirectory
                                                ? () => context.tracker
                                                    .moduleResolverHost!
                                                    .getCurrentDirectory!()
                                                : () => '',
                                        getCommonSourceDirectory: () => context
                                            .tracker.moduleResolverHost!
                                            .getCommonSourceDirectory()
                                    };
                                    const newName = getResolvedExternalModuleName(
                                        resolverHost,
                                        targetFile
                                    );
                                    return createLiteral(newName);
                                }
                            }
                        } else {
                            if (context.tracker
                                && context.tracker
                                    .trackExternalModuleSymbolOfImportTypeNode)
                            {
                                const moduleSym = resolveExternalModuleNameWorker(
                                    lit,
                                    lit, /*moduleNotFoundError*/
                                    undefined
                                );
                                if (moduleSym) {
                                    context.tracker
                                        .trackExternalModuleSymbolOfImportTypeNode(moduleSym);
                                }
                            }
                        }
                        return lit;
                    }
                }

                function serializeSignatures(
                    kind: SignatureKind,
                    input: Type,
                    baseType: Type | undefined,
                    outputKind: SyntaxKind
                ) {
                    const signatures = getSignaturesOfType(input, kind);
                    if (kind === SignatureKind.Construct) {
                        if (!baseType
                            && every(
                                signatures,
                                s => length(s.parameters) === 0
                            ))
                        {
                            return []; // No base type, every constructor is empty - elide the extraneous `constructor()`
                        }
                        if (baseType) {
                            // If there is a base type, if every signature in the class is identical to a signature in the baseType, elide all the declarations
                            const baseSigs = getSignaturesOfType(
                                baseType,
                                SignatureKind.Construct
                            );
                            if (!length(baseSigs)
                                && every(
                                    signatures,
                                    s => length(s.parameters) === 0
                                ))
                            {
                                return []; // Base had no explicit signatures, if all our signatures are also implicit, return an empty list
                            }
                            if (baseSigs.length === signatures.length) {
                                let failed = false;
                                for (let i = 0; i < baseSigs.length; i++) {
                                    if (!compareSignaturesIdentical(
                                        signatures[i],
                                        baseSigs[i], /*partialMatch*/
                                        false, /*ignoreThisTypes*/
                                        false, /*ignoreReturnTypes*/
                                        true,
                                        compareTypesIdentical
                                    )) {
                                        failed = true;
                                        break;
                                    }
                                }
                                if (!failed) {
                                    return []; // Every signature was identical - elide constructor list as it is inherited
                                }
                            }
                        }
                        let privateProtected: ModifierFlags = 0;
                        for (const s of signatures) {
                            if (s.declaration) {
                                privateProtected |= getSelectedModifierFlags(
                                    s.declaration,
                                    ModifierFlags.Private
                                        | ModifierFlags.Protected
                                );
                            }
                        }
                        if (privateProtected) {
                            return [setTextRange(
                                createConstructor(
                                    /*decorators*/ undefined,
                                    createModifiersFromModifierFlags(privateProtected),
                                    /*parameters*/ [],
                                    /*body*/ undefined
                                ),
                                signatures[0].declaration
                            )];
                        }
                    }

                    const results = [];
                    for (const sig of signatures) {
                        // Each overload becomes a separate constructor declaration, in order
                        const decl = signatureToSignatureDeclarationHelper(
                            sig,
                            outputKind,
                            context
                        );
                        results.push(setTextRange(decl, sig.declaration));
                    }
                    return results;
                }

                function serializeIndexSignatures(
                    input: Type,
                    baseType: Type | undefined
                ) {
                    const results: IndexSignatureDeclaration[] = [];
                    for (const type of [IndexKind.String, IndexKind.Number]) {
                        const info = getIndexInfoOfType(input, type);
                        if (info) {
                            if (baseType) {
                                const baseInfo = getIndexInfoOfType(
                                    baseType,
                                    type
                                );
                                if (baseInfo) {
                                    if (isTypeIdenticalTo(
                                        info.type,
                                        baseInfo.type
                                    )) {
                                        continue; // elide identical index signatures
                                    }
                                }
                            }
                            results
                                .push(
                                    indexInfoToIndexSignatureDeclarationHelper(
                                        info,
                                        type,
                                        context
                                    )
                                );
                        }
                    }
                    return results;
                }

                function serializeBaseType(
                    t: Type,
                    staticType: Type,
                    rootName: string
                ) {
                    const ref = trySerializeAsTypeReference(t);
                    if (ref) {
                        return ref;
                    }
                    const tempName = getUnusedName(`${rootName}_base`);
                    const statement = createVariableStatement(
                        /*modifiers*/ undefined,
                        createVariableDeclarationList(
                            [
                                createVariableDeclaration(
                                    tempName,
                                    typeToTypeNodeHelper(staticType, context)
                                )
                            ],
                            NodeFlags.Const
                        )
                    );
                    addResult(statement, ModifierFlags.None);
                    return createExpressionWithTypeArguments(
                        /*typeArgs*/ undefined,
                        createIdentifier(tempName)
                    );
                }

                function trySerializeAsTypeReference(t: Type) {
                    let typeArgs: TypeNode[] | undefined;
                    let reference: Expression | undefined;
                    // We don't use `isValueSymbolAccessible` below. since that considers alternative containers (like modules)
                    // which we can't write out in a syntactically valid way as an expression
                    if ((t as TypeReference).target
                        && getAccessibleSymbolChain(
                            (t as TypeReference).target.symbol,
                            enclosingDeclaration,
                            SymbolFlags.Value, /*useOnlyExternalAliasing*/
                            false
                        ))
                    {
                        typeArgs = map(
                            getTypeArguments(t as TypeReference),
                            t => typeToTypeNodeHelper(t, context)
                        );
                        reference = symbolToExpression(
                            (t as TypeReference).target.symbol,
                            context,
                            SymbolFlags.Type
                        );
                    } else if (t.symbol
                        && getAccessibleSymbolChain(
                            t.symbol,
                            enclosingDeclaration,
                            SymbolFlags.Value, /*useOnlyExternalAliasing*/
                            false
                        ))
                    {
                        reference = symbolToExpression(
                            t.symbol,
                            context,
                            SymbolFlags.Type
                        );
                    }
                    if (reference) {
                        return createExpressionWithTypeArguments(
                            typeArgs,
                            reference
                        );
                    }
                }

                function getUnusedName(input: string,
                    symbol?: Symbol): string
                {
                    if (symbol) {
                        if (context.remappedSymbolNames!
                            .has('' + getSymbolId(symbol)))
                        {
                            return context.remappedSymbolNames!
                                .get('' + getSymbolId(symbol))!;
                        }
                    }
                    if (symbol) {
                        input = getNameCandidateWorker(symbol, input);
                    }
                    let i = 0;
                    const original = input;
                    while (context.usedSymbolNames!.has(input)) {
                        i++;
                        input = `${original}_${i}`;
                    }
                    context.usedSymbolNames!.set(input, true);
                    if (symbol) {
                        context.remappedSymbolNames!
                            .set('' + getSymbolId(symbol), input);
                    }
                    return input;
                }

                function getNameCandidateWorker(
                    symbol: Symbol,
                    localName: string
                ) {
                    if (localName === InternalSymbolName.Default
                        || localName === InternalSymbolName.Class
                        || localName === InternalSymbolName.Function)
                    {
                        const flags = context.flags;
                        context.flags |= NodeBuilderFlags.InInitialEntityName;
                        const nameCandidate = getNameOfSymbolAsWritten(
                            symbol,
                            context
                        );
                        context.flags = flags;
                        localName = nameCandidate.length > 0
                            && isSingleOrDoubleQuote(
                                nameCandidate.charCodeAt(0)
                            )
                            ? stripQuotes(nameCandidate)
                            : nameCandidate;
                    }
                    if (localName === InternalSymbolName.Default) {
                        localName = '_default';
                    } else if (localName === InternalSymbolName.ExportEquals) {
                        localName = '_exports';
                    }
                    localName = isIdentifierText(localName, languageVersion)
                        && !isStringANonContextualKeyword(localName)
                        ? localName
                        : '_' + localName.replace(/[^a-zA-Z0-9]/g, '_');
                    return localName;
                }

                function getInternalSymbolName(
                    symbol: Symbol,
                    localName: string
                ) {
                    if (context.remappedSymbolNames!
                        .has('' + getSymbolId(symbol)))
                    {
                        return context.remappedSymbolNames!
                            .get('' + getSymbolId(symbol))!;
                    }
                    localName = getNameCandidateWorker(symbol, localName);
                    // The result of this is going to be used as the symbol's name - lock it in, so `getUnusedName` will also pick it up
                    context.remappedSymbolNames!.set(
                        '' + getSymbolId(symbol),
                        localName
                    );
                    return localName;
                }
            }
        }

        function typePredicateToString(
            typePredicate: TypePredicate,
            enclosingDeclaration?: Node,
            flags: TypeFormatFlags = TypeFormatFlags
                .UseAliasDefinedOutsideCurrentScope,
            writer?: EmitTextWriter
        ): string {
            return writer
                ? typePredicateToStringWorker(writer).getText()
                : usingSingleLineStringWriter(typePredicateToStringWorker);

            function typePredicateToStringWorker(writer: EmitTextWriter) {
                const predicate = createTypePredicateNodeWithModifier(
                    typePredicate.kind === TypePredicateKind.AssertsThis
                        || typePredicate.kind
                        === TypePredicateKind.AssertsIdentifier
                        ? createToken(SyntaxKind.AssertsKeyword)
                        : undefined,
                    typePredicate.kind === TypePredicateKind.Identifier
                        || typePredicate.kind
                        === TypePredicateKind.AssertsIdentifier
                        ? createIdentifier(typePredicate.parameterName)
                        : createThisTypeNode(),
                    typePredicate.type && nodeBuilder.typeToTypeNode(
                        typePredicate.type,
                        enclosingDeclaration,
                        toNodeBuilderFlags(
                            flags
                        ) | NodeBuilderFlags.IgnoreErrors
                            | NodeBuilderFlags
                                .WriteTypeParametersInQualifiedName
                    )! // TODO: GH#18217
                );
                const printer = createPrinter({ removeComments: true });
                const sourceFile = enclosingDeclaration
                    && getSourceFileOfNode(enclosingDeclaration);
                printer.writeNode(
                    EmitHint.Unspecified,
                    predicate, /*sourceFile*/
                    sourceFile,
                    writer
                );
                return writer;
            }
        }

        function formatUnionTypes(types: readonly Type[]): Type[] {
            const result: Type[] = [];
            let flags: TypeFlags = 0;
            for (let i = 0; i < types.length; i++) {
                const t = types[i];
                flags |= t.flags;
                if (!(t.flags & TypeFlags.Nullable)) {
                    if (t.flags
                        & (TypeFlags.BooleanLiteral | TypeFlags.EnumLiteral))
                    {
                        const baseType = t.flags & TypeFlags.BooleanLiteral
                            ? booleanType
                            : getBaseTypeOfEnumLiteralType(<LiteralType> t);
                        if (baseType.flags & TypeFlags.Union) {
                            const count = (<UnionType> baseType).types.length;
                            if (i + count <= types.length
                                && getRegularTypeOfLiteralType(
                                    types[i + count - 1]
                                )
                                === getRegularTypeOfLiteralType(
                                    (<UnionType> baseType).types[count - 1]
                                ))
                            {
                                result.push(baseType);
                                i += count - 1;
                                continue;
                            }
                        }
                    }
                    result.push(t);
                }
            }
            if (flags & TypeFlags.Null) result.push(nullType);
            if (flags & TypeFlags.Undefined) result.push(undefinedType);
            return result || types;
        }

        function visibilityToString(flags: ModifierFlags): string | undefined {
            if (flags === ModifierFlags.Private) {
                return 'private';
            }
            if (flags === ModifierFlags.Protected) {
                return 'protected';
            }
            return 'public';
        }

        function getTypeAliasForTypeLiteral(type: Type): Symbol | undefined {
            if (type.symbol && type.symbol.flags & SymbolFlags.TypeLiteral) {
                const node = findAncestor(
                    type.symbol.declarations[0].parent,
                    n => n.kind !== SyntaxKind.ParenthesizedType
                )!;
                if (node.kind === SyntaxKind.TypeAliasDeclaration) {
                    return getSymbolOfNode(node);
                }
            }
            return undefined;
        }

        function isTopLevelInExternalModuleAugmentation(node: Node): boolean {
            return node && node.parent
                && node.parent.kind === SyntaxKind.ModuleBlock
                && isExternalModuleAugmentation(node.parent.parent);
        }

        interface NodeBuilderContext {
            enclosingDeclaration: Node | undefined;
            flags: NodeBuilderFlags;
            tracker: SymbolTracker;

            // State
            encounteredError: boolean;
            visitedTypes: Map<true> | undefined;
            symbolDepth: Map<number> | undefined;
            inferTypeParameters: TypeParameter[] | undefined;
            approximateLength: number;
            truncating?: boolean;
            typeParameterSymbolList?: Map<true>;
            typeParameterNames?: Map<Identifier>;
            typeParameterNamesByText?: Map<true>;
            usedSymbolNames?: Map<true>;
            remappedSymbolNames?: Map<string>;
        }

        function isDefaultBindingContext(location: Node) {
            return location.kind === SyntaxKind.SourceFile
                || isAmbientModule(location);
        }

        function getNameOfSymbolFromNameType(
            symbol: Symbol,
            context?: NodeBuilderContext
        ) {
            const nameType = symbol.nameType;
            if (nameType) {
                if (nameType.flags & TypeFlags.StringOrNumberLiteral) {
                    const name = ''
                        + (<StringLiteralType | NumberLiteralType> nameType)
                            .value;
                    if (!isIdentifierText(name, compilerOptions.target)
                        && !isNumericLiteralName(name))
                    {
                        return `"${escapeString(
                            name,
                            CharacterCodes.doubleQuote
                        )}"`;
                    }
                    if (isNumericLiteralName(name) && startsWith(name, '-')) {
                        return `[${name}]`;
                    }
                    return name;
                }
                if (nameType.flags & TypeFlags.UniqueESSymbol) {
                    return `[${
                        getNameOfSymbolAsWritten(
                        (<UniqueESSymbolType> nameType).symbol,
                        context
                    )}]`;
                }
            }
        }

        /**
         * Gets a human-readable name for a symbol.
         * Should *not* be used for the right-hand side of a `.` -- use `symbolName(symbol)` for that instead.
         *
         * Unlike `symbolName(symbol)`, this will include quotes if the name is from a string literal.
         * It will also use a representation of a number as written instead of a decimal form, e.g. `0o11` instead of `9`.
         */
        function getNameOfSymbolAsWritten(
            symbol: Symbol,
            context?: NodeBuilderContext
        ): string {
            if (context && symbol.escapedName === InternalSymbolName.Default
                && !(context.flags
                    & NodeBuilderFlags.UseAliasDefinedOutsideCurrentScope)
                // If it's not the first part of an entity name, it must print as `default`
                && (!(context.flags & NodeBuilderFlags.InInitialEntityName)
                    // if the symbol is synthesized, it will only be referenced externally it must print as `default`
                    || !symbol.declarations
                    // if not in the same binding context (source file, module declaration), it must print as `default`
                    || (context.enclosingDeclaration
                        && findAncestor(
                            symbol.declarations[0],
                            isDefaultBindingContext
                        )
                        !== findAncestor(
                            context.enclosingDeclaration,
                            isDefaultBindingContext
                        ))))
            {
                return 'default';
            }
            if (symbol.declarations && symbol.declarations.length) {
                let declaration = firstDefined(
                    symbol.declarations,
                    d => getNameOfDeclaration(d) ? d : undefined
                ); // Try using a declaration with a name, first
                const name = declaration && getNameOfDeclaration(declaration);
                if (declaration && name) {
                    if (isCallExpression(declaration)
                        && isBindableObjectDefinePropertyCall(declaration))
                    {
                        return symbolName(symbol);
                    }
                    if (isComputedPropertyName(name)
                        && !(getCheckFlags(symbol) & CheckFlags.Late)
                        && symbol.nameType
                        && symbol.nameType.flags
                        & TypeFlags.StringOrNumberLiteral)
                    {
                        // Computed property name isn't late bound, but has a well-known name type - use name type to generate a symbol name
                        const result = getNameOfSymbolFromNameType(
                            symbol,
                            context
                        );
                        if (result !== undefined) {
                            return result;
                        }
                    }
                    return declarationNameToString(name);
                }
                if (!declaration) {
                    declaration = symbol.declarations
                        [0]; // Declaration may be nameless, but we'll try anyway
                }
                if (declaration.parent
                    && declaration.parent.kind
                    === SyntaxKind.VariableDeclaration)
                {
                    return declarationNameToString(
                        (<VariableDeclaration> declaration.parent).name
                    );
                }
                switch (declaration.kind) {
                    case SyntaxKind.ClassExpression:
                    case SyntaxKind.FunctionExpression:
                    case SyntaxKind.ArrowFunction:
                        if (context && !context.encounteredError
                            && !(context.flags
                                & NodeBuilderFlags.AllowAnonymousIdentifier))
                        {
                            context.encounteredError = true;
                        }
                        return declaration.kind === SyntaxKind.ClassExpression
                            ? '(Anonymous class)'
                            : '(Anonymous function)';
                }
            }
            const name = getNameOfSymbolFromNameType(symbol, context);
            return name !== undefined ? name : symbolName(symbol);
        }

        function isDeclarationVisible(node: Node): boolean {
            if (node) {
                const links = getNodeLinks(node);
                if (links.isVisible === undefined) {
                    links.isVisible = !!determineIfDeclarationIsVisible();
                }
                return links.isVisible;
            }

            return false;

            function determineIfDeclarationIsVisible() {
                switch (node.kind) {
                    case SyntaxKind.JSDocCallbackTag:
                    case SyntaxKind.JSDocTypedefTag:
                    case SyntaxKind.JSDocEnumTag:
                        // Top-level jsdoc type aliases are considered exported
                        // First parent is comment node, second is hosting declaration or token; we only care about those tokens or declarations whose parent is a source file
                        return !!(node.parent && node.parent.parent
                            && node.parent.parent.parent
                            && isSourceFile(node.parent.parent.parent));
                    case SyntaxKind.BindingElement:
                        return isDeclarationVisible(node.parent.parent);
                    case SyntaxKind.VariableDeclaration:
                        if (isBindingPattern(
                            (node as VariableDeclaration).name
                        )
                            && !((node as VariableDeclaration)
                                .name as BindingPattern).elements.length)
                        {
                            // If the binding pattern is empty, this variable declaration is not visible
                            return false;
                        }
                        // falls through
                    case SyntaxKind.ModuleDeclaration:
                    case SyntaxKind.ClassDeclaration:
                    case SyntaxKind.InterfaceDeclaration:
                    case SyntaxKind.TypeAliasDeclaration:
                    case SyntaxKind.FunctionDeclaration:
                    case SyntaxKind.EnumDeclaration:
                    case SyntaxKind.ImportEqualsDeclaration:
                        // external module augmentation is always visible
                        if (isExternalModuleAugmentation(node)) {
                            return true;
                        }
                        const parent = getDeclarationContainer(node);
                        // If the node is not exported or it is not ambient module element (except import declaration)
                        if (!(getCombinedModifierFlags(node as Declaration)
                            & ModifierFlags.Export)
                            && !(node.kind
                                !== SyntaxKind.ImportEqualsDeclaration
                                && parent.kind !== SyntaxKind.SourceFile
                                && parent.flags & NodeFlags.Ambient))
                        {
                            return isGlobalSourceFile(parent);
                        }
                        // Exported members/ambient module elements (exception import declaration) are visible if parent is visible
                        return isDeclarationVisible(parent);
                    case SyntaxKind.PropertyDeclaration:
                    case SyntaxKind.PropertySignature:
                    case SyntaxKind.GetAccessor:
                    case SyntaxKind.SetAccessor:
                    case SyntaxKind.MethodDeclaration:
                    case SyntaxKind.MethodSignature:
                        if (hasModifier(
                            node,
                            ModifierFlags.Private | ModifierFlags.Protected
                        )) {
                            // Private/protected properties/methods are not visible
                            return false;
                        }
                        // Public properties/methods are visible if its parents are visible, so:
                    // falls through
                    case SyntaxKind.Constructor:
                    case SyntaxKind.ConstructSignature:
                    case SyntaxKind.CallSignature:
                    case SyntaxKind.IndexSignature:
                    case SyntaxKind.Parameter:
                    case SyntaxKind.ModuleBlock:
                    case SyntaxKind.FunctionType:
                    case SyntaxKind.ConstructorType:
                    case SyntaxKind.TypeLiteral:
                    case SyntaxKind.TypeReference:
                    case SyntaxKind.ArrayType:
                    case SyntaxKind.TupleType:
                    case SyntaxKind.UnionType:
                    case SyntaxKind.IntersectionType:
                    case SyntaxKind.ParenthesizedType:
                        return isDeclarationVisible(node.parent);

                    // Default binding, import specifier and namespace import is visible
                    // only on demand so by default it is not visible
                    case SyntaxKind.ImportClause:
                    case SyntaxKind.NamespaceImport:
                    case SyntaxKind.ImportSpecifier:
                        return false;

                    // Type parameters are always visible
                    case SyntaxKind.TypeParameter:

                    // Source file and namespace export are always visible
                    // falls through
                    case SyntaxKind.SourceFile:
                    case SyntaxKind.NamespaceExportDeclaration:
                        return true;

                    // Export assignments do not create name bindings outside the module
                    case SyntaxKind.ExportAssignment:
                        return false;
                    default:
                        return false;
                }
            }
        }

        function collectLinkedAliases(
            node: Identifier,
            setVisibility?: boolean
        ): Node[] | undefined {
            let exportSymbol: Symbol | undefined;
            if (node.parent
                && node.parent.kind === SyntaxKind.ExportAssignment)
            {
                exportSymbol = resolveName(
                    node,
                    node.escapedText,
                    SymbolFlags.Value | SymbolFlags.Type
                        | SymbolFlags.Namespace
                        | SymbolFlags.Alias, /*nameNotFoundMessage*/
                    undefined,
                    node, /*isUse*/
                    false
                );
            } else if (node.parent.kind === SyntaxKind.ExportSpecifier) {
                exportSymbol = getTargetOfExportSpecifier(
                    <ExportSpecifier> node.parent,
                    SymbolFlags.Value | SymbolFlags.Type
                        | SymbolFlags.Namespace | SymbolFlags.Alias
                );
            }
            let result: Node[] | undefined;
            let visited: Map<true> | undefined;
            if (exportSymbol) {
                visited = createMap();
                visited.set('' + getSymbolId(exportSymbol), true);
                buildVisibleNodeList(exportSymbol.declarations);
            }
            return result;

            function buildVisibleNodeList(declarations: Declaration[]) {
                forEach(
                    declarations,
                    declaration => {
                        const resultNode = getAnyImportSyntax(declaration)
                            || declaration;
                        if (setVisibility) {
                            getNodeLinks(declaration).isVisible = true;
                        } else {
                            result = result || [];
                            pushIfUnique(result, resultNode);
                        }

                        if (isInternalModuleImportEqualsDeclaration(declaration)) {
                            // Add the referenced top container visible
                            const internalModuleReference = <Identifier
                                | QualifiedName> declaration.moduleReference;
                            const firstIdentifier = getFirstIdentifier(internalModuleReference);
                            const importSymbol = resolveName(
                                declaration,
                                firstIdentifier.escapedText,
                                SymbolFlags.Value | SymbolFlags.Type
                                    | SymbolFlags.Namespace,
                                undefined,
                                undefined, /*isUse*/
                                false
                            );
                            const id = importSymbol && ''
                                + getSymbolId(importSymbol);
                            if (importSymbol && !visited!.has(id!)) {
                                visited!.set(id!, true);
                                buildVisibleNodeList(importSymbol
                                    .declarations);
                            }
                        }
                    }
                );
            }
        }

        /**
         * Push an entry on the type resolution stack. If an entry with the given target and the given property name
         * is already on the stack, and no entries in between already have a type, then a circularity has occurred.
         * In this case, the result values of the existing entry and all entries pushed after it are changed to false,
         * and the value false is returned. Otherwise, the new entry is just pushed onto the stack, and true is returned.
         * In order to see if the same query has already been done before, the target object and the propertyName both
         * must match the one passed in.
         *
         * @param target The symbol, type, or signature whose type is being queried
         * @param propertyName The property name that should be used to query the target for its type
         */
        function pushTypeResolution(
            target: TypeSystemEntity,
            propertyName: TypeSystemPropertyName
        ): boolean {
            const resolutionCycleStartIndex = findResolutionCycleStartIndex(
                target,
                propertyName
            );
            if (resolutionCycleStartIndex >= 0) {
                // A cycle was found
                const { length } = resolutionTargets;
                for (let i = resolutionCycleStartIndex; i < length; i++) {
                    resolutionResults[i] = false;
                }
                return false;
            }
            resolutionTargets.push(target);
            resolutionResults.push(/*items*/ true);
            resolutionPropertyNames.push(propertyName);
            return true;
        }

        function findResolutionCycleStartIndex(
            target: TypeSystemEntity,
            propertyName: TypeSystemPropertyName
        ): number {
            for (let i = resolutionTargets.length - 1; i >= 0; i--) {
                if (hasType(resolutionTargets[i],
                    resolutionPropertyNames[i]))
                {
                    return -1;
                }
                if (resolutionTargets[i] === target
                    && resolutionPropertyNames[i] === propertyName)
                {
                    return i;
                }
            }
            return -1;
        }

        function hasType(
            target: TypeSystemEntity,
            propertyName: TypeSystemPropertyName
        ): boolean {
            switch (propertyName) {
                case TypeSystemPropertyName.Type:
                    return !!getSymbolLinks(<Symbol> target).type;
                case TypeSystemPropertyName.EnumTagType:
                    return !!(getNodeLinks(target as JSDocEnumTag)
                        .resolvedEnumType);
                case TypeSystemPropertyName.DeclaredType:
                    return !!getSymbolLinks(<Symbol> target).declaredType;
                case TypeSystemPropertyName.ResolvedBaseConstructorType:
                    return !!(<InterfaceType> target)
                        .resolvedBaseConstructorType;
                case TypeSystemPropertyName.ResolvedReturnType:
                    return !!(<Signature> target).resolvedReturnType;
                case TypeSystemPropertyName.ImmediateBaseConstraint:
                    return !!(<Type> target).immediateBaseConstraint;
                case TypeSystemPropertyName.JSDocTypeReference:
                    return !!getSymbolLinks(target as Symbol)
                        .resolvedJSDocType;
                case TypeSystemPropertyName.ResolvedTypeArguments:
                    return !!(target as TypeReference).resolvedTypeArguments;
            }
            return Debug.assertNever(propertyName);
        }

        /**
         * Pop an entry from the type resolution stack and return its associated result value. The result value will
         * be true if no circularities were detected, or false if a circularity was found.
         */
        function popTypeResolution(): boolean {
            resolutionTargets.pop();
            resolutionPropertyNames.pop();
            return resolutionResults.pop()!;
        }

        function getDeclarationContainer(node: Node): Node {
            return findAncestor(
                getRootDeclaration(node),
                node => {
                    switch (node.kind) {
                        case SyntaxKind.VariableDeclaration:
                        case SyntaxKind.VariableDeclarationList:
                        case SyntaxKind.ImportSpecifier:
                        case SyntaxKind.NamedImports:
                        case SyntaxKind.NamespaceImport:
                        case SyntaxKind.ImportClause:
                            return false;
                        default:
                            return true;
                    }
                }
            )!.parent;
        }

        function getTypeOfPrototypeProperty(prototype: Symbol): Type {
            // TypeScript 1.0 spec (April 2014): 8.4
            // Every class automatically contains a static property member named 'prototype',
            // the type of which is an instantiation of the class type with type Any supplied as a type argument for each type parameter.
            // It is an error to explicitly declare a static property member with the name 'prototype'.
            const classType = <InterfaceType> getDeclaredTypeOfSymbol(getParentOfSymbol(prototype)!);
            return classType.typeParameters
                ? createTypeReference(
                    <GenericType> classType,
                    map(classType.typeParameters, _ => anyType)
                )
                : classType;
        }

        // Return the type of the given property in the given type, or undefined if no such property exists
        function getTypeOfPropertyOfType(
            type: Type,
            name: __String
        ): Type | undefined {
            const prop = getPropertyOfType(type, name);
            return prop ? getTypeOfSymbol(prop) : undefined;
        }

        function getTypeOfPropertyOrIndexSignature(
            type: Type,
            name: __String
        ): Type {
            return getTypeOfPropertyOfType(type, name)
                || isNumericLiteralName(name)
                && getIndexTypeOfType(type, IndexKind.Number)
                || getIndexTypeOfType(type, IndexKind.String) || unknownType;
        }

        function isTypeAny(type: Type | undefined) {
            return type && (type.flags & TypeFlags.Any) !== 0;
        }

        // Return the type of a binding element parent. We check SymbolLinks first to see if a type has been
        // assigned by contextual typing.
        function getTypeForBindingElementParent(
            node: BindingElementGrandparent
        ) {
            const symbol = getSymbolOfNode(node);
            return symbol && getSymbolLinks(symbol).type
                || getTypeForVariableLikeDeclaration(
                    node, /*includeOptionality*/
                    false
                );
        }

        function isComputedNonLiteralName(name: PropertyName): boolean {
            return name.kind === SyntaxKind.ComputedPropertyName
                && !isStringOrNumericLiteralLike(name.expression);
        }

        function getRestType(
            source: Type,
            properties: PropertyName[],
            symbol: Symbol | undefined
        ): Type {
            source = filterType(source, t => !(t.flags & TypeFlags.Nullable));
            if (source.flags & TypeFlags.Never) {
                return emptyObjectType;
            }
            if (source.flags & TypeFlags.Union) {
                return mapType(source,
                    t => getRestType(t, properties, symbol));
            }
            const omitKeyType = getUnionType(
                map(
                    properties,
                    getLiteralTypeFromPropertyName
                )
            );
            if (isGenericObjectType(source)
                || isGenericIndexType(omitKeyType))
            {
                if (omitKeyType.flags & TypeFlags.Never) {
                    return source;
                }

                const omitTypeAlias = getGlobalOmitSymbol();
                if (!omitTypeAlias) {
                    return errorType;
                }
                return getTypeAliasInstantiation(
                    omitTypeAlias,
                    [source, omitKeyType]
                );
            }
            const members = createSymbolTable();
            for (const prop of getPropertiesOfType(source)) {
                if (!isTypeAssignableTo(
                    getLiteralTypeFromProperty(
                        prop,
                        TypeFlags.StringOrNumberLiteralOrUnique
                    ),
                    omitKeyType
                )
                    && !(getDeclarationModifierFlagsFromSymbol(prop)
                        & (ModifierFlags.Private | ModifierFlags.Protected))
                    && isSpreadableProperty(prop))
                {
                    members.set(
                        prop.escapedName,
                        getSpreadSymbol(prop, /*readonly*/ false)
                    );
                }
            }
            const stringIndexInfo = getIndexInfoOfType(
                source,
                IndexKind.String
            );
            const numberIndexInfo = getIndexInfoOfType(
                source,
                IndexKind.Number
            );
            const result = createAnonymousType(
                symbol,
                members,
                emptyArray,
                emptyArray,
                stringIndexInfo,
                numberIndexInfo
            );
            result.objectFlags |= ObjectFlags.ObjectRestType;
            return result;
        }

        // Determine the control flow type associated with a destructuring declaration or assignment. The following
        // forms of destructuring are possible:
        //   let { x } = obj;  // BindingElement
        //   let [ x ] = obj;  // BindingElement
        //   { x } = obj;      // ShorthandPropertyAssignment
        //   { x: v } = obj;   // PropertyAssignment
        //   [ x ] = obj;      // Expression
        // We construct a synthetic element access expression corresponding to 'obj.x' such that the control
        // flow analyzer doesn't have to handle all the different syntactic forms.
        function getFlowTypeOfDestructuring(
            node: BindingElement | PropertyAssignment
                | ShorthandPropertyAssignment | Expression,
            declaredType: Type
        ) {
            const reference = getSyntheticElementAccess(node);
            return reference
                ? getFlowTypeOfReference(reference, declaredType)
                : declaredType;
        }

        function getSyntheticElementAccess(
            node: BindingElement | PropertyAssignment
                | ShorthandPropertyAssignment | Expression
        ): ElementAccessExpression | undefined {
            const parentAccess = getParentElementAccess(node);
            if (parentAccess && parentAccess.flowNode) {
                const propName = getDestructuringPropertyName(node);
                if (propName) {
                    const result = <ElementAccessExpression> createNode(
                        SyntaxKind.ElementAccessExpression,
                        node.pos,
                        node.end
                    );
                    result.parent = node;
                    result.expression = <LeftHandSideExpression> parentAccess;
                    const literal = <StringLiteral> createNode(
                        SyntaxKind.StringLiteral,
                        node.pos,
                        node.end
                    );
                    literal.parent = result;
                    literal.text = propName;
                    result.argumentExpression = literal;
                    result.flowNode = parentAccess.flowNode;
                    return result;
                }
            }
        }

        function getParentElementAccess(
            node: BindingElement | PropertyAssignment
                | ShorthandPropertyAssignment | Expression
        ) {
            const ancestor = node.parent.parent;
            switch (ancestor.kind) {
                case SyntaxKind.BindingElement:
                case SyntaxKind.PropertyAssignment:
                    return getSyntheticElementAccess(
                        <BindingElement | PropertyAssignment> ancestor
                    );
                case SyntaxKind.ArrayLiteralExpression:
                    return getSyntheticElementAccess(<Expression> node.parent);
                case SyntaxKind.VariableDeclaration:
                    return (<VariableDeclaration> ancestor).initializer;
                case SyntaxKind.BinaryExpression:
                    return (<BinaryExpression> ancestor).right;
            }
        }

        function getDestructuringPropertyName(
            node: BindingElement | PropertyAssignment
                | ShorthandPropertyAssignment | Expression
        ) {
            const parent = node.parent;
            if (node.kind === SyntaxKind.BindingElement
                && parent.kind === SyntaxKind.ObjectBindingPattern)
            {
                return getLiteralPropertyNameText(
                    (<BindingElement> node).propertyName
                        || <Identifier> (<BindingElement> node).name
                );
            }
            if (node.kind === SyntaxKind.PropertyAssignment
                || node.kind === SyntaxKind.ShorthandPropertyAssignment)
            {
                return getLiteralPropertyNameText(
                    (<PropertyAssignment | ShorthandPropertyAssignment> node)
                        .name
                );
            }
            return ''
                + (<NodeArray<Node>> (<BindingPattern
                    | ArrayLiteralExpression> parent).elements).indexOf(node);
        }

        function getLiteralPropertyNameText(name: PropertyName) {
            const type = getLiteralTypeFromPropertyName(name);
            return type.flags
                & (TypeFlags.StringLiteral | TypeFlags.NumberLiteral)
                ? '' + (<StringLiteralType | NumberLiteralType> type).value
                : undefined;
        }

        /** Return the inferred type for a binding element */
        function getTypeForBindingElement(
            declaration: BindingElement
        ): Type | undefined {
            const pattern = declaration.parent;
            let parentType = getTypeForBindingElementParent(pattern.parent);
            // If no type or an any type was inferred for parent, infer that for the binding element
            if (!parentType || isTypeAny(parentType)) {
                return parentType;
            }
            // Relax null check on ambient destructuring parameters, since the parameters have no implementation and are just documentation
            if (strictNullChecks && declaration.flags & NodeFlags.Ambient
                && isParameterDeclaration(declaration))
            {
                parentType = getNonNullableType(parentType);
            }

            let type: Type | undefined;
            if (pattern.kind === SyntaxKind.ObjectBindingPattern) {
                if (declaration.dotDotDotToken) {
                    if (parentType.flags & TypeFlags.Unknown
                        || !isValidSpreadType(parentType))
                    {
                        error(
                            declaration,
                            Diagnostics
                                .Rest_types_may_only_be_created_from_object_types
                        );
                        return errorType;
                    }
                    const literalMembers: PropertyName[] = [];
                    for (const element of pattern.elements) {
                        if (!element.dotDotDotToken) {
                            literalMembers
                                .push(
                                    element.propertyName
                                        || element.name as Identifier
                                );
                        }
                    }
                    type = getRestType(
                        parentType,
                        literalMembers,
                        declaration.symbol
                    );
                } else {
                    // Use explicitly specified property name ({ p: xxx } form), or otherwise the implied name ({ p } form)
                    const name = declaration.propertyName
                        || <Identifier> declaration.name;
                    const indexType = getLiteralTypeFromPropertyName(name);
                    const declaredType = getConstraintForLocation(
                        getIndexedAccessType(
                            parentType,
                            indexType,
                            name
                        ),
                        declaration.name
                    );
                    type = getFlowTypeOfDestructuring(
                        declaration,
                        declaredType
                    );
                }
            } else {
                // This elementType will be used if the specific property corresponding to this index is not
                // present (aka the tuple element property). This call also checks that the parentType is in
                // fact an iterable or array (depending on target language).
                const elementType = checkIteratedTypeOrElementType(
                    IterationUse.Destructuring,
                    parentType,
                    undefinedType,
                    pattern
                );
                const index = pattern.elements.indexOf(declaration);
                if (declaration.dotDotDotToken) {
                    // If the parent is a tuple type, the rest element has a tuple type of the
                    // remaining tuple element types. Otherwise, the rest element has an array type with same
                    // element type as the parent type.
                    type = everyType(parentType, isTupleType)
                        ? mapType(
                            parentType,
                            t => sliceTupleType(<TupleTypeReference> t, index)
                        )
                        : createArrayType(elementType);
                } else if (isArrayLikeType(parentType)) {
                    const indexType = getLiteralType(index);
                    const accessFlags = hasDefaultValue(declaration)
                        ? AccessFlags.NoTupleBoundsCheck
                        : 0;
                    const declaredType = getConstraintForLocation(
                        getIndexedAccessTypeOrUndefined(
                            parentType,
                            indexType,
                            declaration.name,
                            accessFlags
                        ) || errorType,
                        declaration.name
                    );
                    type = getFlowTypeOfDestructuring(
                        declaration,
                        declaredType
                    );
                } else {
                    type = elementType;
                }
            }
            if (!declaration.initializer) {
                return type;
            }
            if (getEffectiveTypeAnnotationNode(walkUpBindingElementsAndPatterns(declaration))) {
                // In strict null checking mode, if a default value of a non-undefined type is specified, remove
                // undefined from the final type.
                return strictNullChecks
                    && !(getFalsyFlags(checkDeclarationInitializer(declaration))
                        & TypeFlags.Undefined)
                    ? getTypeWithFacts(type, TypeFacts.NEUndefined)
                    : type;
            }
            return getUnionType(
                [getTypeWithFacts(type, TypeFacts.NEUndefined),
                    checkDeclarationInitializer(declaration)],
                UnionReduction.Subtype
            );
        }

        function getTypeForDeclarationFromJSDocComment(declaration: Node) {
            const jsdocType = getJSDocType(declaration);
            if (jsdocType) {
                return getTypeFromTypeNode(jsdocType);
            }
            return undefined;
        }

        function isNullOrUndefined(node: Expression) {
            const expr = skipParentheses(node);
            return expr.kind === SyntaxKind.NullKeyword
                || expr.kind === SyntaxKind.Identifier
                && getResolvedSymbol(<Identifier> expr) === undefinedSymbol;
        }

        function isEmptyArrayLiteral(node: Expression) {
            const expr = skipParentheses(node);
            return expr.kind === SyntaxKind.ArrayLiteralExpression
                && (<ArrayLiteralExpression> expr).elements.length === 0;
        }

        function addOptionality(type: Type, optional = true): Type {
            return strictNullChecks && optional ? getOptionalType(type) : type;
        }

        function isParameterOfContextuallyTypedFunction(node: Declaration) {
            return node.kind === SyntaxKind.Parameter
                && (node.parent.kind === SyntaxKind.FunctionExpression
                    || node.parent.kind === SyntaxKind.ArrowFunction)
                && !!getContextualType(<Expression> node.parent);
        }

        // Return the inferred type for a variable, parameter, or property declaration
        function getTypeForVariableLikeDeclaration(
            declaration: ParameterDeclaration | PropertyDeclaration
                | PropertySignature | VariableDeclaration | BindingElement,
            includeOptionality: boolean
        ): Type | undefined {
            // A variable declared in a for..in statement is of type string, or of type keyof T when the
            // right hand expression is of a type parameter type.
            if (isVariableDeclaration(declaration)
                && declaration.parent.parent.kind
                === SyntaxKind.ForInStatement)
            {
                const indexType = getIndexType(
                    getNonNullableTypeIfNeeded(
                        checkExpression(
                            declaration.parent.parent.expression
                        )
                    )
                );
                return indexType.flags
                    & (TypeFlags.TypeParameter | TypeFlags.Index)
                    ? getExtractStringType(indexType)
                    : stringType;
            }

            if (isVariableDeclaration(declaration)
                && declaration.parent.parent.kind
                === SyntaxKind.ForOfStatement)
            {
                // checkRightHandSideOfForOf will return undefined if the for-of expression type was
                // missing properties/signatures required to get its iteratedType (like
                // [Symbol.iterator] or next). This may be because we accessed properties from anyType,
                // or it may have led to an error inside getElementTypeOfIterable.
                const forOfStatement = declaration.parent.parent;
                return checkRightHandSideOfForOf(
                    forOfStatement.expression,
                    forOfStatement.awaitModifier
                ) || anyType;
            }

            if (isBindingPattern(declaration.parent)) {
                return getTypeForBindingElement(<BindingElement> declaration);
            }

            const isOptional = includeOptionality && (
                isParameter(declaration)
                && isJSDocOptionalParameter(declaration)
                || !isBindingElement(declaration)
                && !isVariableDeclaration(declaration)
                && !!declaration.questionToken
            );

            // Use type from type annotation if one is present
            const declaredType = tryGetTypeFromEffectiveTypeNode(declaration);
            if (declaredType) {
                return addOptionality(declaredType, isOptional);
            }

            if ((noImplicitAny || isInJSFile(declaration))
                && declaration.kind === SyntaxKind.VariableDeclaration
                && !isBindingPattern(declaration.name)
                && !(getCombinedModifierFlags(declaration)
                    & ModifierFlags.Export)
                && !(declaration.flags & NodeFlags.Ambient))
            {
                // If --noImplicitAny is on or the declaration is in a Javascript file,
                // use control flow tracked 'any' type for non-ambient, non-exported var or let variables with no
                // initializer or a 'null' or 'undefined' initializer.
                if (!(getCombinedNodeFlags(declaration) & NodeFlags.Const)
                    && (!declaration.initializer
                        || isNullOrUndefined(declaration.initializer)))
                {
                    return autoType;
                }
                // Use control flow tracked 'any[]' type for non-ambient, non-exported variables with an empty array
                // literal initializer.
                if (declaration.initializer
                    && isEmptyArrayLiteral(declaration.initializer))
                {
                    return autoArrayType;
                }
            }

            if (declaration.kind === SyntaxKind.Parameter) {
                const func = <FunctionLikeDeclaration> declaration.parent;
                // For a parameter of a set accessor, use the type of the get accessor if one is present
                if (func.kind === SyntaxKind.SetAccessor
                    && !hasNonBindableDynamicName(func))
                {
                    const getter = getDeclarationOfKind<AccessorDeclaration>(
                        getSymbolOfNode(
                            declaration.parent
                        ),
                        SyntaxKind.GetAccessor
                    );
                    if (getter) {
                        const getterSignature = getSignatureFromDeclaration(getter);
                        const thisParameter = getAccessorThisParameter(func as AccessorDeclaration);
                        if (thisParameter && declaration === thisParameter) {
                            // Use the type from the *getter*
                            Debug.assert(!thisParameter.type);
                            return getTypeOfSymbol(
                                getterSignature.thisParameter!
                            );
                        }
                        return getReturnTypeOfSignature(getterSignature);
                    }
                }
                if (isInJSFile(declaration)) {
                    const typeTag = getJSDocType(func);
                    if (typeTag && isFunctionTypeNode(typeTag)) {
                        return getTypeAtPosition(
                            getSignatureFromDeclaration(typeTag),
                            func.parameters.indexOf(declaration)
                        );
                    }
                }
                // Use contextual parameter type if one is available
                const type = declaration.symbol.escapedName
                    === InternalSymbolName.This
                    ? getContextualThisParameterType(func)
                    : getContextuallyTypedParameterType(
                        declaration, /*forCache*/
                        true
                    );
                if (type) {
                    return addOptionality(type, isOptional);
                }
            } else if (isInJSFile(declaration)) {
                const containerObjectType = getJSContainerObjectType(
                    declaration,
                    getSymbolOfNode(declaration),
                    getDeclaredExpandoInitializer(declaration)
                );
                if (containerObjectType) {
                    return containerObjectType;
                }
            }

            // Use the type of the initializer expression if one is present and the declaration is
            // not a parameter of a contextually typed function
            if (declaration.initializer
                && !isParameterOfContextuallyTypedFunction(declaration))
            {
                const type = checkDeclarationInitializer(declaration);
                return addOptionality(type, isOptional);
            }

            if (isJsxAttribute(declaration)) {
                // if JSX attribute doesn't have initializer, by default the attribute will have boolean value of true.
                // I.e <Elem attr /> is sugar for <Elem attr={true} />
                return trueType;
            }

            // If the declaration specifies a binding pattern and is not a parameter of a contextually
            // typed function, use the type implied by the binding pattern
            if (isBindingPattern(declaration.name)
                && !isParameterOfContextuallyTypedFunction(declaration))
            {
                return getTypeFromBindingPattern(
                    declaration.name, /*includePatternInType*/
                    false, /*reportErrors*/
                    true
                );
            }

            // No type specified and nothing can be inferred
            return undefined;
        }

        function getWidenedTypeForAssignmentDeclaration(
            symbol: Symbol,
            resolvedSymbol?: Symbol
        ) {
            // function/class/{} initializers are themselves containers, so they won't merge in the same way as other initializers
            const container = getAssignedExpandoInitializer(
                symbol.valueDeclaration
            );
            if (container) {
                const tag = getJSDocTypeTag(container);
                if (tag && tag.typeExpression) {
                    return getTypeFromTypeNode(tag.typeExpression);
                }
                const containerObjectType = getJSContainerObjectType(
                    symbol.valueDeclaration,
                    symbol,
                    container
                );
                return containerObjectType
                    || getWidenedLiteralType(checkExpressionCached(container));
            }
            let definedInConstructor = false;
            let definedInMethod = false;
            let jsdocType: Type | undefined;
            let types: Type[] | undefined;
            for (const declaration of symbol.declarations) {
                const expression = (isBinaryExpression(declaration)
                    || isCallExpression(declaration))
                    ? declaration
                    : isAccessExpression(declaration)
                        ? isBinaryExpression(declaration.parent)
                            ? declaration.parent
                            : declaration
                        : undefined;
                if (!expression) {
                    continue; // Non-assignment declaration merged in (eg, an Identifier to mark the thing as a namespace) - skip over it and pull type info from elsewhere
                }

                const kind = isAccessExpression(expression)
                    ? getAssignmentDeclarationPropertyAccessKind(expression)
                    : getAssignmentDeclarationKind(expression);
                if (kind === AssignmentDeclarationKind.ThisProperty) {
                    if (isDeclarationInConstructor(expression)) {
                        definedInConstructor = true;
                    } else {
                        definedInMethod = true;
                    }
                }
                if (!isCallExpression(expression)) {
                    jsdocType = getAnnotatedTypeForAssignmentDeclaration(
                        jsdocType,
                        expression,
                        symbol,
                        declaration
                    );
                }
                if (!jsdocType) {
                    (types || (types = []))
                        .push(
                            (isBinaryExpression(expression)
                                || isCallExpression(expression))
                                ? getInitializerTypeFromAssignmentDeclaration(
                                    symbol,
                                    resolvedSymbol,
                                    expression,
                                    kind
                                )
                                : neverType
                        );
                }
            }
            let type = jsdocType;
            if (!type) {
                if (!length(types)) {
                    return errorType; // No types from any declarations :(
                }
                let constructorTypes = definedInConstructor
                    ? getConstructorDefinedThisAssignmentTypes(
                        types!,
                        symbol.declarations
                    )
                    : undefined;
                // use only the constructor types unless they were only assigned null | undefined (including widening variants)
                if (definedInMethod) {
                    const propType = getTypeOfAssignmentDeclarationPropertyOfBaseType(symbol);
                    if (propType) {
                        (constructorTypes || (constructorTypes = []))
                            .push(propType);
                        definedInConstructor = true;
                    }
                }
                const sourceTypes = some(
                    constructorTypes,
                    t => !!(t.flags & ~TypeFlags.Nullable)
                )
                    ? constructorTypes
                    : types; // TODO: GH#18217
                type = getUnionType(sourceTypes!, UnionReduction.Subtype);
            }
            const widened = getWidenedType(
                addOptionality(
                    type,
                    definedInMethod && !definedInConstructor
                )
            );
            if (filterType(widened, t => !!(t.flags & ~TypeFlags.Nullable))
                === neverType)
            {
                reportImplicitAny(symbol.valueDeclaration, anyType);
                return anyType;
            }
            return widened;
        }

        function getJSContainerObjectType(
            decl: Node,
            symbol: Symbol,
            init: Expression | undefined
        ): Type | undefined {
            if (!isInJSFile(decl) || !init || !isObjectLiteralExpression(init)
                || init.properties.length)
            {
                return undefined;
            }
            const exports = createSymbolTable();
            while (isBinaryExpression(decl)
                || isPropertyAccessExpression(decl))
            {
                const s = getSymbolOfNode(decl);
                if (s && hasEntries(s.exports)) {
                    mergeSymbolTable(exports, s.exports);
                }
                decl = isBinaryExpression(decl)
                    ? decl.parent
                    : decl.parent.parent;
            }
            const s = getSymbolOfNode(decl);
            if (s && hasEntries(s.exports)) {
                mergeSymbolTable(exports, s.exports);
            }
            const type = createAnonymousType(
                symbol,
                exports,
                emptyArray,
                emptyArray,
                undefined,
                undefined
            );
            type.objectFlags |= ObjectFlags.JSLiteral;
            return type;
        }

        function getAnnotatedTypeForAssignmentDeclaration(
            declaredType: Type | undefined,
            expression: Expression,
            symbol: Symbol,
            declaration: Declaration
        ) {
            const typeNode = getEffectiveTypeAnnotationNode(expression.parent);
            if (typeNode) {
                const type = getWidenedType(getTypeFromTypeNode(typeNode));
                if (!declaredType) {
                    return type;
                } else if (declaredType !== errorType && type !== errorType
                    && !isTypeIdenticalTo(declaredType, type))
                {
                    errorNextVariableOrPropertyDeclarationMustHaveSameType(
                        /*firstDeclaration*/ undefined,
                        declaredType,
                        declaration,
                        type
                    );
                }
            }
            if (symbol.parent) {
                const typeNode = getEffectiveTypeAnnotationNode(
                    symbol.parent.valueDeclaration
                );
                if (typeNode) {
                    return getTypeOfPropertyOfType(
                        getTypeFromTypeNode(typeNode),
                        symbol.escapedName
                    );
                }
            }

            return declaredType;
        }

        /** If we don't have an explicit JSDoc type, get the type from the initializer. */
        function getInitializerTypeFromAssignmentDeclaration(
            symbol: Symbol,
            resolvedSymbol: Symbol | undefined,
            expression: BinaryExpression | CallExpression,
            kind: AssignmentDeclarationKind
        ) {
            if (isCallExpression(expression)) {
                if (resolvedSymbol) {
                    return getTypeOfSymbol(resolvedSymbol); // This shouldn't happen except under some hopefully forbidden merges of export assignments and object define assignments
                }
                const objectLitType = checkExpressionCached(
                    (expression as BindableObjectDefinePropertyCall).arguments
                        [2]
                );
                const valueType = getTypeOfPropertyOfType(
                    objectLitType,
                    'value' as __String
                );
                if (valueType) {
                    return valueType;
                }
                const getFunc = getTypeOfPropertyOfType(
                    objectLitType,
                    'get' as __String
                );
                if (getFunc) {
                    const getSig = getSingleCallSignature(getFunc);
                    if (getSig) {
                        return getReturnTypeOfSignature(getSig);
                    }
                }
                const setFunc = getTypeOfPropertyOfType(
                    objectLitType,
                    'set' as __String
                );
                if (setFunc) {
                    const setSig = getSingleCallSignature(setFunc);
                    if (setSig) {
                        return getTypeOfFirstParameterOfSignature(setSig);
                    }
                }
                return anyType;
            }
            const type = resolvedSymbol
                ? getTypeOfSymbol(resolvedSymbol)
                : getWidenedLiteralType(
                    checkExpressionCached(expression.right)
                );
            if (type.flags & TypeFlags.Object
                && kind === AssignmentDeclarationKind.ModuleExports
                && symbol.escapedName === InternalSymbolName.ExportEquals)
            {
                const exportedType = resolveStructuredTypeMembers(type as ObjectType);
                const members = createSymbolTable();
                copyEntries(exportedType.members, members);
                if (resolvedSymbol && !resolvedSymbol.exports) {
                    resolvedSymbol.exports = createSymbolTable();
                }
                (resolvedSymbol || symbol).exports!.forEach((s, name) => {
                    if (members.has(name)) {
                        const exportedMember = exportedType.members.get(name)!;
                        const union = createSymbol(
                            s.flags | exportedMember.flags,
                            name
                        );
                        union
                            .type = getUnionType(
                                [getTypeOfSymbol(s),
                                    getTypeOfSymbol(exportedMember)]
                            );
                        members.set(name, union);
                    } else {
                        members.set(name, s);
                    }
                });
                const result = createAnonymousType(
                    exportedType.symbol,
                    members,
                    exportedType.callSignatures,
                    exportedType.constructSignatures,
                    exportedType.stringIndexInfo,
                    exportedType.numberIndexInfo
                );
                result
                    .objectFlags |= (getObjectFlags(type)
                        & ObjectFlags.JSLiteral); // Propagate JSLiteral flag
                return result;
            }
            if (isEmptyArrayLiteralType(type)) {
                reportImplicitAny(expression, anyArrayType);
                return anyArrayType;
            }
            return type;
        }

        function isDeclarationInConstructor(expression: Expression) {
            const thisContainer = getThisContainer(
                expression, /*includeArrowFunctions*/
                false
            );
            // Properties defined in a constructor (or base constructor, or javascript constructor function) don't get undefined added.
            // Function expressions that are assigned to the prototype count as methods.
            return thisContainer.kind === SyntaxKind.Constructor
                || thisContainer.kind === SyntaxKind.FunctionDeclaration
                || (thisContainer.kind === SyntaxKind.FunctionExpression
                    && !isPrototypePropertyAssignment(thisContainer.parent));
        }

        function getConstructorDefinedThisAssignmentTypes(
            types: Type[],
            declarations: Declaration[]
        ): Type[] | undefined {
            Debug.assert(types.length === declarations.length);
            return types.filter((_, i) => {
                const declaration = declarations[i];
                const expression = isBinaryExpression(declaration)
                    ? declaration
                    : isBinaryExpression(declaration.parent)
                        ? declaration.parent
                        : undefined;
                return expression && isDeclarationInConstructor(expression);
            });
        }

        /** check for definition in base class if any declaration is in a class */
        function getTypeOfAssignmentDeclarationPropertyOfBaseType(
            property: Symbol
        ) {
            const parentDeclaration = forEach(
                property.declarations,
                d => {
                    const parent = getThisContainer(
                        d, /*includeArrowFunctions*/
                        false
                    ).parent;
                    return isClassLike(parent) && parent;
                }
            );
            if (parentDeclaration) {
                const classType = getDeclaredTypeOfSymbol(getSymbolOfNode(parentDeclaration)) as InterfaceType;
                const baseClassType = classType && getBaseTypes(classType)[0];
                if (baseClassType) {
                    return getTypeOfPropertyOfType(
                        baseClassType,
                        property.escapedName
                    );
                }
            }
        }

        // Return the type implied by a binding pattern element. This is the type of the initializer of the element if
        // one is present. Otherwise, if the element is itself a binding pattern, it is the type implied by the binding
        // pattern. Otherwise, it is the type any.
        function getTypeFromBindingElement(
            element: BindingElement,
            includePatternInType?: boolean,
            reportErrors?: boolean
        ): Type {
            if (element.initializer) {
                return addOptionality(checkDeclarationInitializer(element));
            }
            if (isBindingPattern(element.name)) {
                return getTypeFromBindingPattern(
                    element.name,
                    includePatternInType,
                    reportErrors
                );
            }
            if (reportErrors
                && !declarationBelongsToPrivateAmbientMember(element))
            {
                reportImplicitAny(element, anyType);
            }
            // When we're including the pattern in the type (an indication we're obtaining a contextual type), we
            // use the non-inferrable any type. Inference will never directly infer this type, but it is possible
            // to infer a type that contains it, e.g. for a binding pattern like [foo] or { foo }. In such cases,
            // widening of the binding pattern type substitutes a regular any for the non-inferrable any.
            return includePatternInType ? nonInferrableAnyType : anyType;
        }

        // Return the type implied by an object binding pattern
        function getTypeFromObjectBindingPattern(
            pattern: ObjectBindingPattern,
            includePatternInType: boolean,
            reportErrors: boolean
        ): Type {
            const members = createSymbolTable();
            let stringIndexInfo: IndexInfo | undefined;
            let objectFlags = ObjectFlags.ObjectLiteral
                | ObjectFlags.ContainsObjectOrArrayLiteral;
            forEach(
                pattern.elements,
                e => {
                    const name = e.propertyName || <Identifier> e.name;
                    if (e.dotDotDotToken) {
                        stringIndexInfo = createIndexInfo(
                            anyType, /*isReadonly*/
                            false
                        );
                        return;
                    }

                    const exprType = getLiteralTypeFromPropertyName(name);
                    if (!isTypeUsableAsPropertyName(exprType)) {
                        // do not include computed properties in the implied type
                        objectFlags |= ObjectFlags
                            .ObjectLiteralPatternWithComputedProperties;
                        return;
                    }
                    const text = getPropertyNameFromType(exprType);
                    const flags = SymbolFlags.Property
                        | (e.initializer ? SymbolFlags.Optional : 0);
                    const symbol = createSymbol(flags, text);
                    symbol.type = getTypeFromBindingElement(
                        e,
                        includePatternInType,
                        reportErrors
                    );
                    symbol.bindingElement = e;
                    members.set(symbol.escapedName, symbol);
                }
            );
            const result = createAnonymousType(
                undefined,
                members,
                emptyArray,
                emptyArray,
                stringIndexInfo,
                undefined
            );
            result.objectFlags |= objectFlags;
            if (includePatternInType) {
                result.pattern = pattern;
                result.objectFlags |= ObjectFlags.ContainsObjectOrArrayLiteral;
            }
            return result;
        }

        // Return the type implied by an array binding pattern
        function getTypeFromArrayBindingPattern(
            pattern: BindingPattern,
            includePatternInType: boolean,
            reportErrors: boolean
        ): Type {
            const elements = pattern.elements;
            const lastElement = lastOrUndefined(elements);
            const hasRestElement = !!(lastElement
                && lastElement.kind === SyntaxKind.BindingElement
                && lastElement.dotDotDotToken);
            if (elements.length === 0 || elements.length === 1
                && hasRestElement)
            {
                return languageVersion >= ScriptTarget.ES2015
                    ? createIterableType(anyType)
                    : anyArrayType;
            }
            const elementTypes = map(
                elements,
                e => isOmittedExpression(e)
                    ? anyType
                    : getTypeFromBindingElement(
                        e,
                        includePatternInType,
                        reportErrors
                    )
            );
            const minLength = findLastIndex(
                elements,
                e => !isOmittedExpression(e) && !hasDefaultValue(e),
                elements.length - (hasRestElement ? 2 : 1)
            ) + 1;
            let result = <TypeReference> createTupleType(
                elementTypes,
                minLength,
                hasRestElement
            );
            if (includePatternInType) {
                result = cloneTypeReference(result);
                result.pattern = pattern;
                result.objectFlags |= ObjectFlags.ContainsObjectOrArrayLiteral;
            }
            return result;
        }

        // Return the type implied by a binding pattern. This is the type implied purely by the binding pattern itself
        // and without regard to its context (i.e. without regard any type annotation or initializer associated with the
        // declaration in which the binding pattern is contained). For example, the implied type of [x, y] is [any, any]
        // and the implied type of { x, y: z = 1 } is { x: any; y: number; }. The type implied by a binding pattern is
        // used as the contextual type of an initializer associated with the binding pattern. Also, for a destructuring
        // parameter with no type annotation or initializer, the type implied by the binding pattern becomes the type of
        // the parameter.
        function getTypeFromBindingPattern(
            pattern: BindingPattern,
            includePatternInType = false,
            reportErrors = false
        ): Type {
            return pattern.kind === SyntaxKind.ObjectBindingPattern
                ? getTypeFromObjectBindingPattern(
                    pattern,
                    includePatternInType,
                    reportErrors
                )
                : getTypeFromArrayBindingPattern(
                    pattern,
                    includePatternInType,
                    reportErrors
                );
        }

        // Return the type associated with a variable, parameter, or property declaration. In the simple case this is the type
        // specified in a type annotation or inferred from an initializer. However, in the case of a destructuring declaration it
        // is a bit more involved. For example:
        //
        //   var [x, s = ""] = [1, "one"];
        //
        // Here, the array literal [1, "one"] is contextually typed by the type [any, string], which is the implied type of the
        // binding pattern [x, s = ""]. Because the contextual type is a tuple type, the resulting type of [1, "one"] is the
        // tuple type [number, string]. Thus, the type inferred for 'x' is number and the type inferred for 's' is string.
        function getWidenedTypeForVariableLikeDeclaration(
            declaration: ParameterDeclaration | PropertyDeclaration
                | PropertySignature | VariableDeclaration | BindingElement,
            reportErrors?: boolean
        ): Type {
            return widenTypeForVariableLikeDeclaration(
                getTypeForVariableLikeDeclaration(
                    declaration, /*includeOptionality*/
                    true
                ),
                declaration,
                reportErrors
            );
        }

        function widenTypeForVariableLikeDeclaration(
            type: Type | undefined,
            declaration: any,
            reportErrors?: boolean
        ) {
            if (type) {
                if (reportErrors) {
                    reportErrorsFromWidening(declaration, type);
                }

                // always widen a 'unique symbol' type if the type was created for a different declaration.
                if (type.flags & TypeFlags.UniqueESSymbol
                    && (isBindingElement(declaration) || !declaration.type)
                    && type.symbol !== getSymbolOfNode(declaration))
                {
                    type = esSymbolType;
                }

                return getWidenedType(type);
            }

            // Rest parameters default to type any[], other parameters default to type any
            type = isParameter(declaration) && declaration.dotDotDotToken
                ? anyArrayType
                : anyType;

            // Report implicit any errors unless this is a private property within an ambient declaration
            if (reportErrors) {
                if (!declarationBelongsToPrivateAmbientMember(declaration)) {
                    reportImplicitAny(declaration, type);
                }
            }
            return type;
        }

        function declarationBelongsToPrivateAmbientMember(
            declaration: VariableLikeDeclaration
        ) {
            const root = getRootDeclaration(declaration);
            const memberDeclaration = root.kind === SyntaxKind.Parameter
                ? root.parent
                : root;
            return isPrivateWithinAmbient(memberDeclaration);
        }

        function tryGetTypeFromEffectiveTypeNode(declaration: Declaration) {
            const typeNode = getEffectiveTypeAnnotationNode(declaration);
            if (typeNode) {
                return getTypeFromTypeNode(typeNode);
            }
        }

        function getTypeOfVariableOrParameterOrProperty(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            if (!links.type) {
                const type = getTypeOfVariableOrParameterOrPropertyWorker(symbol);
                // For a contextually typed parameter it is possible that a type has already
                // been assigned (in assignTypeToParameterAndFixTypeParameters), and we want
                // to preserve this type.
                if (!links.type) {
                    links.type = type;
                }
            }
            return links.type;
        }

        function getTypeOfVariableOrParameterOrPropertyWorker(symbol: Symbol) {
            // Handle prototype property
            if (symbol.flags & SymbolFlags.Prototype) {
                return getTypeOfPrototypeProperty(symbol);
            }
            // CommonsJS require and module both have type any.
            if (symbol === requireSymbol) {
                return anyType;
            }
            if (symbol.flags & SymbolFlags.ModuleExports) {
                const fileSymbol = getSymbolOfNode(
                    getSourceFileOfNode(
                        symbol.valueDeclaration
                    )
                );
                const members = createSymbolTable();
                members.set('exports' as __String, fileSymbol);
                return createAnonymousType(
                    symbol,
                    members,
                    emptyArray,
                    emptyArray,
                    undefined,
                    undefined
                );
            }
            // Handle catch clause variables
            const declaration = symbol.valueDeclaration;
            if (isCatchClauseVariableDeclarationOrBindingElement(declaration)) {
                return anyType;
            }
            // Handle export default expressions
            if (isSourceFile(declaration) && isJsonSourceFile(declaration)) {
                if (!declaration.statements.length) {
                    return emptyObjectType;
                }
                return getWidenedType(
                    getWidenedLiteralType(
                        checkExpression(
                            declaration.statements[0].expression
                        )
                    )
                );
            }

            // Handle variable, parameter or property
            if (!pushTypeResolution(symbol, TypeSystemPropertyName.Type)) {
                // Symbol is property of some kind that is merged with something - should use `getTypeOfFuncClassEnumModule` and not `getTypeOfVariableOrParameterOrProperty`
                if (symbol.flags & SymbolFlags.ValueModule
                    && !(symbol.flags & SymbolFlags.Assignment))
                {
                    return getTypeOfFuncClassEnumModule(symbol);
                }
                return reportCircularityError(symbol);
            }
            let type: Type | undefined;
            if (declaration.kind === SyntaxKind.ExportAssignment) {
                type = widenTypeForVariableLikeDeclaration(
                    checkExpressionCached(
                        (<ExportAssignment> declaration).expression
                    ),
                    declaration
                );
            } else if (
                isBinaryExpression(declaration)
                || (isInJSFile(declaration)
                    && (isCallExpression(declaration)
                        || (isPropertyAccessExpression(declaration)
                            || isBindableStaticElementAccessExpression(declaration))
                        && isBinaryExpression(declaration.parent)))
            ) {
                type = getWidenedTypeForAssignmentDeclaration(symbol);
            } else if (isJSDocPropertyLikeTag(declaration)
                || isPropertyAccessExpression(declaration)
                || isElementAccessExpression(declaration)
                || isIdentifier(declaration)
                || isStringLiteralLike(declaration)
                || isNumericLiteral(declaration)
                || isClassDeclaration(declaration)
                || isFunctionDeclaration(declaration)
                || (isMethodDeclaration(declaration)
                    && !isObjectLiteralMethod(declaration))
                || isMethodSignature(declaration)
                || isSourceFile(declaration))
            {
                // Symbol is property of some kind that is merged with something - should use `getTypeOfFuncClassEnumModule` and not `getTypeOfVariableOrParameterOrProperty`
                if (symbol.flags
                    & (SymbolFlags.Function | SymbolFlags.Method
                        | SymbolFlags.Class | SymbolFlags.Enum
                        | SymbolFlags.ValueModule))
                {
                    return getTypeOfFuncClassEnumModule(symbol);
                }
                type = isBinaryExpression(declaration.parent)
                    ? getWidenedTypeForAssignmentDeclaration(symbol)
                    : tryGetTypeFromEffectiveTypeNode(declaration) || anyType;
            } else if (isPropertyAssignment(declaration)) {
                type = tryGetTypeFromEffectiveTypeNode(declaration)
                    || checkPropertyAssignment(declaration);
            } else if (isJsxAttribute(declaration)) {
                type = tryGetTypeFromEffectiveTypeNode(declaration)
                    || checkJsxAttribute(declaration);
            } else if (isShorthandPropertyAssignment(declaration)) {
                type = tryGetTypeFromEffectiveTypeNode(declaration)
                    || checkExpressionForMutableLocation(
                        declaration.name,
                        CheckMode.Normal
                    );
            } else if (isObjectLiteralMethod(declaration)) {
                type = tryGetTypeFromEffectiveTypeNode(declaration)
                    || checkObjectLiteralMethod(declaration, CheckMode.Normal);
            } else if (isParameter(declaration)
                || isPropertyDeclaration(declaration)
                || isPropertySignature(declaration)
                || isVariableDeclaration(declaration)
                || isBindingElement(declaration))
            {
                type = getWidenedTypeForVariableLikeDeclaration(
                    declaration, /*includeOptionality*/
                    true
                );
            } // getTypeOfSymbol dispatches some JS merges incorrectly because their symbol flags are not mutually exclusive.
            // Re-dispatch based on valueDeclaration.kind instead.
            else if (isEnumDeclaration(declaration)) {
                type = getTypeOfFuncClassEnumModule(symbol);
            } else if (isEnumMember(declaration)) {
                type = getTypeOfEnumMember(symbol);
            } else if (isAccessor(declaration)) {
                type = resolveTypeOfAccessors(symbol);
            } else {
                return Debug
                    .fail(
                        'Unhandled declaration kind! '
                            + Debug.formatSyntaxKind(declaration.kind)
                            + ' for ' + Debug.formatSymbol(symbol)
                    );
            }

            if (!popTypeResolution()) {
                // Symbol is property of some kind that is merged with something - should use `getTypeOfFuncClassEnumModule` and not `getTypeOfVariableOrParameterOrProperty`
                if (symbol.flags & SymbolFlags.ValueModule
                    && !(symbol.flags & SymbolFlags.Assignment))
                {
                    return getTypeOfFuncClassEnumModule(symbol);
                }
                return reportCircularityError(symbol);
            }
            return type;
        }

        function getAnnotatedAccessorTypeNode(
            accessor: AccessorDeclaration | undefined
        ): TypeNode | undefined {
            if (accessor) {
                if (accessor.kind === SyntaxKind.GetAccessor) {
                    const getterTypeAnnotation = getEffectiveReturnTypeNode(accessor);
                    return getterTypeAnnotation;
                } else {
                    const setterTypeAnnotation = getEffectiveSetAccessorTypeAnnotationNode(accessor);
                    return setterTypeAnnotation;
                }
            }
            return undefined;
        }

        function getAnnotatedAccessorType(
            accessor: AccessorDeclaration | undefined
        ): Type | undefined {
            const node = getAnnotatedAccessorTypeNode(accessor);
            return node && getTypeFromTypeNode(node);
        }

        function getAnnotatedAccessorThisParameter(
            accessor: AccessorDeclaration
        ): Symbol | undefined {
            const parameter = getAccessorThisParameter(accessor);
            return parameter && parameter.symbol;
        }

        function getThisTypeOfDeclaration(
            declaration: SignatureDeclaration
        ): Type | undefined {
            return getThisTypeOfSignature(getSignatureFromDeclaration(declaration));
        }

        function getTypeOfAccessors(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            return links.type
                || (links.type = getTypeOfAccessorsWorker(symbol));
        }

        function getTypeOfAccessorsWorker(symbol: Symbol): Type {
            if (!pushTypeResolution(symbol, TypeSystemPropertyName.Type)) {
                return errorType;
            }

            let type = resolveTypeOfAccessors(symbol);

            if (!popTypeResolution()) {
                type = anyType;
                if (noImplicitAny) {
                    const getter = getDeclarationOfKind<AccessorDeclaration>(
                        symbol,
                        SyntaxKind.GetAccessor
                    );
                    error(
                        getter,
                        Diagnostics
                            ._0_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_referenced_directly_or_indirectly_in_one_of_its_return_expressions,
                        symbolToString(symbol)
                    );
                }
            }
            return type;
        }

        function resolveTypeOfAccessors(symbol: Symbol) {
            const getter = getDeclarationOfKind<AccessorDeclaration>(
                symbol,
                SyntaxKind.GetAccessor
            );
            const setter = getDeclarationOfKind<AccessorDeclaration>(
                symbol,
                SyntaxKind.SetAccessor
            );

            if (getter && isInJSFile(getter)) {
                const jsDocType = getTypeForDeclarationFromJSDocComment(getter);
                if (jsDocType) {
                    return jsDocType;
                }
            }
            // First try to see if the user specified a return type on the get-accessor.
            const getterReturnType = getAnnotatedAccessorType(getter);
            if (getterReturnType) {
                return getterReturnType;
            } else {
                // If the user didn't specify a return type, try to use the set-accessor's parameter type.
                const setterParameterType = getAnnotatedAccessorType(setter);
                if (setterParameterType) {
                    return setterParameterType;
                } else {
                    // If there are no specified types, try to infer it from the body of the get accessor if it exists.
                    if (getter && getter.body) {
                        return getReturnTypeFromBody(getter);
                    } // Otherwise, fall back to 'any'.
                    else {
                        if (setter) {
                            if (!isPrivateWithinAmbient(setter)) {
                                errorOrSuggestion(
                                    noImplicitAny,
                                    setter,
                                    Diagnostics
                                        .Property_0_implicitly_has_type_any_because_its_set_accessor_lacks_a_parameter_type_annotation,
                                    symbolToString(symbol)
                                );
                            }
                        } else {
                            Debug.assert(
                                !!getter,
                                'there must exist a getter as we are current checking either setter or getter in this function'
                            );
                            if (!isPrivateWithinAmbient(getter!)) {
                                errorOrSuggestion(
                                    noImplicitAny,
                                    getter!,
                                    Diagnostics
                                        .Property_0_implicitly_has_type_any_because_its_get_accessor_lacks_a_return_type_annotation,
                                    symbolToString(symbol)
                                );
                            }
                        }
                        return anyType;
                    }
                }
            }
        }

        function getBaseTypeVariableOfClass(symbol: Symbol) {
            const baseConstructorType = getBaseConstructorTypeOfClass(getDeclaredTypeOfClassOrInterface(symbol));
            return baseConstructorType.flags & TypeFlags.TypeVariable
                ? baseConstructorType
                : baseConstructorType.flags & TypeFlags.Intersection
                    ? find(
                        (baseConstructorType as IntersectionType).types,
                        t => !!(t.flags & TypeFlags.TypeVariable)
                    )
                    : undefined;
        }

        function getTypeOfFuncClassEnumModule(symbol: Symbol): Type {
            let links = getSymbolLinks(symbol);
            const originalLinks = links;
            if (!links.type) {
                const jsDeclaration = getDeclarationOfExpando(
                    symbol.valueDeclaration
                );
                if (jsDeclaration) {
                    const merged = mergeJSSymbols(
                        symbol,
                        getSymbolOfNode(jsDeclaration)
                    );
                    if (merged) {
                        // note:we overwrite links because we just cloned the symbol
                        symbol = links = merged;
                    }
                }
                originalLinks.type = links
                    .type = getTypeOfFuncClassEnumModuleWorker(symbol);
            }
            return links.type;
        }

        function getTypeOfFuncClassEnumModuleWorker(symbol: Symbol): Type {
            const declaration = symbol.valueDeclaration;
            if (symbol.flags & SymbolFlags.Module
                && isShorthandAmbientModuleSymbol(symbol))
            {
                return anyType;
            } else if (declaration.kind === SyntaxKind.BinaryExpression
                || isAccessExpression(declaration)
                && declaration.parent.kind === SyntaxKind.BinaryExpression)
            {
                return getWidenedTypeForAssignmentDeclaration(symbol);
            } else if (symbol.flags & SymbolFlags.ValueModule && declaration
                && isSourceFile(declaration)
                && declaration.commonJsModuleIndicator)
            {
                const resolvedModule = resolveExternalModuleSymbol(symbol);
                if (resolvedModule !== symbol) {
                    if (!pushTypeResolution(
                        symbol,
                        TypeSystemPropertyName.Type
                    )) {
                        return errorType;
                    }
                    const exportEquals = getMergedSymbol(
                        symbol.exports!.get(InternalSymbolName.ExportEquals)!
                    );
                    const type = getWidenedTypeForAssignmentDeclaration(
                        exportEquals,
                        exportEquals === resolvedModule
                            ? undefined
                            : resolvedModule
                    );
                    if (!popTypeResolution()) {
                        return reportCircularityError(symbol);
                    }
                    return type;
                }
            }
            const type = createObjectType(ObjectFlags.Anonymous, symbol);
            if (symbol.flags & SymbolFlags.Class) {
                const baseTypeVariable = getBaseTypeVariableOfClass(symbol);
                return baseTypeVariable
                    ? getIntersectionType([type, baseTypeVariable])
                    : type;
            } else {
                return strictNullChecks && symbol.flags & SymbolFlags.Optional
                    ? getOptionalType(type)
                    : type;
            }
        }

        function getTypeOfEnumMember(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            return links.type
                || (links.type = getDeclaredTypeOfEnumMember(symbol));
        }

        function getTypeOfAlias(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            if (!links.type) {
                const targetSymbol = resolveAlias(symbol);

                // It only makes sense to get the type of a value symbol. If the result of resolving
                // the alias is not a value, then it has no type. To get the type associated with a
                // type symbol, call getDeclaredTypeOfSymbol.
                // This check is important because without it, a call to getTypeOfSymbol could end
                // up recursively calling getTypeOfAlias, causing a stack overflow.
                links.type = targetSymbol.flags & SymbolFlags.Value
                    ? getTypeOfSymbol(targetSymbol)
                    : errorType;
            }
            return links.type;
        }

        function getTypeOfInstantiatedSymbol(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            if (!links.type) {
                if (!pushTypeResolution(symbol, TypeSystemPropertyName.Type)) {
                    return links.type = errorType;
                }
                let type = instantiateType(
                    getTypeOfSymbol(links.target!),
                    links.mapper
                );
                if (!popTypeResolution()) {
                    type = reportCircularityError(symbol);
                }
                links.type = type;
            }
            return links.type;
        }

        function reportCircularityError(symbol: Symbol) {
            const declaration = <VariableLikeDeclaration> symbol
                .valueDeclaration;
            // Check if variable has type annotation that circularly references the variable itself
            if (getEffectiveTypeAnnotationNode(declaration)) {
                error(
                    symbol.valueDeclaration,
                    Diagnostics
                        ._0_is_referenced_directly_or_indirectly_in_its_own_type_annotation,
                    symbolToString(symbol)
                );
                return errorType;
            }
            // Check if variable has initializer that circularly references the variable itself
            if (noImplicitAny
                && (declaration.kind !== SyntaxKind.Parameter
                    || (<HasInitializer> declaration).initializer))
            {
                error(
                    symbol.valueDeclaration,
                    Diagnostics
                        ._0_implicitly_has_type_any_because_it_does_not_have_a_type_annotation_and_is_referenced_directly_or_indirectly_in_its_own_initializer,
                    symbolToString(symbol)
                );
            }
            // Circularities could also result from parameters in function expressions that end up
            // having themselves as contextual types following type argument inference. In those cases
            // we have already reported an implicit any error so we don't report anything here.
            return anyType;
        }

        function getTypeOfSymbolWithDeferredType(symbol: Symbol) {
            const links = getSymbolLinks(symbol);
            if (!links.type) {
                Debug.assertDefined(links.deferralParent);
                Debug.assertDefined(links.deferralConstituents);
                links.type = links.deferralParent!.flags & TypeFlags.Union
                    ? getUnionType(links.deferralConstituents!)
                    : getIntersectionType(links.deferralConstituents!);
            }
            return links.type;
        }

        function getTypeOfSymbol(symbol: Symbol): Type {
            if (getCheckFlags(symbol) & CheckFlags.DeferredType) {
                return getTypeOfSymbolWithDeferredType(symbol);
            }
            if (getCheckFlags(symbol) & CheckFlags.Instantiated) {
                return getTypeOfInstantiatedSymbol(symbol);
            }
            if (getCheckFlags(symbol) & CheckFlags.ReverseMapped) {
                return getTypeOfReverseMappedSymbol(symbol as ReverseMappedSymbol);
            }
            if (symbol.flags & (SymbolFlags.Variable | SymbolFlags.Property)) {
                return getTypeOfVariableOrParameterOrProperty(symbol);
            }
            if (symbol.flags
                & (SymbolFlags.Function | SymbolFlags.Method
                    | SymbolFlags.Class | SymbolFlags.Enum
                    | SymbolFlags.ValueModule))
            {
                return getTypeOfFuncClassEnumModule(symbol);
            }
            if (symbol.flags & SymbolFlags.EnumMember) {
                return getTypeOfEnumMember(symbol);
            }
            if (symbol.flags & SymbolFlags.Accessor) {
                return getTypeOfAccessors(symbol);
            }
            if (symbol.flags & SymbolFlags.Alias) {
                return getTypeOfAlias(symbol);
            }
            return errorType;
        }

        function isReferenceToType(type: Type, target: Type) {
            return type !== undefined
                && target !== undefined
                && (getObjectFlags(type) & ObjectFlags.Reference) !== 0
                && (<TypeReference> type).target === target;
        }

        function getTargetType(type: Type): Type {
            return getObjectFlags(type) & ObjectFlags.Reference
                ? (<TypeReference> type).target
                : type;
        }

        // TODO: GH#18217 If `checkBase` is undefined, we should not call this because this will always return false.
        function hasBaseType(type: Type, checkBase: Type | undefined) {
            return check(type);
            function check(type: Type): boolean {
                if (getObjectFlags(type)
                    & (ObjectFlags.ClassOrInterface | ObjectFlags.Reference))
                {
                    const target = <InterfaceType> getTargetType(type);
                    return target === checkBase
                        || some(getBaseTypes(target), check);
                } else if (type.flags & TypeFlags.Intersection) {
                    return some((<IntersectionType> type).types, check);
                }
                return false;
            }
        }

        // Appends the type parameters given by a list of declarations to a set of type parameters and returns the resulting set.
        // The function allocates a new array if the input type parameter set is undefined, but otherwise it modifies the set
        // in-place and returns the same array.
        function appendTypeParameters(
            typeParameters: TypeParameter[] | undefined,
            declarations: readonly TypeParameterDeclaration[]
        ): TypeParameter[] | undefined {
            for (const declaration of declarations) {
                typeParameters = appendIfUnique(
                    typeParameters,
                    getDeclaredTypeOfTypeParameter(getSymbolOfNode(declaration))
                );
            }
            return typeParameters;
        }

        // Return the outer type parameters of a node or undefined if the node has no outer type parameters.
        function getOuterTypeParameters(
            node: Node,
            includeThisTypes?: boolean
        ): TypeParameter[] | undefined {
            while (true) {
                node = node
                    .parent; // TODO: GH#18217 Use SourceFile kind check instead
                if (node && isBinaryExpression(node)) {
                    // prototype assignments get the outer type parameters of their constructor function
                    const assignmentKind = getAssignmentDeclarationKind(node);
                    if (assignmentKind === AssignmentDeclarationKind.Prototype
                        || assignmentKind
                        === AssignmentDeclarationKind.PrototypeProperty)
                    {
                        const symbol = getSymbolOfNode(node.left);
                        if (symbol && symbol.parent
                            && !findAncestor(
                                symbol.parent.valueDeclaration,
                                d => node === d
                            ))
                        {
                            node = symbol.parent.valueDeclaration;
                        }
                    }
                }
                if (!node) {
                    return undefined;
                }
                switch (node.kind) {
                    case SyntaxKind.ClassDeclaration:
                    case SyntaxKind.ClassExpression:
                    case SyntaxKind.InterfaceDeclaration:
                    case SyntaxKind.CallSignature:
                    case SyntaxKind.ConstructSignature:
                    case SyntaxKind.MethodSignature:
                    case SyntaxKind.FunctionType:
                    case SyntaxKind.ConstructorType:
                    case SyntaxKind.JSDocFunctionType:
                    case SyntaxKind.FunctionDeclaration:
                    case SyntaxKind.MethodDeclaration:
                    case SyntaxKind.FunctionExpression:
                    case SyntaxKind.ArrowFunction:
                    case SyntaxKind.TypeAliasDeclaration:
                    case SyntaxKind.JSDocTemplateTag:
                    case SyntaxKind.JSDocTypedefTag:
                    case SyntaxKind.JSDocEnumTag:
                    case SyntaxKind.JSDocCallbackTag:
                    case SyntaxKind.MappedType:
                    case SyntaxKind.ConditionalType:
                        const outerTypeParameters = getOuterTypeParameters(
                            node,
                            includeThisTypes
                        );
                        if (node.kind === SyntaxKind.MappedType) {
                            return append(
                                outerTypeParameters,
                                getDeclaredTypeOfTypeParameter(
                                    getSymbolOfNode(
                                        (<MappedTypeNode> node).typeParameter
                                    )
                                )
                            );
                        } else if (node.kind === SyntaxKind.ConditionalType) {
                            return concatenate(
                                outerTypeParameters,
                                getInferTypeParameters(<ConditionalTypeNode> node)
                            );
                        }
                        const outerAndOwnTypeParameters = appendTypeParameters(
                            outerTypeParameters,
                            getEffectiveTypeParameterDeclarations(<DeclarationWithTypeParameters> node)
                        );
                        const thisType = includeThisTypes
                            && (node.kind === SyntaxKind.ClassDeclaration
                                || node.kind === SyntaxKind.ClassExpression
                                || node.kind
                                === SyntaxKind.InterfaceDeclaration
                                || isJSConstructor(node))
                            && getDeclaredTypeOfClassOrInterface(
                                getSymbolOfNode(
                                    node as ClassLikeDeclaration
                                        | InterfaceDeclaration
                                )
                            ).thisType;
                        return thisType
                            ? append(outerAndOwnTypeParameters, thisType)
                            : outerAndOwnTypeParameters;
                }
            }
        }

        // The outer type parameters are those defined by enclosing generic classes, methods, or functions.
        function getOuterTypeParametersOfClassOrInterface(
            symbol: Symbol
        ): TypeParameter[] | undefined {
            const declaration = symbol.flags & SymbolFlags.Class
                ? symbol.valueDeclaration
                : getDeclarationOfKind(
                    symbol,
                    SyntaxKind.InterfaceDeclaration
                )!;
            Debug.assert(
                !!declaration,
                'Class was missing valueDeclaration -OR- non-class had no interface declarations'
            );
            return getOuterTypeParameters(declaration);
        }

        // The local type parameters are the combined set of type parameters from all declarations of the class,
        // interface, or type alias.
        function getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(
            symbol: Symbol
        ): TypeParameter[] | undefined {
            let result: TypeParameter[] | undefined;
            for (const node of symbol.declarations) {
                if (node.kind === SyntaxKind.InterfaceDeclaration
                    || node.kind === SyntaxKind.ClassDeclaration
                    || node.kind === SyntaxKind.ClassExpression
                    || isJSConstructor(node)
                    || isTypeAlias(node))
                {
                    const declaration = <InterfaceDeclaration
                        | TypeAliasDeclaration | JSDocTypedefTag
                        | JSDocCallbackTag> node;
                    result = appendTypeParameters(
                        result,
                        getEffectiveTypeParameterDeclarations(declaration)
                    );
                }
            }
            return result;
        }

        // The full set of type parameters for a generic class or interface type consists of its outer type parameters plus
        // its locally declared type parameters.
        function getTypeParametersOfClassOrInterface(
            symbol: Symbol
        ): TypeParameter[] | undefined {
            return concatenate(
                getOuterTypeParametersOfClassOrInterface(symbol),
                getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol)
            );
        }

        // A type is a mixin constructor if it has a single construct signature taking no type parameters and a single
        // rest parameter of type any[].
        function isMixinConstructorType(type: Type) {
            const signatures = getSignaturesOfType(
                type,
                SignatureKind.Construct
            );
            if (signatures.length === 1) {
                const s = signatures[0];
                return !s.typeParameters && s.parameters.length === 1
                    && signatureHasRestParameter(s)
                    && getElementTypeOfArrayType(
                        getTypeOfParameter(
                            s.parameters[0]
                        )
                    ) === anyType;
            }
            return false;
        }

        function isConstructorType(type: Type): boolean {
            if (getSignaturesOfType(type, SignatureKind.Construct).length
                > 0)
            {
                return true;
            }
            if (type.flags & TypeFlags.TypeVariable) {
                const constraint = getBaseConstraintOfType(type);
                return !!constraint && isMixinConstructorType(constraint);
            }
            return false;
        }

        function getBaseTypeNodeOfClass(
            type: InterfaceType
        ): ExpressionWithTypeArguments | undefined {
            return getEffectiveBaseTypeNode(
                type.symbol.valueDeclaration as ClassLikeDeclaration
            );
        }

        function getConstructorsForTypeArguments(
            type: Type,
            typeArgumentNodes: readonly TypeNode[] | undefined,
            location: Node
        ): readonly Signature[] {
            const typeArgCount = length(typeArgumentNodes);
            const isJavascript = isInJSFile(location);
            return filter(
                getSignaturesOfType(type, SignatureKind.Construct),
                sig => (isJavascript
                    || typeArgCount
                    >= getMinTypeArgumentCount(sig.typeParameters))
                    && typeArgCount <= length(sig.typeParameters)
            );
        }

        function getInstantiatedConstructorsForTypeArguments(
            type: Type,
            typeArgumentNodes: readonly TypeNode[] | undefined,
            location: Node
        ): readonly Signature[] {
            const signatures = getConstructorsForTypeArguments(
                type,
                typeArgumentNodes,
                location
            );
            const typeArguments = map(typeArgumentNodes, getTypeFromTypeNode);
            return sameMap<Signature>(
                signatures,
                sig => some(sig.typeParameters)
                    ? getSignatureInstantiation(
                        sig,
                        typeArguments,
                        isInJSFile(location)
                    )
                    : sig
            );
        }

        /**
         * The base constructor of a class can resolve to
         * * undefinedType if the class has no extends clause,
         * * unknownType if an error occurred during resolution of the extends expression,
         * * nullType if the extends expression is the null value,
         * * anyType if the extends expression has type any, or
         * * an object type with at least one construct signature.
         */
        function getBaseConstructorTypeOfClass(type: InterfaceType): Type {
            if (!type.resolvedBaseConstructorType) {
                const decl = <ClassLikeDeclaration> type.symbol
                    .valueDeclaration;
                const extended = getEffectiveBaseTypeNode(decl);
                const baseTypeNode = getBaseTypeNodeOfClass(type);
                if (!baseTypeNode) {
                    return type.resolvedBaseConstructorType = undefinedType;
                }
                if (!pushTypeResolution(
                    type,
                    TypeSystemPropertyName.ResolvedBaseConstructorType
                )) {
                    return errorType;
                }
                const baseConstructorType = checkExpression(
                    baseTypeNode.expression
                );
                if (extended && baseTypeNode !== extended) {
                    Debug
                        .assert(!extended
                            .typeArguments); // Because this is in a JS file, and baseTypeNode is in an @extends tag
                    checkExpression(extended.expression);
                }
                if (baseConstructorType.flags
                    & (TypeFlags.Object | TypeFlags.Intersection))
                {
                    // Resolving the members of a class requires us to resolve the base class of that class.
                    // We force resolution here such that we catch circularities now.
                    resolveStructuredTypeMembers(<ObjectType> baseConstructorType);
                }
                if (!popTypeResolution()) {
                    error(
                        type.symbol.valueDeclaration,
                        Diagnostics
                            ._0_is_referenced_directly_or_indirectly_in_its_own_base_expression,
                        symbolToString(type.symbol)
                    );
                    return type.resolvedBaseConstructorType = errorType;
                }
                if (!(baseConstructorType.flags & TypeFlags.Any)
                    && baseConstructorType !== nullWideningType
                    && !isConstructorType(baseConstructorType))
                {
                    const err = error(
                        baseTypeNode.expression,
                        Diagnostics.Type_0_is_not_a_constructor_function_type,
                        typeToString(baseConstructorType)
                    );
                    if (baseConstructorType.flags & TypeFlags.TypeParameter) {
                        const constraint = getConstraintFromTypeParameter(baseConstructorType);
                        let ctorReturn: Type = unknownType;
                        if (constraint) {
                            const ctorSig = getSignaturesOfType(
                                constraint,
                                SignatureKind.Construct
                            );
                            if (ctorSig[0]) {
                                ctorReturn = getReturnTypeOfSignature(
                                    ctorSig[0]
                                );
                            }
                        }
                        addRelatedInfo(
                            err,
                            createDiagnosticForNode(
                                baseConstructorType.symbol.declarations[0],
                                Diagnostics
                                    .Did_you_mean_for_0_to_be_constrained_to_type_new_args_Colon_any_1,
                                symbolToString(baseConstructorType.symbol),
                                typeToString(ctorReturn)
                            )
                        );
                    }
                    return type.resolvedBaseConstructorType = errorType;
                }
                type.resolvedBaseConstructorType = baseConstructorType;
            }
            return type.resolvedBaseConstructorType;
        }

        function getBaseTypes(type: InterfaceType): BaseType[] {
            if (!type.resolvedBaseTypes) {
                if (type.objectFlags & ObjectFlags.Tuple) {
                    type
                        .resolvedBaseTypes = [createArrayType(
                            getUnionType(
                                type.typeParameters || emptyArray
                            ),
                            (<TupleType> type).readonly
                        )];
                } else if (type.symbol.flags
                    & (SymbolFlags.Class | SymbolFlags.Interface))
                {
                    if (type.symbol.flags & SymbolFlags.Class) {
                        resolveBaseTypesOfClass(type);
                    }
                    if (type.symbol.flags & SymbolFlags.Interface) {
                        resolveBaseTypesOfInterface(type);
                    }
                } else {
                    Debug.fail('type must be class or interface');
                }
            }
            return type.resolvedBaseTypes;
        }

        function resolveBaseTypesOfClass(type: InterfaceType) {
            type.resolvedBaseTypes = resolvingEmptyArray;
            const baseConstructorType = getApparentType(getBaseConstructorTypeOfClass(type));
            if (!(baseConstructorType.flags
                & (TypeFlags.Object | TypeFlags.Intersection | TypeFlags.Any)))
            {
                return type.resolvedBaseTypes = emptyArray;
            }
            const baseTypeNode = getBaseTypeNodeOfClass(type)!;
            let baseType: Type;
            const originalBaseType = baseConstructorType.symbol
                ? getDeclaredTypeOfSymbol(baseConstructorType.symbol)
                : undefined;
            if (baseConstructorType.symbol
                && baseConstructorType.symbol.flags & SymbolFlags.Class
                && areAllOuterTypeParametersApplied(originalBaseType!))
            {
                // When base constructor type is a class with no captured type arguments we know that the constructors all have the same type parameters as the
                // class and all return the instance type of the class. There is no need for further checks and we can apply the
                // type arguments in the same manner as a type reference to get the same error reporting experience.
                baseType = getTypeFromClassOrInterfaceReference(
                    baseTypeNode,
                    baseConstructorType.symbol
                );
            } else if (baseConstructorType.flags & TypeFlags.Any) {
                baseType = baseConstructorType;
            } else {
                // The class derives from a "class-like" constructor function, check that we have at least one construct signature
                // with a matching number of type parameters and use the return type of the first instantiated signature. Elsewhere
                // we check that all instantiated signatures return the same type.
                const constructors = getInstantiatedConstructorsForTypeArguments(
                    baseConstructorType,
                    baseTypeNode.typeArguments,
                    baseTypeNode
                );
                if (!constructors.length) {
                    error(
                        baseTypeNode.expression,
                        Diagnostics
                            .No_base_constructor_has_the_specified_number_of_type_arguments
                    );
                    return type.resolvedBaseTypes = emptyArray;
                }
                baseType = getReturnTypeOfSignature(constructors[0]);
            }

            if (baseType === errorType) {
                return type.resolvedBaseTypes = emptyArray;
            }
            if (!isValidBaseType(baseType)) {
                error(
                    baseTypeNode.expression,
                    Diagnostics
                        .Base_constructor_return_type_0_is_not_an_object_type_or_intersection_of_object_types_with_statically_known_members,
                    typeToString(baseType)
                );
                return type.resolvedBaseTypes = emptyArray;
            }
            if (type === baseType || hasBaseType(baseType, type)) {
                error(
                    type.symbol.valueDeclaration,
                    Diagnostics
                        .Type_0_recursively_references_itself_as_a_base_type,
                    typeToString(
                        type, /*enclosingDeclaration*/
                        undefined,
                        TypeFormatFlags.WriteArrayAsGenericType
                    )
                );
                return type.resolvedBaseTypes = emptyArray;
            }
            if (type.resolvedBaseTypes === resolvingEmptyArray) {
                // Circular reference, likely through instantiation of default parameters
                // (otherwise there'd be an error from hasBaseType) - this is fine, but `.members` should be reset
                // as `getIndexedAccessType` via `instantiateType` via `getTypeFromClassOrInterfaceReference` forces a
                // partial instantiation of the members without the base types fully resolved
                type.members = undefined;
            }
            return type.resolvedBaseTypes = [baseType];
        }

        function areAllOuterTypeParametersApplied(type:
            Type): boolean
        { // TODO: GH#18217 Shouldn't this take an InterfaceType?
            // An unapplied type parameter has its symbol still the same as the matching argument symbol.
            // Since parameters are applied outer-to-inner, only the last outer parameter needs to be checked.
            const outerTypeParameters = (<InterfaceType> type)
                .outerTypeParameters;
            if (outerTypeParameters) {
                const last = outerTypeParameters.length - 1;
                const typeArguments = getTypeArguments(<TypeReference> type);
                return outerTypeParameters[last].symbol
                    !== typeArguments[last].symbol;
            }
            return true;
        }

        // A valid base type is `any`, an object type or intersection of object types.
        function isValidBaseType(type: Type): type is BaseType {
            if (type.flags & TypeFlags.TypeParameter) {
                const constraint = getBaseConstraintOfType(type);
                if (constraint) {
                    return isValidBaseType(constraint);
                }
            }
            // TODO: Given that we allow type parmeters here now, is this `!isGenericMappedType(type)` check really needed?
            // There's no reason a `T` should be allowed while a `Readonly<T>` should not.
            return !!(type.flags
                & (TypeFlags.Object | TypeFlags.NonPrimitive | TypeFlags.Any))
                && !isGenericMappedType(type)
                || !!(type.flags & TypeFlags.Intersection)
                && every((<IntersectionType> type).types, isValidBaseType);
        }

        function resolveBaseTypesOfInterface(type: InterfaceType): void {
            type.resolvedBaseTypes = type.resolvedBaseTypes || emptyArray;
            for (const declaration of type.symbol.declarations) {
                if (declaration.kind === SyntaxKind.InterfaceDeclaration
                    && getInterfaceBaseTypeNodes(<InterfaceDeclaration> declaration))
                {
                    for (const node
                        of getInterfaceBaseTypeNodes(<InterfaceDeclaration> declaration)!)
                    {
                        const baseType = getTypeFromTypeNode(node);
                        if (baseType !== errorType) {
                            if (isValidBaseType(baseType)) {
                                if (type !== baseType
                                    && !hasBaseType(baseType, type))
                                {
                                    if (type.resolvedBaseTypes
                                        === emptyArray)
                                    {
                                        type
                                            .resolvedBaseTypes = [<ObjectType> baseType];
                                    } else {
                                        type.resolvedBaseTypes.push(baseType);
                                    }
                                } else {
                                    error(
                                        declaration,
                                        Diagnostics
                                            .Type_0_recursively_references_itself_as_a_base_type,
                                        typeToString(
                                            type, /*enclosingDeclaration*/
                                            undefined,
                                            TypeFormatFlags
                                                .WriteArrayAsGenericType
                                        )
                                    );
                                }
                            } else {
                                error(
                                    node,
                                    Diagnostics
                                        .An_interface_can_only_extend_an_object_type_or_intersection_of_object_types_with_statically_known_members
                                );
                            }
                        }
                    }
                }
            }
        }

        /**
         * Returns true if the interface given by the symbol is free of "this" references.
         *
         * Specifically, the result is true if the interface itself contains no references
         * to "this" in its body, if all base types are interfaces,
         * and if none of the base interfaces have a "this" type.
         */
        function isThislessInterface(symbol: Symbol): boolean {
            for (const declaration of symbol.declarations) {
                if (declaration.kind === SyntaxKind.InterfaceDeclaration) {
                    if (declaration.flags & NodeFlags.ContainsThis) {
                        return false;
                    }
                    const baseTypeNodes = getInterfaceBaseTypeNodes(<InterfaceDeclaration> declaration);
                    if (baseTypeNodes) {
                        for (const node of baseTypeNodes) {
                            if (isEntityNameExpression(node.expression)) {
                                const baseSymbol = resolveEntityName(
                                    node.expression,
                                    SymbolFlags.Type, /*ignoreErrors*/
                                    true
                                );
                                if (!baseSymbol
                                    || !(baseSymbol.flags
                                        & SymbolFlags.Interface)
                                    || getDeclaredTypeOfClassOrInterface(baseSymbol)
                                        .thisType)
                                {
                                    return false;
                                }
                            }
                        }
                    }
                }
            }
            return true;
        }

        function getDeclaredTypeOfClassOrInterface(
            symbol: Symbol
        ): InterfaceType {
            let links = getSymbolLinks(symbol);
            const originalLinks = links;
            if (!links.declaredType) {
                const kind = symbol.flags & SymbolFlags.Class
                    ? ObjectFlags.Class
                    : ObjectFlags.Interface;
                const merged = mergeJSSymbols(
                    symbol,
                    getAssignedClassSymbol(symbol.valueDeclaration)
                );
                if (merged) {
                    // note:we overwrite links because we just cloned the symbol
                    symbol = links = merged;
                }

                const type = originalLinks.declaredType = links
                    .declaredType = <InterfaceType> createObjectType(
                        kind,
                        symbol
                    );
                const outerTypeParameters = getOuterTypeParametersOfClassOrInterface(symbol);
                const localTypeParameters = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol);
                // A class or interface is generic if it has type parameters or a "this" type. We always give classes a "this" type
                // because it is not feasible to analyze all members to determine if the "this" type escapes the class (in particular,
                // property types inferred from initializers and method return types inferred from return statements are very hard
                // to exhaustively analyze). We give interfaces a "this" type if we can't definitely determine that they are free of
                // "this" references.
                if (outerTypeParameters || localTypeParameters
                    || kind === ObjectFlags.Class
                    || !isThislessInterface(symbol))
                {
                    type.objectFlags |= ObjectFlags.Reference;
                    type.typeParameters = concatenate(
                        outerTypeParameters,
                        localTypeParameters
                    );
                    type.outerTypeParameters = outerTypeParameters;
                    type.localTypeParameters = localTypeParameters;
                    (<GenericType> type)
                        .instantiations = createMap<TypeReference>();
                    (<GenericType> type).instantiations
                        .set(
                            getTypeListId(type.typeParameters),
                            <GenericType> type
                        );
                    (<GenericType> type).target = <GenericType> type;
                    (<GenericType> type).resolvedTypeArguments = type
                        .typeParameters;
                    type.thisType = createTypeParameter(symbol);
                    type.thisType.isThisType = true;
                    type.thisType.constraint = type;
                }
            }
            return <InterfaceType> links.declaredType;
        }

        function getDeclaredTypeOfTypeAlias(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            if (!links.declaredType) {
                // Note that we use the links object as the target here because the symbol object is used as the unique
                // identity for resolution of the 'type' property in SymbolLinks.
                if (!pushTypeResolution(
                    symbol,
                    TypeSystemPropertyName.DeclaredType
                )) {
                    return errorType;
                }

                let type: Type;
                let declaration;
                if (isTypeOnlyAlias(symbol)) {
                    // Symbol is synthetic type alias for type-only import or export.
                    // See `createSyntheticTypeAlias`.
                    type = getDeclaredTypeOfSymbol(symbol.immediateTarget);
                    declaration = symbol.valueDeclaration;
                } else {
                    declaration = Debug
                        .assertDefined(
                            find(symbol.declarations, isTypeAlias),
                            'Type alias symbol with no valid declaration found'
                        );
                    const typeNode = isJSDocTypeAlias(declaration)
                        ? declaration.typeExpression
                        : declaration.type;
                    // If typeNode is missing, we will error in checkJSDocTypedefTag.
                    type = typeNode
                        ? getTypeFromTypeNode(typeNode)
                        : errorType;
                }

                if (popTypeResolution()) {
                    const typeParameters = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol);
                    if (typeParameters) {
                        // Initialize the instantiation cache for generic type aliases. The declared type corresponds to
                        // an instantiation of the type alias with the type parameters supplied as type arguments.
                        links.typeParameters = typeParameters;
                        links.instantiations = createMap<Type>();
                        links.instantiations.set(
                            getTypeListId(typeParameters),
                            type
                        );
                    }
                } else {
                    type = errorType;
                    error(
                        isNamedDeclaration(declaration)
                            ? declaration.name
                            : declaration || declaration,
                        Diagnostics.Type_alias_0_circularly_references_itself,
                        symbolToString(symbol)
                    );
                }
                links.declaredType = type;
            }
            return links.declaredType;
        }

        function isStringConcatExpression(expr: Node): boolean {
            if (isStringLiteralLike(expr)) {
                return true;
            } else if (expr.kind === SyntaxKind.BinaryExpression) {
                return isStringConcatExpression((<BinaryExpression> expr).left)
                    && isStringConcatExpression(
                        (<BinaryExpression> expr).right
                    );
            }
            return false;
        }

        function isLiteralEnumMember(member: EnumMember) {
            const expr = member.initializer;
            if (!expr) {
                return !(member.flags & NodeFlags.Ambient);
            }
            switch (expr.kind) {
                case SyntaxKind.StringLiteral:
                case SyntaxKind.NumericLiteral:
                case SyntaxKind.NoSubstitutionTemplateLiteral:
                    return true;
                case SyntaxKind.PrefixUnaryExpression:
                    return (<PrefixUnaryExpression> expr).operator
                        === SyntaxKind.MinusToken
                        && (<PrefixUnaryExpression> expr).operand.kind
                        === SyntaxKind.NumericLiteral;
                case SyntaxKind.Identifier:
                    return nodeIsMissing(expr)
                        || !!getSymbolOfNode(member.parent).exports!
                            .get((<Identifier> expr).escapedText);
                case SyntaxKind.BinaryExpression:
                    return isStringConcatExpression(expr);
                default:
                    return false;
            }
        }

        function getEnumKind(symbol: Symbol): EnumKind {
            const links = getSymbolLinks(symbol);
            if (links.enumKind !== undefined) {
                return links.enumKind;
            }
            let hasNonLiteralMember = false;
            for (const declaration of symbol.declarations) {
                if (declaration.kind === SyntaxKind.EnumDeclaration) {
                    for (const member of (<EnumDeclaration> declaration)
                        .members)
                    {
                        if (member.initializer
                            && isStringLiteralLike(member.initializer))
                        {
                            return links.enumKind = EnumKind.Literal;
                        }
                        if (!isLiteralEnumMember(member)) {
                            hasNonLiteralMember = true;
                        }
                    }
                }
            }
            return links.enumKind = hasNonLiteralMember
                ? EnumKind.Numeric
                : EnumKind.Literal;
        }

        function getBaseTypeOfEnumLiteralType(type: Type) {
            return type.flags & TypeFlags.EnumLiteral
                && !(type.flags & TypeFlags.Union)
                ? getDeclaredTypeOfSymbol(getParentOfSymbol(type.symbol)!)
                : type;
        }

        function getDeclaredTypeOfEnum(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            if (links.declaredType) {
                return links.declaredType;
            }
            if (getEnumKind(symbol) === EnumKind.Literal) {
                enumCount++;
                const memberTypeList: Type[] = [];
                for (const declaration of symbol.declarations) {
                    if (declaration.kind === SyntaxKind.EnumDeclaration) {
                        for (const member of (<EnumDeclaration> declaration)
                            .members)
                        {
                            const value = getEnumMemberValue(member);
                            const memberType = getFreshTypeOfLiteralType(
                                getLiteralType(
                                    value !== undefined
                                        ? value
                                        : 0,
                                    enumCount,
                                    getSymbolOfNode(member)
                                )
                            );
                            getSymbolLinks(getSymbolOfNode(member))
                                .declaredType = memberType;
                            memberTypeList
                                .push(getRegularTypeOfLiteralType(memberType));
                        }
                    }
                }
                if (memberTypeList.length) {
                    const enumType = getUnionType(
                        memberTypeList,
                        UnionReduction.Literal,
                        symbol, /*aliasTypeArguments*/
                        undefined
                    );
                    if (enumType.flags & TypeFlags.Union) {
                        enumType.flags |= TypeFlags.EnumLiteral;
                        enumType.symbol = symbol;
                    }
                    return links.declaredType = enumType;
                }
            }
            const enumType = createType(TypeFlags.Enum);
            enumType.symbol = symbol;
            return links.declaredType = enumType;
        }

        function getDeclaredTypeOfEnumMember(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            if (!links.declaredType) {
                const enumType = getDeclaredTypeOfEnum(getParentOfSymbol(symbol)!);
                if (!links.declaredType) {
                    links.declaredType = enumType;
                }
            }
            return links.declaredType;
        }

        function getDeclaredTypeOfTypeParameter(symbol:
            Symbol): TypeParameter
        {
            const links = getSymbolLinks(symbol);
            return links.declaredType
                || (links.declaredType = createTypeParameter(symbol));
        }

        function getDeclaredTypeOfAlias(symbol: Symbol): Type {
            const links = getSymbolLinks(symbol);
            return links.declaredType
                || (links
                    .declaredType = getDeclaredTypeOfSymbol(resolveAlias(symbol)));
        }

        function getDeclaredTypeOfSymbol(symbol: Symbol): Type {
            return tryGetDeclaredTypeOfSymbol(symbol) || errorType;
        }

        function tryGetDeclaredTypeOfSymbol(symbol: Symbol): Type | undefined {
            if (symbol.flags & (SymbolFlags.Class | SymbolFlags.Interface)) {
                return getDeclaredTypeOfClassOrInterface(symbol);
            }
            if (symbol.flags & SymbolFlags.TypeAlias) {
                return getDeclaredTypeOfTypeAlias(symbol);
            }
            if (symbol.flags & SymbolFlags.TypeParameter) {
                return getDeclaredTypeOfTypeParameter(symbol);
            }
            if (symbol.flags & SymbolFlags.Enum) {
                return getDeclaredTypeOfEnum(symbol);
            }
            if (symbol.flags & SymbolFlags.EnumMember) {
                return getDeclaredTypeOfEnumMember(symbol);
            }
            if (symbol.flags & SymbolFlags.Alias) {
                return getDeclaredTypeOfAlias(symbol);
            }
            return undefined;
        }

        /**
         * A type is free of this references if it's the any, string, number, boolean, symbol, or void keyword, a string
         * literal type, an array with an element type that is free of this references, or a type reference that is
         * free of this references.
         */
        function isThislessType(node: TypeNode): boolean {
            switch (node.kind) {
                case SyntaxKind.AnyKeyword:
                case SyntaxKind.UnknownKeyword:
                case SyntaxKind.StringKeyword:
                case SyntaxKind.NumberKeyword:
                case SyntaxKind.BigIntKeyword:
                case SyntaxKind.BooleanKeyword:
                case SyntaxKind.SymbolKeyword:
                case SyntaxKind.ObjectKeyword:
                case SyntaxKind.VoidKeyword:
                case SyntaxKind.UndefinedKeyword:
                case SyntaxKind.NullKeyword:
                case SyntaxKind.NeverKeyword:
                case SyntaxKind.LiteralType:
                    return true;
                case SyntaxKind.ArrayType:
                    return isThislessType((<ArrayTypeNode> node).elementType);
                case SyntaxKind.TypeReference:
                    return !(node as TypeReferenceNode).typeArguments
                        || (node as TypeReferenceNode).typeArguments!
                            .every(isThislessType);
            }
            return false;
        }

        /** A type parameter is thisless if its constraint is thisless, or if it has no constraint. */
        function isThislessTypeParameter(node: TypeParameterDeclaration) {
            const constraint = getEffectiveConstraintOfTypeParameter(node);
            return !constraint || isThislessType(constraint);
        }

        /**
         * A variable-like declaration is free of this references if it has a type annotation
         * that is thisless, or if it has no type annotation and no initializer (and is thus of type any).
         */
        function isThislessVariableLikeDeclaration(
            node: VariableLikeDeclaration
        ): boolean {
            const typeNode = getEffectiveTypeAnnotationNode(node);
            return typeNode ? isThislessType(typeNode) : !hasInitializer(node);
        }

        /**
         * A function-like declaration is considered free of `this` references if it has a return type
         * annotation that is free of this references and if each parameter is thisless and if
         * each type parameter (if present) is thisless.
         */
        function isThislessFunctionLikeDeclaration(
            node: FunctionLikeDeclaration
        ): boolean {
            const returnType = getEffectiveReturnTypeNode(node);
            const typeParameters = getEffectiveTypeParameterDeclarations(node);
            return (node.kind === SyntaxKind.Constructor
                || (!!returnType && isThislessType(returnType)))
                && node.parameters.every(isThislessVariableLikeDeclaration)
                && typeParameters.every(isThislessTypeParameter);
        }

        /**
         * Returns true if the class or interface member given by the symbol is free of "this" references. The
         * function may return false for symbols that are actually free of "this" references because it is not
         * feasible to perform a complete analysis in all cases. In particular, property members with types
         * inferred from their initializers and function members with inferred return types are conservatively
         * assumed not to be free of "this" references.
         */
        function isThisless(symbol: Symbol): boolean {
            if (symbol.declarations && symbol.declarations.length === 1) {
                const declaration = symbol.declarations[0];
                if (declaration) {
                    switch (declaration.kind) {
                        case SyntaxKind.PropertyDeclaration:
                        case SyntaxKind.PropertySignature:
                            return isThislessVariableLikeDeclaration(<VariableLikeDeclaration> declaration);
                        case SyntaxKind.MethodDeclaration:
                        case SyntaxKind.MethodSignature:
                        case SyntaxKind.Constructor:
                        case SyntaxKind.GetAccessor:
                        case SyntaxKind.SetAccessor:
                            return isThislessFunctionLikeDeclaration(
                                <FunctionLikeDeclaration
                                    | AccessorDeclaration> declaration
                            );
                    }
                }
            }
            return false;
        }

        // The mappingThisOnly flag indicates that the only type parameter being mapped is "this". When the flag is true,
        // we check symbols to see if we can quickly conclude they are free of "this" references, thus needing no instantiation.
        function createInstantiatedSymbolTable(
            symbols: Symbol[],
            mapper: TypeMapper,
            mappingThisOnly: boolean
        ): SymbolTable {
            const result = createSymbolTable();
            for (const symbol of symbols) {
                result.set(
                    symbol.escapedName,
                    mappingThisOnly && isThisless(symbol)
                        ? symbol
                        : instantiateSymbol(symbol, mapper)
                );
            }
            return result;
        }

        function addInheritedMembers(
            symbols: SymbolTable,
            baseSymbols: Symbol[]
        ) {
            for (const s of baseSymbols) {
                if (!symbols.has(s.escapedName)
                    && !isStaticPrivateIdentifierProperty(s))
                {
                    symbols.set(s.escapedName, s);
                }
            }
        }

        function isStaticPrivateIdentifierProperty(s: Symbol): boolean {
            return !!s.valueDeclaration
                && isPrivateIdentifierPropertyDeclaration(s.valueDeclaration)
                && hasModifier(s.valueDeclaration, ModifierFlags.Static);
        }

        function resolveDeclaredMembers(
            type: InterfaceType
        ): InterfaceTypeWithDeclaredMembers {
            if (!(<InterfaceTypeWithDeclaredMembers> type)
                .declaredProperties)
            {
                const symbol = type.symbol;
                const members = getMembersOfSymbol(symbol);
                (<InterfaceTypeWithDeclaredMembers> type)
                    .declaredProperties = getNamedMembers(members);
                // Start with signatures at empty array in case of recursive types
                (<InterfaceTypeWithDeclaredMembers> type)
                    .declaredCallSignatures = emptyArray;
                (<InterfaceTypeWithDeclaredMembers> type)
                    .declaredConstructSignatures = emptyArray;

                (<InterfaceTypeWithDeclaredMembers> type)
                    .declaredCallSignatures = getSignaturesOfSymbol(
                        members.get(InternalSymbolName.Call)
                    );
                (<InterfaceTypeWithDeclaredMembers> type)
                    .declaredConstructSignatures = getSignaturesOfSymbol(
                        members.get(InternalSymbolName.New)
                    );
                (<InterfaceTypeWithDeclaredMembers> type)
                    .declaredStringIndexInfo = getIndexInfoOfSymbol(
                        symbol,
                        IndexKind.String
                    );
                (<InterfaceTypeWithDeclaredMembers> type)
                    .declaredNumberIndexInfo = getIndexInfoOfSymbol(
                        symbol,
                        IndexKind.Number
                    );
            }
            return <InterfaceTypeWithDeclaredMembers> type;
        }

        /**
         * Indicates whether a type can be used as a property name.
         */
        function isTypeUsableAsPropertyName(
            type: Type
        ): type is StringLiteralType | NumberLiteralType | UniqueESSymbolType {
            return !!(type.flags & TypeFlags.StringOrNumberLiteralOrUnique);
        }

        /**
         * Indicates whether a declaration name is definitely late-bindable.
         * A declaration name is only late-bindable if:
         * - It is a `ComputedPropertyName`.
         * - Its expression is an `Identifier` or either a `PropertyAccessExpression` an
         * `ElementAccessExpression` consisting only of these same three types of nodes.
         * - The type of its expression is a string or numeric literal type, or is a `unique symbol` type.
         */
        function isLateBindableName(
            node: DeclarationName
        ): node is LateBoundName {
            if (!isComputedPropertyName(node)
                && !isElementAccessExpression(node))
            {
                return false;
            }
            const expr = isComputedPropertyName(node)
                ? node.expression
                : node.argumentExpression;
            return isEntityNameExpression(expr)
                && isTypeUsableAsPropertyName(
                    isComputedPropertyName(node)
                        ? checkComputedPropertyName(node)
                        : checkExpressionCached(expr)
                );
        }

        function isLateBoundName(name: __String): boolean {
            return (name as string).charCodeAt(0) === CharacterCodes._
                && (name as string).charCodeAt(1) === CharacterCodes._
                && (name as string).charCodeAt(2) === CharacterCodes.at;
        }

        /**
         * Indicates whether a declaration has a late-bindable dynamic name.
         */
        function hasLateBindableName(
            node: Declaration
        ): node is LateBoundDeclaration
            | LateBoundBinaryExpressionDeclaration
        {
            const name = getNameOfDeclaration(node);
            return !!name && isLateBindableName(name);
        }

        /**
         * Indicates whether a declaration has a dynamic name that cannot be late-bound.
         */
        function hasNonBindableDynamicName(node: Declaration) {
            return hasDynamicName(node) && !hasLateBindableName(node);
        }

        /**
         * Indicates whether a declaration name is a dynamic name that cannot be late-bound.
         */
        function isNonBindableDynamicName(node: DeclarationName) {
            return isDynamicName(node) && !isLateBindableName(node);
        }

        /**
         * Gets the symbolic name for a member from its type.
         */
        function getPropertyNameFromType(
            type: StringLiteralType | NumberLiteralType | UniqueESSymbolType
        ): __String {
            if (type.flags & TypeFlags.UniqueESSymbol) {
                return (<UniqueESSymbolType> type).escapedName;
            }
            if (type.flags
                & (TypeFlags.StringLiteral | TypeFlags.NumberLiteral))
            {
                return escapeLeadingUnderscores(
                    '' + (<StringLiteralType | NumberLiteralType> type).value
                );
            }
            return Debug.fail();
        }

        /**
         * Adds a declaration to a late-bound dynamic member. This performs the same function for
         * late-bound members that `addDeclarationToSymbol` in binder.ts performs for early-bound
         * members.
         */
        function addDeclarationToLateBoundSymbol(
            symbol: Symbol,
            member: LateBoundDeclaration | BinaryExpression,
            symbolFlags: SymbolFlags
        ) {
            Debug.assert(
                !!(getCheckFlags(symbol) & CheckFlags.Late),
                'Expected a late-bound symbol.'
            );
            symbol.flags |= symbolFlags;
            getSymbolLinks(member.symbol).lateSymbol = symbol;
            if (!symbol.declarations) {
                symbol.declarations = [member];
            } else {
                symbol.declarations.push(member);
            }
            if (symbolFlags & SymbolFlags.Value) {
                if (!symbol.valueDeclaration
                    || symbol.valueDeclaration.kind !== member.kind)
                {
                    symbol.valueDeclaration = member;
                }
            }
        }

        /**
         * Performs late-binding of a dynamic member. This performs the same function for
         * late-bound members that `declareSymbol` in binder.ts performs for early-bound
         * members.
         *
         * If a symbol is a dynamic name from a computed property, we perform an additional "late"
         * binding phase to attempt to resolve the name for the symbol from the type of the computed
         * property's expression. If the type of the expression is a string-literal, numeric-literal,
         * or unique symbol type, we can use that type as the name of the symbol.
         *
         * For example, given:
         *
         *   const x = Symbol();
         *
         *   interface I {
         *     [x]: number;
         *   }
         *
         * The binder gives the property `[x]: number` a special symbol with the name "__computed".
         * In the late-binding phase we can type-check the expression `x` and see that it has a
         * unique symbol type which we can then use as the name of the member. This allows users
         * to define custom symbols that can be used in the members of an object type.
         *
         * @param parent The containing symbol for the member.
         * @param earlySymbols The early-bound symbols of the parent.
         * @param lateSymbols The late-bound symbols of the parent.
         * @param decl The member to bind.
         */
        function lateBindMember(
            parent: Symbol,
            earlySymbols: SymbolTable | undefined,
            lateSymbols: SymbolTable,
            decl: LateBoundDeclaration | LateBoundBinaryExpressionDeclaration
        ) {
            Debug.assert(
                !!decl.symbol,
                'The member is expected to have a symbol.'
            );
            const links = getNodeLinks(decl);
            if (!links.resolvedSymbol) {
                // In the event we attempt to resolve the late-bound name of this member recursively,
                // fall back to the early-bound name of this member.
                links.resolvedSymbol = decl.symbol;
                const declName = isBinaryExpression(decl)
                    ? decl.left
                    : decl.name;
                const type = isElementAccessExpression(declName)
                    ? checkExpressionCached(declName.argumentExpression)
                    : checkComputedPropertyName(declName);
                if (isTypeUsableAsPropertyName(type)) {
                    const memberName = getPropertyNameFromType(type);
                    const symbolFlags = decl.symbol.flags;

                    // Get or add a late-bound symbol for the member. This allows us to merge late-bound accessor declarations.
                    let lateSymbol = lateSymbols.get(memberName);
                    if (!lateSymbol) {
                        lateSymbols.set(
                            memberName,
                            lateSymbol = createSymbol(
                                SymbolFlags.None,
                                memberName,
                                CheckFlags.Late
                            )
                        );
                    }

                    // Report an error if a late-bound member has the same name as an early-bound member,
                    // or if we have another early-bound symbol declaration with the same name and
                    // conflicting flags.
                    const earlySymbol = earlySymbols
                        && earlySymbols.get(memberName);
                    if (lateSymbol.flags & getExcludedSymbolFlags(symbolFlags)
                        || earlySymbol)
                    {
                        // If we have an existing early-bound member, combine its declarations so that we can
                        // report an error at each declaration.
                        const declarations = earlySymbol
                            ? concatenate(
                                earlySymbol.declarations,
                                lateSymbol.declarations
                            )
                            : lateSymbol.declarations;
                        const name = !(type.flags & TypeFlags.UniqueESSymbol)
                            && unescapeLeadingUnderscores(memberName)
                            || declarationNameToString(declName);
                        forEach(
                            declarations,
                            declaration => error(
                                getNameOfDeclaration(declaration)
                                    || declaration,
                                Diagnostics.Property_0_was_also_declared_here,
                                name
                            )
                        );
                        error(
                            declName || decl,
                            Diagnostics.Duplicate_property_0,
                            name
                        );
                        lateSymbol = createSymbol(
                            SymbolFlags.None,
                            memberName,
                            CheckFlags.Late
                        );
                    }
                    lateSymbol.nameType = type;
                    addDeclarationToLateBoundSymbol(
                        lateSymbol,
                        decl,
                        symbolFlags
                    );
                    if (lateSymbol.parent) {
                        Debug.assert(
                            lateSymbol.parent === parent,
                            'Existing symbol parent should match new one'
                        );
                    } else {
                        lateSymbol.parent = parent;
                    }
                    return links.resolvedSymbol = lateSymbol;
                }
            }
            return links.resolvedSymbol;
        }

        function getResolvedMembersOrExportsOfSymbol(
            symbol: Symbol,
            resolutionKind: MembersOrExportsResolutionKind
        ): UnderscoreEscapedMap<Symbol> {
            const links = getSymbolLinks(symbol);
            if (!links[resolutionKind]) {
                const isStatic = resolutionKind
                    === MembersOrExportsResolutionKind.resolvedExports;
                const earlySymbols = !isStatic
                    ? symbol.members
                    : symbol.flags & SymbolFlags.Module
                        ? getExportsOfModuleWorker(symbol)
                        : symbol.exports;

                // In the event we recursively resolve the members/exports of the symbol, we
                // set the initial value of resolvedMembers/resolvedExports to the early-bound
                // members/exports of the symbol.
                links[resolutionKind] = earlySymbols || emptySymbols;

                // fill in any as-yet-unresolved late-bound members.
                const lateSymbols = createSymbolTable();
                for (const decl of symbol.declarations) {
                    const members = getMembersOfDeclaration(decl);
                    if (members) {
                        for (const member of members) {
                            if (isStatic === hasStaticModifier(member)
                                && hasLateBindableName(member))
                            {
                                lateBindMember(
                                    symbol,
                                    earlySymbols,
                                    lateSymbols,
                                    member
                                );
                            }
                        }
                    }
                }
                const assignments = symbol.assignmentDeclarationMembers;
                if (assignments) {
                    const decls = arrayFrom(assignments.values());
                    for (const member of decls) {
                        const assignmentKind = getAssignmentDeclarationKind(
                            member as BinaryExpression | CallExpression
                        );
                        const isInstanceMember = assignmentKind
                            === AssignmentDeclarationKind.PrototypeProperty
                            || assignmentKind
                            === AssignmentDeclarationKind.ThisProperty
                            || assignmentKind
                            === AssignmentDeclarationKind
                                .ObjectDefinePrototypeProperty
                            || assignmentKind
                            === AssignmentDeclarationKind
                                .Prototype; // A straight `Prototype` assignment probably can never have a computed name
                        if (isStatic === !isInstanceMember
                            && hasLateBindableName(member))
                        {
                            lateBindMember(
                                symbol,
                                earlySymbols,
                                lateSymbols,
                                member
                            );
                        }
                    }
                }

                links
                    [resolutionKind] = combineSymbolTables(
                        earlySymbols,
                        lateSymbols
                    ) || emptySymbols;
            }

            return links[resolutionKind]!;
        }

        /**
         * Gets a SymbolTable containing both the early- and late-bound members of a symbol.
         *
         * For a description of late-binding, see `lateBindMember`.
         */
        function getMembersOfSymbol(symbol: Symbol) {
            return symbol.flags & SymbolFlags.LateBindingContainer
                ? getResolvedMembersOrExportsOfSymbol(
                    symbol,
                    MembersOrExportsResolutionKind.resolvedMembers
                )
                : symbol.members || emptySymbols;
        }

        /**
         * If a symbol is the dynamic name of the member of an object type, get the late-bound
         * symbol of the member.
         *
         * For a description of late-binding, see `lateBindMember`.
         */
        function getLateBoundSymbol(symbol: Symbol): Symbol {
            if (symbol.flags & SymbolFlags.ClassMember
                && symbol.escapedName === InternalSymbolName.Computed)
            {
                const links = getSymbolLinks(symbol);
                if (!links.lateSymbol
                    && some(symbol.declarations, hasLateBindableName))
                {
                    // force late binding of members/exports. This will set the late-bound symbol
                    const parent = getMergedSymbol(symbol.parent)!;
                    if (some(symbol.declarations, hasStaticModifier)) {
                        getExportsOfSymbol(parent);
                    } else {
                        getMembersOfSymbol(parent);
                    }
                }
                return links.lateSymbol || (links.lateSymbol = symbol);
            }
            return symbol;
        }

        function getTypeWithThisArgument(
            type: Type,
            thisArgument?: Type,
            needApparentType?: boolean
        ): Type {
            if (getObjectFlags(type) & ObjectFlags.Reference) {
                const target = (<TypeReference> type).target;
                const typeArguments = getTypeArguments(<TypeReference> type);
                if (length(target.typeParameters) === length(typeArguments)) {
                    const ref = createTypeReference(
                        target,
                        concatenate(
                            typeArguments,
                            [thisArgument || target.thisType!]
                        )
                    );
                    return needApparentType ? getApparentType(ref) : ref;
                }
            } else if (type.flags & TypeFlags.Intersection) {
                return getIntersectionType(
                    map(
                        (<IntersectionType> type).types,
                        t => getTypeWithThisArgument(
                            t,
                            thisArgument,
                            needApparentType
                        )
                    )
                );
            }
            return needApparentType ? getApparentType(type) : type;
        }

        function resolveObjectTypeMembers(
            type: ObjectType,
            source: InterfaceTypeWithDeclaredMembers,
            typeParameters: readonly TypeParameter[],
            typeArguments: readonly Type[]
        ) {
            let mapper: TypeMapper;
            let members: SymbolTable;
            let callSignatures: readonly Signature[];
            let constructSignatures: readonly Signature[] | undefined;
            let stringIndexInfo: IndexInfo | undefined;
            let numberIndexInfo: IndexInfo | undefined;
            if (rangeEquals(
                typeParameters,
                typeArguments,
                0,
                typeParameters.length
            )) {
                mapper = identityMapper;
                members = source.symbol
                    ? getMembersOfSymbol(source.symbol)
                    : createSymbolTable(source.declaredProperties);
                callSignatures = source.declaredCallSignatures;
                constructSignatures = source.declaredConstructSignatures;
                stringIndexInfo = source.declaredStringIndexInfo;
                numberIndexInfo = source.declaredNumberIndexInfo;
            } else {
                mapper = createTypeMapper(typeParameters, typeArguments);
                members = createInstantiatedSymbolTable(
                    source.declaredProperties,
                    mapper, /*mappingThisOnly*/
                    typeParameters.length === 1
                );
                callSignatures = instantiateSignatures(
                    source.declaredCallSignatures,
                    mapper
                );
                constructSignatures = instantiateSignatures(
                    source.declaredConstructSignatures,
                    mapper
                );
                stringIndexInfo = instantiateIndexInfo(
                    source.declaredStringIndexInfo,
                    mapper
                );
                numberIndexInfo = instantiateIndexInfo(
                    source.declaredNumberIndexInfo,
                    mapper
                );
            }
            const baseTypes = getBaseTypes(source);
            if (baseTypes.length) {
                if (source.symbol
                    && members === getMembersOfSymbol(source.symbol))
                {
                    members = createSymbolTable(source.declaredProperties);
                }
                setStructuredTypeMembers(
                    type,
                    members,
                    callSignatures,
                    constructSignatures,
                    stringIndexInfo,
                    numberIndexInfo
                );
                const thisArgument = lastOrUndefined(typeArguments);
                for (const baseType of baseTypes) {
                    const instantiatedBaseType = thisArgument
                        ? getTypeWithThisArgument(
                            instantiateType(
                                baseType,
                                mapper
                            ),
                            thisArgument
                        )
                        : baseType;
                    addInheritedMembers(
                        members,
                        getPropertiesOfType(instantiatedBaseType)
                    );
                    callSignatures = concatenate(
                        callSignatures,
                        getSignaturesOfType(
                            instantiatedBaseType,
                            SignatureKind.Call
                        )
                    );
                    constructSignatures = concatenate(
                        constructSignatures,
                        getSignaturesOfType(
                            instantiatedBaseType,
                            SignatureKind.Construct
                        )
                    );
                    if (!stringIndexInfo) {
                        stringIndexInfo = instantiatedBaseType === anyType
                            ? createIndexInfo(anyType, /*isReadonly*/ false)
                            : getIndexInfoOfType(
                                instantiatedBaseType,
                                IndexKind.String
                            );
                    }
                    numberIndexInfo = numberIndexInfo
                        || getIndexInfoOfType(
                            instantiatedBaseType,
                            IndexKind.Number
                        );
                }
            }
            setStructuredTypeMembers(
                type,
                members,
                callSignatures,
                constructSignatures,
                stringIndexInfo,
                numberIndexInfo
            );
        }

        function resolveClassOrInterfaceMembers(type: InterfaceType): void {
            resolveObjectTypeMembers(
                type,
                resolveDeclaredMembers(type),
                emptyArray,
                emptyArray
            );
        }

        function resolveTypeReferenceMembers(type: TypeReference): void {
            const source = resolveDeclaredMembers(type.target);
            const typeParameters = concatenate(
                source.typeParameters!,
                [source.thisType!]
            );
            const typeArguments = getTypeArguments(type);
            const paddedTypeArguments = typeArguments.length
                === typeParameters.length
                ? typeArguments
                : concatenate(typeArguments, [type]);
            resolveObjectTypeMembers(
                type,
                source,
                typeParameters,
                paddedTypeArguments
            );
        }

        function createSignature(
            declaration: SignatureDeclaration | JSDocSignature | undefined,
            typeParameters: readonly TypeParameter[] | undefined,
            thisParameter: Symbol | undefined,
            parameters: readonly Symbol[],
            resolvedReturnType: Type | undefined,
            resolvedTypePredicate: TypePredicate | undefined,
            minArgumentCount: number,
            flags: SignatureFlags
        ): Signature {
            const sig = new Signature(checker, flags);
            sig.declaration = declaration;
            sig.typeParameters = typeParameters;
            sig.parameters = parameters;
            sig.thisParameter = thisParameter;
            sig.resolvedReturnType = resolvedReturnType;
            sig.resolvedTypePredicate = resolvedTypePredicate;
            sig.minArgumentCount = minArgumentCount;
            sig.target = undefined;
            sig.mapper = undefined;
            sig.unionSignatures = undefined;
            return sig;
        }

        function cloneSignature(sig: Signature): Signature {
            const result = createSignature(
                sig.declaration,
                sig.typeParameters,
                sig.thisParameter,
                sig.parameters, /*resolvedReturnType*/
                undefined,
                /*resolvedTypePredicate*/ undefined,
                sig.minArgumentCount,
                sig.flags & SignatureFlags.PropagatingFlags
            );
            result.target = sig.target;
            result.mapper = sig.mapper;
            result.unionSignatures = sig.unionSignatures;
            return result;
        }

        function createUnionSignature(
            signature: Signature,
            unionSignatures: Signature[]
        ) {
            const result = cloneSignature(signature);
            result.unionSignatures = unionSignatures;
            result.target = undefined;
            result.mapper = undefined;
            return result;
        }

        function getOptionalCallSignature(
            signature: Signature,
            callChainFlags: SignatureFlags
        ): Signature {
            if ((signature.flags & SignatureFlags.CallChainFlags)
                === callChainFlags)
            {
                return signature;
            }
            if (!signature.optionalCallSignatureCache) {
                signature.optionalCallSignatureCache = {};
            }
            const key = callChainFlags === SignatureFlags.IsInnerCallChain
                ? 'inner'
                : 'outer';
            return signature.optionalCallSignatureCache[key]
                || (signature.optionalCallSignatureCache
                    [key] = createOptionalCallSignature(
                        signature,
                        callChainFlags
                    ));
        }

        function createOptionalCallSignature(
            signature: Signature,
            callChainFlags: SignatureFlags
        ) {
            Debug
                .assert(
                    callChainFlags === SignatureFlags.IsInnerCallChain
                        || callChainFlags === SignatureFlags.IsOuterCallChain,
                    'An optional call signature can either be for an inner call chain or an outer call chain, but not both.'
                );
            const result = cloneSignature(signature);
            result.flags |= callChainFlags;
            return result;
        }

        function getExpandedParameters(sig: Signature): readonly Symbol[] {
            if (signatureHasRestParameter(sig)) {
                const restIndex = sig.parameters.length - 1;
                const restParameter = sig.parameters[restIndex];
                const restType = getTypeOfSymbol(restParameter);
                if (isTupleType(restType)) {
                    const elementTypes = getTypeArguments(restType);
                    const minLength = restType.target.minLength;
                    const tupleRestIndex = restType.target.hasRestElement
                        ? elementTypes.length - 1
                        : -1;
                    const restParams = map(
                        elementTypes,
                        (t, i) => {
                            const name = getParameterNameAtPosition(
                                sig,
                                restIndex + i
                            );
                            const checkFlags = i === tupleRestIndex
                                ? CheckFlags.RestParameter
                                : i >= minLength ? CheckFlags.OptionalParameter
                                    : 0;
                            const symbol = createSymbol(
                                SymbolFlags.FunctionScopedVariable,
                                name,
                                checkFlags
                            );
                            symbol.type = i === tupleRestIndex
                                ? createArrayType(t)
                                : t;
                            return symbol;
                        }
                    );
                    return concatenate(
                        sig.parameters.slice(0, restIndex),
                        restParams
                    );
                }
            }
            return sig.parameters;
        }

        function getDefaultConstructSignatures(
            classType: InterfaceType
        ): Signature[] {
            const baseConstructorType = getBaseConstructorTypeOfClass(classType);
            const baseSignatures = getSignaturesOfType(
                baseConstructorType,
                SignatureKind.Construct
            );
            if (baseSignatures.length === 0) {
                return [createSignature(
                    undefined,
                    classType.localTypeParameters,
                    undefined,
                    emptyArray,
                    classType, /*resolvedTypePredicate*/
                    undefined,
                    0,
                    SignatureFlags.None
                )];
            }
            const baseTypeNode = getBaseTypeNodeOfClass(classType)!;
            const isJavaScript = isInJSFile(baseTypeNode);
            const typeArguments = typeArgumentsFromTypeReferenceNode(baseTypeNode);
            const typeArgCount = length(typeArguments);
            const result: Signature[] = [];
            for (const baseSig of baseSignatures) {
                const minTypeArgumentCount = getMinTypeArgumentCount(
                    baseSig.typeParameters
                );
                const typeParamCount = length(baseSig.typeParameters);
                if (isJavaScript || typeArgCount >= minTypeArgumentCount
                    && typeArgCount <= typeParamCount)
                {
                    const sig = typeParamCount
                        ? createSignatureInstantiation(
                            baseSig,
                            fillMissingTypeArguments(
                                typeArguments,
                                baseSig.typeParameters,
                                minTypeArgumentCount,
                                isJavaScript
                            )
                        )
                        : cloneSignature(baseSig);
                    sig.typeParameters = classType.localTypeParameters;
                    sig.resolvedReturnType = classType;
                    result.push(sig);
                }
            }
            return result;
        }

        function findMatchingSignature(
            signatureList: readonly Signature[],
            signature: Signature,
            partialMatch: boolean,
            ignoreThisTypes: boolean,
            ignoreReturnTypes: boolean
        ): Signature | undefined {
            for (const s of signatureList) {
                if (compareSignaturesIdentical(
                    s,
                    signature,
                    partialMatch,
                    ignoreThisTypes,
                    ignoreReturnTypes,
                    partialMatch
                        ? compareTypesSubtypeOf
                        : compareTypesIdentical
                )) {
                    return s;
                }
            }
        }

        function findMatchingSignatures(
            signatureLists: readonly (readonly Signature[])[],
            signature: Signature,
            listIndex: number
        ): Signature[] | undefined {
            if (signature.typeParameters) {
                // We require an exact match for generic signatures, so we only return signatures from the first
                // signature list and only if they have exact matches in the other signature lists.
                if (listIndex > 0) {
                    return undefined;
                }
                for (let i = 1; i < signatureLists.length; i++) {
                    if (!findMatchingSignature(
                        signatureLists[i],
                        signature, /*partialMatch*/
                        false, /*ignoreThisTypes*/
                        false, /*ignoreReturnTypes*/
                        false
                    )) {
                        return undefined;
                    }
                }
                return [signature];
            }
            let result: Signature[] | undefined;
            for (let i = 0; i < signatureLists.length; i++) {
                // Allow matching non-generic signatures to have excess parameters and different return types.
                // Prefer matching this types if possible.
                const match = i === listIndex
                    ? signature
                    : findMatchingSignature(
                        signatureLists[i],
                        signature, /*partialMatch*/
                        true, /*ignoreThisTypes*/
                        false, /*ignoreReturnTypes*/
                        true
                    );
                if (!match) {
                    return undefined;
                }
                result = appendIfUnique(result, match);
            }
            return result;
        }

        // The signatures of a union type are those signatures that are present in each of the constituent types.
        // Generic signatures must match exactly, but non-generic signatures are allowed to have extra optional
        // parameters and may differ in return types. When signatures differ in return types, the resulting return
        // type is the union of the constituent return types.
        function getUnionSignatures(
            signatureLists: readonly (readonly Signature[])[]
        ): Signature[] {
            let result: Signature[] | undefined;
            let indexWithLengthOverOne: number | undefined;
            for (let i = 0; i < signatureLists.length; i++) {
                if (signatureLists[i].length === 0) return emptyArray;
                if (signatureLists[i].length > 1) {
                    indexWithLengthOverOne = indexWithLengthOverOne
                        === undefined
                        ? i
                        : -1; // -1 is a signal there are multiple overload sets
                }
                for (const signature of signatureLists[i]) {
                    // Only process signatures with parameter lists that aren't already in the result list
                    if (!result
                        || !findMatchingSignature(
                            result,
                            signature, /*partialMatch*/
                            false, /*ignoreThisTypes*/
                            false, /*ignoreReturnTypes*/
                            true
                        ))
                    {
                        const unionSignatures = findMatchingSignatures(
                            signatureLists,
                            signature,
                            i
                        );
                        if (unionSignatures) {
                            let s = signature;
                            // Union the result types when more than one signature matches
                            if (unionSignatures.length > 1) {
                                let thisParameter = signature.thisParameter;
                                const firstThisParameterOfUnionSignatures = forEach(
                                    unionSignatures,
                                    sig => sig.thisParameter
                                );
                                if (firstThisParameterOfUnionSignatures) {
                                    const thisType = getIntersectionType(
                                        mapDefined(
                                            unionSignatures,
                                            sig => sig.thisParameter
                                                && getTypeOfSymbol(
                                                    sig.thisParameter
                                                )
                                        )
                                    );
                                    thisParameter = createSymbolWithType(
                                        firstThisParameterOfUnionSignatures,
                                        thisType
                                    );
                                }
                                s = createUnionSignature(
                                    signature,
                                    unionSignatures
                                );
                                s.thisParameter = thisParameter;
                            }
                            (result || (result = [])).push(s);
                        }
                    }
                }
            }
            if (!length(result) && indexWithLengthOverOne !== -1) {
                // No sufficiently similar signature existed to subsume all the other signatures in the union - time to see if we can make a single
                // signature that handles all over them. We only do this when there are overloads in only one constituent.
                // (Overloads are conditional in nature and having overloads in multiple constituents would necessitate making a power set of
                // signatures from the type, whose ordering would be non-obvious)
                const masterList = signatureLists
                    [indexWithLengthOverOne !== undefined
                        ? indexWithLengthOverOne
                        : 0];
                let results: Signature[] | undefined = masterList.slice();
                for (const signatures of signatureLists) {
                    if (signatures !== masterList) {
                        const signature = signatures[0];
                        Debug.assert(
                            !!signature,
                            'getUnionSignatures bails early on empty signature lists and should not have empty lists on second pass'
                        );
                        results = signature.typeParameters
                            && some(results, s => !!s.typeParameters)
                            ? undefined
                            : map(
                                results,
                                sig => combineSignaturesOfUnionMembers(
                                    sig,
                                    signature
                                )
                            );
                        if (!results) {
                            break;
                        }
                    }
                }
                result = results;
            }
            return result || emptyArray;
        }

        function combineUnionThisParam(
            left: Symbol | undefined,
            right: Symbol | undefined
        ): Symbol | undefined {
            if (!left || !right) {
                return left || right;
            }
            // A signature `this` type might be a read or a write position... It's very possible that it should be invariant
            // and we should refuse to merge signatures if there are `this` types and they do not match. However, so as to be
            // permissive when calling, for now, we'll intersect the `this` types just like we do for param types in union signatures.
            const thisType = getIntersectionType(
                [getTypeOfSymbol(left), getTypeOfSymbol(right)]
            );
            return createSymbolWithType(left, thisType);
        }

        function combineUnionParameters(left: Signature, right: Signature) {
            const leftCount = getParameterCount(left);
            const rightCount = getParameterCount(right);
            const longest = leftCount >= rightCount ? left : right;
            const shorter = longest === left ? right : left;
            const longestCount = longest === left ? leftCount : rightCount;
            const eitherHasEffectiveRest = (hasEffectiveRestParameter(left)
                || hasEffectiveRestParameter(right));
            const needsExtraRestElement = eitherHasEffectiveRest
                && !hasEffectiveRestParameter(longest);
            const params = new Array<Symbol>(
                longestCount + (needsExtraRestElement ? 1 : 0)
            );
            for (let i = 0; i < longestCount; i++) {
                const longestParamType = tryGetTypeAtPosition(longest, i)!;
                const shorterParamType = tryGetTypeAtPosition(shorter, i)
                    || unknownType;
                const unionParamType = getIntersectionType(
                    [longestParamType, shorterParamType]
                );
                const isRestParam = eitherHasEffectiveRest
                    && !needsExtraRestElement && i === (longestCount - 1);
                const isOptional = i >= getMinArgumentCount(longest)
                    && i >= getMinArgumentCount(shorter);
                const leftName = i >= leftCount
                    ? undefined
                    : getParameterNameAtPosition(left, i);
                const rightName = i >= rightCount
                    ? undefined
                    : getParameterNameAtPosition(right, i);

                const paramName = leftName === rightName
                    ? leftName
                    : !leftName
                        ? rightName
                        : !rightName
                            ? leftName
                            : undefined;
                const paramSymbol = createSymbol(
                    SymbolFlags.FunctionScopedVariable
                        | (isOptional && !isRestParam
                            ? SymbolFlags.Optional
                            : 0),
                    paramName || `arg${i}` as __String
                );
                paramSymbol.type = isRestParam
                    ? createArrayType(unionParamType)
                    : unionParamType;
                params[i] = paramSymbol;
            }
            if (needsExtraRestElement) {
                const restParamSymbol = createSymbol(
                    SymbolFlags.FunctionScopedVariable,
                    'args' as __String
                );
                restParamSymbol
                    .type = createArrayType(
                        getTypeAtPosition(
                            shorter,
                            longestCount
                        )
                    );
                params[longestCount] = restParamSymbol;
            }
            return params;
        }

        function combineSignaturesOfUnionMembers(
            left: Signature,
            right: Signature
        ): Signature {
            const declaration = left.declaration;
            const params = combineUnionParameters(left, right);
            const thisParam = combineUnionThisParam(
                left.thisParameter,
                right.thisParameter
            );
            const minArgCount = Math.max(
                left.minArgumentCount,
                right.minArgumentCount
            );
            const result = createSignature(
                declaration,
                left.typeParameters || right.typeParameters,
                thisParam,
                params,
                /*resolvedReturnType*/ undefined,
                /*resolvedTypePredicate*/ undefined,
                minArgCount,
                (left.flags | right.flags) & SignatureFlags.PropagatingFlags
            );
            result
                .unionSignatures = concatenate(
                    left.unionSignatures || [left],
                    [right]
                );
            return result;
        }

        function getUnionIndexInfo(
            types: readonly Type[],
            kind: IndexKind
        ): IndexInfo | undefined {
            const indexTypes: Type[] = [];
            let isAnyReadonly = false;
            for (const type of types) {
                const indexInfo = getIndexInfoOfType(type, kind);
                if (!indexInfo) {
                    return undefined;
                }
                indexTypes.push(indexInfo.type);
                isAnyReadonly = isAnyReadonly || indexInfo.isReadonly;
            }
            return createIndexInfo(
                getUnionType(
                    indexTypes,
                    UnionReduction.Subtype
                ),
                isAnyReadonly
            );
        }

        function resolveUnionTypeMembers(type: UnionType) {
            // The members and properties collections are empty for union types. To get all properties of a union
            // type use getPropertiesOfType (only the language service uses this).
            const callSignatures = getUnionSignatures(
                map(
                    type.types,
                    t => t === globalFunctionType
                        ? [unknownSignature]
                        : getSignaturesOfType(t, SignatureKind.Call)
                )
            );
            const constructSignatures = getUnionSignatures(
                map(
                    type.types,
                    t => getSignaturesOfType(t, SignatureKind.Construct)
                )
            );
            const stringIndexInfo = getUnionIndexInfo(
                type.types,
                IndexKind.String
            );
            const numberIndexInfo = getUnionIndexInfo(
                type.types,
                IndexKind.Number
            );
            setStructuredTypeMembers(
                type,
                emptySymbols,
                callSignatures,
                constructSignatures,
                stringIndexInfo,
                numberIndexInfo
            );
        }

        function intersectTypes(type1: Type, type2: Type): Type;
        function intersectTypes(
            type1: Type | undefined,
            type2: Type | undefined
        ): Type | undefined;
        function intersectTypes(
            type1: Type | undefined,
            type2: Type | undefined
        ): Type | undefined {
            return !type1
                ? type2
                : !type2 ? type1 : getIntersectionType([type1, type2]);
        }

        function intersectIndexInfos(
            info1: IndexInfo | undefined,
            info2: IndexInfo | undefined
        ): IndexInfo | undefined {
            return !info1 ? info2 : !info2 ? info1 : createIndexInfo(
                getIntersectionType([info1.type, info2.type]),
                info1.isReadonly && info2.isReadonly
            );
        }

        function unionSpreadIndexInfos(
            info1: IndexInfo | undefined,
            info2: IndexInfo | undefined
        ): IndexInfo | undefined {
            return info1 && info2 && createIndexInfo(
                getUnionType([info1.type, info2.type]),
                info1.isReadonly || info2.isReadonly
            );
        }

        function findMixins(types: readonly Type[]): readonly boolean[] {
            const constructorTypeCount = countWhere(
                types,
                (t) => getSignaturesOfType(t, SignatureKind.Construct).length
                    > 0
            );
            const mixinFlags = map(types, isMixinConstructorType);
            if (constructorTypeCount > 0
                && constructorTypeCount === countWhere(mixinFlags, (b) => b))
            {
                const firstMixinIndex = mixinFlags
                    .indexOf(/*searchElement*/ true);
                mixinFlags[firstMixinIndex] = false;
            }
            return mixinFlags;
        }

        function includeMixinType(
            type: Type,
            types: readonly Type[],
            mixinFlags: readonly boolean[],
            index: number
        ): Type {
            const mixedTypes: Type[] = [];
            for (let i = 0; i < types.length; i++) {
                if (i === index) {
                    mixedTypes.push(type);
                } else if (mixinFlags[i]) {
                    mixedTypes
                        .push(
                            getReturnTypeOfSignature(
                                getSignaturesOfType(
                                    types[i],
                                    SignatureKind.Construct
                                )[0]
                            )
                        );
                }
            }
            return getIntersectionType(mixedTypes);
        }

        function resolveIntersectionTypeMembers(type: IntersectionType) {
            // The members and properties collections are empty for intersection types. To get all properties of an
            // intersection type use getPropertiesOfType (only the language service uses this).
            let callSignatures: Signature[] | undefined;
            let constructSignatures: Signature[] | undefined;
            let stringIndexInfo: IndexInfo | undefined;
            let numberIndexInfo: IndexInfo | undefined;
            const types = type.types;
            const mixinFlags = findMixins(types);
            const mixinCount = countWhere(mixinFlags, (b) => b);
            for (let i = 0; i < types.length; i++) {
                const t = type.types[i];
                // When an intersection type contains mixin constructor types, the construct signatures from
                // those types are discarded and their return types are mixed into the return types of all
                // other construct signatures in the intersection type. For example, the intersection type
                // '{ new(...args: any[]) => A } & { new(s: string) => B }' has a single construct signature
                // 'new(s: string) => A & B'.
                if (!mixinFlags[i]) {
                    let signatures = getSignaturesOfType(
                        t,
                        SignatureKind.Construct
                    );
                    if (signatures.length && mixinCount > 0) {
                        signatures = map(
                            signatures,
                            s => {
                                const clone = cloneSignature(s);
                                clone.resolvedReturnType = includeMixinType(
                                    getReturnTypeOfSignature(s),
                                    types,
                                    mixinFlags,
                                    i
                                );
                                return clone;
                            }
                        );
                    }
                    constructSignatures = appendSignatures(
                        constructSignatures,
                        signatures
                    );
                }
                callSignatures = appendSignatures(
                    callSignatures,
                    getSignaturesOfType(t, SignatureKind.Call)
                );
                stringIndexInfo = intersectIndexInfos(
                    stringIndexInfo,
                    getIndexInfoOfType(t, IndexKind.String)
                );
                numberIndexInfo = intersectIndexInfos(
                    numberIndexInfo,
                    getIndexInfoOfType(t, IndexKind.Number)
                );
            }
            setStructuredTypeMembers(
                type,
                emptySymbols,
                callSignatures || emptyArray,
                constructSignatures || emptyArray,
                stringIndexInfo,
                numberIndexInfo
            );
        }

        function appendSignatures(
            signatures: Signature[] | undefined,
            newSignatures: readonly Signature[]
        ) {
            for (const sig of newSignatures) {
                if (!signatures
                    || every(
                        signatures,
                        s => !compareSignaturesIdentical(
                            s,
                            sig, /*partialMatch*/
                            false, /*ignoreThisTypes*/
                            false, /*ignoreReturnTypes*/
                            false,
                            compareTypesIdentical
                        )
                    ))
                {
                    signatures = append(signatures, sig);
                }
            }
            return signatures;
        }

        /**
         * Converts an AnonymousType to a ResolvedType.
         */
        function resolveAnonymousTypeMembers(type: AnonymousType) {
            const symbol = getMergedSymbol(type.symbol);
            if (type.target) {
                setStructuredTypeMembers(
                    type,
                    emptySymbols,
                    emptyArray,
                    emptyArray,
                    undefined,
                    undefined
                );
                const members = createInstantiatedSymbolTable(
                    getPropertiesOfObjectType(
                        type.target
                    ),
                    type.mapper!, /*mappingThisOnly*/
                    false
                );
                const callSignatures = instantiateSignatures(
                    getSignaturesOfType(
                        type.target,
                        SignatureKind.Call
                    ),
                    type.mapper!
                );
                const constructSignatures = instantiateSignatures(
                    getSignaturesOfType(
                        type.target,
                        SignatureKind.Construct
                    ),
                    type.mapper!
                );
                const stringIndexInfo = instantiateIndexInfo(
                    getIndexInfoOfType(
                        type.target,
                        IndexKind.String
                    ),
                    type.mapper!
                );
                const numberIndexInfo = instantiateIndexInfo(
                    getIndexInfoOfType(
                        type.target,
                        IndexKind.Number
                    ),
                    type.mapper!
                );
                setStructuredTypeMembers(
                    type,
                    members,
                    callSignatures,
                    constructSignatures,
                    stringIndexInfo,
                    numberIndexInfo
                );
            } else if (symbol.flags & SymbolFlags.TypeLiteral) {
                setStructuredTypeMembers(
                    type,
                    emptySymbols,
                    emptyArray,
                    emptyArray,
                    undefined,
                    undefined
                );
                const members = getMembersOfSymbol(symbol);
                const callSignatures = getSignaturesOfSymbol(
                    members.get(InternalSymbolName.Call)
                );
                const constructSignatures = getSignaturesOfSymbol(
                    members.get(InternalSymbolName.New)
                );
                const stringIndexInfo = getIndexInfoOfSymbol(
                    symbol,
                    IndexKind.String
                );
                const numberIndexInfo = getIndexInfoOfSymbol(
                    symbol,
                    IndexKind.Number
                );
                setStructuredTypeMembers(
                    type,
                    members,
                    callSignatures,
                    constructSignatures,
                    stringIndexInfo,
                    numberIndexInfo
                );
            } else {
                // Combinations of function, class, enum and module
                let members = emptySymbols;
                let stringIndexInfo: IndexInfo | undefined;
                if (symbol.exports) {
                    members = getExportsOfSymbol(symbol);
                    if (symbol === globalThisSymbol) {
                        const varsOnly = createMap<Symbol>() as SymbolTable;
                        members.forEach(p => {
                            if (!(p.flags & SymbolFlags.BlockScoped)) {
                                varsOnly.set(p.escapedName, p);
                            }
                        });
                        members = varsOnly;
                    }
                }
                setStructuredTypeMembers(
                    type,
                    members,
                    emptyArray,
                    emptyArray,
                    undefined,
                    undefined
                );
                if (symbol.flags & SymbolFlags.Class) {
                    const classType = getDeclaredTypeOfClassOrInterface(symbol);
                    const baseConstructorType = getBaseConstructorTypeOfClass(classType);
                    if (baseConstructorType.flags
                        & (TypeFlags.Object | TypeFlags.Intersection
                            | TypeFlags.TypeVariable))
                    {
                        members = createSymbolTable(getNamedMembers(members));
                        addInheritedMembers(
                            members,
                            getPropertiesOfType(baseConstructorType)
                        );
                    } else if (baseConstructorType === anyType) {
                        stringIndexInfo = createIndexInfo(
                            anyType, /*isReadonly*/
                            false
                        );
                    }
                }
                const numberIndexInfo = symbol.flags & SymbolFlags.Enum
                    && (getDeclaredTypeOfSymbol(symbol).flags & TypeFlags.Enum
                        || some(
                            type.properties,
                            prop => !!(getTypeOfSymbol(prop).flags
                                & TypeFlags.NumberLike)
                        ))
                    ? enumNumberIndexInfo
                    : undefined;
                setStructuredTypeMembers(
                    type,
                    members,
                    emptyArray,
                    emptyArray,
                    stringIndexInfo,
                    numberIndexInfo
                );
                // We resolve the members before computing the signatures because a signature may use
                // typeof with a qualified name expression that circularly references the type we are
                // in the process of resolving (see issue #6072). The temporarily empty signature list
                // will never be observed because a qualified name can't reference signatures.
                if (symbol.flags
                    & (SymbolFlags.Function | SymbolFlags.Method))
                {
                    type.callSignatures = getSignaturesOfSymbol(symbol);
                }
                // And likewise for construct signatures for classes
                if (symbol.flags & SymbolFlags.Class) {
                    const classType = getDeclaredTypeOfClassOrInterface(symbol);
                    let constructSignatures = symbol.members
                        ? getSignaturesOfSymbol(
                            symbol.members.get(InternalSymbolName.Constructor)
                        )
                        : emptyArray;
                    if (symbol.flags & SymbolFlags.Function) {
                        constructSignatures = addRange(
                            constructSignatures.slice(),
                            mapDefined(
                                type.callSignatures,
                                sig => isJSConstructor(sig.declaration)
                                    ? createSignature(
                                        sig.declaration,
                                        sig.typeParameters,
                                        sig.thisParameter,
                                        sig.parameters,
                                        classType, /*resolvedTypePredicate*/
                                        undefined,
                                        sig.minArgumentCount,
                                        sig.flags
                                            & SignatureFlags.PropagatingFlags
                                    )
                                    : undefined
                            )
                        );
                    }
                    if (!constructSignatures.length) {
                        constructSignatures = getDefaultConstructSignatures(classType);
                    }
                    type.constructSignatures = constructSignatures;
                }
            }
        }

        function resolveReverseMappedTypeMembers(type: ReverseMappedType) {
            const indexInfo = getIndexInfoOfType(type.source,
                IndexKind.String);
            const modifiers = getMappedTypeModifiers(type.mappedType);
            const readonlyMask = modifiers
                & MappedTypeModifiers.IncludeReadonly
                ? false
                : true;
            const optionalMask = modifiers
                & MappedTypeModifiers.IncludeOptional
                ? 0
                : SymbolFlags.Optional;
            const stringIndexInfo = indexInfo
                && createIndexInfo(
                    inferReverseMappedType(
                        indexInfo.type,
                        type.mappedType,
                        type.constraintType
                    ),
                    readonlyMask && indexInfo.isReadonly
                );
            const members = createSymbolTable();
            for (const prop of getPropertiesOfType(type.source)) {
                const checkFlags = CheckFlags.ReverseMapped
                    | (readonlyMask && isReadonlySymbol(prop)
                        ? CheckFlags.Readonly
                        : 0);
                const inferredProp = createSymbol(
                    SymbolFlags.Property | prop.flags & optionalMask,
                    prop.escapedName,
                    checkFlags
                ) as ReverseMappedSymbol;
                inferredProp.declarations = prop.declarations;
                inferredProp.nameType = prop.nameType;
                inferredProp.propertyType = getTypeOfSymbol(prop);
                inferredProp.mappedType = type.mappedType;
                inferredProp.constraintType = type.constraintType;
                members.set(prop.escapedName, inferredProp);
            }
            setStructuredTypeMembers(
                type,
                members,
                emptyArray,
                emptyArray,
                stringIndexInfo,
                undefined
            );
        }

        // Return the lower bound of the key type in a mapped type. Intuitively, the lower
        // bound includes those keys that are known to always be present, for example because
        // because of constraints on type parameters (e.g. 'keyof T' for a constrained T).
        function getLowerBoundOfKeyType(type: Type): Type {
            if (type.flags & (TypeFlags.Any | TypeFlags.Primitive)) {
                return type;
            }
            if (type.flags & TypeFlags.Index) {
                return getIndexType(getApparentType((<IndexType> type).type));
            }
            if (type.flags & TypeFlags.Conditional) {
                if ((<ConditionalType> type).root.isDistributive) {
                    const checkType = (<ConditionalType> type).checkType;
                    const constraint = getLowerBoundOfKeyType(checkType);
                    if (constraint !== checkType) {
                        const mapper = makeUnaryTypeMapper(
                            (<ConditionalType> type).root.checkType,
                            constraint
                        );
                        return getConditionalTypeInstantiation(
                            <ConditionalType> type,
                            combineTypeMappers(
                                mapper,
                                (<ConditionalType> type).mapper
                            )
                        );
                    }
                }
                return type;
            }
            if (type.flags & TypeFlags.Union) {
                return getUnionType(
                    sameMap(
                        (<UnionType> type).types,
                        getLowerBoundOfKeyType
                    )
                );
            }
            if (type.flags & TypeFlags.Intersection) {
                return getIntersectionType(
                    sameMap(
                        (<UnionType> type).types,
                        getLowerBoundOfKeyType
                    )
                );
            }
            return neverType;
        }

        /** Resolve the members of a mapped type { [P in K]: T } */
        function resolveMappedTypeMembers(type: MappedType) {
            const members: SymbolTable = createSymbolTable();
            let stringIndexInfo: IndexInfo | undefined;
            let numberIndexInfo: IndexInfo | undefined;
            // Resolve upfront such that recursive references see an empty object type.
            setStructuredTypeMembers(
                type,
                emptySymbols,
                emptyArray,
                emptyArray,
                undefined,
                undefined
            );
            // In { [P in K]: T }, we refer to P as the type parameter type, K as the constraint type,
            // and T as the template type.
            const typeParameter = getTypeParameterFromMappedType(type);
            const constraintType = getConstraintTypeFromMappedType(type);
            const templateType = getTemplateTypeFromMappedType(
                <MappedType> type.target || type
            );
            const modifiersType = getApparentType(getModifiersTypeFromMappedType(type)); // The 'T' in 'keyof T'
            const templateModifiers = getMappedTypeModifiers(type);
            const include = keyofStringsOnly
                ? TypeFlags.StringLiteral
                : TypeFlags.StringOrNumberLiteralOrUnique;
            if (isMappedTypeWithKeyofConstraintDeclaration(type)) {
                // We have a { [P in keyof T]: X }
                for (const prop of getPropertiesOfType(modifiersType)) {
                    addMemberForKeyType(
                        getLiteralTypeFromProperty(
                            prop,
                            include
                        )
                    );
                }
                if (modifiersType.flags & TypeFlags.Any
                    || getIndexInfoOfType(modifiersType, IndexKind.String))
                {
                    addMemberForKeyType(stringType);
                }
                if (!keyofStringsOnly
                    && getIndexInfoOfType(modifiersType, IndexKind.Number))
                {
                    addMemberForKeyType(numberType);
                }
            } else {
                forEachType(
                    getLowerBoundOfKeyType(constraintType),
                    addMemberForKeyType
                );
            }
            setStructuredTypeMembers(
                type,
                members,
                emptyArray,
                emptyArray,
                stringIndexInfo,
                numberIndexInfo
            );

            function addMemberForKeyType(t: Type) {
                // Create a mapper from T to the current iteration type constituent. Then, if the
                // mapped type is itself an instantiated type, combine the iteration mapper with the
                // instantiation mapper.
                const templateMapper = combineTypeMappers(
                    type.mapper,
                    createTypeMapper([typeParameter], [t])
                );
                const propType = instantiateType(templateType, templateMapper);
                // If the current iteration type constituent is a string literal type, create a property.
                // Otherwise, for type string create a string index signature.
                if (isTypeUsableAsPropertyName(t)) {
                    const propName = getPropertyNameFromType(t);
                    const modifiersProp = getPropertyOfType(
                        modifiersType,
                        propName
                    );
                    const isOptional = !!(templateModifiers
                        & MappedTypeModifiers.IncludeOptional
                        || !(templateModifiers
                            & MappedTypeModifiers.ExcludeOptional)
                        && modifiersProp
                        && modifiersProp.flags & SymbolFlags.Optional);
                    const isReadonly = !!(templateModifiers
                        & MappedTypeModifiers.IncludeReadonly
                        || !(templateModifiers
                            & MappedTypeModifiers.ExcludeReadonly)
                        && modifiersProp && isReadonlySymbol(modifiersProp));
                    const prop = createSymbol(
                        SymbolFlags.Property
                            | (isOptional ? SymbolFlags.Optional : 0),
                        propName,
                        isReadonly ? CheckFlags.Readonly : 0
                    );
                    // When creating an optional property in strictNullChecks mode, if 'undefined' isn't assignable to the
                    // type, we include 'undefined' in the type. Similarly, when creating a non-optional property in strictNullChecks
                    // mode, if the underlying property is optional we remove 'undefined' from the type.
                    prop
                        .type = strictNullChecks && isOptional
                            && !isTypeAssignableTo(undefinedType, propType)
                            ? getOptionalType(propType)
                            : strictNullChecks && !isOptional && modifiersProp
                                && modifiersProp.flags & SymbolFlags.Optional
                                ? getTypeWithFacts(
                                    propType,
                                    TypeFacts.NEUndefined
                                )
                                : propType;
                    if (modifiersProp) {
                        prop.syntheticOrigin = modifiersProp;
                        prop.declarations = modifiersProp.declarations;
                    }
                    prop.nameType = t;
                    members.set(propName, prop);
                } else if (t.flags & (TypeFlags.Any | TypeFlags.String)) {
                    stringIndexInfo = createIndexInfo(
                        propType,
                        !!(templateModifiers
                            & MappedTypeModifiers.IncludeReadonly)
                    );
                } else if (t.flags & (TypeFlags.Number | TypeFlags.Enum)) {
                    numberIndexInfo = createIndexInfo(
                        numberIndexInfo
                            ? getUnionType([numberIndexInfo.type, propType])
                            : propType,
                        !!(templateModifiers
                            & MappedTypeModifiers.IncludeReadonly)
                    );
                }
            }
        }

        function getTypeParameterFromMappedType(type: MappedType) {
            return type.typeParameter
                || (type
                    .typeParameter = getDeclaredTypeOfTypeParameter(
                        getSymbolOfNode(
                            type.declaration.typeParameter
                        )
                    ));
        }

        function getConstraintTypeFromMappedType(type: MappedType) {
            return type.constraintType
                || (type
                    .constraintType = getConstraintOfTypeParameter(getTypeParameterFromMappedType(type))
                        || errorType);
        }

        function getTemplateTypeFromMappedType(type: MappedType) {
            return type.templateType
                || (type.templateType = type.declaration.type
                    ? instantiateType(
                        addOptionality(
                            getTypeFromTypeNode(
                                type.declaration.type
                            ),
                            !!(getMappedTypeModifiers(type)
                                & MappedTypeModifiers.IncludeOptional)
                        ),
                        type.mapper || identityMapper
                    )
                    : errorType);
        }

        function getConstraintDeclarationForMappedType(type: MappedType) {
            return getEffectiveConstraintOfTypeParameter(
                type.declaration.typeParameter
            );
        }

        function isMappedTypeWithKeyofConstraintDeclaration(type: MappedType) {
            const constraintDeclaration = getConstraintDeclarationForMappedType(type)!; // TODO: GH#18217
            return constraintDeclaration.kind === SyntaxKind.TypeOperator
                && (<TypeOperatorNode> constraintDeclaration).operator
                === SyntaxKind.KeyOfKeyword;
        }

        function getModifiersTypeFromMappedType(type: MappedType) {
            if (!type.modifiersType) {
                if (isMappedTypeWithKeyofConstraintDeclaration(type)) {
                    // If the constraint declaration is a 'keyof T' node, the modifiers type is T. We check
                    // AST nodes here because, when T is a non-generic type, the logic below eagerly resolves
                    // 'keyof T' to a literal union type and we can't recover T from that type.
                    type
                        .modifiersType = instantiateType(
                            getTypeFromTypeNode(
                                (<TypeOperatorNode> getConstraintDeclarationForMappedType(type))
                                    .type
                            ),
                            type.mapper || identityMapper
                        );
                } else {
                    // Otherwise, get the declared constraint type, and if the constraint type is a type parameter,
                    // get the constraint of that type parameter. If the resulting type is an indexed type 'keyof T',
                    // the modifiers type is T. Otherwise, the modifiers type is unknown.
                    const declaredType = <MappedType> getTypeFromMappedTypeNode(
                        type.declaration
                    );
                    const constraint = getConstraintTypeFromMappedType(declaredType);
                    const extendedConstraint = constraint
                        && constraint.flags & TypeFlags.TypeParameter
                        ? getConstraintOfTypeParameter(<TypeParameter> constraint)
                        : constraint;
                    type
                        .modifiersType = extendedConstraint
                            && extendedConstraint.flags & TypeFlags.Index
                            ? instantiateType(
                                (<IndexType> extendedConstraint).type,
                                type.mapper || identityMapper
                            )
                            : unknownType;
                }
            }
            return type.modifiersType;
        }

        function getMappedTypeModifiers(type:
            MappedType): MappedTypeModifiers
        {
            const declaration = type.declaration;
            return (declaration.readonlyToken
                ? declaration.readonlyToken.kind === SyntaxKind.MinusToken
                    ? MappedTypeModifiers.ExcludeReadonly
                    : MappedTypeModifiers.IncludeReadonly
                : 0)
                | (declaration.questionToken
                    ? declaration.questionToken.kind === SyntaxKind.MinusToken
                        ? MappedTypeModifiers.ExcludeOptional
                        : MappedTypeModifiers.IncludeOptional
                    : 0);
        }

        function getMappedTypeOptionality(type: MappedType): number {
            const modifiers = getMappedTypeModifiers(type);
            return modifiers & MappedTypeModifiers.ExcludeOptional
                ? -1
                : modifiers & MappedTypeModifiers.IncludeOptional ? 1 : 0;
        }

        function getCombinedMappedTypeOptionality(type: MappedType): number {
            const optionality = getMappedTypeOptionality(type);
            const modifiersType = getModifiersTypeFromMappedType(type);
            return optionality
                || (isGenericMappedType(modifiersType)
                    ? getMappedTypeOptionality(modifiersType)
                    : 0);
        }

        function isPartialMappedType(type: Type) {
            return !!(getObjectFlags(type) & ObjectFlags.Mapped
                && getMappedTypeModifiers(<MappedType> type)
                & MappedTypeModifiers.IncludeOptional);
        }

        function isGenericMappedType(type: Type): type is MappedType {
            return !!(getObjectFlags(type) & ObjectFlags.Mapped)
                && isGenericIndexType(getConstraintTypeFromMappedType(<MappedType> type));
        }

        function resolveStructuredTypeMembers(
            type: StructuredType
        ): ResolvedType {
            if (!(<ResolvedType> type).members) {
                if (type.flags & TypeFlags.Object) {
                    if ((<ObjectType> type).objectFlags
                        & ObjectFlags.Reference)
                    {
                        resolveTypeReferenceMembers(<TypeReference> type);
                    } else if ((<ObjectType> type).objectFlags
                        & ObjectFlags.ClassOrInterface)
                    {
                        resolveClassOrInterfaceMembers(<InterfaceType> type);
                    } else if ((<ReverseMappedType> type).objectFlags
                        & ObjectFlags.ReverseMapped)
                    {
                        resolveReverseMappedTypeMembers(type as ReverseMappedType);
                    } else if ((<ObjectType> type).objectFlags
                        & ObjectFlags.Anonymous)
                    {
                        resolveAnonymousTypeMembers(<AnonymousType> type);
                    } else if ((<MappedType> type).objectFlags
                        & ObjectFlags.Mapped)
                    {
                        resolveMappedTypeMembers(<MappedType> type);
                    }
                } else if (type.flags & TypeFlags.Union) {
                    resolveUnionTypeMembers(<UnionType> type);
                } else if (type.flags & TypeFlags.Intersection) {
                    resolveIntersectionTypeMembers(<IntersectionType> type);
                }
            }
            return <ResolvedType> type;
        }

        /** Return properties of an object type or an empty array for other types */
        function getPropertiesOfObjectType(type: Type): Symbol[] {
            if (type.flags & TypeFlags.Object) {
                return resolveStructuredTypeMembers(<ObjectType> type)
                    .properties;
            }
            return emptyArray;
        }

        /** If the given type is an object type and that type has a property by the given name,
         * return the symbol for that property. Otherwise return undefined.
         */
        function getPropertyOfObjectType(
            type: Type,
            name: __String
        ): Symbol | undefined {
            if (type.flags & TypeFlags.Object) {
                const resolved = resolveStructuredTypeMembers(<ObjectType> type);
                const symbol = resolved.members.get(name);
                if (symbol && symbolIsValue(symbol)) {
                    return symbol;
                }
            }
        }

        function getPropertiesOfUnionOrIntersectionType(
            type: UnionOrIntersectionType
        ): Symbol[] {
            if (!type.resolvedProperties) {
                const members = createSymbolTable();
                for (const current of type.types) {
                    for (const prop of getPropertiesOfType(current)) {
                        if (!members.has(prop.escapedName)) {
                            const combinedProp = getPropertyOfUnionOrIntersectionType(
                                type,
                                prop.escapedName
                            );
                            if (combinedProp) {
                                members.set(prop.escapedName, combinedProp);
                            }
                        }
                    }
                    // The properties of a union type are those that are present in all constituent types, so
                    // we only need to check the properties of the first type
                    if (type.flags & TypeFlags.Union) {
                        break;
                    }
                }
                type.resolvedProperties = getNamedMembers(members);
            }
            return type.resolvedProperties;
        }

        function getPropertiesOfType(type: Type): Symbol[] {
            type = getApparentType(type);
            return type.flags & TypeFlags.UnionOrIntersection
                ? getPropertiesOfUnionOrIntersectionType(<UnionType> type)
                : getPropertiesOfObjectType(type);
        }

        function isTypeInvalidDueToUnionDiscriminant(
            contextualType: Type,
            obj: ObjectLiteralExpression | JsxAttributes
        ): boolean {
            const list = obj
                .properties as NodeArray<ObjectLiteralElementLike
                    | JsxAttributeLike>;
            return list.some(property => {
                const nameType = property.name
                    && getLiteralTypeFromPropertyName(property.name);
                const name = nameType && isTypeUsableAsPropertyName(nameType)
                    ? getPropertyNameFromType(nameType)
                    : undefined;
                const expected = name === undefined
                    ? undefined
                    : getTypeOfPropertyOfType(contextualType, name);
                return !!expected && isLiteralType(expected)
                    && !isTypeAssignableTo(getTypeOfNode(property), expected);
            });
        }

        function getAllPossiblePropertiesOfTypes(
            types: readonly Type[]
        ): Symbol[] {
            const unionType = getUnionType(types);
            if (!(unionType.flags & TypeFlags.Union)) {
                return getAugmentedPropertiesOfType(unionType);
            }

            const props = createSymbolTable();
            for (const memberType of types) {
                for (const { escapedName }
                    of getAugmentedPropertiesOfType(memberType))
                {
                    if (!props.has(escapedName)) {
                        const prop = createUnionOrIntersectionProperty(
                            unionType as UnionType,
                            escapedName
                        );
                        // May be undefined if the property is private
                        if (prop) props.set(escapedName, prop);
                    }
                }
            }
            return arrayFrom(props.values());
        }

        function getConstraintOfType(
            type: InstantiableType | UnionOrIntersectionType
        ): Type | undefined {
            return type.flags & TypeFlags.TypeParameter
                ? getConstraintOfTypeParameter(<TypeParameter> type)
                : type.flags & TypeFlags.IndexedAccess
                    ? getConstraintOfIndexedAccess(<IndexedAccessType> type)
                    : type.flags & TypeFlags.Conditional
                        ? getConstraintOfConditionalType(<ConditionalType> type)
                        : getBaseConstraintOfType(type);
        }

        function getConstraintOfTypeParameter(
            typeParameter: TypeParameter
        ): Type | undefined {
            return hasNonCircularBaseConstraint(typeParameter)
                ? getConstraintFromTypeParameter(typeParameter)
                : undefined;
        }

        function getConstraintOfIndexedAccess(type: IndexedAccessType) {
            return hasNonCircularBaseConstraint(type)
                ? getConstraintFromIndexedAccess(type)
                : undefined;
        }

        function getSimplifiedTypeOrConstraint(type: Type) {
            const simplified = getSimplifiedType(type, /*writing*/ false);
            return simplified !== type
                ? simplified
                : getConstraintOfType(type);
        }

        function getConstraintFromIndexedAccess(type: IndexedAccessType) {
            const indexConstraint = getSimplifiedTypeOrConstraint(
                type.indexType
            );
            if (indexConstraint && indexConstraint !== type.indexType) {
                const indexedAccess = getIndexedAccessTypeOrUndefined(
                    type.objectType,
                    indexConstraint
                );
                if (indexedAccess) {
                    return indexedAccess;
                }
            }
            const objectConstraint = getSimplifiedTypeOrConstraint(
                type.objectType
            );
            if (objectConstraint && objectConstraint !== type.objectType) {
                return getIndexedAccessTypeOrUndefined(
                    objectConstraint,
                    type.indexType
                );
            }
            return undefined;
        }

        function getDefaultConstraintOfConditionalType(type: ConditionalType) {
            if (!type.resolvedDefaultConstraint) {
                // An `any` branch of a conditional type would normally be viral - specifically, without special handling here,
                // a conditional type with a single branch of type `any` would be assignable to anything, since it's constraint would simplify to
                // just `any`. This result is _usually_ unwanted - so instead here we elide an `any` branch from the constraint type,
                // in effect treating `any` like `never` rather than `unknown` in this location.
                const trueConstraint = getInferredTrueTypeFromConditionalType(type);
                const falseConstraint = getFalseTypeFromConditionalType(type);
                type.resolvedDefaultConstraint = isTypeAny(trueConstraint)
                    ? falseConstraint
                    : isTypeAny(falseConstraint)
                        ? trueConstraint
                        : getUnionType([trueConstraint, falseConstraint]);
            }
            return type.resolvedDefaultConstraint;
        }

        function getConstraintOfDistributiveConditionalType(
            type: ConditionalType
        ): Type | undefined {
            // Check if we have a conditional type of the form 'T extends U ? X : Y', where T is a constrained
            // type parameter. If so, create an instantiation of the conditional type where T is replaced
            // with its constraint. We do this because if the constraint is a union type it will be distributed
            // over the conditional type and possibly reduced. For example, 'T extends undefined ? never : T'
            // removes 'undefined' from T.
            // We skip returning a distributive constraint for a restrictive instantiation of a conditional type
            // as the constraint for all type params (check type included) have been replace with `unknown`, which
            // is going to produce even more false positive/negative results than the distribute constraint already does.
            // Please note: the distributive constraint is a kludge for emulating what a negated type could to do filter
            // a union - once negated types exist and are applied to the conditional false branch, this "constraint"
            // likely doesn't need to exist.
            if (type.root.isDistributive
                && type.restrictiveInstantiation !== type)
            {
                const simplified = getSimplifiedType(
                    type.checkType, /*writing*/
                    false
                );
                const constraint = simplified === type.checkType
                    ? getConstraintOfType(simplified)
                    : simplified;
                if (constraint && constraint !== type.checkType) {
                    const mapper = makeUnaryTypeMapper(
                        type.root.checkType,
                        constraint
                    );
                    const instantiated = getConditionalTypeInstantiation(
                        type,
                        combineTypeMappers(mapper, type.mapper)
                    );
                    if (!(instantiated.flags & TypeFlags.Never)) {
                        return instantiated;
                    }
                }
            }
            return undefined;
        }

        function getConstraintFromConditionalType(type: ConditionalType) {
            return getConstraintOfDistributiveConditionalType(type)
                || getDefaultConstraintOfConditionalType(type);
        }

        function getConstraintOfConditionalType(type: ConditionalType) {
            return hasNonCircularBaseConstraint(type)
                ? getConstraintFromConditionalType(type)
                : undefined;
        }

        function getEffectiveConstraintOfIntersection(
            types: readonly Type[],
            targetIsUnion: boolean
        ) {
            let constraints: Type[] | undefined;
            let hasDisjointDomainType = false;
            for (const t of types) {
                if (t.flags & TypeFlags.Instantiable) {
                    // We keep following constraints as long as we have an instantiable type that is known
                    // not to be circular or infinite (hence we stop on index access types).
                    let constraint = getConstraintOfType(t);
                    while (constraint
                        && constraint.flags
                        & (TypeFlags.TypeParameter | TypeFlags.Index
                            | TypeFlags.Conditional))
                    {
                        constraint = getConstraintOfType(constraint);
                    }
                    if (constraint) {
                        constraints = append(constraints, constraint);
                        if (targetIsUnion) {
                            constraints = append(constraints, t);
                        }
                    }
                } else if (t.flags & TypeFlags.DisjointDomains) {
                    hasDisjointDomainType = true;
                }
            }
            // If the target is a union type or if we are intersecting with types belonging to one of the
            // disjoint domains, we may end up producing a constraint that hasn't been examined before.
            if (constraints && (targetIsUnion || hasDisjointDomainType)) {
                if (hasDisjointDomainType) {
                    // We add any types belong to one of the disjoint domains because they might cause the final
                    // intersection operation to reduce the union constraints.
                    for (const t of types) {
                        if (t.flags & TypeFlags.DisjointDomains) {
                            constraints = append(constraints, t);
                        }
                    }
                }
                return getIntersectionType(constraints);
            }
            return undefined;
        }

        function getBaseConstraintOfType(type: Type): Type | undefined {
            if (type.flags
                & (TypeFlags.InstantiableNonPrimitive
                    | TypeFlags.UnionOrIntersection))
            {
                const constraint = getResolvedBaseConstraint(
                    <InstantiableType | UnionOrIntersectionType> type
                );
                return constraint !== noConstraintType
                    && constraint !== circularConstraintType
                    ? constraint
                    : undefined;
            }
            return type.flags & TypeFlags.Index
                ? keyofConstraintType
                : undefined;
        }

        /**
         * This is similar to `getBaseConstraintOfType` except it returns the input type if there's no base constraint, instead of `undefined`
         * It also doesn't map indexes to `string`, as where this is used this would be unneeded (and likely undesirable)
         */
        function getBaseConstraintOrType(type: Type) {
            return getBaseConstraintOfType(type) || type;
        }

        function hasNonCircularBaseConstraint(type:
            InstantiableType): boolean
        {
            return getResolvedBaseConstraint(type) !== circularConstraintType;
        }

        /**
         * Return the resolved base constraint of a type variable. The noConstraintType singleton is returned if the
         * type variable has no constraint, and the circularConstraintType singleton is returned if the constraint
         * circularly references the type variable.
         */
        function getResolvedBaseConstraint(
            type: InstantiableType | UnionOrIntersectionType
        ): Type {
            let nonTerminating = false;
            return type.resolvedBaseConstraint
                || (type
                    .resolvedBaseConstraint = getTypeWithThisArgument(
                        getImmediateBaseConstraint(type),
                        type
                    ));

            function getImmediateBaseConstraint(t: Type): Type {
                if (!t.immediateBaseConstraint) {
                    if (!pushTypeResolution(
                        t,
                        TypeSystemPropertyName.ImmediateBaseConstraint
                    )) {
                        return circularConstraintType;
                    }
                    if (constraintDepth >= 50) {
                        // We have reached 50 recursive invocations of getImmediateBaseConstraint and there is a
                        // very high likelihood we're dealing with an infinite generic type that perpetually generates
                        // new type identities as we descend into it. We stop the recursion here and mark this type
                        // and the outer types as having circular constraints.
                        error(
                            currentNode,
                            Diagnostics
                                .Type_instantiation_is_excessively_deep_and_possibly_infinite
                        );
                        nonTerminating = true;
                        return t.immediateBaseConstraint = noConstraintType;
                    }
                    constraintDepth++;
                    let result = computeBaseConstraint(
                        getSimplifiedType(
                            t, /*writing*/
                            false
                        )
                    );
                    constraintDepth--;
                    if (!popTypeResolution()) {
                        if (t.flags & TypeFlags.TypeParameter) {
                            const errorNode = getConstraintDeclaration(<TypeParameter> t);
                            if (errorNode) {
                                const diagnostic = error(
                                    errorNode,
                                    Diagnostics
                                        .Type_parameter_0_has_a_circular_constraint,
                                    typeToString(t)
                                );
                                if (currentNode
                                    && !isNodeDescendantOf(
                                        errorNode,
                                        currentNode
                                    )
                                    && !isNodeDescendantOf(
                                        currentNode,
                                        errorNode
                                    ))
                                {
                                    addRelatedInfo(
                                        diagnostic,
                                        createDiagnosticForNode(
                                            currentNode,
                                            Diagnostics
                                                .Circularity_originates_in_type_at_this_location
                                        )
                                    );
                                }
                            }
                        }
                        result = circularConstraintType;
                    }
                    if (nonTerminating) {
                        result = circularConstraintType;
                    }
                    t.immediateBaseConstraint = result || noConstraintType;
                }
                return t.immediateBaseConstraint;
            }

            function getBaseConstraint(t: Type): Type | undefined {
                const c = getImmediateBaseConstraint(t);
                return c !== noConstraintType && c !== circularConstraintType
                    ? c
                    : undefined;
            }

            function computeBaseConstraint(t: Type): Type | undefined {
                if (t.flags & TypeFlags.TypeParameter) {
                    const constraint = getConstraintFromTypeParameter(<TypeParameter> t);
                    return (t as TypeParameter).isThisType || !constraint
                        ? constraint
                        : getBaseConstraint(constraint);
                }
                if (t.flags & TypeFlags.UnionOrIntersection) {
                    const types = (<UnionOrIntersectionType> t).types;
                    const baseTypes: Type[] = [];
                    for (const type of types) {
                        const baseType = getBaseConstraint(type);
                        if (baseType) {
                            baseTypes.push(baseType);
                        }
                    }
                    return t.flags & TypeFlags.Union
                        && baseTypes.length === types.length
                        ? getUnionType(baseTypes)
                        : t.flags & TypeFlags.Intersection && baseTypes.length
                            ? getIntersectionType(baseTypes)
                            : undefined;
                }
                if (t.flags & TypeFlags.Index) {
                    return keyofConstraintType;
                }
                if (t.flags & TypeFlags.IndexedAccess) {
                    const baseObjectType = getBaseConstraint(
                        (<IndexedAccessType> t).objectType
                    );
                    const baseIndexType = getBaseConstraint(
                        (<IndexedAccessType> t).indexType
                    );
                    const baseIndexedAccess = baseObjectType && baseIndexType
                        && getIndexedAccessTypeOrUndefined(
                            baseObjectType,
                            baseIndexType
                        );
                    return baseIndexedAccess
                        && getBaseConstraint(baseIndexedAccess);
                }
                if (t.flags & TypeFlags.Conditional) {
                    const constraint = getConstraintFromConditionalType(<ConditionalType> t);
                    constraintDepth++; // Penalize repeating conditional types (this captures the recursion within getConstraintFromConditionalType and carries it forward)
                    const result = constraint && getBaseConstraint(constraint);
                    constraintDepth--;
                    return result;
                }
                if (t.flags & TypeFlags.Substitution) {
                    return getBaseConstraint((<SubstitutionType> t)
                        .substitute);
                }
                return t;
            }
        }

        function getApparentTypeOfIntersectionType(type: IntersectionType) {
            return type.resolvedApparentType
                || (type.resolvedApparentType = getTypeWithThisArgument(
                    type,
                    type, /*apparentType*/
                    true
                ));
        }

        function getResolvedTypeParameterDefault(
            typeParameter: TypeParameter
        ): Type | undefined {
            if (!typeParameter.default) {
                if (typeParameter.target) {
                    const targetDefault = getResolvedTypeParameterDefault(
                        typeParameter.target
                    );
                    typeParameter.default = targetDefault
                        ? instantiateType(targetDefault, typeParameter.mapper)
                        : noConstraintType;
                } else {
                    // To block recursion, set the initial value to the resolvingDefaultType.
                    typeParameter.default = resolvingDefaultType;
                    const defaultDeclaration = typeParameter.symbol
                        && forEach(
                            typeParameter.symbol.declarations,
                            decl => isTypeParameterDeclaration(decl)
                                && decl.default
                        );
                    const defaultType = defaultDeclaration
                        ? getTypeFromTypeNode(defaultDeclaration)
                        : noConstraintType;
                    if (typeParameter.default === resolvingDefaultType) {
                        // If we have not been called recursively, set the correct default type.
                        typeParameter.default = defaultType;
                    }
                }
            } else if (typeParameter.default === resolvingDefaultType) {
                // If we are called recursively for this type parameter, mark the default as circular.
                typeParameter.default = circularConstraintType;
            }
            return typeParameter.default;
        }

        /**
         * Gets the default type for a type parameter.
         *
         * If the type parameter is the result of an instantiation, this gets the instantiated
         * default type of its target. If the type parameter has no default type or the default is
         * circular, `undefined` is returned.
         */
        function getDefaultFromTypeParameter(
            typeParameter: TypeParameter
        ): Type | undefined {
            const defaultType = getResolvedTypeParameterDefault(typeParameter);
            return defaultType !== noConstraintType
                && defaultType !== circularConstraintType
                ? defaultType
                : undefined;
        }

        function hasNonCircularTypeParameterDefault(
            typeParameter: TypeParameter
        ) {
            return getResolvedTypeParameterDefault(typeParameter)
                !== circularConstraintType;
        }

        /**
         * Indicates whether the declaration of a typeParameter has a default type.
         */
        function hasTypeParameterDefault(typeParameter:
            TypeParameter): boolean
        {
            return !!(typeParameter.symbol
                && forEach(
                    typeParameter.symbol.declarations,
                    decl => isTypeParameterDeclaration(decl) && decl.default
                ));
        }

        function getApparentTypeOfMappedType(type: MappedType) {
            return type.resolvedApparentType
                || (type
                    .resolvedApparentType = getResolvedApparentTypeOfMappedType(type));
        }

        function getResolvedApparentTypeOfMappedType(type: MappedType) {
            const typeVariable = getHomomorphicTypeVariable(type);
            if (typeVariable) {
                const constraint = getConstraintOfTypeParameter(typeVariable);
                if (constraint
                    && (isArrayType(constraint) || isTupleType(constraint)))
                {
                    const mapper = makeUnaryTypeMapper(
                        typeVariable,
                        constraint
                    );
                    return instantiateType(
                        type,
                        combineTypeMappers(mapper, type.mapper)
                    );
                }
            }
            return type;
        }

        /**
         * For a type parameter, return the base constraint of the type parameter. For the string, number,
         * boolean, and symbol primitive types, return the corresponding object types. Otherwise return the
         * type itself. Note that the apparent type of a union type is the union type itself.
         */
        function getApparentType(type: Type): Type {
            const t = type.flags & TypeFlags.Instantiable
                ? getBaseConstraintOfType(type) || unknownType
                : type;
            return getObjectFlags(t) & ObjectFlags.Mapped
                ? getApparentTypeOfMappedType(<MappedType> t)
                : t.flags & TypeFlags.Intersection
                    ? getApparentTypeOfIntersectionType(<IntersectionType> t)
                    : t.flags & TypeFlags.StringLike
                        ? globalStringType
                        : t.flags & TypeFlags.NumberLike
                            ? globalNumberType
                            : t.flags & TypeFlags.BigIntLike
                                ? getGlobalBigIntType(
                                    /*reportErrors*/ languageVersion
                                        >= ScriptTarget.ESNext
                                )
                                : t.flags & TypeFlags.BooleanLike
                                    ? globalBooleanType
                                    : t.flags & TypeFlags.ESSymbolLike
                                        ? getGlobalESSymbolType(
                                            /*reportErrors*/ languageVersion
                                                >= ScriptTarget.ES2015
                                        )
                                        : t.flags & TypeFlags.NonPrimitive
                                            ? emptyObjectType
                                            : t.flags & TypeFlags.Index
                                                ? keyofConstraintType
                                                : t.flags & TypeFlags.Unknown
                                                    && !strictNullChecks
                                                    ? emptyObjectType
                                                    : t;
        }

        function createUnionOrIntersectionProperty(
            containingType: UnionOrIntersectionType,
            name: __String
        ): Symbol | undefined {
            const propSet = createMap<Symbol>();
            let indexTypes: Type[] | undefined;
            const isUnion = containingType.flags & TypeFlags.Union;
            const excludeModifiers = isUnion
                ? ModifierFlags.NonPublicAccessibilityModifier
                : 0;
            // Flags we want to propagate to the result if they exist in all source symbols
            let optionalFlag = isUnion
                ? SymbolFlags.None
                : SymbolFlags.Optional;
            let syntheticFlag = CheckFlags.SyntheticMethod;
            let checkFlags = 0;
            for (const current of containingType.types) {
                const type = getApparentType(current);
                if (type !== errorType) {
                    const prop = getPropertyOfType(type, name);
                    const modifiers = prop
                        ? getDeclarationModifierFlagsFromSymbol(prop)
                        : 0;
                    if (prop && !(modifiers & excludeModifiers)) {
                        if (isUnion) {
                            optionalFlag |= (prop.flags
                                & SymbolFlags.Optional);
                        } else {
                            optionalFlag &= prop.flags;
                        }
                        const id = '' + getSymbolId(prop);
                        if (!propSet.has(id)) {
                            propSet.set(id, prop);
                        }
                        checkFlags |= (isReadonlySymbol(prop)
                            ? CheckFlags.Readonly
                            : 0)
                            | (!(modifiers
                                & ModifierFlags.NonPublicAccessibilityModifier)
                                ? CheckFlags.ContainsPublic
                                : 0)
                            | (modifiers & ModifierFlags.Protected
                                ? CheckFlags.ContainsProtected
                                : 0)
                            | (modifiers & ModifierFlags.Private
                                ? CheckFlags.ContainsPrivate
                                : 0)
                            | (modifiers & ModifierFlags.Static
                                ? CheckFlags.ContainsStatic
                                : 0);
                        if (!isPrototypeProperty(prop)) {
                            syntheticFlag = CheckFlags.SyntheticProperty;
                        }
                    } else if (isUnion) {
                        const indexInfo = !isLateBoundName(name)
                            && (isNumericLiteralName(name)
                                && getIndexInfoOfType(type, IndexKind.Number)
                                || getIndexInfoOfType(type, IndexKind.String));
                        if (indexInfo) {
                            checkFlags |= CheckFlags.WritePartial
                                | (indexInfo.isReadonly
                                    ? CheckFlags.Readonly
                                    : 0);
                            indexTypes = append(
                                indexTypes,
                                isTupleType(type)
                                    ? getRestTypeOfTupleType(type)
                                        || undefinedType
                                    : indexInfo.type
                            );
                        } else if (isObjectLiteralType(type)) {
                            checkFlags |= CheckFlags.WritePartial;
                            indexTypes = append(indexTypes, undefinedType);
                        } else {
                            checkFlags |= CheckFlags.ReadPartial;
                        }
                    }
                }
            }
            if (!propSet.size) {
                return undefined;
            }
            const props = arrayFrom(propSet.values());
            if (props.length === 1 && !(checkFlags & CheckFlags.ReadPartial)
                && !indexTypes)
            {
                return props[0];
            }
            let declarations: Declaration[] | undefined;
            let firstType: Type | undefined;
            let nameType: Type | undefined;
            const propTypes: Type[] = [];
            let firstValueDeclaration: Declaration | undefined;
            let hasNonUniformValueDeclaration = false;
            for (const prop of props) {
                if (!firstValueDeclaration) {
                    firstValueDeclaration = prop.valueDeclaration;
                } else if (prop.valueDeclaration !== firstValueDeclaration) {
                    hasNonUniformValueDeclaration = true;
                }
                declarations = addRange(declarations, prop.declarations);
                const type = getTypeOfSymbol(prop);
                if (!firstType) {
                    firstType = type;
                    nameType = prop.nameType;
                } else if (type !== firstType) {
                    checkFlags |= CheckFlags.HasNonUniformType;
                }
                if (isLiteralType(type)) {
                    checkFlags |= CheckFlags.HasLiteralType;
                }
                propTypes.push(type);
            }
            addRange(propTypes, indexTypes);
            const result = createSymbol(
                SymbolFlags.Property | optionalFlag,
                name,
                syntheticFlag | checkFlags
            );
            result.containingType = containingType;
            if (!hasNonUniformValueDeclaration && firstValueDeclaration) {
                result.valueDeclaration = firstValueDeclaration;

                // Inherit information about parent type.
                if (firstValueDeclaration.symbol.parent) {
                    result.parent = firstValueDeclaration.symbol.parent;
                }
            }

            result.declarations = declarations!;
            result.nameType = nameType;
            if (propTypes.length > 2) {
                // When `propTypes` has the potential to explode in size when normalized, defer normalization until absolutely needed
                result.checkFlags |= CheckFlags.DeferredType;
                result.deferralParent = containingType;
                result.deferralConstituents = propTypes;
            } else {
                result.type = isUnion
                    ? getUnionType(propTypes)
                    : getIntersectionType(propTypes);
            }
            return result;
        }

        // Return the symbol for a given property in a union or intersection type, or undefined if the property
        // does not exist in any constituent type. Note that the returned property may only be present in some
        // constituents, in which case the isPartial flag is set when the containing type is union type. We need
        // these partial properties when identifying discriminant properties, but otherwise they are filtered out
        // and do not appear to be present in the union type.
        function getUnionOrIntersectionProperty(
            type: UnionOrIntersectionType,
            name: __String
        ): Symbol | undefined {
            const properties = type.propertyCache
                || (type.propertyCache = createSymbolTable());
            let property = properties.get(name);
            if (!property) {
                property = createUnionOrIntersectionProperty(type, name);
                if (property) {
                    properties.set(name, property);
                }
            }
            return property;
        }

        function getPropertyOfUnionOrIntersectionType(
            type: UnionOrIntersectionType,
            name: __String
        ): Symbol | undefined {
            const property = getUnionOrIntersectionProperty(type, name);
            // We need to filter out partial properties in union types
            return property
                && !(getCheckFlags(property) & CheckFlags.ReadPartial)
                ? property
                : undefined;
        }

        /**
         * Return the symbol for the property with the given name in the given type. Creates synthetic union properties when
         * necessary, maps primitive types and type parameters are to their apparent types, and augments with properties from
         * Object and Function as appropriate.
         *
         * @param type a type to look up property from
         * @param name a name of property to look up in a given type
         */
        function getPropertyOfType(
            type: Type,
            name: __String
        ): Symbol | undefined {
            type = getApparentType(type);
            if (type.flags & TypeFlags.Object) {
                const resolved = resolveStructuredTypeMembers(<ObjectType> type);
                const symbol = resolved.members.get(name);
                if (symbol && symbolIsValue(symbol)) {
                    return symbol;
                }
                const functionType = resolved === anyFunctionType
                    ? globalFunctionType
                    : resolved.callSignatures.length
                        ? globalCallableFunctionType
                        : resolved.constructSignatures.length
                            ? globalNewableFunctionType
                            : undefined;
                if (functionType) {
                    const symbol = getPropertyOfObjectType(functionType, name);
                    if (symbol) {
                        return symbol;
                    }
                }
                return getPropertyOfObjectType(globalObjectType, name);
            }
            if (type.flags & TypeFlags.UnionOrIntersection) {
                return getPropertyOfUnionOrIntersectionType(
                    <UnionOrIntersectionType> type,
                    name
                );
            }
            return undefined;
        }

        function getSignaturesOfStructuredType(
            type: Type,
            kind: SignatureKind
        ): readonly Signature[] {
            if (type.flags & TypeFlags.StructuredType) {
                const resolved = resolveStructuredTypeMembers(<ObjectType> type);
                return kind === SignatureKind.Call
                    ? resolved.callSignatures
                    : resolved.constructSignatures;
            }
            return emptyArray;
        }

        /**
         * Return the signatures of the given kind in the given type. Creates synthetic union signatures when necessary and
         * maps primitive types and type parameters are to their apparent types.
         */
        function getSignaturesOfType(
            type: Type,
            kind: SignatureKind
        ): readonly Signature[] {
            return getSignaturesOfStructuredType(getApparentType(type), kind);
        }

        function getIndexInfoOfStructuredType(
            type: Type,
            kind: IndexKind
        ): IndexInfo | undefined {
            if (type.flags & TypeFlags.StructuredType) {
                const resolved = resolveStructuredTypeMembers(<ObjectType> type);
                return kind === IndexKind.String
                    ? resolved.stringIndexInfo
                    : resolved.numberIndexInfo;
            }
        }

        function getIndexTypeOfStructuredType(
            type: Type,
            kind: IndexKind
        ): Type | undefined {
            const info = getIndexInfoOfStructuredType(type, kind);
            return info && info.type;
        }

        // Return the indexing info of the given kind in the given type. Creates synthetic union index types when necessary and
        // maps primitive types and type parameters are to their apparent types.
        function getIndexInfoOfType(
            type: Type,
            kind: IndexKind
        ): IndexInfo | undefined {
            return getIndexInfoOfStructuredType(getApparentType(type), kind);
        }

        // Return the index type of the given kind in the given type. Creates synthetic union index types when necessary and
        // maps primitive types and type parameters are to their apparent types.
        function getIndexTypeOfType(
            type: Type,
            kind: IndexKind
        ): Type | undefined {
            return getIndexTypeOfStructuredType(getApparentType(type), kind);
        }

        function getImplicitIndexTypeOfType(
            type: Type,
            kind: IndexKind
        ): Type | undefined {
            if (isObjectTypeWithInferableIndex(type)) {
                const propTypes: Type[] = [];
                for (const prop of getPropertiesOfType(type)) {
                    if (kind === IndexKind.String
                        || isNumericLiteralName(prop.escapedName))
                    {
                        propTypes.push(getTypeOfSymbol(prop));
                    }
                }
                if (kind === IndexKind.String) {
                    append(
                        propTypes,
                        getIndexTypeOfType(type, IndexKind.Number)
                    );
                }
                if (propTypes.length) {
                    return getUnionType(propTypes, UnionReduction.Subtype);
                }
            }
            return undefined;
        }

        // Return list of type parameters with duplicates removed (duplicate identifier errors are generated in the actual
        // type checking functions).
        function getTypeParametersFromDeclaration(
            declaration: DeclarationWithTypeParameters
        ): TypeParameter[] | undefined {
            let result: TypeParameter[] | undefined;
            for (const node
                of getEffectiveTypeParameterDeclarations(declaration))
            {
                result = appendIfUnique(
                    result,
                    getDeclaredTypeOfTypeParameter(node.symbol)
                );
            }
            return result;
        }

        function symbolsToArray(symbols: SymbolTable): Symbol[] {
            const result: Symbol[] = [];
            symbols.forEach((symbol, id) => {
                if (!isReservedMemberName(id)) {
                    result.push(symbol);
                }
            });
            return result;
        }

        function isJSDocOptionalParameter(node: ParameterDeclaration) {
            return isInJSFile(node) && (
                // node.type should only be a JSDocOptionalType when node is a parameter of a JSDocFunctionType
                node.type && node.type.kind === SyntaxKind.JSDocOptionalType
                || getJSDocParameterTags(node)
                    .some(({ isBracketed, typeExpression }) => isBracketed
                        || !!typeExpression
                        && typeExpression.type.kind
                        === SyntaxKind.JSDocOptionalType)
            );
        }

        function tryFindAmbientModule(
            moduleName: string,
            withAugmentations: boolean
        ) {
            if (isExternalModuleNameRelative(moduleName)) {
                return undefined;
            }
            const symbol = getSymbol(
                globals,
                '"' + moduleName + '"' as __String,
                SymbolFlags.ValueModule
            );
            // merged symbol is module declaration symbol combined with all augmentations
            return symbol && withAugmentations
                ? getMergedSymbol(symbol)
                : symbol;
        }

        function isOptionalParameter(
            node: ParameterDeclaration | JSDocParameterTag
        ) {
            if (hasQuestionToken(node) || isOptionalJSDocParameterTag(node)
                || isJSDocOptionalParameter(node))
            {
                return true;
            }

            if (node.initializer) {
                const signature = getSignatureFromDeclaration(node.parent);
                const parameterIndex = node.parent.parameters.indexOf(node);
                Debug.assert(parameterIndex >= 0);
                return parameterIndex >= getMinArgumentCount(signature);
            }
            const iife = getImmediatelyInvokedFunctionExpression(node.parent);
            if (iife) {
                return !node.type
                    && !node.dotDotDotToken
                    && node.parent.parameters.indexOf(node)
                    >= iife.arguments.length;
            }

            return false;
        }

        function isOptionalJSDocParameterTag(
            node: Node
        ): node is JSDocParameterTag {
            if (!isJSDocParameterTag(node)) {
                return false;
            }
            const { isBracketed, typeExpression } = node;
            return isBracketed || !!typeExpression
                && typeExpression.type.kind === SyntaxKind.JSDocOptionalType;
        }

        function createTypePredicate(
            kind: TypePredicateKind,
            parameterName: string | undefined,
            parameterIndex: number | undefined,
            type: Type | undefined
        ): TypePredicate {
            return { kind, parameterName, parameterIndex,
                type } as TypePredicate;
        }

        /**
         * Gets the minimum number of type arguments needed to satisfy all non-optional type
         * parameters.
         */
        function getMinTypeArgumentCount(
            typeParameters: readonly TypeParameter[] | undefined
        ): number {
            let minTypeArgumentCount = 0;
            if (typeParameters) {
                for (let i = 0; i < typeParameters.length; i++) {
                    if (!hasTypeParameterDefault(typeParameters[i])) {
                        minTypeArgumentCount = i + 1;
                    }
                }
            }
            return minTypeArgumentCount;
        }

        /**
         * Fill in default types for unsupplied type arguments. If `typeArguments` is undefined
         * when a default type is supplied, a new array will be created and returned.
         *
         * @param typeArguments The supplied type arguments.
         * @param typeParameters The requested type parameters.
         * @param minTypeArgumentCount The minimum number of required type arguments.
         */
        function fillMissingTypeArguments(
            typeArguments: readonly Type[],
            typeParameters: readonly TypeParameter[] | undefined,
            minTypeArgumentCount: number,
            isJavaScriptImplicitAny: boolean
        ): Type[];
        function fillMissingTypeArguments(
            typeArguments: readonly Type[] | undefined,
            typeParameters: readonly TypeParameter[] | undefined,
            minTypeArgumentCount: number,
            isJavaScriptImplicitAny: boolean
        ): Type[] | undefined;
        function fillMissingTypeArguments(
            typeArguments: readonly Type[] | undefined,
            typeParameters: readonly TypeParameter[] | undefined,
            minTypeArgumentCount: number,
            isJavaScriptImplicitAny: boolean
        ) {
            const numTypeParameters = length(typeParameters);
            if (!numTypeParameters) {
                return [];
            }
            const numTypeArguments = length(typeArguments);
            if (isJavaScriptImplicitAny
                || (numTypeArguments >= minTypeArgumentCount
                    && numTypeArguments <= numTypeParameters))
            {
                const result = typeArguments ? typeArguments.slice() : [];
                // Map invalid forward references in default types to the error type
                for (let i = numTypeArguments; i < numTypeParameters; i++) {
                    result[i] = errorType;
                }
                const baseDefaultType = getDefaultTypeArgumentType(isJavaScriptImplicitAny);
                for (let i = numTypeArguments; i < numTypeParameters; i++) {
                    let defaultType = getDefaultFromTypeParameter(
                        typeParameters![i]
                    );
                    if (isJavaScriptImplicitAny && defaultType
                        && (isTypeIdenticalTo(defaultType, unknownType)
                            || isTypeIdenticalTo(defaultType,
                                emptyObjectType)))
                    {
                        defaultType = anyType;
                    }
                    result[i] = defaultType
                        ? instantiateType(
                            defaultType,
                            createTypeMapper(typeParameters!, result)
                        )
                        : baseDefaultType;
                }
                result.length = typeParameters!.length;
                return result;
            }
            return typeArguments && typeArguments.slice();
        }

        function getSignatureFromDeclaration(
            declaration: SignatureDeclaration | JSDocSignature
        ): Signature {
            const links = getNodeLinks(declaration);
            if (!links.resolvedSignature) {
                const parameters: Symbol[] = [];
                let flags = SignatureFlags.None;
                let minArgumentCount = 0;
                let thisParameter: Symbol | undefined;
                let hasThisParameter = false;
                const iife = getImmediatelyInvokedFunctionExpression(declaration);
                const isJSConstructSignature = isJSDocConstructSignature(declaration);
                const isUntypedSignatureInJSFile = !iife
                    && isInJSFile(declaration)
                    && isValueSignatureDeclaration(declaration)
                    && !hasJSDocParameterTags(declaration)
                    && !getJSDocType(declaration);

                // If this is a JSDoc construct signature, then skip the first parameter in the
                // parameter list.  The first parameter represents the return type of the construct
                // signature.
                for (let i = isJSConstructSignature ? 1 : 0;
                    i < declaration.parameters.length; i++)
                {
                    const param = declaration.parameters[i];

                    let paramSymbol = param.symbol;
                    const type = isJSDocParameterTag(param)
                        ? (param.typeExpression && param.typeExpression.type)
                        : param.type;
                    // Include parameter symbol instead of property symbol in the signature
                    if (paramSymbol
                        && !!(paramSymbol.flags & SymbolFlags.Property)
                        && !isBindingPattern(param.name))
                    {
                        const resolvedSymbol = resolveName(
                            param,
                            paramSymbol.escapedName,
                            SymbolFlags.Value,
                            undefined,
                            undefined, /*isUse*/
                            false
                        );
                        paramSymbol = resolvedSymbol!;
                    }
                    if (i === 0
                        && paramSymbol.escapedName === InternalSymbolName.This)
                    {
                        hasThisParameter = true;
                        thisParameter = param.symbol;
                    } else {
                        parameters.push(paramSymbol);
                    }

                    if (type && type.kind === SyntaxKind.LiteralType) {
                        flags |= SignatureFlags.HasLiteralTypes;
                    }

                    // Record a new minimum argument count if this is not an optional parameter
                    const isOptionalParameter = isOptionalJSDocParameterTag(param)
                        || param.initializer || param.questionToken
                        || param.dotDotDotToken
                        || iife && parameters.length > iife.arguments.length
                        && !type
                        || isUntypedSignatureInJSFile
                        || isJSDocOptionalParameter(param);
                    if (!isOptionalParameter) {
                        minArgumentCount = parameters.length;
                    }
                }

                // If only one accessor includes a this-type annotation, the other behaves as if it had the same type annotation
                if ((declaration.kind === SyntaxKind.GetAccessor
                    || declaration.kind === SyntaxKind.SetAccessor)
                    && !hasNonBindableDynamicName(declaration)
                    && (!hasThisParameter || !thisParameter))
                {
                    const otherKind = declaration.kind
                        === SyntaxKind.GetAccessor
                        ? SyntaxKind.SetAccessor
                        : SyntaxKind.GetAccessor;
                    const other = getDeclarationOfKind<AccessorDeclaration>(
                        getSymbolOfNode(declaration),
                        otherKind
                    );
                    if (other) {
                        thisParameter = getAnnotatedAccessorThisParameter(other);
                    }
                }

                const classType = declaration.kind === SyntaxKind.Constructor
                    ? getDeclaredTypeOfClassOrInterface(
                        getMergedSymbol(
                            (<ClassDeclaration> declaration.parent).symbol
                        )
                    )
                    : undefined;
                const typeParameters = classType
                    ? classType.localTypeParameters
                    : getTypeParametersFromDeclaration(declaration);
                if (hasRestParameter(declaration) || isInJSFile(declaration)
                    && maybeAddJsSyntheticRestParameter(
                        declaration,
                        parameters
                    ))
                {
                    flags |= SignatureFlags.HasRestParameter;
                }
                links.resolvedSignature = createSignature(
                    declaration,
                    typeParameters,
                    thisParameter,
                    parameters,
                    /*resolvedReturnType*/ undefined, /*resolvedTypePredicate*/
                    undefined,
                    minArgumentCount,
                    flags
                );
            }
            return links.resolvedSignature;
        }

        /**
         * A JS function gets a synthetic rest parameter if it references `arguments` AND:
         * 1. It has no parameters but at least one `@param` with a type that starts with `...`
         * OR
         * 2. It has at least one parameter, and the last parameter has a matching `@param` with a type that starts with `...`
         */
        function maybeAddJsSyntheticRestParameter(
            declaration: SignatureDeclaration | JSDocSignature,
            parameters: Symbol[]
        ): boolean {
            if (isJSDocSignature(declaration)
                || !containsArgumentsReference(declaration))
            {
                return false;
            }
            const lastParam = lastOrUndefined(declaration.parameters);
            const lastParamTags = lastParam
                ? getJSDocParameterTags(lastParam)
                : getJSDocTags(declaration).filter(isJSDocParameterTag);
            const lastParamVariadicType = firstDefined(
                lastParamTags,
                p => p.typeExpression
                    && isJSDocVariadicType(p.typeExpression.type)
                    ? p.typeExpression.type
                    : undefined
            );

            const syntheticArgsSymbol = createSymbol(
                SymbolFlags.Variable,
                'args' as __String,
                CheckFlags.RestParameter
            );
            syntheticArgsSymbol.type = lastParamVariadicType
                ? createArrayType(
                    getTypeFromTypeNode(
                        lastParamVariadicType.type
                    )
                )
                : anyArrayType;
            if (lastParamVariadicType) {
                // Replace the last parameter with a rest parameter.
                parameters.pop();
            }
            parameters.push(syntheticArgsSymbol);
            return true;
        }

        function getSignatureOfTypeTag(
            node: SignatureDeclaration | JSDocSignature
        ) {
            const typeTag = isInJSFile(node)
                ? getJSDocTypeTag(node)
                : undefined;
            const signature = typeTag && typeTag.typeExpression
                && getSingleCallSignature(
                    getTypeFromTypeNode(
                        typeTag.typeExpression
                    )
                );
            return signature && getErasedSignature(signature);
        }

        function getReturnTypeOfTypeTag(
            node: SignatureDeclaration | JSDocSignature
        ) {
            const signature = getSignatureOfTypeTag(node);
            return signature && getReturnTypeOfSignature(signature);
        }

        function containsArgumentsReference(
            declaration: SignatureDeclaration
        ): boolean {
            const links = getNodeLinks(declaration);
            if (links.containsArgumentsReference === undefined) {
                if (links.flags & NodeCheckFlags.CaptureArguments) {
                    links.containsArgumentsReference = true;
                } else {
                    links
                        .containsArgumentsReference = traverse(
                            (declaration as FunctionLikeDeclaration).body!
                        );
                }
            }
            return links.containsArgumentsReference;

            function traverse(node: Node): boolean {
                if (!node) return false;
                switch (node.kind) {
                    case SyntaxKind.Identifier:
                        return (<Identifier> node).escapedText === 'arguments'
                            && isExpressionNode(node);
                    case SyntaxKind.PropertyDeclaration:
                    case SyntaxKind.MethodDeclaration:
                    case SyntaxKind.GetAccessor:
                    case SyntaxKind.SetAccessor:
                        return (<NamedDeclaration> node).name!.kind
                            === SyntaxKind.ComputedPropertyName
                            && traverse((<NamedDeclaration> node).name!);
                    default:
                        return !nodeStartsNewLexicalEnvironment(node)
                            && !isPartOfTypeNode(node)
                            && !!forEachChild(node, traverse);
                }
            }
        }

        function getSignaturesOfSymbol(symbol: Symbol
            | undefined): Signature[]
        {
            if (!symbol) return emptyArray;
            const result: Signature[] = [];
            for (let i = 0; i < symbol.declarations.length; i++) {
                const decl = symbol.declarations[i];
                if (!isFunctionLike(decl)) continue;
                // Don't include signature if node is the implementation of an overloaded function. A node is considered
                // an implementation node if it has a body and the previous node is of the same kind and immediately
                // precedes the implementation node (i.e. has the same parent and ends where the implementation starts).
                if (i > 0 && (decl as FunctionLikeDeclaration).body) {
                    const previous = symbol.declarations[i - 1];
                    if (decl.parent === previous.parent
                        && decl.kind === previous.kind
                        && decl.pos === previous.end)
                    {
                        continue;
                    }
                }
                result.push(getSignatureFromDeclaration(decl));
            }
            return result;
        }

        function resolveExternalModuleTypeByLiteral(name: StringLiteral) {
            const moduleSym = resolveExternalModuleName(name, name);
            if (moduleSym) {
                const resolvedModuleSymbol = resolveExternalModuleSymbol(moduleSym);
                if (resolvedModuleSymbol) {
                    return getTypeOfSymbol(resolvedModuleSymbol);
                }
            }

            return anyType;
        }

        function getThisTypeOfSignature(signature: Signature): Type
            | undefined
        {
            if (signature.thisParameter) {
                return getTypeOfSymbol(signature.thisParameter);
            }
        }

        function getTypePredicateOfSignature(
            signature: Signature
        ): TypePredicate | undefined {
            if (!signature.resolvedTypePredicate) {
                if (signature.target) {
                    const targetTypePredicate = getTypePredicateOfSignature(
                        signature.target
                    );
                    signature.resolvedTypePredicate = targetTypePredicate
                        ? instantiateTypePredicate(
                            targetTypePredicate,
                            signature.mapper!
                        )
                        : noTypePredicate;
                } else if (signature.unionSignatures) {
                    signature
                        .resolvedTypePredicate = getUnionTypePredicate(
                            signature.unionSignatures
                        ) || noTypePredicate;
                } else {
                    const type = signature.declaration
                        && getEffectiveReturnTypeNode(signature.declaration);
                    let jsdocPredicate: TypePredicate | undefined;
                    if (!type && isInJSFile(signature.declaration)) {
                        const jsdocSignature = getSignatureOfTypeTag(
                            signature.declaration!
                        );
                        if (jsdocSignature && signature !== jsdocSignature) {
                            jsdocPredicate = getTypePredicateOfSignature(jsdocSignature);
                        }
                    }
                    signature
                        .resolvedTypePredicate = type
                            && isTypePredicateNode(type)
                            ? createTypePredicateFromTypePredicateNode(
                                type,
                                signature
                            )
                            : jsdocPredicate || noTypePredicate;
                }
                Debug.assert(!!signature.resolvedTypePredicate);
            }
            return signature.resolvedTypePredicate === noTypePredicate
                ? undefined
                : signature.resolvedTypePredicate;
        }

        function createTypePredicateFromTypePredicateNode(
            node: TypePredicateNode,
            signature: Signature
        ): TypePredicate {
            const parameterName = node.parameterName;
            const type = node.type && getTypeFromTypeNode(node.type);
            return parameterName.kind === SyntaxKind.ThisType
                ? createTypePredicate(
                    node.assertsModifier
                        ? TypePredicateKind.AssertsThis
                        : TypePredicateKind.This, /*parameterName*/
                    undefined, /*parameterIndex*/
                    undefined,
                    type
                )
                : createTypePredicate(
                    node.assertsModifier
                        ? TypePredicateKind.AssertsIdentifier
                        : TypePredicateKind.Identifier,
                    parameterName.escapedText as string,
                    findIndex(
                        signature.parameters,
                        p => p.escapedName === parameterName.escapedText
                    ),
                    type
                );
        }

        function getReturnTypeOfSignature(signature: Signature): Type {
            if (!signature.resolvedReturnType) {
                if (!pushTypeResolution(
                    signature,
                    TypeSystemPropertyName.ResolvedReturnType
                )) {
                    return errorType;
                }
                let type = signature.target
                    ? instantiateType(
                        getReturnTypeOfSignature(
                            signature.target
                        ),
                        signature.mapper
                    )
                    : signature.unionSignatures
                        ? getUnionType(
                            map(
                                signature.unionSignatures,
                                getReturnTypeOfSignature
                            ),
                            UnionReduction.Subtype
                        )
                        : getReturnTypeFromAnnotation(signature.declaration!)
                            || (nodeIsMissing(
                                (<FunctionLikeDeclaration> signature
                                    .declaration).body
                            )
                                ? anyType
                                : getReturnTypeFromBody(
                                    <FunctionLikeDeclaration> signature
                                        .declaration
                                ));
                if (signature.flags & SignatureFlags.IsInnerCallChain) {
                    type = addOptionalTypeMarker(type);
                } else if (signature.flags & SignatureFlags.IsOuterCallChain) {
                    type = getOptionalType(type);
                }
                if (!popTypeResolution()) {
                    if (signature.declaration) {
                        const typeNode = getEffectiveReturnTypeNode(
                            signature.declaration
                        );
                        if (typeNode) {
                            error(
                                typeNode,
                                Diagnostics
                                    .Return_type_annotation_circularly_references_itself
                            );
                        } else if (noImplicitAny) {
                            const declaration = <Declaration> signature
                                .declaration;
                            const name = getNameOfDeclaration(declaration);
                            if (name) {
                                error(
                                    name,
                                    Diagnostics
                                        ._0_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_referenced_directly_or_indirectly_in_one_of_its_return_expressions,
                                    declarationNameToString(name)
                                );
                            } else {
                                error(
                                    declaration,
                                    Diagnostics
                                        .Function_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_referenced_directly_or_indirectly_in_one_of_its_return_expressions
                                );
                            }
                        }
                    }
                    type = anyType;
                }
                signature.resolvedReturnType = type;
            }
            return signature.resolvedReturnType;
        }

        function getReturnTypeFromAnnotation(
            declaration: SignatureDeclaration | JSDocSignature
        ) {
            if (declaration.kind === SyntaxKind.Constructor) {
                return getDeclaredTypeOfClassOrInterface(
                    getMergedSymbol(
                        (<ClassDeclaration> declaration.parent).symbol
                    )
                );
            }
            if (isJSDocConstructSignature(declaration)) {
                return getTypeFromTypeNode(
                    (declaration.parameters[0] as ParameterDeclaration).type!
                ); // TODO: GH#18217
            }
            const typeNode = getEffectiveReturnTypeNode(declaration);
            if (typeNode) {
                return getTypeFromTypeNode(typeNode);
            }
            if (declaration.kind === SyntaxKind.GetAccessor
                && !hasNonBindableDynamicName(declaration))
            {
                const jsDocType = isInJSFile(declaration)
                    && getTypeForDeclarationFromJSDocComment(declaration);
                if (jsDocType) {
                    return jsDocType;
                }
                const setter = getDeclarationOfKind<AccessorDeclaration>(
                    getSymbolOfNode(declaration),
                    SyntaxKind.SetAccessor
                );
                const setterType = getAnnotatedAccessorType(setter);
                if (setterType) {
                    return setterType;
                }
            }
            return getReturnTypeOfTypeTag(declaration);
        }

        function isResolvingReturnTypeOfSignature(signature: Signature) {
            return !signature.resolvedReturnType
                && findResolutionCycleStartIndex(
                    signature,
                    TypeSystemPropertyName.ResolvedReturnType
                ) >= 0;
        }

        function getRestTypeOfSignature(signature: Signature): Type {
            return tryGetRestTypeOfSignature(signature) || anyType;
        }

        function tryGetRestTypeOfSignature(
            signature: Signature
        ): Type | undefined {
            if (signatureHasRestParameter(signature)) {
                const sigRestType = getTypeOfSymbol(
                    signature.parameters[signature.parameters.length - 1]
                );
                const restType = isTupleType(sigRestType)
                    ? getRestTypeOfTupleType(sigRestType)
                    : sigRestType;
                return restType
                    && getIndexTypeOfType(restType, IndexKind.Number);
            }
            return undefined;
        }

        function getSignatureInstantiation(
            signature: Signature,
            typeArguments: Type[] | undefined,
            isJavascript: boolean,
            inferredTypeParameters?: readonly TypeParameter[]
        ): Signature {
            const instantiatedSignature = getSignatureInstantiationWithoutFillingInTypeArguments(
                signature,
                fillMissingTypeArguments(
                    typeArguments,
                    signature.typeParameters,
                    getMinTypeArgumentCount(signature.typeParameters),
                    isJavascript
                )
            );
            if (inferredTypeParameters) {
                const returnSignature = getSingleCallOrConstructSignature(getReturnTypeOfSignature(instantiatedSignature));
                if (returnSignature) {
                    const newReturnSignature = cloneSignature(returnSignature);
                    newReturnSignature.typeParameters = inferredTypeParameters;
                    const newInstantiatedSignature = cloneSignature(instantiatedSignature);
                    newInstantiatedSignature
                        .resolvedReturnType = getOrCreateTypeFromSignature(newReturnSignature);
                    return newInstantiatedSignature;
                }
            }
            return instantiatedSignature;
        }

        function getSignatureInstantiationWithoutFillingInTypeArguments(
            signature: Signature,
            typeArguments: readonly Type[] | undefined
        ): Signature {
            const instantiations = signature.instantiations
                || (signature.instantiations = createMap<Signature>());
            const id = getTypeListId(typeArguments);
            let instantiation = instantiations.get(id);
            if (!instantiation) {
                instantiations.set(
                    id,
                    instantiation = createSignatureInstantiation(
                        signature,
                        typeArguments
                    )
                );
            }
            return instantiation;
        }

        function createSignatureInstantiation(
            signature: Signature,
            typeArguments: readonly Type[] | undefined
        ): Signature {
            return instantiateSignature(
                signature,
                createSignatureTypeMapper(signature,
                    typeArguments), /*eraseTypeParameters*/
                true
            );
        }

        function createSignatureTypeMapper(
            signature: Signature,
            typeArguments: readonly Type[] | undefined
        ): TypeMapper {
            return createTypeMapper(signature.typeParameters!, typeArguments);
        }

        function getErasedSignature(signature: Signature): Signature {
            return signature.typeParameters
                ? signature.erasedSignatureCache
                    || (signature.erasedSignatureCache = createErasedSignature(
                        signature
                    ))
                : signature;
        }

        function createErasedSignature(signature: Signature) {
            // Create an instantiation of the signature where all type arguments are the any type.
            return instantiateSignature(
                signature,
                createTypeEraser(signature
                    .typeParameters!), /*eraseTypeParameters*/
                true
            );
        }

        function getCanonicalSignature(signature: Signature): Signature {
            return signature.typeParameters
                ? signature.canonicalSignatureCache
                    || (signature
                        .canonicalSignatureCache = createCanonicalSignature(signature))
                : signature;
        }

        function createCanonicalSignature(signature: Signature) {
            // Create an instantiation of the signature where each unconstrained type parameter is replaced with
            // its original. When a generic class or interface is instantiated, each generic method in the class or
            // interface is instantiated with a fresh set of cloned type parameters (which we need to handle scenarios
            // where different generations of the same type parameter are in scope). This leads to a lot of new type
            // identities, and potentially a lot of work comparing those identities, so here we create an instantiation
            // that uses the original type identities for all unconstrained type parameters.
            return getSignatureInstantiation(
                signature,
                map(
                    signature.typeParameters,
                    tp => tp.target && !getConstraintOfTypeParameter(tp.target)
                        ? tp.target
                        : tp
                ),
                isInJSFile(signature.declaration)
            );
        }

        function getBaseSignature(signature: Signature) {
            const typeParameters = signature.typeParameters;
            if (typeParameters) {
                const typeEraser = createTypeEraser(typeParameters);
                const baseConstraints = map(
                    typeParameters,
                    tp => instantiateType(
                        getBaseConstraintOfType(tp),
                        typeEraser
                    ) || unknownType
                );
                return instantiateSignature(
                    signature,
                    createTypeMapper(typeParameters,
                        baseConstraints), /*eraseTypeParameters*/
                    true
                );
            }
            return signature;
        }

        function getOrCreateTypeFromSignature(signature:
            Signature): ObjectType
        {
            // There are two ways to declare a construct signature, one is by declaring a class constructor
            // using the constructor keyword, and the other is declaring a bare construct signature in an
            // object type literal or interface (using the new keyword). Each way of declaring a constructor
            // will result in a different declaration kind.
            if (!signature.isolatedSignatureType) {
                const kind = signature.declaration
                    ? signature.declaration.kind
                    : SyntaxKind.Unknown;
                const isConstructor = kind === SyntaxKind.Constructor
                    || kind === SyntaxKind.ConstructSignature
                    || kind === SyntaxKind.ConstructorType;
                const type = createObjectType(ObjectFlags.Anonymous);
                type.members = emptySymbols;
                type.properties = emptyArray;
                type.callSignatures = !isConstructor
                    ? [signature]
                    : emptyArray;
                type.constructSignatures = isConstructor
                    ? [signature]
                    : emptyArray;
                signature.isolatedSignatureType = type;
            }

            return signature.isolatedSignatureType;
        }

        function getIndexSymbol(symbol: Symbol): Symbol | undefined {
            return symbol.members!.get(InternalSymbolName.Index);
        }

        function getIndexDeclarationOfSymbol(
            symbol: Symbol,
            kind: IndexKind
        ): IndexSignatureDeclaration | undefined {
            const syntaxKind = kind === IndexKind.Number
                ? SyntaxKind.NumberKeyword
                : SyntaxKind.StringKeyword;
            const indexSymbol = getIndexSymbol(symbol);
            if (indexSymbol) {
                for (const decl of indexSymbol.declarations) {
                    const node = cast(decl, isIndexSignatureDeclaration);
                    if (node.parameters.length === 1) {
                        const parameter = node.parameters[0];
                        if (parameter.type
                            && parameter.type.kind === syntaxKind)
                        {
                            return node;
                        }
                    }
                }
            }

            return undefined;
        }

        function createIndexInfo(
            type: Type,
            isReadonly: boolean,
            declaration?: IndexSignatureDeclaration
        ): IndexInfo {
            return { type, isReadonly, declaration };
        }

        function getIndexInfoOfSymbol(
            symbol: Symbol,
            kind: IndexKind
        ): IndexInfo | undefined {
            const declaration = getIndexDeclarationOfSymbol(symbol, kind);
            if (declaration) {
                return createIndexInfo(
                    declaration.type
                        ? getTypeFromTypeNode(declaration.type)
                        : anyType,
                    hasModifier(declaration, ModifierFlags.Readonly),
                    declaration
                );
            }
            return undefined;
        }

        function getConstraintDeclaration(
            type: TypeParameter
        ): TypeNode | undefined {
            return mapDefined(
                filter(
                    type.symbol && type.symbol.declarations,
                    isTypeParameterDeclaration
                ),
                getEffectiveConstraintOfTypeParameter
            )[0];
        }

        function getInferredTypeParameterConstraint(
            typeParameter: TypeParameter
        ) {
            let inferences: Type[] | undefined;
            if (typeParameter.symbol) {
                for (const declaration of typeParameter.symbol.declarations) {
                    if (declaration.parent.kind === SyntaxKind.InferType) {
                        // When an 'infer T' declaration is immediately contained in a type reference node
                        // (such as 'Foo<infer T>'), T's constraint is inferred from the constraint of the
                        // corresponding type parameter in 'Foo'. When multiple 'infer T' declarations are
                        // present, we form an intersection of the inferred constraint types.
                        const grandParent = declaration.parent.parent;
                        if (grandParent.kind === SyntaxKind.TypeReference) {
                            const typeReference = <TypeReferenceNode> grandParent;
                            const typeParameters = getTypeParametersForTypeReference(typeReference);
                            if (typeParameters) {
                                const index = typeReference.typeArguments!
                                    .indexOf(<TypeNode> declaration.parent);
                                if (index < typeParameters.length) {
                                    const declaredConstraint = getConstraintOfTypeParameter(
                                        typeParameters[index]
                                    );
                                    if (declaredConstraint) {
                                        // Type parameter constraints can reference other type parameters so
                                        // constraints need to be instantiated. If instantiation produces the
                                        // type parameter itself, we discard that inference. For example, in
                                        //   type Foo<T extends string, U extends T> = [T, U];
                                        //   type Bar<T> = T extends Foo<infer X, infer X> ? Foo<X, X> : T;
                                        // the instantiated constraint for U is X, so we discard that inference.
                                        const mapper = createTypeMapper(
                                            typeParameters,
                                            getEffectiveTypeArguments(
                                                typeReference,
                                                typeParameters
                                            )
                                        );
                                        const constraint = instantiateType(
                                            declaredConstraint,
                                            mapper
                                        );
                                        if (constraint !== typeParameter) {
                                            inferences = append(
                                                inferences,
                                                constraint
                                            );
                                        }
                                    }
                                }
                            }
                        } // When an 'infer T' declaration is immediately contained in a rest parameter
                        // declaration, we infer an 'unknown[]' constraint.
                        else if (grandParent.kind === SyntaxKind.Parameter
                            && (<ParameterDeclaration> grandParent)
                                .dotDotDotToken)
                        {
                            inferences = append(
                                inferences,
                                createArrayType(unknownType)
                            );
                        }
                    }
                }
            }
            return inferences && getIntersectionType(inferences);
        }

        /** This is a worker function. Use getConstraintOfTypeParameter which guards against circular constraints. */
        function getConstraintFromTypeParameter(
            typeParameter: TypeParameter
        ): Type | undefined {
            if (!typeParameter.constraint) {
                if (typeParameter.target) {
                    const targetConstraint = getConstraintOfTypeParameter(
                        typeParameter.target
                    );
                    typeParameter.constraint = targetConstraint
                        ? instantiateType(
                            targetConstraint,
                            typeParameter.mapper
                        )
                        : noConstraintType;
                } else {
                    const constraintDeclaration = getConstraintDeclaration(typeParameter);
                    typeParameter.constraint = constraintDeclaration
                        ? getTypeFromTypeNode(constraintDeclaration)
                        : getInferredTypeParameterConstraint(typeParameter)
                            || noConstraintType;
                }
            }
            return typeParameter.constraint === noConstraintType
                ? undefined
                : typeParameter.constraint;
        }

        function getParentSymbolOfTypeParameter(
            typeParameter: TypeParameter
        ): Symbol | undefined {
            const tp = getDeclarationOfKind<TypeParameterDeclaration>(
                typeParameter.symbol,
                SyntaxKind.TypeParameter
            )!;
            const host = isJSDocTemplateTag(tp.parent)
                ? getHostSignatureFromJSDoc(tp.parent)
                : tp.parent;
            return host && getSymbolOfNode(host);
        }

        function getTypeListId(types: readonly Type[] | undefined) {
            let result = '';
            if (types) {
                const length = types.length;
                let i = 0;
                while (i < length) {
                    const startId = types[i].id;
                    let count = 1;
                    while (i + count < length
                        && types[i + count].id === startId + count)
                    {
                        count++;
                    }
                    if (result.length) {
                        result += ',';
                    }
                    result += startId;
                    if (count > 1) {
                        result += ':' + count;
                    }
                    i += count;
                }
            }
            return result;
        }

        // This function is used to propagate certain flags when creating new object type references and union types.
        // It is only necessary to do so if a constituent type might be the undefined type, the null type, the type
        // of an object literal or the anyFunctionType. This is because there are operations in the type checker
        // that care about the presence of such types at arbitrary depth in a containing type.
        function getPropagatingFlagsOfTypes(
            types: readonly Type[],
            excludeKinds: TypeFlags
        ): ObjectFlags {
            let result: ObjectFlags = 0;
            for (const type of types) {
                if (!(type.flags & excludeKinds)) {
                    result |= getObjectFlags(type);
                }
            }
            return result & ObjectFlags.PropagatingFlags;
        }

        function createTypeReference(
            target: GenericType,
            typeArguments: readonly Type[] | undefined
        ): TypeReference {
            const id = getTypeListId(typeArguments);
            let type = target.instantiations.get(id);
            if (!type) {
                type = <TypeReference> createObjectType(
                    ObjectFlags.Reference,
                    target.symbol
                );
                target.instantiations.set(id, type);
                type.objectFlags |= typeArguments
                    ? getPropagatingFlagsOfTypes(
                        typeArguments, /*excludeKinds*/
                        0
                    )
                    : 0;
                type.target = target;
                type.resolvedTypeArguments = typeArguments;
            }
            return type;
        }

        function cloneTypeReference(source: TypeReference): TypeReference {
            const type = <TypeReference> createType(source.flags);
            type.symbol = source.symbol;
            type.objectFlags = source.objectFlags;
            type.target = source.target;
            type.resolvedTypeArguments = source.resolvedTypeArguments;
            return type;
        }

        function createDeferredTypeReference(
            target: GenericType,
            node: TypeReferenceNode | ArrayTypeNode | TupleTypeNode,
            mapper?: TypeMapper
        ): DeferredTypeReference {
            const aliasSymbol = getAliasSymbolForTypeNode(node);
            const aliasTypeArguments = getTypeArgumentsForAliasSymbol(aliasSymbol);
            const type = <DeferredTypeReference> createObjectType(
                ObjectFlags.Reference,
                target.symbol
            );
            type.target = target;
            type.node = node;
            type.mapper = mapper;
            type.aliasSymbol = aliasSymbol;
            type.aliasTypeArguments = mapper
                ? instantiateTypes(aliasTypeArguments, mapper)
                : aliasTypeArguments;
            return type;
        }

        function getTypeArguments(type: TypeReference): readonly Type[] {
            if (!type.resolvedTypeArguments) {
                if (!pushTypeResolution(
                    type,
                    TypeSystemPropertyName.ResolvedTypeArguments
                )) {
                    return type.target.localTypeParameters
                        ?.map(() => errorType) || emptyArray;
                }
                const node = type.node;
                const typeArguments = !node
                    ? emptyArray
                    : node.kind === SyntaxKind.TypeReference
                        ? concatenate(
                            type.target.outerTypeParameters,
                            getEffectiveTypeArguments(
                                node,
                                type.target.localTypeParameters!
                            )
                        )
                        : node.kind === SyntaxKind.ArrayType
                            ? [getTypeFromTypeNode(node.elementType)]
                            : map(node.elementTypes, getTypeFromTypeNode);
                if (popTypeResolution()) {
                    type.resolvedTypeArguments = type.mapper
                        ? instantiateTypes(typeArguments, type.mapper)
                        : typeArguments;
                } else {
                    type
                        .resolvedTypeArguments = type.target
                            .localTypeParameters?.map(() => errorType)
                            || emptyArray;
                    error(
                        type.node || currentNode,
                        type.target.symbol
                            ? Diagnostics
                                .Type_arguments_for_0_circularly_reference_themselves
                            : Diagnostics
                                .Tuple_type_arguments_circularly_reference_themselves,
                        type.target.symbol && symbolToString(
                            type.target.symbol
                        )
                    );
                }
            }
            return type.resolvedTypeArguments;
        }

        function getTypeReferenceArity(type: TypeReference): number {
            return length(type.target.typeParameters);
        }

        /**
         * Get type from type-reference that reference to class or interface
         */
        function getTypeFromClassOrInterfaceReference(
            node: NodeWithTypeArguments,
            symbol: Symbol
        ): Type {
            const type = <InterfaceType> getDeclaredTypeOfSymbol(getMergedSymbol(symbol));
            const typeParameters = type.localTypeParameters;
            if (typeParameters) {
                const numTypeArguments = length(node.typeArguments);
                const minTypeArgumentCount = getMinTypeArgumentCount(typeParameters);
                const isJs = isInJSFile(node);
                const isJsImplicitAny = !noImplicitAny && isJs;
                if (!isJsImplicitAny
                    && (numTypeArguments < minTypeArgumentCount
                        || numTypeArguments > typeParameters.length))
                {
                    const missingAugmentsTag = isJs
                        && isExpressionWithTypeArguments(node)
                        && !isJSDocAugmentsTag(node.parent);
                    const diag = minTypeArgumentCount === typeParameters.length
                        ? missingAugmentsTag
                            ? Diagnostics
                                .Expected_0_type_arguments_provide_these_with_an_extends_tag
                            : Diagnostics
                                .Generic_type_0_requires_1_type_argument_s
                        : missingAugmentsTag
                            ? Diagnostics
                                .Expected_0_1_type_arguments_provide_these_with_an_extends_tag
                            : Diagnostics
                                .Generic_type_0_requires_between_1_and_2_type_arguments;

                    const typeStr = typeToString(
                        type, /*enclosingDeclaration*/
                        undefined,
                        TypeFormatFlags.WriteArrayAsGenericType
                    );
                    error(
                        node,
                        diag,
                        typeStr,
                        minTypeArgumentCount,
                        typeParameters.length
                    );
                    if (!isJs) {
                        // TODO: Adopt same permissive behavior in TS as in JS to reduce follow-on editing experience failures (requires editing fillMissingTypeArguments)
                        return errorType;
                    }
                }
                if (node.kind === SyntaxKind.TypeReference
                    && isAliasedType(node))
                {
                    return createDeferredTypeReference(
                        <GenericType> type,
                        <TypeReferenceNode> node, /*mapper*/
                        undefined
                    );
                }
                // In a type reference, the outer type parameters of the referenced class or interface are automatically
                // supplied as type arguments and the type reference only specifies arguments for the local type parameters
                // of the class or interface.
                const typeArguments = concatenate(
                    type.outerTypeParameters,
                    fillMissingTypeArguments(
                        typeArgumentsFromTypeReferenceNode(node),
                        typeParameters,
                        minTypeArgumentCount,
                        isJs
                    )
                );
                return createTypeReference(<GenericType> type, typeArguments);
            }
            return checkNoTypeArguments(node, symbol) ? type : errorType;
        }

        function getTypeAliasInstantiation(
            symbol: Symbol,
            typeArguments: readonly Type[] | undefined
        ): Type {
            const type = getDeclaredTypeOfSymbol(symbol);
            const links = getSymbolLinks(symbol);
            const typeParameters = links.typeParameters!;
            const id = getTypeListId(typeArguments);
            let instantiation = links.instantiations!.get(id);
            if (!instantiation) {
                links.instantiations!.set(
                    id,
                    instantiation = instantiateType(
                        type,
                        createTypeMapper(
                            typeParameters,
                            fillMissingTypeArguments(
                                typeArguments,
                                typeParameters,
                                getMinTypeArgumentCount(typeParameters),
                                isInJSFile(symbol.valueDeclaration)
                            )
                        )
                    )
                );
            }
            return instantiation;
        }

        /**
         * Get type from reference to type alias. When a type alias is generic, the declared type of the type alias may include
         * references to the type parameters of the alias. We replace those with the actual type arguments by instantiating the
         * declared type. Instantiations are cached using the type identities of the type arguments as the key.
         */
        function getTypeFromTypeAliasReference(
            node: NodeWithTypeArguments,
            symbol: Symbol
        ): Type {
            const type = getDeclaredTypeOfSymbol(symbol);
            const typeParameters = getSymbolLinks(symbol).typeParameters;
            if (typeParameters) {
                const numTypeArguments = length(node.typeArguments);
                const minTypeArgumentCount = getMinTypeArgumentCount(typeParameters);
                if (numTypeArguments < minTypeArgumentCount
                    || numTypeArguments > typeParameters.length)
                {
                    error(
                        node,
                        minTypeArgumentCount === typeParameters.length
                            ? Diagnostics
                                .Generic_type_0_requires_1_type_argument_s
                            : Diagnostics
                                .Generic_type_0_requires_between_1_and_2_type_arguments,
                        symbolToString(symbol),
                        minTypeArgumentCount,
                        typeParameters.length
                    );
                    return errorType;
                }
                return getTypeAliasInstantiation(
                    symbol,
                    typeArgumentsFromTypeReferenceNode(node)
                );
            }
            return checkNoTypeArguments(node, symbol) ? type : errorType;
        }

        function getTypeReferenceName(
            node: TypeReferenceType
        ): EntityNameOrEntityNameExpression | undefined {
            switch (node.kind) {
                case SyntaxKind.TypeReference:
                    return node.typeName;
                case SyntaxKind.ExpressionWithTypeArguments:
                    // We only support expressions that are simple qualified names. For other
                    // expressions this produces undefined.
                    const expr = node.expression;
                    if (isEntityNameExpression(expr)) {
                        return expr;
                    }
                    // fall through;
            }

            return undefined;
        }

        function resolveTypeReferenceName(
            typeReferenceName: EntityNameExpression | EntityName | undefined,
            meaning: SymbolFlags,
            ignoreErrors?: boolean
        ) {
            if (!typeReferenceName) {
                return unknownSymbol;
            }

            return resolveEntityName(typeReferenceName, meaning, ignoreErrors)
                || unknownSymbol;
        }

        function getTypeReferenceType(
            node: NodeWithTypeArguments,
            symbol: Symbol
        ): Type {
            if (symbol === unknownSymbol) {
                return errorType;
            }
            symbol = getExpandoSymbol(symbol) || symbol;
            if (symbol.flags & (SymbolFlags.Class | SymbolFlags.Interface)) {
                return getTypeFromClassOrInterfaceReference(node, symbol);
            }
            if (isTypeOnlyAlias(symbol)) {
                return getTypeReferenceType(node, symbol.immediateTarget);
            }
            if (symbol.flags & SymbolFlags.TypeAlias) {
                return getTypeFromTypeAliasReference(node, symbol);
            }
            // Get type from reference to named type that cannot be generic (enum or type parameter)
            const res = tryGetDeclaredTypeOfSymbol(symbol);
            if (res) {
                return checkNoTypeArguments(node, symbol)
                    ? res.flags & TypeFlags.TypeParameter
                        ? getConstrainedTypeVariable(<TypeParameter> res, node)
                        : getRegularTypeOfLiteralType(res)
                    : errorType;
            }
            if (symbol.flags & SymbolFlags.Value
                && isJSDocTypeReference(node))
            {
                const jsdocType = getTypeFromJSDocValueReference(node, symbol);
                if (jsdocType) {
                    return jsdocType;
                } else {
                    // Resolve the type reference as a Type for the purpose of reporting errors.
                    resolveTypeReferenceName(
                        getTypeReferenceName(node),
                        SymbolFlags.Type
                    );
                    return getTypeOfSymbol(symbol);
                }
            }
            return errorType;
        }

        /**
         * A JSdoc TypeReference may be to a value, but resolve it as a type anyway.
         * Note: If the value is imported from commonjs, it should really be an alias,
         * but this function's special-case code fakes alias resolution as well.
         */
        function getTypeFromJSDocValueReference(
            node: NodeWithTypeArguments,
            symbol: Symbol
        ): Type | undefined {
            const valueType = getTypeOfSymbol(symbol);
            let typeType = valueType;
            if (symbol.valueDeclaration) {
                const decl = getRootDeclaration(symbol.valueDeclaration);
                let isRequireAlias = false;
                if (isVariableDeclaration(decl) && decl.initializer) {
                    let expr = decl.initializer;
                    // skip past entity names, eg `require("x").a.b.c`
                    while (isPropertyAccessExpression(expr)) {
                        expr = expr.expression;
                    }
                    isRequireAlias = isCallExpression(expr)
                        && isRequireCall(
                            expr, /*requireStringLiteralLikeArgument*/
                            true
                        ) && !!valueType.symbol;
                }
                const isImportTypeWithQualifier = node.kind
                    === SyntaxKind.ImportType
                    && (node as ImportTypeNode).qualifier;
                // valueType might not have a symbol, eg, {import('./b').STRING_LITERAL}
                if (valueType.symbol
                    && (isRequireAlias || isImportTypeWithQualifier))
                {
                    typeType = getTypeReferenceType(node, valueType.symbol);
                }
            }
            return getSymbolLinks(symbol).resolvedJSDocType = typeType;
        }

        function getSubstitutionType(
            typeVariable: TypeVariable,
            substitute: Type
        ) {
            if (substitute.flags & TypeFlags.AnyOrUnknown
                || substitute === typeVariable)
            {
                return typeVariable;
            }
            const id = `${getTypeId(typeVariable)}>${getTypeId(substitute)}`;
            const cached = substitutionTypes.get(id);
            if (cached) {
                return cached;
            }
            const result = <SubstitutionType> createType(
                TypeFlags.Substitution
            );
            result.typeVariable = typeVariable;
            result.substitute = substitute;
            substitutionTypes.set(id, result);
            return result;
        }

        function isUnaryTupleTypeNode(node: TypeNode) {
            return node.kind === SyntaxKind.TupleType
                && (<TupleTypeNode> node).elementTypes.length === 1;
        }

        function getImpliedConstraint(
            typeVariable: TypeVariable,
            checkNode: TypeNode,
            extendsNode: TypeNode
        ): Type | undefined {
            return isUnaryTupleTypeNode(checkNode)
                && isUnaryTupleTypeNode(extendsNode)
                ? getImpliedConstraint(
                    typeVariable,
                    (<TupleTypeNode> checkNode).elementTypes[0],
                    (<TupleTypeNode> extendsNode).elementTypes[0]
                )
                : getActualTypeVariable(getTypeFromTypeNode(checkNode))
                    === typeVariable
                    ? getTypeFromTypeNode(extendsNode)
                    : undefined;
        }

        function getConstrainedTypeVariable(
            typeVariable: TypeVariable,
            node: Node
        ) {
            let constraints: Type[] | undefined;
            while (node && !isStatement(node)
                && node.kind !== SyntaxKind.JSDocComment)
            {
                const parent = node.parent;
                if (parent.kind === SyntaxKind.ConditionalType
                    && node === (<ConditionalTypeNode> parent).trueType)
                {
                    const constraint = getImpliedConstraint(
                        typeVariable,
                        (<ConditionalTypeNode> parent).checkType,
                        (<ConditionalTypeNode> parent).extendsType
                    );
                    if (constraint) {
                        constraints = append(constraints, constraint);
                    }
                }
                node = parent;
            }
            return constraints
                ? getSubstitutionType(
                    typeVariable,
                    getIntersectionType(append(constraints, typeVariable))
                )
                : typeVariable;
        }

        function isJSDocTypeReference(node: Node): node is TypeReferenceNode {
            return !!(node.flags & NodeFlags.JSDoc)
                && (node.kind === SyntaxKind.TypeReference
                    || node.kind === SyntaxKind.ImportType);
        }

        function checkNoTypeArguments(
            node: NodeWithTypeArguments,
            symbol?: Symbol
        ) {
            if (node.typeArguments) {
                error(
                    node,
                    Diagnostics.Type_0_is_not_generic,
                    symbol
                        ? symbolToString(symbol)
                        : (<TypeReferenceNode> node).typeName
                            ? declarationNameToString((<TypeReferenceNode> node)
                                .typeName)
                            : anon
                );
                return false;
            }
            return true;
        }

        function getIntendedTypeFromJSDocTypeReference(
            node: TypeReferenceNode
        ): Type | undefined {
            if (isIdentifier(node.typeName)) {
                const typeArgs = node.typeArguments;
                switch (node.typeName.escapedText) {
                    case 'String':
                        checkNoTypeArguments(node);
                        return stringType;
                    case 'Number':
                        checkNoTypeArguments(node);
                        return numberType;
                    case 'Boolean':
                        checkNoTypeArguments(node);
                        return booleanType;
                    case 'Void':
                        checkNoTypeArguments(node);
                        return voidType;
                    case 'Undefined':
                        checkNoTypeArguments(node);
                        return undefinedType;
                    case 'Null':
                        checkNoTypeArguments(node);
                        return nullType;
                    case 'Function':
                    case 'function':
                        checkNoTypeArguments(node);
                        return globalFunctionType;
                    case 'array':
                        return (!typeArgs || !typeArgs.length)
                            && !noImplicitAny
                            ? anyArrayType
                            : undefined;
                    case 'promise':
                        return (!typeArgs || !typeArgs.length)
                            && !noImplicitAny
                            ? createPromiseType(anyType)
                            : undefined;
                    case 'Object':
                        if (typeArgs && typeArgs.length === 2) {
                            if (isJSDocIndexSignature(node)) {
                                const indexed = getTypeFromTypeNode(
                                    typeArgs[0]
                                );
                                const target = getTypeFromTypeNode(typeArgs
                                    [1]);
                                const index = createIndexInfo(
                                    target, /*isReadonly*/
                                    false
                                );
                                return createAnonymousType(
                                    undefined,
                                    emptySymbols,
                                    emptyArray,
                                    emptyArray,
                                    indexed === stringType ? index : undefined,
                                    indexed === numberType ? index : undefined
                                );
                            }
                            return anyType;
                        }
                        checkNoTypeArguments(node);
                        return !noImplicitAny ? anyType : undefined;
                }
            }
        }

        function getTypeFromJSDocNullableTypeNode(node: JSDocNullableType) {
            const type = getTypeFromTypeNode(node.type);
            return strictNullChecks
                ? getNullableType(type, TypeFlags.Null)
                : type;
        }

        function getTypeFromTypeReference(node: TypeReferenceType): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                let symbol: Symbol | undefined;
                let type: Type | undefined;
                const meaning = SymbolFlags.Type;
                if (isJSDocTypeReference(node)) {
                    type = getIntendedTypeFromJSDocTypeReference(node);
                    if (!type) {
                        symbol = resolveTypeReferenceName(
                            getTypeReferenceName(node),
                            meaning, /*ignoreErrors*/
                            true
                        );
                        if (symbol === unknownSymbol) {
                            symbol = resolveTypeReferenceName(
                                getTypeReferenceName(node),
                                meaning | SymbolFlags.Value
                            );
                        } else {
                            resolveTypeReferenceName(
                                getTypeReferenceName(node),
                                meaning
                            ); // Resolve again to mark errors, if any
                        }
                        type = getTypeReferenceType(node, symbol);
                    }
                }
                if (!type) {
                    symbol = resolveTypeReferenceName(
                        getTypeReferenceName(node),
                        meaning
                    );
                    type = getTypeReferenceType(node, symbol);
                }
                // Cache both the resolved symbol and the resolved type. The resolved symbol is needed when we check the
                // type reference in checkTypeReferenceNode.
                links.resolvedSymbol = symbol;
                links.resolvedType = type;
            }
            return links.resolvedType;
        }

        function typeArgumentsFromTypeReferenceNode(
            node: NodeWithTypeArguments
        ): Type[] | undefined {
            return map(node.typeArguments, getTypeFromTypeNode);
        }

        function getTypeFromTypeQueryNode(node: TypeQueryNode): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                // TypeScript 1.0 spec (April 2014): 3.6.3
                // The expression is processed as an identifier expression (section 4.3)
                // or property access expression(section 4.10),
                // the widened type(section 3.9) of which becomes the result.
                links
                    .resolvedType = getRegularTypeOfLiteralType(
                        getWidenedType(
                            checkExpression(
                                node.exprName
                            )
                        )
                    );
            }
            return links.resolvedType;
        }

        function getTypeOfGlobalSymbol(
            symbol: Symbol | undefined,
            arity: number
        ): ObjectType {
            function getTypeDeclaration(
                symbol: Symbol
            ): Declaration | undefined {
                const declarations = symbol.declarations;
                for (const declaration of declarations) {
                    switch (declaration.kind) {
                        case SyntaxKind.ClassDeclaration:
                        case SyntaxKind.InterfaceDeclaration:
                        case SyntaxKind.EnumDeclaration:
                            return declaration;
                    }
                }
            }

            if (!symbol) {
                return arity ? emptyGenericType : emptyObjectType;
            }
            const type = getDeclaredTypeOfSymbol(symbol);
            if (!(type.flags & TypeFlags.Object)) {
                error(
                    getTypeDeclaration(symbol),
                    Diagnostics
                        .Global_type_0_must_be_a_class_or_interface_type,
                    symbolName(symbol)
                );
                return arity ? emptyGenericType : emptyObjectType;
            }
            if (length((<InterfaceType> type).typeParameters) !== arity) {
                error(
                    getTypeDeclaration(symbol),
                    Diagnostics.Global_type_0_must_have_1_type_parameter_s,
                    symbolName(symbol),
                    arity
                );
                return arity ? emptyGenericType : emptyObjectType;
            }
            return <ObjectType> type;
        }

        function getGlobalValueSymbol(
            name: __String,
            reportErrors: boolean
        ): Symbol | undefined {
            return getGlobalSymbol(
                name,
                SymbolFlags.Value,
                reportErrors
                    ? Diagnostics.Cannot_find_global_value_0
                    : undefined
            );
        }

        function getGlobalTypeSymbol(
            name: __String,
            reportErrors: boolean
        ): Symbol | undefined {
            return getGlobalSymbol(
                name,
                SymbolFlags.Type,
                reportErrors
                    ? Diagnostics.Cannot_find_global_type_0
                    : undefined
            );
        }

        function getGlobalSymbol(
            name: __String,
            meaning: SymbolFlags,
            diagnostic: DiagnosticMessage | undefined
        ): Symbol | undefined {
            // Don't track references for global symbols anyway, so value if `isReference` is arbitrary
            return resolveName(
                undefined,
                name,
                meaning,
                diagnostic,
                name, /*isUse*/
                false
            );
        }

        function getGlobalType(
            name: __String,
            arity: 0,
            reportErrors: boolean
        ): ObjectType;
        function getGlobalType(
            name: __String,
            arity: number,
            reportErrors: boolean
        ): GenericType;
        function getGlobalType(
            name: __String,
            arity: number,
            reportErrors: boolean
        ): ObjectType | undefined {
            const symbol = getGlobalTypeSymbol(name, reportErrors);
            return symbol || reportErrors
                ? getTypeOfGlobalSymbol(symbol, arity)
                : undefined;
        }

        function getGlobalTypedPropertyDescriptorType() {
            return deferredGlobalTypedPropertyDescriptorType
                || (deferredGlobalTypedPropertyDescriptorType = getGlobalType(
                    'TypedPropertyDescriptor' as __String /*arity*/,
                    1, /*reportErrors*/
                    true
                )) || emptyGenericType;
        }

        function getGlobalTemplateStringsArrayType() {
            return deferredGlobalTemplateStringsArrayType
                || (deferredGlobalTemplateStringsArrayType = getGlobalType(
                    'TemplateStringsArray' as __String /*arity*/,
                    0, /*reportErrors*/
                    true
                )) || emptyObjectType;
        }

        function getGlobalImportMetaType() {
            return deferredGlobalImportMetaType
                || (deferredGlobalImportMetaType = getGlobalType(
                    'ImportMeta' as __String /*arity*/,
                    0, /*reportErrors*/
                    true
                )) || emptyObjectType;
        }

        function getGlobalESSymbolConstructorSymbol(reportErrors: boolean) {
            return deferredGlobalESSymbolConstructorSymbol
                || (deferredGlobalESSymbolConstructorSymbol = getGlobalValueSymbol(
                    'Symbol' as __String,
                    reportErrors
                ));
        }

        function getGlobalESSymbolType(reportErrors: boolean) {
            return deferredGlobalESSymbolType
                || (deferredGlobalESSymbolType = getGlobalType(
                    'Symbol' as __String /*arity*/,
                    0,
                    reportErrors
                )) || emptyObjectType;
        }

        function getGlobalPromiseType(reportErrors: boolean) {
            return deferredGlobalPromiseType
                || (deferredGlobalPromiseType = getGlobalType(
                    'Promise' as __String /*arity*/,
                    1,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalPromiseLikeType(reportErrors: boolean) {
            return deferredGlobalPromiseLikeType
                || (deferredGlobalPromiseLikeType = getGlobalType(
                    'PromiseLike' as __String /*arity*/,
                    1,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalPromiseConstructorSymbol(
            reportErrors: boolean
        ): Symbol | undefined {
            return deferredGlobalPromiseConstructorSymbol
                || (deferredGlobalPromiseConstructorSymbol = getGlobalValueSymbol(
                    'Promise' as __String,
                    reportErrors
                ));
        }

        function getGlobalPromiseConstructorLikeType(reportErrors: boolean) {
            return deferredGlobalPromiseConstructorLikeType
                || (deferredGlobalPromiseConstructorLikeType = getGlobalType(
                    'PromiseConstructorLike' as __String /*arity*/,
                    0,
                    reportErrors
                )) || emptyObjectType;
        }

        function getGlobalAsyncIterableType(reportErrors: boolean) {
            return deferredGlobalAsyncIterableType
                || (deferredGlobalAsyncIterableType = getGlobalType(
                    'AsyncIterable' as __String /*arity*/,
                    1,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalAsyncIteratorType(reportErrors: boolean) {
            return deferredGlobalAsyncIteratorType
                || (deferredGlobalAsyncIteratorType = getGlobalType(
                    'AsyncIterator' as __String /*arity*/,
                    3,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalAsyncIterableIteratorType(reportErrors: boolean) {
            return deferredGlobalAsyncIterableIteratorType
                || (deferredGlobalAsyncIterableIteratorType = getGlobalType(
                    'AsyncIterableIterator' as __String /*arity*/,
                    1,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalAsyncGeneratorType(reportErrors: boolean) {
            return deferredGlobalAsyncGeneratorType
                || (deferredGlobalAsyncGeneratorType = getGlobalType(
                    'AsyncGenerator' as __String /*arity*/,
                    3,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalIterableType(reportErrors: boolean) {
            return deferredGlobalIterableType
                || (deferredGlobalIterableType = getGlobalType(
                    'Iterable' as __String /*arity*/,
                    1,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalIteratorType(reportErrors: boolean) {
            return deferredGlobalIteratorType
                || (deferredGlobalIteratorType = getGlobalType(
                    'Iterator' as __String /*arity*/,
                    3,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalIterableIteratorType(reportErrors: boolean) {
            return deferredGlobalIterableIteratorType
                || (deferredGlobalIterableIteratorType = getGlobalType(
                    'IterableIterator' as __String /*arity*/,
                    1,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalGeneratorType(reportErrors: boolean) {
            return deferredGlobalGeneratorType
                || (deferredGlobalGeneratorType = getGlobalType(
                    'Generator' as __String /*arity*/,
                    3,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalIteratorYieldResultType(reportErrors: boolean) {
            return deferredGlobalIteratorYieldResultType
                || (deferredGlobalIteratorYieldResultType = getGlobalType(
                    'IteratorYieldResult' as __String /*arity*/,
                    1,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalIteratorReturnResultType(reportErrors: boolean) {
            return deferredGlobalIteratorReturnResultType
                || (deferredGlobalIteratorReturnResultType = getGlobalType(
                    'IteratorReturnResult' as __String /*arity*/,
                    1,
                    reportErrors
                )) || emptyGenericType;
        }

        function getGlobalTypeOrUndefined(
            name: __String,
            arity = 0
        ): ObjectType | undefined {
            const symbol = getGlobalSymbol(
                name,
                SymbolFlags.Type, /*diagnostic*/
                undefined
            );
            return symbol
                && <GenericType> getTypeOfGlobalSymbol(symbol, arity);
        }

        function getGlobalExtractSymbol(): Symbol {
            return deferredGlobalExtractSymbol
                || (deferredGlobalExtractSymbol = getGlobalSymbol(
                    'Extract' as __String,
                    SymbolFlags.TypeAlias,
                    Diagnostics.Cannot_find_global_type_0
                )!); // TODO: GH#18217
        }

        function getGlobalOmitSymbol(): Symbol {
            return deferredGlobalOmitSymbol
                || (deferredGlobalOmitSymbol = getGlobalSymbol(
                    'Omit' as __String,
                    SymbolFlags.TypeAlias,
                    Diagnostics.Cannot_find_global_type_0
                )!); // TODO: GH#18217
        }

        function getGlobalBigIntType(reportErrors: boolean) {
            return deferredGlobalBigIntType
                || (deferredGlobalBigIntType = getGlobalType(
                    'BigInt' as __String /*arity*/,
                    0,
                    reportErrors
                )) || emptyObjectType;
        }

        /**
         * Instantiates a global type that is generic with some element type, and returns that instantiation.
         */
        function createTypeFromGenericGlobalType(
            genericGlobalType: GenericType,
            typeArguments: readonly Type[]
        ): ObjectType {
            return genericGlobalType !== emptyGenericType
                ? createTypeReference(genericGlobalType, typeArguments)
                : emptyObjectType;
        }

        function createTypedPropertyDescriptorType(propertyType: Type): Type {
            return createTypeFromGenericGlobalType(
                getGlobalTypedPropertyDescriptorType(),
                [propertyType]
            );
        }

        function createIterableType(iteratedType: Type): Type {
            return createTypeFromGenericGlobalType(
                getGlobalIterableType(/*reportErrors*/ true),
                [iteratedType]
            );
        }

        function createArrayType(
            elementType: Type,
            readonly?: boolean
        ): ObjectType {
            return createTypeFromGenericGlobalType(
                readonly
                    ? globalReadonlyArrayType
                    : globalArrayType,
                [elementType]
            );
        }

        function getArrayOrTupleTargetType(
            node: ArrayTypeNode | TupleTypeNode
        ): GenericType {
            const readonly = isReadonlyTypeOperator(node.parent);
            if (node.kind === SyntaxKind.ArrayType
                || node.elementTypes.length === 1
                && node.elementTypes[0].kind === SyntaxKind.RestType)
            {
                return readonly ? globalReadonlyArrayType : globalArrayType;
            }
            const lastElement = lastOrUndefined(node.elementTypes);
            const restElement = lastElement
                && lastElement.kind === SyntaxKind.RestType
                ? lastElement
                : undefined;
            const minLength = findLastIndex(
                node.elementTypes,
                n => n.kind !== SyntaxKind.OptionalType && n !== restElement
            ) + 1;
            return getTupleTypeOfArity(
                node.elementTypes.length,
                minLength,
                !!restElement,
                readonly, /*associatedNames*/
                undefined
            );
        }

        // Return true when the given node is transitively contained in type constructs that eagerly
        // resolve their constituent types. We include SyntaxKind.TypeReference because type arguments
        // of type aliases are eagerly resolved.
        function isAliasedType(node: Node): boolean {
            const parent = node.parent;
            switch (parent.kind) {
                case SyntaxKind.ParenthesizedType:
                case SyntaxKind.TypeReference:
                case SyntaxKind.UnionType:
                case SyntaxKind.IntersectionType:
                case SyntaxKind.IndexedAccessType:
                case SyntaxKind.ConditionalType:
                case SyntaxKind.TypeOperator:
                    return isAliasedType(parent);
                case SyntaxKind.TypeAliasDeclaration:
                    return true;
            }
            return false;
        }

        function getTypeFromArrayOrTupleTypeNode(
            node: ArrayTypeNode | TupleTypeNode
        ): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                const target = getArrayOrTupleTargetType(node);
                if (target === emptyGenericType) {
                    links.resolvedType = emptyObjectType;
                } else if (isAliasedType(node)) {
                    links
                        .resolvedType = node.kind === SyntaxKind.TupleType
                            && node.elementTypes.length === 0
                            ? target
                            : createDeferredTypeReference(
                                target,
                                node, /*mapper*/
                                undefined
                            );
                } else {
                    const elementTypes = node.kind === SyntaxKind.ArrayType
                        ? [getTypeFromTypeNode(node.elementType)]
                        : map(node.elementTypes, getTypeFromTypeNode);
                    links.resolvedType = createTypeReference(
                        target,
                        elementTypes
                    );
                }
            }
            return links.resolvedType;
        }

        function isReadonlyTypeOperator(node: Node) {
            return isTypeOperatorNode(node)
                && node.operator === SyntaxKind.ReadonlyKeyword;
        }

        // We represent tuple types as type references to synthesized generic interface types created by
        // this function. The types are of the form:
        //
        //   interface Tuple<T0, T1, T2, ...> extends Array<T0 | T1 | T2 | ...> { 0: T0, 1: T1, 2: T2, ... }
        //
        // Note that the generic type created by this function has no symbol associated with it. The same
        // is true for each of the synthesized type parameters.
        function createTupleTypeOfArity(
            arity: number,
            minLength: number,
            hasRestElement: boolean,
            readonly: boolean,
            associatedNames: __String[] | undefined
        ): TupleType {
            let typeParameters: TypeParameter[] | undefined;
            const properties: Symbol[] = [];
            const maxLength = hasRestElement ? arity - 1 : arity;
            if (arity) {
                typeParameters = new Array(arity);
                for (let i = 0; i < arity; i++) {
                    const typeParameter = typeParameters
                        [i] = createTypeParameter();
                    if (i < maxLength) {
                        const property = createSymbol(
                            SymbolFlags.Property
                                | (i >= minLength ? SymbolFlags.Optional : 0),
                            '' + i as __String,
                            readonly ? CheckFlags.Readonly : 0
                        );
                        property.type = typeParameter;
                        properties.push(property);
                    }
                }
            }
            const literalTypes = [];
            for (let i = minLength; i <= maxLength; i++) {
                literalTypes.push(getLiteralType(i));
            }
            const lengthSymbol = createSymbol(
                SymbolFlags.Property,
                'length' as __String
            );
            lengthSymbol.type = hasRestElement
                ? numberType
                : getUnionType(literalTypes);
            properties.push(lengthSymbol);
            const type = <TupleType
                & InterfaceTypeWithDeclaredMembers> createObjectType(
                    ObjectFlags.Tuple | ObjectFlags.Reference
                );
            type.typeParameters = typeParameters;
            type.outerTypeParameters = undefined;
            type.localTypeParameters = typeParameters;
            type.instantiations = createMap<TypeReference>();
            type.instantiations.set(
                getTypeListId(type.typeParameters),
                <GenericType> type
            );
            type.target = <GenericType> type;
            type.resolvedTypeArguments = type.typeParameters;
            type.thisType = createTypeParameter();
            type.thisType.isThisType = true;
            type.thisType.constraint = type;
            type.declaredProperties = properties;
            type.declaredCallSignatures = emptyArray;
            type.declaredConstructSignatures = emptyArray;
            type.declaredStringIndexInfo = undefined;
            type.declaredNumberIndexInfo = undefined;
            type.minLength = minLength;
            type.hasRestElement = hasRestElement;
            type.readonly = readonly;
            type.associatedNames = associatedNames;
            return type;
        }

        function getTupleTypeOfArity(
            arity: number,
            minLength: number,
            hasRestElement: boolean,
            readonly: boolean,
            associatedNames?: __String[]
        ): GenericType {
            const key = arity + (hasRestElement ? '+' : ',') + minLength
                + (readonly ? 'R' : '')
                + (associatedNames && associatedNames.length
                    ? ',' + associatedNames.join(',')
                    : '');
            let type = tupleTypes.get(key);
            if (!type) {
                tupleTypes.set(
                    key,
                    type = createTupleTypeOfArity(
                        arity,
                        minLength,
                        hasRestElement,
                        readonly,
                        associatedNames
                    )
                );
            }
            return type;
        }

        function createTupleType(
            elementTypes: readonly Type[],
            minLength = elementTypes.length,
            hasRestElement = false,
            readonly = false,
            associatedNames?: __String[]
        ) {
            const arity = elementTypes.length;
            if (arity === 1 && hasRestElement) {
                return createArrayType(elementTypes[0], readonly);
            }
            const tupleType = getTupleTypeOfArity(
                arity,
                minLength,
                arity > 0 && hasRestElement,
                readonly,
                associatedNames
            );
            return elementTypes.length
                ? createTypeReference(tupleType, elementTypes)
                : tupleType;
        }

        function sliceTupleType(type: TupleTypeReference, index: number) {
            const tuple = type.target;
            if (tuple.hasRestElement) {
                // don't slice off rest element
                index = Math.min(index, getTypeReferenceArity(type) - 1);
            }
            return createTupleType(
                getTypeArguments(type).slice(index),
                Math.max(0, tuple.minLength - index),
                tuple.hasRestElement,
                tuple.readonly,
                tuple.associatedNames && tuple.associatedNames.slice(index)
            );
        }

        function getTypeFromOptionalTypeNode(node: OptionalTypeNode): Type {
            const type = getTypeFromTypeNode(node.type);
            return strictNullChecks ? getOptionalType(type) : type;
        }

        function getTypeId(type: Type) {
            return type.id;
        }

        function containsType(types: readonly Type[], type: Type): boolean {
            return binarySearch(types, type, getTypeId, compareValues) >= 0;
        }

        function insertType(types: Type[], type: Type): boolean {
            const index = binarySearch(types, type, getTypeId, compareValues);
            if (index < 0) {
                types.splice(~index, 0, type);
                return true;
            }
            return false;
        }

        function addTypeToUnion(
            typeSet: Type[],
            includes: TypeFlags,
            type: Type
        ) {
            const flags = type.flags;
            if (flags & TypeFlags.Union) {
                return addTypesToUnion(
                    typeSet,
                    includes,
                    (<UnionType> type).types
                );
            }
            // We ignore 'never' types in unions
            if (!(flags & TypeFlags.Never)) {
                includes |= flags & TypeFlags.IncludesMask;
                if (flags
                    & TypeFlags.StructuredOrInstantiable)
                    includes |= TypeFlags.IncludesStructuredOrInstantiable;
                if (type === wildcardType) {
                    includes |= TypeFlags.IncludesWildcard;
                }
                if (!strictNullChecks && flags & TypeFlags.Nullable) {
                    if (!(getObjectFlags(type)
                        & ObjectFlags.ContainsWideningType))
                    {
                        includes |= TypeFlags.IncludesNonWideningType;
                    }
                } else {
                    const len = typeSet.length;
                    const index = len && type.id > typeSet[len - 1].id
                        ? ~len
                        : binarySearch(
                            typeSet,
                            type,
                            getTypeId,
                            compareValues
                        );
                    if (index < 0) {
                        typeSet.splice(~index, 0, type);
                    }
                }
            }
            return includes;
        }

        // Add the given types to the given type set. Order is preserved, duplicates are removed,
        // and nested types of the given kind are flattened into the set.
        function addTypesToUnion(
            typeSet: Type[],
            includes: TypeFlags,
            types: readonly Type[]
        ): TypeFlags {
            for (const type of types) {
                includes = addTypeToUnion(typeSet, includes, type);
            }
            return includes;
        }

        function isSetOfLiteralsFromSameEnum(types: readonly Type[]): boolean {
            const first = types[0];
            if (first.flags & TypeFlags.EnumLiteral) {
                const firstEnum = getParentOfSymbol(first.symbol);
                for (let i = 1; i < types.length; i++) {
                    const other = types[i];
                    if (!(other.flags & TypeFlags.EnumLiteral)
                        || (firstEnum !== getParentOfSymbol(other.symbol)))
                    {
                        return false;
                    }
                }
                return true;
            }

            return false;
        }

        function removeSubtypes(
            types: Type[],
            primitivesOnly: boolean
        ): boolean {
            const len = types.length;
            if (len === 0 || isSetOfLiteralsFromSameEnum(types)) {
                return true;
            }
            let i = len;
            let count = 0;
            while (i > 0) {
                i--;
                const source = types[i];
                for (const target of types) {
                    if (source !== target) {
                        if (count === 100000) {
                            // After 100000 subtype checks we estimate the remaining amount of work by assuming the
                            // same ratio of checks per element. If the estimated number of remaining type checks is
                            // greater than an upper limit we deem the union type too complex to represent. The
                            // upper limit is 25M for unions of primitives only, and 1M otherwise. This for example
                            // caps union types at 5000 unique literal types and 1000 unique object types.
                            const estimatedCount = (count / (len - i)) * len;
                            if (estimatedCount
                                > (primitivesOnly ? 25000000 : 1000000))
                            {
                                error(
                                    currentNode,
                                    Diagnostics
                                        .Expression_produces_a_union_type_that_is_too_complex_to_represent
                                );
                                return false;
                            }
                        }
                        count++;
                        if (isTypeRelatedTo(
                            source,
                            target,
                            strictSubtypeRelation
                        ) && (
                            !(getObjectFlags(getTargetType(source))
                                & ObjectFlags.Class)
                            || !(getObjectFlags(getTargetType(target))
                                & ObjectFlags.Class)
                            || isTypeDerivedFrom(source, target)
                        )) {
                            orderedRemoveItemAt(types, i);
                            break;
                        }
                    }
                }
            }
            return true;
        }

        function removeRedundantLiteralTypes(
            types: Type[],
            includes: TypeFlags
        ) {
            let i = types.length;
            while (i > 0) {
                i--;
                const t = types[i];
                const remove = t.flags & TypeFlags.StringLiteral
                    && includes & TypeFlags.String
                    || t.flags & TypeFlags.NumberLiteral
                    && includes & TypeFlags.Number
                    || t.flags & TypeFlags.BigIntLiteral
                    && includes & TypeFlags.BigInt
                    || t.flags & TypeFlags.UniqueESSymbol
                    && includes & TypeFlags.ESSymbol
                    || isFreshLiteralType(t)
                    && containsType(types, (<LiteralType> t).regularType);
                if (remove) {
                    orderedRemoveItemAt(types, i);
                }
            }
        }

        // We sort and deduplicate the constituent types based on object identity. If the subtypeReduction
        // flag is specified we also reduce the constituent type set to only include types that aren't subtypes
        // of other types. Subtype reduction is expensive for large union types and is possible only when union
        // types are known not to circularly reference themselves (as is the case with union types created by
        // expression constructs such as array literals and the || and ?: operators). Named types can
        // circularly reference themselves and therefore cannot be subtype reduced during their declaration.
        // For example, "type Item = string | (() => Item" is a named type that circularly references itself.
        function getUnionType(
            types: readonly Type[],
            unionReduction: UnionReduction = UnionReduction.Literal,
            aliasSymbol?: Symbol,
            aliasTypeArguments?: readonly Type[]
        ): Type {
            if (types.length === 0) {
                return neverType;
            }
            if (types.length === 1) {
                return types[0];
            }
            const typeSet: Type[] = [];
            const includes = addTypesToUnion(typeSet, 0, types);
            if (unionReduction !== UnionReduction.None) {
                if (includes & TypeFlags.AnyOrUnknown) {
                    return includes & TypeFlags.Any
                        ? includes & TypeFlags.IncludesWildcard
                            ? wildcardType
                            : anyType
                        : unknownType;
                }
                switch (unionReduction) {
                    case UnionReduction.Literal:
                        if (includes
                            & (TypeFlags.Literal | TypeFlags.UniqueESSymbol))
                        {
                            removeRedundantLiteralTypes(typeSet, includes);
                        }
                        break;
                    case UnionReduction.Subtype:
                        if (!removeSubtypes(
                            typeSet,
                            !(includes
                                & TypeFlags.IncludesStructuredOrInstantiable)
                        )) {
                            return errorType;
                        }
                        break;
                }
                if (typeSet.length === 0) {
                    return includes & TypeFlags.Null
                        ? includes & TypeFlags.IncludesNonWideningType
                            ? nullType
                            : nullWideningType
                        : includes & TypeFlags.Undefined
                            ? includes & TypeFlags.IncludesNonWideningType
                                ? undefinedType
                                : undefinedWideningType
                            : neverType;
                }
            }
            return getUnionTypeFromSortedList(
                typeSet,
                includes & TypeFlags.NotPrimitiveUnion
                    ? 0
                    : ObjectFlags.PrimitiveUnion,
                aliasSymbol,
                aliasTypeArguments
            );
        }

        function getUnionTypePredicate(
            signatures: readonly Signature[]
        ): TypePredicate | undefined {
            let first: TypePredicate | undefined;
            const types: Type[] = [];
            for (const sig of signatures) {
                const pred = getTypePredicateOfSignature(sig);
                if (!pred || pred.kind === TypePredicateKind.AssertsThis
                    || pred.kind === TypePredicateKind.AssertsIdentifier)
                {
                    continue;
                }

                if (first) {
                    if (!typePredicateKindsMatch(first, pred)) {
                        // No common type predicate.
                        return undefined;
                    }
                } else {
                    first = pred;
                }
                types.push(pred.type);
            }
            if (!first) {
                // No union signatures had a type predicate.
                return undefined;
            }
            const unionType = getUnionType(types);
            return createTypePredicate(
                first.kind,
                first.parameterName,
                first.parameterIndex,
                unionType
            );
        }

        function typePredicateKindsMatch(
            a: TypePredicate,
            b: TypePredicate
        ): boolean {
            return a.kind === b.kind && a.parameterIndex === b.parameterIndex;
        }

        // This function assumes the constituent type list is sorted and deduplicated.
        function getUnionTypeFromSortedList(
            types: Type[],
            objectFlags: ObjectFlags,
            aliasSymbol?: Symbol,
            aliasTypeArguments?: readonly Type[]
        ): Type {
            if (types.length === 0) {
                return neverType;
            }
            if (types.length === 1) {
                return types[0];
            }
            const id = getTypeListId(types);
            let type = unionTypes.get(id);
            if (!type) {
                type = <UnionType> createType(TypeFlags.Union);
                unionTypes.set(id, type);
                type
                    .objectFlags = objectFlags
                        | getPropagatingFlagsOfTypes(
                            types, /*excludeKinds*/
                            TypeFlags.Nullable
                        );
                type.types = types;
                /*
                Note: This is the alias symbol (or lack thereof) that we see when we first encounter this union type.
                For aliases of identical unions, eg `type T = A | B; type U = A | B`, the symbol of the first alias encountered is the aliasSymbol.
                (In the language service, the order may depend on the order in which a user takes actions, such as hovering over symbols.)
                It's important that we create equivalent union types only once, so that's an unfortunate side effect.
                */
                type.aliasSymbol = aliasSymbol;
                type.aliasTypeArguments = aliasTypeArguments;
            }
            return type;
        }

        function getTypeFromUnionTypeNode(node: UnionTypeNode): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                const aliasSymbol = getAliasSymbolForTypeNode(node);
                links
                    .resolvedType = getUnionType(
                        map(
                            node.types,
                            getTypeFromTypeNode
                        ),
                        UnionReduction.Literal,
                        aliasSymbol,
                        getTypeArgumentsForAliasSymbol(aliasSymbol)
                    );
            }
            return links.resolvedType;
        }

        function addTypeToIntersection(
            typeSet: Map<Type>,
            includes: TypeFlags,
            type: Type
        ) {
            const flags = type.flags;
            if (flags & TypeFlags.Intersection) {
                return addTypesToIntersection(
                    typeSet,
                    includes,
                    (<IntersectionType> type).types
                );
            }
            if (isEmptyAnonymousObjectType(type)) {
                if (!(includes & TypeFlags.IncludesEmptyObject)) {
                    includes |= TypeFlags.IncludesEmptyObject;
                    typeSet.set(type.id.toString(), type);
                }
            } else {
                if (flags & TypeFlags.AnyOrUnknown) {
                    if (type === wildcardType) {
                        includes |= TypeFlags.IncludesWildcard;
                    }
                } else if ((strictNullChecks || !(flags & TypeFlags.Nullable))
                    && !typeSet.has(type.id.toString()))
                {
                    if (type.flags & TypeFlags.Unit
                        && includes & TypeFlags.Unit)
                    {
                        // We have seen two distinct unit types which means we should reduce to an
                        // empty intersection. Adding TypeFlags.NonPrimitive causes that to happen.
                        includes |= TypeFlags.NonPrimitive;
                    }
                    typeSet.set(type.id.toString(), type);
                }
                includes |= flags & TypeFlags.IncludesMask;
            }
            return includes;
        }

        // Add the given types to the given type set. Order is preserved, freshness is removed from literal
        // types, duplicates are removed, and nested types of the given kind are flattened into the set.
        function addTypesToIntersection(
            typeSet: Map<Type>,
            includes: TypeFlags,
            types: readonly Type[]
        ) {
            for (const type of types) {
                includes = addTypeToIntersection(
                    typeSet,
                    includes,
                    getRegularTypeOfLiteralType(type)
                );
            }
            return includes;
        }

        function removeRedundantPrimitiveTypes(
            types: Type[],
            includes: TypeFlags
        ) {
            let i = types.length;
            while (i > 0) {
                i--;
                const t = types[i];
                const remove = t.flags & TypeFlags.String
                    && includes & TypeFlags.StringLiteral
                    || t.flags & TypeFlags.Number
                    && includes & TypeFlags.NumberLiteral
                    || t.flags & TypeFlags.BigInt
                    && includes & TypeFlags.BigIntLiteral
                    || t.flags & TypeFlags.ESSymbol
                    && includes & TypeFlags.UniqueESSymbol;
                if (remove) {
                    orderedRemoveItemAt(types, i);
                }
            }
        }

        // Check that the given type has a match in every union. A given type is matched by
        // an identical type, and a literal type is additionally matched by its corresponding
        // primitive type.
        function eachUnionContains(unionTypes: UnionType[], type: Type) {
            for (const u of unionTypes) {
                if (!containsType(u.types, type)) {
                    const primitive = type.flags & TypeFlags.StringLiteral
                        ? stringType
                        : type.flags & TypeFlags.NumberLiteral
                            ? numberType
                            : type.flags & TypeFlags.BigIntLiteral
                                ? bigintType
                                : type.flags & TypeFlags.UniqueESSymbol
                                    ? esSymbolType
                                    : undefined;
                    if (!primitive || !containsType(u.types, primitive)) {
                        return false;
                    }
                }
            }
            return true;
        }

        function extractIrreducible(types: Type[], flag: TypeFlags) {
            if (every(
                types,
                t => !!(t.flags & TypeFlags.Union)
                    && some((t as UnionType).types, tt => !!(tt.flags & flag))
            )) {
                for (let i = 0; i < types.length; i++) {
                    types[i] = filterType(types[i], t => !(t.flags & flag));
                }
                return true;
            }
            return false;
        }

        // If the given list of types contains more than one union of primitive types, replace the
        // first with a union containing an intersection of those primitive types, then remove the
        // other unions and return true. Otherwise, do nothing and return false.
        function intersectUnionsOfPrimitiveTypes(types: Type[]) {
            let unionTypes: UnionType[] | undefined;
            const index = findIndex(
                types,
                t => !!(getObjectFlags(t) & ObjectFlags.PrimitiveUnion)
            );
            if (index < 0) {
                return false;
            }
            let i = index + 1;
            // Remove all but the first union of primitive types and collect them in
            // the unionTypes array.
            while (i < types.length) {
                const t = types[i];
                if (getObjectFlags(t) & ObjectFlags.PrimitiveUnion) {
                    (unionTypes || (unionTypes = [<UnionType> types[index]]))
                        .push(<UnionType> t);
                    orderedRemoveItemAt(types, i);
                } else {
                    i++;
                }
            }
            // Return false if there was only one union of primitive types
            if (!unionTypes) {
                return false;
            }
            // We have more than one union of primitive types, now intersect them. For each
            // type in each union we check if the type is matched in every union and if so
            // we include it in the result.
            const checked: Type[] = [];
            const result: Type[] = [];
            for (const u of unionTypes) {
                for (const t of u.types) {
                    if (insertType(checked, t)) {
                        if (eachUnionContains(unionTypes, t)) {
                            insertType(result, t);
                        }
                    }
                }
            }
            // Finally replace the first union with the result
            types[index] = getUnionTypeFromSortedList(
                result,
                ObjectFlags.PrimitiveUnion
            );
            return true;
        }

        function createIntersectionType(
            types: Type[],
            aliasSymbol?: Symbol,
            aliasTypeArguments?: readonly Type[]
        ) {
            const result = <IntersectionType> createType(
                TypeFlags.Intersection
            );
            result
                .objectFlags = getPropagatingFlagsOfTypes(
                    types, /*excludeKinds*/
                    TypeFlags.Nullable
                );
            result.types = types;
            result
                .aliasSymbol = aliasSymbol; // See comment in `getUnionTypeFromSortedList`.
            result.aliasTypeArguments = aliasTypeArguments;
            return result;
        }

        // We normalize combinations of intersection and union types based on the distributive property of the '&'
        // operator. Specifically, because X & (A | B) is equivalent to X & A | X & B, we can transform intersection
        // types with union type constituents into equivalent union types with intersection type constituents and
        // effectively ensure that union types are always at the top level in type representations.
        //
        // We do not perform structural deduplication on intersection types. Intersection types are created only by the &
        // type operator and we can't reduce those because we want to support recursive intersection types. For example,
        // a type alias of the form "type List<T> = T & { next: List<T> }" cannot be reduced during its declaration.
        // Also, unlike union types, the order of the constituent types is preserved in order that overload resolution
        // for intersections of types with signatures can be deterministic.
        function getIntersectionType(
            types: readonly Type[],
            aliasSymbol?: Symbol,
            aliasTypeArguments?: readonly Type[]
        ): Type {
            const typeMembershipMap: Map<Type> = createMap();
            const includes = addTypesToIntersection(
                typeMembershipMap,
                0,
                types
            );
            const typeSet: Type[] = arrayFrom(typeMembershipMap.values());
            // An intersection type is considered empty if it contains
            // the type never, or
            // more than one unit type or,
            // an object type and a nullable type (null or undefined), or
            // a string-like type and a type known to be non-string-like, or
            // a number-like type and a type known to be non-number-like, or
            // a symbol-like type and a type known to be non-symbol-like, or
            // a void-like type and a type known to be non-void-like, or
            // a non-primitive type and a type known to be primitive.
            if (includes & TypeFlags.Never
                || strictNullChecks && includes & TypeFlags.Nullable
                && includes
                & (TypeFlags.Object | TypeFlags.NonPrimitive
                    | TypeFlags.IncludesEmptyObject)
                || includes & TypeFlags.NonPrimitive
                && includes
                & (TypeFlags.DisjointDomains & ~TypeFlags.NonPrimitive)
                || includes & TypeFlags.StringLike
                && includes
                & (TypeFlags.DisjointDomains & ~TypeFlags.StringLike)
                || includes & TypeFlags.NumberLike
                && includes
                & (TypeFlags.DisjointDomains & ~TypeFlags.NumberLike)
                || includes & TypeFlags.BigIntLike
                && includes
                & (TypeFlags.DisjointDomains & ~TypeFlags.BigIntLike)
                || includes & TypeFlags.ESSymbolLike
                && includes
                & (TypeFlags.DisjointDomains & ~TypeFlags.ESSymbolLike)
                || includes & TypeFlags.VoidLike
                && includes
                & (TypeFlags.DisjointDomains & ~TypeFlags.VoidLike))
            {
                return neverType;
            }
            if (includes & TypeFlags.Any) {
                return includes & TypeFlags.IncludesWildcard
                    ? wildcardType
                    : anyType;
            }
            if (!strictNullChecks && includes & TypeFlags.Nullable) {
                return includes & TypeFlags.Undefined
                    ? undefinedType
                    : nullType;
            }
            if (includes & TypeFlags.String
                && includes & TypeFlags.StringLiteral
                || includes & TypeFlags.Number
                && includes & TypeFlags.NumberLiteral
                || includes & TypeFlags.BigInt
                && includes & TypeFlags.BigIntLiteral
                || includes & TypeFlags.ESSymbol
                && includes & TypeFlags.UniqueESSymbol)
            {
                removeRedundantPrimitiveTypes(typeSet, includes);
            }
            if (includes & TypeFlags.IncludesEmptyObject
                && includes & TypeFlags.Object)
            {
                orderedRemoveItemAt(
                    typeSet,
                    findIndex(typeSet, isEmptyAnonymousObjectType)
                );
            }
            if (typeSet.length === 0) {
                return unknownType;
            }
            if (typeSet.length === 1) {
                return typeSet[0];
            }
            const id = getTypeListId(typeSet);
            let result = intersectionTypes.get(id);
            if (!result) {
                if (includes & TypeFlags.Union) {
                    if (intersectUnionsOfPrimitiveTypes(typeSet)) {
                        // When the intersection creates a reduced set (which might mean that *all* union types have
                        // disappeared), we restart the operation to get a new set of combined flags. Once we have
                        // reduced we'll never reduce again, so this occurs at most once.
                        result = getIntersectionType(
                            typeSet,
                            aliasSymbol,
                            aliasTypeArguments
                        );
                    } else if (extractIrreducible(typeSet,
                        TypeFlags.Undefined))
                    {
                        result = getUnionType(
                            [getIntersectionType(typeSet), undefinedType],
                            UnionReduction.Literal,
                            aliasSymbol,
                            aliasTypeArguments
                        );
                    } else if (extractIrreducible(typeSet, TypeFlags.Null)) {
                        result = getUnionType(
                            [getIntersectionType(typeSet), nullType],
                            UnionReduction.Literal,
                            aliasSymbol,
                            aliasTypeArguments
                        );
                    } else {
                        // We are attempting to construct a type of the form X & (A | B) & Y. Transform this into a type of
                        // the form X & A & Y | X & B & Y and recursively reduce until no union type constituents remain.
                        // If the estimated size of the resulting union type exceeds 100000 constituents, report an error.
                        const size = reduceLeft(
                            typeSet,
                            (n, t) => n * (t.flags & TypeFlags.Union
                                ? (<UnionType> t).types.length
                                : 1),
                            1
                        );
                        if (size >= 100000) {
                            error(
                                currentNode,
                                Diagnostics
                                    .Expression_produces_a_union_type_that_is_too_complex_to_represent
                            );
                            return errorType;
                        }
                        const unionIndex = findIndex(
                            typeSet,
                            t => (t.flags & TypeFlags.Union) !== 0
                        );
                        const unionType = <UnionType> typeSet[unionIndex];
                        result = getUnionType(
                            map(
                                unionType.types,
                                t => getIntersectionType(
                                    replaceElement(
                                        typeSet,
                                        unionIndex,
                                        t
                                    )
                                )
                            ),
                            UnionReduction.Literal,
                            aliasSymbol,
                            aliasTypeArguments
                        );
                    }
                } else {
                    result = createIntersectionType(
                        typeSet,
                        aliasSymbol,
                        aliasTypeArguments
                    );
                }
                intersectionTypes.set(id, result);
            }
            return result;
        }

        function getTypeFromIntersectionTypeNode(
            node: IntersectionTypeNode
        ): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                const aliasSymbol = getAliasSymbolForTypeNode(node);
                links
                    .resolvedType = getIntersectionType(
                        map(
                            node.types,
                            getTypeFromTypeNode
                        ),
                        aliasSymbol,
                        getTypeArgumentsForAliasSymbol(aliasSymbol)
                    );
            }
            return links.resolvedType;
        }

        function createIndexType(
            type: InstantiableType | UnionOrIntersectionType,
            stringsOnly: boolean
        ) {
            const result = <IndexType> createType(TypeFlags.Index);
            result.type = type;
            result.stringsOnly = stringsOnly;
            return result;
        }

        function getIndexTypeForGenericType(
            type: InstantiableType | UnionOrIntersectionType,
            stringsOnly: boolean
        ) {
            return stringsOnly
                ? type.resolvedStringIndexType
                    || (type.resolvedStringIndexType = createIndexType(
                        type, /*stringsOnly*/
                        true
                    ))
                : type.resolvedIndexType
                    || (type.resolvedIndexType = createIndexType(
                        type, /*stringsOnly*/
                        false
                    ));
        }

        function getLiteralTypeFromPropertyName(name: PropertyName) {
            if (isPrivateIdentifier(name)) {
                return neverType;
            }
            return isIdentifier(name)
                ? getLiteralType(unescapeLeadingUnderscores(name.escapedText))
                : getRegularTypeOfLiteralType(
                    isComputedPropertyName(name)
                        ? checkComputedPropertyName(name)
                        : checkExpression(name)
                );
        }

        function getBigIntLiteralType(node: BigIntLiteral): LiteralType {
            return getLiteralType(
                {
                    negative: false,
                    base10Value: parsePseudoBigInt(node.text)
                }
            );
        }

        function getLiteralTypeFromProperty(prop: Symbol, include: TypeFlags) {
            if (!(getDeclarationModifierFlagsFromSymbol(prop)
                & ModifierFlags.NonPublicAccessibilityModifier))
            {
                let type = getLateBoundSymbol(prop).nameType;
                if (!type && !isKnownSymbol(prop)) {
                    if (prop.escapedName === InternalSymbolName.Default) {
                        type = getLiteralType('default');
                    } else {
                        const name = prop.valueDeclaration
                            && getNameOfDeclaration(prop
                                .valueDeclaration) as PropertyName;
                        type = name && getLiteralTypeFromPropertyName(name)
                            || getLiteralType(symbolName(prop));
                    }
                }
                if (type && type.flags & include) {
                    return type;
                }
            }
            return neverType;
        }

        function getLiteralTypeFromProperties(type: Type, include: TypeFlags) {
            return getUnionType(
                map(
                    getPropertiesOfType(type),
                    p => getLiteralTypeFromProperty(p, include)
                )
            );
        }

        function getNonEnumNumberIndexInfo(type: Type) {
            const numberIndexInfo = getIndexInfoOfType(type, IndexKind.Number);
            return numberIndexInfo !== enumNumberIndexInfo
                ? numberIndexInfo
                : undefined;
        }

        function getIndexType(
            type: Type,
            stringsOnly = keyofStringsOnly,
            noIndexSignatures?: boolean
        ): Type {
            return type.flags & TypeFlags.Union
                ? getIntersectionType(
                    map(
                        (<IntersectionType> type).types,
                        t => getIndexType(t, stringsOnly, noIndexSignatures)
                    )
                )
                : type.flags & TypeFlags.Intersection
                    ? getUnionType(
                        map(
                            (<IntersectionType> type).types,
                            t => getIndexType(
                                t,
                                stringsOnly,
                                noIndexSignatures
                            )
                        )
                    )
                    : maybeTypeOfKind(type, TypeFlags.InstantiableNonPrimitive)
                        ? getIndexTypeForGenericType(<InstantiableType
                            | UnionOrIntersectionType> type, stringsOnly)
                        : getObjectFlags(type) & ObjectFlags.Mapped
                            ? filterType(
                                getConstraintTypeFromMappedType(<MappedType> type),
                                t => !(noIndexSignatures
                                    && t.flags
                                    & (TypeFlags.Any | TypeFlags.String))
                            )
                            : type === wildcardType
                                ? wildcardType
                                : type.flags & TypeFlags.Unknown
                                    ? neverType
                                    : type.flags
                                        & (TypeFlags.Any | TypeFlags.Never)
                                        ? keyofConstraintType
                                        : stringsOnly
                                            ? !noIndexSignatures
                                                && getIndexInfoOfType(
                                                    type,
                                                    IndexKind.String
                                                )
                                                ? stringType
                                                : getLiteralTypeFromProperties(
                                                    type,
                                                    TypeFlags.StringLiteral
                                                )
                                            : !noIndexSignatures
                                                && getIndexInfoOfType(
                                                    type,
                                                    IndexKind.String
                                                )
                                                ? getUnionType(
                                                    [stringType, numberType,
                                                        getLiteralTypeFromProperties(
                                                            type,
                                                            TypeFlags
                                                                .UniqueESSymbol
                                                        )]
                                                )
                                                : getNonEnumNumberIndexInfo(type)
                                                    ? getUnionType(
                                                        [numberType,
                                                            getLiteralTypeFromProperties(
                                                                type,
                                                                TypeFlags
                                                                    .StringLiteral
                                                                    | TypeFlags
                                                                        .UniqueESSymbol
                                                            )]
                                                    )
                                                    : getLiteralTypeFromProperties(
                                                        type,
                                                        TypeFlags
                                                            .StringOrNumberLiteralOrUnique
                                                    );
        }

        function getExtractStringType(type: Type) {
            if (keyofStringsOnly) {
                return type;
            }
            const extractTypeAlias = getGlobalExtractSymbol();
            return extractTypeAlias
                ? getTypeAliasInstantiation(
                    extractTypeAlias,
                    [type, stringType]
                )
                : stringType;
        }

        function getIndexTypeOrString(type: Type): Type {
            const indexType = getExtractStringType(getIndexType(type));
            return indexType.flags & TypeFlags.Never ? stringType : indexType;
        }

        function getTypeFromTypeOperatorNode(node: TypeOperatorNode): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                switch (node.operator) {
                    case SyntaxKind.KeyOfKeyword:
                        links
                            .resolvedType = getIndexType(
                                getTypeFromTypeNode(
                                    node.type
                                )
                            );
                        break;
                    case SyntaxKind.UniqueKeyword:
                        links
                            .resolvedType = node.type.kind
                                === SyntaxKind.SymbolKeyword
                                ? getESSymbolLikeTypeForNode(
                                    walkUpParenthesizedTypes(
                                        node.parent
                                    )
                                )
                                : errorType;
                        break;
                    case SyntaxKind.ReadonlyKeyword:
                        links.resolvedType = getTypeFromTypeNode(node.type);
                        break;
                    default:
                        throw Debug.assertNever(node.operator);
                }
            }
            return links.resolvedType;
        }

        function createIndexedAccessType(objectType: Type, indexType: Type) {
            const type = <IndexedAccessType> createType(
                TypeFlags.IndexedAccess
            );
            type.objectType = objectType;
            type.indexType = indexType;
            return type;
        }

        /**
         * Returns if a type is or consists of a JSLiteral object type
         * In addition to objects which are directly literals,
         * * unions where every element is a jsliteral
         * * intersections where at least one element is a jsliteral
         * * and instantiable types constrained to a jsliteral
         * Should all count as literals and not print errors on access or assignment of possibly existing properties.
         * This mirrors the behavior of the index signature propagation, to which this behaves similarly (but doesn't affect assignability or inference).
         */
        function isJSLiteralType(type: Type): boolean {
            if (noImplicitAny) {
                return false; // Flag is meaningless under `noImplicitAny` mode
            }
            if (getObjectFlags(type) & ObjectFlags.JSLiteral) {
                return true;
            }
            if (type.flags & TypeFlags.Union) {
                return every((type as UnionType).types, isJSLiteralType);
            }
            if (type.flags & TypeFlags.Intersection) {
                return some((type as IntersectionType).types, isJSLiteralType);
            }
            if (type.flags & TypeFlags.Instantiable) {
                return isJSLiteralType(getResolvedBaseConstraint(type));
            }
            return false;
        }

        function getPropertyNameFromIndex(
            indexType: Type,
            accessNode: StringLiteral | Identifier | PrivateIdentifier
                | ObjectBindingPattern | ArrayBindingPattern
                | ComputedPropertyName | NumericLiteral | IndexedAccessTypeNode
                | ElementAccessExpression | SyntheticExpression | undefined
        ) {
            const accessExpression = accessNode
                && accessNode.kind === SyntaxKind.ElementAccessExpression
                ? accessNode
                : undefined;
            return isTypeUsableAsPropertyName(indexType)
                ? getPropertyNameFromType(indexType)
                : accessExpression
                    && checkThatExpressionIsProperSymbolReference(
                        accessExpression.argumentExpression,
                        indexType, /*reportError*/
                        false
                    )
                    ? getPropertyNameForKnownSymbolName(
                        idText(
                            (<PropertyAccessExpression> accessExpression
                                .argumentExpression).name
                        )
                    )
                    : accessNode && isPropertyName(accessNode)
                        ? // late bound names are handled in the first branch, so here we only need to handle normal names
                        getPropertyNameForPropertyNameNode(accessNode)
                        : undefined;
        }

        function getPropertyTypeForIndexType(
            originalObjectType: Type,
            objectType: Type,
            indexType: Type,
            fullIndexType: Type,
            suppressNoImplicitAnyError: boolean,
            accessNode: ElementAccessExpression | IndexedAccessTypeNode
                | PropertyName | BindingName | SyntheticExpression | undefined,
            accessFlags: AccessFlags
        ) {
            const accessExpression = accessNode
                && accessNode.kind === SyntaxKind.ElementAccessExpression
                ? accessNode
                : undefined;
            const propName = accessNode && isPrivateIdentifier(accessNode)
                ? undefined
                : getPropertyNameFromIndex(indexType, accessNode);
            if (propName !== undefined) {
                const prop = getPropertyOfType(objectType, propName);
                if (prop) {
                    if (accessExpression) {
                        markPropertyAsReferenced(
                            prop,
                            accessExpression, /*isThisAccess*/
                            accessExpression.expression.kind
                                === SyntaxKind.ThisKeyword
                        );
                        if (isAssignmentToReadonlyEntity(
                            accessExpression,
                            prop,
                            getAssignmentTargetKind(accessExpression)
                        )) {
                            error(
                                accessExpression.argumentExpression,
                                Diagnostics
                                    .Cannot_assign_to_0_because_it_is_a_read_only_property,
                                symbolToString(prop)
                            );
                            return undefined;
                        }
                        if (accessFlags & AccessFlags.CacheSymbol) {
                            getNodeLinks(accessNode!).resolvedSymbol = prop;
                        }
                    }
                    const propType = getTypeOfSymbol(prop);
                    return accessExpression
                        && getAssignmentTargetKind(accessExpression)
                        !== AssignmentKind.Definite
                        ? getFlowTypeOfReference(accessExpression, propType)
                        : propType;
                }
                if (everyType(objectType, isTupleType)
                    && isNumericLiteralName(propName) && +propName >= 0)
                {
                    if (accessNode
                        && everyType(
                            objectType,
                            t => !(<TupleTypeReference> t).target
                                .hasRestElement
                        ) && !(accessFlags & AccessFlags.NoTupleBoundsCheck))
                    {
                        const indexNode = getIndexNodeForAccessExpression(accessNode);
                        if (isTupleType(objectType)) {
                            error(
                                indexNode,
                                Diagnostics
                                    .Tuple_type_0_of_length_1_has_no_element_at_index_2,
                                typeToString(objectType),
                                getTypeReferenceArity(objectType),
                                unescapeLeadingUnderscores(propName)
                            );
                        } else {
                            error(
                                indexNode,
                                Diagnostics
                                    .Property_0_does_not_exist_on_type_1,
                                unescapeLeadingUnderscores(propName),
                                typeToString(objectType)
                            );
                        }
                    }
                    errorIfWritingToReadonlyIndex(
                        getIndexInfoOfType(
                            objectType,
                            IndexKind.Number
                        )
                    );
                    return mapType(
                        objectType,
                        t => getRestTypeOfTupleType(<TupleTypeReference> t)
                            || undefinedType
                    );
                }
            }
            if (!(indexType.flags & TypeFlags.Nullable)
                && isTypeAssignableToKind(
                    indexType,
                    TypeFlags.StringLike | TypeFlags.NumberLike
                        | TypeFlags.ESSymbolLike
                ))
            {
                if (objectType.flags & (TypeFlags.Any | TypeFlags.Never)) {
                    return objectType;
                }
                const stringIndexInfo = getIndexInfoOfType(
                    objectType,
                    IndexKind.String
                );
                const indexInfo = isTypeAssignableToKind(
                    indexType,
                    TypeFlags.NumberLike
                ) && getIndexInfoOfType(objectType, IndexKind.Number)
                    || stringIndexInfo;
                if (indexInfo) {
                    if (accessFlags & AccessFlags.NoIndexSignatures
                        && indexInfo === stringIndexInfo)
                    {
                        if (accessExpression) {
                            error(
                                accessExpression,
                                Diagnostics
                                    .Type_0_cannot_be_used_to_index_type_1,
                                typeToString(indexType),
                                typeToString(originalObjectType)
                            );
                        }
                        return undefined;
                    }
                    if (accessNode
                        && !isTypeAssignableToKind(
                            indexType,
                            TypeFlags.String | TypeFlags.Number
                        ))
                    {
                        const indexNode = getIndexNodeForAccessExpression(accessNode);
                        error(
                            indexNode,
                            Diagnostics.Type_0_cannot_be_used_as_an_index_type,
                            typeToString(indexType)
                        );
                        return indexInfo.type;
                    }
                    errorIfWritingToReadonlyIndex(indexInfo);
                    return indexInfo.type;
                }
                if (indexType.flags & TypeFlags.Never) {
                    return neverType;
                }
                if (isJSLiteralType(objectType)) {
                    return anyType;
                }
                if (accessExpression && !isConstEnumObjectType(objectType)) {
                    if (objectType.symbol === globalThisSymbol
                        && propName !== undefined
                        && globalThisSymbol.exports!.has(propName)
                        && (globalThisSymbol.exports!.get(propName)!.flags
                            & SymbolFlags.BlockScoped))
                    {
                        error(
                            accessExpression,
                            Diagnostics.Property_0_does_not_exist_on_type_1,
                            unescapeLeadingUnderscores(propName),
                            typeToString(objectType)
                        );
                    } else if (noImplicitAny
                        && !compilerOptions.suppressImplicitAnyIndexErrors
                        && !suppressNoImplicitAnyError)
                    {
                        if (propName !== undefined
                            && typeHasStaticProperty(propName, objectType))
                        {
                            error(
                                accessExpression,
                                Diagnostics
                                    .Property_0_is_a_static_member_of_type_1,
                                propName as string,
                                typeToString(objectType)
                            );
                        } else if (getIndexTypeOfType(
                            objectType,
                            IndexKind.Number
                        )) {
                            error(
                                accessExpression.argumentExpression,
                                Diagnostics
                                    .Element_implicitly_has_an_any_type_because_index_expression_is_not_of_type_number
                            );
                        } else {
                            let suggestion: string | undefined;
                            if (propName !== undefined
                                && (suggestion = getSuggestionForNonexistentProperty(
                                    propName as string,
                                    objectType
                                )))
                            {
                                if (suggestion !== undefined) {
                                    error(
                                        accessExpression.argumentExpression,
                                        Diagnostics
                                            .Property_0_does_not_exist_on_type_1_Did_you_mean_2,
                                        propName as string,
                                        typeToString(objectType),
                                        suggestion
                                    );
                                }
                            } else {
                                const suggestion = getSuggestionForNonexistentIndexSignature(
                                    objectType,
                                    accessExpression,
                                    indexType
                                );
                                if (suggestion !== undefined) {
                                    error(
                                        accessExpression,
                                        Diagnostics
                                            .Element_implicitly_has_an_any_type_because_type_0_has_no_index_signature_Did_you_mean_to_call_1,
                                        typeToString(objectType),
                                        suggestion
                                    );
                                } else {
                                    let errorInfo: DiagnosticMessageChain
                                        | undefined;
                                    if (indexType.flags
                                        & TypeFlags.EnumLiteral)
                                    {
                                        errorInfo = chainDiagnosticMessages(
                                            /* details */ undefined,
                                            Diagnostics
                                                .Property_0_does_not_exist_on_type_1,
                                            '[' + typeToString(indexType)
                                                + ']',
                                            typeToString(objectType)
                                        );
                                    } else if (indexType.flags
                                        & TypeFlags.UniqueESSymbol)
                                    {
                                        const symbolName = getFullyQualifiedName(
                                            (indexType as UniqueESSymbolType)
                                                .symbol,
                                            accessExpression
                                        );
                                        errorInfo = chainDiagnosticMessages(
                                            /* details */ undefined,
                                            Diagnostics
                                                .Property_0_does_not_exist_on_type_1,
                                            '[' + symbolName + ']',
                                            typeToString(objectType)
                                        );
                                    } else if (indexType.flags
                                        & TypeFlags.StringLiteral)
                                    {
                                        errorInfo = chainDiagnosticMessages(
                                            /* details */ undefined,
                                            Diagnostics
                                                .Property_0_does_not_exist_on_type_1,
                                            (indexType as StringLiteralType)
                                                .value,
                                            typeToString(objectType)
                                        );
                                    } else if (indexType.flags
                                        & TypeFlags.NumberLiteral)
                                    {
                                        errorInfo = chainDiagnosticMessages(
                                            /* details */ undefined,
                                            Diagnostics
                                                .Property_0_does_not_exist_on_type_1,
                                            (indexType as NumberLiteralType)
                                                .value,
                                            typeToString(objectType)
                                        );
                                    } else if (indexType.flags
                                        & (TypeFlags.Number
                                            | TypeFlags.String))
                                    {
                                        errorInfo = chainDiagnosticMessages(
                                            /* details */ undefined,
                                            Diagnostics
                                                .No_index_signature_with_a_parameter_of_type_0_was_found_on_type_1,
                                            typeToString(indexType),
                                            typeToString(objectType)
                                        );
                                    }

                                    errorInfo = chainDiagnosticMessages(
                                        errorInfo,
                                        Diagnostics
                                            .Element_implicitly_has_an_any_type_because_expression_of_type_0_can_t_be_used_to_index_type_1,
                                        typeToString(fullIndexType),
                                        typeToString(objectType)
                                    );
                                    diagnostics
                                        .add(
                                            createDiagnosticForNodeFromMessageChain(
                                                accessExpression,
                                                errorInfo
                                            )
                                        );
                                }
                            }
                        }
                    }
                    return undefined;
                }
            }
            if (isJSLiteralType(objectType)) {
                return anyType;
            }
            if (accessNode) {
                const indexNode = getIndexNodeForAccessExpression(accessNode);
                if (indexType.flags
                    & (TypeFlags.StringLiteral | TypeFlags.NumberLiteral))
                {
                    error(
                        indexNode,
                        Diagnostics.Property_0_does_not_exist_on_type_1,
                        ''
                            + (<StringLiteralType
                                | NumberLiteralType> indexType).value,
                        typeToString(objectType)
                    );
                } else if (indexType.flags
                    & (TypeFlags.String | TypeFlags.Number))
                {
                    error(
                        indexNode,
                        Diagnostics
                            .Type_0_has_no_matching_index_signature_for_type_1,
                        typeToString(objectType),
                        typeToString(indexType)
                    );
                } else {
                    error(
                        indexNode,
                        Diagnostics.Type_0_cannot_be_used_as_an_index_type,
                        typeToString(indexType)
                    );
                }
            }
            if (isTypeAny(indexType)) {
                return indexType;
            }
            return undefined;

            function errorIfWritingToReadonlyIndex(
                indexInfo: IndexInfo | undefined
            ): void {
                if (indexInfo && indexInfo.isReadonly && accessExpression
                    && (isAssignmentTarget(accessExpression)
                        || isDeleteTarget(accessExpression)))
                {
                    error(
                        accessExpression,
                        Diagnostics
                            .Index_signature_in_type_0_only_permits_reading,
                        typeToString(objectType)
                    );
                }
            }
        }

        function getIndexNodeForAccessExpression(
            accessNode: ElementAccessExpression | IndexedAccessTypeNode
                | PropertyName | BindingName | SyntheticExpression
        ) {
            return accessNode.kind === SyntaxKind.ElementAccessExpression
                ? accessNode.argumentExpression
                : accessNode.kind === SyntaxKind.IndexedAccessType
                    ? accessNode.indexType
                    : accessNode.kind === SyntaxKind.ComputedPropertyName
                        ? accessNode.expression
                        : accessNode;
        }

        function isGenericObjectType(type: Type): boolean {
            return maybeTypeOfKind(
                type,
                TypeFlags.InstantiableNonPrimitive
                    | TypeFlags.GenericMappedType
            );
        }

        function isGenericIndexType(type: Type): boolean {
            return maybeTypeOfKind(
                type,
                TypeFlags.InstantiableNonPrimitive | TypeFlags.Index
            );
        }

        function isThisTypeParameter(type: Type): boolean {
            return !!(type.flags & TypeFlags.TypeParameter
                && (<TypeParameter> type).isThisType);
        }

        function getSimplifiedType(type: Type, writing: boolean): Type {
            return type.flags & TypeFlags.IndexedAccess
                ? getSimplifiedIndexedAccessType(
                    <IndexedAccessType> type,
                    writing
                )
                : type.flags & TypeFlags.Conditional
                    ? getSimplifiedConditionalType(
                        <ConditionalType> type,
                        writing
                    )
                    : type;
        }

        function distributeIndexOverObjectType(
            objectType: Type,
            indexType: Type,
            writing: boolean
        ) {
            // (T | U)[K] -> T[K] | U[K] (reading)
            // (T | U)[K] -> T[K] & U[K] (writing)
            // (T & U)[K] -> T[K] & U[K]
            if (objectType.flags & TypeFlags.UnionOrIntersection) {
                const types = map(
                    (objectType as UnionOrIntersectionType).types,
                    t => getSimplifiedType(
                        getIndexedAccessType(t, indexType),
                        writing
                    )
                );
                return objectType.flags & TypeFlags.Intersection || writing
                    ? getIntersectionType(types)
                    : getUnionType(types);
            }
        }

        function distributeObjectOverIndexType(
            objectType: Type,
            indexType: Type,
            writing: boolean
        ) {
            // T[A | B] -> T[A] | T[B] (reading)
            // T[A | B] -> T[A] & T[B] (writing)
            if (indexType.flags & TypeFlags.Union) {
                const types = map(
                    (indexType as UnionType).types,
                    t => getSimplifiedType(
                        getIndexedAccessType(objectType, t),
                        writing
                    )
                );
                return writing
                    ? getIntersectionType(types)
                    : getUnionType(types);
            }
        }

        // Transform an indexed access to a simpler form, if possible. Return the simpler form, or return
        // the type itself if no transformation is possible. The writing flag indicates that the type is
        // the target of an assignment.
        function getSimplifiedIndexedAccessType(
            type: IndexedAccessType,
            writing: boolean
        ): Type {
            const cache = writing
                ? 'simplifiedForWriting'
                : 'simplifiedForReading';
            if (type[cache]) {
                return type[cache] === circularConstraintType
                    ? type
                    : type[cache]!;
            }
            type[cache] = circularConstraintType;
            // We recursively simplify the object type as it may in turn be an indexed access type. For example, with
            // '{ [P in T]: { [Q in U]: number } }[T][U]' we want to first simplify the inner indexed access type.
            const objectType = getSimplifiedType(type.objectType, writing);
            const indexType = getSimplifiedType(type.indexType, writing);
            // T[A | B] -> T[A] | T[B] (reading)
            // T[A | B] -> T[A] & T[B] (writing)
            const distributedOverIndex = distributeObjectOverIndexType(
                objectType,
                indexType,
                writing
            );
            if (distributedOverIndex) {
                return type[cache] = distributedOverIndex;
            }
            // Only do the inner distributions if the index can no longer be instantiated to cause index distribution again
            if (!(indexType.flags & TypeFlags.Instantiable)) {
                // (T | U)[K] -> T[K] | U[K] (reading)
                // (T | U)[K] -> T[K] & U[K] (writing)
                // (T & U)[K] -> T[K] & U[K]
                const distributedOverObject = distributeIndexOverObjectType(
                    objectType,
                    indexType,
                    writing
                );
                if (distributedOverObject) {
                    return type[cache] = distributedOverObject;
                }
            }
            // So ultimately (reading):
            // ((A & B) | C)[K1 | K2] -> ((A & B) | C)[K1] | ((A & B) | C)[K2] -> (A & B)[K1] | C[K1] | (A & B)[K2] | C[K2] -> (A[K1] & B[K1]) | C[K1] | (A[K2] & B[K2]) | C[K2]

            // If the object type is a mapped type { [P in K]: E }, where K is generic, instantiate E using a mapper
            // that substitutes the index type for P. For example, for an index access { [P in K]: Box<T[P]> }[X], we
            // construct the type Box<T[X]>.
            if (isGenericMappedType(objectType)) {
                return type
                    [cache] = mapType(
                        substituteIndexedMappedType(
                            objectType,
                            type.indexType
                        ),
                        t => getSimplifiedType(t, writing)
                    );
            }
            return type[cache] = type;
        }

        function getSimplifiedConditionalType(
            type: ConditionalType,
            writing: boolean
        ) {
            const checkType = type.checkType;
            const extendsType = type.extendsType;
            const trueType = getTrueTypeFromConditionalType(type);
            const falseType = getFalseTypeFromConditionalType(type);
            // Simplifications for types of the form `T extends U ? T : never` and `T extends U ? never : T`.
            if (falseType.flags & TypeFlags.Never
                && getActualTypeVariable(trueType)
                === getActualTypeVariable(checkType))
            {
                if (checkType.flags & TypeFlags.Any
                    || isTypeAssignableTo(
                        getRestrictiveInstantiation(checkType),
                        getRestrictiveInstantiation(extendsType)
                    ))
                { // Always true
                    return getSimplifiedType(trueType, writing);
                } else if (isIntersectionEmpty(checkType,
                    extendsType))
                { // Always false
                    return neverType;
                }
            } else if (trueType.flags & TypeFlags.Never
                && getActualTypeVariable(falseType)
                === getActualTypeVariable(checkType))
            {
                if (!(checkType.flags & TypeFlags.Any)
                    && isTypeAssignableTo(
                        getRestrictiveInstantiation(checkType),
                        getRestrictiveInstantiation(extendsType)
                    ))
                { // Always true
                    return neverType;
                } else if (checkType.flags & TypeFlags.Any
                    || isIntersectionEmpty(checkType,
                        extendsType))
                { // Always false
                    return getSimplifiedType(falseType, writing);
                }
            }
            return type;
        }

        /**
         * Invokes union simplification logic to determine if an intersection is considered empty as a union constituent
         */
        function isIntersectionEmpty(type1: Type, type2: Type) {
            return !!(getUnionType([intersectTypes(type1, type2), neverType])
                .flags & TypeFlags.Never);
        }

        function substituteIndexedMappedType(
            objectType: MappedType,
            index: Type
        ) {
            const mapper = createTypeMapper(
                [getTypeParameterFromMappedType(objectType)],
                [index]
            );
            const templateMapper = combineTypeMappers(
                objectType.mapper,
                mapper
            );
            return instantiateType(
                getTemplateTypeFromMappedType(objectType),
                templateMapper
            );
        }

        function getIndexedAccessType(
            objectType: Type,
            indexType: Type,
            accessNode?: ElementAccessExpression | IndexedAccessTypeNode
                | PropertyName | BindingName | SyntheticExpression
        ): Type {
            return getIndexedAccessTypeOrUndefined(
                objectType,
                indexType,
                accessNode,
                AccessFlags.None
            ) || (accessNode ? errorType : unknownType);
        }

        function getIndexedAccessTypeOrUndefined(
            objectType: Type,
            indexType: Type,
            accessNode?: ElementAccessExpression | IndexedAccessTypeNode
                | PropertyName | BindingName | SyntheticExpression,
            accessFlags = AccessFlags.None
        ): Type | undefined {
            if (objectType === wildcardType || indexType === wildcardType) {
                return wildcardType;
            }
            // If the object type has a string index signature and no other members we know that the result will
            // always be the type of that index signature and we can simplify accordingly.
            if (isStringIndexSignatureOnlyType(objectType)
                && !(indexType.flags & TypeFlags.Nullable)
                && isTypeAssignableToKind(
                    indexType,
                    TypeFlags.String | TypeFlags.Number
                ))
            {
                indexType = stringType;
            }
            // If the index type is generic, or if the object type is generic and doesn't originate in an expression,
            // we are performing a higher-order index access where we cannot meaningfully access the properties of the
            // object type. Note that for a generic T and a non-generic K, we eagerly resolve T[K] if it originates in
            // an expression. This is to preserve backwards compatibility. For example, an element access 'this["foo"]'
            // has always been resolved eagerly using the constraint type of 'this' at the given location.
            if (isGenericIndexType(indexType)
                || !(accessNode
                    && accessNode.kind !== SyntaxKind.IndexedAccessType)
                && isGenericObjectType(objectType))
            {
                if (objectType.flags & TypeFlags.AnyOrUnknown) {
                    return objectType;
                }
                // Defer the operation by creating an indexed access type.
                const id = objectType.id + ',' + indexType.id;
                let type = indexedAccessTypes.get(id);
                if (!type) {
                    indexedAccessTypes.set(
                        id,
                        type = createIndexedAccessType(objectType, indexType)
                    );
                }
                return type;
            }
            // In the following we resolve T[K] to the type of the property in T selected by K.
            // We treat boolean as different from other unions to improve errors;
            // skipping straight to getPropertyTypeForIndexType gives errors with 'boolean' instead of 'true'.
            const apparentObjectType = getApparentType(objectType);
            if (indexType.flags & TypeFlags.Union
                && !(indexType.flags & TypeFlags.Boolean))
            {
                const propTypes: Type[] = [];
                let wasMissingProp = false;
                for (const t of (<UnionType> indexType).types) {
                    const propType = getPropertyTypeForIndexType(
                        objectType,
                        apparentObjectType,
                        t,
                        indexType,
                        wasMissingProp,
                        accessNode,
                        accessFlags
                    );
                    if (propType) {
                        propTypes.push(propType);
                    } else if (!accessNode) {
                        // If there's no error node, we can immeditely stop, since error reporting is off
                        return undefined;
                    } else {
                        // Otherwise we set a flag and return at the end of the loop so we still mark all errors
                        wasMissingProp = true;
                    }
                }
                if (wasMissingProp) {
                    return undefined;
                }
                return accessFlags & AccessFlags.Writing
                    ? getIntersectionType(propTypes)
                    : getUnionType(propTypes);
            }
            return getPropertyTypeForIndexType(
                objectType,
                apparentObjectType,
                indexType,
                indexType, /* supressNoImplicitAnyError */
                false,
                accessNode,
                accessFlags | AccessFlags.CacheSymbol
            );
        }

        function getTypeFromIndexedAccessTypeNode(node:
            IndexedAccessTypeNode)
        {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                const objectType = getTypeFromTypeNode(node.objectType);
                const indexType = getTypeFromTypeNode(node.indexType);
                const resolved = getIndexedAccessType(
                    objectType,
                    indexType,
                    node
                );
                links.resolvedType = resolved.flags & TypeFlags.IndexedAccess
                    && (<IndexedAccessType> resolved).objectType === objectType
                    && (<IndexedAccessType> resolved).indexType === indexType
                    ? getConstrainedTypeVariable(
                        <IndexedAccessType> resolved,
                        node
                    )
                    : resolved;
            }
            return links.resolvedType;
        }

        function getTypeFromMappedTypeNode(node: MappedTypeNode): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                const type = <MappedType> createObjectType(
                    ObjectFlags.Mapped,
                    node.symbol
                );
                type.declaration = node;
                type.aliasSymbol = getAliasSymbolForTypeNode(node);
                type
                    .aliasTypeArguments = getTypeArgumentsForAliasSymbol(
                        type.aliasSymbol
                    );
                links.resolvedType = type;
                // Eagerly resolve the constraint type which forces an error if the constraint type circularly
                // references itself through one or more type aliases.
                getConstraintTypeFromMappedType(type);
            }
            return links.resolvedType;
        }

        function getActualTypeVariable(type: Type): Type {
            if (type.flags & TypeFlags.Substitution) {
                return (<SubstitutionType> type).typeVariable;
            }
            if (type.flags & TypeFlags.IndexedAccess && (
                (<IndexedAccessType> type).objectType.flags
                & TypeFlags.Substitution
                || (<IndexedAccessType> type).indexType.flags
                & TypeFlags.Substitution
            )) {
                return getIndexedAccessType(
                    getActualTypeVariable(
                        (<IndexedAccessType> type).objectType
                    ),
                    getActualTypeVariable((<IndexedAccessType> type).indexType)
                );
            }
            return type;
        }

        function getConditionalType(
            root: ConditionalRoot,
            mapper: TypeMapper | undefined
        ): Type {
            const checkType = instantiateType(root.checkType, mapper);
            const extendsType = instantiateType(root.extendsType, mapper);
            if (checkType === wildcardType || extendsType === wildcardType) {
                return wildcardType;
            }
            const checkTypeInstantiable = maybeTypeOfKind(
                checkType,
                TypeFlags.Instantiable | TypeFlags.GenericMappedType
            );
            let combinedMapper: TypeMapper | undefined;
            if (root.inferTypeParameters) {
                const context = createInferenceContext(
                    root.inferTypeParameters, /*signature*/
                    undefined,
                    InferenceFlags.None
                );
                if (!checkTypeInstantiable) {
                    // We don't want inferences from constraints as they may cause us to eagerly resolve the
                    // conditional type instead of deferring resolution. Also, we always want strict function
                    // types rules (i.e. proper contravariance) for inferences.
                    inferTypes(
                        context.inferences,
                        checkType,
                        extendsType,
                        InferencePriority.NoConstraints
                            | InferencePriority.AlwaysStrict
                    );
                }
                combinedMapper = combineTypeMappers(mapper, context.mapper);
            }
            // Instantiate the extends type including inferences for 'infer T' type parameters
            const inferredExtendsType = combinedMapper
                ? instantiateType(root.extendsType, combinedMapper)
                : extendsType;
            // We attempt to resolve the conditional type only when the check and extends types are non-generic
            if (!checkTypeInstantiable
                && !maybeTypeOfKind(
                    inferredExtendsType,
                    TypeFlags.Instantiable | TypeFlags.GenericMappedType
                ))
            {
                if (inferredExtendsType.flags & TypeFlags.AnyOrUnknown) {
                    return instantiateType(
                        root.trueType,
                        combinedMapper || mapper
                    );
                }
                // Return union of trueType and falseType for 'any' since it matches anything
                if (checkType.flags & TypeFlags.Any) {
                    return getUnionType(
                        [instantiateType(
                            root.trueType,
                            combinedMapper || mapper
                        ), instantiateType(root.falseType, mapper)]
                    );
                }
                // Return falseType for a definitely false extends check. We check an instantiations of the two
                // types with type parameters mapped to the wildcard type, the most permissive instantiations
                // possible (the wildcard type is assignable to and from all types). If those are not related,
                // then no instantiations will be and we can just return the false branch type.
                if (!isTypeAssignableTo(
                    getPermissiveInstantiation(checkType),
                    getPermissiveInstantiation(inferredExtendsType)
                )) {
                    return instantiateType(root.falseType, mapper);
                }
                // Return trueType for a definitely true extends check. We check instantiations of the two
                // types with type parameters mapped to their restrictive form, i.e. a form of the type parameter
                // that has no constraint. This ensures that, for example, the type
                //   type Foo<T extends { x: any }> = T extends { x: string } ? string : number
                // doesn't immediately resolve to 'string' instead of being deferred.
                if (isTypeAssignableTo(
                    getRestrictiveInstantiation(checkType),
                    getRestrictiveInstantiation(inferredExtendsType)
                )) {
                    return instantiateType(
                        root.trueType,
                        combinedMapper || mapper
                    );
                }
            }
            // Return a deferred type for a check that is neither definitely true nor definitely false
            const erasedCheckType = getActualTypeVariable(checkType);
            const result = <ConditionalType> createType(TypeFlags.Conditional);
            result.root = root;
            result.checkType = erasedCheckType;
            result.extendsType = extendsType;
            result.mapper = mapper;
            result.combinedMapper = combinedMapper;
            result.aliasSymbol = root.aliasSymbol;
            result
                .aliasTypeArguments = instantiateTypes(
                    root.aliasTypeArguments,
                    mapper!
                ); // TODO: GH#18217
            return result;
        }

        function getTrueTypeFromConditionalType(type: ConditionalType) {
            return type.resolvedTrueType
                || (type.resolvedTrueType = instantiateType(
                    type.root.trueType,
                    type.mapper
                ));
        }

        function getFalseTypeFromConditionalType(type: ConditionalType) {
            return type.resolvedFalseType
                || (type
                    .resolvedFalseType = instantiateType(
                        type.root.falseType,
                        type.mapper
                    ));
        }

        function getInferredTrueTypeFromConditionalType(type:
            ConditionalType)
        {
            return type.resolvedInferredTrueType
                || (type.resolvedInferredTrueType = type.combinedMapper
                    ? instantiateType(type.root.trueType, type.combinedMapper)
                    : getTrueTypeFromConditionalType(type));
        }

        function getInferTypeParameters(
            node: ConditionalTypeNode
        ): TypeParameter[] | undefined {
            let result: TypeParameter[] | undefined;
            if (node.locals) {
                node.locals.forEach(symbol => {
                    if (symbol.flags & SymbolFlags.TypeParameter) {
                        result = append(
                            result,
                            getDeclaredTypeOfSymbol(symbol)
                        );
                    }
                });
            }
            return result;
        }

        function getTypeFromConditionalTypeNode(
            node: ConditionalTypeNode
        ): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                const checkType = getTypeFromTypeNode(node.checkType);
                const aliasSymbol = getAliasSymbolForTypeNode(node);
                const aliasTypeArguments = getTypeArgumentsForAliasSymbol(aliasSymbol);
                const allOuterTypeParameters = getOuterTypeParameters(
                    node, /*includeThisTypes*/
                    true
                );
                const outerTypeParameters = aliasTypeArguments
                    ? allOuterTypeParameters
                    : filter(
                        allOuterTypeParameters,
                        tp => isTypeParameterPossiblyReferenced(tp, node)
                    );
                const root: ConditionalRoot = {
                    node,
                    checkType,
                    extendsType: getTypeFromTypeNode(node.extendsType),
                    trueType: getTypeFromTypeNode(node.trueType),
                    falseType: getTypeFromTypeNode(node.falseType),
                    isDistributive:
                        !!(checkType.flags & TypeFlags.TypeParameter),
                    inferTypeParameters: getInferTypeParameters(node),
                    outerTypeParameters,
                    instantiations: undefined,
                    aliasSymbol,
                    aliasTypeArguments
                };
                links.resolvedType = getConditionalType(
                    root, /*mapper*/
                    undefined
                );
                if (outerTypeParameters) {
                    root.instantiations = createMap<Type>();
                    root.instantiations.set(
                        getTypeListId(outerTypeParameters),
                        links.resolvedType
                    );
                }
            }
            return links.resolvedType;
        }

        function getTypeFromInferTypeNode(node: InferTypeNode): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                links
                    .resolvedType = getDeclaredTypeOfTypeParameter(
                        getSymbolOfNode(
                            node.typeParameter
                        )
                    );
            }
            return links.resolvedType;
        }

        function getIdentifierChain(node: EntityName): Identifier[] {
            if (isIdentifier(node)) {
                return [node];
            } else {
                return append(getIdentifierChain(node.left), node.right);
            }
        }

        function getTypeFromImportTypeNode(node: ImportTypeNode): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                if (node.isTypeOf
                    && node
                        .typeArguments)
                { // Only the non-typeof form can make use of type arguments
                    error(node,
                        Diagnostics.Type_arguments_cannot_be_used_here);
                    links.resolvedSymbol = unknownSymbol;
                    return links.resolvedType = errorType;
                }
                if (!isLiteralImportTypeNode(node)) {
                    error(node.argument, Diagnostics.String_literal_expected);
                    links.resolvedSymbol = unknownSymbol;
                    return links.resolvedType = errorType;
                }
                const targetMeaning = node.isTypeOf
                    ? SymbolFlags.Value
                    : node.flags & NodeFlags.JSDoc
                        ? SymbolFlags.Value | SymbolFlags.Type
                        : SymbolFlags.Type;
                // TODO: Future work: support unions/generics/whatever via a deferred import-type
                const innerModuleSymbol = resolveExternalModuleName(
                    node,
                    node.argument.literal
                );
                if (!innerModuleSymbol) {
                    links.resolvedSymbol = unknownSymbol;
                    return links.resolvedType = errorType;
                }
                const moduleSymbol = resolveExternalModuleSymbol(
                    innerModuleSymbol, /*dontResolveAlias*/
                    false
                );
                if (!nodeIsMissing(node.qualifier)) {
                    const nameStack:
                        Identifier[] = getIdentifierChain(node.qualifier!);
                    let currentNamespace = moduleSymbol;
                    let current: Identifier | undefined;
                    while (current = nameStack.shift()) {
                        const meaning = nameStack.length
                            ? SymbolFlags.Namespace
                            : targetMeaning;
                        const next = getSymbol(
                            getExportsOfSymbol(getMergedSymbol(resolveSymbol(currentNamespace))),
                            current.escapedText,
                            meaning
                        );
                        if (!next) {
                            error(
                                current,
                                Diagnostics
                                    .Namespace_0_has_no_exported_member_1,
                                getFullyQualifiedName(currentNamespace),
                                declarationNameToString(current)
                            );
                            return links.resolvedType = errorType;
                        }
                        getNodeLinks(current).resolvedSymbol = next;
                        getNodeLinks(current.parent).resolvedSymbol = next;
                        currentNamespace = next;
                    }
                    links.resolvedType = resolveImportSymbolType(
                        node,
                        links,
                        currentNamespace,
                        targetMeaning
                    );
                } else {
                    if (moduleSymbol.flags & targetMeaning) {
                        links.resolvedType = resolveImportSymbolType(
                            node,
                            links,
                            moduleSymbol,
                            targetMeaning
                        );
                    } else {
                        const errorMessage = targetMeaning
                            === SymbolFlags.Value
                            ? Diagnostics
                                .Module_0_does_not_refer_to_a_value_but_is_used_as_a_value_here
                            : Diagnostics
                                .Module_0_does_not_refer_to_a_type_but_is_used_as_a_type_here_Did_you_mean_typeof_import_0;

                        error(node, errorMessage, node.argument.literal.text);

                        links.resolvedSymbol = unknownSymbol;
                        links.resolvedType = errorType;
                    }
                }
            }
            return links.resolvedType;
        }

        function resolveImportSymbolType(
            node: ImportTypeNode,
            links: NodeLinks,
            symbol: Symbol,
            meaning: SymbolFlags
        ) {
            const resolvedSymbol = resolveSymbol(symbol);
            links.resolvedSymbol = resolvedSymbol;
            if (meaning === SymbolFlags.Value) {
                return getTypeOfSymbol(symbol); // intentionally doesn't use resolved symbol so type is cached as expected on the alias
            } else {
                return getTypeReferenceType(node,
                    resolvedSymbol); // getTypeReferenceType doesn't handle aliases - it must get the resolved symbol
            }
        }

        function getTypeFromTypeLiteralOrFunctionOrConstructorTypeNode(
            node: TypeNode
        ): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                // Deferred resolution of members is handled by resolveObjectTypeMembers
                const aliasSymbol = getAliasSymbolForTypeNode(node);
                if (getMembersOfSymbol(node.symbol).size === 0
                    && !aliasSymbol)
                {
                    links.resolvedType = emptyTypeLiteralType;
                } else {
                    let type = createObjectType(
                        ObjectFlags.Anonymous,
                        node.symbol
                    );
                    type.aliasSymbol = aliasSymbol;
                    type
                        .aliasTypeArguments = getTypeArgumentsForAliasSymbol(aliasSymbol);
                    if (isJSDocTypeLiteral(node) && node.isArrayType) {
                        type = createArrayType(type);
                    }
                    links.resolvedType = type;
                }
            }
            return links.resolvedType;
        }

        function getAliasSymbolForTypeNode(node: TypeNode) {
            let host = node.parent;
            while (isParenthesizedTypeNode(host) || isTypeOperatorNode(host)
                && host.operator === SyntaxKind.ReadonlyKeyword)
            {
                host = host.parent;
            }
            return isTypeAlias(host) ? getSymbolOfNode(host) : undefined;
        }

        function getTypeArgumentsForAliasSymbol(symbol: Symbol | undefined) {
            return symbol
                ? getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol)
                : undefined;
        }

        function isNonGenericObjectType(type: Type) {
            return !!(type.flags & TypeFlags.Object)
                && !isGenericMappedType(type);
        }

        function isEmptyObjectTypeOrSpreadsIntoEmptyObject(type: Type) {
            return isEmptyObjectType(type)
                || !!(type.flags
                    & (TypeFlags.Null | TypeFlags.Undefined
                        | TypeFlags.BooleanLike | TypeFlags.NumberLike
                        | TypeFlags.BigIntLike | TypeFlags.StringLike
                        | TypeFlags.EnumLike | TypeFlags.NonPrimitive
                        | TypeFlags.Index));
        }

        function isSinglePropertyAnonymousObjectType(type: Type) {
            return !!(type.flags & TypeFlags.Object)
                && !!(getObjectFlags(type) & ObjectFlags.Anonymous)
                && (length(getPropertiesOfType(type)) === 1
                    || every(
                        getPropertiesOfType(type),
                        p => !!(p.flags & SymbolFlags.Optional)
                    ));
        }

        function tryMergeUnionOfObjectTypeAndEmptyObject(
            type: UnionType,
            readonly: boolean
        ): Type | undefined {
            if (type.types.length === 2) {
                const firstType = type.types[0];
                const secondType = type.types[1];
                if (every(
                    type.types,
                    isEmptyObjectTypeOrSpreadsIntoEmptyObject
                )) {
                    return isEmptyObjectType(firstType)
                        ? firstType
                        : isEmptyObjectType(secondType) ? secondType
                            : emptyObjectType;
                }
                if (isEmptyObjectTypeOrSpreadsIntoEmptyObject(firstType)
                    && isSinglePropertyAnonymousObjectType(secondType))
                {
                    return getAnonymousPartialType(secondType);
                }
                if (isEmptyObjectTypeOrSpreadsIntoEmptyObject(secondType)
                    && isSinglePropertyAnonymousObjectType(firstType))
                {
                    return getAnonymousPartialType(firstType);
                }
            }

            function getAnonymousPartialType(type: Type) {
                // gets the type as if it had been spread, but where everything in the spread is made optional
                const members = createSymbolTable();
                for (const prop of getPropertiesOfType(type)) {
                    if (getDeclarationModifierFlagsFromSymbol(prop)
                        & (ModifierFlags.Private | ModifierFlags.Protected))
                    {
                        // do nothing, skip privates
                    } else if (isSpreadableProperty(prop)) {
                        const isSetonlyAccessor = prop.flags
                            & SymbolFlags.SetAccessor
                            && !(prop.flags & SymbolFlags.GetAccessor);
                        const flags = SymbolFlags.Property
                            | SymbolFlags.Optional;
                        const result = createSymbol(
                            flags,
                            prop.escapedName,
                            readonly ? CheckFlags.Readonly : 0
                        );
                        result.type = isSetonlyAccessor
                            ? undefinedType
                            : getTypeOfSymbol(prop);
                        result.declarations = prop.declarations;
                        result.nameType = prop.nameType;
                        result.syntheticOrigin = prop;
                        members.set(prop.escapedName, result);
                    }
                }
                const spread = createAnonymousType(
                    type.symbol,
                    members,
                    emptyArray,
                    emptyArray,
                    getIndexInfoOfType(type, IndexKind.String),
                    getIndexInfoOfType(type, IndexKind.Number)
                );
                spread
                    .objectFlags |= ObjectFlags.ObjectLiteral
                        | ObjectFlags.ContainsObjectOrArrayLiteral;
                return spread;
            }
        }

        /**
         * Since the source of spread types are object literals, which are not binary,
         * this function should be called in a left folding style, with left = previous result of getSpreadType
         * and right = the new element to be spread.
         */
        function getSpreadType(
            left: Type,
            right: Type,
            symbol: Symbol | undefined,
            objectFlags: ObjectFlags,
            readonly: boolean
        ): Type {
            if (left.flags & TypeFlags.Any || right.flags & TypeFlags.Any) {
                return anyType;
            }
            if (left.flags & TypeFlags.Unknown
                || right.flags & TypeFlags.Unknown)
            {
                return unknownType;
            }
            if (left.flags & TypeFlags.Never) {
                return right;
            }
            if (right.flags & TypeFlags.Never) {
                return left;
            }
            if (left.flags & TypeFlags.Union) {
                const merged = tryMergeUnionOfObjectTypeAndEmptyObject(
                    left as UnionType,
                    readonly
                );
                if (merged) {
                    return getSpreadType(
                        merged,
                        right,
                        symbol,
                        objectFlags,
                        readonly
                    );
                }
                return mapType(
                    left,
                    t => getSpreadType(t, right, symbol, objectFlags, readonly)
                );
            }
            if (right.flags & TypeFlags.Union) {
                const merged = tryMergeUnionOfObjectTypeAndEmptyObject(
                    right as UnionType,
                    readonly
                );
                if (merged) {
                    return getSpreadType(
                        left,
                        merged,
                        symbol,
                        objectFlags,
                        readonly
                    );
                }
                return mapType(
                    right,
                    t => getSpreadType(left, t, symbol, objectFlags, readonly)
                );
            }
            if (right.flags
                & (TypeFlags.BooleanLike | TypeFlags.NumberLike
                    | TypeFlags.BigIntLike | TypeFlags.StringLike
                    | TypeFlags.EnumLike | TypeFlags.NonPrimitive
                    | TypeFlags.Index))
            {
                return left;
            }

            if (isGenericObjectType(left) || isGenericObjectType(right)) {
                if (isEmptyObjectType(left)) {
                    return right;
                }
                // When the left type is an intersection, we may need to merge the last constituent of the
                // intersection with the right type. For example when the left type is 'T & { a: string }'
                // and the right type is '{ b: string }' we produce 'T & { a: string, b: string }'.
                if (left.flags & TypeFlags.Intersection) {
                    const types = (<IntersectionType> left).types;
                    const lastLeft = types[types.length - 1];
                    if (isNonGenericObjectType(lastLeft)
                        && isNonGenericObjectType(right))
                    {
                        return getIntersectionType(
                            concatenate(
                                types.slice(
                                    0,
                                    types.length - 1
                                ),
                                [getSpreadType(
                                    lastLeft,
                                    right,
                                    symbol,
                                    objectFlags,
                                    readonly
                                )]
                            )
                        );
                    }
                }
                return getIntersectionType([left, right]);
            }

            const members = createSymbolTable();
            const skippedPrivateMembers = createUnderscoreEscapedMap<boolean>();
            let stringIndexInfo: IndexInfo | undefined;
            let numberIndexInfo: IndexInfo | undefined;
            if (left === emptyObjectType) {
                // for the first spread element, left === emptyObjectType, so take the right's string indexer
                stringIndexInfo = getIndexInfoOfType(right, IndexKind.String);
                numberIndexInfo = getIndexInfoOfType(right, IndexKind.Number);
            } else {
                stringIndexInfo = unionSpreadIndexInfos(
                    getIndexInfoOfType(
                        left,
                        IndexKind.String
                    ),
                    getIndexInfoOfType(right, IndexKind.String)
                );
                numberIndexInfo = unionSpreadIndexInfos(
                    getIndexInfoOfType(
                        left,
                        IndexKind.Number
                    ),
                    getIndexInfoOfType(right, IndexKind.Number)
                );
            }

            for (const rightProp of getPropertiesOfType(right)) {
                if (getDeclarationModifierFlagsFromSymbol(rightProp)
                    & (ModifierFlags.Private | ModifierFlags.Protected))
                {
                    skippedPrivateMembers.set(rightProp.escapedName, true);
                } else if (isSpreadableProperty(rightProp)) {
                    members.set(
                        rightProp.escapedName,
                        getSpreadSymbol(rightProp, readonly)
                    );
                }
            }

            for (const leftProp of getPropertiesOfType(left)) {
                if (skippedPrivateMembers.has(leftProp.escapedName)
                    || !isSpreadableProperty(leftProp))
                {
                    continue;
                }
                if (members.has(leftProp.escapedName)) {
                    const rightProp = members.get(leftProp.escapedName)!;
                    const rightType = getTypeOfSymbol(rightProp);
                    if (rightProp.flags & SymbolFlags.Optional) {
                        const declarations = concatenate(
                            leftProp.declarations,
                            rightProp.declarations
                        );
                        const flags = SymbolFlags.Property
                            | (leftProp.flags & SymbolFlags.Optional);
                        const result = createSymbol(
                            flags,
                            leftProp.escapedName
                        );
                        result
                            .type = getUnionType(
                                [getTypeOfSymbol(leftProp), getTypeWithFacts(
                                    rightType,
                                    TypeFacts.NEUndefined
                                )]
                            );
                        result.leftSpread = leftProp;
                        result.rightSpread = rightProp;
                        result.declarations = declarations;
                        result.nameType = leftProp.nameType;
                        members.set(leftProp.escapedName, result);
                    }
                } else {
                    members.set(
                        leftProp.escapedName,
                        getSpreadSymbol(leftProp, readonly)
                    );
                }
            }

            const spread = createAnonymousType(
                symbol,
                members,
                emptyArray,
                emptyArray,
                getIndexInfoWithReadonly(stringIndexInfo, readonly),
                getIndexInfoWithReadonly(numberIndexInfo, readonly)
            );
            spread
                .objectFlags |= ObjectFlags.ObjectLiteral
                    | ObjectFlags.ContainsObjectOrArrayLiteral
                    | ObjectFlags.ContainsSpread | objectFlags;
            return spread;
        }

        /** We approximate own properties as non-methods plus methods that are inside the object literal */
        function isSpreadableProperty(prop: Symbol): boolean {
            return !(prop.flags
                & (SymbolFlags.Method | SymbolFlags.GetAccessor
                    | SymbolFlags.SetAccessor))
                || !prop.declarations.some(decl => isClassLike(decl.parent));
        }

        function getSpreadSymbol(prop: Symbol, readonly: boolean) {
            const isSetonlyAccessor = prop.flags & SymbolFlags.SetAccessor
                && !(prop.flags & SymbolFlags.GetAccessor);
            if (!isSetonlyAccessor && readonly === isReadonlySymbol(prop)) {
                return prop;
            }
            const flags = SymbolFlags.Property
                | (prop.flags & SymbolFlags.Optional);
            const result = createSymbol(
                flags,
                prop.escapedName,
                readonly ? CheckFlags.Readonly : 0
            );
            result.type = isSetonlyAccessor
                ? undefinedType
                : getTypeOfSymbol(prop);
            result.declarations = prop.declarations;
            result.nameType = prop.nameType;
            result.syntheticOrigin = prop;
            return result;
        }

        function getIndexInfoWithReadonly(
            info: IndexInfo | undefined,
            readonly: boolean
        ) {
            return info && info.isReadonly !== readonly
                ? createIndexInfo(info.type, readonly, info.declaration)
                : info;
        }

        function createLiteralType(
            flags: TypeFlags,
            value: string | number | PseudoBigInt,
            symbol: Symbol | undefined
        ) {
            const type = <LiteralType> createType(flags);
            type.symbol = symbol!;
            type.value = value;
            return type;
        }

        function getFreshTypeOfLiteralType(type: Type): Type {
            if (type.flags & TypeFlags.Literal) {
                if (!(<LiteralType> type).freshType) {
                    const freshType = createLiteralType(
                        type.flags,
                        (<LiteralType> type).value,
                        (<LiteralType> type).symbol
                    );
                    freshType.regularType = <LiteralType> type;
                    freshType.freshType = freshType;
                    (<LiteralType> type).freshType = freshType;
                }
                return (<LiteralType> type).freshType;
            }
            return type;
        }

        function getRegularTypeOfLiteralType(type: Type): Type {
            return type.flags & TypeFlags.Literal
                ? (<LiteralType> type).regularType
                : type.flags & TypeFlags.Union
                    ? getUnionType(
                        sameMap(
                            (<UnionType> type).types,
                            getRegularTypeOfLiteralType
                        )
                    )
                    : type;
        }

        function isFreshLiteralType(type: Type) {
            return !!(type.flags & TypeFlags.Literal)
                && (<LiteralType> type).freshType === type;
        }

        function getLiteralType(
            value: string | number | PseudoBigInt,
            enumId?: number,
            symbol?: Symbol
        ) {
            // We store all literal types in a single map with keys of the form '#NNN' and '@SSS',
            // where NNN is the text representation of a numeric literal and SSS are the characters
            // of a string literal. For literal enum members we use 'EEE#NNN' and 'EEE@SSS', where
            // EEE is a unique id for the containing enum type.
            const qualifier = typeof value === 'number'
                ? '#'
                : typeof value === 'string' ? '@' : 'n';
            const key = (enumId ? enumId : '') + qualifier
                + (typeof value === 'object'
                    ? pseudoBigIntToString(value)
                    : value);
            let type = literalTypes.get(key);
            if (!type) {
                const flags = (typeof value === 'number'
                    ? TypeFlags.NumberLiteral
                    : typeof value === 'string'
                        ? TypeFlags.StringLiteral
                        : TypeFlags.BigIntLiteral)
                    | (enumId ? TypeFlags.EnumLiteral : 0);
                literalTypes.set(
                    key,
                    type = createLiteralType(flags, value, symbol)
                );
                type.regularType = type;
            }
            return type;
        }

        function getTypeFromLiteralTypeNode(node: LiteralTypeNode): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                links
                    .resolvedType = getRegularTypeOfLiteralType(
                        checkExpression(
                            node.literal
                        )
                    );
            }
            return links.resolvedType;
        }

        function createUniqueESSymbolType(symbol: Symbol) {
            const type = <UniqueESSymbolType> createType(
                TypeFlags.UniqueESSymbol
            );
            type.symbol = symbol;
            type
                .escapedName = `__@${type.symbol.escapedName}@${
                    getSymbolId(type.symbol)}` as __String;
            return type;
        }

        function getESSymbolLikeTypeForNode(node: Node) {
            if (isValidESSymbolDeclaration(node)) {
                const symbol = getSymbolOfNode(node);
                const links = getSymbolLinks(symbol);
                return links.uniqueESSymbolType
                    || (links
                        .uniqueESSymbolType = createUniqueESSymbolType(symbol));
            }
            return esSymbolType;
        }

        function getThisType(node: Node): Type {
            const container = getThisContainer(
                node, /*includeArrowFunctions*/
                false
            );
            const parent = container && container.parent;
            if (parent
                && (isClassLike(parent)
                    || parent.kind === SyntaxKind.InterfaceDeclaration))
            {
                if (!hasModifier(container, ModifierFlags.Static)
                    && (!isConstructorDeclaration(container)
                        || isNodeDescendantOf(node, container.body)))
                {
                    return getDeclaredTypeOfClassOrInterface(
                        getSymbolOfNode(
                            parent as ClassLikeDeclaration
                                | InterfaceDeclaration
                        )
                    ).thisType!;
                }
            }

            // inside x.prototype = { ... }
            if (parent && isObjectLiteralExpression(parent)
                && isBinaryExpression(parent.parent)
                && getAssignmentDeclarationKind(parent.parent)
                === AssignmentDeclarationKind.Prototype)
            {
                return getDeclaredTypeOfClassOrInterface(
                    getSymbolOfNode(
                        parent.parent.left
                    )!.parent!
                ).thisType!;
            }
            // /** @return {this} */
            // x.prototype.m = function() { ... }
            const host = node.flags & NodeFlags.JSDoc
                ? getHostSignatureFromJSDoc(node)
                : undefined;
            if (host && isFunctionExpression(host)
                && isBinaryExpression(host.parent)
                && getAssignmentDeclarationKind(host.parent)
                === AssignmentDeclarationKind.PrototypeProperty)
            {
                return getDeclaredTypeOfClassOrInterface(
                    getSymbolOfNode(
                        host.parent.left
                    )!.parent!
                ).thisType!;
            }
            // inside constructor function C() { ... }
            if (isJSConstructor(container)
                && isNodeDescendantOf(node, container.body))
            {
                return getDeclaredTypeOfClassOrInterface(getSymbolOfNode(container))
                    .thisType!;
            }
            error(
                node,
                Diagnostics
                    .A_this_type_is_available_only_in_a_non_static_member_of_a_class_or_interface
            );
            return errorType;
        }

        function getTypeFromThisTypeNode(
            node: ThisExpression | ThisTypeNode
        ): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                links.resolvedType = getThisType(node);
            }
            return links.resolvedType;
        }

        function getTypeFromTypeNode(node: TypeNode): Type {
            switch (node.kind) {
                case SyntaxKind.AnyKeyword:
                case SyntaxKind.JSDocAllType:
                case SyntaxKind.JSDocUnknownType:
                    return anyType;
                case SyntaxKind.UnknownKeyword:
                    return unknownType;
                case SyntaxKind.StringKeyword:
                    return stringType;
                case SyntaxKind.NumberKeyword:
                    return numberType;
                case SyntaxKind.BigIntKeyword:
                    return bigintType;
                case SyntaxKind.BooleanKeyword:
                    return booleanType;
                case SyntaxKind.SymbolKeyword:
                    return esSymbolType;
                case SyntaxKind.VoidKeyword:
                    return voidType;
                case SyntaxKind.UndefinedKeyword:
                    return undefinedType;
                case SyntaxKind.NullKeyword:
                    return nullType;
                case SyntaxKind.NeverKeyword:
                    return neverType;
                case SyntaxKind.ObjectKeyword:
                    return node.flags & NodeFlags.JavaScriptFile
                        && !noImplicitAny
                        ? anyType
                        : nonPrimitiveType;
                case SyntaxKind.ThisType:
                case SyntaxKind.ThisKeyword:
                    return getTypeFromThisTypeNode(
                        node as ThisExpression | ThisTypeNode
                    );
                case SyntaxKind.LiteralType:
                    return getTypeFromLiteralTypeNode(<LiteralTypeNode> node);
                case SyntaxKind.TypeReference:
                    return getTypeFromTypeReference(<TypeReferenceNode> node);
                case SyntaxKind.TypePredicate:
                    return (<TypePredicateNode> node).assertsModifier
                        ? voidType
                        : booleanType;
                case SyntaxKind.ExpressionWithTypeArguments:
                    return getTypeFromTypeReference(<ExpressionWithTypeArguments> node);
                case SyntaxKind.TypeQuery:
                    return getTypeFromTypeQueryNode(<TypeQueryNode> node);
                case SyntaxKind.ArrayType:
                case SyntaxKind.TupleType:
                    return getTypeFromArrayOrTupleTypeNode(
                        <ArrayTypeNode | TupleTypeNode> node
                    );
                case SyntaxKind.OptionalType:
                    return getTypeFromOptionalTypeNode(<OptionalTypeNode> node);
                case SyntaxKind.UnionType:
                    return getTypeFromUnionTypeNode(<UnionTypeNode> node);
                case SyntaxKind.IntersectionType:
                    return getTypeFromIntersectionTypeNode(<IntersectionTypeNode> node);
                case SyntaxKind.JSDocNullableType:
                    return getTypeFromJSDocNullableTypeNode(<JSDocNullableType> node);
                case SyntaxKind.JSDocOptionalType:
                    return addOptionality(
                        getTypeFromTypeNode(
                            (node as JSDocOptionalType).type
                        )
                    );
                case SyntaxKind.ParenthesizedType:
                case SyntaxKind.JSDocNonNullableType:
                case SyntaxKind.JSDocTypeExpression:
                    return getTypeFromTypeNode(
                        (<ParenthesizedTypeNode | JSDocTypeReferencingNode
                            | JSDocTypeExpression> node).type
                    );
                case SyntaxKind.RestType:
                    return getElementTypeOfArrayType(
                        getTypeFromTypeNode(
                            (<RestTypeNode> node).type
                        )
                    ) || errorType;
                case SyntaxKind.JSDocVariadicType:
                    return getTypeFromJSDocVariadicType(node as JSDocVariadicType);
                case SyntaxKind.FunctionType:
                case SyntaxKind.ConstructorType:
                case SyntaxKind.TypeLiteral:
                case SyntaxKind.JSDocTypeLiteral:
                case SyntaxKind.JSDocFunctionType:
                case SyntaxKind.JSDocSignature:
                    return getTypeFromTypeLiteralOrFunctionOrConstructorTypeNode(node);
                case SyntaxKind.TypeOperator:
                    return getTypeFromTypeOperatorNode(<TypeOperatorNode> node);
                case SyntaxKind.IndexedAccessType:
                    return getTypeFromIndexedAccessTypeNode(<IndexedAccessTypeNode> node);
                case SyntaxKind.MappedType:
                    return getTypeFromMappedTypeNode(<MappedTypeNode> node);
                case SyntaxKind.ConditionalType:
                    return getTypeFromConditionalTypeNode(<ConditionalTypeNode> node);
                case SyntaxKind.InferType:
                    return getTypeFromInferTypeNode(<InferTypeNode> node);
                case SyntaxKind.ImportType:
                    return getTypeFromImportTypeNode(<ImportTypeNode> node);
                // This function assumes that an identifier or qualified name is a type expression
                // Callers should first ensure this by calling isTypeNode
                case SyntaxKind.Identifier:
                case SyntaxKind.QualifiedName:
                    const symbol = getSymbolAtLocation(node);
                    return symbol
                        ? getDeclaredTypeOfSymbol(symbol)
                        : errorType;
                default:
                    return errorType;
            }
        }

        function instantiateList<T>(
            items: readonly T[],
            mapper: TypeMapper,
            instantiator: (item: T, mapper: TypeMapper) => T
        ): readonly T[];
        function instantiateList<T>(
            items: readonly T[] | undefined,
            mapper: TypeMapper,
            instantiator: (item: T, mapper: TypeMapper) => T
        ): readonly T[] | undefined;
        function instantiateList<T>(
            items: readonly T[] | undefined,
            mapper: TypeMapper,
            instantiator: (item: T, mapper: TypeMapper) => T
        ): readonly T[] | undefined {
            if (items && items.length) {
                for (let i = 0; i < items.length; i++) {
                    const item = items[i];
                    const mapped = instantiator(item, mapper);
                    if (item !== mapped) {
                        const result = i === 0 ? [] : items.slice(0, i);
                        result.push(mapped);
                        for (i++; i < items.length; i++) {
                            result.push(instantiator(items[i], mapper));
                        }
                        return result;
                    }
                }
            }
            return items;
        }

        function instantiateTypes(
            types: readonly Type[],
            mapper: TypeMapper
        ): readonly Type[];
        function instantiateTypes(
            types: readonly Type[] | undefined,
            mapper: TypeMapper
        ): readonly Type[] | undefined;
        function instantiateTypes(
            types: readonly Type[] | undefined,
            mapper: TypeMapper
        ): readonly Type[] | undefined {
            return instantiateList<Type>(types, mapper, instantiateType);
        }

        function instantiateSignatures(
            signatures: readonly Signature[],
            mapper: TypeMapper
        ): readonly Signature[] {
            return instantiateList<Signature>(
                signatures,
                mapper,
                instantiateSignature
            );
        }

        function makeUnaryTypeMapper(source: Type, target: Type) {
            return (t: Type) => t === source ? target : t;
        }

        function makeBinaryTypeMapper(
            source1: Type,
            target1: Type,
            source2: Type,
            target2: Type
        ) {
            return (t: Type) => t === source1
                ? target1
                : t === source2 ? target2 : t;
        }

        function makeArrayTypeMapper(
            sources: readonly Type[],
            targets: readonly Type[] | undefined
        ) {
            return (t: Type) => {
                for (let i = 0; i < sources.length; i++) {
                    if (t === sources[i]) {
                        return targets ? targets[i] : anyType;
                    }
                }
                return t;
            };
        }

        function createTypeMapper(
            sources: readonly TypeParameter[],
            targets: readonly Type[] | undefined
        ): TypeMapper {
            Debug
                .assert(
                    targets === undefined || sources.length === targets.length
                );
            return sources.length === 1
                ? makeUnaryTypeMapper(
                    sources[0],
                    targets ? targets[0] : anyType
                )
                : sources.length === 2
                    ? makeBinaryTypeMapper(
                        sources[0],
                        targets ? targets[0] : anyType,
                        sources[1],
                        targets ? targets[1] : anyType
                    )
                    : makeArrayTypeMapper(sources, targets);
        }

        function createTypeEraser(
            sources: readonly TypeParameter[]
        ): TypeMapper {
            return createTypeMapper(sources, /*targets*/ undefined);
        }

        /**
         * Maps forward-references to later types parameters to the empty object type.
         * This is used during inference when instantiating type parameter defaults.
         */
        function createBackreferenceMapper(
            context: InferenceContext,
            index: number
        ): TypeMapper {
            return t => findIndex(
                context.inferences,
                info => info.typeParameter === t
            ) >= index
                ? unknownType
                : t;
        }

        function combineTypeMappers(
            mapper1: TypeMapper | undefined,
            mapper2: TypeMapper
        ): TypeMapper;
        function combineTypeMappers(
            mapper1: TypeMapper,
            mapper2: TypeMapper | undefined
        ): TypeMapper;
        function combineTypeMappers(
            mapper1: TypeMapper,
            mapper2: TypeMapper
        ): TypeMapper {
            if (!mapper1) return mapper2;
            if (!mapper2) return mapper1;
            return t => instantiateType(mapper1(t), mapper2);
        }

        function createReplacementMapper(
            source: Type,
            target: Type,
            baseMapper: TypeMapper
        ): TypeMapper {
            return t => t === source ? target : baseMapper(t);
        }

        function permissiveMapper(type: Type) {
            return type.flags & TypeFlags.TypeParameter ? wildcardType : type;
        }

        function getRestrictiveTypeParameter(tp: TypeParameter) {
            return tp.constraint === unknownType
                ? tp
                : tp.restrictiveInstantiation || (
                    tp.restrictiveInstantiation = createTypeParameter(
                        tp.symbol
                    ),
                        (tp.restrictiveInstantiation as TypeParameter)
                            .constraint = unknownType,
                        tp.restrictiveInstantiation
                );
        }

        function restrictiveMapper(type: Type) {
            return type.flags & TypeFlags.TypeParameter
                ? getRestrictiveTypeParameter(<TypeParameter> type)
                : type;
        }

        function cloneTypeParameter(
            typeParameter: TypeParameter
        ): TypeParameter {
            const result = createTypeParameter(typeParameter.symbol);
            result.target = typeParameter;
            return result;
        }

        function instantiateTypePredicate(
            predicate: TypePredicate,
            mapper: TypeMapper
        ): TypePredicate {
            return createTypePredicate(
                predicate.kind,
                predicate.parameterName,
                predicate.parameterIndex,
                instantiateType(predicate.type, mapper)
            );
        }

        function instantiateSignature(
            signature: Signature,
            mapper: TypeMapper,
            eraseTypeParameters?: boolean
        ): Signature {
            let freshTypeParameters: TypeParameter[] | undefined;
            if (signature.typeParameters && !eraseTypeParameters) {
                // First create a fresh set of type parameters, then include a mapping from the old to the
                // new type parameters in the mapper function. Finally store this mapper in the new type
                // parameters such that we can use it when instantiating constraints.
                freshTypeParameters = map(
                    signature.typeParameters,
                    cloneTypeParameter
                );
                mapper = combineTypeMappers(
                    createTypeMapper(
                        signature.typeParameters,
                        freshTypeParameters
                    ),
                    mapper
                );
                for (const tp of freshTypeParameters) {
                    tp.mapper = mapper;
                }
            }
            // Don't compute resolvedReturnType and resolvedTypePredicate now,
            // because using `mapper` now could trigger inferences to become fixed. (See `createInferenceContext`.)
            // See GH#17600.
            const result = createSignature(
                signature.declaration,
                freshTypeParameters,
                signature.thisParameter
                    && instantiateSymbol(signature.thisParameter, mapper),
                instantiateList(
                    signature.parameters,
                    mapper,
                    instantiateSymbol
                ),
                /*resolvedReturnType*/ undefined,
                /*resolvedTypePredicate*/ undefined,
                signature.minArgumentCount,
                signature.flags & SignatureFlags.PropagatingFlags
            );
            result.target = signature;
            result.mapper = mapper;
            return result;
        }

        function instantiateSymbol(symbol: Symbol,
            mapper: TypeMapper): Symbol
        {
            const links = getSymbolLinks(symbol);
            if (links.type
                && !maybeTypeOfKind(
                    links.type,
                    TypeFlags.Object | TypeFlags.Instantiable
                ))
            {
                // If the type of the symbol is already resolved, and if that type could not possibly
                // be affected by instantiation, simply return the symbol itself.
                return symbol;
            }
            if (getCheckFlags(symbol) & CheckFlags.Instantiated) {
                // If symbol being instantiated is itself a instantiation, fetch the original target and combine the
                // type mappers. This ensures that original type identities are properly preserved and that aliases
                // always reference a non-aliases.
                symbol = links.target!;
                mapper = combineTypeMappers(links.mapper, mapper);
            }
            // Keep the flags from the symbol we're instantiating.  Mark that is instantiated, and
            // also transient so that we can just store data on it directly.
            const result = createSymbol(
                symbol.flags,
                symbol.escapedName,
                CheckFlags.Instantiated
                    | getCheckFlags(symbol)
                    & (CheckFlags.Readonly | CheckFlags.Late
                        | CheckFlags.OptionalParameter
                        | CheckFlags.RestParameter)
            );
            result.declarations = symbol.declarations;
            result.parent = symbol.parent;
            result.target = symbol;
            result.mapper = mapper;
            if (symbol.valueDeclaration) {
                result.valueDeclaration = symbol.valueDeclaration;
            }
            if (symbol.nameType) {
                result.nameType = symbol.nameType;
            }
            return result;
        }

        function getObjectTypeInstantiation(
            type: AnonymousType | DeferredTypeReference,
            mapper: TypeMapper
        ) {
            const target = type.objectFlags & ObjectFlags.Instantiated
                ? type.target!
                : type;
            const node = type.objectFlags & ObjectFlags.Reference
                ? (<TypeReference> type).node!
                : type.symbol.declarations[0];
            const links = getNodeLinks(node);
            let typeParameters = links.outerTypeParameters;
            if (!typeParameters) {
                // The first time an anonymous type is instantiated we compute and store a list of the type
                // parameters that are in scope (and therefore potentially referenced). For type literals that
                // aren't the right hand side of a generic type alias declaration we optimize by reducing the
                // set of type parameters to those that are possibly referenced in the literal.
                let declaration = node;
                if (isInJSFile(declaration)) {
                    const paramTag = findAncestor(
                        declaration,
                        isJSDocParameterTag
                    );
                    if (paramTag) {
                        const paramSymbol = getParameterSymbolFromJSDoc(paramTag);
                        if (paramSymbol) {
                            declaration = paramSymbol.valueDeclaration;
                        }
                    }
                }
                let outerTypeParameters = getOuterTypeParameters(
                    declaration, /*includeThisTypes*/
                    true
                );
                if (isJSConstructor(declaration)) {
                    const templateTagParameters = getTypeParametersFromDeclaration(declaration as DeclarationWithTypeParameters);
                    outerTypeParameters = addRange(
                        outerTypeParameters,
                        templateTagParameters
                    );
                }
                typeParameters = outerTypeParameters || emptyArray;
                typeParameters = (target.objectFlags & ObjectFlags.Reference
                    || target.symbol.flags & SymbolFlags.TypeLiteral)
                    && !target.aliasTypeArguments
                    ? filter(
                        typeParameters,
                        tp => isTypeParameterPossiblyReferenced(
                            tp,
                            declaration
                        )
                    )
                    : typeParameters;
                links.outerTypeParameters = typeParameters;
                if (typeParameters.length) {
                    links.instantiations = createMap<Type>();
                    links.instantiations.set(
                        getTypeListId(typeParameters),
                        target
                    );
                }
            }
            if (typeParameters.length) {
                // We are instantiating an anonymous type that has one or more type parameters in scope. Apply the
                // mapper to the type parameters to produce the effective list of type arguments, and compute the
                // instantiation cache key from the type IDs of the type arguments.
                const typeArguments = map(
                    typeParameters,
                    combineTypeMappers(type.mapper, mapper)
                );
                const id = getTypeListId(typeArguments);
                let result = links.instantiations!.get(id);
                if (!result) {
                    const newMapper = createTypeMapper(
                        typeParameters,
                        typeArguments
                    );
                    result = target.objectFlags & ObjectFlags.Reference
                        ? createDeferredTypeReference(
                            (<DeferredTypeReference> type).target,
                            (<DeferredTypeReference> type).node,
                            newMapper
                        )
                        : target.objectFlags & ObjectFlags.Mapped
                            ? instantiateMappedType(
                                <MappedType> target,
                                newMapper
                            )
                            : instantiateAnonymousType(target, newMapper);
                    links.instantiations!.set(id, result);
                }
                return result;
            }
            return type;
        }

        function maybeTypeParameterReference(node: Node) {
            return !(node.kind === SyntaxKind.QualifiedName
                || node.parent.kind === SyntaxKind.TypeReference
                && (<TypeReferenceNode> node.parent).typeArguments
                && node === (<TypeReferenceNode> node.parent).typeName
                || node.parent.kind === SyntaxKind.ImportType
                && (node.parent as ImportTypeNode).typeArguments
                && node === (node.parent as ImportTypeNode).qualifier);
        }

        function isTypeParameterPossiblyReferenced(
            tp: TypeParameter,
            node: Node
        ) {
            // If the type parameter doesn't have exactly one declaration, if there are invening statement blocks
            // between the node and the type parameter declaration, if the node contains actual references to the
            // type parameter, or if the node contains type queries, we consider the type parameter possibly referenced.
            if (tp.symbol && tp.symbol.declarations
                && tp.symbol.declarations.length === 1)
            {
                const container = tp.symbol.declarations[0].parent;
                for (let n = node; n !== container; n = n.parent) {
                    if (!n || n.kind === SyntaxKind.Block
                        || n.kind === SyntaxKind.ConditionalType
                        && forEachChild(
                            (<ConditionalTypeNode> n).extendsType,
                            containsReference
                        ))
                    {
                        return true;
                    }
                }
                return !!forEachChild(node, containsReference);
            }
            return true;
            function containsReference(node: Node): boolean {
                switch (node.kind) {
                    case SyntaxKind.ThisType:
                        return !!tp.isThisType;
                    case SyntaxKind.Identifier:
                        return !tp.isThisType && isPartOfTypeNode(node)
                            && maybeTypeParameterReference(node)
                            && getTypeFromTypeNode(<TypeNode> node) === tp;
                    case SyntaxKind.TypeQuery:
                        return true;
                }
                return !!forEachChild(node, containsReference);
            }
        }

        function getHomomorphicTypeVariable(type: MappedType) {
            const constraintType = getConstraintTypeFromMappedType(type);
            if (constraintType.flags & TypeFlags.Index) {
                const typeVariable = getActualTypeVariable(
                    (<IndexType> constraintType).type
                );
                if (typeVariable.flags & TypeFlags.TypeParameter) {
                    return <TypeParameter> typeVariable;
                }
            }
            return undefined;
        }

        function instantiateMappedType(
            type: MappedType,
            mapper: TypeMapper
        ): Type {
            // For a homomorphic mapped type { [P in keyof T]: X }, where T is some type variable, the mapping
            // operation depends on T as follows:
            // * If T is a primitive type no mapping is performed and the result is simply T.
            // * If T is a union type we distribute the mapped type over the union.
            // * If T is an array we map to an array where the element type has been transformed.
            // * If T is a tuple we map to a tuple where the element types have been transformed.
            // * Otherwise we map to an object type where the type of each property has been transformed.
            // For example, when T is instantiated to a union type A | B, we produce { [P in keyof A]: X } |
            // { [P in keyof B]: X }, and when when T is instantiated to a union type A | undefined, we produce
            // { [P in keyof A]: X } | undefined.
            const typeVariable = getHomomorphicTypeVariable(type);
            if (typeVariable) {
                const mappedTypeVariable = instantiateType(
                    typeVariable,
                    mapper
                );
                if (typeVariable !== mappedTypeVariable) {
                    return mapType(
                        mappedTypeVariable,
                        t => {
                            if (t.flags
                                & (TypeFlags.AnyOrUnknown
                                    | TypeFlags.InstantiableNonPrimitive
                                    | TypeFlags.Object
                                    | TypeFlags.Intersection)
                                && t !== wildcardType && t !== errorType)
                            {
                                const replacementMapper = createReplacementMapper(
                                    typeVariable,
                                    t,
                                    mapper
                                );
                                return isArrayType(t)
                                    ? instantiateMappedArrayType(
                                        t,
                                        type,
                                        replacementMapper
                                    )
                                    : isTupleType(t)
                                        ? instantiateMappedTupleType(
                                            t,
                                            type,
                                            replacementMapper
                                        )
                                        : instantiateAnonymousType(type,
                                            replacementMapper);
                            }
                            return t;
                        }
                    );
                }
            }
            return instantiateAnonymousType(type, mapper);
        }

        function getModifiedReadonlyState(
            state: boolean,
            modifiers: MappedTypeModifiers
        ) {
            return modifiers & MappedTypeModifiers.IncludeReadonly
                ? true
                : modifiers & MappedTypeModifiers.ExcludeReadonly ? false
                    : state;
        }

        function instantiateMappedArrayType(
            arrayType: Type,
            mappedType: MappedType,
            mapper: TypeMapper
        ) {
            const elementType = instantiateMappedTypeTemplate(
                mappedType,
                numberType, /*isOptional*/
                true,
                mapper
            );
            return elementType === errorType
                ? errorType
                : createArrayType(
                    elementType,
                    getModifiedReadonlyState(
                        isReadonlyArrayType(arrayType),
                        getMappedTypeModifiers(mappedType)
                    )
                );
        }

        function instantiateMappedTupleType(
            tupleType: TupleTypeReference,
            mappedType: MappedType,
            mapper: TypeMapper
        ) {
            const minLength = tupleType.target.minLength;
            const elementTypes = map(
                getTypeArguments(tupleType),
                (_, i) => instantiateMappedTypeTemplate(
                    mappedType,
                    getLiteralType('' + i),
                    i >= minLength,
                    mapper
                )
            );
            const modifiers = getMappedTypeModifiers(mappedType);
            const newMinLength = modifiers
                & MappedTypeModifiers.IncludeOptional
                ? 0
                : modifiers & MappedTypeModifiers.ExcludeOptional
                    ? getTypeReferenceArity(tupleType)
                        - (tupleType.target.hasRestElement ? 1 : 0)
                    : minLength;
            const newReadonly = getModifiedReadonlyState(
                tupleType.target.readonly,
                modifiers
            );
            return contains(elementTypes, errorType)
                ? errorType
                : createTupleType(
                    elementTypes,
                    newMinLength,
                    tupleType.target.hasRestElement,
                    newReadonly,
                    tupleType.target.associatedNames
                );
        }

        function instantiateMappedTypeTemplate(
            type: MappedType,
            key: Type,
            isOptional: boolean,
            mapper: TypeMapper
        ) {
            const templateMapper = combineTypeMappers(
                mapper,
                createTypeMapper([getTypeParameterFromMappedType(type)], [key])
            );
            const propType = instantiateType(
                getTemplateTypeFromMappedType(
                    <MappedType> type.target || type
                ),
                templateMapper
            );
            const modifiers = getMappedTypeModifiers(type);
            return strictNullChecks
                && modifiers & MappedTypeModifiers.IncludeOptional
                && !isTypeAssignableTo(undefinedType, propType)
                ? getOptionalType(propType)
                : strictNullChecks
                    && modifiers & MappedTypeModifiers.ExcludeOptional
                    && isOptional
                    ? getTypeWithFacts(propType, TypeFacts.NEUndefined)
                    : propType;
        }

        function instantiateAnonymousType(
            type: AnonymousType,
            mapper: TypeMapper
        ): AnonymousType {
            const result = <AnonymousType> createObjectType(
                type.objectFlags | ObjectFlags.Instantiated,
                type.symbol
            );
            if (type.objectFlags & ObjectFlags.Mapped) {
                (<MappedType> result).declaration = (<MappedType> type)
                    .declaration;
                // C.f. instantiateSignature
                const origTypeParameter = getTypeParameterFromMappedType(<MappedType> type);
                const freshTypeParameter = cloneTypeParameter(origTypeParameter);
                (<MappedType> result).typeParameter = freshTypeParameter;
                mapper = combineTypeMappers(
                    makeUnaryTypeMapper(
                        origTypeParameter,
                        freshTypeParameter
                    ),
                    mapper
                );
                freshTypeParameter.mapper = mapper;
            }
            result.target = type;
            result.mapper = mapper;
            result.aliasSymbol = type.aliasSymbol;
            result
                .aliasTypeArguments = instantiateTypes(
                    type.aliasTypeArguments,
                    mapper
                );
            return result;
        }

        function getConditionalTypeInstantiation(
            type: ConditionalType,
            mapper: TypeMapper
        ): Type {
            const root = type.root;
            if (root.outerTypeParameters) {
                // We are instantiating a conditional type that has one or more type parameters in scope. Apply the
                // mapper to the type parameters to produce the effective list of type arguments, and compute the
                // instantiation cache key from the type IDs of the type arguments.
                const typeArguments = map(root.outerTypeParameters, mapper);
                const id = getTypeListId(typeArguments);
                let result = root.instantiations!.get(id);
                if (!result) {
                    const newMapper = createTypeMapper(
                        root.outerTypeParameters,
                        typeArguments
                    );
                    result = instantiateConditionalType(root, newMapper);
                    root.instantiations!.set(id, result);
                }
                return result;
            }
            return type;
        }

        function instantiateConditionalType(
            root: ConditionalRoot,
            mapper: TypeMapper
        ): Type {
            // Check if we have a conditional type where the check type is a naked type parameter. If so,
            // the conditional type is distributive over union types and when T is instantiated to a union
            // type A | B, we produce (A extends U ? X : Y) | (B extends U ? X : Y).
            if (root.isDistributive) {
                const checkType = <TypeParameter> root.checkType;
                const instantiatedType = mapper(checkType);
                if (checkType !== instantiatedType
                    && instantiatedType.flags
                    & (TypeFlags.Union | TypeFlags.Never))
                {
                    return mapType(
                        instantiatedType,
                        t => getConditionalType(
                            root,
                            createReplacementMapper(checkType, t, mapper)
                        )
                    );
                }
            }
            return getConditionalType(root, mapper);
        }

        function instantiateType(
            type: Type,
            mapper: TypeMapper | undefined
        ): Type;
        function instantiateType(
            type: Type | undefined,
            mapper: TypeMapper | undefined
        ): Type | undefined;
        function instantiateType(
            type: Type | undefined,
            mapper: TypeMapper | undefined
        ): Type | undefined {
            if (!type || !mapper || mapper === identityMapper) {
                return type;
            }
            if (instantiationDepth === 50 || instantiationCount >= 5000000) {
                // We have reached 50 recursive type instantiations and there is a very high likelyhood we're dealing
                // with a combination of infinite generic types that perpetually generate new type identities. We stop
                // the recursion here by yielding the error type.
                error(
                    currentNode,
                    Diagnostics
                        .Type_instantiation_is_excessively_deep_and_possibly_infinite
                );
                return errorType;
            }
            instantiationCount++;
            instantiationDepth++;
            const result = instantiateTypeWorker(type, mapper);
            instantiationDepth--;
            return result;
        }

        function instantiateTypeWorker(type: Type, mapper: TypeMapper): Type {
            const flags = type.flags;
            if (flags & TypeFlags.TypeParameter) {
                return mapper(type);
            }
            if (flags & TypeFlags.Object) {
                const objectFlags = (<ObjectType> type).objectFlags;
                if (objectFlags & ObjectFlags.Anonymous) {
                    // If the anonymous type originates in a declaration of a function, method, class, or
                    // interface, in an object type literal, or in an object literal expression, we may need
                    // to instantiate the type because it might reference a type parameter.
                    return couldContainTypeVariables(type)
                        ? getObjectTypeInstantiation(
                            <AnonymousType> type,
                            mapper
                        )
                        : type;
                }
                if (objectFlags & ObjectFlags.Mapped) {
                    return getObjectTypeInstantiation(
                        <AnonymousType> type,
                        mapper
                    );
                }
                if (objectFlags & ObjectFlags.Reference) {
                    if ((<TypeReference> type).node) {
                        return getObjectTypeInstantiation(
                            <TypeReference> type,
                            mapper
                        );
                    }
                    const resolvedTypeArguments = (<TypeReference> type)
                        .resolvedTypeArguments;
                    const newTypeArguments = instantiateTypes(
                        resolvedTypeArguments,
                        mapper
                    );
                    return newTypeArguments !== resolvedTypeArguments
                        ? createTypeReference(
                            (<TypeReference> type).target,
                            newTypeArguments
                        )
                        : type;
                }
                return type;
            }
            if (flags & TypeFlags.Union && !(flags & TypeFlags.Primitive)) {
                const types = (<UnionType> type).types;
                const newTypes = instantiateTypes(types, mapper);
                return newTypes !== types
                    ? getUnionType(
                        newTypes,
                        UnionReduction.Literal,
                        type.aliasSymbol,
                        instantiateTypes(type.aliasTypeArguments, mapper)
                    )
                    : type;
            }
            if (flags & TypeFlags.Intersection) {
                const types = (<IntersectionType> type).types;
                const newTypes = instantiateTypes(types, mapper);
                return newTypes !== types
                    ? getIntersectionType(
                        newTypes,
                        type.aliasSymbol,
                        instantiateTypes(type.aliasTypeArguments, mapper)
                    )
                    : type;
            }
            if (flags & TypeFlags.Index) {
                return getIndexType(
                    instantiateType(
                        (<IndexType> type).type,
                        mapper
                    )
                );
            }
            if (flags & TypeFlags.IndexedAccess) {
                return getIndexedAccessType(
                    instantiateType(
                        (<IndexedAccessType> type).objectType,
                        mapper
                    ),
                    instantiateType(
                        (<IndexedAccessType> type).indexType,
                        mapper
                    )
                );
            }
            if (flags & TypeFlags.Conditional) {
                return getConditionalTypeInstantiation(
                    <ConditionalType> type,
                    combineTypeMappers((<ConditionalType> type).mapper, mapper)
                );
            }
            if (flags & TypeFlags.Substitution) {
                const maybeVariable = instantiateType(
                    (<SubstitutionType> type).typeVariable,
                    mapper
                );
                if (maybeVariable.flags & TypeFlags.TypeVariable) {
                    return getSubstitutionType(
                        maybeVariable as TypeVariable,
                        instantiateType(
                            (<SubstitutionType> type).substitute,
                            mapper
                        )
                    );
                } else {
                    const sub = instantiateType(
                        (<SubstitutionType> type).substitute,
                        mapper
                    );
                    if (sub.flags & TypeFlags.AnyOrUnknown
                        || isTypeAssignableTo(
                            getRestrictiveInstantiation(maybeVariable),
                            getRestrictiveInstantiation(sub)
                        ))
                    {
                        return maybeVariable;
                    }
                    return sub;
                }
            }
            return type;
        }

        function getPermissiveInstantiation(type: Type) {
            return type.flags
                & (TypeFlags.Primitive | TypeFlags.AnyOrUnknown
                    | TypeFlags.Never)
                ? type
                : type.permissiveInstantiation
                    || (type.permissiveInstantiation = instantiateType(
                        type,
                        permissiveMapper
                    ));
        }

        function getRestrictiveInstantiation(type: Type) {
            if (type.flags
                & (TypeFlags.Primitive | TypeFlags.AnyOrUnknown
                    | TypeFlags.Never))
            {
                return type;
            }
            if (type.restrictiveInstantiation) {
                return type.restrictiveInstantiation;
            }
            type.restrictiveInstantiation = instantiateType(
                type,
                restrictiveMapper
            );
            // We set the following so we don't attempt to set the restrictive instance of a restrictive instance
            // which is redundant - we'll produce new type identities, but all type params have already been mapped.
            // This also gives us a way to detect restrictive instances upon comparisons and _disable_ the "distributeive constraint"
            // assignability check for them, which is distinctly unsafe, as once you have a restrctive instance, all the type parameters
            // are constrained to `unknown` and produce tons of false positives/negatives!
            type.restrictiveInstantiation.restrictiveInstantiation = type
                .restrictiveInstantiation;
            return type.restrictiveInstantiation;
        }

        function instantiateIndexInfo(
            info: IndexInfo | undefined,
            mapper: TypeMapper
        ): IndexInfo | undefined {
            return info
                && createIndexInfo(
                    instantiateType(info.type, mapper),
                    info.isReadonly,
                    info.declaration
                );
        }

        // Returns true if the given expression contains (at any level of nesting) a function or arrow expression
        // that is subject to contextual typing.
        function isContextSensitive(
            node: Expression | MethodDeclaration | ObjectLiteralElementLike
                | JsxAttributeLike | JsxChild
        ): boolean {
            Debug
                .assert(
                    node.kind !== SyntaxKind.MethodDeclaration
                        || isObjectLiteralMethod(node)
                );
            switch (node.kind) {
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.ArrowFunction:
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind
                    .FunctionDeclaration: // Function declarations can have context when annotated with a jsdoc @type
                    return isContextSensitiveFunctionLikeDeclaration(
                        <FunctionExpression | ArrowFunction
                            | MethodDeclaration> node
                    );
                case SyntaxKind.ObjectLiteralExpression:
                    return some(
                        (<ObjectLiteralExpression> node).properties,
                        isContextSensitive
                    );
                case SyntaxKind.ArrayLiteralExpression:
                    return some(
                        (<ArrayLiteralExpression> node).elements,
                        isContextSensitive
                    );
                case SyntaxKind.ConditionalExpression:
                    return isContextSensitive(
                        (<ConditionalExpression> node).whenTrue
                    )
                        || isContextSensitive(
                            (<ConditionalExpression> node).whenFalse
                        );
                case SyntaxKind.BinaryExpression:
                    return ((<BinaryExpression> node).operatorToken.kind
                        === SyntaxKind.BarBarToken
                        || (<BinaryExpression> node).operatorToken.kind
                        === SyntaxKind.QuestionQuestionToken)
                        && (isContextSensitive((<BinaryExpression> node).left)
                            || isContextSensitive(
                                (<BinaryExpression> node).right
                            ));
                case SyntaxKind.PropertyAssignment:
                    return isContextSensitive(
                        (<PropertyAssignment> node).initializer
                    );
                case SyntaxKind.ParenthesizedExpression:
                    return isContextSensitive(
                        (<ParenthesizedExpression> node).expression
                    );
                case SyntaxKind.JsxAttributes:
                    return some(
                        (<JsxAttributes> node).properties,
                        isContextSensitive
                    ) || isJsxOpeningElement(node.parent)
                        && some(
                            node.parent.parent.children,
                            isContextSensitive
                        );
                case SyntaxKind.JsxAttribute: {
                    // If there is no initializer, JSX attribute has a boolean value of true which is not context sensitive.
                    const { initializer } = node as JsxAttribute;
                    return !!initializer && isContextSensitive(initializer);
                }
                case SyntaxKind.JsxExpression: {
                    // It is possible to that node.expression is undefined (e.g <div x={} />)
                    const { expression } = node as JsxExpression;
                    return !!expression && isContextSensitive(expression);
                }
            }

            return false;
        }

        function isContextSensitiveFunctionLikeDeclaration(
            node: FunctionLikeDeclaration
        ): boolean {
            if (isFunctionDeclaration(node)
                && (!isInJSFile(node)
                    || !getTypeForDeclarationFromJSDocComment(node)))
            {
                return false;
            }
            // Functions with type parameters are not context sensitive.
            if (node.typeParameters) {
                return false;
            }
            // Functions with any parameters that lack type annotations are context sensitive.
            if (some(node.parameters,
                p => !getEffectiveTypeAnnotationNode(p)))
            {
                return true;
            }
            if (node.kind !== SyntaxKind.ArrowFunction) {
                // If the first parameter is not an explicit 'this' parameter, then the function has
                // an implicit 'this' parameter which is subject to contextual typing.
                const parameter = firstOrUndefined(node.parameters);
                if (!(parameter && parameterIsThisKeyword(parameter))) {
                    return true;
                }
            }
            return hasContextSensitiveReturnExpression(node);
        }

        function hasContextSensitiveReturnExpression(
            node: FunctionLikeDeclaration
        ) {
            // TODO(anhans): A block should be context-sensitive if it has a context-sensitive return value.
            return !!node.body && node.body.kind !== SyntaxKind.Block
                && isContextSensitive(node.body);
        }

        function isContextSensitiveFunctionOrObjectLiteralMethod(
            func: Node
        ): func is FunctionExpression | ArrowFunction | MethodDeclaration {
            return (isInJSFile(func) && isFunctionDeclaration(func)
                || isFunctionExpressionOrArrowFunction(func)
                || isObjectLiteralMethod(func))
                && isContextSensitiveFunctionLikeDeclaration(func);
        }

        function getTypeWithoutSignatures(type: Type): Type {
            if (type.flags & TypeFlags.Object) {
                const resolved = resolveStructuredTypeMembers(<ObjectType> type);
                if (resolved.constructSignatures.length
                    || resolved.callSignatures.length)
                {
                    const result = createObjectType(
                        ObjectFlags.Anonymous,
                        type.symbol
                    );
                    result.members = resolved.members;
                    result.properties = resolved.properties;
                    result.callSignatures = emptyArray;
                    result.constructSignatures = emptyArray;
                    return result;
                }
            } else if (type.flags & TypeFlags.Intersection) {
                return getIntersectionType(
                    map(
                        (<IntersectionType> type).types,
                        getTypeWithoutSignatures
                    )
                );
            }
            return type;
        }

        // TYPE CHECKING

        function isTypeIdenticalTo(source: Type, target: Type): boolean {
            return isTypeRelatedTo(source, target, identityRelation);
        }

        function compareTypesIdentical(source: Type, target: Type): Ternary {
            return isTypeRelatedTo(source, target, identityRelation)
                ? Ternary.True
                : Ternary.False;
        }

        function compareTypesAssignable(source: Type, target: Type): Ternary {
            return isTypeRelatedTo(source, target, assignableRelation)
                ? Ternary.True
                : Ternary.False;
        }

        function compareTypesSubtypeOf(source: Type, target: Type): Ternary {
            return isTypeRelatedTo(source, target, subtypeRelation)
                ? Ternary.True
                : Ternary.False;
        }

        function isTypeSubtypeOf(source: Type, target: Type): boolean {
            return isTypeRelatedTo(source, target, subtypeRelation);
        }

        function isTypeAssignableTo(source: Type, target: Type): boolean {
            return isTypeRelatedTo(source, target, assignableRelation);
        }

        // An object type S is considered to be derived from an object type T if
        // S is a union type and every constituent of S is derived from T,
        // T is a union type and S is derived from at least one constituent of T, or
        // S is a type variable with a base constraint that is derived from T,
        // T is one of the global types Object and Function and S is a subtype of T, or
        // T occurs directly or indirectly in an 'extends' clause of S.
        // Note that this check ignores type parameters and only considers the
        // inheritance hierarchy.
        function isTypeDerivedFrom(source: Type, target: Type): boolean {
            return source.flags & TypeFlags.Union
                ? every(
                    (<UnionType> source).types,
                    t => isTypeDerivedFrom(t, target)
                )
                : target.flags & TypeFlags.Union
                    ? some(
                        (<UnionType> target).types,
                        t => isTypeDerivedFrom(source, t)
                    )
                    : source.flags & TypeFlags.InstantiableNonPrimitive
                        ? isTypeDerivedFrom(
                            getBaseConstraintOfType(source) || unknownType,
                            target
                        )
                        : target === globalObjectType
                            ? !!(source.flags
                                & (TypeFlags.Object | TypeFlags.NonPrimitive))
                            : target === globalFunctionType
                                ? !!(source.flags & TypeFlags.Object)
                                    && isFunctionObjectType(source as ObjectType)
                                : hasBaseType(source, getTargetType(target));
        }

        /**
         * This is *not* a bi-directional relationship.
         * If one needs to check both directions for comparability, use a second call to this function or 'checkTypeComparableTo'.
         *
         * A type S is comparable to a type T if some (but not necessarily all) of the possible values of S are also possible values of T.
         * It is used to check following cases:
         *   - the types of the left and right sides of equality/inequality operators (`===`, `!==`, `==`, `!=`).
         *   - the types of `case` clause expressions and their respective `switch` expressions.
         *   - the type of an expression in a type assertion with the type being asserted.
         */
        function isTypeComparableTo(source: Type, target: Type): boolean {
            return isTypeRelatedTo(source, target, comparableRelation);
        }

        function areTypesComparable(type1: Type, type2: Type): boolean {
            return isTypeComparableTo(type1, type2)
                || isTypeComparableTo(type2, type1);
        }

        function checkTypeAssignableTo(
            source: Type,
            target: Type,
            errorNode: Node | undefined,
            headMessage?: DiagnosticMessage,
            containingMessageChain?: () => DiagnosticMessageChain | undefined,
            errorOutputObject?: { errors?: Diagnostic[]; }
        ): boolean {
            return checkTypeRelatedTo(
                source,
                target,
                assignableRelation,
                errorNode,
                headMessage,
                containingMessageChain,
                errorOutputObject
            );
        }

        /**
         * Like `checkTypeAssignableTo`, but if it would issue an error, instead performs structural comparisons of the types using the given expression node to
         * attempt to issue more specific errors on, for example, specific object literal properties or tuple members.
         */
        function checkTypeAssignableToAndOptionallyElaborate(
            source: Type,
            target: Type,
            errorNode: Node | undefined,
            expr: Expression | undefined,
            headMessage?: DiagnosticMessage,
            containingMessageChain?: () => DiagnosticMessageChain | undefined
        ): boolean {
            return checkTypeRelatedToAndOptionallyElaborate(
                source,
                target,
                assignableRelation,
                errorNode,
                expr,
                headMessage,
                containingMessageChain, /*errorOutputContainer*/
                undefined
            );
        }

        function checkTypeRelatedToAndOptionallyElaborate(
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            errorNode: Node | undefined,
            expr: Expression | undefined,
            headMessage: DiagnosticMessage | undefined,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } | undefined
        ): boolean {
            if (isTypeRelatedTo(source, target, relation)) return true;
            if (!errorNode
                || !elaborateError(
                    expr,
                    source,
                    target,
                    relation,
                    headMessage,
                    containingMessageChain,
                    errorOutputContainer
                ))
            {
                return checkTypeRelatedTo(
                    source,
                    target,
                    relation,
                    errorNode,
                    headMessage,
                    containingMessageChain,
                    errorOutputContainer
                );
            }
            return false;
        }

        function isOrHasGenericConditional(type: Type): boolean {
            return !!(type.flags & TypeFlags.Conditional
                || (type.flags & TypeFlags.Intersection
                    && some(
                        (type as IntersectionType).types,
                        isOrHasGenericConditional
                    )));
        }

        function elaborateError(
            node: Expression | undefined,
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            headMessage: DiagnosticMessage | undefined,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } | undefined
        ): boolean {
            if (!node || isOrHasGenericConditional(target)) return false;
            if (!checkTypeRelatedTo(
                source,
                target,
                relation, /*errorNode*/
                undefined
            )
                && elaborateDidYouMeanToCallOrConstruct(
                    node,
                    source,
                    target,
                    relation,
                    headMessage,
                    containingMessageChain,
                    errorOutputContainer
                ))
            {
                return true;
            }
            switch (node.kind) {
                case SyntaxKind.JsxExpression:
                case SyntaxKind.ParenthesizedExpression:
                    return elaborateError(
                        (node as ParenthesizedExpression | JsxExpression)
                            .expression,
                        source,
                        target,
                        relation,
                        headMessage,
                        containingMessageChain,
                        errorOutputContainer
                    );
                case SyntaxKind.BinaryExpression:
                    switch ((node as BinaryExpression).operatorToken.kind) {
                        case SyntaxKind.EqualsToken:
                        case SyntaxKind.CommaToken:
                            return elaborateError(
                                (node as BinaryExpression).right,
                                source,
                                target,
                                relation,
                                headMessage,
                                containingMessageChain,
                                errorOutputContainer
                            );
                    }
                    break;
                case SyntaxKind.ObjectLiteralExpression:
                    return elaborateObjectLiteral(
                        node as ObjectLiteralExpression,
                        source,
                        target,
                        relation,
                        containingMessageChain,
                        errorOutputContainer
                    );
                case SyntaxKind.ArrayLiteralExpression:
                    return elaborateArrayLiteral(
                        node as ArrayLiteralExpression,
                        source,
                        target,
                        relation,
                        containingMessageChain,
                        errorOutputContainer
                    );
                case SyntaxKind.JsxAttributes:
                    return elaborateJsxComponents(
                        node as JsxAttributes,
                        source,
                        target,
                        relation,
                        containingMessageChain,
                        errorOutputContainer
                    );
                case SyntaxKind.ArrowFunction:
                    return elaborateArrowFunction(
                        node as ArrowFunction,
                        source,
                        target,
                        relation,
                        containingMessageChain,
                        errorOutputContainer
                    );
            }
            return false;
        }

        function elaborateDidYouMeanToCallOrConstruct(
            node: Expression,
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            headMessage: DiagnosticMessage | undefined,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } | undefined
        ): boolean {
            const callSignatures = getSignaturesOfType(
                source,
                SignatureKind.Call
            );
            const constructSignatures = getSignaturesOfType(
                source,
                SignatureKind.Construct
            );
            for (const signatures of [constructSignatures, callSignatures]) {
                if (some(
                    signatures,
                    s => {
                        const returnType = getReturnTypeOfSignature(s);
                        return !(returnType.flags
                            & (TypeFlags.Any | TypeFlags.Never))
                            && checkTypeRelatedTo(
                                returnType,
                                target,
                                relation, /*errorNode*/
                                undefined
                            );
                    }
                )) {
                    const resultObj:
                        { errors?: Diagnostic[]; } = errorOutputContainer
                        || {};
                    checkTypeAssignableTo(
                        source,
                        target,
                        node,
                        headMessage,
                        containingMessageChain,
                        resultObj
                    );
                    const diagnostic = resultObj.errors!
                        [resultObj.errors!.length - 1];
                    addRelatedInfo(
                        diagnostic,
                        createDiagnosticForNode(
                            node,
                            signatures === constructSignatures
                                ? Diagnostics
                                    .Did_you_mean_to_use_new_with_this_expression
                                : Diagnostics
                                    .Did_you_mean_to_call_this_expression
                        )
                    );
                    return true;
                }
            }
            return false;
        }

        function elaborateArrowFunction(
            node: ArrowFunction,
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } | undefined
        ): boolean {
            // Don't elaborate blocks
            if (isBlock(node.body)) {
                return false;
            }
            // Or functions with annotated parameter types
            if (some(node.parameters, ts.hasType)) {
                return false;
            }
            const sourceSig = getSingleCallSignature(source);
            if (!sourceSig) {
                return false;
            }
            const targetSignatures = getSignaturesOfType(
                target,
                SignatureKind.Call
            );
            if (!length(targetSignatures)) {
                return false;
            }
            const returnExpression = node.body;
            const sourceReturn = getReturnTypeOfSignature(sourceSig);
            const targetReturn = getUnionType(
                map(
                    targetSignatures,
                    getReturnTypeOfSignature
                )
            );
            if (!checkTypeRelatedTo(
                sourceReturn,
                targetReturn,
                relation, /*errorNode*/
                undefined
            )) {
                const elaborated = returnExpression
                    && elaborateError(
                        returnExpression,
                        sourceReturn,
                        targetReturn,
                        relation, /*headMessage*/
                        undefined,
                        containingMessageChain,
                        errorOutputContainer
                    );
                if (elaborated) {
                    return elaborated;
                }
                const resultObj:
                    { errors?: Diagnostic[]; } = errorOutputContainer || {};
                checkTypeRelatedTo(
                    sourceReturn,
                    targetReturn,
                    relation,
                    returnExpression, /*message*/
                    undefined,
                    containingMessageChain,
                    resultObj
                );
                if (resultObj.errors) {
                    if (target.symbol && length(target.symbol.declarations)) {
                        addRelatedInfo(
                            resultObj.errors[resultObj.errors.length - 1],
                            createDiagnosticForNode(
                                target.symbol.declarations[0],
                                Diagnostics
                                    .The_expected_type_comes_from_the_return_type_of_this_signature
                            )
                        );
                    }
                    return true;
                }
            }
            return false;
        }

        function getBestMatchIndexedAccessTypeOrUndefined(
            source: Type,
            target: Type,
            nameType: Type
        ) {
            const idx = getIndexedAccessTypeOrUndefined(target, nameType);
            if (idx) {
                return idx;
            }
            if (target.flags & TypeFlags.Union) {
                const best = getBestMatchingType(source, target as UnionType);
                if (best) {
                    return getIndexedAccessTypeOrUndefined(best, nameType);
                }
            }
        }

        type ElaborationIterator = IterableIterator<{ errorNode: Node;
            innerExpression: Expression | undefined; nameType: Type;
            errorMessage?: DiagnosticMessage | undefined; }>;
        /**
         * For every element returned from the iterator, checks that element to issue an error on a property of that element's type
         * If that element would issue an error, we first attempt to dive into that element's inner expression and issue a more specific error by recuring into `elaborateError`
         * Otherwise, we issue an error on _every_ element which fail the assignability check
         */
        function elaborateElementwise(
            iterator: ElaborationIterator,
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } | undefined
        ) {
            // Assignability failure - check each prop individually, and if that fails, fall back on the bad error span
            let reportedError = false;
            for (let status = iterator.next(); !status.done; status = iterator
                .next())
            {
                const { errorNode: prop, innerExpression: next, nameType,
                    errorMessage } = status.value;
                const targetPropType = getBestMatchIndexedAccessTypeOrUndefined(
                    source,
                    target,
                    nameType
                );
                if (!targetPropType
                    || targetPropType.flags & TypeFlags.IndexedAccess)
                {
                    continue; // Don't elaborate on indexes on generic variables
                }
                const sourcePropType = getIndexedAccessTypeOrUndefined(
                    source,
                    nameType
                );
                if (sourcePropType
                    && !checkTypeRelatedTo(
                        sourcePropType,
                        targetPropType,
                        relation, /*errorNode*/
                        undefined
                    ))
                {
                    const elaborated = next
                        && elaborateError(
                            next,
                            sourcePropType,
                            targetPropType,
                            relation, /*headMessage*/
                            undefined,
                            containingMessageChain,
                            errorOutputContainer
                        );
                    if (elaborated) {
                        reportedError = true;
                    } else {
                        // Issue error on the prop itself, since the prop couldn't elaborate the error
                        const resultObj:
                            { errors?: Diagnostic[]; } = errorOutputContainer
                            || {};
                        // Use the expression type, if available
                        const specificSource = next
                            ? checkExpressionForMutableLocation(
                                next,
                                CheckMode.Normal,
                                sourcePropType
                            )
                            : sourcePropType;
                        const result = checkTypeRelatedTo(
                            specificSource,
                            targetPropType,
                            relation,
                            prop,
                            errorMessage,
                            containingMessageChain,
                            resultObj
                        );
                        if (result && specificSource !== sourcePropType) {
                            // If for whatever reason the expression type doesn't yield an error, make sure we still issue an error on the sourcePropType
                            checkTypeRelatedTo(
                                sourcePropType,
                                targetPropType,
                                relation,
                                prop,
                                errorMessage,
                                containingMessageChain,
                                resultObj
                            );
                        }
                        if (resultObj.errors) {
                            const reportedDiag = resultObj.errors
                                [resultObj.errors.length - 1];
                            const propertyName = isTypeUsableAsPropertyName(nameType)
                                ? getPropertyNameFromType(nameType)
                                : undefined;
                            const targetProp = propertyName !== undefined
                                ? getPropertyOfType(target, propertyName)
                                : undefined;

                            let issuedElaboration = false;
                            if (!targetProp) {
                                const indexInfo = isTypeAssignableToKind(
                                    nameType,
                                    TypeFlags.NumberLike
                                )
                                    && getIndexInfoOfType(
                                        target,
                                        IndexKind.Number
                                    )
                                    || getIndexInfoOfType(
                                        target,
                                        IndexKind.String
                                    )
                                    || undefined;
                                if (indexInfo && indexInfo.declaration
                                    && !getSourceFileOfNode(
                                        indexInfo.declaration
                                    ).hasNoDefaultLib)
                                {
                                    issuedElaboration = true;
                                    addRelatedInfo(
                                        reportedDiag,
                                        createDiagnosticForNode(
                                            indexInfo.declaration,
                                            Diagnostics
                                                .The_expected_type_comes_from_this_index_signature
                                        )
                                    );
                                }
                            }

                            if (!issuedElaboration
                                && (targetProp
                                    && length(targetProp.declarations)
                                    || target.symbol
                                    && length(target.symbol.declarations)))
                            {
                                const targetNode = targetProp
                                    && length(targetProp.declarations)
                                    ? targetProp.declarations[0]
                                    : target.symbol.declarations[0];
                                if (!getSourceFileOfNode(targetNode)
                                    .hasNoDefaultLib)
                                {
                                    addRelatedInfo(
                                        reportedDiag,
                                        createDiagnosticForNode(
                                            targetNode,
                                            Diagnostics
                                                .The_expected_type_comes_from_property_0_which_is_declared_here_on_type_1,
                                            propertyName
                                                && !(nameType.flags
                                                    & TypeFlags.UniqueESSymbol)
                                                ? unescapeLeadingUnderscores(propertyName)
                                                : typeToString(nameType),
                                            typeToString(target)
                                        )
                                    );
                                }
                            }
                        }
                        reportedError = true;
                    }
                }
            }
            return reportedError;
        }

        function* generateJsxAttributes(
            node: JsxAttributes
        ): ElaborationIterator {
            if (!length(node.properties)) return;
            for (const prop of node.properties) {
                if (isJsxSpreadAttribute(prop)) continue;
                yield { errorNode: prop.name,
                    innerExpression: prop.initializer,
                    nameType: getLiteralType(idText(prop.name)) };
            }
        }

        function* generateJsxChildren(
            node: JsxElement,
            getInvalidTextDiagnostic: () => DiagnosticMessage
        ): ElaborationIterator {
            if (!length(node.children)) return;
            let memberOffset = 0;
            for (let i = 0; i < node.children.length; i++) {
                const child = node.children[i];
                const nameType = getLiteralType(i - memberOffset);
                const elem = getElaborationElementForJsxChild(
                    child,
                    nameType,
                    getInvalidTextDiagnostic
                );
                if (elem) {
                    yield elem;
                } else {
                    memberOffset++;
                }
            }
        }

        function getElaborationElementForJsxChild(
            child: JsxChild,
            nameType: LiteralType,
            getInvalidTextDiagnostic: () => DiagnosticMessage
        ) {
            switch (child.kind) {
                case SyntaxKind.JsxExpression:
                    // child is of the type of the expression
                    return { errorNode: child,
                        innerExpression: child.expression, nameType };
                case SyntaxKind.JsxText:
                    if (child.containsOnlyTriviaWhiteSpaces) {
                        break; // Whitespace only jsx text isn't real jsx text
                    }
                    // child is a string
                    return { errorNode: child, innerExpression: undefined,
                        nameType, errorMessage: getInvalidTextDiagnostic() };
                case SyntaxKind.JsxElement:
                case SyntaxKind.JsxSelfClosingElement:
                case SyntaxKind.JsxFragment:
                    // child is of type JSX.Element
                    return { errorNode: child, innerExpression: child,
                        nameType };
                default:
                    return Debug.assertNever(child, 'Found invalid jsx child');
            }
        }

        function getSemanticJsxChildren(children: NodeArray<JsxChild>) {
            return filter(
                children,
                i => !isJsxText(i) || !i.containsOnlyTriviaWhiteSpaces
            );
        }

        function elaborateJsxComponents(
            node: JsxAttributes,
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } | undefined
        ) {
            let result = elaborateElementwise(
                generateJsxAttributes(node),
                source,
                target,
                relation,
                containingMessageChain,
                errorOutputContainer
            );
            let invalidTextDiagnostic: DiagnosticMessage | undefined;
            if (isJsxOpeningElement(node.parent)
                && isJsxElement(node.parent.parent))
            {
                const containingElement = node.parent.parent;
                const childPropName = getJsxElementChildrenPropertyName(getJsxNamespaceAt(node));
                const childrenPropName = childPropName === undefined
                    ? 'children'
                    : unescapeLeadingUnderscores(childPropName);
                const childrenNameType = getLiteralType(childrenPropName);
                const childrenTargetType = getIndexedAccessType(
                    target,
                    childrenNameType
                );
                const validChildren = getSemanticJsxChildren(
                    containingElement.children
                );
                if (!length(validChildren)) {
                    return result;
                }
                const moreThanOneRealChildren = length(validChildren) > 1;
                const arrayLikeTargetParts = filterType(
                    childrenTargetType,
                    isArrayOrTupleLikeType
                );
                const nonArrayLikeTargetParts = filterType(
                    childrenTargetType,
                    t => !isArrayOrTupleLikeType(t)
                );
                if (moreThanOneRealChildren) {
                    if (arrayLikeTargetParts !== neverType) {
                        const realSource = createTupleType(
                            checkJsxChildren(
                                containingElement,
                                CheckMode.Normal
                            )
                        );
                        const children = generateJsxChildren(
                            containingElement,
                            getInvalidTextualChildDiagnostic
                        );
                        result = elaborateElementwise(
                            children,
                            realSource,
                            arrayLikeTargetParts,
                            relation,
                            containingMessageChain,
                            errorOutputContainer
                        ) || result;
                    } else if (!isTypeRelatedTo(
                        getIndexedAccessType(
                            source,
                            childrenNameType
                        ),
                        childrenTargetType,
                        relation
                    )) {
                        // arity mismatch
                        result = true;
                        const diag = error(
                            containingElement.openingElement.tagName,
                            Diagnostics
                                .This_JSX_tag_s_0_prop_expects_a_single_child_of_type_1_but_multiple_children_were_provided,
                            childrenPropName,
                            typeToString(childrenTargetType)
                        );
                        if (errorOutputContainer
                            && errorOutputContainer.skipLogging)
                        {
                            (errorOutputContainer.errors
                                || (errorOutputContainer.errors = []))
                                .push(diag);
                        }
                    }
                } else {
                    if (nonArrayLikeTargetParts !== neverType) {
                        const child = validChildren[0];
                        const elem = getElaborationElementForJsxChild(
                            child,
                            childrenNameType,
                            getInvalidTextualChildDiagnostic
                        );
                        if (elem) {
                            result = elaborateElementwise(
                                (function*() {
                                    yield elem;
                                })(),
                                source,
                                target,
                                relation,
                                containingMessageChain,
                                errorOutputContainer
                            ) || result;
                        }
                    } else if (!isTypeRelatedTo(
                        getIndexedAccessType(
                            source,
                            childrenNameType
                        ),
                        childrenTargetType,
                        relation
                    )) {
                        // arity mismatch
                        result = true;
                        const diag = error(
                            containingElement.openingElement.tagName,
                            Diagnostics
                                .This_JSX_tag_s_0_prop_expects_type_1_which_requires_multiple_children_but_only_a_single_child_was_provided,
                            childrenPropName,
                            typeToString(childrenTargetType)
                        );
                        if (errorOutputContainer
                            && errorOutputContainer.skipLogging)
                        {
                            (errorOutputContainer.errors
                                || (errorOutputContainer.errors = []))
                                .push(diag);
                        }
                    }
                }
            }
            return result;

            function getInvalidTextualChildDiagnostic() {
                if (!invalidTextDiagnostic) {
                    const tagNameText = getTextOfNode(node.parent.tagName);
                    const childPropName = getJsxElementChildrenPropertyName(getJsxNamespaceAt(node));
                    const childrenPropName = childPropName === undefined
                        ? 'children'
                        : unescapeLeadingUnderscores(childPropName);
                    const childrenTargetType = getIndexedAccessType(
                        target,
                        getLiteralType(childrenPropName)
                    );
                    const diagnostic = Diagnostics
                        ._0_components_don_t_accept_text_as_child_elements_Text_in_JSX_has_the_type_string_but_the_expected_type_of_1_is_2;
                    invalidTextDiagnostic = { ...diagnostic,
                        key: '!!ALREADY FORMATTED!!',
                        message: formatMessage(
                            /*_dummy*/ undefined,
                            diagnostic,
                            tagNameText,
                            childrenPropName,
                            typeToString(childrenTargetType)
                        ) };
                }
                return invalidTextDiagnostic;
            }
        }

        function* generateLimitedTupleElements(
            node: ArrayLiteralExpression,
            target: Type
        ): ElaborationIterator {
            const len = length(node.elements);
            if (!len) return;
            for (let i = 0; i < len; i++) {
                // Skip elements which do not exist in the target - a length error on the tuple overall is likely better than an error on a mismatched index signature
                if (isTupleLikeType(target)
                    && !getPropertyOfType(target, ('' + i) as __String))
                {
                    continue;
                }
                const elem = node.elements[i];
                if (isOmittedExpression(elem)) continue;
                const nameType = getLiteralType(i);
                yield { errorNode: elem, innerExpression: elem, nameType };
            }
        }

        function elaborateArrayLiteral(
            node: ArrayLiteralExpression,
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } | undefined
        ) {
            if (target.flags & TypeFlags.Primitive) return false;
            if (isTupleLikeType(source)) {
                return elaborateElementwise(
                    generateLimitedTupleElements(
                        node,
                        target
                    ),
                    source,
                    target,
                    relation,
                    containingMessageChain,
                    errorOutputContainer
                );
            }
            // recreate a tuple from the elements, if possible
            const tupleizedType = checkArrayLiteral(
                node,
                CheckMode.Contextual, /*forceTuple*/
                true
            );
            if (isTupleLikeType(tupleizedType)) {
                return elaborateElementwise(
                    generateLimitedTupleElements(
                        node,
                        target
                    ),
                    tupleizedType,
                    target,
                    relation,
                    containingMessageChain,
                    errorOutputContainer
                );
            }
            return false;
        }

        function* generateObjectLiteralElements(
            node: ObjectLiteralExpression
        ): ElaborationIterator {
            if (!length(node.properties)) return;
            for (const prop of node.properties) {
                if (isSpreadAssignment(prop)) continue;
                const type = getLiteralTypeFromProperty(
                    getSymbolOfNode(prop),
                    TypeFlags.StringOrNumberLiteralOrUnique
                );
                if (!type || (type.flags & TypeFlags.Never)) {
                    continue;
                }
                switch (prop.kind) {
                    case SyntaxKind.SetAccessor:
                    case SyntaxKind.GetAccessor:
                    case SyntaxKind.MethodDeclaration:
                    case SyntaxKind.ShorthandPropertyAssignment:
                        yield { errorNode: prop.name,
                            innerExpression: undefined, nameType: type };
                        break;
                    case SyntaxKind.PropertyAssignment:
                        yield { errorNode: prop.name,
                            innerExpression: prop.initializer, nameType: type,
                            errorMessage: isComputedNonLiteralName(prop.name)
                                ? Diagnostics
                                    .Type_of_computed_property_s_value_is_0_which_is_not_assignable_to_type_1
                                : undefined };
                        break;
                    default:
                        Debug.assertNever(prop);
                }
            }
        }

        function elaborateObjectLiteral(
            node: ObjectLiteralExpression,
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } | undefined
        ) {
            if (target.flags & TypeFlags.Primitive) return false;
            return elaborateElementwise(
                generateObjectLiteralElements(node),
                source,
                target,
                relation,
                containingMessageChain,
                errorOutputContainer
            );
        }

        /**
         * This is *not* a bi-directional relationship.
         * If one needs to check both directions for comparability, use a second call to this function or 'isTypeComparableTo'.
         */
        function checkTypeComparableTo(
            source: Type,
            target: Type,
            errorNode: Node,
            headMessage?: DiagnosticMessage,
            containingMessageChain?: () => DiagnosticMessageChain | undefined
        ): boolean {
            return checkTypeRelatedTo(
                source,
                target,
                comparableRelation,
                errorNode,
                headMessage,
                containingMessageChain
            );
        }

        function isSignatureAssignableTo(
            source: Signature,
            target: Signature,
            ignoreReturnTypes: boolean
        ): boolean {
            return compareSignaturesRelated(
                source,
                target,
                ignoreReturnTypes
                    ? SignatureCheckMode.IgnoreReturnTypes
                    : 0, /*reportErrors*/
                false,
                /*errorReporter*/ undefined, /*errorReporter*/
                undefined,
                compareTypesAssignable, /*reportUnreliableMarkers*/
                undefined
            ) !== Ternary.False;
        }

        type ErrorReporter = (
            message: DiagnosticMessage,
            arg0?: string,
            arg1?: string
        ) => void;

        /**
         * Returns true if `s` is `(...args: any[]) => any` or `(this: any, ...args: any[]) => any`
         */
        function isAnySignature(s: Signature) {
            return !s.typeParameters
                && (!s.thisParameter
                    || isTypeAny(getTypeOfParameter(s.thisParameter)))
                && s.parameters.length === 1
                && signatureHasRestParameter(s)
                && (getTypeOfParameter(s.parameters[0]) === anyArrayType
                    || isTypeAny(getTypeOfParameter(s.parameters[0])))
                && isTypeAny(getReturnTypeOfSignature(s));
        }

        /**
         * See signatureRelatedTo, compareSignaturesIdentical
         */
        function compareSignaturesRelated(
            source: Signature,
            target: Signature,
            checkMode: SignatureCheckMode,
            reportErrors: boolean,
            errorReporter: ErrorReporter | undefined,
            incompatibleErrorReporter: ((source: Type, target: Type) => void)
                | undefined,
            compareTypes: TypeComparer,
            reportUnreliableMarkers: TypeMapper | undefined
        ): Ternary {
            // TODO (drosen): De-duplicate code between related functions.
            if (source === target) {
                return Ternary.True;
            }

            if (isAnySignature(target)) {
                return Ternary.True;
            }

            const targetCount = getParameterCount(target);
            const sourceHasMoreParameters = !hasEffectiveRestParameter(target)
                && (checkMode & SignatureCheckMode.StrictArity
                    ? hasEffectiveRestParameter(source) || getParameterCount(
                        source
                    ) > targetCount
                    : getMinArgumentCount(source) > targetCount);
            if (sourceHasMoreParameters) {
                return Ternary.False;
            }

            if (source.typeParameters
                && source.typeParameters !== target.typeParameters)
            {
                target = getCanonicalSignature(target);
                source = instantiateSignatureInContextOf(
                    source,
                    target, /*inferenceContext*/
                    undefined,
                    compareTypes
                );
            }

            const sourceCount = getParameterCount(source);
            const sourceRestType = getNonArrayRestType(source);
            const targetRestType = getNonArrayRestType(target);
            if (sourceRestType || targetRestType) {
                void instantiateType(
                    sourceRestType || targetRestType,
                    reportUnreliableMarkers
                );
            }
            if (sourceRestType && targetRestType
                && sourceCount !== targetCount)
            {
                // We're not able to relate misaligned complex rest parameters
                return Ternary.False;
            }

            const kind = target.declaration
                ? target.declaration.kind
                : SyntaxKind.Unknown;
            const strictVariance = !(checkMode & SignatureCheckMode.Callback)
                && strictFunctionTypes && kind !== SyntaxKind.MethodDeclaration
                && kind !== SyntaxKind.MethodSignature
                && kind !== SyntaxKind.Constructor;
            let result = Ternary.True;

            const sourceThisType = getThisTypeOfSignature(source);
            if (sourceThisType && sourceThisType !== voidType) {
                const targetThisType = getThisTypeOfSignature(target);
                if (targetThisType) {
                    // void sources are assignable to anything.
                    const related = !strictVariance
                        && compareTypes(
                            sourceThisType,
                            targetThisType, /*reportErrors*/
                            false
                        )
                        || compareTypes(
                            targetThisType,
                            sourceThisType,
                            reportErrors
                        );
                    if (!related) {
                        if (reportErrors) {
                            errorReporter!(
                                Diagnostics
                                    .The_this_types_of_each_signature_are_incompatible
                            );
                        }
                        return Ternary.False;
                    }
                    result &= related;
                }
            }

            const paramCount = sourceRestType || targetRestType
                ? Math.min(sourceCount, targetCount)
                : Math.max(sourceCount, targetCount);
            const restIndex = sourceRestType || targetRestType
                ? paramCount - 1
                : -1;

            for (let i = 0; i < paramCount; i++) {
                const sourceType = i === restIndex
                    ? getRestTypeAtPosition(source, i)
                    : getTypeAtPosition(source, i);
                const targetType = i === restIndex
                    ? getRestTypeAtPosition(target, i)
                    : getTypeAtPosition(target, i);
                // In order to ensure that any generic type Foo<T> is at least co-variant with respect to T no matter
                // how Foo uses T, we need to relate parameters bi-variantly (given that parameters are input positions,
                // they naturally relate only contra-variantly). However, if the source and target parameters both have
                // function types with a single call signature, we know we are relating two callback parameters. In
                // that case it is sufficient to only relate the parameters of the signatures co-variantly because,
                // similar to return values, callback parameters are output positions. This means that a Promise<T>,
                // where T is used only in callback parameter positions, will be co-variant (as opposed to bi-variant)
                // with respect to T.
                const sourceSig = checkMode & SignatureCheckMode.Callback
                    ? undefined
                    : getSingleCallSignature(getNonNullableType(sourceType));
                const targetSig = checkMode & SignatureCheckMode.Callback
                    ? undefined
                    : getSingleCallSignature(getNonNullableType(targetType));
                const callbacks = sourceSig && targetSig
                    && !getTypePredicateOfSignature(sourceSig)
                    && !getTypePredicateOfSignature(targetSig)
                    && (getFalsyFlags(sourceType) & TypeFlags.Nullable)
                    === (getFalsyFlags(targetType) & TypeFlags.Nullable);
                let related = callbacks
                    ? compareSignaturesRelated(
                        targetSig!,
                        sourceSig!,
                        (checkMode & SignatureCheckMode.StrictArity)
                            | (strictVariance
                                ? SignatureCheckMode.StrictCallback
                                : SignatureCheckMode.BivariantCallback),
                        reportErrors,
                        errorReporter,
                        incompatibleErrorReporter,
                        compareTypes,
                        reportUnreliableMarkers
                    )
                    : !(checkMode & SignatureCheckMode.Callback)
                        && !strictVariance && compareTypes(
                            sourceType,
                            targetType, /*reportErrors*/
                            false
                        ) || compareTypes(
                            targetType,
                            sourceType,
                            reportErrors
                        );
                // With strict arity, (x: number | undefined) => void is a subtype of (x?: number | undefined) => void
                if (related && checkMode & SignatureCheckMode.StrictArity
                    && i >= getMinArgumentCount(source)
                    && i < getMinArgumentCount(target)
                    && compareTypes(
                        sourceType,
                        targetType, /*reportErrors*/
                        false
                    ))
                {
                    related = Ternary.False;
                }
                if (!related) {
                    if (reportErrors) {
                        errorReporter!(
                            Diagnostics
                                .Types_of_parameters_0_and_1_are_incompatible,
                            unescapeLeadingUnderscores(
                                getParameterNameAtPosition(
                                    source,
                                    i
                                )
                            ),
                            unescapeLeadingUnderscores(
                                getParameterNameAtPosition(
                                    target,
                                    i
                                )
                            )
                        );
                    }
                    return Ternary.False;
                }
                result &= related;
            }

            if (!(checkMode & SignatureCheckMode.IgnoreReturnTypes)) {
                // If a signature resolution is already in-flight, skip issuing a circularity error
                // here and just use the `any` type directly
                const targetReturnType = isResolvingReturnTypeOfSignature(target)
                    ? anyType
                    : target.declaration && isJSConstructor(target.declaration)
                        ? getDeclaredTypeOfClassOrInterface(
                            getMergedSymbol(
                                target.declaration.symbol
                            )
                        )
                        : getReturnTypeOfSignature(target);
                if (targetReturnType === voidType) {
                    return result;
                }
                const sourceReturnType = isResolvingReturnTypeOfSignature(source)
                    ? anyType
                    : source.declaration && isJSConstructor(source.declaration)
                        ? getDeclaredTypeOfClassOrInterface(
                            getMergedSymbol(
                                source.declaration.symbol
                            )
                        )
                        : getReturnTypeOfSignature(source);

                // The following block preserves behavior forbidding boolean returning functions from being assignable to type guard returning functions
                const targetTypePredicate = getTypePredicateOfSignature(target);
                if (targetTypePredicate) {
                    const sourceTypePredicate = getTypePredicateOfSignature(source);
                    if (sourceTypePredicate) {
                        result &= compareTypePredicateRelatedTo(
                            sourceTypePredicate,
                            targetTypePredicate,
                            reportErrors,
                            errorReporter,
                            compareTypes
                        );
                    } else if (isIdentifierTypePredicate(targetTypePredicate)) {
                        if (reportErrors) {
                            errorReporter!(
                                Diagnostics
                                    .Signature_0_must_be_a_type_predicate,
                                signatureToString(source)
                            );
                        }
                        return Ternary.False;
                    }
                } else {
                    // When relating callback signatures, we still need to relate return types bi-variantly as otherwise
                    // the containing type wouldn't be co-variant. For example, interface Foo<T> { add(cb: () => T): void }
                    // wouldn't be co-variant for T without this rule.
                    result &= checkMode & SignatureCheckMode.BivariantCallback
                        && compareTypes(
                            targetReturnType,
                            sourceReturnType, /*reportErrors*/
                            false
                        )
                        || compareTypes(
                            sourceReturnType,
                            targetReturnType,
                            reportErrors
                        );
                    if (!result && reportErrors && incompatibleErrorReporter) {
                        incompatibleErrorReporter(
                            sourceReturnType,
                            targetReturnType
                        );
                    }
                }
            }

            return result;
        }

        function compareTypePredicateRelatedTo(
            source: TypePredicate,
            target: TypePredicate,
            reportErrors: boolean,
            errorReporter: ErrorReporter | undefined,
            compareTypes: (s: Type, t: Type, reportErrors?: boolean) => Ternary
        ): Ternary {
            if (source.kind !== target.kind) {
                if (reportErrors) {
                    errorReporter!(
                        Diagnostics
                            .A_this_based_type_guard_is_not_compatible_with_a_parameter_based_type_guard
                    );
                    errorReporter!(
                        Diagnostics.Type_predicate_0_is_not_assignable_to_1,
                        typePredicateToString(source),
                        typePredicateToString(target)
                    );
                }
                return Ternary.False;
            }

            if (source.kind === TypePredicateKind.Identifier
                || source.kind === TypePredicateKind.AssertsIdentifier)
            {
                if (source.parameterIndex
                    !== (target as IdentifierTypePredicate).parameterIndex)
                {
                    if (reportErrors) {
                        errorReporter!(
                            Diagnostics
                                .Parameter_0_is_not_in_the_same_position_as_parameter_1,
                            source.parameterName,
                            (target as IdentifierTypePredicate).parameterName
                        );
                        errorReporter!(
                            Diagnostics
                                .Type_predicate_0_is_not_assignable_to_1,
                            typePredicateToString(source),
                            typePredicateToString(target)
                        );
                    }
                    return Ternary.False;
                }
            }

            const related = source.type === target.type
                ? Ternary.True
                : source.type && target.type
                    ? compareTypes(source.type, target.type, reportErrors)
                    : Ternary.False;
            if (related === Ternary.False && reportErrors) {
                errorReporter!(
                    Diagnostics.Type_predicate_0_is_not_assignable_to_1,
                    typePredicateToString(source),
                    typePredicateToString(target)
                );
            }
            return related;
        }

        function isImplementationCompatibleWithOverload(
            implementation: Signature,
            overload: Signature
        ): boolean {
            const erasedSource = getErasedSignature(implementation);
            const erasedTarget = getErasedSignature(overload);

            // First see if the return types are compatible in either direction.
            const sourceReturnType = getReturnTypeOfSignature(erasedSource);
            const targetReturnType = getReturnTypeOfSignature(erasedTarget);
            if (targetReturnType === voidType
                || isTypeRelatedTo(
                    targetReturnType,
                    sourceReturnType,
                    assignableRelation
                )
                || isTypeRelatedTo(
                    sourceReturnType,
                    targetReturnType,
                    assignableRelation
                ))
            {
                return isSignatureAssignableTo(
                    erasedSource,
                    erasedTarget, /*ignoreReturnTypes*/
                    true
                );
            }

            return false;
        }

        function isEmptyResolvedType(t: ResolvedType) {
            return t.properties.length === 0
                && t.callSignatures.length === 0
                && t.constructSignatures.length === 0
                && !t.stringIndexInfo
                && !t.numberIndexInfo;
        }

        function isEmptyObjectType(type: Type): boolean {
            return type.flags & TypeFlags.Object
                ? !isGenericMappedType(type) && isEmptyResolvedType(
                    resolveStructuredTypeMembers(<ObjectType> type)
                )
                : type.flags & TypeFlags.NonPrimitive
                    ? true
                    : type.flags & TypeFlags.Union
                        ? some((<UnionType> type).types, isEmptyObjectType)
                        : type.flags & TypeFlags.Intersection
                            ? every(
                                (<UnionType> type).types,
                                isEmptyObjectType
                            )
                            : false;
        }

        function isEmptyAnonymousObjectType(type: Type) {
            return !!(getObjectFlags(type) & ObjectFlags.Anonymous)
                && isEmptyObjectType(type);
        }

        function isStringIndexSignatureOnlyType(type: Type): boolean {
            return type.flags & TypeFlags.Object && !isGenericMappedType(type)
                && getPropertiesOfType(type).length === 0
                && getIndexInfoOfType(type, IndexKind.String)
                && !getIndexInfoOfType(type, IndexKind.Number)
                || type.flags & TypeFlags.UnionOrIntersection
                && every(
                    (<UnionOrIntersectionType> type).types,
                    isStringIndexSignatureOnlyType
                )
                || false;
        }

        function isEnumTypeRelatedTo(
            sourceSymbol: Symbol,
            targetSymbol: Symbol,
            errorReporter?: ErrorReporter
        ) {
            if (sourceSymbol === targetSymbol) {
                return true;
            }
            const id = getSymbolId(sourceSymbol) + ','
                + getSymbolId(targetSymbol);
            const entry = enumRelation.get(id);
            if (entry !== undefined
                && !(!(entry & RelationComparisonResult.Reported)
                    && entry & RelationComparisonResult.Failed
                    && errorReporter))
            {
                return !!(entry & RelationComparisonResult.Succeeded);
            }
            if (sourceSymbol.escapedName !== targetSymbol.escapedName
                || !(sourceSymbol.flags & SymbolFlags.RegularEnum)
                || !(targetSymbol.flags & SymbolFlags.RegularEnum))
            {
                enumRelation.set(
                    id,
                    RelationComparisonResult.Failed
                        | RelationComparisonResult.Reported
                );
                return false;
            }
            const targetEnumType = getTypeOfSymbol(targetSymbol);
            for (const property
                of getPropertiesOfType(getTypeOfSymbol(sourceSymbol)))
            {
                if (property.flags & SymbolFlags.EnumMember) {
                    const targetProperty = getPropertyOfType(
                        targetEnumType,
                        property.escapedName
                    );
                    if (!targetProperty
                        || !(targetProperty.flags & SymbolFlags.EnumMember))
                    {
                        if (errorReporter) {
                            errorReporter(
                                Diagnostics.Property_0_is_missing_in_type_1,
                                symbolName(property),
                                typeToString(
                                    getDeclaredTypeOfSymbol(targetSymbol), /*enclosingDeclaration*/
                                    undefined,
                                    TypeFormatFlags.UseFullyQualifiedType
                                )
                            );
                            enumRelation.set(
                                id,
                                RelationComparisonResult.Failed
                                    | RelationComparisonResult.Reported
                            );
                        } else {
                            enumRelation.set(
                                id,
                                RelationComparisonResult.Failed
                            );
                        }
                        return false;
                    }
                }
            }
            enumRelation.set(id, RelationComparisonResult.Succeeded);
            return true;
        }

        function isSimpleTypeRelatedTo(
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            errorReporter?: ErrorReporter
        ) {
            const s = source.flags;
            const t = target.flags;
            if (t & TypeFlags.AnyOrUnknown || s & TypeFlags.Never
                || source === wildcardType)
            {
                return true;
            }
            if (t & TypeFlags.Never) return false;
            if (s & TypeFlags.StringLike && t & TypeFlags.String) return true;
            if (s & TypeFlags.StringLiteral && s & TypeFlags.EnumLiteral
                && t & TypeFlags.StringLiteral && !(t & TypeFlags.EnumLiteral)
                && (<StringLiteralType> source).value
                === (<StringLiteralType> target).value)
            {
                return true;
            }
            if (s & TypeFlags.NumberLike && t & TypeFlags.Number) return true;
            if (s & TypeFlags.NumberLiteral && s & TypeFlags.EnumLiteral
                && t & TypeFlags.NumberLiteral && !(t & TypeFlags.EnumLiteral)
                && (<NumberLiteralType> source).value
                === (<NumberLiteralType> target).value)
            {
                return true;
            }
            if (s & TypeFlags.BigIntLike && t & TypeFlags.BigInt) return true;
            if (s & TypeFlags.BooleanLike
                && t & TypeFlags.Boolean)
                return true;
            if (s & TypeFlags.ESSymbolLike
                && t & TypeFlags.ESSymbol)
                return true;
            if (s & TypeFlags.Enum && t & TypeFlags.Enum
                && isEnumTypeRelatedTo(
                    source.symbol,
                    target.symbol,
                    errorReporter
                ))
            {
                return true;
            }
            if (s & TypeFlags.EnumLiteral && t & TypeFlags.EnumLiteral) {
                if (s & TypeFlags.Union && t & TypeFlags.Union
                    && isEnumTypeRelatedTo(
                        source.symbol,
                        target.symbol,
                        errorReporter
                    ))
                {
                    return true;
                }
                if (s & TypeFlags.Literal && t & TypeFlags.Literal
                    && (<LiteralType> source).value
                    === (<LiteralType> target).value
                    && isEnumTypeRelatedTo(
                        getParentOfSymbol(source.symbol)!,
                        getParentOfSymbol(target.symbol)!,
                        errorReporter
                    ))
                {
                    return true;
                }
            }
            if (s & TypeFlags.Undefined
                && (!strictNullChecks
                    || t & (TypeFlags.Undefined | TypeFlags.Void)))
            {
                return true;
            }
            if (s & TypeFlags.Null
                && (!strictNullChecks || t & TypeFlags.Null))
            {
                return true;
            }
            if (s & TypeFlags.Object
                && t & TypeFlags.NonPrimitive)
                return true;
            if (relation === assignableRelation
                || relation === comparableRelation)
            {
                if (s & TypeFlags.Any) return true;
                // Type number or any numeric literal type is assignable to any numeric enum type or any
                // numeric enum literal type. This rule exists for backwards compatibility reasons because
                // bit-flag enum types sometimes look like literal enum types with numeric literal values.
                if (s & (TypeFlags.Number | TypeFlags.NumberLiteral)
                    && !(s & TypeFlags.EnumLiteral) && (
                        t & TypeFlags.Enum || t & TypeFlags.NumberLiteral
                        && t & TypeFlags.EnumLiteral
                    ))
                {
                    return true;
                }
            }
            return false;
        }

        function isTypeRelatedTo(
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>
        ) {
            if (isFreshLiteralType(source)) {
                source = (<FreshableType> source).regularType;
            }
            if (isFreshLiteralType(target)) {
                target = (<FreshableType> target).regularType;
            }
            if (source === target
                || relation === comparableRelation
                && !(target.flags & TypeFlags.Never)
                && isSimpleTypeRelatedTo(target, source, relation)
                || relation !== identityRelation
                && isSimpleTypeRelatedTo(source, target, relation))
            {
                return true;
            }
            if (source.flags & TypeFlags.Object
                && target.flags & TypeFlags.Object)
            {
                const related = relation
                    .get(
                        getRelationKey(
                            source,
                            target, /*isIntersectionConstituent*/
                            false,
                            relation
                        )
                    );
                if (related !== undefined) {
                    return !!(related & RelationComparisonResult.Succeeded);
                }
            }
            if (source.flags & TypeFlags.StructuredOrInstantiable
                || target.flags & TypeFlags.StructuredOrInstantiable)
            {
                return checkTypeRelatedTo(
                    source,
                    target,
                    relation, /*errorNode*/
                    undefined
                );
            }
            return false;
        }

        function isIgnoredJsxProperty(source: Type, sourceProp: Symbol) {
            return getObjectFlags(source) & ObjectFlags.JsxAttributes
                && !isUnhyphenatedJsxName(sourceProp.escapedName);
        }

        function getNormalizedType(type: Type, writing: boolean): Type {
            return isFreshLiteralType(type)
                ? (<FreshableType> type).regularType
                : getObjectFlags(type) & ObjectFlags.Reference
                    && (<TypeReference> type).node
                    ? createTypeReference(
                        (<TypeReference> type).target,
                        getTypeArguments(<TypeReference> type)
                    )
                    : type.flags & TypeFlags.Substitution
                        ? writing
                            ? (<SubstitutionType> type).typeVariable
                            : (<SubstitutionType> type).substitute
                        : type.flags & TypeFlags.Simplifiable
                            ? getSimplifiedType(type, writing)
                            : type;
        }

        /**
         * Checks if 'source' is related to 'target' (e.g.: is a assignable to).
         * @param source The left-hand-side of the relation.
         * @param target The right-hand-side of the relation.
         * @param relation The relation considered. One of 'identityRelation', 'subtypeRelation', 'assignableRelation', or 'comparableRelation'.
         * Used as both to determine which checks are performed and as a cache of previously computed results.
         * @param errorNode The suggested node upon which all errors will be reported, if defined. This may or may not be the actual node used.
         * @param headMessage If the error chain should be prepended by a head message, then headMessage will be used.
         * @param containingMessageChain A chain of errors to prepend any new errors found.
         * @param errorOutputContainer Return the diagnostic. Do not log if 'skipLogging' is truthy.
         */
        function checkTypeRelatedTo(
            source: Type,
            target: Type,
            relation: Map<RelationComparisonResult>,
            errorNode: Node | undefined,
            headMessage?: DiagnosticMessage,
            containingMessageChain?: () => DiagnosticMessageChain | undefined,
            errorOutputContainer?: { errors?: Diagnostic[];
                skipLogging?: boolean; }
        ): boolean {
            let errorInfo: DiagnosticMessageChain | undefined;
            let relatedInfo: [DiagnosticRelatedInformation,
                ...DiagnosticRelatedInformation[]] | undefined;
            let maybeKeys: string[];
            let sourceStack: Type[];
            let targetStack: Type[];
            let maybeCount = 0;
            let depth = 0;
            let expandingFlags = ExpandingFlags.None;
            let overflow = false;
            let overrideNextErrorInfo = 0; // How many `reportRelationError` calls should be skipped in the elaboration pyramid
            let lastSkippedInfo: [Type, Type] | undefined;
            let incompatibleStack: [DiagnosticMessage, (string | number)?,
                (string | number)?, (string | number)?,
                (string | number)?][] = [];

            Debug.assert(
                relation !== identityRelation || !errorNode,
                'no error reporting in identity checking'
            );

            const result = isRelatedTo(
                source,
                target, /*reportErrors*/
                !!errorNode,
                headMessage
            );
            if (incompatibleStack.length) {
                reportIncompatibleStack();
            }
            if (overflow) {
                const diag = error(
                    errorNode,
                    Diagnostics.Excessive_stack_depth_comparing_types_0_and_1,
                    typeToString(source),
                    typeToString(target)
                );
                if (errorOutputContainer) {
                    (errorOutputContainer.errors
                        || (errorOutputContainer.errors = [])).push(diag);
                }
            } else if (errorInfo) {
                if (containingMessageChain) {
                    const chain = containingMessageChain();
                    if (chain) {
                        concatenateDiagnosticMessageChains(chain, errorInfo);
                        errorInfo = chain;
                    }
                }

                let relatedInformation: DiagnosticRelatedInformation[]
                    | undefined;
                // Check if we should issue an extra diagnostic to produce a quickfix for a slightly incorrect import statement
                if (headMessage && errorNode && !result && source.symbol) {
                    const links = getSymbolLinks(source.symbol);
                    if (links.originatingImport
                        && !isImportCall(links.originatingImport))
                    {
                        const helpfulRetry = checkTypeRelatedTo(
                            getTypeOfSymbol(
                                links.target!
                            ),
                            target,
                            relation, /*errorNode*/
                            undefined
                        );
                        if (helpfulRetry) {
                            // Likely an incorrect import. Issue a helpful diagnostic to produce a quickfix to change the import
                            const diag = createDiagnosticForNode(
                                links.originatingImport,
                                Diagnostics
                                    .Type_originates_at_this_import_A_namespace_style_import_cannot_be_called_or_constructed_and_will_cause_a_failure_at_runtime_Consider_using_a_default_import_or_import_require_here_instead
                            );
                            relatedInformation = append(
                                relatedInformation,
                                diag
                            ); // Cause the error to appear with the error that triggered it
                        }
                    }
                }
                const diag = createDiagnosticForNodeFromMessageChain(
                    errorNode!,
                    errorInfo,
                    relatedInformation
                );
                if (relatedInfo) {
                    addRelatedInfo(diag, ...relatedInfo);
                }
                if (errorOutputContainer) {
                    (errorOutputContainer.errors
                        || (errorOutputContainer.errors = [])).push(diag);
                }
                if (!errorOutputContainer
                    || !errorOutputContainer.skipLogging)
                {
                    diagnostics.add(diag);
                }
            }
            if (errorNode && errorOutputContainer
                && errorOutputContainer.skipLogging
                && result === Ternary.False)
            {
                Debug.assert(
                    !!errorOutputContainer.errors,
                    'missed opportunity to interact with error.'
                );
            }
            return result !== Ternary.False;

            function resetErrorInfo(
                saved: ReturnType<typeof captureErrorCalculationState>
            ) {
                errorInfo = saved.errorInfo;
                lastSkippedInfo = saved.lastSkippedInfo;
                incompatibleStack = saved.incompatibleStack;
                overrideNextErrorInfo = saved.overrideNextErrorInfo;
                relatedInfo = saved.relatedInfo;
            }

            function captureErrorCalculationState() {
                return {
                    errorInfo,
                    lastSkippedInfo,
                    incompatibleStack: incompatibleStack.slice(),
                    overrideNextErrorInfo,
                    relatedInfo: !relatedInfo
                        ? undefined
                        : relatedInfo
                            .slice() as ([DiagnosticRelatedInformation,
                                ...DiagnosticRelatedInformation[]] | undefined)
                };
            }

            function reportIncompatibleError(
                message: DiagnosticMessage,
                arg0?: string | number,
                arg1?: string | number,
                arg2?: string | number,
                arg3?: string | number
            ) {
                overrideNextErrorInfo++; // Suppress the next relation error
                lastSkippedInfo = undefined; // Reset skipped info cache
                incompatibleStack.push([message, arg0, arg1, arg2, arg3]);
            }

            function reportIncompatibleStack() {
                const stack = incompatibleStack;
                incompatibleStack = [];
                const info = lastSkippedInfo;
                lastSkippedInfo = undefined;
                if (stack.length === 1) {
                    reportError(...stack[0]);
                    if (info) {
                        // Actually do the last relation error
                        reportRelationError(/*headMessage*/ undefined,
                            ...info);
                    }
                    return;
                }
                // The first error will be the innermost, while the last will be the outermost - so by popping off the end,
                // we can build from left to right
                let path = '';
                const secondaryRootErrors: typeof incompatibleStack = [];
                while (stack.length) {
                    const [msg, ...args] = stack.pop()!;
                    switch (msg.code) {
                        case Diagnostics.Types_of_property_0_are_incompatible
                            .code: {
                            // Parenthesize a `new` if there is one
                            if (path.indexOf('new ') === 0) {
                                path = `(${path})`;
                            }
                            const str = '' + args[0];
                            // If leading, just print back the arg (irrespective of if it's a valid identifier)
                            if (path.length === 0) {
                                path = `${str}`;
                            } // Otherwise write a dotted name if possible
                            else if (isIdentifierText(
                                str,
                                compilerOptions.target
                            )) {
                                path = `${path}.${str}`;
                            } // Failing that, check if the name is already a computed name
                            else if (str[0] === '['
                                && str[str.length - 1] === ']')
                            {
                                path = `${path}${str}`;
                            } // And finally write out a computed name as a last resort
                            else {
                                path = `${path}[${str}]`;
                            }
                            break;
                        }
                        case Diagnostics
                            .Call_signature_return_types_0_and_1_are_incompatible
                            .code:
                        case Diagnostics
                            .Construct_signature_return_types_0_and_1_are_incompatible
                            .code:
                        case Diagnostics
                            .Call_signatures_with_no_arguments_have_incompatible_return_types_0_and_1
                            .code:
                        case Diagnostics
                            .Construct_signatures_with_no_arguments_have_incompatible_return_types_0_and_1
                            .code: {
                            if (path.length === 0) {
                                // Don't flatten signature compatability errors at the start of a chain - instead prefer
                                // to unify (the with no arguments bit is excessive for printback) and print them back
                                let mappedMsg = msg;
                                if (msg.code
                                    === Diagnostics
                                        .Call_signatures_with_no_arguments_have_incompatible_return_types_0_and_1
                                        .code)
                                {
                                    mappedMsg = Diagnostics
                                        .Call_signature_return_types_0_and_1_are_incompatible;
                                } else if (msg.code
                                    === Diagnostics
                                        .Construct_signatures_with_no_arguments_have_incompatible_return_types_0_and_1
                                        .code)
                                {
                                    mappedMsg = Diagnostics
                                        .Construct_signature_return_types_0_and_1_are_incompatible;
                                }
                                secondaryRootErrors
                                    .unshift([mappedMsg, args[0], args[1]]);
                            } else {
                                const prefix = (msg.code
                                    === Diagnostics
                                        .Construct_signature_return_types_0_and_1_are_incompatible
                                        .code
                                    || msg.code
                                    === Diagnostics
                                        .Construct_signatures_with_no_arguments_have_incompatible_return_types_0_and_1
                                        .code)
                                    ? 'new '
                                    : '';
                                const params = (msg.code
                                    === Diagnostics
                                        .Call_signatures_with_no_arguments_have_incompatible_return_types_0_and_1
                                        .code
                                    || msg.code
                                    === Diagnostics
                                        .Construct_signatures_with_no_arguments_have_incompatible_return_types_0_and_1
                                        .code)
                                    ? ''
                                    : '...';
                                path = `${prefix}${path}(${params})`;
                            }
                            break;
                        }
                        default:
                            return Debug
                                .fail(`Unhandled Diagnostic: ${msg.code}`);
                    }
                }
                if (path) {
                    reportError(
                        path[path.length - 1] === ')'
                            ? Diagnostics
                                .The_types_returned_by_0_are_incompatible_between_these_types
                            : Diagnostics
                                .The_types_of_0_are_incompatible_between_these_types,
                        path
                    );
                } else {
                    // Remove the innermost secondary error as it will duplicate the error already reported by `reportRelationError` on entry
                    secondaryRootErrors.shift();
                }
                for (const [msg, ...args] of secondaryRootErrors) {
                    const originalValue = msg.elidedInCompatabilityPyramid;
                    msg
                        .elidedInCompatabilityPyramid = false; // Teporarily override elision to ensure error is reported
                    reportError(msg, ...args);
                    msg.elidedInCompatabilityPyramid = originalValue;
                }
                if (info) {
                    // Actually do the last relation error
                    reportRelationError(/*headMessage*/ undefined, ...info);
                }
            }

            function reportError(
                message: DiagnosticMessage,
                arg0?: string | number,
                arg1?: string | number,
                arg2?: string | number,
                arg3?: string | number
            ): void {
                Debug.assert(!!errorNode);
                if (incompatibleStack.length) reportIncompatibleStack();
                if (message.elidedInCompatabilityPyramid) return;
                errorInfo = chainDiagnosticMessages(
                    errorInfo,
                    message,
                    arg0,
                    arg1,
                    arg2,
                    arg3
                );
            }

            function associateRelatedInfo(info: DiagnosticRelatedInformation) {
                Debug.assert(!!errorInfo);
                if (!relatedInfo) {
                    relatedInfo = [info];
                } else {
                    relatedInfo.push(info);
                }
            }

            function reportRelationError(
                message: DiagnosticMessage | undefined,
                source: Type,
                target: Type
            ) {
                if (incompatibleStack.length) reportIncompatibleStack();
                const [sourceType,
                    targetType] = getTypeNamesForErrorDisplay(source, target);

                if (target.flags & TypeFlags.TypeParameter
                    && target.immediateBaseConstraint !== undefined
                    && isTypeAssignableTo(
                        source,
                        target.immediateBaseConstraint
                    ))
                {
                    reportError(
                        Diagnostics
                            ._0_is_assignable_to_the_constraint_of_type_1_but_1_could_be_instantiated_with_a_different_subtype_of_constraint_2,
                        sourceType,
                        targetType,
                        typeToString(target.immediateBaseConstraint)
                    );
                }

                if (!message) {
                    if (relation === comparableRelation) {
                        message = Diagnostics
                            .Type_0_is_not_comparable_to_type_1;
                    } else if (sourceType === targetType) {
                        message = Diagnostics
                            .Type_0_is_not_assignable_to_type_1_Two_different_types_with_this_name_exist_but_they_are_unrelated;
                    } else {
                        message = Diagnostics
                            .Type_0_is_not_assignable_to_type_1;
                    }
                }

                reportError(message, sourceType, targetType);
            }

            function tryElaborateErrorsForPrimitivesAndObjects(
                source: Type,
                target: Type
            ) {
                const sourceType = symbolValueDeclarationIsContextSensitive(
                    source.symbol
                )
                    ? typeToString(source, source.symbol.valueDeclaration)
                    : typeToString(source);
                const targetType = symbolValueDeclarationIsContextSensitive(
                    target.symbol
                )
                    ? typeToString(target, target.symbol.valueDeclaration)
                    : typeToString(target);

                if ((globalStringType === source && stringType === target)
                    || (globalNumberType === source && numberType === target)
                    || (globalBooleanType === source && booleanType === target)
                    || (getGlobalESSymbolType(/*reportErrors*/ false)
                        === source && esSymbolType === target))
                {
                    reportError(
                        Diagnostics
                            ._0_is_a_primitive_but_1_is_a_wrapper_object_Prefer_using_0_when_possible,
                        targetType,
                        sourceType
                    );
                }
            }

            /**
             * Try and elaborate array and tuple errors. Returns false
             * if we have found an elaboration, or we should ignore
             * any other elaborations when relating the `source` and
             * `target` types.
             */
            function tryElaborateArrayLikeErrors(
                source: Type,
                target: Type,
                reportErrors: boolean
            ): boolean {
                /**
                 * The spec for elaboration is:
                 * - If the source is a readonly tuple and the target is a mutable array or tuple, elaborate on mutability and skip property elaborations.
                 * - If the source is a tuple then skip property elaborations if the target is an array or tuple.
                 * - If the source is a readonly array and the target is a mutable array or tuple, elaborate on mutability and skip property elaborations.
                 * - If the source an array then skip property elaborations if the target is a tuple.
                 */
                if (isTupleType(source)) {
                    if (source.target.readonly
                        && isMutableArrayOrTuple(target))
                    {
                        if (reportErrors) {
                            reportError(
                                Diagnostics
                                    .The_type_0_is_readonly_and_cannot_be_assigned_to_the_mutable_type_1,
                                typeToString(source),
                                typeToString(target)
                            );
                        }
                        return false;
                    }
                    return isTupleType(target) || isArrayType(target);
                }
                if (isReadonlyArrayType(source)
                    && isMutableArrayOrTuple(target))
                {
                    if (reportErrors) {
                        reportError(
                            Diagnostics
                                .The_type_0_is_readonly_and_cannot_be_assigned_to_the_mutable_type_1,
                            typeToString(source),
                            typeToString(target)
                        );
                    }
                    return false;
                }
                if (isTupleType(target)) {
                    return isArrayType(source);
                }
                return true;
            }

            /**
             * Compare two types and return
             * * Ternary.True if they are related with no assumptions,
             * * Ternary.Maybe if they are related with assumptions of other relationships, or
             * * Ternary.False if they are not related.
             */
            function isRelatedTo(
                originalSource: Type,
                originalTarget: Type,
                reportErrors = false,
                headMessage?: DiagnosticMessage,
                isApparentIntersectionConstituent?: boolean
            ): Ternary {
                // Normalize the source and target types: Turn fresh literal types into regular literal types,
                // turn deferred type references into regular type references, simplify indexed access and
                // conditional types, and resolve substitution types to either the substitution (on the source
                // side) or the type variable (on the target side).
                let source = getNormalizedType(
                    originalSource, /*writing*/
                    false
                );
                let target = getNormalizedType(
                    originalTarget, /*writing*/
                    true
                );

                // Try to see if we're relating something like `Foo` -> `Bar | null | undefined`.
                // If so, reporting the `null` and `undefined` in the type is hardly useful.
                // First, see if we're even relating an object type to a union.
                // Then see if the target is stripped down to a single non-union type.
                // Note
                //  * We actually want to remove null and undefined naively here (rather than using getNonNullableType),
                //    since we don't want to end up with a worse error like "`Foo` is not assignable to `NonNullable<T>`"
                //    when dealing with generics.
                //  * We also don't deal with primitive source types, since we already halt elaboration below.
                if (target.flags & TypeFlags.Union
                    && source.flags & TypeFlags.Object
                    && (target as UnionType).types.length <= 3
                    && maybeTypeOfKind(target, TypeFlags.Nullable))
                {
                    const nullStrippedTarget = extractTypesOfKind(
                        target,
                        ~TypeFlags.Nullable
                    );
                    if (!(nullStrippedTarget.flags
                        & (TypeFlags.Union | TypeFlags.Never)))
                    {
                        target = nullStrippedTarget;
                    }
                }

                // both types are the same - covers 'they are the same primitive type or both are Any' or the same type parameter cases
                if (source === target) return Ternary.True;

                if (relation === identityRelation) {
                    return isIdenticalTo(source, target);
                }

                if (relation === comparableRelation
                    && !(target.flags & TypeFlags.Never)
                    && isSimpleTypeRelatedTo(target, source, relation)
                    || isSimpleTypeRelatedTo(
                        source,
                        target,
                        relation,
                        reportErrors ? reportError : undefined
                    ))
                {
                    return Ternary.True;
                }

                const isComparingJsxAttributes = !!(getObjectFlags(source)
                    & ObjectFlags.JsxAttributes);
                const isPerformingExcessPropertyChecks = !isApparentIntersectionConstituent
                    && (isObjectLiteralType(source)
                        && getObjectFlags(source) & ObjectFlags.FreshLiteral);
                if (isPerformingExcessPropertyChecks) {
                    if (hasExcessProperties(
                        <FreshObjectLiteralType> source,
                        target,
                        reportErrors
                    )) {
                        if (reportErrors) {
                            reportRelationError(headMessage, source, target);
                        }
                        return Ternary.False;
                    }
                }

                const isPerformingCommonPropertyChecks = relation
                    !== comparableRelation
                    && !isApparentIntersectionConstituent
                    && source.flags
                    & (TypeFlags.Primitive | TypeFlags.Object
                        | TypeFlags.Intersection)
                    && source !== globalObjectType
                    && target.flags
                    & (TypeFlags.Object | TypeFlags.Intersection)
                    && isWeakType(target)
                    && (getPropertiesOfType(source).length > 0
                        || typeHasCallOrConstructSignatures(source));
                if (isPerformingCommonPropertyChecks
                    && !hasCommonProperties(
                        source,
                        target,
                        isComparingJsxAttributes
                    ))
                {
                    if (reportErrors) {
                        const calls = getSignaturesOfType(
                            source,
                            SignatureKind.Call
                        );
                        const constructs = getSignaturesOfType(
                            source,
                            SignatureKind.Construct
                        );
                        if (calls.length > 0
                            && isRelatedTo(
                                getReturnTypeOfSignature(calls[0]),
                                target, /*reportErrors*/
                                false
                            )
                            || constructs.length > 0
                            && isRelatedTo(
                                getReturnTypeOfSignature(
                                    constructs[0]
                                ),
                                target, /*reportErrors*/
                                false
                            ))
                        {
                            reportError(
                                Diagnostics
                                    .Value_of_type_0_has_no_properties_in_common_with_type_1_Did_you_mean_to_call_it,
                                typeToString(source),
                                typeToString(target)
                            );
                        } else {
                            reportError(
                                Diagnostics
                                    .Type_0_has_no_properties_in_common_with_type_1,
                                typeToString(source),
                                typeToString(target)
                            );
                        }
                    }
                    return Ternary.False;
                }

                let result = Ternary.False;
                const saveErrorInfo = captureErrorCalculationState();
                let isIntersectionConstituent = !!isApparentIntersectionConstituent;

                // Note that these checks are specifically ordered to produce correct results. In particular,
                // we need to deconstruct unions before intersections (because unions are always at the top),
                // and we need to handle "each" relations before "some" relations for the same kind of type.
                if (source.flags & TypeFlags.Union) {
                    result = relation === comparableRelation
                        ? someTypeRelatedToType(
                            source as UnionType,
                            target,
                            reportErrors
                                && !(source.flags & TypeFlags.Primitive)
                        )
                        : eachTypeRelatedToType(
                            source as UnionType,
                            target,
                            reportErrors
                                && !(source.flags & TypeFlags.Primitive)
                        );
                } else {
                    if (target.flags & TypeFlags.Union) {
                        result = typeRelatedToSomeType(
                            getRegularTypeOfObjectLiteral(source),
                            <UnionType> target,
                            reportErrors
                                && !(source.flags & TypeFlags.Primitive)
                                && !(target.flags & TypeFlags.Primitive)
                        );
                    } else if (target.flags & TypeFlags.Intersection) {
                        isIntersectionConstituent = true; // set here to affect the following trio of checks
                        result = typeRelatedToEachType(
                            getRegularTypeOfObjectLiteral(source),
                            target as IntersectionType,
                            reportErrors
                        );
                        if (result
                            && (isPerformingExcessPropertyChecks
                                || isPerformingCommonPropertyChecks))
                        {
                            // Validate against excess props using the original `source`
                            if (!propertiesRelatedTo(
                                source,
                                target,
                                reportErrors, /*excludedProperties*/
                                undefined, /*isIntersectionConstituent*/
                                false
                            )) {
                                return Ternary.False;
                            }
                        }
                    } else if (source.flags & TypeFlags.Intersection) {
                        // Check to see if any constituents of the intersection are immediately related to the target.
                        //
                        // Don't report errors though. Checking whether a constituent is related to the source is not actually
                        // useful and leads to some confusing error messages. Instead it is better to let the below checks
                        // take care of this, or to not elaborate at all. For instance,
                        //
                        //    - For an object type (such as 'C = A & B'), users are usually more interested in structural errors.
                        //
                        //    - For a union type (such as '(A | B) = (C & D)'), it's better to hold onto the whole intersection
                        //          than to report that 'D' is not assignable to 'A' or 'B'.
                        //
                        //    - For a primitive type or type parameter (such as 'number = A & B') there is no point in
                        //          breaking the intersection apart.
                        result = someTypeRelatedToType(
                            <IntersectionType> source,
                            target, /*reportErrors*/
                            false
                        );
                    }
                    if (!result
                        && (source.flags & TypeFlags.StructuredOrInstantiable
                            || target.flags
                            & TypeFlags.StructuredOrInstantiable))
                    {
                        if (result = recursiveTypeRelatedTo(
                            source,
                            target,
                            reportErrors,
                            isIntersectionConstituent
                        )) {
                            resetErrorInfo(saveErrorInfo);
                        }
                    }
                }
                if (!result
                    && source.flags
                    & (TypeFlags.Intersection | TypeFlags.TypeParameter))
                {
                    // The combined constraint of an intersection type is the intersection of the constraints of
                    // the constituents. When an intersection type contains instantiable types with union type
                    // constraints, there are situations where we need to examine the combined constraint. One is
                    // when the target is a union type. Another is when the intersection contains types belonging
                    // to one of the disjoint domains. For example, given type variables T and U, each with the
                    // constraint 'string | number', the combined constraint of 'T & U' is 'string | number' and
                    // we need to check this constraint against a union on the target side. Also, given a type
                    // variable V constrained to 'string | number', 'V & number' has a combined constraint of
                    // 'string & number | number & number' which reduces to just 'number'.
                    // This also handles type parameters, as a type parameter with a union constraint compared against a union
                    // needs to have its constraint hoisted into an intersection with said type parameter, this way
                    // the type param can be compared with itself in the target (with the influence of its constraint to match other parts)
                    // For example, if `T extends 1 | 2` and `U extends 2 | 3` and we compare `T & U` to `T & U & (1 | 2 | 3)`
                    const constraint = getEffectiveConstraintOfIntersection(
                        source.flags & TypeFlags.Intersection
                            ? (<IntersectionType> source).types
                            : [source],
                        !!(target.flags & TypeFlags.Union)
                    );
                    if (constraint
                        && (source.flags & TypeFlags.Intersection
                            || target.flags & TypeFlags.Union))
                    {
                        if (everyType(constraint,
                            c => c
                                !== source))
                        { // Skip comparison if expansion contains the source itself
                            // TODO: Stack errors so we get a pyramid for the "normal" comparison above, _and_ a second for this
                            if (result = isRelatedTo(
                                constraint,
                                target, /*reportErrors*/
                                false, /*headMessage*/
                                undefined,
                                isIntersectionConstituent
                            )) {
                                resetErrorInfo(saveErrorInfo);
                            }
                        }
                    }
                }

                if (!result && reportErrors) {
                    source = originalSource.aliasSymbol
                        ? originalSource
                        : source;
                    target = originalTarget.aliasSymbol
                        ? originalTarget
                        : target;
                    let maybeSuppress = overrideNextErrorInfo > 0;
                    if (maybeSuppress) {
                        overrideNextErrorInfo--;
                    }
                    if (source.flags & TypeFlags.Object
                        && target.flags & TypeFlags.Object)
                    {
                        const currentError = errorInfo;
                        tryElaborateArrayLikeErrors(
                            source,
                            target,
                            reportErrors
                        );
                        if (errorInfo !== currentError) {
                            maybeSuppress = !!errorInfo;
                        }
                    }
                    if (source.flags & TypeFlags.Object
                        && target.flags & TypeFlags.Primitive)
                    {
                        tryElaborateErrorsForPrimitivesAndObjects(
                            source,
                            target
                        );
                    } else if (source.symbol && source.flags & TypeFlags.Object
                        && globalObjectType === source)
                    {
                        reportError(
                            Diagnostics
                                .The_Object_type_is_assignable_to_very_few_other_types_Did_you_mean_to_use_the_any_type_instead
                        );
                    } else if (isComparingJsxAttributes
                        && target.flags & TypeFlags.Intersection)
                    {
                        const targetTypes = (target as IntersectionType).types;
                        const intrinsicAttributes = getJsxType(
                            JsxNames.IntrinsicAttributes,
                            errorNode
                        );
                        const intrinsicClassAttributes = getJsxType(
                            JsxNames.IntrinsicClassAttributes,
                            errorNode
                        );
                        if (intrinsicAttributes !== errorType
                            && intrinsicClassAttributes !== errorType
                            && (contains(targetTypes, intrinsicAttributes)
                                || contains(
                                    targetTypes,
                                    intrinsicClassAttributes
                                )))
                        {
                            // do not report top error
                            return result;
                        }
                    }
                    if (!headMessage && maybeSuppress) {
                        lastSkippedInfo = [source, target];
                        // Used by, eg, missing property checking to replace the top-level message with a more informative one
                        return result;
                    }
                    reportRelationError(headMessage, source, target);
                }
                return result;
            }

            function isIdenticalTo(source: Type, target: Type): Ternary {
                let result: Ternary;
                const flags = source.flags & target.flags;
                if (flags & TypeFlags.Object || flags & TypeFlags.IndexedAccess
                    || flags & TypeFlags.Conditional || flags & TypeFlags.Index
                    || flags & TypeFlags.Substitution)
                {
                    return recursiveTypeRelatedTo(
                        source,
                        target, /*reportErrors*/
                        false, /*isIntersectionConstituent*/
                        false
                    );
                }
                if (flags & (TypeFlags.Union | TypeFlags.Intersection)) {
                    if (result = eachTypeRelatedToSomeType(
                        <UnionOrIntersectionType> source,
                        <UnionOrIntersectionType> target
                    )) {
                        if (result &= eachTypeRelatedToSomeType(
                            <UnionOrIntersectionType> target,
                            <UnionOrIntersectionType> source
                        )) {
                            return result;
                        }
                    }
                }
                return Ternary.False;
            }

            function getTypeOfPropertyInTypes(types: Type[], name: __String) {
                const appendPropType = (
                    propTypes: Type[] | undefined,
                    type: Type
                ) => {
                    type = getApparentType(type);
                    const prop = type.flags & TypeFlags.UnionOrIntersection
                        ? getPropertyOfUnionOrIntersectionType(
                            <UnionOrIntersectionType> type,
                            name
                        )
                        : getPropertyOfObjectType(type, name);
                    const propType = prop && getTypeOfSymbol(prop)
                        || isNumericLiteralName(name)
                        && getIndexTypeOfType(type, IndexKind.Number)
                        || getIndexTypeOfType(type, IndexKind.String)
                        || undefinedType;
                    return append(propTypes, propType);
                };
                return getUnionType(
                    reduceLeft(
                        types,
                        appendPropType, /*initial*/
                        undefined
                    ) || emptyArray
                );
            }

            function hasExcessProperties(
                source: FreshObjectLiteralType,
                target: Type,
                reportErrors: boolean
            ): boolean {
                if (!isExcessPropertyCheckTarget(target) || !noImplicitAny
                    && getObjectFlags(target) & ObjectFlags.JSLiteral)
                {
                    return false; // Disable excess property checks on JS literals to simulate having an implicit "index signature" - but only outside of noImplicitAny
                }
                const isComparingJsxAttributes = !!(getObjectFlags(source)
                    & ObjectFlags.JsxAttributes);
                if ((relation === assignableRelation
                    || relation === comparableRelation)
                    && (isTypeSubsetOf(globalObjectType, target)
                        || (!isComparingJsxAttributes
                            && isEmptyObjectType(target))))
                {
                    return false;
                }
                let reducedTarget = target;
                let checkTypes: Type[] | undefined;
                if (target.flags & TypeFlags.Union) {
                    reducedTarget = findMatchingDiscriminantType(
                        source,
                        <UnionType> target,
                        isRelatedTo
                    )
                        || filterPrimitivesIfContainsNonPrimitive(<UnionType> target);
                    checkTypes = reducedTarget.flags & TypeFlags.Union
                        ? (<UnionType> reducedTarget).types
                        : [reducedTarget];
                }
                for (const prop of getPropertiesOfType(source)) {
                    if (shouldCheckAsExcessProperty(prop, source.symbol)) {
                        if (!isKnownProperty(
                            reducedTarget,
                            prop.escapedName,
                            isComparingJsxAttributes
                        )) {
                            if (reportErrors) {
                                // Report error in terms of object types in the target as those are the only ones
                                // we check in isKnownProperty.
                                const errorTarget = filterType(
                                    reducedTarget,
                                    isExcessPropertyCheckTarget
                                );
                                // We know *exactly* where things went wrong when comparing the types.
                                // Use this property as the error node as this will be more helpful in
                                // reasoning about what went wrong.
                                if (!errorNode) return Debug.fail();
                                if (isJsxAttributes(errorNode)
                                    || isJsxOpeningLikeElement(errorNode)
                                    || isJsxOpeningLikeElement(
                                        errorNode.parent
                                    ))
                                {
                                    // JsxAttributes has an object-literal flag and undergo same type-assignablity check as normal object-literal.
                                    // However, using an object-literal error message will be very confusing to the users so we give different a message.
                                    // TODO: Spelling suggestions for excess jsx attributes (needs new diagnostic messages)
                                    if (prop.valueDeclaration
                                        && isJsxAttribute(
                                            prop.valueDeclaration
                                        )
                                        && getSourceFileOfNode(errorNode)
                                        === getSourceFileOfNode(
                                            prop.valueDeclaration.name
                                        ))
                                    {
                                        // Note that extraneous children (as in `<NoChild>extra</NoChild>`) don't pass this check,
                                        // since `children` is a SyntaxKind.PropertySignature instead of a SyntaxKind.JsxAttribute.
                                        errorNode = prop.valueDeclaration.name;
                                    }
                                    reportError(
                                        Diagnostics
                                            .Property_0_does_not_exist_on_type_1,
                                        symbolToString(prop),
                                        typeToString(errorTarget)
                                    );
                                } else {
                                    // use the property's value declaration if the property is assigned inside the literal itself
                                    const objectLiteralDeclaration = source
                                        .symbol
                                        && firstOrUndefined(
                                            source.symbol.declarations
                                        );
                                    let suggestion;
                                    if (prop.valueDeclaration
                                        && findAncestor(
                                            prop.valueDeclaration,
                                            d => d === objectLiteralDeclaration
                                        )
                                        && getSourceFileOfNode(objectLiteralDeclaration)
                                        === getSourceFileOfNode(errorNode))
                                    {
                                        const propDeclaration = prop
                                            .valueDeclaration as ObjectLiteralElementLike;
                                        Debug.assertNode(
                                            propDeclaration,
                                            isObjectLiteralElementLike
                                        );

                                        errorNode = propDeclaration;

                                        const name = propDeclaration.name!;
                                        if (isIdentifier(name)) {
                                            suggestion = getSuggestionForNonexistentProperty(
                                                name,
                                                errorTarget
                                            );
                                        }
                                    }
                                    if (suggestion !== undefined) {
                                        reportError(
                                            Diagnostics
                                                .Object_literal_may_only_specify_known_properties_but_0_does_not_exist_in_type_1_Did_you_mean_to_write_2,
                                            symbolToString(prop),
                                            typeToString(errorTarget),
                                            suggestion
                                        );
                                    } else {
                                        reportError(
                                            Diagnostics
                                                .Object_literal_may_only_specify_known_properties_and_0_does_not_exist_in_type_1,
                                            symbolToString(prop),
                                            typeToString(errorTarget)
                                        );
                                    }
                                }
                            }
                            return true;
                        }
                        if (checkTypes
                            && !isRelatedTo(
                                getTypeOfSymbol(prop),
                                getTypeOfPropertyInTypes(
                                    checkTypes,
                                    prop.escapedName
                                ),
                                reportErrors
                            ))
                        {
                            if (reportErrors) {
                                reportIncompatibleError(
                                    Diagnostics
                                        .Types_of_property_0_are_incompatible,
                                    symbolToString(prop)
                                );
                            }
                            return true;
                        }
                    }
                }
                return false;
            }

            function shouldCheckAsExcessProperty(
                prop: Symbol,
                container: Symbol
            ) {
                return prop.valueDeclaration && container.valueDeclaration
                    && prop.valueDeclaration.parent
                    === container.valueDeclaration;
            }

            function eachTypeRelatedToSomeType(
                source: UnionOrIntersectionType,
                target: UnionOrIntersectionType
            ): Ternary {
                let result = Ternary.True;
                const sourceTypes = source.types;
                for (const sourceType of sourceTypes) {
                    const related = typeRelatedToSomeType(
                        sourceType,
                        target, /*reportErrors*/
                        false
                    );
                    if (!related) {
                        return Ternary.False;
                    }
                    result &= related;
                }
                return result;
            }

            function typeRelatedToSomeType(
                source: Type,
                target: UnionOrIntersectionType,
                reportErrors: boolean
            ): Ternary {
                const targetTypes = target.types;
                if (target.flags & TypeFlags.Union
                    && containsType(targetTypes, source))
                {
                    return Ternary.True;
                }
                for (const type of targetTypes) {
                    const related = isRelatedTo(
                        source,
                        type, /*reportErrors*/
                        false
                    );
                    if (related) {
                        return related;
                    }
                }
                if (reportErrors) {
                    const bestMatchingType = getBestMatchingType(
                        source,
                        target,
                        isRelatedTo
                    );
                    isRelatedTo(
                        source,
                        bestMatchingType
                            || targetTypes[targetTypes.length
                                - 1], /*reportErrors*/
                        true
                    );
                }
                return Ternary.False;
            }

            function typeRelatedToEachType(
                source: Type,
                target: IntersectionType,
                reportErrors: boolean
            ): Ternary {
                let result = Ternary.True;
                const targetTypes = target.types;
                for (const targetType of targetTypes) {
                    const related = isRelatedTo(
                        source,
                        targetType,
                        reportErrors, /*headMessage*/
                        undefined, /*isIntersectionConstituent*/
                        true
                    );
                    if (!related) {
                        return Ternary.False;
                    }
                    result &= related;
                }
                return result;
            }

            function someTypeRelatedToType(
                source: UnionOrIntersectionType,
                target: Type,
                reportErrors: boolean
            ): Ternary {
                const sourceTypes = source.types;
                if (source.flags & TypeFlags.Union
                    && containsType(sourceTypes, target))
                {
                    return Ternary.True;
                }
                const len = sourceTypes.length;
                for (let i = 0; i < len; i++) {
                    const related = isRelatedTo(
                        sourceTypes[i],
                        target,
                        reportErrors && i === len - 1
                    );
                    if (related) {
                        return related;
                    }
                }
                return Ternary.False;
            }

            function eachTypeRelatedToType(
                source: UnionOrIntersectionType,
                target: Type,
                reportErrors: boolean
            ): Ternary {
                let result = Ternary.True;
                const sourceTypes = source.types;
                for (const sourceType of sourceTypes) {
                    const related = isRelatedTo(
                        sourceType,
                        target,
                        reportErrors
                    );
                    if (!related) {
                        return Ternary.False;
                    }
                    result &= related;
                }
                return result;
            }

            function typeArgumentsRelatedTo(
                sources: readonly Type[] = emptyArray,
                targets: readonly Type[] = emptyArray,
                variances: readonly VarianceFlags[] = emptyArray,
                reportErrors: boolean,
                isIntersectionConstituent: boolean
            ): Ternary {
                if (sources.length !== targets.length
                    && relation === identityRelation)
                {
                    return Ternary.False;
                }
                const length = sources.length <= targets.length
                    ? sources.length
                    : targets.length;
                let result = Ternary.True;
                for (let i = 0; i < length; i++) {
                    // When variance information isn't available we default to covariance. This happens
                    // in the process of computing variance information for recursive types and when
                    // comparing 'this' type arguments.
                    const varianceFlags = i < variances.length
                        ? variances[i]
                        : VarianceFlags.Covariant;
                    const variance = varianceFlags
                        & VarianceFlags.VarianceMask;
                    // We ignore arguments for independent type parameters (because they're never witnessed).
                    if (variance !== VarianceFlags.Independent) {
                        const s = sources[i];
                        const t = targets[i];
                        let related = Ternary.True;
                        if (varianceFlags & VarianceFlags.Unmeasurable) {
                            // Even an `Unmeasurable` variance works out without a structural check if the source and target are _identical_.
                            // We can't simply assume invariance, because `Unmeasurable` marks nonlinear relations, for example, a relation tained by
                            // the `-?` modifier in a mapped type (where, no matter how the inputs are related, the outputs still might not be)
                            related = relation === identityRelation
                                ? isRelatedTo(s, t, /*reportErrors*/ false)
                                : compareTypesIdentical(s, t);
                        } else if (variance === VarianceFlags.Covariant) {
                            related = isRelatedTo(
                                s,
                                t,
                                reportErrors, /*headMessage*/
                                undefined,
                                isIntersectionConstituent
                            );
                        } else if (variance === VarianceFlags.Contravariant) {
                            related = isRelatedTo(
                                t,
                                s,
                                reportErrors, /*headMessage*/
                                undefined,
                                isIntersectionConstituent
                            );
                        } else if (variance === VarianceFlags.Bivariant) {
                            // In the bivariant case we first compare contravariantly without reporting
                            // errors. Then, if that doesn't succeed, we compare covariantly with error
                            // reporting. Thus, error elaboration will be based on the the covariant check,
                            // which is generally easier to reason about.
                            related = isRelatedTo(t, s, /*reportErrors*/
                                false);
                            if (!related) {
                                related = isRelatedTo(
                                    s,
                                    t,
                                    reportErrors, /*headMessage*/
                                    undefined,
                                    isIntersectionConstituent
                                );
                            }
                        } else {
                            // In the invariant case we first compare covariantly, and only when that
                            // succeeds do we proceed to compare contravariantly. Thus, error elaboration
                            // will typically be based on the covariant check.
                            related = isRelatedTo(
                                s,
                                t,
                                reportErrors, /*headMessage*/
                                undefined,
                                isIntersectionConstituent
                            );
                            if (related) {
                                related &= isRelatedTo(
                                    t,
                                    s,
                                    reportErrors, /*headMessage*/
                                    undefined,
                                    isIntersectionConstituent
                                );
                            }
                        }
                        if (!related) {
                            return Ternary.False;
                        }
                        result &= related;
                    }
                }
                return result;
            }

            // Determine if possibly recursive types are related. First, check if the result is already available in the global cache.
            // Second, check if we have already started a comparison of the given two types in which case we assume the result to be true.
            // Third, check if both types are part of deeply nested chains of generic type instantiations and if so assume the types are
            // equal and infinitely expanding. Fourth, if we have reached a depth of 100 nested comparisons, assume we have runaway recursion
            // and issue an error. Otherwise, actually compare the structure of the two types.
            function recursiveTypeRelatedTo(
                source: Type,
                target: Type,
                reportErrors: boolean,
                isIntersectionConstituent: boolean
            ): Ternary {
                if (overflow) {
                    return Ternary.False;
                }
                const id = getRelationKey(
                    source,
                    target,
                    isIntersectionConstituent,
                    relation
                );
                const entry = relation.get(id);
                if (entry !== undefined) {
                    if (reportErrors && entry & RelationComparisonResult.Failed
                        && !(entry & RelationComparisonResult.Reported))
                    {
                        // We are elaborating errors and the cached result is an unreported failure. The result will be reported
                        // as a failure, and should be updated as a reported failure by the bottom of this function.
                    } else {
                        if (outofbandVarianceMarkerHandler) {
                            // We're in the middle of variance checking - integrate any unmeasurable/unreliable flags from this cached component
                            const saved = entry
                                & RelationComparisonResult.ReportsMask;
                            if (saved
                                & RelationComparisonResult.ReportsUnmeasurable)
                            {
                                instantiateType(
                                    source,
                                    reportUnmeasurableMarkers
                                );
                            }
                            if (saved
                                & RelationComparisonResult.ReportsUnreliable)
                            {
                                instantiateType(
                                    source,
                                    reportUnreliableMarkers
                                );
                            }
                        }
                        return entry & RelationComparisonResult.Succeeded
                            ? Ternary.True
                            : Ternary.False;
                    }
                }
                if (!maybeKeys) {
                    maybeKeys = [];
                    sourceStack = [];
                    targetStack = [];
                } else {
                    for (let i = 0; i < maybeCount; i++) {
                        // If source and target are already being compared, consider them related with assumptions
                        if (id === maybeKeys[i]) {
                            return Ternary.Maybe;
                        }
                    }
                    if (depth === 100) {
                        overflow = true;
                        return Ternary.False;
                    }
                }
                const maybeStart = maybeCount;
                maybeKeys[maybeCount] = id;
                maybeCount++;
                sourceStack[depth] = source;
                targetStack[depth] = target;
                depth++;
                const saveExpandingFlags = expandingFlags;
                if (!(expandingFlags & ExpandingFlags.Source)
                    && isDeeplyNestedType(source, sourceStack, depth))
                {
                    expandingFlags |= ExpandingFlags.Source;
                }
                if (!(expandingFlags & ExpandingFlags.Target)
                    && isDeeplyNestedType(target, targetStack, depth))
                {
                    expandingFlags |= ExpandingFlags.Target;
                }
                let originalHandler: typeof outofbandVarianceMarkerHandler;
                let propagatingVarianceFlags: RelationComparisonResult = 0;
                if (outofbandVarianceMarkerHandler) {
                    originalHandler = outofbandVarianceMarkerHandler;
                    outofbandVarianceMarkerHandler = onlyUnreliable => {
                        propagatingVarianceFlags |= onlyUnreliable
                            ? RelationComparisonResult.ReportsUnreliable
                            : RelationComparisonResult.ReportsUnmeasurable;
                        return originalHandler!(onlyUnreliable);
                    };
                }
                const result = expandingFlags !== ExpandingFlags.Both
                    ? structuredTypeRelatedTo(
                        source,
                        target,
                        reportErrors,
                        isIntersectionConstituent
                    )
                    : Ternary.Maybe;
                if (outofbandVarianceMarkerHandler) {
                    outofbandVarianceMarkerHandler = originalHandler;
                }
                expandingFlags = saveExpandingFlags;
                depth--;
                if (result) {
                    if (result === Ternary.True || depth === 0) {
                        // If result is definitely true, record all maybe keys as having succeeded
                        for (let i = maybeStart; i < maybeCount; i++) {
                            relation.set(
                                maybeKeys[i],
                                RelationComparisonResult.Succeeded
                                    | propagatingVarianceFlags
                            );
                        }
                        maybeCount = maybeStart;
                    }
                } else {
                    // A false result goes straight into global cache (when something is false under
                    // assumptions it will also be false without assumptions)
                    relation.set(
                        id,
                        (reportErrors ? RelationComparisonResult.Reported : 0)
                            | RelationComparisonResult.Failed
                            | propagatingVarianceFlags
                    );
                    maybeCount = maybeStart;
                }
                return result;
            }

            function structuredTypeRelatedTo(
                source: Type,
                target: Type,
                reportErrors: boolean,
                isIntersectionConstituent: boolean
            ): Ternary {
                const flags = source.flags & target.flags;
                if (relation === identityRelation
                    && !(flags & TypeFlags.Object))
                {
                    if (flags & TypeFlags.Index) {
                        return isRelatedTo(
                            (<IndexType> source).type,
                            (<IndexType> target).type, /*reportErrors*/
                            false
                        );
                    }
                    let result = Ternary.False;
                    if (flags & TypeFlags.IndexedAccess) {
                        if (result = isRelatedTo(
                            (<IndexedAccessType> source).objectType,
                            (<IndexedAccessType> target)
                                .objectType, /*reportErrors*/
                            false
                        )) {
                            if (result &= isRelatedTo(
                                (<IndexedAccessType> source).indexType,
                                (<IndexedAccessType> target)
                                    .indexType, /*reportErrors*/
                                false
                            )) {
                                return result;
                            }
                        }
                    }
                    if (flags & TypeFlags.Conditional) {
                        if ((<ConditionalType> source).root.isDistributive
                            === (<ConditionalType> target).root.isDistributive)
                        {
                            if (result = isRelatedTo(
                                (<ConditionalType> source).checkType,
                                (<ConditionalType> target)
                                    .checkType, /*reportErrors*/
                                false
                            )) {
                                if (result &= isRelatedTo(
                                    (<ConditionalType> source).extendsType,
                                    (<ConditionalType> target)
                                        .extendsType, /*reportErrors*/
                                    false
                                )) {
                                    if (result &= isRelatedTo(
                                        getTrueTypeFromConditionalType(<ConditionalType> source),
                                        getTrueTypeFromConditionalType(<ConditionalType> target), /*reportErrors*/
                                        false
                                    )) {
                                        if (result &= isRelatedTo(
                                            getFalseTypeFromConditionalType(<ConditionalType> source),
                                            getFalseTypeFromConditionalType(<ConditionalType> target), /*reportErrors*/
                                            false
                                        )) {
                                            return result;
                                        }
                                    }
                                }
                            }
                        }
                    }
                    if (flags & TypeFlags.Substitution) {
                        return isRelatedTo(
                            (<SubstitutionType> source).substitute,
                            (<SubstitutionType> target)
                                .substitute, /*reportErrors*/
                            false
                        );
                    }
                    return Ternary.False;
                }

                let result: Ternary;
                let originalErrorInfo: DiagnosticMessageChain | undefined;
                let varianceCheckFailed = false;
                const saveErrorInfo = captureErrorCalculationState();

                // We limit alias variance probing to only object and conditional types since their alias behavior
                // is more predictable than other, interned types, which may or may not have an alias depending on
                // the order in which things were checked.
                if (source.flags & (TypeFlags.Object | TypeFlags.Conditional)
                    && source.aliasSymbol
                    && source.aliasTypeArguments
                    && source.aliasSymbol === target.aliasSymbol
                    && !(source.aliasTypeArgumentsContainsMarker
                        || target.aliasTypeArgumentsContainsMarker))
                {
                    const variances = getAliasVariances(source.aliasSymbol);
                    const varianceResult = relateVariances(
                        source.aliasTypeArguments,
                        target.aliasTypeArguments,
                        variances,
                        isIntersectionConstituent
                    );
                    if (varianceResult !== undefined) {
                        return varianceResult;
                    }
                }

                if (target.flags & TypeFlags.TypeParameter) {
                    // A source type { [P in Q]: X } is related to a target type T if keyof T is related to Q and X is related to T[Q].
                    if (getObjectFlags(source) & ObjectFlags.Mapped
                        && isRelatedTo(
                            getIndexType(target),
                            getConstraintTypeFromMappedType(<MappedType> source)
                        ))
                    {
                        if (!(getMappedTypeModifiers(<MappedType> source)
                            & MappedTypeModifiers.IncludeOptional))
                        {
                            const templateType = getTemplateTypeFromMappedType(<MappedType> source);
                            const indexedAccessType = getIndexedAccessType(
                                target,
                                getTypeParameterFromMappedType(<MappedType> source)
                            );
                            if (result = isRelatedTo(
                                templateType,
                                indexedAccessType,
                                reportErrors
                            )) {
                                return result;
                            }
                        }
                    }
                } else if (target.flags & TypeFlags.Index) {
                    // A keyof S is related to a keyof T if T is related to S.
                    if (source.flags & TypeFlags.Index) {
                        if (result = isRelatedTo(
                            (<IndexType> target).type,
                            (<IndexType> source).type, /*reportErrors*/
                            false
                        )) {
                            return result;
                        }
                    }
                    // A type S is assignable to keyof T if S is assignable to keyof C, where C is the
                    // simplified form of T or, if T doesn't simplify, the constraint of T.
                    const constraint = getSimplifiedTypeOrConstraint(
                        (<IndexType> target).type
                    );
                    if (constraint) {
                        // We require Ternary.True here such that circular constraints don't cause
                        // false positives. For example, given 'T extends { [K in keyof T]: string }',
                        // 'keyof T' has itself as its constraint and produces a Ternary.Maybe when
                        // related to other types.
                        if (isRelatedTo(
                            source,
                            getIndexType(
                                constraint,
                                (target as IndexType).stringsOnly
                            ),
                            reportErrors
                        ) === Ternary.True) {
                            return Ternary.True;
                        }
                    }
                } else if (target.flags & TypeFlags.IndexedAccess) {
                    // A type S is related to a type T[K] if S is related to C, where C is the base
                    // constraint of T[K] for writing.
                    if (relation !== identityRelation) {
                        const objectType = (<IndexedAccessType> target)
                            .objectType;
                        const indexType = (<IndexedAccessType> target)
                            .indexType;
                        const baseObjectType = getBaseConstraintOfType(objectType)
                            || objectType;
                        const baseIndexType = getBaseConstraintOfType(indexType)
                            || indexType;
                        if (!isGenericObjectType(baseObjectType)
                            && !isGenericIndexType(baseIndexType))
                        {
                            const accessFlags = AccessFlags.Writing
                                | (baseObjectType !== objectType
                                    ? AccessFlags.NoIndexSignatures
                                    : 0);
                            const constraint = getIndexedAccessTypeOrUndefined(
                                baseObjectType,
                                baseIndexType, /*accessNode*/
                                undefined,
                                accessFlags
                            );
                            if (constraint
                                && (result = isRelatedTo(
                                    source,
                                    constraint,
                                    reportErrors
                                )))
                            {
                                return result;
                            }
                        }
                    }
                } else if (isGenericMappedType(target)) {
                    // A source type T is related to a target type { [P in X]: T[P] }
                    const template = getTemplateTypeFromMappedType(target);
                    const modifiers = getMappedTypeModifiers(target);
                    if (!(modifiers & MappedTypeModifiers.ExcludeOptional)) {
                        if (template.flags & TypeFlags.IndexedAccess
                            && (<IndexedAccessType> template).objectType
                            === source
                            && (<IndexedAccessType> template).indexType
                            === getTypeParameterFromMappedType(target))
                        {
                            return Ternary.True;
                        }
                        if (!isGenericMappedType(source)) {
                            const targetConstraint = getConstraintTypeFromMappedType(target);
                            const sourceKeys = getIndexType(
                                source, /*stringsOnly*/
                                undefined, /*noIndexSignatures*/
                                true
                            );
                            const includeOptional = modifiers
                                & MappedTypeModifiers.IncludeOptional;
                            const filteredByApplicability = includeOptional
                                ? intersectTypes(targetConstraint, sourceKeys)
                                : undefined;
                            // A source type T is related to a target type { [P in Q]: X } if Q is related to keyof T and T[Q] is related to X.
                            // A source type T is related to a target type { [P in Q]?: X } if some constituent Q' of Q is related to keyof T and T[Q'] is related to X.
                            if (includeOptional
                                ? !(filteredByApplicability!.flags
                                    & TypeFlags.Never)
                                : isRelatedTo(targetConstraint, sourceKeys))
                            {
                                const typeParameter = getTypeParameterFromMappedType(target);
                                const indexingType = filteredByApplicability
                                    ? getIntersectionType(
                                        [filteredByApplicability,
                                            typeParameter]
                                    )
                                    : typeParameter;
                                const indexedAccessType = getIndexedAccessType(
                                    source,
                                    indexingType
                                );
                                const templateType = getTemplateTypeFromMappedType(target);
                                if (result = isRelatedTo(
                                    indexedAccessType,
                                    templateType,
                                    reportErrors
                                )) {
                                    return result;
                                }
                            }
                            originalErrorInfo = errorInfo;
                            resetErrorInfo(saveErrorInfo);
                        }
                    }
                }

                if (source.flags & TypeFlags.TypeVariable) {
                    if (source.flags & TypeFlags.IndexedAccess
                        && target.flags & TypeFlags.IndexedAccess)
                    {
                        // A type S[K] is related to a type T[J] if S is related to T and K is related to J.
                        if (result = isRelatedTo(
                            (<IndexedAccessType> source).objectType,
                            (<IndexedAccessType> target).objectType,
                            reportErrors
                        )) {
                            result &= isRelatedTo(
                                (<IndexedAccessType> source).indexType,
                                (<IndexedAccessType> target).indexType,
                                reportErrors
                            );
                        }
                        if (result) {
                            resetErrorInfo(saveErrorInfo);
                            return result;
                        }
                    } else {
                        const constraint = getConstraintOfType(<TypeVariable> source);
                        if (!constraint
                            || (source.flags & TypeFlags.TypeParameter
                                && constraint.flags & TypeFlags.Any))
                        {
                            // A type variable with no constraint is not related to the non-primitive object type.
                            if (result = isRelatedTo(
                                emptyObjectType,
                                extractTypesOfKind(
                                    target,
                                    ~TypeFlags.NonPrimitive
                                )
                            )) {
                                resetErrorInfo(saveErrorInfo);
                                return result;
                            }
                        } // hi-speed no-this-instantiation check (less accurate, but avoids costly `this`-instantiation when the constraint will suffice), see #28231 for report on why this is needed
                        else if (result = isRelatedTo(
                            constraint,
                            target, /*reportErrors*/
                            false, /*headMessage*/
                            undefined,
                            isIntersectionConstituent
                        )) {
                            resetErrorInfo(saveErrorInfo);
                            return result;
                        } // slower, fuller, this-instantiated check (necessary when comparing raw `this` types from base classes), see `subclassWithPolymorphicThisIsAssignable.ts` test for example
                        else if (result = isRelatedTo(
                            getTypeWithThisArgument(
                                constraint,
                                source
                            ),
                            target,
                            reportErrors, /*headMessage*/
                            undefined,
                            isIntersectionConstituent
                        )) {
                            resetErrorInfo(saveErrorInfo);
                            return result;
                        }
                    }
                } else if (source.flags & TypeFlags.Index) {
                    if (result = isRelatedTo(
                        keyofConstraintType,
                        target,
                        reportErrors
                    )) {
                        resetErrorInfo(saveErrorInfo);
                        return result;
                    }
                } else if (source.flags & TypeFlags.Conditional) {
                    if (target.flags & TypeFlags.Conditional) {
                        // Two conditional types 'T1 extends U1 ? X1 : Y1' and 'T2 extends U2 ? X2 : Y2' are related if
                        // one of T1 and T2 is related to the other, U1 and U2 are identical types, X1 is related to X2,
                        // and Y1 is related to Y2.
                        const sourceParams = (source as ConditionalType).root
                            .inferTypeParameters;
                        let sourceExtends = (<ConditionalType> source)
                            .extendsType;
                        let mapper: TypeMapper | undefined;
                        if (sourceParams) {
                            // If the source has infer type parameters, we instantiate them in the context of the target
                            const ctx = createInferenceContext(
                                sourceParams, /*signature*/
                                undefined,
                                InferenceFlags.None,
                                isRelatedTo
                            );
                            inferTypes(
                                ctx.inferences,
                                (<ConditionalType> target).extendsType,
                                sourceExtends,
                                InferencePriority.NoConstraints
                                    | InferencePriority.AlwaysStrict
                            );
                            sourceExtends = instantiateType(
                                sourceExtends,
                                ctx.mapper
                            );
                            mapper = ctx.mapper;
                        }
                        if (isTypeIdenticalTo(
                            sourceExtends,
                            (<ConditionalType> target).extendsType
                        )
                            && (isRelatedTo(
                                (<ConditionalType> source).checkType,
                                (<ConditionalType> target).checkType
                            )
                                || isRelatedTo(
                                    (<ConditionalType> target).checkType,
                                    (<ConditionalType> source).checkType
                                )))
                        {
                            if (result = isRelatedTo(
                                instantiateType(
                                    getTrueTypeFromConditionalType(<ConditionalType> source),
                                    mapper
                                ),
                                getTrueTypeFromConditionalType(<ConditionalType> target),
                                reportErrors
                            )) {
                                result &= isRelatedTo(
                                    getFalseTypeFromConditionalType(<ConditionalType> source),
                                    getFalseTypeFromConditionalType(<ConditionalType> target),
                                    reportErrors
                                );
                            }
                            if (result) {
                                resetErrorInfo(saveErrorInfo);
                                return result;
                            }
                        }
                    } else {
                        const distributiveConstraint = getConstraintOfDistributiveConditionalType(<ConditionalType> source);
                        if (distributiveConstraint) {
                            if (result = isRelatedTo(
                                distributiveConstraint,
                                target,
                                reportErrors
                            )) {
                                resetErrorInfo(saveErrorInfo);
                                return result;
                            }
                        }
                        const defaultConstraint = getDefaultConstraintOfConditionalType(<ConditionalType> source);
                        if (defaultConstraint) {
                            if (result = isRelatedTo(
                                defaultConstraint,
                                target,
                                reportErrors
                            )) {
                                resetErrorInfo(saveErrorInfo);
                                return result;
                            }
                        }
                    }
                } else {
                    // An empty object type is related to any mapped type that includes a '?' modifier.
                    if (relation !== subtypeRelation
                        && relation !== strictSubtypeRelation
                        && isPartialMappedType(target)
                        && isEmptyObjectType(source))
                    {
                        return Ternary.True;
                    }
                    if (isGenericMappedType(target)) {
                        if (isGenericMappedType(source)) {
                            if (result = mappedTypeRelatedTo(
                                source,
                                target,
                                reportErrors
                            )) {
                                resetErrorInfo(saveErrorInfo);
                                return result;
                            }
                        }
                        return Ternary.False;
                    }
                    const sourceIsPrimitive = !!(source.flags
                        & TypeFlags.Primitive);
                    if (relation !== identityRelation) {
                        source = getApparentType(source);
                    } else if (isGenericMappedType(source)) {
                        return Ternary.False;
                    }
                    if (getObjectFlags(source) & ObjectFlags.Reference
                        && getObjectFlags(target) & ObjectFlags.Reference
                        && (<TypeReference> source).target
                        === (<TypeReference> target).target
                        && !(getObjectFlags(source) & ObjectFlags.MarkerType
                            || getObjectFlags(target)
                            & ObjectFlags.MarkerType))
                    {
                        // We have type references to the same generic type, and the type references are not marker
                        // type references (which are intended by be compared structurally). Obtain the variance
                        // information for the type parameters and relate the type arguments accordingly.
                        const variances = getVariances(
                            (<TypeReference> source).target
                        );
                        const varianceResult = relateVariances(
                            getTypeArguments(<TypeReference> source),
                            getTypeArguments(<TypeReference> target),
                            variances,
                            isIntersectionConstituent
                        );
                        if (varianceResult !== undefined) {
                            return varianceResult;
                        }
                    } else if (isReadonlyArrayType(target)
                        ? isArrayType(source) || isTupleType(source)
                        : isArrayType(target) && isTupleType(source)
                            && !source.target.readonly)
                    {
                        if (relation !== identityRelation) {
                            return isRelatedTo(
                                getIndexTypeOfType(
                                    source,
                                    IndexKind.Number
                                ) || anyType,
                                getIndexTypeOfType(target, IndexKind.Number)
                                    || anyType,
                                reportErrors
                            );
                        } else {
                            // By flags alone, we know that the `target` is a readonly array while the source is a normal array or tuple
                            // or `target` is an array and source is a tuple - in both cases the types cannot be identical, by construction
                            return Ternary.False;
                        }
                    } // Consider a fresh empty object literal type "closed" under the subtype relationship - this way `{} <- {[idx: string]: any} <- fresh({})`
                    // and not `{} <- fresh({}) <- {[idx: string]: any}`
                    else if ((relation === subtypeRelation
                        || relation === strictSubtypeRelation)
                        && isEmptyObjectType(target) && getObjectFlags(
                            target
                        ) & ObjectFlags.FreshLiteral
                        && !isEmptyObjectType(source))
                    {
                        return Ternary.False;
                    }
                    // Even if relationship doesn't hold for unions, intersections, or generic type references,
                    // it may hold in a structural comparison.
                    // In a check of the form X = A & B, we will have previously checked if A relates to X or B relates
                    // to X. Failing both of those we want to check if the aggregation of A and B's members structurally
                    // relates to X. Thus, we include intersection types on the source side here.
                    if (source.flags
                        & (TypeFlags.Object | TypeFlags.Intersection)
                        && target.flags & TypeFlags.Object)
                    {
                        // Report structural errors only if we haven't reported any errors yet
                        const reportStructuralErrors = reportErrors
                            && errorInfo === saveErrorInfo.errorInfo
                            && !sourceIsPrimitive;
                        result = propertiesRelatedTo(
                            source,
                            target,
                            reportStructuralErrors, /*excludedProperties*/
                            undefined,
                            isIntersectionConstituent
                        );
                        if (result) {
                            result &= signaturesRelatedTo(
                                source,
                                target,
                                SignatureKind.Call,
                                reportStructuralErrors
                            );
                            if (result) {
                                result &= signaturesRelatedTo(
                                    source,
                                    target,
                                    SignatureKind.Construct,
                                    reportStructuralErrors
                                );
                                if (result) {
                                    result &= indexTypesRelatedTo(
                                        source,
                                        target,
                                        IndexKind.String,
                                        sourceIsPrimitive,
                                        reportStructuralErrors
                                    );
                                    if (result) {
                                        result &= indexTypesRelatedTo(
                                            source,
                                            target,
                                            IndexKind.Number,
                                            sourceIsPrimitive,
                                            reportStructuralErrors
                                        );
                                    }
                                }
                            }
                        }
                        if (varianceCheckFailed && result) {
                            errorInfo = originalErrorInfo || errorInfo
                                || saveErrorInfo
                                    .errorInfo; // Use variance error (there is no structural one) and return false
                        } else if (result) {
                            return result;
                        }
                    }
                    // If S is an object type and T is a discriminated union, S may be related to T if
                    // there exists a constituent of T for every combination of the discriminants of S
                    // with respect to T. We do not report errors here, as we will use the existing
                    // error result from checking each constituent of the union.
                    if (source.flags
                        & (TypeFlags.Object | TypeFlags.Intersection)
                        && target.flags & TypeFlags.Union)
                    {
                        const objectOnlyTarget = extractTypesOfKind(
                            target,
                            TypeFlags.Object
                        );
                        if (objectOnlyTarget.flags & TypeFlags.Union) {
                            const result = typeRelatedToDiscriminatedType(
                                source,
                                objectOnlyTarget as UnionType
                            );
                            if (result) {
                                return result;
                            }
                        }
                    }
                }
                return Ternary.False;

                function relateVariances(
                    sourceTypeArguments: readonly Type[] | undefined,
                    targetTypeArguments: readonly Type[] | undefined,
                    variances: VarianceFlags[],
                    isIntersectionConstituent: boolean
                ) {
                    if (result = typeArgumentsRelatedTo(
                        sourceTypeArguments,
                        targetTypeArguments,
                        variances,
                        reportErrors,
                        isIntersectionConstituent
                    )) {
                        return result;
                    }
                    if (some(
                        variances,
                        v => !!(v & VarianceFlags.AllowsStructuralFallback)
                    )) {
                        // If some type parameter was `Unmeasurable` or `Unreliable`, and we couldn't pass by assuming it was identical, then we
                        // have to allow a structural fallback check
                        // We elide the variance-based error elaborations, since those might not be too helpful, since we'll potentially
                        // be assuming identity of the type parameter.
                        originalErrorInfo = undefined;
                        resetErrorInfo(saveErrorInfo);
                        return undefined;
                    }
                    const allowStructuralFallback = targetTypeArguments
                        && hasCovariantVoidArgument(
                            targetTypeArguments,
                            variances
                        );
                    varianceCheckFailed = !allowStructuralFallback;
                    // The type arguments did not relate appropriately, but it may be because we have no variance
                    // information (in which case typeArgumentsRelatedTo defaulted to covariance for all type
                    // arguments). It might also be the case that the target type has a 'void' type argument for
                    // a covariant type parameter that is only used in return positions within the generic type
                    // (in which case any type argument is permitted on the source side). In those cases we proceed
                    // with a structural comparison. Otherwise, we know for certain the instantiations aren't
                    // related and we can return here.
                    if (variances !== emptyArray && !allowStructuralFallback) {
                        // In some cases generic types that are covariant in regular type checking mode become
                        // invariant in --strictFunctionTypes mode because one or more type parameters are used in
                        // both co- and contravariant positions. In order to make it easier to diagnose *why* such
                        // types are invariant, if any of the type parameters are invariant we reset the reported
                        // errors and instead force a structural comparison (which will include elaborations that
                        // reveal the reason).
                        // We can switch on `reportErrors` here, since varianceCheckFailed guarantees we return `False`,
                        // we can return `False` early here to skip calculating the structural error message we don't need.
                        if (varianceCheckFailed
                            && !(reportErrors
                                && some(
                                    variances,
                                    v => (v & VarianceFlags.VarianceMask)
                                        === VarianceFlags.Invariant
                                )))
                        {
                            return Ternary.False;
                        }
                        // We remember the original error information so we can restore it in case the structural
                        // comparison unexpectedly succeeds. This can happen when the structural comparison result
                        // is a Ternary.Maybe for example caused by the recursion depth limiter.
                        originalErrorInfo = errorInfo;
                        resetErrorInfo(saveErrorInfo);
                    }
                }
            }

            function reportUnmeasurableMarkers(p: TypeParameter) {
                if (outofbandVarianceMarkerHandler
                    && (p === markerSuperType || p === markerSubType
                        || p === markerOtherType))
                {
                    outofbandVarianceMarkerHandler(/*onlyUnreliable*/ false);
                }
                return p;
            }

            function reportUnreliableMarkers(p: TypeParameter) {
                if (outofbandVarianceMarkerHandler
                    && (p === markerSuperType || p === markerSubType
                        || p === markerOtherType))
                {
                    outofbandVarianceMarkerHandler(/*onlyUnreliable*/ true);
                }
                return p;
            }

            // A type [P in S]: X is related to a type [Q in T]: Y if T is related to S and X' is
            // related to Y, where X' is an instantiation of X in which P is replaced with Q. Notice
            // that S and T are contra-variant whereas X and Y are co-variant.
            function mappedTypeRelatedTo(
                source: MappedType,
                target: MappedType,
                reportErrors: boolean
            ): Ternary {
                const modifiersRelated = relation === comparableRelation
                    || (relation === identityRelation
                        ? getMappedTypeModifiers(source)
                            === getMappedTypeModifiers(target)
                        : getCombinedMappedTypeOptionality(source)
                            <= getCombinedMappedTypeOptionality(target));
                if (modifiersRelated) {
                    let result: Ternary;
                    const targetConstraint = getConstraintTypeFromMappedType(target);
                    const sourceConstraint = instantiateType(
                        getConstraintTypeFromMappedType(source),
                        getCombinedMappedTypeOptionality(source) < 0
                            ? reportUnmeasurableMarkers
                            : reportUnreliableMarkers
                    );
                    if (result = isRelatedTo(
                        targetConstraint,
                        sourceConstraint,
                        reportErrors
                    )) {
                        const mapper = createTypeMapper(
                            [getTypeParameterFromMappedType(source)],
                            [getTypeParameterFromMappedType(target)]
                        );
                        return result
                            & isRelatedTo(
                                instantiateType(
                                    getTemplateTypeFromMappedType(source),
                                    mapper
                                ),
                                getTemplateTypeFromMappedType(target),
                                reportErrors
                            );
                    }
                }
                return Ternary.False;
            }

            function typeRelatedToDiscriminatedType(
                source: Type,
                target: UnionType
            ) {
                // 1. Generate the combinations of discriminant properties & types 'source' can satisfy.
                //    a. If the number of combinations is above a set limit, the comparison is too complex.
                // 2. Filter 'target' to the subset of types whose discriminants exist in the matrix.
                //    a. If 'target' does not satisfy all discriminants in the matrix, 'source' is not related.
                // 3. For each type in the filtered 'target', determine if all non-discriminant properties of
                //    'target' are related to a property in 'source'.
                //
                // NOTE: See ~/tests/cases/conformance/types/typeRelationships/assignmentCompatibility/assignmentCompatWithDiscriminatedUnion.ts
                //       for examples.

                const sourceProperties = getPropertiesOfObjectType(source);
                const sourcePropertiesFiltered = findDiscriminantProperties(
                    sourceProperties,
                    target
                );
                if (!sourcePropertiesFiltered) return Ternary.False;

                // Though we could compute the number of combinations as we generate
                // the matrix, this would incur additional memory overhead due to
                // array allocations. To reduce this overhead, we first compute
                // the number of combinations to ensure we will not surpass our
                // fixed limit before incurring the cost of any allocations:
                let numCombinations = 1;
                for (const sourceProperty of sourcePropertiesFiltered) {
                    numCombinations *= countTypes(getTypeOfSymbol(sourceProperty));
                    if (numCombinations > 25) {
                        // We've reached the complexity limit.
                        return Ternary.False;
                    }
                }

                // Compute the set of types for each discriminant property.
                const sourceDiscriminantTypes:
                    Type[][] = new Array<Type[]>(
                    sourcePropertiesFiltered.length
                );
                const excludedProperties = createUnderscoreEscapedMap<true>();
                for (let i = 0; i < sourcePropertiesFiltered.length; i++) {
                    const sourceProperty = sourcePropertiesFiltered[i];
                    const sourcePropertyType = getTypeOfSymbol(sourceProperty);
                    sourceDiscriminantTypes
                        [i] = sourcePropertyType.flags & TypeFlags.Union
                            ? (sourcePropertyType as UnionType).types
                            : [sourcePropertyType];
                    excludedProperties.set(sourceProperty.escapedName, true);
                }

                // Match each combination of the cartesian product of discriminant properties to one or more
                // constituents of 'target'. If any combination does not have a match then 'source' is not relatable.
                const discriminantCombinations = cartesianProduct(sourceDiscriminantTypes);
                const matchingTypes: Type[] = [];
                for (const combination of discriminantCombinations) {
                    let hasMatch = false;
                    outer:
                    for (const type of target.types) {
                        for (let i = 0; i < sourcePropertiesFiltered.length;
                            i++)
                        {
                            const sourceProperty = sourcePropertiesFiltered[i];
                            const targetProperty = getPropertyOfObjectType(
                                type,
                                sourceProperty.escapedName
                            );
                            if (!targetProperty) continue outer;
                            if (sourceProperty === targetProperty) continue;
                            // We compare the source property to the target in the context of a single discriminant type.
                            const related = propertyRelatedTo(
                                source,
                                target,
                                sourceProperty,
                                targetProperty,
                                _ => combination[i], /*reportErrors*/
                                false, /*isIntersectionConstituent*/
                                false
                            );
                            // If the target property could not be found, or if the properties were not related,
                            // then this constituent is not a match.
                            if (!related) {
                                continue outer;
                            }
                        }
                        pushIfUnique(matchingTypes, type, equateValues);
                        hasMatch = true;
                    }
                    if (!hasMatch) {
                        // We failed to match any type for this combination.
                        return Ternary.False;
                    }
                }

                // Compare the remaining non-discriminant properties of each match.
                let result = Ternary.True;
                for (const type of matchingTypes) {
                    result &= propertiesRelatedTo(
                        source,
                        type, /*reportErrors*/
                        false,
                        excludedProperties, /*isIntersectionConstituent*/
                        false
                    );
                    if (result) {
                        result &= signaturesRelatedTo(
                            source,
                            type,
                            SignatureKind.Call, /*reportStructuralErrors*/
                            false
                        );
                        if (result) {
                            result &= signaturesRelatedTo(
                                source,
                                type,
                                SignatureKind
                                    .Construct, /*reportStructuralErrors*/
                                false
                            );
                            if (result) {
                                result &= indexTypesRelatedTo(
                                    source,
                                    type,
                                    IndexKind.String, /*sourceIsPrimitive*/
                                    false, /*reportStructuralErrors*/
                                    false
                                );
                                if (result) {
                                    result &= indexTypesRelatedTo(
                                        source,
                                        type,
                                        IndexKind.Number, /*sourceIsPrimitive*/
                                        false, /*reportStructuralErrors*/
                                        false
                                    );
                                }
                            }
                        }
                    }
                    if (!result) {
                        return result;
                    }
                }
                return result;
            }

            function excludeProperties(
                properties: Symbol[],
                excludedProperties: UnderscoreEscapedMap<true> | undefined
            ) {
                if (!excludedProperties
                    || properties.length === 0)
                    return properties;
                let result: Symbol[] | undefined;
                for (let i = 0; i < properties.length; i++) {
                    if (!excludedProperties.has(properties[i].escapedName)) {
                        if (result) {
                            result.push(properties[i]);
                        }
                    } else if (!result) {
                        result = properties.slice(0, i);
                    }
                }
                return result || properties;
            }

            function isPropertySymbolTypeRelated(
                sourceProp: Symbol,
                targetProp: Symbol,
                getTypeOfSourceProperty: (sym: Symbol) => Type,
                reportErrors: boolean,
                isIntersectionConstituent: boolean
            ): Ternary {
                const targetIsOptional = strictNullChecks
                    && !!(getCheckFlags(targetProp) & CheckFlags.Partial);
                const source = getTypeOfSourceProperty(sourceProp);
                if (getCheckFlags(targetProp) & CheckFlags.DeferredType
                    && !getSymbolLinks(targetProp).type)
                {
                    // Rather than resolving (and normalizing) the type, relate constituent-by-constituent without performing normalization or seconadary passes
                    const links = getSymbolLinks(targetProp);
                    Debug.assertDefined(links.deferralParent);
                    Debug.assertDefined(links.deferralConstituents);
                    const unionParent = !!(links.deferralParent!.flags
                        & TypeFlags.Union);
                    let result = unionParent ? Ternary.False : Ternary.True;
                    const targetTypes = links.deferralConstituents!;
                    for (const targetType of targetTypes) {
                        const related = isRelatedTo(
                            source,
                            targetType, /*reportErrors*/
                            false, /*headMessage*/
                            undefined, /*isIntersectionConstituent*/
                            !unionParent
                        );
                        if (!unionParent) {
                            if (!related) {
                                // Can't assign to a target individually - have to fallback to assigning to the _whole_ intersection (which forces normalization)
                                return isRelatedTo(
                                    source,
                                    addOptionality(
                                        getTypeOfSymbol(targetProp),
                                        targetIsOptional
                                    ),
                                    reportErrors
                                );
                            }
                            result &= related;
                        } else {
                            if (related) {
                                return related;
                            }
                        }
                    }
                    if (unionParent && !result && targetIsOptional) {
                        result = isRelatedTo(source, undefinedType);
                    }
                    if (unionParent && !result && reportErrors) {
                        // The easiest way to get the right errors here is to un-defer (which may be costly)
                        // If it turns out this is too costly too often, we can replicate the error handling logic within
                        // typeRelatedToSomeType without the discriminatable type branch (as that requires a manifest union
                        // type on which to hand discriminable properties, which we are expressly trying to avoid here)
                        return isRelatedTo(
                            source,
                            addOptionality(
                                getTypeOfSymbol(targetProp),
                                targetIsOptional
                            ),
                            reportErrors
                        );
                    }
                    return result;
                } else {
                    return isRelatedTo(
                        source,
                        addOptionality(
                            getTypeOfSymbol(targetProp),
                            targetIsOptional
                        ),
                        reportErrors, /*headMessage*/
                        undefined,
                        isIntersectionConstituent
                    );
                }
            }

            function propertyRelatedTo(
                source: Type,
                target: Type,
                sourceProp: Symbol,
                targetProp: Symbol,
                getTypeOfSourceProperty: (sym: Symbol) => Type,
                reportErrors: boolean,
                isIntersectionConstituent: boolean
            ): Ternary {
                const sourcePropFlags = getDeclarationModifierFlagsFromSymbol(sourceProp);
                const targetPropFlags = getDeclarationModifierFlagsFromSymbol(targetProp);
                if (sourcePropFlags & ModifierFlags.Private
                    || targetPropFlags & ModifierFlags.Private)
                {
                    const hasDifferingDeclarations = sourceProp
                        .valueDeclaration !== targetProp.valueDeclaration;
                    if (getCheckFlags(sourceProp) & CheckFlags.ContainsPrivate
                        && hasDifferingDeclarations)
                    {
                        if (reportErrors) {
                            reportError(
                                Diagnostics
                                    .Property_0_has_conflicting_declarations_and_is_inaccessible_in_type_1,
                                symbolToString(sourceProp),
                                typeToString(source)
                            );
                        }
                        return Ternary.False;
                    }
                    if (hasDifferingDeclarations) {
                        if (reportErrors) {
                            if (sourcePropFlags & ModifierFlags.Private
                                && targetPropFlags & ModifierFlags.Private)
                            {
                                reportError(
                                    Diagnostics
                                        .Types_have_separate_declarations_of_a_private_property_0,
                                    symbolToString(targetProp)
                                );
                            } else {
                                reportError(
                                    Diagnostics
                                        .Property_0_is_private_in_type_1_but_not_in_type_2,
                                    symbolToString(targetProp),
                                    typeToString(
                                        sourcePropFlags & ModifierFlags.Private
                                            ? source
                                            : target
                                    ),
                                    typeToString(
                                        sourcePropFlags & ModifierFlags.Private
                                            ? target
                                            : source
                                    )
                                );
                            }
                        }
                        return Ternary.False;
                    }
                } else if (targetPropFlags & ModifierFlags.Protected) {
                    if (!isValidOverrideOf(sourceProp, targetProp)) {
                        if (reportErrors) {
                            reportError(
                                Diagnostics
                                    .Property_0_is_protected_but_type_1_is_not_a_class_derived_from_2,
                                symbolToString(targetProp),
                                typeToString(
                                    getDeclaringClass(sourceProp) || source
                                ),
                                typeToString(
                                    getDeclaringClass(targetProp) || target
                                )
                            );
                        }
                        return Ternary.False;
                    }
                } else if (sourcePropFlags & ModifierFlags.Protected) {
                    if (reportErrors) {
                        reportError(
                            Diagnostics
                                .Property_0_is_protected_in_type_1_but_public_in_type_2,
                            symbolToString(targetProp),
                            typeToString(source),
                            typeToString(target)
                        );
                    }
                    return Ternary.False;
                }
                // If the target comes from a partial union prop, allow `undefined` in the target type
                const related = isPropertySymbolTypeRelated(
                    sourceProp,
                    targetProp,
                    getTypeOfSourceProperty,
                    reportErrors,
                    isIntersectionConstituent
                );
                if (!related) {
                    if (reportErrors) {
                        reportIncompatibleError(
                            Diagnostics.Types_of_property_0_are_incompatible,
                            symbolToString(targetProp)
                        );
                    }
                    return Ternary.False;
                }
                // When checking for comparability, be more lenient with optional properties.
                if (relation !== comparableRelation
                    && sourceProp.flags & SymbolFlags.Optional
                    && !(targetProp.flags & SymbolFlags.Optional))
                {
                    // TypeScript 1.0 spec (April 2014): 3.8.3
                    // S is a subtype of a type T, and T is a supertype of S if ...
                    // S' and T are object types and, for each member M in T..
                    // M is a property and S' contains a property N where
                    // if M is a required property, N is also a required property
                    // (M - property in T)
                    // (N - property in S)
                    if (reportErrors) {
                        reportError(
                            Diagnostics
                                .Property_0_is_optional_in_type_1_but_required_in_type_2,
                            symbolToString(targetProp),
                            typeToString(source),
                            typeToString(target)
                        );
                    }
                    return Ternary.False;
                }
                return related;
            }

            function reportUnmatchedProperty(
                source: Type,
                target: Type,
                unmatchedProperty: Symbol,
                requireOptionalProperties: boolean
            ) {
                let shouldSkipElaboration = false;
                // give specific error in case where private names have the same description
                if (
                    unmatchedProperty.valueDeclaration
                    && isNamedDeclaration(unmatchedProperty.valueDeclaration)
                    && isPrivateIdentifier(
                        unmatchedProperty.valueDeclaration.name
                    )
                    && isClassDeclaration(source.symbol.valueDeclaration)
                ) {
                    const privateIdentifierDescription = unmatchedProperty
                        .valueDeclaration.name.escapedText;
                    const symbolTableKey = getSymbolNameForPrivateIdentifier(
                        source.symbol,
                        privateIdentifierDescription
                    );
                    if (symbolTableKey
                        && !!getPropertyOfType(source, symbolTableKey))
                    {
                        const sourceName = source.symbol.valueDeclaration.name;
                        const targetName = isClassDeclaration(
                            target.symbol.valueDeclaration
                        )
                            ? target.symbol.valueDeclaration.name
                            : undefined;
                        reportError(
                            Diagnostics
                                .Property_0_in_type_1_refers_to_a_different_member_that_cannot_be_accessed_from_within_type_2,
                            diagnosticName(privateIdentifierDescription),
                            diagnosticName(sourceName || anon),
                            diagnosticName(targetName || anon)
                        );
                        return;
                    }
                }
                const props = arrayFrom(
                    getUnmatchedProperties(
                        source,
                        target,
                        requireOptionalProperties, /*matchDiscriminantProperties*/
                        false
                    )
                );
                if (!headMessage
                    || (headMessage.code
                        !== Diagnostics
                            .Class_0_incorrectly_implements_interface_1.code
                        && headMessage.code
                        !== Diagnostics
                            .Class_0_incorrectly_implements_class_1_Did_you_mean_to_extend_1_and_inherit_its_members_as_a_subclass
                            .code))
                {
                    shouldSkipElaboration = true; // Retain top-level error for interface implementing issues, otherwise omit it
                }
                if (props.length === 1) {
                    const propName = symbolToString(unmatchedProperty);
                    reportError(
                        Diagnostics
                            .Property_0_is_missing_in_type_1_but_required_in_type_2,
                        propName,
                        ...getTypeNamesForErrorDisplay(source, target)
                    );
                    if (length(unmatchedProperty.declarations)) {
                        associateRelatedInfo(
                            createDiagnosticForNode(
                                unmatchedProperty.declarations[0],
                                Diagnostics._0_is_declared_here,
                                propName
                            )
                        );
                    }
                    if (shouldSkipElaboration && errorInfo) {
                        overrideNextErrorInfo++;
                    }
                } else if (tryElaborateArrayLikeErrors(
                    source,
                    target, /*reportErrors*/
                    false
                )) {
                    if (props.length
                        > 5)
                    { // arbitrary cutoff for too-long list form
                        reportError(
                            Diagnostics
                                .Type_0_is_missing_the_following_properties_from_type_1_Colon_2_and_3_more,
                            typeToString(source),
                            typeToString(target),
                            map(props.slice(0, 4), p => symbolToString(p))
                                .join(', '),
                            props.length - 4
                        );
                    } else {
                        reportError(
                            Diagnostics
                                .Type_0_is_missing_the_following_properties_from_type_1_Colon_2,
                            typeToString(source),
                            typeToString(target),
                            map(props, p => symbolToString(p)).join(', ')
                        );
                    }
                    if (shouldSkipElaboration && errorInfo) {
                        overrideNextErrorInfo++;
                    }
                }
                // No array like or unmatched property error - just issue top level error (errorInfo = undefined)
            }

            function propertiesRelatedTo(
                source: Type,
                target: Type,
                reportErrors: boolean,
                excludedProperties: UnderscoreEscapedMap<true> | undefined,
                isIntersectionConstituent: boolean
            ): Ternary {
                if (relation === identityRelation) {
                    return propertiesIdenticalTo(
                        source,
                        target,
                        excludedProperties
                    );
                }
                const requireOptionalProperties = (relation === subtypeRelation
                    || relation === strictSubtypeRelation)
                    && !isObjectLiteralType(source)
                    && !isEmptyArrayLiteralType(source)
                    && !isTupleType(source);
                const unmatchedProperty = getUnmatchedProperty(
                    source,
                    target,
                    requireOptionalProperties, /*matchDiscriminantProperties*/
                    false
                );
                if (unmatchedProperty) {
                    if (reportErrors) {
                        reportUnmatchedProperty(
                            source,
                            target,
                            unmatchedProperty,
                            requireOptionalProperties
                        );
                    }
                    return Ternary.False;
                }
                if (isObjectLiteralType(target)) {
                    for (const sourceProp
                        of excludeProperties(
                            getPropertiesOfType(source),
                            excludedProperties
                        ))
                    {
                        if (!getPropertyOfObjectType(
                            target,
                            sourceProp.escapedName
                        )) {
                            const sourceType = getTypeOfSymbol(sourceProp);
                            if (!(sourceType === undefinedType
                                || sourceType === undefinedWideningType
                                || sourceType === optionalType))
                            {
                                if (reportErrors) {
                                    reportError(
                                        Diagnostics
                                            .Property_0_does_not_exist_on_type_1,
                                        symbolToString(sourceProp),
                                        typeToString(target)
                                    );
                                }
                                return Ternary.False;
                            }
                        }
                    }
                }
                let result = Ternary.True;
                if (isTupleType(target)) {
                    const targetRestType = getRestTypeOfTupleType(target);
                    if (targetRestType) {
                        if (!isTupleType(source)) {
                            return Ternary.False;
                        }
                        const sourceRestType = getRestTypeOfTupleType(source);
                        if (sourceRestType
                            && !isRelatedTo(
                                sourceRestType,
                                targetRestType,
                                reportErrors
                            ))
                        {
                            if (reportErrors) {
                                reportError(
                                    Diagnostics
                                        .Rest_signatures_are_incompatible
                                );
                            }
                            return Ternary.False;
                        }
                        const targetCount = getTypeReferenceArity(target) - 1;
                        const sourceCount = getTypeReferenceArity(source)
                            - (sourceRestType ? 1 : 0);
                        const sourceTypeArguments = getTypeArguments(<TypeReference> source);
                        for (let i = targetCount; i < sourceCount; i++) {
                            const related = isRelatedTo(
                                sourceTypeArguments[i],
                                targetRestType,
                                reportErrors
                            );
                            if (!related) {
                                if (reportErrors) {
                                    reportError(
                                        Diagnostics
                                            .Property_0_is_incompatible_with_rest_element_type,
                                        '' + i
                                    );
                                }
                                return Ternary.False;
                            }
                            result &= related;
                        }
                    }
                }
                // We only call this for union target types when we're attempting to do excess property checking - in those cases, we want to get _all possible props_
                // from the target union, across all members
                const properties = getPropertiesOfType(target);
                const numericNamesOnly = isTupleType(source)
                    && isTupleType(target);
                for (const targetProp of excludeProperties(
                    properties,
                    excludedProperties
                )) {
                    const name = targetProp.escapedName;
                    if (!(targetProp.flags & SymbolFlags.Prototype)
                        && (!numericNamesOnly || isNumericLiteralName(name)
                            || name === 'length'))
                    {
                        const sourceProp = getPropertyOfType(source, name);
                        if (sourceProp && sourceProp !== targetProp) {
                            const related = propertyRelatedTo(
                                source,
                                target,
                                sourceProp,
                                targetProp,
                                getTypeOfSymbol,
                                reportErrors,
                                isIntersectionConstituent
                            );
                            if (!related) {
                                return Ternary.False;
                            }
                            result &= related;
                        }
                    }
                }
                return result;
            }

            function propertiesIdenticalTo(
                source: Type,
                target: Type,
                excludedProperties: UnderscoreEscapedMap<true> | undefined
            ): Ternary {
                if (!(source.flags & TypeFlags.Object
                    && target.flags & TypeFlags.Object))
                {
                    return Ternary.False;
                }
                const sourceProperties = excludeProperties(
                    getPropertiesOfObjectType(source),
                    excludedProperties
                );
                const targetProperties = excludeProperties(
                    getPropertiesOfObjectType(target),
                    excludedProperties
                );
                if (sourceProperties.length !== targetProperties.length) {
                    return Ternary.False;
                }
                let result = Ternary.True;
                for (const sourceProp of sourceProperties) {
                    const targetProp = getPropertyOfObjectType(
                        target,
                        sourceProp.escapedName
                    );
                    if (!targetProp) {
                        return Ternary.False;
                    }
                    const related = compareProperties(
                        sourceProp,
                        targetProp,
                        isRelatedTo
                    );
                    if (!related) {
                        return Ternary.False;
                    }
                    result &= related;
                }
                return result;
            }

            function signaturesRelatedTo(
                source: Type,
                target: Type,
                kind: SignatureKind,
                reportErrors: boolean
            ): Ternary {
                if (relation === identityRelation) {
                    return signaturesIdenticalTo(source, target, kind);
                }
                if (target === anyFunctionType || source === anyFunctionType) {
                    return Ternary.True;
                }

                const sourceIsJSConstructor = source.symbol
                    && isJSConstructor(source.symbol.valueDeclaration);
                const targetIsJSConstructor = target.symbol
                    && isJSConstructor(target.symbol.valueDeclaration);

                const sourceSignatures = getSignaturesOfType(
                    source,
                    (sourceIsJSConstructor && kind === SignatureKind.Construct)
                        ? SignatureKind.Call
                        : kind
                );
                const targetSignatures = getSignaturesOfType(
                    target,
                    (targetIsJSConstructor && kind === SignatureKind.Construct)
                        ? SignatureKind.Call
                        : kind
                );

                if (kind === SignatureKind.Construct && sourceSignatures.length
                    && targetSignatures.length)
                {
                    if (isAbstractConstructorType(source)
                        && !isAbstractConstructorType(target))
                    {
                        // An abstract constructor type is not assignable to a non-abstract constructor type
                        // as it would otherwise be possible to new an abstract class. Note that the assignability
                        // check we perform for an extends clause excludes construct signatures from the target,
                        // so this check never proceeds.
                        if (reportErrors) {
                            reportError(
                                Diagnostics
                                    .Cannot_assign_an_abstract_constructor_type_to_a_non_abstract_constructor_type
                            );
                        }
                        return Ternary.False;
                    }
                    if (!constructorVisibilitiesAreCompatible(
                        sourceSignatures[0],
                        targetSignatures[0],
                        reportErrors
                    )) {
                        return Ternary.False;
                    }
                }

                let result = Ternary.True;
                const saveErrorInfo = captureErrorCalculationState();
                const incompatibleReporter = kind === SignatureKind.Construct
                    ? reportIncompatibleConstructSignatureReturn
                    : reportIncompatibleCallSignatureReturn;

                if (getObjectFlags(source) & ObjectFlags.Instantiated
                    && getObjectFlags(target) & ObjectFlags.Instantiated
                    && source.symbol === target.symbol)
                {
                    // We have instantiations of the same anonymous type (which typically will be the type of a
                    // method). Simply do a pairwise comparison of the signatures in the two signature lists instead
                    // of the much more expensive N * M comparison matrix we explore below. We erase type parameters
                    // as they are known to always be the same.
                    for (let i = 0; i < targetSignatures.length; i++) {
                        const related = signatureRelatedTo(
                            sourceSignatures[i],
                            targetSignatures[i], /*erase*/
                            true,
                            reportErrors,
                            incompatibleReporter(sourceSignatures[i],
                                targetSignatures[i])
                        );
                        if (!related) {
                            return Ternary.False;
                        }
                        result &= related;
                    }
                } else if (sourceSignatures.length === 1
                    && targetSignatures.length === 1)
                {
                    // For simple functions (functions with a single signature) we only erase type parameters for
                    // the comparable relation. Otherwise, if the source signature is generic, we instantiate it
                    // in the context of the target signature before checking the relationship. Ideally we'd do
                    // this regardless of the number of signatures, but the potential costs are prohibitive due
                    // to the quadratic nature of the logic below.
                    const eraseGenerics = relation === comparableRelation
                        || !!compilerOptions.noStrictGenericChecks;
                    result = signatureRelatedTo(
                        sourceSignatures[0],
                        targetSignatures[0],
                        eraseGenerics,
                        reportErrors,
                        incompatibleReporter(sourceSignatures[0],
                            targetSignatures[0])
                    );
                } else {
                    outer:
                    for (const t of targetSignatures) {
                        // Only elaborate errors from the first failure
                        let shouldElaborateErrors = reportErrors;
                        for (const s of sourceSignatures) {
                            const related = signatureRelatedTo(
                                s,
                                t, /*erase*/
                                true,
                                shouldElaborateErrors,
                                incompatibleReporter(s, t)
                            );
                            if (related) {
                                result &= related;
                                resetErrorInfo(saveErrorInfo);
                                continue outer;
                            }
                            shouldElaborateErrors = false;
                        }

                        if (shouldElaborateErrors) {
                            reportError(
                                Diagnostics
                                    .Type_0_provides_no_match_for_the_signature_1,
                                typeToString(source),
                                signatureToString(
                                    t, /*enclosingDeclaration*/
                                    undefined, /*flags*/
                                    undefined,
                                    kind
                                )
                            );
                        }
                        return Ternary.False;
                    }
                }
                return result;
            }

            function reportIncompatibleCallSignatureReturn(
                siga: Signature,
                sigb: Signature
            ) {
                if (siga.parameters.length === 0
                    && sigb.parameters.length === 0)
                {
                    return (source: Type,
                        target: Type) =>
                    reportIncompatibleError(
                        Diagnostics
                            .Call_signatures_with_no_arguments_have_incompatible_return_types_0_and_1,
                        typeToString(source),
                        typeToString(target)
                    );
                }
                return (source: Type,
                    target: Type) =>
                reportIncompatibleError(
                    Diagnostics
                        .Call_signature_return_types_0_and_1_are_incompatible,
                    typeToString(source),
                    typeToString(target)
                );
            }

            function reportIncompatibleConstructSignatureReturn(
                siga: Signature,
                sigb: Signature
            ) {
                if (siga.parameters.length === 0
                    && sigb.parameters.length === 0)
                {
                    return (source: Type,
                        target: Type) =>
                    reportIncompatibleError(
                        Diagnostics
                            .Construct_signatures_with_no_arguments_have_incompatible_return_types_0_and_1,
                        typeToString(source),
                        typeToString(target)
                    );
                }
                return (source: Type,
                    target: Type) =>
                reportIncompatibleError(
                    Diagnostics
                        .Construct_signature_return_types_0_and_1_are_incompatible,
                    typeToString(source),
                    typeToString(target)
                );
            }

            /**
             * See signatureAssignableTo, compareSignaturesIdentical
             */
            function signatureRelatedTo(
                source: Signature,
                target: Signature,
                erase: boolean,
                reportErrors: boolean,
                incompatibleReporter: (source: Type, target: Type) => void
            ): Ternary {
                return compareSignaturesRelated(
                    erase
                        ? getErasedSignature(source)
                        : source,
                    erase ? getErasedSignature(target) : target,
                    relation === strictSubtypeRelation
                        ? SignatureCheckMode.StrictArity
                        : 0,
                    reportErrors,
                    reportError,
                    incompatibleReporter,
                    isRelatedTo,
                    reportUnreliableMarkers
                );
            }

            function signaturesIdenticalTo(
                source: Type,
                target: Type,
                kind: SignatureKind
            ): Ternary {
                const sourceSignatures = getSignaturesOfType(source, kind);
                const targetSignatures = getSignaturesOfType(target, kind);
                if (sourceSignatures.length !== targetSignatures.length) {
                    return Ternary.False;
                }
                let result = Ternary.True;
                for (let i = 0; i < sourceSignatures.length; i++) {
                    const related = compareSignaturesIdentical(
                        sourceSignatures[i],
                        targetSignatures[i], /*partialMatch*/
                        false, /*ignoreThisTypes*/
                        false, /*ignoreReturnTypes*/
                        false,
                        isRelatedTo
                    );
                    if (!related) {
                        return Ternary.False;
                    }
                    result &= related;
                }
                return result;
            }

            function eachPropertyRelatedTo(
                source: Type,
                target: Type,
                kind: IndexKind,
                reportErrors: boolean
            ): Ternary {
                let result = Ternary.True;
                for (const prop of getPropertiesOfObjectType(source)) {
                    if (isIgnoredJsxProperty(source, prop)) {
                        continue;
                    }
                    // Skip over symbol-named members
                    if (prop.nameType
                        && prop.nameType.flags & TypeFlags.UniqueESSymbol)
                    {
                        continue;
                    }
                    if (kind === IndexKind.String
                        || isNumericLiteralName(prop.escapedName))
                    {
                        const related = isRelatedTo(
                            getTypeOfSymbol(prop),
                            target,
                            reportErrors
                        );
                        if (!related) {
                            if (reportErrors) {
                                reportError(
                                    Diagnostics
                                        .Property_0_is_incompatible_with_index_signature,
                                    symbolToString(prop)
                                );
                            }
                            return Ternary.False;
                        }
                        result &= related;
                    }
                }
                return result;
            }

            function indexInfoRelatedTo(
                sourceInfo: IndexInfo,
                targetInfo: IndexInfo,
                reportErrors: boolean
            ) {
                const related = isRelatedTo(
                    sourceInfo.type,
                    targetInfo.type,
                    reportErrors
                );
                if (!related && reportErrors) {
                    reportError(Diagnostics.Index_signatures_are_incompatible);
                }
                return related;
            }

            function indexTypesRelatedTo(
                source: Type,
                target: Type,
                kind: IndexKind,
                sourceIsPrimitive: boolean,
                reportErrors: boolean
            ): Ternary {
                if (relation === identityRelation) {
                    return indexTypesIdenticalTo(source, target, kind);
                }
                const targetInfo = getIndexInfoOfType(target, kind);
                if (!targetInfo || targetInfo.type.flags & TypeFlags.Any
                    && !sourceIsPrimitive)
                {
                    // Index signature of type any permits assignment from everything but primitives
                    return Ternary.True;
                }
                const sourceInfo = getIndexInfoOfType(source, kind)
                    || kind === IndexKind.Number
                    && getIndexInfoOfType(source, IndexKind.String);
                if (sourceInfo) {
                    return indexInfoRelatedTo(
                        sourceInfo,
                        targetInfo,
                        reportErrors
                    );
                }
                if (isGenericMappedType(source)) {
                    // A generic mapped type { [P in K]: T } is related to an index signature { [x: string]: U }
                    // if T is related to U.
                    return kind === IndexKind.String
                        ? isRelatedTo(
                            getTemplateTypeFromMappedType(source),
                            targetInfo.type,
                            reportErrors
                        )
                        : Ternary.False;
                }
                if (isObjectTypeWithInferableIndex(source)) {
                    let related = Ternary.True;
                    if (kind === IndexKind.String) {
                        const sourceNumberInfo = getIndexInfoOfType(
                            source,
                            IndexKind.Number
                        );
                        if (sourceNumberInfo) {
                            related = indexInfoRelatedTo(
                                sourceNumberInfo,
                                targetInfo,
                                reportErrors
                            );
                        }
                    }
                    if (related) {
                        related &= eachPropertyRelatedTo(
                            source,
                            targetInfo.type,
                            kind,
                            reportErrors
                        );
                    }
                    return related;
                }
                if (reportErrors) {
                    reportError(
                        Diagnostics.Index_signature_is_missing_in_type_0,
                        typeToString(source)
                    );
                }
                return Ternary.False;
            }

            function indexTypesIdenticalTo(
                source: Type,
                target: Type,
                indexKind: IndexKind
            ): Ternary {
                const targetInfo = getIndexInfoOfType(target, indexKind);
                const sourceInfo = getIndexInfoOfType(source, indexKind);
                if (!sourceInfo && !targetInfo) {
                    return Ternary.True;
                }
                if (sourceInfo && targetInfo
                    && sourceInfo.isReadonly === targetInfo.isReadonly)
                {
                    return isRelatedTo(sourceInfo.type, targetInfo.type);
                }
                return Ternary.False;
            }

            function constructorVisibilitiesAreCompatible(
                sourceSignature: Signature,
                targetSignature: Signature,
                reportErrors: boolean
            ) {
                if (!sourceSignature.declaration
                    || !targetSignature.declaration)
                {
                    return true;
                }

                const sourceAccessibility = getSelectedModifierFlags(
                    sourceSignature.declaration,
                    ModifierFlags.NonPublicAccessibilityModifier
                );
                const targetAccessibility = getSelectedModifierFlags(
                    targetSignature.declaration,
                    ModifierFlags.NonPublicAccessibilityModifier
                );

                // A public, protected and private signature is assignable to a private signature.
                if (targetAccessibility === ModifierFlags.Private) {
                    return true;
                }

                // A public and protected signature is assignable to a protected signature.
                if (targetAccessibility === ModifierFlags.Protected
                    && sourceAccessibility !== ModifierFlags.Private)
                {
                    return true;
                }

                // Only a public signature is assignable to public signature.
                if (targetAccessibility !== ModifierFlags.Protected
                    && !sourceAccessibility)
                {
                    return true;
                }

                if (reportErrors) {
                    reportError(
                        Diagnostics
                            .Cannot_assign_a_0_constructor_type_to_a_1_constructor_type,
                        visibilityToString(sourceAccessibility),
                        visibilityToString(targetAccessibility)
                    );
                }

                return false;
            }
        }

        function getBestMatchingType(
            source: Type,
            target: UnionOrIntersectionType,
            isRelatedTo = compareTypesAssignable
        ) {
            return findMatchingDiscriminantType(source, target, isRelatedTo)
                || findMatchingTypeReferenceOrTypeAliasReference(
                    source,
                    target
                )
                || findBestTypeForObjectLiteral(source, target)
                || findBestTypeForInvokable(source, target)
                || findMostOverlappyType(source, target);
        }

        function discriminateTypeByDiscriminableItems(
            target: UnionType,
            discriminators: [() => Type, __String][],
            related: (source: Type, target: Type) => boolean | Ternary
        ): Type | undefined;
        function discriminateTypeByDiscriminableItems(
            target: UnionType,
            discriminators: [() => Type, __String][],
            related: (source: Type, target: Type) => boolean | Ternary,
            defaultValue: Type
        ): Type;
        function discriminateTypeByDiscriminableItems(
            target: UnionType,
            discriminators: [() => Type, __String][],
            related: (source: Type, target: Type) => boolean | Ternary,
            defaultValue?: Type
        ) {
            // undefined=unknown, true=discriminated, false=not discriminated
            // The state of each type progresses from left to right. Discriminated types stop at 'true'.
            const discriminable = target.types
                .map(_ => undefined) as (boolean | undefined)[];
            for (const [getDiscriminatingType, propertyName]
                of discriminators)
            {
                let i = 0;
                for (const type of target.types) {
                    const targetType = getTypeOfPropertyOfType(
                        type,
                        propertyName
                    );
                    if (targetType
                        && related(getDiscriminatingType(), targetType))
                    {
                        discriminable[i] = discriminable[i] === undefined
                            ? true
                            : discriminable[i];
                    } else {
                        discriminable[i] = false;
                    }
                    i++;
                }
            }
            const match = discriminable.indexOf(/*searchElement*/ true);
            // make sure exactly 1 matches before returning it
            return match === -1
                || discriminable.indexOf(/*searchElement*/ true, match + 1)
                !== -1
                ? defaultValue
                : target.types[match];
        }

        /**
         * A type is 'weak' if it is an object type with at least one optional property
         * and no required properties, call/construct signatures or index signatures
         */
        function isWeakType(type: Type): boolean {
            if (type.flags & TypeFlags.Object) {
                const resolved = resolveStructuredTypeMembers(<ObjectType> type);
                return resolved.callSignatures.length === 0
                    && resolved.constructSignatures.length === 0
                    && !resolved.stringIndexInfo && !resolved.numberIndexInfo
                    && resolved.properties.length > 0
                    && every(
                        resolved.properties,
                        p => !!(p.flags & SymbolFlags.Optional)
                    );
            }
            if (type.flags & TypeFlags.Intersection) {
                return every((<IntersectionType> type).types, isWeakType);
            }
            return false;
        }

        function hasCommonProperties(
            source: Type,
            target: Type,
            isComparingJsxAttributes: boolean
        ) {
            for (const prop of getPropertiesOfType(source)) {
                if (isKnownProperty(
                    target,
                    prop.escapedName,
                    isComparingJsxAttributes
                )) {
                    return true;
                }
            }
            return false;
        }

        // Return a type reference where the source type parameter is replaced with the target marker
        // type, and flag the result as a marker type reference.
        function getMarkerTypeReference(
            type: GenericType,
            source: TypeParameter,
            target: Type
        ) {
            const result = createTypeReference(
                type,
                map(type.typeParameters, t => t === source ? target : t)
            );
            result.objectFlags |= ObjectFlags.MarkerType;
            return result;
        }

        function getAliasVariances(symbol: Symbol) {
            const links = getSymbolLinks(symbol);
            return getVariancesWorker(
                links.typeParameters,
                links,
                (_links, param, marker) => {
                    const type = getTypeAliasInstantiation(
                        symbol,
                        instantiateTypes(
                            links.typeParameters!,
                            makeUnaryTypeMapper(param, marker)
                        )
                    );
                    type.aliasTypeArgumentsContainsMarker = true;
                    return type;
                }
            );
        }

        // Return an array containing the variance of each type parameter. The variance is effectively
        // a digest of the type comparisons that occur for each type argument when instantiations of the
        // generic type are structurally compared. We infer the variance information by comparing
        // instantiations of the generic type for type arguments with known relations. The function
        // returns the emptyArray singleton if we're not in strictFunctionTypes mode or if the function
        // has been invoked recursively for the given generic type.
        function getVariancesWorker<TCache
            extends { variances?: VarianceFlags[]; }>(
            typeParameters: readonly TypeParameter[] = emptyArray,
            cache: TCache,
            createMarkerType: (
                input: TCache,
                param: TypeParameter,
                marker: Type
            ) => Type
        ): VarianceFlags[] {
            let variances = cache.variances;
            if (!variances) {
                // The emptyArray singleton is used to signal a recursive invocation.
                cache.variances = emptyArray;
                variances = [];
                for (const tp of typeParameters) {
                    let unmeasurable = false;
                    let unreliable = false;
                    const oldHandler = outofbandVarianceMarkerHandler;
                    outofbandVarianceMarkerHandler = (onlyUnreliable) => onlyUnreliable
                        ? unreliable = true
                        : unmeasurable = true;
                    // We first compare instantiations where the type parameter is replaced with
                    // marker types that have a known subtype relationship. From this we can infer
                    // invariance, covariance, contravariance or bivariance.
                    const typeWithSuper = createMarkerType(
                        cache,
                        tp,
                        markerSuperType
                    );
                    const typeWithSub = createMarkerType(
                        cache,
                        tp,
                        markerSubType
                    );
                    let variance = (isTypeAssignableTo(
                        typeWithSub,
                        typeWithSuper
                    )
                        ? VarianceFlags.Covariant
                        : 0)
                        | (isTypeAssignableTo(typeWithSuper, typeWithSub)
                            ? VarianceFlags.Contravariant
                            : 0);
                    // If the instantiations appear to be related bivariantly it may be because the
                    // type parameter is independent (i.e. it isn't witnessed anywhere in the generic
                    // type). To determine this we compare instantiations where the type parameter is
                    // replaced with marker types that are known to be unrelated.
                    if (variance === VarianceFlags.Bivariant
                        && isTypeAssignableTo(
                            createMarkerType(
                                cache,
                                tp,
                                markerOtherType
                            ),
                            typeWithSuper
                        ))
                    {
                        variance = VarianceFlags.Independent;
                    }
                    outofbandVarianceMarkerHandler = oldHandler;
                    if (unmeasurable || unreliable) {
                        if (unmeasurable) {
                            variance |= VarianceFlags.Unmeasurable;
                        }
                        if (unreliable) {
                            variance |= VarianceFlags.Unreliable;
                        }
                    }
                    variances.push(variance);
                }
                cache.variances = variances;
            }
            return variances;
        }

        function getVariances(type: GenericType): VarianceFlags[] {
            // Arrays and tuples are known to be covariant, no need to spend time computing this (emptyArray implies covariance for all parameters)
            if (type === globalArrayType || type === globalReadonlyArrayType
                || type.objectFlags & ObjectFlags.Tuple)
            {
                return emptyArray;
            }
            return getVariancesWorker(
                type.typeParameters,
                type,
                getMarkerTypeReference
            );
        }

        // Return true if the given type reference has a 'void' type argument for a covariant type parameter.
        // See comment at call in recursiveTypeRelatedTo for when this case matters.
        function hasCovariantVoidArgument(
            typeArguments: readonly Type[],
            variances: VarianceFlags[]
        ): boolean {
            for (let i = 0; i < variances.length; i++) {
                if ((variances[i] & VarianceFlags.VarianceMask)
                    === VarianceFlags.Covariant
                    && typeArguments[i].flags & TypeFlags.Void)
                {
                    return true;
                }
            }
            return false;
        }

        function isUnconstrainedTypeParameter(type: Type) {
            return type.flags & TypeFlags.TypeParameter
                && !getConstraintOfTypeParameter(<TypeParameter> type);
        }

        function isNonDeferredTypeReference(type:
            Type): type is TypeReference
        {
            return !!(getObjectFlags(type) & ObjectFlags.Reference)
                && !(<TypeReference> type).node;
        }

        function isTypeReferenceWithGenericArguments(type: Type): boolean {
            return isNonDeferredTypeReference(type)
                && some(
                    getTypeArguments(type),
                    t => isUnconstrainedTypeParameter(t)
                        || isTypeReferenceWithGenericArguments(t)
                );
        }

        /**
         * getTypeReferenceId(A<T, number, U>) returns "111=0-12=1"
         *   where A.id=111 and number.id=12
         */
        function getTypeReferenceId(
            type: TypeReference,
            typeParameters: Type[],
            depth = 0
        ) {
            let result = '' + type.target.id;
            for (const t of getTypeArguments(type)) {
                if (isUnconstrainedTypeParameter(t)) {
                    let index = typeParameters.indexOf(t);
                    if (index < 0) {
                        index = typeParameters.length;
                        typeParameters.push(t);
                    }
                    result += '=' + index;
                } else if (depth < 4
                    && isTypeReferenceWithGenericArguments(t))
                {
                    result += '<'
                        + getTypeReferenceId(
                            t as TypeReference,
                            typeParameters,
                            depth + 1
                        ) + '>';
                } else {
                    result += '-' + t.id;
                }
            }
            return result;
        }

        /**
         * To improve caching, the relation key for two generic types uses the target's id plus ids of the type parameters.
         * For other cases, the types ids are used.
         */
        function getRelationKey(
            source: Type,
            target: Type,
            isIntersectionConstituent: boolean,
            relation: Map<RelationComparisonResult>
        ) {
            if (relation === identityRelation && source.id > target.id) {
                const temp = source;
                source = target;
                target = temp;
            }
            const delimiter = isIntersectionConstituent ? ';' : ',';
            if (isTypeReferenceWithGenericArguments(source)
                && isTypeReferenceWithGenericArguments(target))
            {
                const typeParameters: Type[] = [];
                return getTypeReferenceId(
                    <TypeReference> source,
                    typeParameters
                ) + delimiter
                    + getTypeReferenceId(
                        <TypeReference> target,
                        typeParameters
                    );
            }
            return source.id + delimiter + target.id;
        }

        // Invoke the callback for each underlying property symbol of the given symbol and return the first
        // value that isn't undefined.
        function forEachProperty<T>(
            prop: Symbol,
            callback: (p: Symbol) => T
        ): T | undefined {
            if (getCheckFlags(prop) & CheckFlags.Synthetic) {
                for (const t of (<TransientSymbol> prop).containingType!
                    .types)
                {
                    const p = getPropertyOfType(t, prop.escapedName);
                    const result = p && forEachProperty(p, callback);
                    if (result) {
                        return result;
                    }
                }
                return undefined;
            }
            return callback(prop);
        }

        // Return the declaring class type of a property or undefined if property not declared in class
        function getDeclaringClass(prop: Symbol) {
            return prop.parent && prop.parent.flags & SymbolFlags.Class
                ? getDeclaredTypeOfSymbol(getParentOfSymbol(prop)!)
                : undefined;
        }

        // Return true if some underlying source property is declared in a class that derives
        // from the given base class.
        function isPropertyInClassDerivedFrom(
            prop: Symbol,
            baseClass: Type | undefined
        ) {
            return forEachProperty(
                prop,
                sp => {
                    const sourceClass = getDeclaringClass(sp);
                    return sourceClass ? hasBaseType(sourceClass, baseClass)
                        : false;
                }
            );
        }

        // Return true if source property is a valid override of protected parts of target property.
        function isValidOverrideOf(sourceProp: Symbol, targetProp: Symbol) {
            return !forEachProperty(
                targetProp,
                tp => getDeclarationModifierFlagsFromSymbol(tp)
                    & ModifierFlags.Protected
                    ? !isPropertyInClassDerivedFrom(
                        sourceProp,
                        getDeclaringClass(tp)
                    )
                    : false
            );
        }

        // Return true if the given class derives from each of the declaring classes of the protected
        // constituents of the given property.
        function isClassDerivedFromDeclaringClasses(
            checkClass: Type,
            prop: Symbol
        ) {
            return forEachProperty(
                prop,
                p => getDeclarationModifierFlagsFromSymbol(p)
                    & ModifierFlags.Protected
                    ? !hasBaseType(checkClass, getDeclaringClass(p))
                    : false
            )
                ? undefined
                : checkClass;
        }

        // Return true if the given type is deeply nested. We consider this to be the case when structural type comparisons
        // for 5 or more occurrences or instantiations of the type have been recorded on the given stack. It is possible,
        // though highly unlikely, for this test to be true in a situation where a chain of instantiations is not infinitely
        // expanding. Effectively, we will generate a false positive when two types are structurally equal to at least 5
        // levels, but unequal at some level beyond that.
        // In addition, this will also detect when an indexed access has been chained off of 5 or more times (which is essentially
        // the dual of the structural comparison), and likewise mark the type as deeply nested, potentially adding false positives
        // for finite but deeply expanding indexed accesses (eg, for `Q[P1][P2][P3][P4][P5]`).
        function isDeeplyNestedType(
            type: Type,
            stack: Type[],
            depth: number
        ): boolean {
            // We track all object types that have an associated symbol (representing the origin of the type)
            if (depth >= 5 && type.flags & TypeFlags.Object
                && !isObjectOrArrayLiteralType(type))
            {
                const symbol = type.symbol;
                if (symbol) {
                    let count = 0;
                    for (let i = 0; i < depth; i++) {
                        const t = stack[i];
                        if (t.flags & TypeFlags.Object
                            && t.symbol === symbol)
                        {
                            count++;
                            if (count >= 5) return true;
                        }
                    }
                }
            }
            if (depth >= 5 && type.flags & TypeFlags.IndexedAccess) {
                const root = getRootObjectTypeFromIndexedAccessChain(type);
                let count = 0;
                for (let i = 0; i < depth; i++) {
                    const t = stack[i];
                    if (getRootObjectTypeFromIndexedAccessChain(t) === root) {
                        count++;
                        if (count >= 5) return true;
                    }
                }
            }
            return false;
        }

        /**
         * Gets the leftmost object type in a chain of indexed accesses, eg, in A[P][Q], returns A
         */
        function getRootObjectTypeFromIndexedAccessChain(type: Type) {
            let t = type;
            while (t.flags & TypeFlags.IndexedAccess) {
                t = (t as IndexedAccessType).objectType;
            }
            return t;
        }

        function isPropertyIdenticalTo(
            sourceProp: Symbol,
            targetProp: Symbol
        ): boolean {
            return compareProperties(
                sourceProp,
                targetProp,
                compareTypesIdentical
            ) !== Ternary.False;
        }

        function compareProperties(
            sourceProp: Symbol,
            targetProp: Symbol,
            compareTypes: (source: Type, target: Type) => Ternary
        ): Ternary {
            // Two members are considered identical when
            // - they are public properties with identical names, optionality, and types,
            // - they are private or protected properties originating in the same declaration and having identical types
            if (sourceProp === targetProp) {
                return Ternary.True;
            }
            const sourcePropAccessibility = getDeclarationModifierFlagsFromSymbol(sourceProp)
                & ModifierFlags.NonPublicAccessibilityModifier;
            const targetPropAccessibility = getDeclarationModifierFlagsFromSymbol(targetProp)
                & ModifierFlags.NonPublicAccessibilityModifier;
            if (sourcePropAccessibility !== targetPropAccessibility) {
                return Ternary.False;
            }
            if (sourcePropAccessibility) {
                if (getTargetSymbol(sourceProp)
                    !== getTargetSymbol(targetProp))
                {
                    return Ternary.False;
                }
            } else {
                if ((sourceProp.flags & SymbolFlags.Optional)
                    !== (targetProp.flags & SymbolFlags.Optional))
                {
                    return Ternary.False;
                }
            }
            if (isReadonlySymbol(sourceProp)
                !== isReadonlySymbol(targetProp))
            {
                return Ternary.False;
            }
            return compareTypes(
                getTypeOfSymbol(sourceProp),
                getTypeOfSymbol(targetProp)
            );
        }

        function isMatchingSignature(
            source: Signature,
            target: Signature,
            partialMatch: boolean
        ) {
            const sourceParameterCount = getParameterCount(source);
            const targetParameterCount = getParameterCount(target);
            const sourceMinArgumentCount = getMinArgumentCount(source);
            const targetMinArgumentCount = getMinArgumentCount(target);
            const sourceHasRestParameter = hasEffectiveRestParameter(source);
            const targetHasRestParameter = hasEffectiveRestParameter(target);
            // A source signature matches a target signature if the two signatures have the same number of required,
            // optional, and rest parameters.
            if (sourceParameterCount === targetParameterCount
                && sourceMinArgumentCount === targetMinArgumentCount
                && sourceHasRestParameter === targetHasRestParameter)
            {
                return true;
            }
            // A source signature partially matches a target signature if the target signature has no fewer required
            // parameters
            if (partialMatch
                && sourceMinArgumentCount <= targetMinArgumentCount)
            {
                return true;
            }
            return false;
        }

        /**
         * See signatureRelatedTo, compareSignaturesIdentical
         */
        function compareSignaturesIdentical(
            source: Signature,
            target: Signature,
            partialMatch: boolean,
            ignoreThisTypes: boolean,
            ignoreReturnTypes: boolean,
            compareTypes: (s: Type, t: Type) => Ternary
        ): Ternary {
            // TODO (drosen): De-duplicate code between related functions.
            if (source === target) {
                return Ternary.True;
            }
            if (!(isMatchingSignature(source, target, partialMatch))) {
                return Ternary.False;
            }
            // Check that the two signatures have the same number of type parameters.
            if (length(source.typeParameters)
                !== length(target.typeParameters))
            {
                return Ternary.False;
            }
            // Check that type parameter constraints and defaults match. If they do, instantiate the source
            // signature with the type parameters of the target signature and continue the comparison.
            if (target.typeParameters) {
                const mapper = createTypeMapper(
                    source.typeParameters!,
                    target.typeParameters
                );
                for (let i = 0; i < target.typeParameters.length; i++) {
                    const s = source.typeParameters![i];
                    const t = target.typeParameters[i];
                    if (!(s === t
                        || compareTypes(
                            instantiateType(
                                getConstraintFromTypeParameter(s),
                                mapper
                            ) || unknownType,
                            getConstraintFromTypeParameter(t) || unknownType
                        )
                        && compareTypes(
                            instantiateType(
                                getDefaultFromTypeParameter(s),
                                mapper
                            ) || unknownType,
                            getDefaultFromTypeParameter(t) || unknownType
                        )))
                    {
                        return Ternary.False;
                    }
                }
                source = instantiateSignature(
                    source,
                    mapper, /*eraseTypeParameters*/
                    true
                );
            }
            let result = Ternary.True;
            if (!ignoreThisTypes) {
                const sourceThisType = getThisTypeOfSignature(source);
                if (sourceThisType) {
                    const targetThisType = getThisTypeOfSignature(target);
                    if (targetThisType) {
                        const related = compareTypes(
                            sourceThisType,
                            targetThisType
                        );
                        if (!related) {
                            return Ternary.False;
                        }
                        result &= related;
                    }
                }
            }
            const targetLen = getParameterCount(target);
            for (let i = 0; i < targetLen; i++) {
                const s = getTypeAtPosition(source, i);
                const t = getTypeAtPosition(target, i);
                const related = compareTypes(t, s);
                if (!related) {
                    return Ternary.False;
                }
                result &= related;
            }
            if (!ignoreReturnTypes) {
                const sourceTypePredicate = getTypePredicateOfSignature(source);
                const targetTypePredicate = getTypePredicateOfSignature(target);
                result &= sourceTypePredicate || targetTypePredicate
                    ? compareTypePredicatesIdentical(
                        sourceTypePredicate,
                        targetTypePredicate,
                        compareTypes
                    )
                    : compareTypes(
                        getReturnTypeOfSignature(source),
                        getReturnTypeOfSignature(target)
                    );
            }
            return result;
        }

        function compareTypePredicatesIdentical(
            source: TypePredicate | undefined,
            target: TypePredicate | undefined,
            compareTypes: (s: Type, t: Type) => Ternary
        ): Ternary {
            return !(source && target
                && typePredicateKindsMatch(source, target))
                ? Ternary.False
                : source.type === target.type
                    ? Ternary.True
                    : source.type && target.type
                        ? compareTypes(source.type, target.type)
                        : Ternary.False;
        }

        function literalTypesWithSameBaseType(types: Type[]): boolean {
            let commonBaseType: Type | undefined;
            for (const t of types) {
                const baseType = getBaseTypeOfLiteralType(t);
                if (!commonBaseType) {
                    commonBaseType = baseType;
                }
                if (baseType === t || baseType !== commonBaseType) {
                    return false;
                }
            }
            return true;
        }

        // When the candidate types are all literal types with the same base type, return a union
        // of those literal types. Otherwise, return the leftmost type for which no type to the
        // right is a supertype.
        function getSupertypeOrUnion(types: Type[]): Type {
            return literalTypesWithSameBaseType(types)
                ? getUnionType(types)
                : reduceLeft(types, (s, t) => isTypeSubtypeOf(s, t) ? t : s)!;
        }

        function getCommonSupertype(types: Type[]): Type {
            if (!strictNullChecks) {
                return getSupertypeOrUnion(types);
            }
            const primaryTypes = filter(
                types,
                t => !(t.flags & TypeFlags.Nullable)
            );
            return primaryTypes.length
                ? getNullableType(
                    getSupertypeOrUnion(primaryTypes),
                    getFalsyFlagsOfTypes(types) & TypeFlags.Nullable
                )
                : getUnionType(types, UnionReduction.Subtype);
        }

        // Return the leftmost type for which no type to the right is a subtype.
        function getCommonSubtype(types: Type[]) {
            return reduceLeft(types, (s, t) => isTypeSubtypeOf(t, s) ? t : s)!;
        }

        function isArrayType(type: Type): boolean {
            return !!(getObjectFlags(type) & ObjectFlags.Reference)
                && ((<TypeReference> type).target === globalArrayType
                    || (<TypeReference> type).target
                    === globalReadonlyArrayType);
        }

        function isReadonlyArrayType(type: Type): boolean {
            return !!(getObjectFlags(type) & ObjectFlags.Reference)
                && (<TypeReference> type).target === globalReadonlyArrayType;
        }

        function isMutableArrayOrTuple(type: Type): boolean {
            return isArrayType(type) && !isReadonlyArrayType(type)
                || isTupleType(type) && !type.target.readonly;
        }

        function getElementTypeOfArrayType(type: Type): Type | undefined {
            return isArrayType(type)
                ? getTypeArguments(type as TypeReference)[0]
                : undefined;
        }

        function isArrayLikeType(type: Type): boolean {
            // A type is array-like if it is a reference to the global Array or global ReadonlyArray type,
            // or if it is not the undefined or null type and if it is assignable to ReadonlyArray<any>
            return isArrayType(type) || !(type.flags & TypeFlags.Nullable)
                && isTypeAssignableTo(type, anyReadonlyArrayType);
        }

        function isEmptyArrayLiteralType(type: Type): boolean {
            const elementType = isArrayType(type)
                ? getTypeArguments(<TypeReference> type)[0]
                : undefined;
            return elementType === undefinedWideningType
                || elementType === implicitNeverType;
        }

        function isTupleLikeType(type: Type): boolean {
            return isTupleType(type)
                || !!getPropertyOfType(type, '0' as __String);
        }

        function isArrayOrTupleLikeType(type: Type): boolean {
            return isArrayLikeType(type) || isTupleLikeType(type);
        }

        function getTupleElementType(type: Type, index: number) {
            const propType = getTypeOfPropertyOfType(
                type,
                '' + index as __String
            );
            if (propType) {
                return propType;
            }
            if (everyType(type, isTupleType)) {
                return mapType(
                    type,
                    t => getRestTypeOfTupleType(<TupleTypeReference> t)
                        || undefinedType
                );
            }
            return undefined;
        }

        function isNeitherUnitTypeNorNever(type: Type): boolean {
            return !(type.flags & (TypeFlags.Unit | TypeFlags.Never));
        }

        function isUnitType(type: Type): boolean {
            return !!(type.flags & TypeFlags.Unit);
        }

        function isLiteralType(type: Type): boolean {
            return type.flags & TypeFlags.Boolean
                ? true
                : type.flags & TypeFlags.Union
                    ? type.flags & TypeFlags.EnumLiteral
                        ? true
                        : every((<UnionType> type).types, isUnitType)
                    : isUnitType(type);
        }

        function getBaseTypeOfLiteralType(type: Type): Type {
            return type.flags & TypeFlags.EnumLiteral
                ? getBaseTypeOfEnumLiteralType(<LiteralType> type)
                : type.flags & TypeFlags.StringLiteral
                    ? stringType
                    : type.flags & TypeFlags.NumberLiteral
                        ? numberType
                        : type.flags & TypeFlags.BigIntLiteral
                            ? bigintType
                            : type.flags & TypeFlags.BooleanLiteral
                                ? booleanType
                                : type.flags & TypeFlags.Union
                                    ? getUnionType(
                                        sameMap(
                                            (<UnionType> type).types,
                                            getBaseTypeOfLiteralType
                                        )
                                    )
                                    : type;
        }

        function getWidenedLiteralType(type: Type): Type {
            return type.flags & TypeFlags.EnumLiteral
                && isFreshLiteralType(type)
                ? getBaseTypeOfEnumLiteralType(<LiteralType> type)
                : type.flags & TypeFlags.StringLiteral && isFreshLiteralType(
                    type
                )
                    ? stringType
                    : type.flags & TypeFlags.NumberLiteral
                        && isFreshLiteralType(type)
                        ? numberType
                        : type.flags & TypeFlags.BigIntLiteral
                            && isFreshLiteralType(type)
                            ? bigintType
                            : type.flags & TypeFlags.BooleanLiteral
                                && isFreshLiteralType(type)
                                ? booleanType
                                : type.flags & TypeFlags.Union
                                    ? getUnionType(
                                        sameMap(
                                            (<UnionType> type).types,
                                            getWidenedLiteralType
                                        )
                                    )
                                    : type;
        }

        function getWidenedUniqueESSymbolType(type: Type): Type {
            return type.flags & TypeFlags.UniqueESSymbol
                ? esSymbolType
                : type.flags & TypeFlags.Union
                    ? getUnionType(
                        sameMap(
                            (<UnionType> type).types,
                            getWidenedUniqueESSymbolType
                        )
                    )
                    : type;
        }

        function getWidenedLiteralLikeTypeForContextualType(
            type: Type,
            contextualType: Type | undefined
        ) {
            if (!isLiteralOfContextualType(type, contextualType)) {
                type = getWidenedUniqueESSymbolType(getWidenedLiteralType(type));
            }
            return type;
        }

        function getWidenedLiteralLikeTypeForContextualReturnTypeIfNeeded(
            type: Type | undefined,
            contextualSignatureReturnType: Type | undefined,
            isAsync: boolean
        ) {
            if (type && isUnitType(type)) {
                const contextualType = !contextualSignatureReturnType
                    ? undefined
                    : isAsync
                        ? getPromisedTypeOfPromise(contextualSignatureReturnType)
                        : contextualSignatureReturnType;
                type = getWidenedLiteralLikeTypeForContextualType(
                    type,
                    contextualType
                );
            }
            return type;
        }

        function getWidenedLiteralLikeTypeForContextualIterationTypeIfNeeded(
            type: Type | undefined,
            contextualSignatureReturnType: Type | undefined,
            kind: IterationTypeKind,
            isAsyncGenerator: boolean
        ) {
            if (type && isUnitType(type)) {
                const contextualType = !contextualSignatureReturnType
                    ? undefined
                    : getIterationTypeOfGeneratorFunctionReturnType(
                        kind,
                        contextualSignatureReturnType,
                        isAsyncGenerator
                    );
                type = getWidenedLiteralLikeTypeForContextualType(
                    type,
                    contextualType
                );
            }
            return type;
        }

        /**
         * Check if a Type was written as a tuple type literal.
         * Prefer using isTupleLikeType() unless the use of `elementTypes` is required.
         */
        function isTupleType(type: Type): type is TupleTypeReference {
            return !!(getObjectFlags(type) & ObjectFlags.Reference
                && (<TypeReference> type).target.objectFlags
                & ObjectFlags.Tuple);
        }

        function getRestTypeOfTupleType(type: TupleTypeReference) {
            return type.target.hasRestElement
                ? getTypeArguments(type)[type.target.typeParameters!.length
                    - 1]
                : undefined;
        }

        function getRestArrayTypeOfTupleType(type: TupleTypeReference) {
            const restType = getRestTypeOfTupleType(type);
            return restType && createArrayType(restType);
        }

        function getLengthOfTupleType(type: TupleTypeReference) {
            return getTypeReferenceArity(type)
                - (type.target.hasRestElement ? 1 : 0);
        }

        function isZeroBigInt({ value }BigIntLiteralType) {
            return value.base10Value === '0';
        }

        function getFalsyFlagsOfTypes(types: Type[]): TypeFlags {
            let result: TypeFlags = 0;
            for (const t of types) {
                result |= getFalsyFlags(t);
            }
            return result;
        }

        // Returns the String, Number, Boolean, StringLiteral, NumberLiteral, BooleanLiteral, Void, Undefined, or Null
        // flags for the string, number, boolean, "", 0, false, void, undefined, or null types respectively. Returns
        // no flags for all other types (including non-falsy literal types).
        function getFalsyFlags(type: Type): TypeFlags {
            return type.flags & TypeFlags.Union
                ? getFalsyFlagsOfTypes((<UnionType> type).types)
                : type.flags & TypeFlags.StringLiteral
                    ? (<StringLiteralType> type).value === ''
                        ? TypeFlags.StringLiteral
                        : 0
                    : type.flags & TypeFlags.NumberLiteral
                        ? (<NumberLiteralType> type).value === 0
                            ? TypeFlags.NumberLiteral
                            : 0
                        : type.flags & TypeFlags.BigIntLiteral
                            ? isZeroBigInt(<BigIntLiteralType> type)
                                ? TypeFlags.BigIntLiteral
                                : 0
                            : type.flags & TypeFlags.BooleanLiteral
                                ? (type === falseType
                                    || type === regularFalseType)
                                    ? TypeFlags.BooleanLiteral
                                    : 0
                                : type.flags & TypeFlags.PossiblyFalsy;
        }

        function removeDefinitelyFalsyTypes(type: Type): Type {
            return getFalsyFlags(type) & TypeFlags.DefinitelyFalsy
                ? filterType(
                    type,
                    t => !(getFalsyFlags(t) & TypeFlags.DefinitelyFalsy)
                )
                : type;
        }

        function extractDefinitelyFalsyTypes(type: Type): Type {
            return mapType(type, getDefinitelyFalsyPartOfType);
        }

        function getDefinitelyFalsyPartOfType(type: Type): Type {
            return type.flags & TypeFlags.String
                ? emptyStringType
                : type.flags & TypeFlags.Number
                    ? zeroType
                    : type.flags & TypeFlags.BigInt
                        ? zeroBigIntType
                        : type === regularFalseType
                            || type === falseType
                            || type.flags
                            & (TypeFlags.Void | TypeFlags.Undefined
                                | TypeFlags.Null)
                            || type.flags & TypeFlags.StringLiteral
                            && (<StringLiteralType> type).value === ''
                            || type.flags & TypeFlags.NumberLiteral
                            && (<NumberLiteralType> type).value === 0
                            || type.flags & TypeFlags.BigIntLiteral
                            && isZeroBigInt(<BigIntLiteralType> type)
                            ? type
                            : neverType;
        }

        /**
         * Add undefined or null or both to a type if they are missing.
         * @param type - type to add undefined and/or null to if not present
         * @param flags - Either TypeFlags.Undefined or TypeFlags.Null, or both
         */
        function getNullableType(type: Type, flags: TypeFlags): Type {
            const missing = (flags & ~type.flags)
                & (TypeFlags.Undefined | TypeFlags.Null);
            return missing === 0
                ? type
                : missing === TypeFlags.Undefined
                    ? getUnionType([type, undefinedType])
                    : missing === TypeFlags.Null
                        ? getUnionType([type, nullType])
                        : getUnionType([type, undefinedType, nullType]);
        }

        function getOptionalType(type: Type): Type {
            Debug.assert(strictNullChecks);
            return type.flags & TypeFlags.Undefined
                ? type
                : getUnionType([type, undefinedType]);
        }

        function getGlobalNonNullableTypeInstantiation(type: Type) {
            if (!deferredGlobalNonNullableTypeAlias) {
                deferredGlobalNonNullableTypeAlias = getGlobalSymbol(
                    'NonNullable' as __String,
                    SymbolFlags.TypeAlias, /*diagnostic*/
                    undefined
                ) || unknownSymbol;
            }
            // Use NonNullable global type alias if available to improve quick info/declaration emit
            if (deferredGlobalNonNullableTypeAlias !== unknownSymbol) {
                return getTypeAliasInstantiation(
                    deferredGlobalNonNullableTypeAlias,
                    [type]
                );
            }
            return getTypeWithFacts(type,
                TypeFacts
                    .NEUndefinedOrNull); // Type alias unavailable, fall back to non-higher-order behavior
        }

        function getNonNullableType(type: Type): Type {
            return strictNullChecks
                ? getGlobalNonNullableTypeInstantiation(type)
                : type;
        }

        function addOptionalTypeMarker(type: Type) {
            return strictNullChecks
                ? getUnionType([type, optionalType])
                : type;
        }

        function isNotOptionalTypeMarker(type: Type) {
            return type !== optionalType;
        }

        function removeOptionalTypeMarker(type: Type): Type {
            return strictNullChecks
                ? filterType(type, isNotOptionalTypeMarker)
                : type;
        }

        function propagateOptionalTypeMarker(
            type: Type,
            node: OptionalChain,
            wasOptional: boolean
        ) {
            return wasOptional
                ? isOutermostOptionalChain(node)
                    ? getOptionalType(type)
                    : addOptionalTypeMarker(type)
                : type;
        }

        function getOptionalExpressionType(
            exprType: Type,
            expression: Expression
        ) {
            return isExpressionOfOptionalChainRoot(expression)
                ? getNonNullableType(exprType)
                : isOptionalChain(expression)
                    ? removeOptionalTypeMarker(exprType)
                    : exprType;
        }

        /**
         * Is source potentially coercible to target type under `==`.
         * Assumes that `source` is a constituent of a union, hence
         * the boolean literal flag on the LHS, but not on the RHS.
         *
         * This does not fully replicate the semantics of `==`. The
         * intention is to catch cases that are clearly not right.
         *
         * Comparing (string | number) to number should not remove the
         * string element.
         *
         * Comparing (string | number) to 1 will remove the string
         * element, though this is not sound. This is a pragmatic
         * choice.
         *
         * @see narrowTypeByEquality
         *
         * @param source
         * @param target
         */
        function isCoercibleUnderDoubleEquals(
            source: Type,
            target: Type
        ): boolean {
            return ((source.flags
                & (TypeFlags.Number | TypeFlags.String
                    | TypeFlags.BooleanLiteral)) !== 0)
                && ((target.flags
                    & (TypeFlags.Number | TypeFlags.String
                        | TypeFlags.Boolean)) !== 0);
        }

        /**
         * Return true if type was inferred from an object literal, written as an object type literal, or is the shape of a module
         * with no call or construct signatures.
         */
        function isObjectTypeWithInferableIndex(type: Type): boolean {
            return !!(type.symbol
                && (type.symbol.flags
                    & (SymbolFlags.ObjectLiteral | SymbolFlags.TypeLiteral
                        | SymbolFlags.Enum | SymbolFlags.ValueModule)) !== 0
                && !typeHasCallOrConstructSignatures(type))
                || !!(getObjectFlags(type) & ObjectFlags.ReverseMapped
                    && isObjectTypeWithInferableIndex(
                        (type as ReverseMappedType).source
                    ));
        }

        function createSymbolWithType(source: Symbol, type: Type | undefined) {
            const symbol = createSymbol(
                source.flags,
                source.escapedName,
                getCheckFlags(source) & CheckFlags.Readonly
            );
            symbol.declarations = source.declarations;
            symbol.parent = source.parent;
            symbol.type = type;
            symbol.target = source;
            if (source.valueDeclaration) {
                symbol.valueDeclaration = source.valueDeclaration;
            }
            if (source.nameType) {
                symbol.nameType = source.nameType;
            }
            return symbol;
        }

        function transformTypeOfMembers(
            type: Type,
            f: (propertyType: Type) => Type
        ) {
            const members = createSymbolTable();
            for (const property of getPropertiesOfObjectType(type)) {
                const original = getTypeOfSymbol(property);
                const updated = f(original);
                members.set(
                    property.escapedName,
                    updated === original
                        ? property
                        : createSymbolWithType(property, updated)
                );
            }
            return members;
        }

        /**
         * If the the provided object literal is subject to the excess properties check,
         * create a new that is exempt. Recursively mark object literal members as exempt.
         * Leave signatures alone since they are not subject to the check.
         */
        function getRegularTypeOfObjectLiteral(type: Type): Type {
            if (!(isObjectLiteralType(type)
                && getObjectFlags(type) & ObjectFlags.FreshLiteral))
            {
                return type;
            }
            const regularType = (<FreshObjectLiteralType> type).regularType;
            if (regularType) {
                return regularType;
            }

            const resolved = <ResolvedType> type;
            const members = transformTypeOfMembers(
                type,
                getRegularTypeOfObjectLiteral
            );
            const regularNew = createAnonymousType(
                resolved.symbol,
                members,
                resolved.callSignatures,
                resolved.constructSignatures,
                resolved.stringIndexInfo,
                resolved.numberIndexInfo
            );
            regularNew.flags = resolved.flags;
            regularNew
                .objectFlags |= resolved.objectFlags
                    & ~ObjectFlags.FreshLiteral;
            (<FreshObjectLiteralType> type).regularType = regularNew;
            return regularNew;
        }

        function createWideningContext(
            parent: WideningContext | undefined,
            propertyName: __String | undefined,
            siblings: Type[] | undefined
        ): WideningContext {
            return { parent, propertyName, siblings,
                resolvedProperties: undefined };
        }

        function getSiblingsOfContext(context: WideningContext): Type[] {
            if (!context.siblings) {
                const siblings: Type[] = [];
                for (const type of getSiblingsOfContext(context.parent!)) {
                    if (isObjectLiteralType(type)) {
                        const prop = getPropertyOfObjectType(
                            type,
                            context.propertyName!
                        );
                        if (prop) {
                            forEachType(
                                getTypeOfSymbol(prop),
                                t => {
                                    siblings.push(t);
                                }
                            );
                        }
                    }
                }
                context.siblings = siblings;
            }
            return context.siblings;
        }

        function getPropertiesOfContext(context: WideningContext): Symbol[] {
            if (!context.resolvedProperties) {
                const names = createMap<Symbol>() as UnderscoreEscapedMap<Symbol>;
                for (const t of getSiblingsOfContext(context)) {
                    if (isObjectLiteralType(t)
                        && !(getObjectFlags(t) & ObjectFlags.ContainsSpread))
                    {
                        for (const prop of getPropertiesOfType(t)) {
                            names.set(prop.escapedName, prop);
                        }
                    }
                }
                context.resolvedProperties = arrayFrom(names.values());
            }
            return context.resolvedProperties;
        }

        function getWidenedProperty(
            prop: Symbol,
            context: WideningContext | undefined
        ): Symbol {
            if (!(prop.flags & SymbolFlags.Property)) {
                // Since get accessors already widen their return value there is no need to
                // widen accessor based properties here.
                return prop;
            }
            const original = getTypeOfSymbol(prop);
            const propContext = context
                && createWideningContext(
                    context,
                    prop.escapedName, /*siblings*/
                    undefined
                );
            const widened = getWidenedTypeWithContext(original, propContext);
            return widened === original
                ? prop
                : createSymbolWithType(prop, widened);
        }

        function getUndefinedProperty(prop: Symbol) {
            const cached = undefinedProperties.get(prop.escapedName);
            if (cached) {
                return cached;
            }
            const result = createSymbolWithType(prop, undefinedType);
            result.flags |= SymbolFlags.Optional;
            undefinedProperties.set(prop.escapedName, result);
            return result;
        }

        function getWidenedTypeOfObjectLiteral(
            type: Type,
            context: WideningContext | undefined
        ): Type {
            const members = createSymbolTable();
            for (const prop of getPropertiesOfObjectType(type)) {
                members.set(
                    prop.escapedName,
                    getWidenedProperty(prop, context)
                );
            }
            if (context) {
                for (const prop of getPropertiesOfContext(context)) {
                    if (!members.has(prop.escapedName)) {
                        members.set(
                            prop.escapedName,
                            getUndefinedProperty(prop)
                        );
                    }
                }
            }
            const stringIndexInfo = getIndexInfoOfType(type, IndexKind.String);
            const numberIndexInfo = getIndexInfoOfType(type, IndexKind.Number);
            const result = createAnonymousType(
                type.symbol,
                members,
                emptyArray,
                emptyArray,
                stringIndexInfo && createIndexInfo(
                    getWidenedType(stringIndexInfo.type),
                    stringIndexInfo.isReadonly
                ),
                numberIndexInfo && createIndexInfo(
                    getWidenedType(numberIndexInfo.type),
                    numberIndexInfo.isReadonly
                )
            );
            result
                .objectFlags |= (getObjectFlags(type)
                    & (ObjectFlags.JSLiteral
                        | ObjectFlags
                            .NonInferrableType)); // Retain js literal flag through widening
            return result;
        }

        function getWidenedType(type: Type) {
            return getWidenedTypeWithContext(type, /*context*/ undefined);
        }

        function getWidenedTypeWithContext(
            type: Type,
            context: WideningContext | undefined
        ): Type {
            if (getObjectFlags(type) & ObjectFlags.RequiresWidening) {
                if (context === undefined && type.widened) {
                    return type.widened;
                }
                let result: Type | undefined;
                if (type.flags & (TypeFlags.Any | TypeFlags.Nullable)) {
                    result = anyType;
                } else if (isObjectLiteralType(type)) {
                    result = getWidenedTypeOfObjectLiteral(type, context);
                } else if (type.flags & TypeFlags.Union) {
                    const unionContext = context
                        || createWideningContext(
                            /*parent*/ undefined, /*propertyName*/
                            undefined,
                            (<UnionType> type).types
                        );
                    const widenedTypes = sameMap(
                        (<UnionType> type).types,
                        t => t.flags & TypeFlags.Nullable
                            ? t
                            : getWidenedTypeWithContext(t, unionContext)
                    );
                    // Widening an empty object literal transitions from a highly restrictive type to
                    // a highly inclusive one. For that reason we perform subtype reduction here if the
                    // union includes empty object types (e.g. reducing {} | string to just {}).
                    result = getUnionType(
                        widenedTypes,
                        some(widenedTypes, isEmptyObjectType)
                            ? UnionReduction.Subtype
                            : UnionReduction.Literal
                    );
                } else if (type.flags & TypeFlags.Intersection) {
                    result = getIntersectionType(
                        sameMap(
                            (<IntersectionType> type).types,
                            getWidenedType
                        )
                    );
                } else if (isArrayType(type) || isTupleType(type)) {
                    result = createTypeReference(
                        (<TypeReference> type).target,
                        sameMap(
                            getTypeArguments(<TypeReference> type),
                            getWidenedType
                        )
                    );
                }
                if (result && context === undefined) {
                    type.widened = result;
                }
                return result || type;
            }
            return type;
        }

        /**
         * Reports implicit any errors that occur as a result of widening 'null' and 'undefined'
         * to 'any'. A call to reportWideningErrorsInType is normally accompanied by a call to
         * getWidenedType. But in some cases getWidenedType is called without reporting errors
         * (type argument inference is an example).
         *
         * The return value indicates whether an error was in fact reported. The particular circumstances
         * are on a best effort basis. Currently, if the null or undefined that causes widening is inside
         * an object literal property (arbitrarily deeply), this function reports an error. If no error is
         * reported, reportImplicitAnyError is a suitable fallback to report a general error.
         */
        function reportWideningErrorsInType(type: Type): boolean {
            let errorReported = false;
            if (getObjectFlags(type) & ObjectFlags.ContainsWideningType) {
                if (type.flags & TypeFlags.Union) {
                    if (some((<UnionType> type).types, isEmptyObjectType)) {
                        errorReported = true;
                    } else {
                        for (const t of (<UnionType> type).types) {
                            if (reportWideningErrorsInType(t)) {
                                errorReported = true;
                            }
                        }
                    }
                }
                if (isArrayType(type) || isTupleType(type)) {
                    for (const t of getTypeArguments(<TypeReference> type)) {
                        if (reportWideningErrorsInType(t)) {
                            errorReported = true;
                        }
                    }
                }
                if (isObjectLiteralType(type)) {
                    for (const p of getPropertiesOfObjectType(type)) {
                        const t = getTypeOfSymbol(p);
                        if (getObjectFlags(t)
                            & ObjectFlags.ContainsWideningType)
                        {
                            if (!reportWideningErrorsInType(t)) {
                                error(
                                    p.valueDeclaration,
                                    Diagnostics
                                        .Object_literal_s_property_0_implicitly_has_an_1_type,
                                    symbolToString(p),
                                    typeToString(getWidenedType(t))
                                );
                            }
                            errorReported = true;
                        }
                    }
                }
            }
            return errorReported;
        }

        function reportImplicitAny(
            declaration: Declaration,
            type: Type,
            wideningKind?: WideningKind
        ) {
            const typeAsString = typeToString(getWidenedType(type));
            if (isInJSFile(declaration)
                && !isCheckJsEnabledForFile(
                    getSourceFileOfNode(declaration),
                    compilerOptions
                ))
            {
                // Only report implicit any errors/suggestions in TS and ts-check JS files
                return;
            }
            let diagnostic: DiagnosticMessage;
            switch (declaration.kind) {
                case SyntaxKind.BinaryExpression:
                case SyntaxKind.PropertyDeclaration:
                case SyntaxKind.PropertySignature:
                    diagnostic = noImplicitAny
                        ? Diagnostics.Member_0_implicitly_has_an_1_type
                        : Diagnostics
                            .Member_0_implicitly_has_an_1_type_but_a_better_type_may_be_inferred_from_usage;
                    break;
                case SyntaxKind.Parameter:
                    const param = declaration as ParameterDeclaration;
                    if (isIdentifier(param.name)
                        && (isCallSignatureDeclaration(param.parent)
                            || isMethodSignature(param.parent)
                            || isFunctionTypeNode(param.parent))
                        && param.parent.parameters.indexOf(param) > -1
                        && (resolveName(
                            param,
                            param.name.escapedText,
                            SymbolFlags.Type,
                            undefined,
                            param.name.escapedText, /*isUse*/
                            true
                        )
                            || param.name.originalKeywordKind
                            && isTypeNodeKind(param.name.originalKeywordKind)))
                    {
                        const newName = 'arg'
                            + param.parent.parameters.indexOf(param);
                        errorOrSuggestion(
                            noImplicitAny,
                            declaration,
                            Diagnostics
                                .Parameter_has_a_name_but_no_type_Did_you_mean_0_Colon_1,
                            newName,
                            declarationNameToString(param.name)
                        );
                        return;
                    }
                    diagnostic = (<ParameterDeclaration> declaration)
                        .dotDotDotToken
                        ? noImplicitAny
                            ? Diagnostics
                                .Rest_parameter_0_implicitly_has_an_any_type
                            : Diagnostics
                                .Rest_parameter_0_implicitly_has_an_any_type_but_a_better_type_may_be_inferred_from_usage
                        : noImplicitAny
                            ? Diagnostics.Parameter_0_implicitly_has_an_1_type
                            : Diagnostics
                                .Parameter_0_implicitly_has_an_1_type_but_a_better_type_may_be_inferred_from_usage;
                    break;
                case SyntaxKind.BindingElement:
                    diagnostic = Diagnostics
                        .Binding_element_0_implicitly_has_an_1_type;
                    if (!noImplicitAny) {
                        // Don't issue a suggestion for binding elements since the codefix doesn't yet support them.
                        return;
                    }
                    break;
                case SyntaxKind.JSDocFunctionType:
                    error(
                        declaration,
                        Diagnostics
                            .Function_type_which_lacks_return_type_annotation_implicitly_has_an_0_return_type,
                        typeAsString
                    );
                    return;
                case SyntaxKind.FunctionDeclaration:
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.MethodSignature:
                case SyntaxKind.GetAccessor:
                case SyntaxKind.SetAccessor:
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.ArrowFunction:
                    if (noImplicitAny
                        && !(declaration as NamedDeclaration).name)
                    {
                        if (wideningKind === WideningKind.GeneratorYield) {
                            error(
                                declaration,
                                Diagnostics
                                    .Generator_implicitly_has_yield_type_0_because_it_does_not_yield_any_values_Consider_supplying_a_return_type_annotation,
                                typeAsString
                            );
                        } else {
                            error(
                                declaration,
                                Diagnostics
                                    .Function_expression_which_lacks_return_type_annotation_implicitly_has_an_0_return_type,
                                typeAsString
                            );
                        }
                        return;
                    }
                    diagnostic = !noImplicitAny
                        ? Diagnostics
                            ._0_implicitly_has_an_1_return_type_but_a_better_type_may_be_inferred_from_usage
                        : wideningKind === WideningKind.GeneratorYield
                            ? Diagnostics
                                ._0_which_lacks_return_type_annotation_implicitly_has_an_1_yield_type
                            : Diagnostics
                                ._0_which_lacks_return_type_annotation_implicitly_has_an_1_return_type;
                    break;
                case SyntaxKind.MappedType:
                    if (noImplicitAny) {
                        error(
                            declaration,
                            Diagnostics
                                .Mapped_object_type_implicitly_has_an_any_template_type
                        );
                    }
                    return;
                default:
                    diagnostic = noImplicitAny
                        ? Diagnostics.Variable_0_implicitly_has_an_1_type
                        : Diagnostics
                            .Variable_0_implicitly_has_an_1_type_but_a_better_type_may_be_inferred_from_usage;
            }
            errorOrSuggestion(
                noImplicitAny,
                declaration,
                diagnostic,
                declarationNameToString(getNameOfDeclaration(declaration)),
                typeAsString
            );
        }

        function reportErrorsFromWidening(
            declaration: Declaration,
            type: Type,
            wideningKind?: WideningKind
        ) {
            if (produceDiagnostics && noImplicitAny
                && getObjectFlags(type) & ObjectFlags.ContainsWideningType)
            {
                // Report implicit any error within type if possible, otherwise report error on declaration
                if (!reportWideningErrorsInType(type)) {
                    reportImplicitAny(declaration, type, wideningKind);
                }
            }
        }

        function applyToParameterTypes(
            source: Signature,
            target: Signature,
            callback: (s: Type, t: Type) => void
        ) {
            const sourceCount = getParameterCount(source);
            const targetCount = getParameterCount(target);
            const sourceRestType = getEffectiveRestType(source);
            const targetRestType = getEffectiveRestType(target);
            const targetNonRestCount = targetRestType
                ? targetCount - 1
                : targetCount;
            const paramCount = sourceRestType
                ? targetNonRestCount
                : Math.min(sourceCount, targetNonRestCount);
            const sourceThisType = getThisTypeOfSignature(source);
            if (sourceThisType) {
                const targetThisType = getThisTypeOfSignature(target);
                if (targetThisType) {
                    callback(sourceThisType, targetThisType);
                }
            }
            for (let i = 0; i < paramCount; i++) {
                callback(
                    getTypeAtPosition(source, i),
                    getTypeAtPosition(target, i)
                );
            }
            if (targetRestType) {
                callback(
                    getRestTypeAtPosition(source, paramCount),
                    targetRestType
                );
            }
        }

        function applyToReturnTypes(
            source: Signature,
            target: Signature,
            callback: (s: Type, t: Type) => void
        ) {
            const sourceTypePredicate = getTypePredicateOfSignature(source);
            const targetTypePredicate = getTypePredicateOfSignature(target);
            if (sourceTypePredicate && targetTypePredicate
                && typePredicateKindsMatch(
                    sourceTypePredicate,
                    targetTypePredicate
                ) && sourceTypePredicate.type && targetTypePredicate.type)
            {
                callback(sourceTypePredicate.type, targetTypePredicate.type);
            } else {
                callback(
                    getReturnTypeOfSignature(source),
                    getReturnTypeOfSignature(target)
                );
            }
        }

        function createInferenceContext(
            typeParameters: readonly TypeParameter[],
            signature: Signature | undefined,
            flags: InferenceFlags,
            compareTypes?: TypeComparer
        ): InferenceContext {
            return createInferenceContextWorker(
                typeParameters.map(createInferenceInfo),
                signature,
                flags,
                compareTypes || compareTypesAssignable
            );
        }

        function cloneInferenceContext<T extends InferenceContext
            | undefined>(
            context: T,
            extraFlags: InferenceFlags = 0
        ): InferenceContext | T & undefined {
            return context
                && createInferenceContextWorker(
                    map(
                        context.inferences,
                        cloneInferenceInfo
                    ),
                    context.signature,
                    context.flags | extraFlags,
                    context.compareTypes
                );
        }

        function createInferenceContextWorker(
            inferences: InferenceInfo[],
            signature: Signature | undefined,
            flags: InferenceFlags,
            compareTypes: TypeComparer
        ): InferenceContext {
            const context: InferenceContext = {
                inferences,
                signature,
                flags,
                compareTypes,
                mapper: t => mapToInferredType(context, t, /*fix*/ true),
                nonFixingMapper: t => mapToInferredType(
                    context,
                    t, /*fix*/
                    false
                )
            };
            return context;
        }

        function mapToInferredType(
            context: InferenceContext,
            t: Type,
            fix: boolean
        ): Type {
            const inferences = context.inferences;
            for (let i = 0; i < inferences.length; i++) {
                const inference = inferences[i];
                if (t === inference.typeParameter) {
                    if (fix && !inference.isFixed) {
                        clearCachedInferences(inferences);
                        inference.isFixed = true;
                    }
                    return getInferredType(context, i);
                }
            }
            return t;
        }

        function clearCachedInferences(inferences: InferenceInfo[]) {
            for (const inference of inferences) {
                if (!inference.isFixed) {
                    inference.inferredType = undefined;
                }
            }
        }

        function createInferenceInfo(
            typeParameter: TypeParameter
        ): InferenceInfo {
            return {
                typeParameter,
                candidates: undefined,
                contraCandidates: undefined,
                inferredType: undefined,
                priority: undefined,
                topLevel: true,
                isFixed: false
            };
        }

        function cloneInferenceInfo(inference: InferenceInfo): InferenceInfo {
            return {
                typeParameter: inference.typeParameter,
                candidates: inference.candidates
                    && inference.candidates.slice(),
                contraCandidates: inference.contraCandidates
                    && inference.contraCandidates.slice(),
                inferredType: inference.inferredType,
                priority: inference.priority,
                topLevel: inference.topLevel,
                isFixed: inference.isFixed
            };
        }

        function cloneInferredPartOfContext(
            context: InferenceContext
        ): InferenceContext | undefined {
            const inferences = filter(
                context.inferences,
                hasInferenceCandidates
            );
            return inferences.length
                ? createInferenceContextWorker(
                    map(
                        inferences,
                        cloneInferenceInfo
                    ),
                    context.signature,
                    context.flags,
                    context.compareTypes
                )
                : undefined;
        }

        function getMapperFromContext<T extends InferenceContext
            | undefined>(context: T): TypeMapper | T & undefined
        {
            return context && context.mapper;
        }

        // Return true if the given type could possibly reference a type parameter for which
        // we perform type inference (i.e. a type parameter of a generic function). We cache
        // results for union and intersection types for performance reasons.
        function couldContainTypeVariables(type: Type): boolean {
            const objectFlags = getObjectFlags(type);
            return !!(type.flags & TypeFlags.Instantiable
                || objectFlags & ObjectFlags.Reference
                && ((<TypeReference> type).node
                    || forEach(
                        getTypeArguments(<TypeReference> type),
                        couldContainTypeVariables
                    ))
                || objectFlags & ObjectFlags.Anonymous && type.symbol
                && type.symbol.flags
                & (SymbolFlags.Function | SymbolFlags.Method
                    | SymbolFlags.Class | SymbolFlags.TypeLiteral
                    | SymbolFlags.ObjectLiteral) && type.symbol.declarations
                || objectFlags
                & (ObjectFlags.Mapped | ObjectFlags.ObjectRestType)
                || type.flags & TypeFlags.UnionOrIntersection
                && !(type.flags & TypeFlags.EnumLiteral)
                && couldUnionOrIntersectionContainTypeVariables(<UnionOrIntersectionType> type));
        }

        function couldUnionOrIntersectionContainTypeVariables(
            type: UnionOrIntersectionType
        ): boolean {
            if (type.couldContainTypeVariables === undefined) {
                type.couldContainTypeVariables = some(
                    type.types,
                    couldContainTypeVariables
                );
            }
            return type.couldContainTypeVariables;
        }

        function isTypeParameterAtTopLevel(
            type: Type,
            typeParameter: TypeParameter
        ): boolean {
            return !!(type === typeParameter
                || type.flags & TypeFlags.UnionOrIntersection
                && some(
                    (<UnionOrIntersectionType> type).types,
                    t => isTypeParameterAtTopLevel(t, typeParameter)
                )
                || type.flags & TypeFlags.Conditional && (
                    isTypeParameterAtTopLevel(
                        getTrueTypeFromConditionalType(<ConditionalType> type),
                        typeParameter
                    )
                    || isTypeParameterAtTopLevel(
                        getFalseTypeFromConditionalType(<ConditionalType> type),
                        typeParameter
                    )
                ));
        }

        /** Create an object with properties named in the string literal type. Every property has type `any` */
        function createEmptyObjectTypeFromStringLiteral(type: Type) {
            const members = createSymbolTable();
            forEachType(
                type,
                t => {
                    if (!(t.flags & TypeFlags.StringLiteral)) {
                        return;
                    }
                    const name = escapeLeadingUnderscores((t as StringLiteralType)
                        .value);
                    const literalProp = createSymbol(SymbolFlags.Property,
                        name);
                    literalProp.type = anyType;
                    if (t.symbol) {
                        literalProp.declarations = t.symbol.declarations;
                        literalProp.valueDeclaration = t.symbol
                            .valueDeclaration;
                    }
                    members.set(name, literalProp);
                }
            );
            const indexInfo = type.flags & TypeFlags.String
                ? createIndexInfo(emptyObjectType, /*isReadonly*/ false)
                : undefined;
            return createAnonymousType(
                undefined,
                members,
                emptyArray,
                emptyArray,
                indexInfo,
                undefined
            );
        }

        /**
         * Infer a suitable input type for a homomorphic mapped type { [P in keyof T]: X }. We construct
         * an object type with the same set of properties as the source type, where the type of each
         * property is computed by inferring from the source property type to X for the type
         * variable T[P] (i.e. we treat the type T[P] as the type variable we're inferring for).
         */
        function inferTypeForHomomorphicMappedType(
            source: Type,
            target: MappedType,
            constraint: IndexType
        ): Type | undefined {
            const key = source.id + ',' + target.id + ',' + constraint.id;
            if (reverseMappedCache.has(key)) {
                return reverseMappedCache.get(key);
            }
            reverseMappedCache.set(key, undefined);
            const type = createReverseMappedType(source, target, constraint);
            reverseMappedCache.set(key, type);
            return type;
        }

        // We consider a type to be partially inferable if it isn't marked non-inferable or if it is
        // an object literal type with at least one property of an inferable type. For example, an object
        // literal { a: 123, b: x => true } is marked non-inferable because it contains a context sensitive
        // arrow function, but is considered partially inferable because property 'a' has an inferable type.
        function isPartiallyInferableType(type: Type): boolean {
            return !(getObjectFlags(type) & ObjectFlags.NonInferrableType)
                || isObjectLiteralType(type)
                && some(
                    getPropertiesOfType(type),
                    prop => isPartiallyInferableType(getTypeOfSymbol(prop))
                );
        }

        function createReverseMappedType(
            source: Type,
            target: MappedType,
            constraint: IndexType
        ) {
            // We consider a source type reverse mappable if it has a string index signature or if
            // it has one or more properties and is of a partially inferable type.
            if (!(getIndexInfoOfType(source, IndexKind.String)
                || getPropertiesOfType(source).length !== 0
                && isPartiallyInferableType(source)))
            {
                return undefined;
            }
            // For arrays and tuples we infer new arrays and tuples where the reverse mapping has been
            // applied to the element type(s).
            if (isArrayType(source)) {
                return createArrayType(
                    inferReverseMappedType(
                        getTypeArguments(<TypeReference> source)[0],
                        target,
                        constraint
                    ),
                    isReadonlyArrayType(source)
                );
            }
            if (isTupleType(source)) {
                const elementTypes = map(
                    getTypeArguments(source),
                    t => inferReverseMappedType(t, target, constraint)
                );
                const minLength = getMappedTypeModifiers(target)
                    & MappedTypeModifiers.IncludeOptional
                    ? getTypeReferenceArity(source)
                        - (source.target.hasRestElement ? 1 : 0)
                    : source.target.minLength;
                return createTupleType(
                    elementTypes,
                    minLength,
                    source.target.hasRestElement,
                    source.target.readonly,
                    source.target.associatedNames
                );
            }
            // For all other object types we infer a new object type where the reverse mapping has been
            // applied to the type of each property.
            const reversed = createObjectType(
                ObjectFlags.ReverseMapped | ObjectFlags.Anonymous, /*symbol*/
                undefined
            ) as ReverseMappedType;
            reversed.source = source;
            reversed.mappedType = target;
            reversed.constraintType = constraint;
            return reversed;
        }

        function getTypeOfReverseMappedSymbol(symbol: ReverseMappedSymbol) {
            return inferReverseMappedType(
                symbol.propertyType,
                symbol.mappedType,
                symbol.constraintType
            );
        }

        function inferReverseMappedType(
            sourceType: Type,
            target: MappedType,
            constraint: IndexType
        ): Type {
            const typeParameter = <TypeParameter> getIndexedAccessType(
                constraint.type,
                getTypeParameterFromMappedType(target)
            );
            const templateType = getTemplateTypeFromMappedType(target);
            const inference = createInferenceInfo(typeParameter);
            inferTypes([inference], sourceType, templateType);
            return getTypeFromInference(inference) || unknownType;
        }

        function* getUnmatchedProperties(
            source: Type,
            target: Type,
            requireOptionalProperties: boolean,
            matchDiscriminantProperties: boolean
        ): IterableIterator<Symbol> {
            const properties = getPropertiesOfType(target);
            for (const targetProp of properties) {
                // TODO: remove this when we support static private identifier fields and find other solutions to get privateNamesAndStaticFields test to pass
                if (isStaticPrivateIdentifierProperty(targetProp)) {
                    continue;
                }
                if (requireOptionalProperties
                    || !(targetProp.flags & SymbolFlags.Optional
                        || getCheckFlags(targetProp) & CheckFlags.Partial))
                {
                    const sourceProp = getPropertyOfType(
                        source,
                        targetProp.escapedName
                    );
                    if (!sourceProp) {
                        yield targetProp;
                    } else if (matchDiscriminantProperties) {
                        const targetType = getTypeOfSymbol(targetProp);
                        if (targetType.flags & TypeFlags.Unit) {
                            const sourceType = getTypeOfSymbol(sourceProp);
                            if (!(sourceType.flags & TypeFlags.Any
                                || getRegularTypeOfLiteralType(sourceType)
                                === getRegularTypeOfLiteralType(targetType)))
                            {
                                yield targetProp;
                            }
                        }
                    }
                }
            }
        }

        function getUnmatchedProperty(
            source: Type,
            target: Type,
            requireOptionalProperties: boolean,
            matchDiscriminantProperties: boolean
        ): Symbol | undefined {
            const result = getUnmatchedProperties(
                source,
                target,
                requireOptionalProperties,
                matchDiscriminantProperties
            ).next();
            if (!result.done) return result.value;
        }

        function tupleTypesDefinitelyUnrelated(
            source: TupleTypeReference,
            target: TupleTypeReference
        ) {
            return target.target.minLength > source.target.minLength
                || !getRestTypeOfTupleType(target)
                && (!!getRestTypeOfTupleType(source)
                    || getLengthOfTupleType(target)
                    < getLengthOfTupleType(source));
        }

        function typesDefinitelyUnrelated(source: Type, target: Type) {
            // Two tuple types with incompatible arities are definitely unrelated.
            // Two object types that each have a property that is unmatched in the other are definitely unrelated.
            return isTupleType(source) && isTupleType(target)
                && tupleTypesDefinitelyUnrelated(source, target)
                || !!getUnmatchedProperty(
                    source,
                    target, /*requireOptionalProperties*/
                    false, /*matchDiscriminantProperties*/
                    true
                )
                && !!getUnmatchedProperty(
                    target,
                    source, /*requireOptionalProperties*/
                    false, /*matchDiscriminantProperties*/
                    true
                );
        }

        function getTypeFromInference(inference: InferenceInfo) {
            return inference.candidates
                ? getUnionType(inference.candidates, UnionReduction.Subtype)
                : inference.contraCandidates
                    ? getIntersectionType(inference.contraCandidates)
                    : undefined;
        }

        function inferTypes(
            inferences: InferenceInfo[],
            originalSource: Type,
            originalTarget: Type,
            priority: InferencePriority = 0,
            contravariant = false
        ) {
            let symbolStack: Symbol[];
            let visited: Map<number>;
            let bivariant = false;
            let propagationType: Type;
            let inferencePriority = InferencePriority.MaxValue;
            let allowComplexConstraintInference = true;
            inferFromTypes(originalSource, originalTarget);

            function inferFromTypes(source: Type, target: Type): void {
                if (!couldContainTypeVariables(target)) {
                    return;
                }
                if (source === wildcardType) {
                    // We are inferring from an 'any' type. We want to infer this type for every type parameter
                    // referenced in the target type, so we record it as the propagation type and infer from the
                    // target to itself. Then, as we find candidates we substitute the propagation type.
                    const savePropagationType = propagationType;
                    propagationType = source;
                    inferFromTypes(target, target);
                    propagationType = savePropagationType;
                    return;
                }
                if (source.aliasSymbol && source.aliasTypeArguments
                    && source.aliasSymbol === target.aliasSymbol)
                {
                    // Source and target are types originating in the same generic type alias declaration.
                    // Simply infer from source type arguments to target type arguments.
                    inferFromTypeArguments(
                        source.aliasTypeArguments,
                        target.aliasTypeArguments!,
                        getAliasVariances(source.aliasSymbol)
                    );
                    return;
                }
                if (source === target
                    && source.flags & TypeFlags.UnionOrIntersection)
                {
                    // When source and target are the same union or intersection type, just relate each constituent
                    // type to itself.
                    for (const t of (<UnionOrIntersectionType> source).types) {
                        inferFromTypes(t, t);
                    }
                    return;
                }
                if (target.flags & TypeFlags.Union) {
                    // First, infer between identically matching source and target constituents and remove the
                    // matching types.
                    const [tempSources,
                        tempTargets] = inferFromMatchingTypes(
                            source.flags & TypeFlags.Union
                                ? (<UnionType> source).types
                                : [source],
                            (<UnionType> target).types,
                            isTypeOrBaseIdenticalTo
                        );
                    // Next, infer between closely matching source and target constituents and remove
                    // the matching types. Types closely match when they are instantiations of the same
                    // object type or instantiations of the same type alias.
                    const [sources,
                        targets] = inferFromMatchingTypes(
                            tempSources,
                            tempTargets,
                            isTypeCloselyMatchedBy
                        );
                    if (targets.length === 0) {
                        return;
                    }
                    target = getUnionType(targets);
                    if (sources.length === 0) {
                        // All source constituents have been matched and there is nothing further to infer from.
                        // However, simply making no inferences is undesirable because it could ultimately mean
                        // inferring a type parameter constraint. Instead, make a lower priority inference from
                        // the full source to whatever remains in the target. For example, when inferring from
                        // string to 'string | T', make a lower priority inference of string for T.
                        inferWithPriority(
                            source,
                            target,
                            InferencePriority.NakedTypeVariable
                        );
                        return;
                    }
                    source = getUnionType(sources);
                } else if (target.flags & TypeFlags.Intersection
                    && some(
                        (<IntersectionType> target).types,
                        t => !!getInferenceInfoForType(t)
                            || (isGenericMappedType(t)
                                && !!getInferenceInfoForType(
                                    getHomomorphicTypeVariable(t) || neverType
                                ))
                    ))
                {
                    // We reduce intersection types only when they contain naked type parameters. For example, when
                    // inferring from 'string[] & { extra: any }' to 'string[] & T' we want to remove string[] and
                    // infer { extra: any } for T. But when inferring to 'string[] & Iterable<T>' we want to keep the
                    // string[] on the source side and infer string for T.
                    // Likewise, we consider a homomorphic mapped type constrainted to the target type parameter as similar to a "naked type variable"
                    // in such scenarios.
                    if (!(source.flags & TypeFlags.Union)) {
                        // Infer between identically matching source and target constituents and remove the matching types.
                        const [sources,
                            targets] = inferFromMatchingTypes(
                                source.flags & TypeFlags.Intersection
                                    ? (<IntersectionType> source).types
                                    : [source],
                                (<IntersectionType> target).types,
                                isTypeIdenticalTo
                            );
                        if (sources.length === 0 || targets.length === 0) {
                            return;
                        }
                        source = getIntersectionType(sources);
                        target = getIntersectionType(targets);
                    }
                } else if (target.flags
                    & (TypeFlags.IndexedAccess | TypeFlags.Substitution))
                {
                    target = getActualTypeVariable(target);
                }
                if (target.flags & TypeFlags.TypeVariable) {
                    // If target is a type parameter, make an inference, unless the source type contains
                    // the anyFunctionType (the wildcard type that's used to avoid contextually typing functions).
                    // Because the anyFunctionType is internal, it should not be exposed to the user by adding
                    // it as an inference candidate. Hopefully, a better candidate will come along that does
                    // not contain anyFunctionType when we come back to this argument for its second round
                    // of inference. Also, we exclude inferences for silentNeverType (which is used as a wildcard
                    // when constructing types from type parameters that had no inference candidates).
                    if (getObjectFlags(source) & ObjectFlags.NonInferrableType
                        || source === nonInferrableAnyType
                        || source === silentNeverType
                        || (priority & InferencePriority.ReturnType
                            && (source === autoType
                                || source === autoArrayType)))
                    {
                        return;
                    }
                    const inference = getInferenceInfoForType(target);
                    if (inference) {
                        if (!inference.isFixed) {
                            if (inference.priority === undefined
                                || priority < inference.priority)
                            {
                                inference.candidates = undefined;
                                inference.contraCandidates = undefined;
                                inference.topLevel = true;
                                inference.priority = priority;
                            }
                            if (priority === inference.priority) {
                                const candidate = propagationType || source;
                                // We make contravariant inferences only if we are in a pure contravariant position,
                                // i.e. only if we have not descended into a bivariant position.
                                if (contravariant && !bivariant) {
                                    if (!contains(
                                        inference.contraCandidates,
                                        candidate
                                    )) {
                                        inference
                                            .contraCandidates = append(
                                                inference.contraCandidates,
                                                candidate
                                            );
                                        clearCachedInferences(inferences);
                                    }
                                } else if (!contains(
                                    inference.candidates,
                                    candidate
                                )) {
                                    inference
                                        .candidates = append(
                                            inference.candidates,
                                            candidate
                                        );
                                    clearCachedInferences(inferences);
                                }
                            }
                            if (!(priority & InferencePriority.ReturnType)
                                && target.flags & TypeFlags.TypeParameter
                                && inference.topLevel
                                && !isTypeParameterAtTopLevel(
                                    originalTarget,
                                    <TypeParameter> target
                                ))
                            {
                                inference.topLevel = false;
                                clearCachedInferences(inferences);
                            }
                        }
                        inferencePriority = Math.min(
                            inferencePriority,
                            priority
                        );
                        return;
                    } else {
                        // Infer to the simplified version of an indexed access, if possible, to (hopefully) expose more bare type parameters to the inference engine
                        const simplified = getSimplifiedType(
                            target, /*writing*/
                            false
                        );
                        if (simplified !== target) {
                            invokeOnce(source, simplified, inferFromTypes);
                        } else if (target.flags & TypeFlags.IndexedAccess) {
                            const indexType = getSimplifiedType(
                                (target as IndexedAccessType)
                                    .indexType, /*writing*/
                                false
                            );
                            // Generally simplifications of instantiable indexes are avoided to keep relationship checking correct, however if our target is an access, we can consider
                            // that key of that access to be "instantiated", since we're looking to find the infernce goal in any way we can.
                            if (indexType.flags & TypeFlags.Instantiable) {
                                const simplified = distributeIndexOverObjectType(
                                    getSimplifiedType(
                                        (target as IndexedAccessType)
                                            .objectType, /*writing*/
                                        false
                                    ),
                                    indexType, /*writing*/
                                    false
                                );
                                if (simplified && simplified !== target) {
                                    invokeOnce(
                                        source,
                                        simplified,
                                        inferFromTypes
                                    );
                                }
                            }
                        }
                    }
                }
                if (getObjectFlags(source) & ObjectFlags.Reference
                    && getObjectFlags(target) & ObjectFlags.Reference && (
                        (<TypeReference> source).target
                        === (<TypeReference> target).target
                        || isArrayType(source) && isArrayType(target)
                    )
                    && !((<TypeReference> source).node
                        && (<TypeReference> target).node))
                {
                    // If source and target are references to the same generic type, infer from type arguments
                    inferFromTypeArguments(
                        getTypeArguments(<TypeReference> source),
                        getTypeArguments(<TypeReference> target),
                        getVariances((<TypeReference> source).target)
                    );
                } else if (source.flags & TypeFlags.Index
                    && target.flags & TypeFlags.Index)
                {
                    contravariant = !contravariant;
                    inferFromTypes(
                        (<IndexType> source).type,
                        (<IndexType> target).type
                    );
                    contravariant = !contravariant;
                } else if ((isLiteralType(source)
                    || source.flags & TypeFlags.String)
                    && target.flags & TypeFlags.Index)
                {
                    const empty = createEmptyObjectTypeFromStringLiteral(source);
                    contravariant = !contravariant;
                    inferWithPriority(
                        empty,
                        (target as IndexType).type,
                        InferencePriority.LiteralKeyof
                    );
                    contravariant = !contravariant;
                } else if (source.flags & TypeFlags.IndexedAccess
                    && target.flags & TypeFlags.IndexedAccess)
                {
                    inferFromTypes(
                        (<IndexedAccessType> source).objectType,
                        (<IndexedAccessType> target).objectType
                    );
                    inferFromTypes(
                        (<IndexedAccessType> source).indexType,
                        (<IndexedAccessType> target).indexType
                    );
                } else if (source.flags & TypeFlags.Conditional
                    && target.flags & TypeFlags.Conditional)
                {
                    inferFromTypes(
                        (<ConditionalType> source).checkType,
                        (<ConditionalType> target).checkType
                    );
                    inferFromTypes(
                        (<ConditionalType> source).extendsType,
                        (<ConditionalType> target).extendsType
                    );
                    inferFromTypes(
                        getTrueTypeFromConditionalType(<ConditionalType> source),
                        getTrueTypeFromConditionalType(<ConditionalType> target)
                    );
                    inferFromTypes(
                        getFalseTypeFromConditionalType(<ConditionalType> source),
                        getFalseTypeFromConditionalType(<ConditionalType> target)
                    );
                } else if (target.flags & TypeFlags.Conditional) {
                    const savePriority = priority;
                    priority |= contravariant
                        ? InferencePriority.ContravariantConditional
                        : 0;
                    const targetTypes = [getTrueTypeFromConditionalType(<ConditionalType> target),
                        getFalseTypeFromConditionalType(<ConditionalType> target)];
                    inferToMultipleTypes(source, targetTypes, target.flags);
                    priority = savePriority;
                } else if (target.flags & TypeFlags.UnionOrIntersection) {
                    inferToMultipleTypes(
                        source,
                        (<UnionOrIntersectionType> target).types,
                        target.flags
                    );
                } else if (source.flags & TypeFlags.Union) {
                    // Source is a union or intersection type, infer from each constituent type
                    const sourceTypes = (<UnionOrIntersectionType> source)
                        .types;
                    for (const sourceType of sourceTypes) {
                        inferFromTypes(sourceType, target);
                    }
                } else {
                    if (!(priority & InferencePriority.NoConstraints
                        && source.flags
                        & (TypeFlags.Intersection | TypeFlags.Instantiable)))
                    {
                        const apparentSource = getApparentType(source);
                        // getApparentType can return _any_ type, since an indexed access or conditional may simplify to any other type.
                        // If that occurs and it doesn't simplify to an object or intersection, we'll need to restart `inferFromTypes`
                        // with the simplified source.
                        if (apparentSource !== source
                            && allowComplexConstraintInference
                            && !(apparentSource.flags
                                & (TypeFlags.Object | TypeFlags.Intersection)))
                        {
                            // TODO: The `allowComplexConstraintInference` flag is a hack! This forbids inference from complex constraints within constraints!
                            // This isn't required algorithmically, but rather is used to lower the memory burden caused by performing inference
                            // that is _too good_ in projects with complicated constraints (eg, fp-ts). In such cases, if we did not limit ourselves
                            // here, we might produce more valid inferences for types, causing us to do more checks and perform more instantiations
                            // (in addition to the extra stack depth here) which, in turn, can push the already close process over its limit.
                            // TL;DR: If we ever become generally more memory efficient (or our resource budget ever increases), we should just
                            // remove this `allowComplexConstraintInference` flag.
                            allowComplexConstraintInference = false;
                            return inferFromTypes(apparentSource, target);
                        }
                        source = apparentSource;
                    }
                    if (source.flags
                        & (TypeFlags.Object | TypeFlags.Intersection))
                    {
                        invokeOnce(source, target, inferFromObjectTypes);
                    }
                }
            }

            function inferWithPriority(
                source: Type,
                target: Type,
                newPriority: InferencePriority
            ) {
                const savePriority = priority;
                priority |= newPriority;
                inferFromTypes(source, target);
                priority = savePriority;
            }

            function invokeOnce(
                source: Type,
                target: Type,
                action: (source: Type, target: Type) => void
            ) {
                const key = source.id + ',' + target.id;
                const status = visited && visited.get(key);
                if (status !== undefined) {
                    inferencePriority = Math.min(inferencePriority, status);
                    return;
                }
                (visited || (visited = createMap<number>())).set(
                    key,
                    InferencePriority.Circularity
                );
                const saveInferencePriority = inferencePriority;
                inferencePriority = InferencePriority.MaxValue;
                action(source, target);
                visited.set(key, inferencePriority);
                inferencePriority = Math.min(
                    inferencePriority,
                    saveInferencePriority
                );
            }

            function inferFromMatchingTypes(
                sources: Type[],
                targets: Type[],
                matches: (s: Type, t: Type) => boolean
            ): [Type[], Type[]] {
                let matchedSources: Type[] | undefined;
                let matchedTargets: Type[] | undefined;
                for (const t of targets) {
                    for (const s of sources) {
                        if (matches(s, t)) {
                            inferFromTypes(s, t);
                            matchedSources = appendIfUnique(matchedSources, s);
                            matchedTargets = appendIfUnique(matchedTargets, t);
                        }
                    }
                }
                return [
                    matchedSources
                        ? filter(sources, t => !contains(matchedSources, t))
                        : sources,
                    matchedTargets
                        ? filter(targets, t => !contains(matchedTargets, t))
                        : targets
                ];
            }

            function inferFromTypeArguments(
                sourceTypes: readonly Type[],
                targetTypes: readonly Type[],
                variances: readonly VarianceFlags[]
            ) {
                const count = sourceTypes.length < targetTypes.length
                    ? sourceTypes.length
                    : targetTypes.length;
                for (let i = 0; i < count; i++) {
                    if (i < variances.length
                        && (variances[i] & VarianceFlags.VarianceMask)
                        === VarianceFlags.Contravariant)
                    {
                        inferFromContravariantTypes(
                            sourceTypes[i],
                            targetTypes[i]
                        );
                    } else {
                        inferFromTypes(sourceTypes[i], targetTypes[i]);
                    }
                }
            }

            function inferFromContravariantTypes(source: Type, target: Type) {
                if (strictFunctionTypes
                    || priority & InferencePriority.AlwaysStrict)
                {
                    contravariant = !contravariant;
                    inferFromTypes(source, target);
                    contravariant = !contravariant;
                } else {
                    inferFromTypes(source, target);
                }
            }

            function getInferenceInfoForType(type: Type) {
                if (type.flags & TypeFlags.TypeVariable) {
                    for (const inference of inferences) {
                        if (type === inference.typeParameter) {
                            return inference;
                        }
                    }
                }
                return undefined;
            }

            function getSingleTypeVariableFromIntersectionTypes(types:
                Type[])
            {
                let typeVariable: Type | undefined;
                for (const type of types) {
                    const t = type.flags & TypeFlags.Intersection
                        && find(
                            (<IntersectionType> type).types,
                            t => !!getInferenceInfoForType(t)
                        );
                    if (!t || typeVariable && t !== typeVariable) {
                        return undefined;
                    }
                    typeVariable = t;
                }
                return typeVariable;
            }

            function inferToMultipleTypes(
                source: Type,
                targets: Type[],
                targetFlags: TypeFlags
            ) {
                let typeVariableCount = 0;
                if (targetFlags & TypeFlags.Union) {
                    let nakedTypeVariable: Type | undefined;
                    const sources = source.flags & TypeFlags.Union
                        ? (<UnionType> source).types
                        : [source];
                    const matched = new Array<boolean>(sources.length);
                    let inferenceCircularity = false;
                    // First infer to types that are not naked type variables. For each source type we
                    // track whether inferences were made from that particular type to some target with
                    // equal priority (i.e. of equal quality) to what we would infer for a naked type
                    // parameter.
                    for (const t of targets) {
                        if (getInferenceInfoForType(t)) {
                            nakedTypeVariable = t;
                            typeVariableCount++;
                        } else {
                            for (let i = 0; i < sources.length; i++) {
                                const saveInferencePriority = inferencePriority;
                                inferencePriority = InferencePriority.MaxValue;
                                inferFromTypes(sources[i], t);
                                if (inferencePriority === priority) {
                                    matched[i] = true;
                                }
                                inferenceCircularity = inferenceCircularity
                                    || inferencePriority
                                    === InferencePriority.Circularity;
                                inferencePriority = Math.min(
                                    inferencePriority,
                                    saveInferencePriority
                                );
                            }
                        }
                    }
                    if (typeVariableCount === 0) {
                        // If every target is an intersection of types containing a single naked type variable,
                        // make a lower priority inference to that type variable. This handles inferring from
                        // 'A | B' to 'T & (X | Y)' where we want to infer 'A | B' for T.
                        const intersectionTypeVariable = getSingleTypeVariableFromIntersectionTypes(targets);
                        if (intersectionTypeVariable) {
                            inferWithPriority(
                                source,
                                intersectionTypeVariable,
                                InferencePriority.NakedTypeVariable
                            );
                        }
                        return;
                    }
                    // If the target has a single naked type variable and no inference circularities were
                    // encountered above (meaning we explored the types fully), create a union of the source
                    // types from which no inferences have been made so far and infer from that union to the
                    // naked type variable.
                    if (typeVariableCount === 1 && !inferenceCircularity) {
                        const unmatched = flatMap(
                            sources,
                            (s, i) => matched[i] ? undefined : s
                        );
                        if (unmatched.length) {
                            inferFromTypes(
                                getUnionType(unmatched),
                                nakedTypeVariable!
                            );
                            return;
                        }
                    }
                } else {
                    // We infer from types that are not naked type variables first so that inferences we
                    // make from nested naked type variables and given slightly higher priority by virtue
                    // of being first in the candidates array.
                    for (const t of targets) {
                        if (getInferenceInfoForType(t)) {
                            typeVariableCount++;
                        } else {
                            inferFromTypes(source, t);
                        }
                    }
                }
                // Inferences directly to naked type variables are given lower priority as they are
                // less specific. For example, when inferring from Promise<string> to T | Promise<T>,
                // we want to infer string for T, not Promise<string> | string. For intersection types
                // we only infer to single naked type variables.
                if (targetFlags & TypeFlags.Intersection
                    ? typeVariableCount === 1
                    : typeVariableCount > 0)
                {
                    for (const t of targets) {
                        if (getInferenceInfoForType(t)) {
                            inferWithPriority(
                                source,
                                t,
                                InferencePriority.NakedTypeVariable
                            );
                        }
                    }
                }
            }

            function inferToMappedType(
                source: Type,
                target: MappedType,
                constraintType: Type
            ): boolean {
                if (constraintType.flags & TypeFlags.Union) {
                    let result = false;
                    for (const type of (constraintType as UnionType).types) {
                        result = inferToMappedType(source, target, type)
                            || result;
                    }
                    return result;
                }
                if (constraintType.flags & TypeFlags.Index) {
                    // We're inferring from some source type S to a homomorphic mapped type { [P in keyof T]: X },
                    // where T is a type variable. Use inferTypeForHomomorphicMappedType to infer a suitable source
                    // type and then make a secondary inference from that type to T. We make a secondary inference
                    // such that direct inferences to T get priority over inferences to Partial<T>, for example.
                    const inference = getInferenceInfoForType(
                        (<IndexType> constraintType).type
                    );
                    if (inference && !inference.isFixed) {
                        const inferredType = inferTypeForHomomorphicMappedType(
                            source,
                            target,
                            <IndexType> constraintType
                        );
                        if (inferredType) {
                            // We assign a lower priority to inferences made from types containing non-inferrable
                            // types because we may only have a partial result (i.e. we may have failed to make
                            // reverse inferences for some properties).
                            inferWithPriority(
                                inferredType,
                                inference.typeParameter,
                                getObjectFlags(source)
                                    & ObjectFlags.NonInferrableType
                                    ? InferencePriority
                                        .PartialHomomorphicMappedType
                                    : InferencePriority.HomomorphicMappedType
                            );
                        }
                    }
                    return true;
                }
                if (constraintType.flags & TypeFlags.TypeParameter) {
                    // We're inferring from some source type S to a mapped type { [P in K]: X }, where K is a type
                    // parameter. First infer from 'keyof S' to K.
                    inferWithPriority(
                        getIndexType(source),
                        constraintType,
                        InferencePriority.MappedTypeConstraint
                    );
                    // If K is constrained to a type C, also infer to C. Thus, for a mapped type { [P in K]: X },
                    // where K extends keyof T, we make the same inferences as for a homomorphic mapped type
                    // { [P in keyof T]: X }. This enables us to make meaningful inferences when the target is a
                    // Pick<T, K>.
                    const extendedConstraint = getConstraintOfType(constraintType);
                    if (extendedConstraint
                        && inferToMappedType(
                            source,
                            target,
                            extendedConstraint
                        ))
                    {
                        return true;
                    }
                    // If no inferences can be made to K's constraint, infer from a union of the property types
                    // in the source to the template type X.
                    const propTypes = map(
                        getPropertiesOfType(source),
                        getTypeOfSymbol
                    );
                    const stringIndexType = getIndexTypeOfType(
                        source,
                        IndexKind.String
                    );
                    const numberIndexInfo = getNonEnumNumberIndexInfo(source);
                    const numberIndexType = numberIndexInfo
                        && numberIndexInfo.type;
                    inferFromTypes(
                        getUnionType(
                            append(
                                append(
                                    propTypes,
                                    stringIndexType
                                ),
                                numberIndexType
                            )
                        ),
                        getTemplateTypeFromMappedType(target)
                    );
                    return true;
                }
                return false;
            }

            function inferFromObjectTypes(source: Type, target: Type) {
                // If we are already processing another target type with the same associated symbol (such as
                // an instantiation of the same generic type), we do not explore this target as it would yield
                // no further inferences. We exclude the static side of classes from this check since it shares
                // its symbol with the instance side which would lead to false positives.
                const isNonConstructorObject = target.flags & TypeFlags.Object
                    && !(getObjectFlags(target) & ObjectFlags.Anonymous
                        && target.symbol
                        && target.symbol.flags & SymbolFlags.Class);
                const symbol = isNonConstructorObject
                    ? target.symbol
                    : undefined;
                if (symbol) {
                    if (contains(symbolStack, symbol)) {
                        inferencePriority = InferencePriority.Circularity;
                        return;
                    }
                    (symbolStack || (symbolStack = [])).push(symbol);
                    inferFromObjectTypesWorker(source, target);
                    symbolStack.pop();
                } else {
                    inferFromObjectTypesWorker(source, target);
                }
            }

            function inferFromObjectTypesWorker(source: Type, target: Type) {
                if (getObjectFlags(source) & ObjectFlags.Reference
                    && getObjectFlags(target) & ObjectFlags.Reference && (
                        (<TypeReference> source).target
                        === (<TypeReference> target).target
                        || isArrayType(source) && isArrayType(target)
                    ))
                {
                    // If source and target are references to the same generic type, infer from type arguments
                    inferFromTypeArguments(
                        getTypeArguments(<TypeReference> source),
                        getTypeArguments(<TypeReference> target),
                        getVariances((<TypeReference> source).target)
                    );
                    return;
                }
                if (isGenericMappedType(source)
                    && isGenericMappedType(target))
                {
                    // The source and target types are generic types { [P in S]: X } and { [P in T]: Y }, so we infer
                    // from S to T and from X to Y.
                    inferFromTypes(
                        getConstraintTypeFromMappedType(source),
                        getConstraintTypeFromMappedType(target)
                    );
                    inferFromTypes(
                        getTemplateTypeFromMappedType(source),
                        getTemplateTypeFromMappedType(target)
                    );
                }
                if (getObjectFlags(target) & ObjectFlags.Mapped) {
                    const constraintType = getConstraintTypeFromMappedType(<MappedType> target);
                    if (inferToMappedType(
                        source,
                        <MappedType> target,
                        constraintType
                    )) {
                        return;
                    }
                }
                // Infer from the members of source and target only if the two types are possibly related
                if (!typesDefinitelyUnrelated(source, target)) {
                    inferFromProperties(source, target);
                    inferFromSignatures(source, target, SignatureKind.Call);
                    inferFromSignatures(
                        source,
                        target,
                        SignatureKind.Construct
                    );
                    inferFromIndexTypes(source, target);
                }
            }

            function inferFromProperties(source: Type, target: Type) {
                if (isArrayType(source) || isTupleType(source)) {
                    if (isTupleType(target)) {
                        const sourceLength = isTupleType(source)
                            ? getLengthOfTupleType(source)
                            : 0;
                        const targetLength = getLengthOfTupleType(target);
                        const sourceRestType = isTupleType(source)
                            ? getRestTypeOfTupleType(source)
                            : getElementTypeOfArrayType(source);
                        const targetRestType = getRestTypeOfTupleType(target);
                        const fixedLength = targetLength < sourceLength
                            || sourceRestType
                            ? targetLength
                            : sourceLength;
                        for (let i = 0; i < fixedLength; i++) {
                            inferFromTypes(
                                i < sourceLength
                                    ? getTypeArguments(<TypeReference> source)
                                        [i]
                                    : sourceRestType!,
                                getTypeArguments(target)[i]
                            );
                        }
                        if (targetRestType) {
                            const types = fixedLength < sourceLength
                                ? getTypeArguments(<TypeReference> source)
                                    .slice(fixedLength, sourceLength)
                                : [];
                            if (sourceRestType) {
                                types.push(sourceRestType);
                            }
                            if (types.length) {
                                inferFromTypes(
                                    getUnionType(types),
                                    targetRestType
                                );
                            }
                        }
                        return;
                    }
                    if (isArrayType(target)) {
                        inferFromIndexTypes(source, target);
                        return;
                    }
                }
                const properties = getPropertiesOfObjectType(target);
                for (const targetProp of properties) {
                    const sourceProp = getPropertyOfType(
                        source,
                        targetProp.escapedName
                    );
                    if (sourceProp) {
                        inferFromTypes(
                            getTypeOfSymbol(sourceProp),
                            getTypeOfSymbol(targetProp)
                        );
                    }
                }
            }

            function inferFromSignatures(
                source: Type,
                target: Type,
                kind: SignatureKind
            ) {
                const sourceSignatures = getSignaturesOfType(source, kind);
                const targetSignatures = getSignaturesOfType(target, kind);
                const sourceLen = sourceSignatures.length;
                const targetLen = targetSignatures.length;
                const len = sourceLen < targetLen ? sourceLen : targetLen;
                const skipParameters = !!(getObjectFlags(source)
                    & ObjectFlags.NonInferrableType);
                for (let i = 0; i < len; i++) {
                    inferFromSignature(
                        getBaseSignature(
                            sourceSignatures[sourceLen - len + i]
                        ),
                        getBaseSignature(targetSignatures[targetLen - len
                            + i]),
                        skipParameters
                    );
                }
            }

            function inferFromSignature(
                source: Signature,
                target: Signature,
                skipParameters: boolean
            ) {
                if (!skipParameters) {
                    const saveBivariant = bivariant;
                    const kind = target.declaration
                        ? target.declaration.kind
                        : SyntaxKind.Unknown;
                    // Once we descend into a bivariant signature we remain bivariant for all nested inferences
                    bivariant = bivariant
                        || kind === SyntaxKind.MethodDeclaration
                        || kind === SyntaxKind.MethodSignature
                        || kind === SyntaxKind.Constructor;
                    applyToParameterTypes(
                        source,
                        target,
                        inferFromContravariantTypes
                    );
                    bivariant = saveBivariant;
                }
                applyToReturnTypes(source, target, inferFromTypes);
            }

            function inferFromIndexTypes(source: Type, target: Type) {
                const targetStringIndexType = getIndexTypeOfType(
                    target,
                    IndexKind.String
                );
                if (targetStringIndexType) {
                    const sourceIndexType = getIndexTypeOfType(
                        source,
                        IndexKind.String
                    )
                        || getImplicitIndexTypeOfType(source,
                            IndexKind.String);
                    if (sourceIndexType) {
                        inferFromTypes(sourceIndexType, targetStringIndexType);
                    }
                }
                const targetNumberIndexType = getIndexTypeOfType(
                    target,
                    IndexKind.Number
                );
                if (targetNumberIndexType) {
                    const sourceIndexType = getIndexTypeOfType(
                        source,
                        IndexKind.Number
                    )
                        || getIndexTypeOfType(source, IndexKind.String)
                        || getImplicitIndexTypeOfType(source,
                            IndexKind.Number);
                    if (sourceIndexType) {
                        inferFromTypes(sourceIndexType, targetNumberIndexType);
                    }
                }
            }
        }

        function isTypeOrBaseIdenticalTo(s: Type, t: Type) {
            return isTypeIdenticalTo(s, t)
                || !!(s.flags
                    & (TypeFlags.StringLiteral | TypeFlags.NumberLiteral))
                && isTypeIdenticalTo(getBaseTypeOfLiteralType(s), t);
        }

        function isTypeCloselyMatchedBy(s: Type, t: Type) {
            return !!(s.flags & TypeFlags.Object && t.flags & TypeFlags.Object
                && s.symbol && s.symbol === t.symbol
                || s.aliasSymbol && s.aliasTypeArguments
                && s.aliasSymbol === t.aliasSymbol);
        }

        function hasPrimitiveConstraint(type: TypeParameter): boolean {
            const constraint = getConstraintOfTypeParameter(type);
            return !!constraint
                && maybeTypeOfKind(
                    constraint.flags & TypeFlags.Conditional
                        ? getDefaultConstraintOfConditionalType(constraint as ConditionalType)
                        : constraint,
                    TypeFlags.Primitive | TypeFlags.Index
                );
        }

        function isObjectLiteralType(type: Type) {
            return !!(getObjectFlags(type) & ObjectFlags.ObjectLiteral);
        }

        function isObjectOrArrayLiteralType(type: Type) {
            return !!(getObjectFlags(type)
                & (ObjectFlags.ObjectLiteral | ObjectFlags.ArrayLiteral));
        }

        function unionObjectAndArrayLiteralCandidates(
            candidates: Type[]
        ): Type[] {
            if (candidates.length > 1) {
                const objectLiterals = filter(
                    candidates,
                    isObjectOrArrayLiteralType
                );
                if (objectLiterals.length) {
                    const literalsType = getUnionType(
                        objectLiterals,
                        UnionReduction.Subtype
                    );
                    return concatenate(
                        filter(
                            candidates,
                            t => !isObjectOrArrayLiteralType(t)
                        ),
                        [literalsType]
                    );
                }
            }
            return candidates;
        }

        function getContravariantInference(inference: InferenceInfo) {
            return inference.priority!
                & InferencePriority.PriorityImpliesCombination
                ? getIntersectionType(inference.contraCandidates!)
                : getCommonSubtype(inference.contraCandidates!);
        }

        function getCovariantInference(
            inference: InferenceInfo,
            signature: Signature
        ) {
            // Extract all object and array literal types and replace them with a single widened and normalized type.
            const candidates = unionObjectAndArrayLiteralCandidates(
                inference.candidates!
            );
            // We widen inferred literal types if
            // all inferences were made to top-level occurrences of the type parameter, and
            // the type parameter has no constraint or its constraint includes no primitive or literal types, and
            // the type parameter was fixed during inference or does not occur at top-level in the return type.
            const primitiveConstraint = hasPrimitiveConstraint(
                inference.typeParameter
            );
            const widenLiteralTypes = !primitiveConstraint
                && inference.topLevel
                && (inference.isFixed
                    || !isTypeParameterAtTopLevel(
                        getReturnTypeOfSignature(signature),
                        inference.typeParameter
                    ));
            const baseCandidates = primitiveConstraint
                ? sameMap(candidates, getRegularTypeOfLiteralType)
                : widenLiteralTypes
                    ? sameMap(candidates, getWidenedLiteralType)
                    : candidates;
            // If all inferences were made from a position that implies a combined result, infer a union type.
            // Otherwise, infer a common supertype.
            const unwidenedType = inference.priority!
                & InferencePriority.PriorityImpliesCombination
                ? getUnionType(baseCandidates, UnionReduction.Subtype)
                : getCommonSupertype(baseCandidates);
            return getWidenedType(unwidenedType);
        }

        function getInferredType(
            context: InferenceContext,
            index: number
        ): Type {
            const inference = context.inferences[index];
            if (!inference.inferredType) {
                let inferredType: Type | undefined;
                const signature = context.signature;
                if (signature) {
                    const inferredCovariantType = inference.candidates
                        ? getCovariantInference(inference, signature)
                        : undefined;
                    if (inference.contraCandidates) {
                        const inferredContravariantType = getContravariantInference(inference);
                        // If we have both co- and contra-variant inferences, we prefer the contra-variant inference
                        // unless the co-variant inference is a subtype and not 'never'.
                        inferredType = inferredCovariantType
                            && !(inferredCovariantType.flags & TypeFlags.Never)
                            && isTypeSubtypeOf(
                                inferredCovariantType,
                                inferredContravariantType
                            )
                            ? inferredCovariantType
                            : inferredContravariantType;
                    } else if (inferredCovariantType) {
                        inferredType = inferredCovariantType;
                    } else if (context.flags & InferenceFlags.NoDefault) {
                        // We use silentNeverType as the wildcard that signals no inferences.
                        inferredType = silentNeverType;
                    } else {
                        // Infer either the default or the empty object type when no inferences were
                        // made. It is important to remember that in this case, inference still
                        // succeeds, meaning there is no error for not having inference candidates. An
                        // inference error only occurs when there are *conflicting* candidates, i.e.
                        // candidates with no common supertype.
                        const defaultType = getDefaultFromTypeParameter(
                            inference.typeParameter
                        );
                        if (defaultType) {
                            // Instantiate the default type. Any forward reference to a type
                            // parameter should be instantiated to the empty object type.
                            inferredType = instantiateType(
                                defaultType,
                                combineTypeMappers(
                                    createBackreferenceMapper(
                                        context,
                                        index
                                    ),
                                    context.nonFixingMapper
                                )
                            );
                        }
                    }
                } else {
                    inferredType = getTypeFromInference(inference);
                }

                inference.inferredType = inferredType
                    || getDefaultTypeArgumentType(
                        !!(context.flags & InferenceFlags.AnyDefault)
                    );

                const constraint = getConstraintOfTypeParameter(
                    inference.typeParameter
                );
                if (constraint) {
                    const instantiatedConstraint = instantiateType(
                        constraint,
                        context.nonFixingMapper
                    );
                    if (!inferredType
                        || !context.compareTypes(
                            inferredType,
                            getTypeWithThisArgument(
                                instantiatedConstraint,
                                inferredType
                            )
                        ))
                    {
                        inference
                            .inferredType = inferredType = instantiatedConstraint;
                    }
                }
            }

            return inference.inferredType;
        }

        function getDefaultTypeArgumentType(isInJavaScriptFile:
            boolean): Type
        {
            return isInJavaScriptFile ? anyType : unknownType;
        }

        function getInferredTypes(context: InferenceContext): Type[] {
            const result: Type[] = [];
            for (let i = 0; i < context.inferences.length; i++) {
                result.push(getInferredType(context, i));
            }
            return result;
        }

        // EXPRESSION TYPE CHECKING

        function getCannotFindNameDiagnosticForName(
            node: Identifier
        ): DiagnosticMessage {
            switch (node.escapedText) {
                case 'document':
                case 'console':
                    return Diagnostics
                        .Cannot_find_name_0_Do_you_need_to_change_your_target_library_Try_changing_the_lib_compiler_option_to_include_dom;
                case '$':
                    return compilerOptions.types
                        ? Diagnostics
                            .Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_jQuery_Try_npm_i_types_Slashjquery_and_then_add_jquery_to_the_types_field_in_your_tsconfig
                        : Diagnostics
                            .Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_jQuery_Try_npm_i_types_Slashjquery;
                case 'describe':
                case 'suite':
                case 'it':
                case 'test':
                    return compilerOptions.types
                        ? Diagnostics
                            .Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_a_test_runner_Try_npm_i_types_Slashjest_or_npm_i_types_Slashmocha_and_then_add_jest_or_mocha_to_the_types_field_in_your_tsconfig
                        : Diagnostics
                            .Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_a_test_runner_Try_npm_i_types_Slashjest_or_npm_i_types_Slashmocha;
                case 'process':
                case 'require':
                case 'Buffer':
                case 'module':
                    return compilerOptions.types
                        ? Diagnostics
                            .Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_node_Try_npm_i_types_Slashnode_and_then_add_node_to_the_types_field_in_your_tsconfig
                        : Diagnostics
                            .Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_node_Try_npm_i_types_Slashnode;
                case 'Map':
                case 'Set':
                case 'Promise':
                case 'Symbol':
                case 'WeakMap':
                case 'WeakSet':
                case 'Iterator':
                case 'AsyncIterator':
                    return Diagnostics
                        .Cannot_find_name_0_Do_you_need_to_change_your_target_library_Try_changing_the_lib_compiler_option_to_es2015_or_later;
                default:
                    if (node.parent.kind
                        === SyntaxKind.ShorthandPropertyAssignment)
                    {
                        return Diagnostics
                            .No_value_exists_in_scope_for_the_shorthand_property_0_Either_declare_one_or_provide_an_initializer;
                    } else {
                        return Diagnostics.Cannot_find_name_0;
                    }
            }
        }

        function getResolvedSymbol(node: Identifier): Symbol {
            const links = getNodeLinks(node);
            if (!links.resolvedSymbol) {
                links.resolvedSymbol = !nodeIsMissing(node)
                    && resolveName(
                        node,
                        node.escapedText,
                        SymbolFlags.Value | SymbolFlags.ExportValue,
                        getCannotFindNameDiagnosticForName(node),
                        node,
                        !isWriteOnlyAccess(node),
                        /*excludeGlobals*/ false,
                        Diagnostics.Cannot_find_name_0_Did_you_mean_1
                    ) || unknownSymbol;
            }
            return links.resolvedSymbol;
        }

        function isInTypeQuery(node: Node): boolean {
            // TypeScript 1.0 spec (April 2014): 3.6.3
            // A type query consists of the keyword typeof followed by an expression.
            // The expression is restricted to a single identifier or a sequence of identifiers separated by periods
            return !!findAncestor(
                node,
                n => n.kind === SyntaxKind.TypeQuery
                    ? true
                    : n.kind === SyntaxKind.Identifier
                        || n.kind === SyntaxKind.QualifiedName
                        ? false
                        : 'quit'
            );
        }

        // Return the flow cache key for a "dotted name" (i.e. a sequence of identifiers
        // separated by dots). The key consists of the id of the symbol referenced by the
        // leftmost identifier followed by zero or more property names separated by dots.
        // The result is undefined if the reference isn't a dotted name. We prefix nodes
        // occurring in an apparent type position with '@' because the control flow type
        // of such nodes may be based on the apparent type instead of the declared type.
        function getFlowCacheKey(
            node: Node,
            declaredType: Type,
            initialType: Type,
            flowContainer: Node | undefined
        ): string | undefined {
            switch (node.kind) {
                case SyntaxKind.Identifier:
                    const symbol = getResolvedSymbol(<Identifier> node);
                    return symbol !== unknownSymbol
                        ? `${flowContainer ? getNodeId(flowContainer) : '-1'
                            }|${getTypeId(declaredType)}|${getTypeId(
                            initialType
                        )}|${isConstraintPosition(node) ? '@' : ''}${
                            getSymbolId(symbol)}`
                        : undefined;
                case SyntaxKind.ThisKeyword:
                    return '0';
                case SyntaxKind.NonNullExpression:
                case SyntaxKind.ParenthesizedExpression:
                    return getFlowCacheKey(
                        (<NonNullExpression | ParenthesizedExpression> node)
                            .expression,
                        declaredType,
                        initialType,
                        flowContainer
                    );
                case SyntaxKind.PropertyAccessExpression:
                case SyntaxKind.ElementAccessExpression:
                    const propName = getAccessedPropertyName(<AccessExpression> node);
                    if (propName !== undefined) {
                        const key = getFlowCacheKey(
                            (<AccessExpression> node).expression,
                            declaredType,
                            initialType,
                            flowContainer
                        );
                        return key && key + '.' + propName;
                    }
            }
            return undefined;
        }

        function isMatchingReference(source: Node, target: Node): boolean {
            switch (target.kind) {
                case SyntaxKind.ParenthesizedExpression:
                case SyntaxKind.NonNullExpression:
                    return isMatchingReference(
                        source,
                        (target as NonNullExpression | ParenthesizedExpression)
                            .expression
                    );
            }
            switch (source.kind) {
                case SyntaxKind.Identifier:
                    return target.kind === SyntaxKind.Identifier
                        && getResolvedSymbol(<Identifier> source)
                        === getResolvedSymbol(<Identifier> target)
                        || (target.kind === SyntaxKind.VariableDeclaration
                            || target.kind === SyntaxKind.BindingElement)
                        && getExportSymbolOfValueSymbolIfExported(getResolvedSymbol(<Identifier> source))
                        === getSymbolOfNode(target);
                case SyntaxKind.ThisKeyword:
                    return target.kind === SyntaxKind.ThisKeyword;
                case SyntaxKind.SuperKeyword:
                    return target.kind === SyntaxKind.SuperKeyword;
                case SyntaxKind.NonNullExpression:
                case SyntaxKind.ParenthesizedExpression:
                    return isMatchingReference(
                        (source as NonNullExpression | ParenthesizedExpression)
                            .expression,
                        target
                    );
                case SyntaxKind.PropertyAccessExpression:
                case SyntaxKind.ElementAccessExpression:
                    return isAccessExpression(target)
                        && getAccessedPropertyName(<AccessExpression> source)
                        === getAccessedPropertyName(target)
                        && isMatchingReference(
                            (<AccessExpression> source).expression,
                            target.expression
                        );
            }
            return false;
        }

        function getAccessedPropertyName(
            access: AccessExpression
        ): __String | undefined {
            return access.kind === SyntaxKind.PropertyAccessExpression
                ? access.name.escapedText
                : isStringOrNumericLiteralLike(access.argumentExpression)
                    ? escapeLeadingUnderscores(access.argumentExpression.text)
                    : undefined;
        }

        function containsMatchingReference(source: Node, target: Node) {
            while (isAccessExpression(source)) {
                source = source.expression;
                if (isMatchingReference(source, target)) {
                    return true;
                }
            }
            return false;
        }

        function optionalChainContainsReference(source: Node, target: Node) {
            while (isOptionalChain(source)) {
                source = source.expression;
                if (isMatchingReference(source, target)) {
                    return true;
                }
            }
            return false;
        }

        // Return true if target is a property access xxx.yyy, source is a property access xxx.zzz, the declared
        // type of xxx is a union type, and yyy is a property that is possibly a discriminant. We consider a property
        // a possible discriminant if its type differs in the constituents of containing union type, and if every
        // choice is a unit type or a union of unit types.
        function containsMatchingReferenceDiscriminant(
            source: Node,
            target: Node
        ) {
            let name;
            return isAccessExpression(target)
                && containsMatchingReference(source, target.expression)
                && (name = getAccessedPropertyName(target)) !== undefined
                && isDiscriminantProperty(
                    getDeclaredTypeOfReference(
                        target.expression
                    ),
                    name
                );
        }

        function getDeclaredTypeOfReference(expr: Node): Type | undefined {
            if (expr.kind === SyntaxKind.Identifier) {
                return getTypeOfSymbol(getResolvedSymbol(<Identifier> expr));
            }
            if (isAccessExpression(expr)) {
                const type = getDeclaredTypeOfReference(expr.expression);
                if (type) {
                    const propName = getAccessedPropertyName(expr);
                    return propName !== undefined
                        ? getTypeOfPropertyOfType(type, propName)
                        : undefined;
                }
            }
            return undefined;
        }

        function isDiscriminantProperty(type: Type | undefined,
            name: __String)
        {
            if (type && type.flags & TypeFlags.Union) {
                const prop = getUnionOrIntersectionProperty(
                    <UnionType> type,
                    name
                );
                if (prop
                    && getCheckFlags(prop) & CheckFlags.SyntheticProperty)
                {
                    if ((<TransientSymbol> prop).isDiscriminantProperty
                        === undefined)
                    {
                        (<TransientSymbol> prop)
                            .isDiscriminantProperty = ((<TransientSymbol> prop)
                                .checkFlags & CheckFlags.Discriminant)
                                === CheckFlags.Discriminant
                                && !maybeTypeOfKind(
                                    getTypeOfSymbol(prop),
                                    TypeFlags.Instantiable
                                );
                    }
                    return !!(<TransientSymbol> prop).isDiscriminantProperty;
                }
            }
            return false;
        }

        function isSyntheticThisPropertyAccess(expr: Node) {
            return isAccessExpression(expr)
                && expr.expression.kind === SyntaxKind.ThisKeyword
                && !!(expr.expression.flags & NodeFlags.Synthesized);
        }

        function findDiscriminantProperties(
            sourceProperties: Symbol[],
            target: Type
        ): Symbol[] | undefined {
            let result: Symbol[] | undefined;
            for (const sourceProperty of sourceProperties) {
                if (isDiscriminantProperty(target,
                    sourceProperty.escapedName))
                {
                    if (result) {
                        result.push(sourceProperty);
                        continue;
                    }
                    result = [sourceProperty];
                }
            }
            return result;
        }

        function isOrContainsMatchingReference(source: Node, target: Node) {
            return isMatchingReference(source, target)
                || containsMatchingReference(source, target);
        }

        function hasMatchingArgument(
            callExpression: CallExpression,
            reference: Node
        ) {
            if (callExpression.arguments) {
                for (const argument of callExpression.arguments) {
                    if (isOrContainsMatchingReference(reference, argument)) {
                        return true;
                    }
                }
            }
            if (callExpression.expression.kind
                === SyntaxKind.PropertyAccessExpression
                && isOrContainsMatchingReference(
                    reference,
                    (<PropertyAccessExpression> callExpression.expression)
                        .expression
                ))
            {
                return true;
            }
            return false;
        }

        function getFlowNodeId(flow: FlowNode): number {
            if (!flow.id || flow.id < 0) {
                flow.id = nextFlowId;
                nextFlowId++;
            }
            return flow.id;
        }

        function typeMaybeAssignableTo(source: Type, target: Type) {
            if (!(source.flags & TypeFlags.Union)) {
                return isTypeAssignableTo(source, target);
            }
            for (const t of (<UnionType> source).types) {
                if (isTypeAssignableTo(t, target)) {
                    return true;
                }
            }
            return false;
        }

        // Remove those constituent types of declaredType to which no constituent type of assignedType is assignable.
        // For example, when a variable of type number | string | boolean is assigned a value of type number | boolean,
        // we remove type string.
        function getAssignmentReducedType(
            declaredType: UnionType,
            assignedType: Type
        ) {
            if (declaredType !== assignedType) {
                if (assignedType.flags & TypeFlags.Never) {
                    return assignedType;
                }
                let reducedType = filterType(
                    declaredType,
                    t => typeMaybeAssignableTo(assignedType, t)
                );
                if (assignedType.flags & TypeFlags.BooleanLiteral
                    && isFreshLiteralType(assignedType))
                {
                    reducedType = mapType(
                        reducedType,
                        getFreshTypeOfLiteralType
                    ); // Ensure that if the assignment is a fresh type, that we narrow to fresh types
                }
                // Our crude heuristic produces an invalid result in some cases: see GH#26130.
                // For now, when that happens, we give up and don't narrow at all.  (This also
                // means we'll never narrow for erroneous assignments where the assigned type
                // is not assignable to the declared type.)
                if (isTypeAssignableTo(assignedType, reducedType)) {
                    return reducedType;
                }
            }
            return declaredType;
        }

        function getTypeFactsOfTypes(types: Type[]): TypeFacts {
            let result: TypeFacts = TypeFacts.None;
            for (const t of types) {
                result |= getTypeFacts(t);
            }
            return result;
        }

        function isFunctionObjectType(type: ObjectType): boolean {
            // We do a quick check for a "bind" property before performing the more expensive subtype
            // check. This gives us a quicker out in the common case where an object type is not a function.
            const resolved = resolveStructuredTypeMembers(type);
            return !!(resolved.callSignatures.length
                || resolved.constructSignatures.length
                || resolved.members.get('bind' as __String)
                && isTypeSubtypeOf(type, globalFunctionType));
        }

        function getTypeFacts(type: Type): TypeFacts {
            const flags = type.flags;
            if (flags & TypeFlags.String) {
                return strictNullChecks
                    ? TypeFacts.StringStrictFacts
                    : TypeFacts.StringFacts;
            }
            if (flags & TypeFlags.StringLiteral) {
                const isEmpty = (<StringLiteralType> type).value === '';
                return strictNullChecks
                    ? isEmpty
                        ? TypeFacts.EmptyStringStrictFacts
                        : TypeFacts.NonEmptyStringStrictFacts
                    : isEmpty ? TypeFacts.EmptyStringFacts
                        : TypeFacts.NonEmptyStringFacts;
            }
            if (flags & (TypeFlags.Number | TypeFlags.Enum)) {
                return strictNullChecks
                    ? TypeFacts.NumberStrictFacts
                    : TypeFacts.NumberFacts;
            }
            if (flags & TypeFlags.NumberLiteral) {
                const isZero = (<NumberLiteralType> type).value === 0;
                return strictNullChecks
                    ? isZero
                        ? TypeFacts.ZeroNumberStrictFacts
                        : TypeFacts.NonZeroNumberStrictFacts
                    : isZero ? TypeFacts.ZeroNumberFacts
                        : TypeFacts.NonZeroNumberFacts;
            }
            if (flags & TypeFlags.BigInt) {
                return strictNullChecks
                    ? TypeFacts.BigIntStrictFacts
                    : TypeFacts.BigIntFacts;
            }
            if (flags & TypeFlags.BigIntLiteral) {
                const isZero = isZeroBigInt(<BigIntLiteralType> type);
                return strictNullChecks
                    ? isZero
                        ? TypeFacts.ZeroBigIntStrictFacts
                        : TypeFacts.NonZeroBigIntStrictFacts
                    : isZero ? TypeFacts.ZeroBigIntFacts
                        : TypeFacts.NonZeroBigIntFacts;
            }
            if (flags & TypeFlags.Boolean) {
                return strictNullChecks
                    ? TypeFacts.BooleanStrictFacts
                    : TypeFacts.BooleanFacts;
            }
            if (flags & TypeFlags.BooleanLike) {
                return strictNullChecks
                    ? (type === falseType || type === regularFalseType)
                        ? TypeFacts.FalseStrictFacts
                        : TypeFacts.TrueStrictFacts
                    : (type === falseType || type === regularFalseType)
                        ? TypeFacts.FalseFacts
                        : TypeFacts.TrueFacts;
            }
            if (flags & TypeFlags.Object) {
                return getObjectFlags(type) & ObjectFlags.Anonymous
                    && isEmptyObjectType(<ObjectType> type)
                    ? strictNullChecks
                        ? TypeFacts.EmptyObjectStrictFacts
                        : TypeFacts.EmptyObjectFacts
                    : isFunctionObjectType(<ObjectType> type)
                        ? strictNullChecks ? TypeFacts.FunctionStrictFacts
                            : TypeFacts.FunctionFacts
                        : strictNullChecks ? TypeFacts.ObjectStrictFacts
                            : TypeFacts.ObjectFacts;
            }
            if (flags & (TypeFlags.Void | TypeFlags.Undefined)) {
                return TypeFacts.UndefinedFacts;
            }
            if (flags & TypeFlags.Null) {
                return TypeFacts.NullFacts;
            }
            if (flags & TypeFlags.ESSymbolLike) {
                return strictNullChecks
                    ? TypeFacts.SymbolStrictFacts
                    : TypeFacts.SymbolFacts;
            }
            if (flags & TypeFlags.NonPrimitive) {
                return strictNullChecks
                    ? TypeFacts.ObjectStrictFacts
                    : TypeFacts.ObjectFacts;
            }
            if (flags & TypeFlags.Instantiable) {
                return getTypeFacts(
                    getBaseConstraintOfType(type) || unknownType
                );
            }
            if (flags & TypeFlags.UnionOrIntersection) {
                return getTypeFactsOfTypes(
                    (<UnionOrIntersectionType> type).types
                );
            }
            return TypeFacts.All;
        }

        function getTypeWithFacts(type: Type, include: TypeFacts) {
            return filterType(type, t => (getTypeFacts(t) & include) !== 0);
        }

        function getTypeWithDefault(type: Type,
            defaultExpression: Expression)
        {
            if (defaultExpression) {
                const defaultType = getTypeOfExpression(defaultExpression);
                return getUnionType(
                    [getTypeWithFacts(
                        type,
                        TypeFacts.NEUndefined
                    ), defaultType]
                );
            }
            return type;
        }

        function getTypeOfDestructuredProperty(type: Type,
            name: PropertyName)
        {
            const nameType = getLiteralTypeFromPropertyName(name);
            if (!isTypeUsableAsPropertyName(nameType)) return errorType;
            const text = getPropertyNameFromType(nameType);
            return getConstraintForLocation(
                getTypeOfPropertyOfType(type, text),
                name
            )
                || isNumericLiteralName(text)
                && getIndexTypeOfType(type, IndexKind.Number)
                || getIndexTypeOfType(type, IndexKind.String)
                || errorType;
        }

        function getTypeOfDestructuredArrayElement(type: Type, index: number) {
            return everyType(type, isTupleLikeType)
                && getTupleElementType(type, index)
                || checkIteratedTypeOrElementType(
                    IterationUse.Destructuring,
                    type,
                    undefinedType, /*errorNode*/
                    undefined
                )
                || errorType;
        }

        function getTypeOfDestructuredSpreadExpression(type: Type) {
            return createArrayType(
                checkIteratedTypeOrElementType(
                    IterationUse.Destructuring,
                    type,
                    undefinedType, /*errorNode*/
                    undefined
                ) || errorType
            );
        }

        function getAssignedTypeOfBinaryExpression(
            node: BinaryExpression
        ): Type {
            const isDestructuringDefaultAssignment = node.parent.kind
                === SyntaxKind.ArrayLiteralExpression
                && isDestructuringAssignmentTarget(node.parent)
                || node.parent.kind === SyntaxKind.PropertyAssignment
                && isDestructuringAssignmentTarget(node.parent.parent);
            return isDestructuringDefaultAssignment
                ? getTypeWithDefault(getAssignedType(node), node.right)
                : getTypeOfExpression(node.right);
        }

        function isDestructuringAssignmentTarget(parent: Node) {
            return parent.parent.kind === SyntaxKind.BinaryExpression
                && (parent.parent as BinaryExpression).left === parent
                || parent.parent.kind === SyntaxKind.ForOfStatement
                && (parent.parent as ForOfStatement).initializer === parent;
        }

        function getAssignedTypeOfArrayLiteralElement(
            node: ArrayLiteralExpression,
            element: Expression
        ): Type {
            return getTypeOfDestructuredArrayElement(
                getAssignedType(node),
                node.elements.indexOf(element)
            );
        }

        function getAssignedTypeOfSpreadExpression(node: SpreadElement): Type {
            return getTypeOfDestructuredSpreadExpression(
                getAssignedType(
                    <ArrayLiteralExpression> node.parent
                )
            );
        }

        function getAssignedTypeOfPropertyAssignment(
            node: PropertyAssignment | ShorthandPropertyAssignment
        ): Type {
            return getTypeOfDestructuredProperty(
                getAssignedType(node.parent),
                node.name
            );
        }

        function getAssignedTypeOfShorthandPropertyAssignment(
            node: ShorthandPropertyAssignment
        ): Type {
            return getTypeWithDefault(
                getAssignedTypeOfPropertyAssignment(node),
                node.objectAssignmentInitializer!
            );
        }

        function getAssignedType(node: Expression): Type {
            const { parent } = node;
            switch (parent.kind) {
                case SyntaxKind.ForInStatement:
                    return stringType;
                case SyntaxKind.ForOfStatement:
                    return checkRightHandSideOfForOf(
                        (<ForOfStatement> parent).expression,
                        (<ForOfStatement> parent).awaitModifier
                    ) || errorType;
                case SyntaxKind.BinaryExpression:
                    return getAssignedTypeOfBinaryExpression(<BinaryExpression> parent);
                case SyntaxKind.DeleteExpression:
                    return undefinedType;
                case SyntaxKind.ArrayLiteralExpression:
                    return getAssignedTypeOfArrayLiteralElement(
                        <ArrayLiteralExpression> parent,
                        node
                    );
                case SyntaxKind.SpreadElement:
                    return getAssignedTypeOfSpreadExpression(<SpreadElement> parent);
                case SyntaxKind.PropertyAssignment:
                    return getAssignedTypeOfPropertyAssignment(<PropertyAssignment> parent);
                case SyntaxKind.ShorthandPropertyAssignment:
                    return getAssignedTypeOfShorthandPropertyAssignment(<ShorthandPropertyAssignment> parent);
            }
            return errorType;
        }

        function getInitialTypeOfBindingElement(node: BindingElement): Type {
            const pattern = node.parent;
            const parentType = getInitialType(
                <VariableDeclaration | BindingElement> pattern.parent
            );
            const type = pattern.kind === SyntaxKind.ObjectBindingPattern
                ? getTypeOfDestructuredProperty(
                    parentType,
                    node.propertyName || <Identifier> node.name
                )
                : !node.dotDotDotToken
                    ? getTypeOfDestructuredArrayElement(
                        parentType,
                        pattern.elements.indexOf(node)
                    )
                    : getTypeOfDestructuredSpreadExpression(parentType);
            return getTypeWithDefault(type, node.initializer!);
        }

        function getTypeOfInitializer(node: Expression) {
            // Return the cached type if one is available. If the type of the variable was inferred
            // from its initializer, we'll already have cached the type. Otherwise we compute it now
            // without caching such that transient types are reflected.
            const links = getNodeLinks(node);
            return links.resolvedType || getTypeOfExpression(node);
        }

        function getInitialTypeOfVariableDeclaration(node:
            VariableDeclaration)
        {
            if (node.initializer) {
                return getTypeOfInitializer(node.initializer);
            }
            if (node.parent.parent.kind === SyntaxKind.ForInStatement) {
                return stringType;
            }
            if (node.parent.parent.kind === SyntaxKind.ForOfStatement) {
                return checkRightHandSideOfForOf(
                    node.parent.parent.expression,
                    node.parent.parent.awaitModifier
                ) || errorType;
            }
            return errorType;
        }

        function getInitialType(node: VariableDeclaration | BindingElement) {
            return node.kind === SyntaxKind.VariableDeclaration
                ? getInitialTypeOfVariableDeclaration(node)
                : getInitialTypeOfBindingElement(node);
        }

        function isEmptyArrayAssignment(
            node: VariableDeclaration | BindingElement | Expression
        ) {
            return node.kind === SyntaxKind.VariableDeclaration
                && (<VariableDeclaration> node).initializer
                && isEmptyArrayLiteral(
                    (<VariableDeclaration> node).initializer!
                )
                || node.kind !== SyntaxKind.BindingElement
                && node.parent.kind === SyntaxKind.BinaryExpression
                && isEmptyArrayLiteral((<BinaryExpression> node.parent).right);
        }

        function getReferenceCandidate(node: Expression): Expression {
            switch (node.kind) {
                case SyntaxKind.ParenthesizedExpression:
                    return getReferenceCandidate(
                        (<ParenthesizedExpression> node).expression
                    );
                case SyntaxKind.BinaryExpression:
                    switch ((<BinaryExpression> node).operatorToken.kind) {
                        case SyntaxKind.EqualsToken:
                            return getReferenceCandidate(
                                (<BinaryExpression> node).left
                            );
                        case SyntaxKind.CommaToken:
                            return getReferenceCandidate(
                                (<BinaryExpression> node).right
                            );
                    }
            }
            return node;
        }

        function getReferenceRoot(node: Node): Node {
            const { parent } = node;
            return parent.kind === SyntaxKind.ParenthesizedExpression
                || parent.kind === SyntaxKind.BinaryExpression
                && (<BinaryExpression> parent).operatorToken.kind
                === SyntaxKind.EqualsToken
                && (<BinaryExpression> parent).left === node
                || parent.kind === SyntaxKind.BinaryExpression
                && (<BinaryExpression> parent).operatorToken.kind
                === SyntaxKind.CommaToken
                && (<BinaryExpression> parent).right === node
                ? getReferenceRoot(parent)
                : node;
        }

        function getTypeOfSwitchClause(clause: CaseClause | DefaultClause) {
            if (clause.kind === SyntaxKind.CaseClause) {
                return getRegularTypeOfLiteralType(
                    getTypeOfExpression(
                        clause.expression
                    )
                );
            }
            return neverType;
        }

        function getSwitchClauseTypes(switchStatement:
            SwitchStatement): Type[]
        {
            const links = getNodeLinks(switchStatement);
            if (!links.switchTypes) {
                links.switchTypes = [];
                for (const clause of switchStatement.caseBlock.clauses) {
                    links.switchTypes.push(getTypeOfSwitchClause(clause));
                }
            }
            return links.switchTypes;
        }

        // Get the types from all cases in a switch on `typeof`. An
        // `undefined` element denotes an explicit `default` clause.
        function getSwitchClauseTypeOfWitnesses(
            switchStatement: SwitchStatement
        ): (string | undefined)[] {
            const witnesses: (string | undefined)[] = [];
            for (const clause of switchStatement.caseBlock.clauses) {
                if (clause.kind === SyntaxKind.CaseClause) {
                    if (isStringLiteralLike(clause.expression)) {
                        witnesses.push(clause.expression.text);
                        continue;
                    }
                    return emptyArray;
                }
                witnesses.push(/*explicitDefaultStatement*/ undefined);
            }
            return witnesses;
        }

        function eachTypeContainedIn(source: Type, types: Type[]) {
            return source.flags & TypeFlags.Union
                ? !forEach(
                    (<UnionType> source).types,
                    t => !contains(types, t)
                )
                : contains(types, source);
        }

        function isTypeSubsetOf(source: Type, target: Type) {
            return source === target || target.flags & TypeFlags.Union
                && isTypeSubsetOfUnion(source, <UnionType> target);
        }

        function isTypeSubsetOfUnion(source: Type, target: UnionType) {
            if (source.flags & TypeFlags.Union) {
                for (const t of (<UnionType> source).types) {
                    if (!containsType(target.types, t)) {
                        return false;
                    }
                }
                return true;
            }
            if (source.flags & TypeFlags.EnumLiteral
                && getBaseTypeOfEnumLiteralType(<LiteralType> source)
                === target)
            {
                return true;
            }
            return containsType(target.types, source);
        }

        function forEachType<T>(
            type: Type,
            f: (t: Type) => T | undefined
        ): T | undefined {
            return type.flags & TypeFlags.Union
                ? forEach((<UnionType> type).types, f)
                : f(type);
        }

        function everyType(type: Type, f: (t: Type) => boolean): boolean {
            return type.flags & TypeFlags.Union
                ? every((<UnionType> type).types, f)
                : f(type);
        }

        function filterType(type: Type, f: (t: Type) => boolean): Type {
            if (type.flags & TypeFlags.Union) {
                const types = (<UnionType> type).types;
                const filtered = filter(types, f);
                return filtered === types
                    ? type
                    : getUnionTypeFromSortedList(
                        filtered,
                        (<UnionType> type).objectFlags
                    );
            }
            return f(type) ? type : neverType;
        }

        function countTypes(type: Type) {
            return type.flags & TypeFlags.Union
                ? (type as UnionType).types.length
                : 1;
        }

        // Apply a mapping function to a type and return the resulting type. If the source type
        // is a union type, the mapping function is applied to each constituent type and a union
        // of the resulting types is returned.
        function mapType(
            type: Type,
            mapper: (t: Type) => Type,
            noReductions?: boolean
        ): Type;
        function mapType(
            type: Type,
            mapper: (t: Type) => Type | undefined,
            noReductions?: boolean
        ): Type | undefined;
        function mapType(
            type: Type,
            mapper: (t: Type) => Type | undefined,
            noReductions?: boolean
        ): Type | undefined {
            if (type.flags & TypeFlags.Never) {
                return type;
            }
            if (!(type.flags & TypeFlags.Union)) {
                return mapper(type);
            }
            let mappedTypes: Type[] | undefined;
            for (const t of (<UnionType> type).types) {
                const mapped = mapper(t);
                if (mapped) {
                    if (!mappedTypes) {
                        mappedTypes = [mapped];
                    } else {
                        mappedTypes.push(mapped);
                    }
                }
            }
            return mappedTypes
                && getUnionType(
                    mappedTypes,
                    noReductions ? UnionReduction.None : UnionReduction.Literal
                );
        }

        function extractTypesOfKind(type: Type, kind: TypeFlags) {
            return filterType(type, t => (t.flags & kind) !== 0);
        }

        // Return a new type in which occurrences of the string and number primitive types in
        // typeWithPrimitives have been replaced with occurrences of string literals and numeric
        // literals in typeWithLiterals, respectively.
        function replacePrimitivesWithLiterals(
            typeWithPrimitives: Type,
            typeWithLiterals: Type
        ) {
            if (isTypeSubsetOf(stringType, typeWithPrimitives)
                && maybeTypeOfKind(typeWithLiterals, TypeFlags.StringLiteral)
                || isTypeSubsetOf(numberType, typeWithPrimitives)
                && maybeTypeOfKind(typeWithLiterals, TypeFlags.NumberLiteral)
                || isTypeSubsetOf(bigintType, typeWithPrimitives)
                && maybeTypeOfKind(typeWithLiterals, TypeFlags.BigIntLiteral))
            {
                return mapType(
                    typeWithPrimitives,
                    t => t.flags & TypeFlags.String
                        ? extractTypesOfKind(
                            typeWithLiterals,
                            TypeFlags.String | TypeFlags.StringLiteral
                        )
                        : t.flags & TypeFlags.Number
                            ? extractTypesOfKind(
                                typeWithLiterals,
                                TypeFlags.Number | TypeFlags.NumberLiteral
                            )
                            : t.flags & TypeFlags.BigInt
                                ? extractTypesOfKind(
                                    typeWithLiterals,
                                    TypeFlags.BigInt | TypeFlags.BigIntLiteral
                                )
                                : t
                );
            }
            return typeWithPrimitives;
        }

        function isIncomplete(flowType: FlowType) {
            return flowType.flags === 0;
        }

        function getTypeFromFlowType(flowType: FlowType) {
            return flowType.flags === 0
                ? (<IncompleteType> flowType).type
                : <Type> flowType;
        }

        function createFlowType(type: Type, incomplete: boolean): FlowType {
            return incomplete ? { flags: 0, type } : type;
        }

        // An evolving array type tracks the element types that have so far been seen in an
        // 'x.push(value)' or 'x[n] = value' operation along the control flow graph. Evolving
        // array types are ultimately converted into manifest array types (using getFinalArrayType)
        // and never escape the getFlowTypeOfReference function.
        function createEvolvingArrayType(elementType:
            Type): EvolvingArrayType
        {
            const result = <EvolvingArrayType> createObjectType(
                ObjectFlags.EvolvingArray
            );
            result.elementType = elementType;
            return result;
        }

        function getEvolvingArrayType(elementType: Type): EvolvingArrayType {
            return evolvingArrayTypes[elementType.id]
                || (evolvingArrayTypes[elementType
                    .id] = createEvolvingArrayType(elementType));
        }

        // When adding evolving array element types we do not perform subtype reduction. Instead,
        // we defer subtype reduction until the evolving array type is finalized into a manifest
        // array type.
        function addEvolvingArrayElementType(
            evolvingArrayType: EvolvingArrayType,
            node: Expression
        ): EvolvingArrayType {
            const elementType = getBaseTypeOfLiteralType(getContextFreeTypeOfExpression(node));
            return isTypeSubsetOf(elementType, evolvingArrayType.elementType)
                ? evolvingArrayType
                : getEvolvingArrayType(
                    getUnionType(
                        [evolvingArrayType.elementType, elementType]
                    )
                );
        }

        function createFinalArrayType(elementType: Type) {
            return elementType.flags & TypeFlags.Never
                ? autoArrayType
                : createArrayType(
                    elementType.flags & TypeFlags.Union
                        ? getUnionType(
                            (<UnionType> elementType).types,
                            UnionReduction.Subtype
                        )
                        : elementType
                );
        }

        // We perform subtype reduction upon obtaining the final array type from an evolving array type.
        function getFinalArrayType(evolvingArrayType:
            EvolvingArrayType): Type
        {
            return evolvingArrayType.finalArrayType
                || (evolvingArrayType
                    .finalArrayType = createFinalArrayType(
                        evolvingArrayType.elementType
                    ));
        }

        function finalizeEvolvingArrayType(type: Type): Type {
            return getObjectFlags(type) & ObjectFlags.EvolvingArray
                ? getFinalArrayType(<EvolvingArrayType> type)
                : type;
        }

        function getElementTypeOfEvolvingArrayType(type: Type) {
            return getObjectFlags(type) & ObjectFlags.EvolvingArray
                ? (<EvolvingArrayType> type).elementType
                : neverType;
        }

        function isEvolvingArrayTypeList(types: Type[]) {
            let hasEvolvingArrayType = false;
            for (const t of types) {
                if (!(t.flags & TypeFlags.Never)) {
                    if (!(getObjectFlags(t) & ObjectFlags.EvolvingArray)) {
                        return false;
                    }
                    hasEvolvingArrayType = true;
                }
            }
            return hasEvolvingArrayType;
        }

        // At flow control branch or loop junctions, if the type along every antecedent code path
        // is an evolving array type, we construct a combined evolving array type. Otherwise we
        // finalize all evolving array types.
        function getUnionOrEvolvingArrayType(
            types: Type[],
            subtypeReduction: UnionReduction
        ) {
            return isEvolvingArrayTypeList(types)
                ? getEvolvingArrayType(
                    getUnionType(
                        map(
                            types,
                            getElementTypeOfEvolvingArrayType
                        )
                    )
                )
                : getUnionType(
                    sameMap(types, finalizeEvolvingArrayType),
                    subtypeReduction
                );
        }

        // Return true if the given node is 'x' in an 'x.length', x.push(value)', 'x.unshift(value)' or
        // 'x[n] = value' operation, where 'n' is an expression of type any, undefined, or a number-like type.
        function isEvolvingArrayOperationTarget(node: Node) {
            const root = getReferenceRoot(node);
            const parent = root.parent;
            const isLengthPushOrUnshift = isPropertyAccessExpression(parent)
                && (
                    parent.name.escapedText === 'length'
                    || parent.parent.kind === SyntaxKind.CallExpression
                    && isIdentifier(parent.name)
                    && isPushOrUnshiftIdentifier(parent.name)
                );
            const isElementAssignment = parent.kind
                === SyntaxKind.ElementAccessExpression
                && (<ElementAccessExpression> parent).expression === root
                && parent.parent.kind === SyntaxKind.BinaryExpression
                && (<BinaryExpression> parent.parent).operatorToken.kind
                === SyntaxKind.EqualsToken
                && (<BinaryExpression> parent.parent).left === parent
                && !isAssignmentTarget(parent.parent)
                && isTypeAssignableToKind(
                    getTypeOfExpression(
                        (<ElementAccessExpression> parent).argumentExpression
                    ),
                    TypeFlags.NumberLike
                );
            return isLengthPushOrUnshift || isElementAssignment;
        }

        function isDeclarationWithExplicitTypeAnnotation(
            declaration: Declaration | undefined
        ) {
            return !!(declaration && (
                declaration.kind === SyntaxKind.VariableDeclaration
                || declaration.kind === SyntaxKind.Parameter
                || declaration.kind === SyntaxKind.PropertyDeclaration
                || declaration.kind === SyntaxKind.PropertySignature
            )
                && getEffectiveTypeAnnotationNode(
                    declaration as VariableDeclaration | ParameterDeclaration
                        | PropertyDeclaration | PropertySignature
                ));
        }

        function getExplicitTypeOfSymbol(
            symbol: Symbol,
            diagnostic?: Diagnostic
        ) {
            if (symbol.flags
                & (SymbolFlags.Function | SymbolFlags.Method
                    | SymbolFlags.Class | SymbolFlags.ValueModule))
            {
                return getTypeOfSymbol(symbol);
            }
            if (symbol.flags & (SymbolFlags.Variable | SymbolFlags.Property)) {
                if (isDeclarationWithExplicitTypeAnnotation(
                    symbol.valueDeclaration
                )) {
                    return getTypeOfSymbol(symbol);
                }
                if (diagnostic && symbol.valueDeclaration) {
                    addRelatedInfo(
                        diagnostic,
                        createDiagnosticForNode(
                            symbol.valueDeclaration,
                            Diagnostics._0_is_declared_here,
                            symbolToString(symbol)
                        )
                    );
                }
            }
        }

        // We require the dotted function name in an assertion expression to be comprised of identifiers
        // that reference function, method, class or value module symbols; or variable, property or
        // parameter symbols with declarations that have explicit type annotations. Such references are
        // resolvable with no possibility of triggering circularities in control flow analysis.
        function getTypeOfDottedName(
            node: Expression,
            diagnostic: Diagnostic | undefined
        ): Type | undefined {
            if (!(node.flags & NodeFlags.InWithStatement)) {
                switch (node.kind) {
                    case SyntaxKind.Identifier:
                        const symbol = getExportSymbolOfValueSymbolIfExported(getResolvedSymbol(<Identifier> node));
                        return getExplicitTypeOfSymbol(
                            symbol.flags & SymbolFlags.Alias
                                ? resolveAlias(symbol)
                                : symbol,
                            diagnostic
                        );
                    case SyntaxKind.ThisKeyword:
                        return getExplicitThisType(node);
                    case SyntaxKind.PropertyAccessExpression:
                        const type = getTypeOfDottedName(
                            (<PropertyAccessExpression> node).expression,
                            diagnostic
                        );
                        const prop = type
                            && getPropertyOfType(
                                type,
                                (<PropertyAccessExpression> node).name
                                    .escapedText
                            );
                        return prop
                            && getExplicitTypeOfSymbol(prop, diagnostic);
                    case SyntaxKind.ParenthesizedExpression:
                        return getTypeOfDottedName(
                            (<ParenthesizedExpression> node).expression,
                            diagnostic
                        );
                }
            }
        }

        function getEffectsSignature(node: CallExpression) {
            const links = getNodeLinks(node);
            let signature = links.effectsSignature;
            if (signature === undefined) {
                // A call expression parented by an expression statement is a potential assertion. Other call
                // expressions are potential type predicate function calls. In order to avoid triggering
                // circularities in control flow analysis, we use getTypeOfDottedName when resolving the call
                // target expression of an assertion.
                let funcType: Type | undefined;
                if (node.parent.kind === SyntaxKind.ExpressionStatement) {
                    funcType = getTypeOfDottedName(
                        node.expression, /*diagnostic*/
                        undefined
                    );
                } else if (node.expression.kind !== SyntaxKind.SuperKeyword) {
                    if (isOptionalChain(node)) {
                        funcType = checkNonNullType(
                            getOptionalExpressionType(
                                checkExpression(
                                    node.expression
                                ),
                                node.expression
                            ),
                            node.expression
                        );
                    } else {
                        funcType = checkNonNullExpression(node.expression);
                    }
                }
                const signatures = getSignaturesOfType(
                    funcType && getApparentType(funcType) || unknownType,
                    SignatureKind.Call
                );
                const candidate = signatures.length === 1
                    && !signatures[0].typeParameters
                    ? signatures[0]
                    : some(signatures, hasTypePredicateOrNeverReturnType)
                        ? getResolvedSignature(node)
                        : undefined;
                signature = links
                    .effectsSignature = candidate
                        && hasTypePredicateOrNeverReturnType(candidate)
                        ? candidate
                        : unknownSignature;
            }
            return signature === unknownSignature ? undefined : signature;
        }

        function hasTypePredicateOrNeverReturnType(signature: Signature) {
            return !!(getTypePredicateOfSignature(signature)
                || signature.declaration
                && (getReturnTypeFromAnnotation(signature.declaration)
                    || unknownType).flags & TypeFlags.Never);
        }

        function getTypePredicateArgument(
            predicate: TypePredicate,
            callExpression: CallExpression
        ) {
            if (predicate.kind === TypePredicateKind.Identifier
                || predicate.kind === TypePredicateKind.AssertsIdentifier)
            {
                return callExpression.arguments[predicate.parameterIndex];
            }
            const invokedExpression = skipParentheses(
                callExpression.expression
            );
            return isAccessExpression(invokedExpression)
                ? skipParentheses(invokedExpression.expression)
                : undefined;
        }

        function reportFlowControlError(node: Node) {
            const block = <Block | ModuleBlock | SourceFile> findAncestor(
                node,
                isFunctionOrModuleBlock
            );
            const sourceFile = getSourceFileOfNode(node);
            const span = getSpanOfTokenAtPosition(
                sourceFile,
                block.statements.pos
            );
            diagnostics
                .add(
                    createFileDiagnostic(
                        sourceFile,
                        span.start,
                        span.length,
                        Diagnostics
                            .The_containing_function_or_module_body_is_too_large_for_control_flow_analysis
                    )
                );
        }

        function isReachableFlowNode(flow: FlowNode) {
            const result = isReachableFlowNodeWorker(
                flow, /*skipCacheCheck*/
                false
            );
            lastFlowNode = flow;
            lastFlowNodeReachable = result;
            return result;
        }

        function isUnlockedReachableFlowNode(flow: FlowNode) {
            return !(flow.flags & FlowFlags.PreFinally
                && (<PreFinallyFlow> flow).lock.locked)
                && isReachableFlowNodeWorker(flow, /*skipCacheCheck*/ false);
        }

        function isFalseExpression(expr: Expression): boolean {
            const node = skipParentheses(expr);
            return node.kind === SyntaxKind.FalseKeyword
                || node.kind === SyntaxKind.BinaryExpression && (
                    (<BinaryExpression> node).operatorToken.kind
                    === SyntaxKind.AmpersandAmpersandToken
                    && (isFalseExpression((<BinaryExpression> node).left)
                        || isFalseExpression((<BinaryExpression> node).right))
                    || (<BinaryExpression> node).operatorToken.kind
                    === SyntaxKind.BarBarToken
                    && isFalseExpression((<BinaryExpression> node).left)
                    && isFalseExpression((<BinaryExpression> node).right)
                );
        }

        function isReachableFlowNodeWorker(
            flow: FlowNode,
            noCacheCheck: boolean
        ): boolean {
            while (true) {
                if (flow === lastFlowNode) {
                    return lastFlowNodeReachable;
                }
                const flags = flow.flags;
                if (flags & FlowFlags.Shared) {
                    if (!noCacheCheck) {
                        const id = getFlowNodeId(flow);
                        const reachable = flowNodeReachable[id];
                        return reachable !== undefined
                            ? reachable
                            : (flowNodeReachable
                                [id] = isReachableFlowNodeWorker(
                                    flow, /*skipCacheCheck*/
                                    true
                                ));
                    }
                    noCacheCheck = false;
                }
                if (flags
                    & (FlowFlags.Assignment | FlowFlags.Condition
                        | FlowFlags.ArrayMutation | FlowFlags.PreFinally))
                {
                    flow = (<FlowAssignment | FlowCondition | FlowArrayMutation
                        | PreFinallyFlow> flow).antecedent;
                } else if (flags & FlowFlags.Call) {
                    const signature = getEffectsSignature(
                        (<FlowCall> flow).node
                    );
                    if (signature) {
                        const predicate = getTypePredicateOfSignature(signature);
                        if (predicate
                            && predicate.kind
                            === TypePredicateKind.AssertsIdentifier)
                        {
                            const predicateArgument = (<FlowCall> flow).node
                                .arguments[predicate.parameterIndex];
                            if (predicateArgument
                                && isFalseExpression(predicateArgument))
                            {
                                return false;
                            }
                        }
                        if (getReturnTypeOfSignature(signature).flags
                            & TypeFlags.Never)
                        {
                            return false;
                        }
                    }
                    flow = (<FlowCall> flow).antecedent;
                } else if (flags & FlowFlags.BranchLabel) {
                    // A branching point is reachable if any branch is reachable.
                    return some(
                        (<FlowLabel> flow).antecedents,
                        isUnlockedReachableFlowNode
                    );
                } else if (flags & FlowFlags.LoopLabel) {
                    // A loop is reachable if the control flow path that leads to the top is reachable.
                    flow = (<FlowLabel> flow).antecedents![0];
                } else if (flags & FlowFlags.SwitchClause) {
                    // The control flow path representing an unmatched value in a switch statement with
                    // no default clause is unreachable if the switch statement is exhaustive.
                    if ((<FlowSwitchClause> flow).clauseStart
                        === (<FlowSwitchClause> flow).clauseEnd
                        && isExhaustiveSwitchStatement(
                            (<FlowSwitchClause> flow).switchStatement
                        ))
                    {
                        return false;
                    }
                    flow = (<FlowSwitchClause> flow).antecedent;
                } else if (flags & FlowFlags.AfterFinally) {
                    // Cache is unreliable once we start locking nodes
                    lastFlowNode = undefined;
                    (<AfterFinallyFlow> flow).locked = true;
                    const result = isReachableFlowNodeWorker(
                        (<AfterFinallyFlow> flow)
                            .antecedent, /*skipCacheCheck*/
                        false
                    );
                    (<AfterFinallyFlow> flow).locked = false;
                    return result;
                } else {
                    return !(flags & FlowFlags.Unreachable);
                }
            }
        }

        function getFlowTypeOfReference(
            reference: Node,
            declaredType: Type,
            initialType = declaredType,
            flowContainer?: Node,
            couldBeUninitialized?: boolean
        ) {
            let key: string | undefined;
            let keySet = false;
            let flowDepth = 0;
            if (flowAnalysisDisabled) {
                return errorType;
            }
            if (!reference.flowNode || !couldBeUninitialized
                && !(declaredType.flags & TypeFlags.Narrowable))
            {
                return declaredType;
            }
            flowInvocationCount++;
            const sharedFlowStart = sharedFlowCount;
            const evolvedType = getTypeFromFlowType(
                getTypeAtFlowNode(
                    reference.flowNode
                )
            );
            sharedFlowCount = sharedFlowStart;
            // When the reference is 'x' in an 'x.length', 'x.push(value)', 'x.unshift(value)' or x[n] = value' operation,
            // we give type 'any[]' to 'x' instead of using the type determined by control flow analysis such that operations
            // on empty arrays are possible without implicit any errors and new element types can be inferred without
            // type mismatch errors.
            const resultType = getObjectFlags(evolvedType)
                & ObjectFlags.EvolvingArray
                && isEvolvingArrayOperationTarget(reference)
                ? autoArrayType
                : finalizeEvolvingArrayType(evolvedType);
            if (resultType === unreachableNeverType || reference.parent
                && reference.parent.kind === SyntaxKind.NonNullExpression
                && getTypeWithFacts(resultType, TypeFacts.NEUndefinedOrNull)
                    .flags & TypeFlags.Never)
            {
                return declaredType;
            }
            return resultType;

            function getOrSetCacheKey() {
                if (keySet) {
                    return key;
                }
                keySet = true;
                return key = getFlowCacheKey(
                    reference,
                    declaredType,
                    initialType,
                    flowContainer
                );
            }

            function getTypeAtFlowNode(flow: FlowNode): FlowType {
                if (flowDepth === 2000) {
                    // We have made 2000 recursive invocations. To avoid overflowing the call stack we report an error
                    // and disable further control flow analysis in the containing function or module body.
                    flowAnalysisDisabled = true;
                    reportFlowControlError(reference);
                    return errorType;
                }
                flowDepth++;
                while (true) {
                    const flags = flow.flags;
                    if (flags & FlowFlags.Shared) {
                        // We cache results of flow type resolution for shared nodes that were previously visited in
                        // the same getFlowTypeOfReference invocation. A node is considered shared when it is the
                        // antecedent of more than one node.
                        for (let i = sharedFlowStart; i < sharedFlowCount;
                            i++)
                        {
                            if (sharedFlowNodes[i] === flow) {
                                flowDepth--;
                                return sharedFlowTypes[i];
                            }
                        }
                    }
                    let type: FlowType | undefined;
                    if (flags & FlowFlags.AfterFinally) {
                        // block flow edge: finally -> pre-try (for larger explanation check comment in binder.ts - bindTryStatement
                        (<AfterFinallyFlow> flow).locked = true;
                        type = getTypeAtFlowNode(
                            (<AfterFinallyFlow> flow).antecedent
                        );
                        (<AfterFinallyFlow> flow).locked = false;
                    } else if (flags & FlowFlags.PreFinally) {
                        // locked pre-finally flows are filtered out in getTypeAtFlowBranchLabel
                        // so here just redirect to antecedent
                        flow = (<PreFinallyFlow> flow).antecedent;
                        continue;
                    } else if (flags & FlowFlags.Assignment) {
                        type = getTypeAtFlowAssignment(<FlowAssignment> flow);
                        if (!type) {
                            flow = (<FlowAssignment> flow).antecedent;
                            continue;
                        }
                    } else if (flags & FlowFlags.Call) {
                        type = getTypeAtFlowCall(<FlowCall> flow);
                        if (!type) {
                            flow = (<FlowCall> flow).antecedent;
                            continue;
                        }
                    } else if (flags & FlowFlags.Condition) {
                        type = getTypeAtFlowCondition(<FlowCondition> flow);
                    } else if (flags & FlowFlags.SwitchClause) {
                        type = getTypeAtSwitchClause(<FlowSwitchClause> flow);
                    } else if (flags & FlowFlags.Label) {
                        if ((<FlowLabel> flow).antecedents!.length === 1) {
                            flow = (<FlowLabel> flow).antecedents![0];
                            continue;
                        }
                        type = flags & FlowFlags.BranchLabel
                            ? getTypeAtFlowBranchLabel(<FlowLabel> flow)
                            : getTypeAtFlowLoopLabel(<FlowLabel> flow);
                    } else if (flags & FlowFlags.ArrayMutation) {
                        type = getTypeAtFlowArrayMutation(<FlowArrayMutation> flow);
                        if (!type) {
                            flow = (<FlowArrayMutation> flow).antecedent;
                            continue;
                        }
                    } else if (flags & FlowFlags.Start) {
                        // Check if we should continue with the control flow of the containing function.
                        const container = (<FlowStart> flow).node;
                        if (container && container !== flowContainer
                            && reference.kind
                            !== SyntaxKind.PropertyAccessExpression
                            && reference.kind
                            !== SyntaxKind.ElementAccessExpression
                            && reference.kind !== SyntaxKind.ThisKeyword)
                        {
                            flow = container.flowNode!;
                            continue;
                        }
                        // At the top of the flow we have the initial type.
                        type = initialType;
                    } else {
                        // Unreachable code errors are reported in the binding phase. Here we
                        // simply return the non-auto declared type to reduce follow-on errors.
                        type = convertAutoToAny(declaredType);
                    }
                    if (flags & FlowFlags.Shared) {
                        // Record visited node and the associated type in the cache.
                        sharedFlowNodes[sharedFlowCount] = flow;
                        sharedFlowTypes[sharedFlowCount] = type;
                        sharedFlowCount++;
                    }
                    flowDepth--;
                    return type;
                }
            }

            function getInitialOrAssignedType(flow: FlowAssignment) {
                const node = flow.node;
                return getConstraintForLocation(
                    node.kind === SyntaxKind.VariableDeclaration
                        || node.kind === SyntaxKind.BindingElement
                        ? getInitialType(
                            <VariableDeclaration | BindingElement> node
                        )
                        : getAssignedType(node),
                    reference
                );
            }

            function getTypeAtFlowAssignment(flow: FlowAssignment) {
                const node = flow.node;
                // Assignments only narrow the computed type if the declared type is a union type. Thus, we
                // only need to evaluate the assigned type if the declared type is a union type.
                if (isMatchingReference(reference, node)) {
                    if (!isReachableFlowNode(flow)) {
                        return unreachableNeverType;
                    }
                    if (getAssignmentTargetKind(node)
                        === AssignmentKind.Compound)
                    {
                        const flowType = getTypeAtFlowNode(flow.antecedent);
                        return createFlowType(
                            getBaseTypeOfLiteralType(getTypeFromFlowType(flowType)),
                            isIncomplete(flowType)
                        );
                    }
                    if (declaredType === autoType
                        || declaredType === autoArrayType)
                    {
                        if (isEmptyArrayAssignment(node)) {
                            return getEvolvingArrayType(neverType);
                        }
                        const assignedType = getBaseTypeOfLiteralType(getInitialOrAssignedType(flow));
                        return isTypeAssignableTo(assignedType, declaredType)
                            ? assignedType
                            : anyArrayType;
                    }
                    if (declaredType.flags & TypeFlags.Union) {
                        return getAssignmentReducedType(
                            <UnionType> declaredType,
                            getInitialOrAssignedType(flow)
                        );
                    }
                    return declaredType;
                }
                // We didn't have a direct match. However, if the reference is a dotted name, this
                // may be an assignment to a left hand part of the reference. For example, for a
                // reference 'x.y.z', we may be at an assignment to 'x.y' or 'x'. In that case,
                // return the declared type.
                if (containsMatchingReference(reference, node)) {
                    if (!isReachableFlowNode(flow)) {
                        return unreachableNeverType;
                    }
                    // A matching dotted name might also be an expando property on a function *expression*,
                    // in which case we continue control flow analysis back to the function's declaration
                    if (isVariableDeclaration(node)
                        && (isInJSFile(node) || isVarConst(node)))
                    {
                        const init = getDeclaredExpandoInitializer(node);
                        if (init
                            && (init.kind === SyntaxKind.FunctionExpression
                                || init.kind === SyntaxKind.ArrowFunction))
                        {
                            return getTypeAtFlowNode(flow.antecedent);
                        }
                    }
                    return declaredType;
                }
                // for (const _ in ref) acts as a nonnull on ref
                if (isVariableDeclaration(node)
                    && node.parent.parent.kind === SyntaxKind.ForInStatement
                    && isMatchingReference(
                        reference,
                        node.parent.parent.expression
                    ))
                {
                    return getNonNullableTypeIfNeeded(
                        getTypeFromFlowType(
                            getTypeAtFlowNode(
                                flow.antecedent
                            )
                        )
                    );
                }
                // Assignment doesn't affect reference
                return undefined;
            }

            function narrowTypeByAssertion(type: Type,
                expr: Expression): Type
            {
                const node = skipParentheses(expr);
                if (node.kind === SyntaxKind.FalseKeyword) {
                    return unreachableNeverType;
                }
                if (node.kind === SyntaxKind.BinaryExpression) {
                    if ((<BinaryExpression> node).operatorToken.kind
                        === SyntaxKind.AmpersandAmpersandToken)
                    {
                        return narrowTypeByAssertion(
                            narrowTypeByAssertion(
                                type,
                                (<BinaryExpression> node).left
                            ),
                            (<BinaryExpression> node).right
                        );
                    }
                    if ((<BinaryExpression> node).operatorToken.kind
                        === SyntaxKind.BarBarToken)
                    {
                        return getUnionType(
                            [narrowTypeByAssertion(
                                type,
                                (<BinaryExpression> node).left
                            ), narrowTypeByAssertion(
                                type,
                                (<BinaryExpression> node).right
                            )]
                        );
                    }
                }
                return narrowType(type, node, /*assumeTrue*/ true);
            }

            function getTypeAtFlowCall(flow: FlowCall): FlowType | undefined {
                const signature = getEffectsSignature(flow.node);
                if (signature) {
                    const predicate = getTypePredicateOfSignature(signature);
                    if (predicate
                        && (predicate.kind === TypePredicateKind.AssertsThis
                            || predicate.kind
                            === TypePredicateKind.AssertsIdentifier))
                    {
                        const flowType = getTypeAtFlowNode(flow.antecedent);
                        const type = getTypeFromFlowType(flowType);
                        const narrowedType = predicate.type
                            ? narrowTypeByTypePredicate(
                                type,
                                predicate,
                                flow.node, /*assumeTrue*/
                                true
                            )
                            : predicate.kind
                                === TypePredicateKind.AssertsIdentifier
                                && predicate.parameterIndex >= 0
                                && predicate.parameterIndex
                                < flow.node.arguments.length
                                ? narrowTypeByAssertion(
                                    type,
                                    flow.node.arguments[predicate
                                        .parameterIndex]
                                )
                                : type;
                        return narrowedType === type
                            ? flowType
                            : createFlowType(
                                narrowedType,
                                isIncomplete(flowType)
                            );
                    }
                    if (getReturnTypeOfSignature(signature).flags
                        & TypeFlags.Never)
                    {
                        return unreachableNeverType;
                    }
                }
                return undefined;
            }

            function getTypeAtFlowArrayMutation(
                flow: FlowArrayMutation
            ): FlowType | undefined {
                if (declaredType === autoType
                    || declaredType === autoArrayType)
                {
                    const node = flow.node;
                    const expr = node.kind === SyntaxKind.CallExpression
                        ? (<PropertyAccessExpression> node.expression)
                            .expression
                        : (<ElementAccessExpression> node.left).expression;
                    if (isMatchingReference(
                        reference,
                        getReferenceCandidate(expr)
                    )) {
                        const flowType = getTypeAtFlowNode(flow.antecedent);
                        const type = getTypeFromFlowType(flowType);
                        if (getObjectFlags(type) & ObjectFlags.EvolvingArray) {
                            let evolvedType = <EvolvingArrayType> type;
                            if (node.kind === SyntaxKind.CallExpression) {
                                for (const arg of node.arguments) {
                                    evolvedType = addEvolvingArrayElementType(
                                        evolvedType,
                                        arg
                                    );
                                }
                            } else {
                                // We must get the context free expression type so as to not recur in an uncached fashion on the LHS (which causes exponential blowup in compile time)
                                const indexType = getContextFreeTypeOfExpression(
                                    (<ElementAccessExpression> node.left)
                                        .argumentExpression
                                );
                                if (isTypeAssignableToKind(
                                    indexType,
                                    TypeFlags.NumberLike
                                )) {
                                    evolvedType = addEvolvingArrayElementType(
                                        evolvedType,
                                        node.right
                                    );
                                }
                            }
                            return evolvedType === type
                                ? flowType
                                : createFlowType(
                                    evolvedType,
                                    isIncomplete(flowType)
                                );
                        }
                        return flowType;
                    }
                }
                return undefined;
            }

            function getTypeAtFlowCondition(flow: FlowCondition): FlowType {
                const flowType = getTypeAtFlowNode(flow.antecedent);
                const type = getTypeFromFlowType(flowType);
                if (type.flags & TypeFlags.Never) {
                    return flowType;
                }
                // If we have an antecedent type (meaning we're reachable in some way), we first
                // attempt to narrow the antecedent type. If that produces the never type, and if
                // the antecedent type is incomplete (i.e. a transient type in a loop), then we
                // take the type guard as an indication that control *could* reach here once we
                // have the complete type. We proceed by switching to the silent never type which
                // doesn't report errors when operators are applied to it. Note that this is the
                // *only* place a silent never type is ever generated.
                const assumeTrue = (flow.flags & FlowFlags.TrueCondition)
                    !== 0;
                const nonEvolvingType = finalizeEvolvingArrayType(type);
                const narrowedType = narrowType(
                    nonEvolvingType,
                    flow.node,
                    assumeTrue
                );
                if (narrowedType === nonEvolvingType) {
                    return flowType;
                }
                const incomplete = isIncomplete(flowType);
                const resultType = incomplete
                    && narrowedType.flags & TypeFlags.Never
                    ? silentNeverType
                    : narrowedType;
                return createFlowType(resultType, incomplete);
            }

            function getTypeAtSwitchClause(flow: FlowSwitchClause): FlowType {
                const expr = flow.switchStatement.expression;
                const flowType = getTypeAtFlowNode(flow.antecedent);
                let type = getTypeFromFlowType(flowType);
                if (isMatchingReference(reference, expr)) {
                    type = narrowTypeBySwitchOnDiscriminant(
                        type,
                        flow.switchStatement,
                        flow.clauseStart,
                        flow.clauseEnd
                    );
                } else if (expr.kind === SyntaxKind.TypeOfExpression
                    && isMatchingReference(
                        reference,
                        (expr as TypeOfExpression).expression
                    ))
                {
                    type = narrowBySwitchOnTypeOf(
                        type,
                        flow.switchStatement,
                        flow.clauseStart,
                        flow.clauseEnd
                    );
                } else {
                    if (strictNullChecks) {
                        if (optionalChainContainsReference(expr, reference)) {
                            type = narrowTypeBySwitchOptionalChainContainment(
                                type,
                                flow.switchStatement,
                                flow.clauseStart,
                                flow.clauseEnd,
                                t => !(t.flags
                                    & (TypeFlags.Undefined | TypeFlags.Never))
                            );
                        } else if (expr.kind === SyntaxKind.TypeOfExpression
                            && optionalChainContainsReference(
                                (expr as TypeOfExpression).expression,
                                reference
                            ))
                        {
                            type = narrowTypeBySwitchOptionalChainContainment(
                                type,
                                flow.switchStatement,
                                flow.clauseStart,
                                flow.clauseEnd,
                                t => !(t.flags & TypeFlags.Never
                                    || t.flags & TypeFlags.StringLiteral
                                    && (<StringLiteralType> t).value
                                    === 'undefined')
                            );
                        }
                    }
                    if (isMatchingReferenceDiscriminant(expr, type)) {
                        type = narrowTypeByDiscriminant(
                            type,
                            expr as AccessExpression,
                            t => narrowTypeBySwitchOnDiscriminant(
                                t,
                                flow.switchStatement,
                                flow.clauseStart,
                                flow.clauseEnd
                            )
                        );
                    } else if (containsMatchingReferenceDiscriminant(
                        reference,
                        expr
                    )) {
                        type = declaredType;
                    }
                }
                return createFlowType(type, isIncomplete(flowType));
            }

            function getTypeAtFlowBranchLabel(flow: FlowLabel): FlowType {
                const antecedentTypes: Type[] = [];
                let subtypeReduction = false;
                let seenIncomplete = false;
                let bypassFlow: FlowSwitchClause | undefined;
                for (const antecedent of flow.antecedents!) {
                    if (antecedent.flags & FlowFlags.PreFinally
                        && (<PreFinallyFlow> antecedent).lock.locked)
                    {
                        // if flow correspond to branch from pre-try to finally and this branch is locked - this means that
                        // we initially have started following the flow outside the finally block.
                        // in this case we should ignore this branch.
                        continue;
                    }
                    if (!bypassFlow
                        && antecedent.flags & FlowFlags.SwitchClause
                        && (<FlowSwitchClause> antecedent).clauseStart
                        === (<FlowSwitchClause> antecedent).clauseEnd)
                    {
                        // The antecedent is the bypass branch of a potentially exhaustive switch statement.
                        bypassFlow = <FlowSwitchClause> antecedent;
                        continue;
                    }
                    const flowType = getTypeAtFlowNode(antecedent);
                    const type = getTypeFromFlowType(flowType);
                    // If the type at a particular antecedent path is the declared type and the
                    // reference is known to always be assigned (i.e. when declared and initial types
                    // are the same), there is no reason to process more antecedents since the only
                    // possible outcome is subtypes that will be removed in the final union type anyway.
                    if (type === declaredType
                        && declaredType === initialType)
                    {
                        return type;
                    }
                    pushIfUnique(antecedentTypes, type);
                    // If an antecedent type is not a subset of the declared type, we need to perform
                    // subtype reduction. This happens when a "foreign" type is injected into the control
                    // flow using the instanceof operator or a user defined type predicate.
                    if (!isTypeSubsetOf(type, declaredType)) {
                        subtypeReduction = true;
                    }
                    if (isIncomplete(flowType)) {
                        seenIncomplete = true;
                    }
                }
                if (bypassFlow) {
                    const flowType = getTypeAtFlowNode(bypassFlow);
                    const type = getTypeFromFlowType(flowType);
                    // If the bypass flow contributes a type we haven't seen yet and the switch statement
                    // isn't exhaustive, process the bypass flow type. Since exhaustiveness checks increase
                    // the risk of circularities, we only want to perform them when they make a difference.
                    if (!contains(antecedentTypes, type)
                        && !isExhaustiveSwitchStatement(
                            bypassFlow.switchStatement
                        ))
                    {
                        if (type === declaredType
                            && declaredType === initialType)
                        {
                            return type;
                        }
                        antecedentTypes.push(type);
                        if (!isTypeSubsetOf(type, declaredType)) {
                            subtypeReduction = true;
                        }
                        if (isIncomplete(flowType)) {
                            seenIncomplete = true;
                        }
                    }
                }
                return createFlowType(
                    getUnionOrEvolvingArrayType(
                        antecedentTypes,
                        subtypeReduction
                            ? UnionReduction.Subtype
                            : UnionReduction.Literal
                    ),
                    seenIncomplete
                );
            }

            function getTypeAtFlowLoopLabel(flow: FlowLabel): FlowType {
                // If we have previously computed the control flow type for the reference at
                // this flow loop junction, return the cached type.
                const id = getFlowNodeId(flow);
                const cache = flowLoopCaches[id]
                    || (flowLoopCaches[id] = createMap<Type>());
                const key = getOrSetCacheKey();
                if (!key) {
                    // No cache key is generated when binding patterns are in unnarrowable situations
                    return declaredType;
                }
                const cached = cache.get(key);
                if (cached) {
                    return cached;
                }
                // If this flow loop junction and reference are already being processed, return
                // the union of the types computed for each branch so far, marked as incomplete.
                // It is possible to see an empty array in cases where loops are nested and the
                // back edge of the outer loop reaches an inner loop that is already being analyzed.
                // In such cases we restart the analysis of the inner loop, which will then see
                // a non-empty in-process array for the outer loop and eventually terminate because
                // the first antecedent of a loop junction is always the non-looping control flow
                // path that leads to the top.
                for (let i = flowLoopStart; i < flowLoopCount; i++) {
                    if (flowLoopNodes[i] === flow && flowLoopKeys[i] === key
                        && flowLoopTypes[i].length)
                    {
                        return createFlowType(
                            getUnionOrEvolvingArrayType(
                                flowLoopTypes[i],
                                UnionReduction.Literal
                            ), /*incomplete*/
                            true
                        );
                    }
                }
                // Add the flow loop junction and reference to the in-process stack and analyze
                // each antecedent code path.
                const antecedentTypes: Type[] = [];
                let subtypeReduction = false;
                let firstAntecedentType: FlowType | undefined;
                for (const antecedent of flow.antecedents!) {
                    let flowType;
                    if (!firstAntecedentType) {
                        // The first antecedent of a loop junction is always the non-looping control
                        // flow path that leads to the top.
                        flowType = firstAntecedentType = getTypeAtFlowNode(antecedent);
                    } else {
                        // All but the first antecedent are the looping control flow paths that lead
                        // back to the loop junction. We track these on the flow loop stack.
                        flowLoopNodes[flowLoopCount] = flow;
                        flowLoopKeys[flowLoopCount] = key;
                        flowLoopTypes[flowLoopCount] = antecedentTypes;
                        flowLoopCount++;
                        const saveFlowTypeCache = flowTypeCache;
                        flowTypeCache = undefined;
                        flowType = getTypeAtFlowNode(antecedent);
                        flowTypeCache = saveFlowTypeCache;
                        flowLoopCount--;
                        // If we see a value appear in the cache it is a sign that control flow analysis
                        // was restarted and completed by checkExpressionCached. We can simply pick up
                        // the resulting type and bail out.
                        const cached = cache.get(key);
                        if (cached) {
                            return cached;
                        }
                    }
                    const type = getTypeFromFlowType(flowType);
                    pushIfUnique(antecedentTypes, type);
                    // If an antecedent type is not a subset of the declared type, we need to perform
                    // subtype reduction. This happens when a "foreign" type is injected into the control
                    // flow using the instanceof operator or a user defined type predicate.
                    if (!isTypeSubsetOf(type, declaredType)) {
                        subtypeReduction = true;
                    }
                    // If the type at a particular antecedent path is the declared type there is no
                    // reason to process more antecedents since the only possible outcome is subtypes
                    // that will be removed in the final union type anyway.
                    if (type === declaredType) {
                        break;
                    }
                }
                // The result is incomplete if the first antecedent (the non-looping control flow path)
                // is incomplete.
                const result = getUnionOrEvolvingArrayType(
                    antecedentTypes,
                    subtypeReduction
                        ? UnionReduction.Subtype
                        : UnionReduction.Literal
                );
                if (isIncomplete(firstAntecedentType!)) {
                    return createFlowType(result, /*incomplete*/ true);
                }
                cache.set(key, result);
                return result;
            }

            function isMatchingReferenceDiscriminant(
                expr: Expression,
                computedType: Type
            ) {
                if (!(computedType.flags & TypeFlags.Union)
                    || !isAccessExpression(expr))
                {
                    return false;
                }
                const name = getAccessedPropertyName(expr);
                if (name === undefined) {
                    return false;
                }
                return isMatchingReference(reference, expr.expression)
                    && isDiscriminantProperty(computedType, name);
            }

            function narrowTypeByDiscriminant(
                type: Type,
                access: AccessExpression,
                narrowType: (t: Type) => Type
            ): Type {
                const propName = getAccessedPropertyName(access);
                if (propName === undefined) {
                    return type;
                }
                const propType = getTypeOfPropertyOfType(type, propName);
                if (!propType) {
                    return type;
                }
                const narrowedPropType = narrowType(propType);
                return filterType(
                    type,
                    t => {
                        const discriminantType = getTypeOfPropertyOrIndexSignature(
                            t,
                            propName
                        );
                        return !(discriminantType.flags & TypeFlags.Never)
                            && isTypeComparableTo(
                                discriminantType,
                                narrowedPropType
                            );
                    }
                );
            }

            function narrowTypeByTruthiness(
                type: Type,
                expr: Expression,
                assumeTrue: boolean
            ): Type {
                if (isMatchingReference(reference, expr)) {
                    return getTypeWithFacts(
                        type,
                        assumeTrue ? TypeFacts.Truthy : TypeFacts.Falsy
                    );
                }
                if (strictNullChecks && assumeTrue
                    && optionalChainContainsReference(expr, reference))
                {
                    type = getTypeWithFacts(type, TypeFacts.NEUndefinedOrNull);
                }
                if (isMatchingReferenceDiscriminant(expr, declaredType)) {
                    return narrowTypeByDiscriminant(
                        type,
                        <AccessExpression> expr,
                        t => getTypeWithFacts(
                            t,
                            assumeTrue ? TypeFacts.Truthy : TypeFacts.Falsy
                        )
                    );
                }
                if (containsMatchingReferenceDiscriminant(reference, expr)) {
                    return declaredType;
                }
                return type;
            }

            function isTypePresencePossible(
                type: Type,
                propName: __String,
                assumeTrue: boolean
            ) {
                if (getIndexInfoOfType(type, IndexKind.String)) {
                    return true;
                }
                const prop = getPropertyOfType(type, propName);
                if (prop) {
                    return prop.flags & SymbolFlags.Optional
                        ? true
                        : assumeTrue;
                }
                return !assumeTrue;
            }

            function narrowByInKeyword(
                type: Type,
                literal: LiteralExpression,
                assumeTrue: boolean
            ) {
                if (type.flags & (TypeFlags.Union | TypeFlags.Object)
                    || isThisTypeParameter(type))
                {
                    const propName = escapeLeadingUnderscores(literal.text);
                    return filterType(
                        type,
                        t => isTypePresencePossible(t, propName, assumeTrue)
                    );
                }
                return type;
            }

            function narrowTypeByBinaryExpression(
                type: Type,
                expr: BinaryExpression,
                assumeTrue: boolean
            ): Type {
                switch (expr.operatorToken.kind) {
                    case SyntaxKind.EqualsToken:
                        return narrowTypeByTruthiness(
                            narrowType(
                                type,
                                expr.right,
                                assumeTrue
                            ),
                            expr.left,
                            assumeTrue
                        );
                    case SyntaxKind.EqualsEqualsToken:
                    case SyntaxKind.ExclamationEqualsToken:
                    case SyntaxKind.EqualsEqualsEqualsToken:
                    case SyntaxKind.ExclamationEqualsEqualsToken:
                        const operator = expr.operatorToken.kind;
                        const left = getReferenceCandidate(expr.left);
                        const right = getReferenceCandidate(expr.right);
                        if (left.kind === SyntaxKind.TypeOfExpression
                            && isStringLiteralLike(right))
                        {
                            return narrowTypeByTypeof(
                                type,
                                <TypeOfExpression> left,
                                operator,
                                right,
                                assumeTrue
                            );
                        }
                        if (right.kind === SyntaxKind.TypeOfExpression
                            && isStringLiteralLike(left))
                        {
                            return narrowTypeByTypeof(
                                type,
                                <TypeOfExpression> right,
                                operator,
                                left,
                                assumeTrue
                            );
                        }
                        if (isMatchingReference(reference, left)) {
                            return narrowTypeByEquality(
                                type,
                                operator,
                                right,
                                assumeTrue
                            );
                        }
                        if (isMatchingReference(reference, right)) {
                            return narrowTypeByEquality(
                                type,
                                operator,
                                left,
                                assumeTrue
                            );
                        }
                        if (strictNullChecks) {
                            if (optionalChainContainsReference(left,
                                reference))
                            {
                                type = narrowTypeByOptionalChainContainment(
                                    type,
                                    operator,
                                    right,
                                    assumeTrue
                                );
                            } else if (optionalChainContainsReference(
                                right,
                                reference
                            )) {
                                type = narrowTypeByOptionalChainContainment(
                                    type,
                                    operator,
                                    left,
                                    assumeTrue
                                );
                            }
                        }
                        if (isMatchingReferenceDiscriminant(left,
                            declaredType))
                        {
                            return narrowTypeByDiscriminant(
                                type,
                                <AccessExpression> left,
                                t => narrowTypeByEquality(
                                    t,
                                    operator,
                                    right,
                                    assumeTrue
                                )
                            );
                        }
                        if (isMatchingReferenceDiscriminant(
                            right,
                            declaredType
                        )) {
                            return narrowTypeByDiscriminant(
                                type,
                                <AccessExpression> right,
                                t => narrowTypeByEquality(
                                    t,
                                    operator,
                                    left,
                                    assumeTrue
                                )
                            );
                        }
                        if (containsMatchingReferenceDiscriminant(
                            reference,
                            left
                        )
                            || containsMatchingReferenceDiscriminant(
                                reference,
                                right
                            ))
                        {
                            return declaredType;
                        }
                        break;
                    case SyntaxKind.InstanceOfKeyword:
                        return narrowTypeByInstanceof(type, expr, assumeTrue);
                    case SyntaxKind.InKeyword:
                        const target = getReferenceCandidate(expr.right);
                        if (isStringLiteralLike(expr.left)
                            && isMatchingReference(reference, target))
                        {
                            return narrowByInKeyword(
                                type,
                                expr.left,
                                assumeTrue
                            );
                        }
                        break;
                    case SyntaxKind.CommaToken:
                        return narrowType(type, expr.right, assumeTrue);
                }
                return type;
            }

            function narrowTypeByOptionalChainContainment(
                type: Type,
                operator: SyntaxKind,
                value: Expression,
                assumeTrue: boolean
            ): Type {
                // We are in a branch of obj?.foo === value or obj?.foo !== value. We remove undefined and null from
                // the type of obj if (a) the operator is === and the type of value doesn't include undefined or (b) the
                // operator is !== and the type of value is undefined.
                const effectiveTrue = operator === SyntaxKind.EqualsEqualsToken
                    || operator === SyntaxKind.EqualsEqualsEqualsToken
                    ? assumeTrue
                    : !assumeTrue;
                const doubleEquals = operator === SyntaxKind.EqualsEqualsToken
                    || operator === SyntaxKind.ExclamationEqualsToken;
                const valueNonNullish = !(getTypeFacts(getTypeOfExpression(value))
                    & (doubleEquals
                        ? TypeFacts.EQUndefinedOrNull
                        : TypeFacts.EQUndefined));
                return effectiveTrue === valueNonNullish
                    ? getTypeWithFacts(type, TypeFacts.NEUndefinedOrNull)
                    : type;
            }

            function narrowTypeByEquality(
                type: Type,
                operator: SyntaxKind,
                value: Expression,
                assumeTrue: boolean
            ): Type {
                if (type.flags & TypeFlags.Any) {
                    return type;
                }
                if (operator === SyntaxKind.ExclamationEqualsToken
                    || operator === SyntaxKind.ExclamationEqualsEqualsToken)
                {
                    assumeTrue = !assumeTrue;
                }
                const valueType = getTypeOfExpression(value);
                if ((type.flags & TypeFlags.Unknown) && assumeTrue
                    && (operator === SyntaxKind.EqualsEqualsEqualsToken
                        || operator
                        === SyntaxKind.ExclamationEqualsEqualsToken))
                {
                    if (valueType.flags
                        & (TypeFlags.Primitive | TypeFlags.NonPrimitive))
                    {
                        return valueType;
                    }
                    if (valueType.flags & TypeFlags.Object) {
                        return nonPrimitiveType;
                    }
                    return type;
                }
                if (valueType.flags & TypeFlags.Nullable) {
                    if (!strictNullChecks) {
                        return type;
                    }
                    const doubleEquals = operator
                        === SyntaxKind.EqualsEqualsToken
                        || operator === SyntaxKind.ExclamationEqualsToken;
                    const facts = doubleEquals
                        ? assumeTrue
                            ? TypeFacts.EQUndefinedOrNull
                            : TypeFacts.NEUndefinedOrNull
                        : valueType.flags & TypeFlags.Null
                            ? assumeTrue ? TypeFacts.EQNull : TypeFacts.NENull
                            : assumeTrue ? TypeFacts.EQUndefined
                                : TypeFacts.NEUndefined;
                    return getTypeWithFacts(type, facts);
                }
                if (type.flags & TypeFlags.NotUnionOrUnit) {
                    return type;
                }
                if (assumeTrue) {
                    const narrowedType = filterType(type, filterFn);
                    return narrowedType.flags & TypeFlags.Never
                        ? type
                        : replacePrimitivesWithLiterals(
                            narrowedType,
                            valueType
                        );
                }
                if (isUnitType(valueType)) {
                    const regularType = getRegularTypeOfLiteralType(valueType);
                    return filterType(
                        type,
                        t => getRegularTypeOfLiteralType(t) !== regularType
                    );
                }
                return type;
            }

            function narrowTypeByTypeof(
                type: Type,
                typeOfExpr: TypeOfExpression,
                operator: SyntaxKind,
                literal: LiteralExpression,
                assumeTrue: boolean
            ): Type {
                // We have '==', '!=', '===', or !==' operator with 'typeof xxx' and string literal operands
                if (operator === SyntaxKind.ExclamationEqualsToken
                    || operator === SyntaxKind.ExclamationEqualsEqualsToken)
                {
                    assumeTrue = !assumeTrue;
                }
                const target = getReferenceCandidate(typeOfExpr.expression);
                if (!isMatchingReference(reference, target)) {
                    if (strictNullChecks
                        && optionalChainContainsReference(target, reference)
                        && assumeTrue === (literal.text !== 'undefined'))
                    {
                        return getTypeWithFacts(
                            type,
                            TypeFacts.NEUndefinedOrNull
                        );
                    }
                    // For a reference of the form 'x.y', a 'typeof x === ...' type guard resets the
                    // narrowed type of 'y' to its declared type.
                    if (containsMatchingReference(reference, target)) {
                        return declaredType;
                    }
                    return type;
                }
                if (type.flags & TypeFlags.Any
                    && literal.text === 'function')
                {
                    return type;
                }
                const facts = assumeTrue
                    ? typeofEQFacts.get(literal.text)
                        || TypeFacts.TypeofEQHostObject
                    : typeofNEFacts.get(literal.text)
                        || TypeFacts.TypeofNEHostObject;
                return getTypeWithFacts(
                    assumeTrue
                        ? mapType(type, narrowTypeForTypeof)
                        : type,
                    facts
                );

                function narrowTypeForTypeof(type: Type) {
                    if (type.flags & TypeFlags.Unknown
                        && literal.text === 'object')
                    {
                        return getUnionType([nonPrimitiveType, nullType]);
                    }
                    // We narrow a non-union type to an exact primitive type if the non-union type
                    // is a supertype of that primitive type. For example, type 'any' can be narrowed
                    // to one of the primitive types.
                    const targetType = literal.text === 'function'
                        ? globalFunctionType
                        : typeofTypesByName.get(literal.text);
                    if (targetType) {
                        if (isTypeSubtypeOf(type, targetType)) {
                            return type;
                        }
                        if (isTypeSubtypeOf(targetType, type)) {
                            return targetType;
                        }
                        if (type.flags & TypeFlags.Instantiable) {
                            const constraint = getBaseConstraintOfType(type)
                                || anyType;
                            if (isTypeSubtypeOf(targetType, constraint)) {
                                return getIntersectionType([type, targetType]);
                            }
                        }
                    }
                    return type;
                }
            }

            function narrowTypeBySwitchOptionalChainContainment(
                type: Type,
                switchStatement: SwitchStatement,
                clauseStart: number,
                clauseEnd: number,
                clauseCheck: (type: Type) => boolean
            ) {
                const everyClauseChecks = clauseStart !== clauseEnd
                    && every(
                        getSwitchClauseTypes(switchStatement)
                            .slice(clauseStart, clauseEnd),
                        clauseCheck
                    );
                return everyClauseChecks
                    ? getTypeWithFacts(type, TypeFacts.NEUndefinedOrNull)
                    : type;
            }

            function narrowTypeBySwitchOnDiscriminant(
                type: Type,
                switchStatement: SwitchStatement,
                clauseStart: number,
                clauseEnd: number
            ) {
                // We only narrow if all case expressions specify
                // values with unit types, except for the case where
                // `type` is unknown. In this instance we map object
                // types to the nonPrimitive type and narrow with that.
                const switchTypes = getSwitchClauseTypes(switchStatement);
                if (!switchTypes.length) {
                    return type;
                }
                const clauseTypes = switchTypes.slice(clauseStart, clauseEnd);
                const hasDefaultClause = clauseStart === clauseEnd
                    || contains(clauseTypes, neverType);
                if ((type.flags & TypeFlags.Unknown) && !hasDefaultClause) {
                    let groundClauseTypes: Type[] | undefined;
                    for (let i = 0; i < clauseTypes.length; i += 1) {
                        const t = clauseTypes[i];
                        if (t.flags
                            & (TypeFlags.Primitive | TypeFlags.NonPrimitive))
                        {
                            if (groundClauseTypes !== undefined) {
                                groundClauseTypes.push(t);
                            }
                        } else if (t.flags & TypeFlags.Object) {
                            if (groundClauseTypes === undefined) {
                                groundClauseTypes = clauseTypes.slice(0, i);
                            }
                            groundClauseTypes.push(nonPrimitiveType);
                        } else {
                            return type;
                        }
                    }
                    return getUnionType(
                        groundClauseTypes === undefined
                            ? clauseTypes
                            : groundClauseTypes
                    );
                }
                const discriminantType = getUnionType(clauseTypes);
                const caseType = discriminantType.flags & TypeFlags.Never
                    ? neverType
                    : replacePrimitivesWithLiterals(
                        filterType(
                            type,
                            t => areTypesComparable(discriminantType, t)
                        ),
                        discriminantType
                    );
                if (!hasDefaultClause) {
                    return caseType;
                }
                const defaultType = filterType(
                    type,
                    t => !(isUnitType(t) && contains(
                        switchTypes,
                        getRegularTypeOfLiteralType(t)
                    ))
                );
                return caseType.flags & TypeFlags.Never
                    ? defaultType
                    : getUnionType([caseType, defaultType]);
            }

            function getImpliedTypeFromTypeofCase(type: Type, text: string) {
                switch (text) {
                    case 'function':
                        return type.flags & TypeFlags.Any
                            ? type
                            : globalFunctionType;
                    case 'object':
                        return type.flags & TypeFlags.Unknown
                            ? getUnionType([nonPrimitiveType, nullType])
                            : type;
                    default:
                        return typeofTypesByName.get(text) || type;
                }
            }

            function narrowTypeForTypeofSwitch(candidate: Type) {
                return (type: Type) => {
                    if (isTypeSubtypeOf(candidate, type)) {
                        return candidate;
                    }
                    if (type.flags & TypeFlags.Instantiable) {
                        const constraint = getBaseConstraintOfType(type)
                            || anyType;
                        if (isTypeSubtypeOf(candidate, constraint)) {
                            return getIntersectionType([type, candidate]);
                        }
                    }
                    return type;
                };
            }

            function narrowBySwitchOnTypeOf(
                type: Type,
                switchStatement: SwitchStatement,
                clauseStart: number,
                clauseEnd: number
            ): Type {
                const switchWitnesses = getSwitchClauseTypeOfWitnesses(switchStatement);
                if (!switchWitnesses.length) {
                    return type;
                }
                //  Equal start and end denotes implicit fallthrough; undefined marks explicit default clause
                const defaultCaseLocation = findIndex(
                    switchWitnesses,
                    elem => elem === undefined
                );
                const hasDefaultClause = clauseStart === clauseEnd
                    || (defaultCaseLocation >= clauseStart
                        && defaultCaseLocation < clauseEnd);
                let clauseWitnesses: string[];
                let switchFacts: TypeFacts;
                if (defaultCaseLocation > -1) {
                    // We no longer need the undefined denoting an
                    // explicit default case. Remove the undefined and
                    // fix-up clauseStart and clauseEnd.  This means
                    // that we don't have to worry about undefined
                    // in the witness array.
                    const witnesses = <string[]> switchWitnesses
                        .filter(witness => witness !== undefined);
                    // The adjusted clause start and end after removing the `default` statement.
                    const fixedClauseStart = defaultCaseLocation < clauseStart
                        ? clauseStart - 1
                        : clauseStart;
                    const fixedClauseEnd = defaultCaseLocation < clauseEnd
                        ? clauseEnd - 1
                        : clauseEnd;
                    clauseWitnesses = witnesses.slice(
                        fixedClauseStart,
                        fixedClauseEnd
                    );
                    switchFacts = getFactsFromTypeofSwitch(
                        fixedClauseStart,
                        fixedClauseEnd,
                        witnesses,
                        hasDefaultClause
                    );
                } else {
                    clauseWitnesses = <string[]> switchWitnesses
                        .slice(clauseStart, clauseEnd);
                    switchFacts = getFactsFromTypeofSwitch(
                        clauseStart,
                        clauseEnd,
                        <string[]> switchWitnesses,
                        hasDefaultClause
                    );
                }
                if (hasDefaultClause) {
                    return filterType(
                        type,
                        t => (getTypeFacts(t) & switchFacts) === switchFacts
                    );
                }
                /*
                  The implied type is the raw type suggested by a
                  value being caught in this clause.

                  When the clause contains a default case we ignore
                  the implied type and try to narrow using any facts
                  we can learn: see `switchFacts`.

                  Example:
                  switch (typeof x) {
                      case 'number':
                      case 'string': break;
                      default: break;
                      case 'number':
                      case 'boolean': break
                  }

                  In the first clause (case `number` and `string`) the
                  implied type is number | string.

                  In the default clause we de not compute an implied type.

                  In the third clause (case `number` and `boolean`)
                  the naive implied type is number | boolean, however
                  we use the type facts to narrow the implied type to
                  boolean. We know that number cannot be selected
                  because it is caught in the first clause.
                */
                let impliedType = getTypeWithFacts(
                    getUnionType(
                        clauseWitnesses
                            .map(text => getImpliedTypeFromTypeofCase(type,
                                text))
                    ),
                    switchFacts
                );
                if (impliedType.flags & TypeFlags.Union) {
                    impliedType = getAssignmentReducedType(
                        impliedType as UnionType,
                        getBaseConstraintOrType(type)
                    );
                }
                return getTypeWithFacts(
                    mapType(
                        type,
                        narrowTypeForTypeofSwitch(impliedType)
                    ),
                    switchFacts
                );
            }

            function narrowTypeByInstanceof(
                type: Type,
                expr: BinaryExpression,
                assumeTrue: boolean
            ): Type {
                const left = getReferenceCandidate(expr.left);
                if (!isMatchingReference(reference, left)) {
                    if (assumeTrue && strictNullChecks
                        && optionalChainContainsReference(left, reference))
                    {
                        return getTypeWithFacts(
                            type,
                            TypeFacts.NEUndefinedOrNull
                        );
                    }
                    // For a reference of the form 'x.y', an 'x instanceof T' type guard resets the
                    // narrowed type of 'y' to its declared type. We do this because preceding 'x.y'
                    // references might reference a different 'y' property. However, we make an exception
                    // for property accesses where x is a synthetic 'this' expression, indicating that we
                    // were called from isPropertyInitializedInConstructor. Without this exception,
                    // initializations of 'this' properties that occur before a 'this instanceof XXX'
                    // check would not be considered.
                    if (containsMatchingReference(reference, left)
                        && !isSyntheticThisPropertyAccess(reference))
                    {
                        return declaredType;
                    }
                    return type;
                }

                // Check that right operand is a function type with a prototype property
                const rightType = getTypeOfExpression(expr.right);
                if (!isTypeDerivedFrom(rightType, globalFunctionType)) {
                    return type;
                }

                let targetType: Type | undefined;
                const prototypeProperty = getPropertyOfType(
                    rightType,
                    'prototype' as __String
                );
                if (prototypeProperty) {
                    // Target type is type of the prototype property
                    const prototypePropertyType = getTypeOfSymbol(prototypeProperty);
                    if (!isTypeAny(prototypePropertyType)) {
                        targetType = prototypePropertyType;
                    }
                }

                // Don't narrow from 'any' if the target type is exactly 'Object' or 'Function'
                if (isTypeAny(type)
                    && (targetType === globalObjectType
                        || targetType === globalFunctionType))
                {
                    return type;
                }

                if (!targetType) {
                    const constructSignatures = getSignaturesOfType(
                        rightType,
                        SignatureKind.Construct
                    );
                    targetType = constructSignatures.length
                        ? getUnionType(
                            map(
                                constructSignatures,
                                signature => getReturnTypeOfSignature(getErasedSignature(signature))
                            )
                        )
                        : emptyObjectType;
                }

                return getNarrowedType(
                    type,
                    targetType,
                    assumeTrue,
                    isTypeDerivedFrom
                );
            }

            function getNarrowedType(
                type: Type,
                candidate: Type,
                assumeTrue: boolean,
                isRelated: (source: Type, target: Type) => boolean
            ) {
                if (!assumeTrue) {
                    return filterType(type, t => !isRelated(t, candidate));
                }
                // If the current type is a union type, remove all constituents that couldn't be instances of
                // the candidate type. If one or more constituents remain, return a union of those.
                if (type.flags & TypeFlags.Union) {
                    const assignableType = filterType(
                        type,
                        t => isRelated(t, candidate)
                    );
                    if (!(assignableType.flags & TypeFlags.Never)) {
                        return assignableType;
                    }
                }
                // If the candidate type is a subtype of the target type, narrow to the candidate type.
                // Otherwise, if the target type is assignable to the candidate type, keep the target type.
                // Otherwise, if the candidate type is assignable to the target type, narrow to the candidate
                // type. Otherwise, the types are completely unrelated, so narrow to an intersection of the
                // two types.
                return isTypeSubtypeOf(candidate, type)
                    ? candidate
                    : isTypeAssignableTo(type, candidate)
                        ? type
                        : isTypeAssignableTo(candidate, type)
                            ? candidate
                            : getIntersectionType([type, candidate]);
            }

            function narrowTypeByCallExpression(
                type: Type,
                callExpression: CallExpression,
                assumeTrue: boolean
            ): Type {
                if (hasMatchingArgument(callExpression, reference)) {
                    const signature = assumeTrue
                        || !isCallChain(callExpression)
                        ? getEffectsSignature(callExpression)
                        : undefined;
                    const predicate = signature
                        && getTypePredicateOfSignature(signature);
                    if (predicate
                        && (predicate.kind === TypePredicateKind.This
                            || predicate.kind
                            === TypePredicateKind.Identifier))
                    {
                        return narrowTypeByTypePredicate(
                            type,
                            predicate,
                            callExpression,
                            assumeTrue
                        );
                    }
                }
                return type;
            }

            function narrowTypeByTypePredicate(
                type: Type,
                predicate: TypePredicate,
                callExpression: CallExpression,
                assumeTrue: boolean
            ): Type {
                // Don't narrow from 'any' if the predicate type is exactly 'Object' or 'Function'
                if (predicate.type
                    && !(isTypeAny(type)
                        && (predicate.type === globalObjectType
                            || predicate.type === globalFunctionType)))
                {
                    const predicateArgument = getTypePredicateArgument(
                        predicate,
                        callExpression
                    );
                    if (predicateArgument) {
                        if (isMatchingReference(reference,
                            predicateArgument))
                        {
                            return getNarrowedType(
                                type,
                                predicate.type,
                                assumeTrue,
                                isTypeSubtypeOf
                            );
                        }
                        if (strictNullChecks && assumeTrue
                            && optionalChainContainsReference(
                                predicateArgument,
                                reference
                            )
                            && !(getTypeFacts(predicate.type)
                                & TypeFacts.EQUndefined))
                        {
                            return getTypeWithFacts(
                                type,
                                TypeFacts.NEUndefinedOrNull
                            );
                        }
                        if (containsMatchingReference(
                            reference,
                            predicateArgument
                        )) {
                            return declaredType;
                        }
                    }
                }
                return type;
            }

            // Narrow the given type based on the given expression having the assumed boolean value. The returned type
            // will be a subtype or the same type as the argument.
            function narrowType(
                type: Type,
                expr: Expression,
                assumeTrue: boolean
            ): Type {
                // for `a?.b`, we emulate a synthetic `a !== null && a !== undefined` condition for `a`
                if (isExpressionOfOptionalChainRoot(expr)
                    || isBinaryExpression(expr.parent)
                    && expr.parent.operatorToken.kind
                    === SyntaxKind.QuestionQuestionToken
                    && expr.parent.left === expr)
                {
                    return narrowTypeByOptionality(type, expr, assumeTrue);
                }
                switch (expr.kind) {
                    case SyntaxKind.Identifier:
                    case SyntaxKind.ThisKeyword:
                    case SyntaxKind.SuperKeyword:
                    case SyntaxKind.PropertyAccessExpression:
                    case SyntaxKind.ElementAccessExpression:
                        return narrowTypeByTruthiness(type, expr, assumeTrue);
                    case SyntaxKind.CallExpression:
                        return narrowTypeByCallExpression(
                            type,
                            <CallExpression> expr,
                            assumeTrue
                        );
                    case SyntaxKind.ParenthesizedExpression:
                        return narrowType(
                            type,
                            (<ParenthesizedExpression> expr).expression,
                            assumeTrue
                        );
                    case SyntaxKind.BinaryExpression:
                        return narrowTypeByBinaryExpression(
                            type,
                            <BinaryExpression> expr,
                            assumeTrue
                        );
                    case SyntaxKind.PrefixUnaryExpression:
                        if ((<PrefixUnaryExpression> expr).operator
                            === SyntaxKind.ExclamationToken)
                        {
                            return narrowType(
                                type,
                                (<PrefixUnaryExpression> expr).operand,
                                !assumeTrue
                            );
                        }
                        break;
                }
                return type;
            }

            function narrowTypeByOptionality(
                type: Type,
                expr: Expression,
                assumePresent: boolean
            ): Type {
                if (isMatchingReference(reference, expr)) {
                    return getTypeWithFacts(
                        type,
                        assumePresent
                            ? TypeFacts.NEUndefinedOrNull
                            : TypeFacts.EQUndefinedOrNull
                    );
                }
                if (isMatchingReferenceDiscriminant(expr, declaredType)) {
                    return narrowTypeByDiscriminant(
                        type,
                        <AccessExpression> expr,
                        t => getTypeWithFacts(
                            t,
                            assumePresent
                                ? TypeFacts.NEUndefinedOrNull
                                : TypeFacts.EQUndefinedOrNull
                        )
                    );
                }
                if (containsMatchingReferenceDiscriminant(reference, expr)) {
                    return declaredType;
                }
                return type;
            }
        }

        function getTypeOfSymbolAtLocation(symbol: Symbol, location: Node) {
            symbol = symbol.exportSymbol || symbol;

            // If we have an identifier or a property access at the given location, if the location is
            // an dotted name expression, and if the location is not an assignment target, obtain the type
            // of the expression (which will reflect control flow analysis). If the expression indeed
            // resolved to the given symbol, return the narrowed type.
            if (location.kind === SyntaxKind.Identifier) {
                if (isRightSideOfQualifiedNameOrPropertyAccess(location)) {
                    location = location.parent;
                }
                if (isExpressionNode(location)
                    && !isAssignmentTarget(location))
                {
                    const type = getTypeOfExpression(<Expression> location);
                    if (getExportSymbolOfValueSymbolIfExported(
                        getNodeLinks(location).resolvedSymbol
                    ) === symbol) {
                        return type;
                    }
                }
            }
            // The location isn't a reference to the given symbol, meaning we're being asked
            // a hypothetical question of what type the symbol would have if there was a reference
            // to it at the given location. Since we have no control flow information for the
            // hypothetical reference (control flow information is created and attached by the
            // binder), we simply return the declared type of the symbol.
            return getTypeOfSymbol(symbol);
        }

        function getControlFlowContainer(node: Node): Node {
            return findAncestor(
                node.parent,
                node => isFunctionLike(node)
                    && !getImmediatelyInvokedFunctionExpression(node)
                    || node.kind === SyntaxKind.ModuleBlock
                    || node.kind === SyntaxKind.SourceFile
                    || node.kind === SyntaxKind.PropertyDeclaration
            )!;
        }

        // Check if a parameter is assigned anywhere within its declaring function.
        function isParameterAssigned(symbol: Symbol) {
            const func = <FunctionLikeDeclaration> getRootDeclaration(
                symbol.valueDeclaration
            ).parent;
            const links = getNodeLinks(func);
            if (!(links.flags & NodeCheckFlags.AssignmentsMarked)) {
                links.flags |= NodeCheckFlags.AssignmentsMarked;
                if (!hasParentWithAssignmentsMarked(func)) {
                    markParameterAssignments(func);
                }
            }
            return symbol.isAssigned || false;
        }

        function hasParentWithAssignmentsMarked(node: Node) {
            return !!findAncestor(
                node.parent,
                node => isFunctionLike(node)
                    && !!(getNodeLinks(node).flags
                        & NodeCheckFlags.AssignmentsMarked)
            );
        }

        function markParameterAssignments(node: Node) {
            if (node.kind === SyntaxKind.Identifier) {
                if (isAssignmentTarget(node)) {
                    const symbol = getResolvedSymbol(<Identifier> node);
                    if (symbol.valueDeclaration
                        && getRootDeclaration(symbol.valueDeclaration).kind
                        === SyntaxKind.Parameter)
                    {
                        symbol.isAssigned = true;
                    }
                }
            } else {
                forEachChild(node, markParameterAssignments);
            }
        }

        function isConstVariable(symbol: Symbol) {
            return symbol.flags & SymbolFlags.Variable
                && (getDeclarationNodeFlagsFromSymbol(symbol)
                    & NodeFlags.Const) !== 0
                && getTypeOfSymbol(symbol) !== autoArrayType;
        }

        /** remove undefined from the annotated type of a parameter when there is an initializer (that doesn't include undefined) */
        function removeOptionalityFromDeclaredType(
            declaredType: Type,
            declaration: VariableLikeDeclaration
        ): Type {
            const annotationIncludesUndefined = strictNullChecks
                && declaration.kind === SyntaxKind.Parameter
                && declaration.initializer
                && getFalsyFlags(declaredType) & TypeFlags.Undefined
                && !(getFalsyFlags(checkExpression(declaration.initializer))
                    & TypeFlags.Undefined);
            return annotationIncludesUndefined
                ? getTypeWithFacts(declaredType, TypeFacts.NEUndefined)
                : declaredType;
        }

        function isConstraintPosition(node: Node) {
            const parent = node.parent;
            return parent.kind === SyntaxKind.PropertyAccessExpression
                || parent.kind === SyntaxKind.CallExpression
                && (<CallExpression> parent).expression === node
                || parent.kind === SyntaxKind.ElementAccessExpression
                && (<ElementAccessExpression> parent).expression === node
                || parent.kind === SyntaxKind.BindingElement
                && (<BindingElement> parent).name === node
                && !!(<BindingElement> parent).initializer;
        }

        function typeHasNullableConstraint(type: Type) {
            return type.flags & TypeFlags.InstantiableNonPrimitive
                && maybeTypeOfKind(
                    getBaseConstraintOfType(type) || unknownType,
                    TypeFlags.Nullable
                );
        }

        function getConstraintForLocation(type: Type, node: Node): Type;
        function getConstraintForLocation(
            type: Type | undefined,
            node: Node
        ): Type | undefined;
        function getConstraintForLocation(
            type: Type,
            node: Node
        ): Type | undefined {
            // When a node is the left hand expression of a property access, element access, or call expression,
            // and the type of the node includes type variables with constraints that are nullable, we fetch the
            // apparent type of the node *before* performing control flow analysis such that narrowings apply to
            // the constraint type.
            if (type && isConstraintPosition(node)
                && forEachType(type, typeHasNullableConstraint))
            {
                return mapType(getWidenedType(type), getBaseConstraintOrType);
            }
            return type;
        }

        function isExportOrExportExpression(location: Node) {
            return !!findAncestor(
                location,
                e => e.parent && isExportAssignment(e.parent)
                    && e.parent.expression === e && isEntityNameExpression(e)
            );
        }

        function markAliasReferenced(symbol: Symbol, location: Node) {
            if (isNonLocalAlias(symbol, /*excludes*/ SymbolFlags.Value)
                && !isInTypeQuery(location)
                && ((compilerOptions.preserveConstEnums
                    && isExportOrExportExpression(location))
                    || !isConstEnumOrConstEnumOnlyModule(resolveAlias(symbol))))
            {
                markAliasSymbolAsReferenced(symbol);
            }
        }

        function checkIdentifier(node: Identifier): Type {
            const symbol = getResolvedSymbol(node);
            if (symbol === unknownSymbol) {
                return errorType;
            }

            // As noted in ECMAScript 6 language spec, arrow functions never have an arguments objects.
            // Although in down-level emit of arrow function, we emit it using function expression which means that
            // arguments objects will be bound to the inner object; emitting arrow function natively in ES6, arguments objects
            // will be bound to non-arrow function that contain this arrow function. This results in inconsistent behavior.
            // To avoid that we will give an error to users if they use arguments objects in arrow function so that they
            // can explicitly bound arguments objects
            if (symbol === argumentsSymbol) {
                const container = getContainingFunction(node)!;
                if (languageVersion < ScriptTarget.ES2015) {
                    if (container.kind === SyntaxKind.ArrowFunction) {
                        error(
                            node,
                            Diagnostics
                                .The_arguments_object_cannot_be_referenced_in_an_arrow_function_in_ES3_and_ES5_Consider_using_a_standard_function_expression
                        );
                    } else if (hasModifier(container, ModifierFlags.Async)) {
                        error(
                            node,
                            Diagnostics
                                .The_arguments_object_cannot_be_referenced_in_an_async_function_or_method_in_ES3_and_ES5_Consider_using_a_standard_function_or_method
                        );
                    }
                }

                getNodeLinks(container).flags |= NodeCheckFlags
                    .CaptureArguments;
                return getTypeOfSymbol(symbol);
            }

            // We should only mark aliases as referenced if there isn't a local value declaration
            // for the symbol. Also, don't mark any property access expression LHS - checkPropertyAccessExpression will handle that
            if (!(node.parent && isPropertyAccessExpression(node.parent)
                && node.parent.expression === node))
            {
                markAliasReferenced(symbol, node);
            }

            const localOrExportSymbol = getExportSymbolOfValueSymbolIfExported(symbol);
            let declaration: Declaration | undefined = localOrExportSymbol
                .valueDeclaration;

            if (localOrExportSymbol.flags & SymbolFlags.Class) {
                // Due to the emit for class decorators, any reference to the class from inside of the class body
                // must instead be rewritten to point to a temporary variable to avoid issues with the double-bind
                // behavior of class names in ES6.
                if (declaration.kind === SyntaxKind.ClassDeclaration
                    && nodeIsDecorated(declaration as ClassDeclaration))
                {
                    let container = getContainingClass(node);
                    while (container !== undefined) {
                        if (container === declaration
                            && container.name !== node)
                        {
                            getNodeLinks(declaration).flags |= NodeCheckFlags
                                .ClassWithConstructorReference;
                            getNodeLinks(node).flags |= NodeCheckFlags
                                .ConstructorReferenceInClass;
                            break;
                        }

                        container = getContainingClass(container);
                    }
                } else if (declaration.kind === SyntaxKind.ClassExpression) {
                    // When we emit a class expression with static members that contain a reference
                    // to the constructor in the initializer, we will need to substitute that
                    // binding with an alias as the class name is not in scope.
                    let container = getThisContainer(
                        node, /*includeArrowFunctions*/
                        false
                    );
                    while (container.kind !== SyntaxKind.SourceFile) {
                        if (container.parent === declaration) {
                            if (container.kind
                                === SyntaxKind.PropertyDeclaration
                                && hasModifier(container,
                                    ModifierFlags.Static))
                            {
                                getNodeLinks(declaration)
                                    .flags |= NodeCheckFlags
                                        .ClassWithConstructorReference;
                                getNodeLinks(node).flags |= NodeCheckFlags
                                    .ConstructorReferenceInClass;
                            }
                            break;
                        }

                        container = getThisContainer(
                            container, /*includeArrowFunctions*/
                            false
                        );
                    }
                }
            }

            checkNestedBlockScopedBinding(node, symbol);

            const type = getConstraintForLocation(
                getTypeOfSymbol(localOrExportSymbol),
                node
            );
            const assignmentKind = getAssignmentTargetKind(node);

            if (assignmentKind) {
                if (!(localOrExportSymbol.flags & SymbolFlags.Variable)
                    && !(isInJSFile(node)
                        && localOrExportSymbol.flags
                        & SymbolFlags.ValueModule))
                {
                    error(
                        node,
                        Diagnostics
                            .Cannot_assign_to_0_because_it_is_not_a_variable,
                        symbolToString(symbol)
                    );
                    return errorType;
                }
                if (isReadonlySymbol(localOrExportSymbol)) {
                    if (localOrExportSymbol.flags & SymbolFlags.Variable) {
                        error(
                            node,
                            Diagnostics
                                .Cannot_assign_to_0_because_it_is_a_constant,
                            symbolToString(symbol)
                        );
                    } else {
                        error(
                            node,
                            Diagnostics
                                .Cannot_assign_to_0_because_it_is_a_read_only_property,
                            symbolToString(symbol)
                        );
                    }
                    return errorType;
                }
            }

            const isAlias = localOrExportSymbol.flags & SymbolFlags.Alias;

            // We only narrow variables and parameters occurring in a non-assignment position. For all other
            // entities we simply return the declared type.
            if (localOrExportSymbol.flags & SymbolFlags.Variable) {
                if (assignmentKind === AssignmentKind.Definite) {
                    return type;
                }
            } else if (isAlias) {
                declaration = find<Declaration>(
                    symbol.declarations,
                    isSomeImportDeclaration
                );
            } else {
                return type;
            }

            if (!declaration) {
                return type;
            }

            // The declaration container is the innermost function that encloses the declaration of the variable
            // or parameter. The flow container is the innermost function starting with which we analyze the control
            // flow graph to determine the control flow based type.
            const isParameter = getRootDeclaration(declaration).kind
                === SyntaxKind.Parameter;
            const declarationContainer = getControlFlowContainer(declaration);
            let flowContainer = getControlFlowContainer(node);
            const isOuterVariable = flowContainer !== declarationContainer;
            const isSpreadDestructuringAssignmentTarget = node.parent
                && node.parent.parent && isSpreadAssignment(node.parent)
                && isDestructuringAssignmentTarget(node.parent.parent);
            const isModuleExports = symbol.flags & SymbolFlags.ModuleExports;
            // When the control flow originates in a function expression or arrow function and we are referencing
            // a const variable or parameter from an outer function, we extend the origin of the control flow
            // analysis to include the immediately enclosing function.
            while (flowContainer !== declarationContainer
                && (flowContainer.kind === SyntaxKind.FunctionExpression
                    || flowContainer.kind === SyntaxKind.ArrowFunction
                    || isObjectLiteralOrClassExpressionMethod(flowContainer))
                && (isConstVariable(localOrExportSymbol) || isParameter
                    && !isParameterAssigned(localOrExportSymbol)))
            {
                flowContainer = getControlFlowContainer(flowContainer);
            }
            // We only look for uninitialized variables in strict null checking mode, and only when we can analyze
            // the entire control flow graph from the variable's declaration (i.e. when the flow container and
            // declaration container are the same).
            const assumeInitialized = isParameter || isAlias || isOuterVariable
                || isSpreadDestructuringAssignmentTarget || isModuleExports
                || isBindingElement(declaration)
                || type !== autoType && type !== autoArrayType
                && (!strictNullChecks
                    || (type.flags & (TypeFlags.AnyOrUnknown | TypeFlags.Void))
                    !== 0
                    || isInTypeQuery(node)
                    || node.parent.kind === SyntaxKind.ExportSpecifier)
                || node.parent.kind === SyntaxKind.NonNullExpression
                || declaration.kind === SyntaxKind.VariableDeclaration
                && (<VariableDeclaration> declaration).exclamationToken
                || declaration.flags & NodeFlags.Ambient;
            const initialType = assumeInitialized
                ? (isParameter
                    ? removeOptionalityFromDeclaredType(
                        type,
                        declaration as VariableLikeDeclaration
                    )
                    : type)
                : type === autoType || type === autoArrayType
                    ? undefinedType
                    : getOptionalType(type);
            const flowType = getFlowTypeOfReference(
                node,
                type,
                initialType,
                flowContainer,
                !assumeInitialized
            );
            // A variable is considered uninitialized when it is possible to analyze the entire control flow graph
            // from declaration to use, and when the variable's declared type doesn't include undefined but the
            // control flow based type does include undefined.
            if (!isEvolvingArrayOperationTarget(node)
                && (type === autoType || type === autoArrayType))
            {
                if (flowType === autoType || flowType === autoArrayType) {
                    if (noImplicitAny) {
                        error(
                            getNameOfDeclaration(declaration),
                            Diagnostics
                                .Variable_0_implicitly_has_type_1_in_some_locations_where_its_type_cannot_be_determined,
                            symbolToString(symbol),
                            typeToString(flowType)
                        );
                        error(
                            node,
                            Diagnostics.Variable_0_implicitly_has_an_1_type,
                            symbolToString(symbol),
                            typeToString(flowType)
                        );
                    }
                    return convertAutoToAny(flowType);
                }
            } else if (!assumeInitialized
                && !(getFalsyFlags(type) & TypeFlags.Undefined)
                && getFalsyFlags(flowType) & TypeFlags.Undefined)
            {
                const diag = error(
                    node,
                    Diagnostics.Variable_0_is_used_before_being_assigned,
                    symbolToString(symbol)
                );

                // See GH:32846 - if the user is using a variable whose type is () => T1 | ... | undefined
                // they may have meant to specify the type as (() => T1 | ...) | undefined
                // This is assumed if: the type is a FunctionType, the return type is a Union, the last constituent of
                // the union is `undefined`
                if (type.symbol && type.symbol.declarations.length === 1
                    && isFunctionTypeNode(type.symbol.declarations[0]))
                {
                    const funcTypeNode = <FunctionTypeNode> type.symbol
                        .declarations[0];
                    const returnType = getReturnTypeFromAnnotation(funcTypeNode);
                    if (returnType && returnType.flags & TypeFlags.Union) {
                        const unionTypes = (<UnionTypeNode> funcTypeNode.type)
                            .types;
                        if (unionTypes
                            && unionTypes[unionTypes.length - 1].kind
                            === SyntaxKind.UndefinedKeyword)
                        {
                            const parenedFuncType = getMutableClone(funcTypeNode);
                            // Highlight to the end of the second to last constituent of the union
                            parenedFuncType.end = unionTypes[unionTypes.length
                                - 2].end;
                            addRelatedInfo(
                                diag,
                                createDiagnosticForNode(
                                    parenedFuncType,
                                    Diagnostics
                                        .Did_you_mean_to_parenthesize_this_function_type
                                )
                            );
                        }
                    }
                }

                // Return the declared type to reduce follow-on errors
                return type;
            }
            return assignmentKind
                ? getBaseTypeOfLiteralType(flowType)
                : flowType;
        }

        function isInsideFunction(node: Node, threshold: Node): boolean {
            return !!findAncestor(
                node,
                n => n === threshold ? 'quit' : isFunctionLike(n)
            );
        }

        function getPartOfForStatementContainingNode(
            node: Node,
            container: ForStatement
        ) {
            return findAncestor(
                node,
                n => n === container
                    ? 'quit'
                    : n === container.initializer || n === container.condition
                        || n === container.incrementor
                        || n === container.statement
            );
        }

        function checkNestedBlockScopedBinding(
            node: Identifier,
            symbol: Symbol
        ): void {
            if (languageVersion >= ScriptTarget.ES2015
                || (symbol.flags
                    & (SymbolFlags.BlockScopedVariable | SymbolFlags.Class))
                === 0
                || isSourceFile(symbol.valueDeclaration)
                || symbol.valueDeclaration.parent.kind
                === SyntaxKind.CatchClause)
            {
                return;
            }

            // 1. walk from the use site up to the declaration and check
            // if there is anything function like between declaration and use-site (is binding/class is captured in function).
            // 2. walk from the declaration up to the boundary of lexical environment and check
            // if there is an iteration statement in between declaration and boundary (is binding/class declared inside iteration statement)

            const container = getEnclosingBlockScopeContainer(
                symbol.valueDeclaration
            );
            const usedInFunction = isInsideFunction(node.parent, container);
            let current = container;

            let containedInIterationStatement = false;
            while (current && !nodeStartsNewLexicalEnvironment(current)) {
                if (isIterationStatement(
                    current, /*lookInLabeledStatements*/
                    false
                )) {
                    containedInIterationStatement = true;
                    break;
                }
                current = current.parent;
            }

            if (containedInIterationStatement) {
                if (usedInFunction) {
                    // mark iteration statement as containing block-scoped binding captured in some function
                    let capturesBlockScopeBindingInLoopBody = true;
                    if (isForStatement(container)) {
                        const varDeclList = getAncestor(
                            symbol.valueDeclaration,
                            SyntaxKind.VariableDeclarationList
                        );
                        if (varDeclList && varDeclList.parent === container) {
                            const part = getPartOfForStatementContainingNode(
                                node.parent,
                                container
                            );
                            if (part) {
                                const links = getNodeLinks(part);
                                links.flags |= NodeCheckFlags
                                    .ContainsCapturedBlockScopeBinding;

                                const capturedBindings = links
                                    .capturedBlockScopeBindings
                                    || (links.capturedBlockScopeBindings = []);
                                pushIfUnique(capturedBindings, symbol);

                                if (part === container.initializer) {
                                    capturesBlockScopeBindingInLoopBody = false; // Initializer is outside of loop body
                                }
                            }
                        }
                    }
                    if (capturesBlockScopeBindingInLoopBody) {
                        getNodeLinks(current).flags |= NodeCheckFlags
                            .LoopWithCapturedBlockScopedBinding;
                    }
                }

                // mark variables that are declared in loop initializer and reassigned inside the body of ForStatement.
                // if body of ForStatement will be converted to function then we'll need a extra machinery to propagate reassigned values back.
                if (isForStatement(container)) {
                    const varDeclList = getAncestor(
                        symbol.valueDeclaration,
                        SyntaxKind.VariableDeclarationList
                    );
                    if (varDeclList && varDeclList.parent === container
                        && isAssignedInBodyOfForStatement(node, container))
                    {
                        getNodeLinks(symbol.valueDeclaration)
                            .flags |= NodeCheckFlags.NeedsLoopOutParameter;
                    }
                }

                // set 'declared inside loop' bit on the block-scoped binding
                getNodeLinks(symbol.valueDeclaration).flags |= NodeCheckFlags
                    .BlockScopedBindingInLoop;
            }

            if (usedInFunction) {
                getNodeLinks(symbol.valueDeclaration).flags |= NodeCheckFlags
                    .CapturedBlockScopedBinding;
            }
        }

        function isBindingCapturedByNode(
            node: Node,
            decl: VariableDeclaration | BindingElement
        ) {
            const links = getNodeLinks(node);
            return !!links
                && contains(
                    links.capturedBlockScopeBindings,
                    getSymbolOfNode(decl)
                );
        }

        function isAssignedInBodyOfForStatement(
            node: Identifier,
            container: ForStatement
        ): boolean {
            // skip parenthesized nodes
            let current: Node = node;
            while (current.parent.kind
                === SyntaxKind.ParenthesizedExpression)
            {
                current = current.parent;
            }

            // check if node is used as LHS in some assignment expression
            let isAssigned = false;
            if (isAssignmentTarget(current)) {
                isAssigned = true;
            } else if ((current.parent.kind
                === SyntaxKind.PrefixUnaryExpression
                || current.parent.kind === SyntaxKind.PostfixUnaryExpression))
            {
                const expr = <PrefixUnaryExpression
                    | PostfixUnaryExpression> current.parent;
                isAssigned = expr.operator === SyntaxKind.PlusPlusToken
                    || expr.operator === SyntaxKind.MinusMinusToken;
            }

            if (!isAssigned) {
                return false;
            }

            // at this point we know that node is the target of assignment
            // now check that modification happens inside the statement part of the ForStatement
            return !!findAncestor(
                current,
                n => n === container ? 'quit' : n === container.statement
            );
        }

        function captureLexicalThis(node: Node, container: Node): void {
            getNodeLinks(node).flags |= NodeCheckFlags.LexicalThis;
            if (container.kind === SyntaxKind.PropertyDeclaration
                || container.kind === SyntaxKind.Constructor)
            {
                const classNode = container.parent;
                getNodeLinks(classNode).flags |= NodeCheckFlags.CaptureThis;
            } else {
                getNodeLinks(container).flags |= NodeCheckFlags.CaptureThis;
            }
        }

        function findFirstSuperCall(n: Node): SuperCall | undefined {
            if (isSuperCall(n)) {
                return n;
            } else if (isFunctionLike(n)) {
                return undefined;
            }
            return forEachChild(n, findFirstSuperCall);
        }

        /**
         * Return a cached result if super-statement is already found.
         * Otherwise, find a super statement in a given constructor function and cache the result in the node-links of the constructor
         *
         * @param constructor constructor-function to look for super statement
         */
        function getSuperCallInConstructor(
            constructor: ConstructorDeclaration
        ): SuperCall | undefined {
            const links = getNodeLinks(constructor);

            // Only trying to find super-call if we haven't yet tried to find one.  Once we try, we will record the result
            if (links.hasSuperCall === undefined) {
                links.superCall = findFirstSuperCall(constructor.body!);
                links.hasSuperCall = links.superCall ? true : false;
            }
            return links.superCall!;
        }

        /**
         * Check if the given class-declaration extends null then return true.
         * Otherwise, return false
         * @param classDecl a class declaration to check if it extends null
         */
        function classDeclarationExtendsNull(
            classDecl: ClassDeclaration
        ): boolean {
            const classSymbol = getSymbolOfNode(classDecl);
            const classInstanceType = <InterfaceType> getDeclaredTypeOfSymbol(classSymbol);
            const baseConstructorType = getBaseConstructorTypeOfClass(classInstanceType);

            return baseConstructorType === nullWideningType;
        }

        function checkThisBeforeSuper(
            node: Node,
            container: Node,
            diagnosticMessage: DiagnosticMessage
        ) {
            const containingClassDecl = <ClassDeclaration> container.parent;
            const baseTypeNode = getClassExtendsHeritageElement(containingClassDecl);

            // If a containing class does not have extends clause or the class extends null
            // skip checking whether super statement is called before "this" accessing.
            if (baseTypeNode
                && !classDeclarationExtendsNull(containingClassDecl))
            {
                const superCall = getSuperCallInConstructor(<ConstructorDeclaration> container);

                // We should give an error in the following cases:
                //      - No super-call
                //      - "this" is accessing before super-call.
                //          i.e super(this)
                //              this.x; super();
                // We want to make sure that super-call is done before accessing "this" so that
                // "this" is not accessed as a parameter of the super-call.
                if (!superCall || superCall.end > node.pos) {
                    // In ES6, super inside constructor of class-declaration has to precede "this" accessing
                    error(node, diagnosticMessage);
                }
            }
        }

        function checkThisExpression(node: Node): Type {
            // Stop at the first arrow function so that we can
            // tell whether 'this' needs to be captured.
            let container = getThisContainer(
                node, /* includeArrowFunctions */
                true
            );
            let capturedByArrowFunction = false;

            if (container.kind === SyntaxKind.Constructor) {
                checkThisBeforeSuper(
                    node,
                    container,
                    Diagnostics
                        .super_must_be_called_before_accessing_this_in_the_constructor_of_a_derived_class
                );
            }

            // Now skip arrow functions to get the "real" owner of 'this'.
            if (container.kind === SyntaxKind.ArrowFunction) {
                container = getThisContainer(
                    container, /* includeArrowFunctions */
                    false
                );
                capturedByArrowFunction = true;
            }

            switch (container.kind) {
                case SyntaxKind.ModuleDeclaration:
                    error(
                        node,
                        Diagnostics
                            .this_cannot_be_referenced_in_a_module_or_namespace_body
                    );
                    // do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks
                    break;
                case SyntaxKind.EnumDeclaration:
                    error(
                        node,
                        Diagnostics
                            .this_cannot_be_referenced_in_current_location
                    );
                    // do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks
                    break;
                case SyntaxKind.Constructor:
                    if (isInConstructorArgumentInitializer(node, container)) {
                        error(
                            node,
                            Diagnostics
                                .this_cannot_be_referenced_in_constructor_arguments
                        );
                        // do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks
                    }
                    break;
                case SyntaxKind.PropertyDeclaration:
                case SyntaxKind.PropertySignature:
                    if (hasModifier(container, ModifierFlags.Static)) {
                        error(
                            node,
                            Diagnostics
                                .this_cannot_be_referenced_in_a_static_property_initializer
                        );
                        // do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks
                    }
                    break;
                case SyntaxKind.ComputedPropertyName:
                    error(
                        node,
                        Diagnostics
                            .this_cannot_be_referenced_in_a_computed_property_name
                    );
                    break;
            }

            // When targeting es6, mark that we'll need to capture `this` in its lexically bound scope.
            if (capturedByArrowFunction
                && languageVersion < ScriptTarget.ES2015)
            {
                captureLexicalThis(node, container);
            }

            const type = tryGetThisTypeAt(
                node, /*includeGlobalThis*/
                true,
                container
            );
            if (noImplicitThis) {
                const globalThisType = getTypeOfSymbol(globalThisSymbol);
                if (type === globalThisType && capturedByArrowFunction) {
                    error(
                        node,
                        Diagnostics
                            .The_containing_arrow_function_captures_the_global_value_of_this
                    );
                } else if (!type) {
                    // With noImplicitThis, functions may not reference 'this' if it has type 'any'
                    const diag = error(
                        node,
                        Diagnostics
                            .this_implicitly_has_type_any_because_it_does_not_have_a_type_annotation
                    );
                    if (!isSourceFile(container)) {
                        const outsideThis = tryGetThisTypeAt(container);
                        if (outsideThis && outsideThis !== globalThisType) {
                            addRelatedInfo(
                                diag,
                                createDiagnosticForNode(
                                    container,
                                    Diagnostics
                                        .An_outer_value_of_this_is_shadowed_by_this_container
                                )
                            );
                        }
                    }
                }
            }
            return type || anyType;
        }

        function tryGetThisTypeAt(
            node: Node,
            includeGlobalThis = true,
            container = getThisContainer(node, false)
        ): /*includeArrowFunctions*/ Type | undefined {
            const isInJS = isInJSFile(node);
            if (isFunctionLike(container)
                && (!isInParameterInitializerBeforeContainingFunction(node)
                    || getThisParameter(container)))
            {
                // Note: a parameter initializer should refer to class-this unless function-this is explicitly annotated.
                // If this is a function in a JS file, it might be a class method.
                const className = getClassNameFromPrototypeMethod(container);
                if (isInJS && className) {
                    const classSymbol = checkExpression(className).symbol;
                    if (classSymbol && classSymbol.members
                        && (classSymbol.flags & SymbolFlags.Function))
                    {
                        const classType = (getDeclaredTypeOfSymbol(classSymbol) as InterfaceType)
                            .thisType!;
                        return getFlowTypeOfReference(node, classType);
                    }
                } // Check if it's a constructor definition, can be either a variable decl or function decl
                // i.e.
                //   * /** @constructor */ function [name]() { ... }
                //   * /** @constructor */ var x = function() { ... }
                else if (isInJS
                    && (container.kind === SyntaxKind.FunctionExpression
                        || container.kind === SyntaxKind.FunctionDeclaration)
                    && getJSDocClassTag(container))
                {
                    const classType = (getDeclaredTypeOfSymbol(
                        getMergedSymbol(
                            container.symbol
                        )
                    ) as InterfaceType).thisType!;
                    return getFlowTypeOfReference(node, classType);
                }

                const thisType = getThisTypeOfDeclaration(container)
                    || getContextualThisParameterType(container);
                if (thisType) {
                    return getFlowTypeOfReference(node, thisType);
                }
            }

            if (isClassLike(container.parent)) {
                const symbol = getSymbolOfNode(container.parent);
                const type = hasModifier(container, ModifierFlags.Static)
                    ? getTypeOfSymbol(symbol)
                    : (getDeclaredTypeOfSymbol(symbol) as InterfaceType)
                        .thisType!;
                return getFlowTypeOfReference(node, type);
            }

            if (isInJS) {
                const type = getTypeForThisExpressionFromJSDoc(container);
                if (type && type !== errorType) {
                    return getFlowTypeOfReference(node, type);
                }
            }
            if (isSourceFile(container)) {
                // look up in the source file's locals or exports
                if (container.commonJsModuleIndicator) {
                    const fileSymbol = getSymbolOfNode(container);
                    return fileSymbol && getTypeOfSymbol(fileSymbol);
                } else if (includeGlobalThis) {
                    return getTypeOfSymbol(globalThisSymbol);
                }
            }
        }

        function getExplicitThisType(node: Expression) {
            const container = getThisContainer(
                node, /*includeArrowFunctions*/
                false
            );
            if (isFunctionLike(container)) {
                const signature = getSignatureFromDeclaration(container);
                if (signature.thisParameter) {
                    return getExplicitTypeOfSymbol(signature.thisParameter);
                }
            }
            if (isClassLike(container.parent)) {
                const symbol = getSymbolOfNode(container.parent);
                return hasModifier(container, ModifierFlags.Static)
                    ? getTypeOfSymbol(symbol)
                    : (getDeclaredTypeOfSymbol(symbol) as InterfaceType)
                        .thisType!;
            }
        }

        function getClassNameFromPrototypeMethod(container: Node) {
            // Check if it's the RHS of a x.prototype.y = function [name]() { .... }
            if (container.kind === SyntaxKind.FunctionExpression
                && isBinaryExpression(container.parent)
                && getAssignmentDeclarationKind(container.parent)
                === AssignmentDeclarationKind.PrototypeProperty)
            {
                // Get the 'x' of 'x.prototype.y = container'
                return ((container.parent // x.prototype.y = container
                    .left as PropertyAccessExpression) // x.prototype.y
                    .expression as PropertyAccessExpression) // x.prototype
                    .expression; // x
            } // x.prototype = { method() { } }
            else if (container.kind === SyntaxKind.MethodDeclaration
                && container.parent.kind === SyntaxKind.ObjectLiteralExpression
                && isBinaryExpression(container.parent.parent)
                && getAssignmentDeclarationKind(container.parent.parent)
                === AssignmentDeclarationKind.Prototype)
            {
                return (container.parent.parent
                    .left as PropertyAccessExpression).expression;
            } // x.prototype = { method: function() { } }
            else if (container.kind === SyntaxKind.FunctionExpression
                && container.parent.kind === SyntaxKind.PropertyAssignment
                && container.parent.parent.kind
                === SyntaxKind.ObjectLiteralExpression
                && isBinaryExpression(container.parent.parent.parent)
                && getAssignmentDeclarationKind(container.parent.parent.parent)
                === AssignmentDeclarationKind.Prototype)
            {
                return (container.parent.parent.parent
                    .left as PropertyAccessExpression).expression;
            } // Object.defineProperty(x, "method", { value: function() { } });
            // Object.defineProperty(x, "method", { set: (x: () => void) => void });
            // Object.defineProperty(x, "method", { get: () => function() { }) });
            else if (container.kind === SyntaxKind.FunctionExpression
                && isPropertyAssignment(container.parent)
                && isIdentifier(container.parent.name)
                && (container.parent.name.escapedText === 'value'
                    || container.parent.name.escapedText === 'get'
                    || container.parent.name.escapedText === 'set')
                && isObjectLiteralExpression(container.parent.parent)
                && isCallExpression(container.parent.parent.parent)
                && container.parent.parent.parent.arguments[2]
                === container.parent.parent
                && getAssignmentDeclarationKind(container.parent.parent.parent)
                === AssignmentDeclarationKind.ObjectDefinePrototypeProperty)
            {
                return (container.parent.parent.parent.arguments
                    [0] as PropertyAccessExpression).expression;
            } // Object.defineProperty(x, "method", { value() { } });
            // Object.defineProperty(x, "method", { set(x: () => void) {} });
            // Object.defineProperty(x, "method", { get() { return () => {} } });
            else if (isMethodDeclaration(container)
                && isIdentifier(container.name)
                && (container.name.escapedText === 'value'
                    || container.name.escapedText === 'get'
                    || container.name.escapedText === 'set')
                && isObjectLiteralExpression(container.parent)
                && isCallExpression(container.parent.parent)
                && container.parent.parent.arguments[2] === container.parent
                && getAssignmentDeclarationKind(container.parent.parent)
                === AssignmentDeclarationKind.ObjectDefinePrototypeProperty)
            {
                return (container.parent.parent.arguments
                    [0] as PropertyAccessExpression).expression;
            }
        }

        function getTypeForThisExpressionFromJSDoc(node: Node) {
            const jsdocType = getJSDocType(node);
            if (jsdocType && jsdocType.kind === SyntaxKind.JSDocFunctionType) {
                const jsDocFunctionType = <JSDocFunctionType> jsdocType;
                if (jsDocFunctionType.parameters.length > 0
                    && jsDocFunctionType.parameters[0].name
                    && (jsDocFunctionType.parameters[0].name as Identifier)
                        .escapedText === InternalSymbolName.This)
                {
                    return getTypeFromTypeNode(
                        jsDocFunctionType.parameters[0].type!
                    );
                }
            }
            const thisTag = getJSDocThisTag(node);
            if (thisTag && thisTag.typeExpression) {
                return getTypeFromTypeNode(thisTag.typeExpression);
            }
        }

        function isInConstructorArgumentInitializer(
            node: Node,
            constructorDecl: Node
        ): boolean {
            return !!findAncestor(
                node,
                n => isFunctionLikeDeclaration(n)
                    ? 'quit'
                    : n.kind === SyntaxKind.Parameter
                        && n.parent === constructorDecl
            );
        }

        function checkSuperExpression(node: Node): Type {
            const isCallExpression = node.parent.kind
                === SyntaxKind.CallExpression
                && (<CallExpression> node.parent).expression === node;

            let container = getSuperContainer(node, /*stopOnFunctions*/ true);
            let needToCaptureLexicalThis = false;

            // adjust the container reference in case if super is used inside arrow functions with arbitrarily deep nesting
            if (!isCallExpression) {
                while (container
                    && container.kind === SyntaxKind.ArrowFunction)
                {
                    container = getSuperContainer(
                        container, /*stopOnFunctions*/
                        true
                    );
                    needToCaptureLexicalThis = languageVersion
                        < ScriptTarget.ES2015;
                }
            }

            const canUseSuperExpression = isLegalUsageOfSuperExpression(container);
            let nodeCheckFlag: NodeCheckFlags = 0;

            if (!canUseSuperExpression) {
                // issue more specific error if super is used in computed property name
                // class A { foo() { return "1" }}
                // class B {
                //     [super.foo()]() {}
                // }
                const current = findAncestor(
                    node,
                    n => n === container
                        ? 'quit'
                        : n.kind === SyntaxKind.ComputedPropertyName
                );
                if (current
                    && current.kind === SyntaxKind.ComputedPropertyName)
                {
                    error(
                        node,
                        Diagnostics
                            .super_cannot_be_referenced_in_a_computed_property_name
                    );
                } else if (isCallExpression) {
                    error(
                        node,
                        Diagnostics
                            .Super_calls_are_not_permitted_outside_constructors_or_in_nested_functions_inside_constructors
                    );
                } else if (!container || !container.parent
                    || !(isClassLike(container.parent)
                        || container.parent.kind
                        === SyntaxKind.ObjectLiteralExpression))
                {
                    error(
                        node,
                        Diagnostics
                            .super_can_only_be_referenced_in_members_of_derived_classes_or_object_literal_expressions
                    );
                } else {
                    error(
                        node,
                        Diagnostics
                            .super_property_access_is_permitted_only_in_a_constructor_member_function_or_member_accessor_of_a_derived_class
                    );
                }
                return errorType;
            }

            if (!isCallExpression
                && container.kind === SyntaxKind.Constructor)
            {
                checkThisBeforeSuper(
                    node,
                    container,
                    Diagnostics
                        .super_must_be_called_before_accessing_a_property_of_super_in_the_constructor_of_a_derived_class
                );
            }

            if (hasModifier(container, ModifierFlags.Static)
                || isCallExpression)
            {
                nodeCheckFlag = NodeCheckFlags.SuperStatic;
            } else {
                nodeCheckFlag = NodeCheckFlags.SuperInstance;
            }

            getNodeLinks(node).flags |= nodeCheckFlag;

            // Due to how we emit async functions, we need to specialize the emit for an async method that contains a `super` reference.
            // This is due to the fact that we emit the body of an async function inside of a generator function. As generator
            // functions cannot reference `super`, we emit a helper inside of the method body, but outside of the generator. This helper
            // uses an arrow function, which is permitted to reference `super`.
            //
            // There are two primary ways we can access `super` from within an async method. The first is getting the value of a property
            // or indexed access on super, either as part of a right-hand-side expression or call expression. The second is when setting the value
            // of a property or indexed access, either as part of an assignment expression or destructuring assignment.
            //
            // The simplest case is reading a value, in which case we will emit something like the following:
            //
            //  // ts
            //  ...
            //  async asyncMethod() {
            //    let x = await super.asyncMethod();
            //    return x;
            //  }
            //  ...
            //
            //  // js
            //  ...
            //  asyncMethod() {
            //      const _super = Object.create(null, {
            //        asyncMethod: { get: () => super.asyncMethod },
            //      });
            //      return __awaiter(this, arguments, Promise, function *() {
            //          let x = yield _super.asyncMethod.call(this);
            //          return x;
            //      });
            //  }
            //  ...
            //
            // The more complex case is when we wish to assign a value, especially as part of a destructuring assignment. As both cases
            // are legal in ES6, but also likely less frequent, we only emit setters if there is an assignment:
            //
            //  // ts
            //  ...
            //  async asyncMethod(ar: Promise<any[]>) {
            //      [super.a, super.b] = await ar;
            //  }
            //  ...
            //
            //  // js
            //  ...
            //  asyncMethod(ar) {
            //      const _super = Object.create(null, {
            //        a: { get: () => super.a, set: (v) => super.a = v },
            //        b: { get: () => super.b, set: (v) => super.b = v }
            //      };
            //      return __awaiter(this, arguments, Promise, function *() {
            //          [_super.a, _super.b] = yield ar;
            //      });
            //  }
            //  ...
            //
            // Creating an object that has getter and setters instead of just an accessor function is required for destructuring assignments
            // as a call expression cannot be used as the target of a destructuring assignment while a property access can.
            //
            // For element access expressions (`super[x]`), we emit a generic helper that forwards the element access in both situations.
            if (container.kind === SyntaxKind.MethodDeclaration
                && hasModifier(container, ModifierFlags.Async))
            {
                if (isSuperProperty(node.parent)
                    && isAssignmentTarget(node.parent))
                {
                    getNodeLinks(container).flags |= NodeCheckFlags
                        .AsyncMethodWithSuperBinding;
                } else {
                    getNodeLinks(container).flags |= NodeCheckFlags
                        .AsyncMethodWithSuper;
                }
            }

            if (needToCaptureLexicalThis) {
                // call expressions are allowed only in constructors so they should always capture correct 'this'
                // super property access expressions can also appear in arrow functions -
                // in this case they should also use correct lexical this
                captureLexicalThis(node.parent, container);
            }

            if (container.parent.kind === SyntaxKind.ObjectLiteralExpression) {
                if (languageVersion < ScriptTarget.ES2015) {
                    error(
                        node,
                        Diagnostics
                            .super_is_only_allowed_in_members_of_object_literal_expressions_when_option_target_is_ES2015_or_higher
                    );
                    return errorType;
                } else {
                    // for object literal assume that type of 'super' is 'any'
                    return anyType;
                }
            }

            // at this point the only legal case for parent is ClassLikeDeclaration
            const classLikeDeclaration = <ClassLikeDeclaration> container
                .parent;
            if (!getClassExtendsHeritageElement(classLikeDeclaration)) {
                error(
                    node,
                    Diagnostics.super_can_only_be_referenced_in_a_derived_class
                );
                return errorType;
            }

            const classType = <InterfaceType> getDeclaredTypeOfSymbol(getSymbolOfNode(classLikeDeclaration));
            const baseClassType = classType && getBaseTypes(classType)[0];
            if (!baseClassType) {
                return errorType;
            }

            if (container.kind === SyntaxKind.Constructor
                && isInConstructorArgumentInitializer(node, container))
            {
                // issue custom error message for super property access in constructor arguments (to be aligned with old compiler)
                error(
                    node,
                    Diagnostics
                        .super_cannot_be_referenced_in_constructor_arguments
                );
                return errorType;
            }

            return nodeCheckFlag === NodeCheckFlags.SuperStatic
                ? getBaseConstructorTypeOfClass(classType)
                : getTypeWithThisArgument(baseClassType, classType.thisType);

            function isLegalUsageOfSuperExpression(container: Node): boolean {
                if (!container) {
                    return false;
                }

                if (isCallExpression) {
                    // TS 1.0 SPEC (April 2014): 4.8.1
                    // Super calls are only permitted in constructors of derived classes
                    return container.kind === SyntaxKind.Constructor;
                } else {
                    // TS 1.0 SPEC (April 2014)
                    // 'super' property access is allowed
                    // - In a constructor, instance member function, instance member accessor, or instance member variable initializer where this references a derived class instance
                    // - In a static member function or static member accessor

                    // topmost container must be something that is directly nested in the class declaration\object literal expression
                    if (isClassLike(container.parent)
                        || container.parent.kind
                        === SyntaxKind.ObjectLiteralExpression)
                    {
                        if (hasModifier(container, ModifierFlags.Static)) {
                            return container.kind
                                === SyntaxKind.MethodDeclaration
                                || container.kind
                                === SyntaxKind.MethodSignature
                                || container.kind === SyntaxKind.GetAccessor
                                || container.kind === SyntaxKind.SetAccessor;
                        } else {
                            return container.kind
                                === SyntaxKind.MethodDeclaration
                                || container.kind
                                === SyntaxKind.MethodSignature
                                || container.kind === SyntaxKind.GetAccessor
                                || container.kind === SyntaxKind.SetAccessor
                                || container.kind
                                === SyntaxKind.PropertyDeclaration
                                || container.kind
                                === SyntaxKind.PropertySignature
                                || container.kind === SyntaxKind.Constructor;
                        }
                    }
                }

                return false;
            }
        }

        function getContainingObjectLiteral(
            func: SignatureDeclaration
        ): ObjectLiteralExpression | undefined {
            return (func.kind === SyntaxKind.MethodDeclaration
                || func.kind === SyntaxKind.GetAccessor
                || func.kind === SyntaxKind.SetAccessor)
                && func.parent.kind === SyntaxKind.ObjectLiteralExpression
                ? func.parent
                : func.kind === SyntaxKind.FunctionExpression
                    && func.parent.kind === SyntaxKind.PropertyAssignment
                    ? <ObjectLiteralExpression> func.parent.parent
                    : undefined;
        }

        function getThisTypeArgument(type: Type): Type | undefined {
            return getObjectFlags(type) & ObjectFlags.Reference
                && (<TypeReference> type).target === globalThisType
                ? getTypeArguments(<TypeReference> type)[0]
                : undefined;
        }

        function getThisTypeFromContextualType(type: Type): Type | undefined {
            return mapType(
                type,
                t => {
                    return t.flags & TypeFlags.Intersection
                        ? forEach(
                            (<IntersectionType> t).types,
                            getThisTypeArgument
                        )
                        : getThisTypeArgument(t);
                }
            );
        }

        function getContextualThisParameterType(
            func: SignatureDeclaration
        ): Type | undefined {
            if (func.kind === SyntaxKind.ArrowFunction) {
                return undefined;
            }
            if (isContextSensitiveFunctionOrObjectLiteralMethod(func)) {
                const contextualSignature = getContextualSignature(func);
                if (contextualSignature) {
                    const thisParameter = contextualSignature.thisParameter;
                    if (thisParameter) {
                        return getTypeOfSymbol(thisParameter);
                    }
                }
            }
            const inJs = isInJSFile(func);
            if (noImplicitThis || inJs) {
                const containingLiteral = getContainingObjectLiteral(func);
                if (containingLiteral) {
                    // We have an object literal method. Check if the containing object literal has a contextual type
                    // that includes a ThisType<T>. If so, T is the contextual type for 'this'. We continue looking in
                    // any directly enclosing object literals.
                    const contextualType = getApparentTypeOfContextualType(containingLiteral);
                    let literal = containingLiteral;
                    let type = contextualType;
                    while (type) {
                        const thisType = getThisTypeFromContextualType(type);
                        if (thisType) {
                            return instantiateType(
                                thisType,
                                getMapperFromContext(getInferenceContext(containingLiteral))
                            );
                        }
                        if (literal.parent.kind
                            !== SyntaxKind.PropertyAssignment)
                        {
                            break;
                        }
                        literal = <ObjectLiteralExpression> literal.parent
                            .parent;
                        type = getApparentTypeOfContextualType(literal);
                    }
                    // There was no contextual ThisType<T> for the containing object literal, so the contextual type
                    // for 'this' is the non-null form of the contextual type for the containing object literal or
                    // the type of the object literal itself.
                    return getWidenedType(
                        contextualType
                            ? getNonNullableType(contextualType)
                            : checkExpressionCached(containingLiteral)
                    );
                }
                // In an assignment of the form 'obj.xxx = function(...)' or 'obj[xxx] = function(...)', the
                // contextual type for 'this' is 'obj'.
                const parent = func.parent;
                if (parent.kind === SyntaxKind.BinaryExpression
                    && (<BinaryExpression> parent).operatorToken.kind
                    === SyntaxKind.EqualsToken)
                {
                    const target = (<BinaryExpression> parent).left;
                    if (isAccessExpression(target)) {
                        const { expression } = target;
                        // Don't contextually type `this` as `exports` in `exports.Point = function(x, y) { this.x = x; this.y = y; }`
                        if (inJs && isIdentifier(expression)) {
                            const sourceFile = getSourceFileOfNode(parent);
                            if (sourceFile.commonJsModuleIndicator
                                && getResolvedSymbol(expression)
                                === sourceFile.symbol)
                            {
                                return undefined;
                            }
                        }

                        return getWidenedType(checkExpressionCached(expression));
                    }
                }
            }
            return undefined;
        }

        // Return contextual type of parameter or undefined if no contextual type is available
        function getContextuallyTypedParameterType(
            parameter: ParameterDeclaration,
            forCache: boolean
        ): Type | undefined {
            const func = parameter.parent;
            if (!isContextSensitiveFunctionOrObjectLiteralMethod(func)) {
                return undefined;
            }
            const iife = getImmediatelyInvokedFunctionExpression(func);
            if (iife && iife.arguments) {
                const args = getEffectiveCallArguments(iife);
                const indexOfParameter = func.parameters.indexOf(parameter);
                if (parameter.dotDotDotToken) {
                    return getSpreadArgumentType(
                        args,
                        indexOfParameter,
                        args.length,
                        anyType, /*context*/
                        undefined
                    );
                }
                const links = getNodeLinks(iife);
                const cached = links.resolvedSignature;
                links.resolvedSignature = anySignature;
                const type = indexOfParameter < args.length
                    ? getWidenedLiteralType(
                        checkExpression(
                            args[indexOfParameter]
                        )
                    )
                    : parameter.initializer
                        ? undefined
                        : undefinedWideningType;
                links.resolvedSignature = cached;
                return type;
            }
            let contextualSignature = getContextualSignature(func);
            if (contextualSignature) {
                if (forCache) {
                    // Calling the below guarantees the types are primed and assigned in the same way
                    // as when the parameter is reached via `checkFunctionExpressionOrObjectLiteralMethod`.
                    // This should prevent any uninstantiated inference variables in the contextual signature
                    // from leaking, and should lock in cached parameter types via `assignContextualParameterTypes`
                    // which we will then immediately use the results of below.
                    contextuallyCheckFunctionExpressionOrObjectLiteralMethod(func);
                    const type = getTypeOfSymbol(getMergedSymbol(func.symbol));
                    if (isTypeAny(type)) {
                        return type;
                    }
                    contextualSignature = getSignaturesOfType(
                        type,
                        SignatureKind.Call
                    )[0];
                }
                const index = func.parameters.indexOf(parameter)
                    - (getThisParameter(func) ? 1 : 0);
                return parameter.dotDotDotToken
                    && lastOrUndefined(func.parameters) === parameter
                    ? getRestTypeAtPosition(contextualSignature, index)
                    : tryGetTypeAtPosition(contextualSignature, index);
            }
        }

        function getContextualTypeForVariableLikeDeclaration(
            declaration: VariableLikeDeclaration
        ): Type | undefined {
            const typeNode = getEffectiveTypeAnnotationNode(declaration);
            if (typeNode) {
                return getTypeFromTypeNode(typeNode);
            }
            switch (declaration.kind) {
                case SyntaxKind.Parameter:
                    return getContextuallyTypedParameterType(
                        declaration, /*forCache*/
                        false
                    );
                case SyntaxKind.BindingElement:
                    return getContextualTypeForBindingElement(declaration);
                    // By default, do nothing and return undefined - only parameters and binding elements have context implied by a parent
            }
        }

        function getContextualTypeForBindingElement(
            declaration: BindingElement
        ): Type | undefined {
            const parentDeclaration = declaration.parent.parent;
            const name = declaration.propertyName || declaration.name;
            const parentType = getContextualTypeForVariableLikeDeclaration(parentDeclaration);
            if (parentType && !isBindingPattern(name)
                && !isComputedNonLiteralName(name))
            {
                const nameType = getLiteralTypeFromPropertyName(name);
                if (isTypeUsableAsPropertyName(nameType)) {
                    const text = getPropertyNameFromType(nameType);
                    return getTypeOfPropertyOfType(parentType, text);
                }
            }
        }

        // In a variable, parameter or property declaration with a type annotation,
        //   the contextual type of an initializer expression is the type of the variable, parameter or property.
        // Otherwise, in a parameter declaration of a contextually typed function expression,
        //   the contextual type of an initializer expression is the contextual type of the parameter.
        // Otherwise, in a variable or parameter declaration with a binding pattern name,
        //   the contextual type of an initializer expression is the type implied by the binding pattern.
        // Otherwise, in a binding pattern inside a variable or parameter declaration,
        //   the contextual type of an initializer expression is the type annotation of the containing declaration, if present.
        function getContextualTypeForInitializerExpression(
            node: Expression
        ): Type | undefined {
            const declaration = <VariableLikeDeclaration> node.parent;
            if (hasInitializer(declaration)
                && node === declaration.initializer)
            {
                const result = getContextualTypeForVariableLikeDeclaration(declaration);
                if (result) {
                    return result;
                }
                if (isBindingPattern(declaration
                    .name))
                { // This is less a contextual type and more an implied shape - in some cases, this may be undesirable
                    return getTypeFromBindingPattern(
                        declaration.name, /*includePatternInType*/
                        true, /*reportErrors*/
                        false
                    );
                }
            }
            return undefined;
        }

        function getContextualTypeForReturnExpression(
            node: Expression
        ): Type | undefined {
            const func = getContainingFunction(node);
            if (func) {
                const functionFlags = getFunctionFlags(func);
                if (functionFlags
                    & FunctionFlags
                        .Generator)
                { // AsyncGenerator function or Generator function
                    return undefined;
                }

                const contextualReturnType = getContextualReturnType(func);
                if (contextualReturnType) {
                    if (functionFlags
                        & FunctionFlags.Async)
                    { // Async function
                        const contextualAwaitedType = getAwaitedTypeOfPromise(contextualReturnType);
                        return contextualAwaitedType
                            && getUnionType(
                                [contextualAwaitedType,
                                    createPromiseLikeType(contextualAwaitedType)]
                            );
                    }
                    return contextualReturnType; // Regular function
                }
            }
            return undefined;
        }

        function getContextualTypeForAwaitOperand(
            node: AwaitExpression
        ): Type | undefined {
            const contextualType = getContextualType(node);
            if (contextualType) {
                const contextualAwaitedType = getAwaitedType(contextualType);
                return contextualAwaitedType
                    && getUnionType(
                        [contextualAwaitedType,
                            createPromiseLikeType(contextualAwaitedType)]
                    );
            }
            return undefined;
        }

        function getContextualTypeForYieldOperand(
            node: YieldExpression
        ): Type | undefined {
            const func = getContainingFunction(node);
            if (func) {
                const functionFlags = getFunctionFlags(func);
                const contextualReturnType = getContextualReturnType(func);
                if (contextualReturnType) {
                    return node.asteriskToken
                        ? contextualReturnType
                        : getIterationTypeOfGeneratorFunctionReturnType(
                            IterationTypeKind.Yield,
                            contextualReturnType,
                            (functionFlags & FunctionFlags.Async) !== 0
                        );
                }
            }

            return undefined;
        }

        function isInParameterInitializerBeforeContainingFunction(node: Node) {
            let inBindingInitializer = false;
            while (node.parent && !isFunctionLike(node.parent)) {
                if (isParameter(node.parent)
                    && (inBindingInitializer
                        || node.parent.initializer === node))
                {
                    return true;
                }
                if (isBindingElement(node.parent)
                    && node.parent.initializer === node)
                {
                    inBindingInitializer = true;
                }

                node = node.parent;
            }

            return false;
        }

        function getContextualIterationType(
            kind: IterationTypeKind,
            functionDecl: SignatureDeclaration
        ): Type | undefined {
            const isAsync = !!(getFunctionFlags(functionDecl)
                & FunctionFlags.Async);
            const contextualReturnType = getContextualReturnType(functionDecl);
            if (contextualReturnType) {
                return getIterationTypeOfGeneratorFunctionReturnType(
                    kind,
                    contextualReturnType,
                    isAsync
                )
                    || undefined;
            }

            return undefined;
        }

        function getContextualReturnType(
            functionDecl: SignatureDeclaration
        ): Type | undefined {
            // If the containing function has a return type annotation, is a constructor, or is a get accessor whose
            // corresponding set accessor has a type annotation, return statements in the function are contextually typed
            const returnType = getReturnTypeFromAnnotation(functionDecl);
            if (returnType) {
                return returnType;
            }
            // Otherwise, if the containing function is contextually typed by a function type with exactly one call signature
            // and that call signature is non-generic, return statements are contextually typed by the return type of the signature
            const signature = getContextualSignatureForFunctionLikeDeclaration(<FunctionExpression> functionDecl);
            if (signature && !isResolvingReturnTypeOfSignature(signature)) {
                return getReturnTypeOfSignature(signature);
            }
            return undefined;
        }

        // In a typed function call, an argument or substitution expression is contextually typed by the type of the corresponding parameter.
        function getContextualTypeForArgument(
            callTarget: CallLikeExpression,
            arg: Expression,
            contextFlags?: ContextFlags
        ): Type | undefined {
            const args = getEffectiveCallArguments(callTarget);
            const argIndex = args
                .indexOf(arg); // -1 for e.g. the expression of a CallExpression, or the tag of a TaggedTemplateExpression
            return argIndex === -1
                ? undefined
                : getContextualTypeForArgumentAtIndex(
                    callTarget,
                    argIndex,
                    contextFlags
                );
        }

        function getContextualTypeForArgumentAtIndex(
            callTarget: CallLikeExpression,
            argIndex: number,
            contextFlags?: ContextFlags
        ): Type {
            // If we're already in the process of resolving the given signature, don't resolve again as
            // that could cause infinite recursion. Instead, return anySignature.
            let signature = getNodeLinks(callTarget).resolvedSignature
                === resolvingSignature
                ? resolvingSignature
                : getResolvedSignature(callTarget);
            if (contextFlags && contextFlags & ContextFlags.BaseConstraint
                && signature.target && !hasTypeArguments(callTarget))
            {
                signature = getBaseSignature(signature.target);
            }

            if (isJsxOpeningLikeElement(callTarget) && argIndex === 0) {
                return getEffectiveFirstArgumentForJsxSignature(
                    signature,
                    callTarget
                );
            }
            return getTypeAtPosition(signature, argIndex);
        }

        function getContextualTypeForSubstitutionExpression(
            template: TemplateExpression,
            substitutionExpression: Expression
        ) {
            if (template.parent.kind === SyntaxKind.TaggedTemplateExpression) {
                return getContextualTypeForArgument(
                    <TaggedTemplateExpression> template.parent,
                    substitutionExpression
                );
            }

            return undefined;
        }

        function getContextualTypeForBinaryOperand(
            node: Expression,
            contextFlags?: ContextFlags
        ): Type | undefined {
            const binaryExpression = <BinaryExpression> node.parent;
            const { left, operatorToken, right } = binaryExpression;
            switch (operatorToken.kind) {
                case SyntaxKind.EqualsToken:
                    if (node !== right) {
                        return undefined;
                    }
                    const contextSensitive = getIsContextSensitiveAssignmentOrContextType(binaryExpression);
                    if (!contextSensitive) {
                        return undefined;
                    }
                    return contextSensitive === true
                        ? getTypeOfExpression(left)
                        : contextSensitive;
                case SyntaxKind.BarBarToken:
                case SyntaxKind.QuestionQuestionToken:
                    // When an || expression has a contextual type, the operands are contextually typed by that type, except
                    // when that type originates in a binding pattern, the right operand is contextually typed by the type of
                    // the left operand. When an || expression has no contextual type, the right operand is contextually typed
                    // by the type of the left operand, except for the special case of Javascript declarations of the form
                    // `namespace.prop = namespace.prop || {}`.
                    const type = getContextualType(
                        binaryExpression,
                        contextFlags
                    );
                    return node === right
                        && (type && type.pattern || !type
                            && !isDefaultedExpandoInitializer(binaryExpression))
                        ? getTypeOfExpression(left)
                        : type;
                case SyntaxKind.AmpersandAmpersandToken:
                case SyntaxKind.CommaToken:
                    return node === right
                        ? getContextualType(binaryExpression, contextFlags)
                        : undefined;
                default:
                    return undefined;
            }
        }

        // In an assignment expression, the right operand is contextually typed by the type of the left operand.
        // Don't do this for assignment declarations unless there is a type tag on the assignment, to avoid circularity from checking the right operand.
        function getIsContextSensitiveAssignmentOrContextType(
            binaryExpression: BinaryExpression
        ): boolean | Type {
            const kind = getAssignmentDeclarationKind(binaryExpression);
            switch (kind) {
                case AssignmentDeclarationKind.None:
                    return true;
                case AssignmentDeclarationKind.Property:
                case AssignmentDeclarationKind.ExportsProperty:
                case AssignmentDeclarationKind.Prototype:
                case AssignmentDeclarationKind.PrototypeProperty:
                    // If `binaryExpression.left` was assigned a symbol, then this is a new declaration; otherwise it is an assignment to an existing declaration.
                    // See `bindStaticPropertyAssignment` in `binder.ts`.
                    if (!binaryExpression.left.symbol) {
                        return true;
                    } else {
                        const decl = binaryExpression.left.symbol
                            .valueDeclaration;
                        if (!decl) {
                            return false;
                        }
                        const lhs = cast(
                            binaryExpression.left,
                            isAccessExpression
                        );
                        const overallAnnotation = getEffectiveTypeAnnotationNode(decl);
                        if (overallAnnotation) {
                            return getTypeFromTypeNode(overallAnnotation);
                        } else if (isIdentifier(lhs.expression)) {
                            const id = lhs.expression;
                            const parentSymbol = resolveName(
                                id,
                                id.escapedText,
                                SymbolFlags.Value,
                                undefined,
                                id.escapedText, /*isUse*/
                                true
                            );
                            if (parentSymbol) {
                                const annotated = getEffectiveTypeAnnotationNode(
                                    parentSymbol.valueDeclaration
                                );
                                if (annotated) {
                                    const nameStr = getElementOrPropertyAccessName(lhs);
                                    if (nameStr !== undefined) {
                                        const type = getTypeOfPropertyOfContextualType(
                                            getTypeFromTypeNode(annotated),
                                            nameStr
                                        );
                                        return type || false;
                                    }
                                }
                                return false;
                            }
                        }
                        return !isInJSFile(decl);
                    }
                case AssignmentDeclarationKind.ModuleExports:
                case AssignmentDeclarationKind.ThisProperty:
                    if (!binaryExpression.symbol) return true;
                    if (binaryExpression.symbol.valueDeclaration) {
                        const annotated = getEffectiveTypeAnnotationNode(
                            binaryExpression.symbol.valueDeclaration
                        );
                        if (annotated) {
                            const type = getTypeFromTypeNode(annotated);
                            if (type) {
                                return type;
                            }
                        }
                    }
                    if (kind
                        === AssignmentDeclarationKind.ModuleExports)
                        return false;
                    const thisAccess = cast(
                        binaryExpression.left,
                        isAccessExpression
                    );
                    if (!isObjectLiteralMethod(
                        getThisContainer(
                            thisAccess.expression, /*includeArrowFunctions*/
                            false
                        )
                    )) {
                        return false;
                    }
                    const thisType = checkThisExpression(thisAccess
                        .expression);
                    const nameStr = getElementOrPropertyAccessName(thisAccess);
                    return nameStr !== undefined && thisType
                        && getTypeOfPropertyOfContextualType(thisType, nameStr)
                        || false;
                case AssignmentDeclarationKind.ObjectDefinePropertyValue:
                case AssignmentDeclarationKind.ObjectDefinePropertyExports:
                case AssignmentDeclarationKind.ObjectDefinePrototypeProperty:
                    return Debug.fail('Does not apply');
                default:
                    return Debug.assertNever(kind);
            }
        }

        function getTypeOfPropertyOfContextualType(type: Type,
            name: __String)
        {
            return mapType(
                type,
                t => {
                    if (isGenericMappedType(t)) {
                        const constraint = getConstraintTypeFromMappedType(t);
                        const constraintOfConstraint = getBaseConstraintOfType(constraint)
                            || constraint;
                        const propertyNameType = getLiteralType(unescapeLeadingUnderscores(name));
                        if (isTypeAssignableTo(
                            propertyNameType,
                            constraintOfConstraint
                        )) {
                            return substituteIndexedMappedType(t,
                                propertyNameType);
                        }
                    } else if (t.flags & TypeFlags.StructuredType) {
                        const prop = getPropertyOfType(t, name);
                        if (prop) {
                            return getTypeOfSymbol(prop);
                        }
                        if (isTupleType(t)) {
                            const restType = getRestTypeOfTupleType(t);
                            if (restType && isNumericLiteralName(name)
                                && +name >= 0)
                            {
                                return restType;
                            }
                        }
                        return isNumericLiteralName(name)
                            && getIndexTypeOfContextualType(t,
                                IndexKind.Number)
                            || getIndexTypeOfContextualType(t,
                                IndexKind.String);
                    }
                    return undefined;
                }, /*noReductions*/
                true
            );
        }

        function getIndexTypeOfContextualType(type: Type, kind: IndexKind) {
            return mapType(
                type,
                t => getIndexTypeOfStructuredType(t, kind), /*noReductions*/
                true
            );
        }

        // In an object literal contextually typed by a type T, the contextual type of a property assignment is the type of
        // the matching property in T, if one exists. Otherwise, it is the type of the numeric index signature in T, if one
        // exists. Otherwise, it is the type of the string index signature in T, if one exists.
        function getContextualTypeForObjectLiteralMethod(
            node: MethodDeclaration,
            contextFlags?: ContextFlags
        ): Type | undefined {
            Debug.assert(isObjectLiteralMethod(node));
            if (node.flags & NodeFlags.InWithStatement) {
                // We cannot answer semantic questions within a with block, do not proceed any further
                return undefined;
            }
            return getContextualTypeForObjectLiteralElement(node,
                contextFlags);
        }

        function getContextualTypeForObjectLiteralElement(
            element: ObjectLiteralElementLike,
            contextFlags?: ContextFlags
        ) {
            const objectLiteral = <ObjectLiteralExpression> element.parent;
            const type = getApparentTypeOfContextualType(
                objectLiteral,
                contextFlags
            );
            if (type) {
                if (!hasNonBindableDynamicName(element)) {
                    // For a (non-symbol) computed property, there is no reason to look up the name
                    // in the type. It will just be "__computed", which does not appear in any
                    // SymbolTable.
                    const symbolName = getSymbolOfNode(element).escapedName;
                    const propertyType = getTypeOfPropertyOfContextualType(
                        type,
                        symbolName
                    );
                    if (propertyType) {
                        return propertyType;
                    }
                }
                return isNumericName(element.name!)
                    && getIndexTypeOfContextualType(type, IndexKind.Number)
                    || getIndexTypeOfContextualType(type, IndexKind.String);
            }
            return undefined;
        }

        // In an array literal contextually typed by a type T, the contextual type of an element expression at index N is
        // the type of the property with the numeric name N in T, if one exists. Otherwise, if T has a numeric index signature,
        // it is the type of the numeric index signature in T. Otherwise, in ES6 and higher, the contextual type is the iterated
        // type of T.
        function getContextualTypeForElementExpression(
            arrayContextualType: Type | undefined,
            index: number
        ): Type | undefined {
            return arrayContextualType && (
                getTypeOfPropertyOfContextualType(
                    arrayContextualType,
                    '' + index as __String
                )
                || getIteratedTypeOrElementType(
                    IterationUse.Element,
                    arrayContextualType,
                    undefinedType, /*errorNode*/
                    undefined, /*checkAssignability*/
                    false
                )
            );
        }

        // In a contextually typed conditional expression, the true/false expressions are contextually typed by the same type.
        function getContextualTypeForConditionalOperand(
            node: Expression,
            contextFlags?: ContextFlags
        ): Type | undefined {
            const conditional = <ConditionalExpression> node.parent;
            return node === conditional.whenTrue
                || node === conditional.whenFalse
                ? getContextualType(conditional, contextFlags)
                : undefined;
        }

        function getContextualTypeForChildJsxExpression(
            node: JsxElement,
            child: JsxChild
        ) {
            const attributesType = getApparentTypeOfContextualType(
                node.openingElement.tagName
            );
            // JSX expression is in children of JSX Element, we will look for an "children" atttribute (we get the name from JSX.ElementAttributesProperty)
            const jsxChildrenPropertyName = getJsxElementChildrenPropertyName(getJsxNamespaceAt(node));
            if (!(attributesType && !isTypeAny(attributesType)
                && jsxChildrenPropertyName && jsxChildrenPropertyName !== ''))
            {
                return undefined;
            }
            const realChildren = getSemanticJsxChildren(node.children);
            const childIndex = realChildren.indexOf(child);
            const childFieldType = getTypeOfPropertyOfContextualType(
                attributesType,
                jsxChildrenPropertyName
            );
            return childFieldType
                && (realChildren.length === 1
                    ? childFieldType
                    : mapType(
                        childFieldType,
                        t => {
                            if (isArrayLikeType(t)) {
                                return getIndexedAccessType(
                                    t,
                                    getLiteralType(childIndex)
                                );
                            } else {
                                return t;
                            }
                        }, /*noReductions*/
                        true
                    ));
        }

        function getContextualTypeForJsxExpression(
            node: JsxExpression
        ): Type | undefined {
            const exprParent = node.parent;
            return isJsxAttributeLike(exprParent)
                ? getContextualType(node)
                : isJsxElement(exprParent)
                    ? getContextualTypeForChildJsxExpression(exprParent, node)
                    : undefined;
        }

        function getContextualTypeForJsxAttribute(
            attribute: JsxAttribute | JsxSpreadAttribute
        ): Type | undefined {
            // When we trying to resolve JsxOpeningLikeElement as a stateless function element, we will already give its attributes a contextual type
            // which is a type of the parameter of the signature we are trying out.
            // If there is no contextual type (e.g. we are trying to resolve stateful component), get attributes type from resolving element's tagName
            if (isJsxAttribute(attribute)) {
                const attributesType = getApparentTypeOfContextualType(
                    attribute.parent
                );
                if (!attributesType || isTypeAny(attributesType)) {
                    return undefined;
                }
                return getTypeOfPropertyOfContextualType(
                    attributesType,
                    attribute.name.escapedText
                );
            } else {
                return getContextualType(attribute.parent);
            }
        }

        // Return true if the given expression is possibly a discriminant value. We limit the kinds of
        // expressions we check to those that don't depend on their contextual type in order not to cause
        // recursive (and possibly infinite) invocations of getContextualType.
        function isPossiblyDiscriminantValue(node: Expression): boolean {
            switch (node.kind) {
                case SyntaxKind.StringLiteral:
                case SyntaxKind.NumericLiteral:
                case SyntaxKind.BigIntLiteral:
                case SyntaxKind.NoSubstitutionTemplateLiteral:
                case SyntaxKind.TrueKeyword:
                case SyntaxKind.FalseKeyword:
                case SyntaxKind.NullKeyword:
                case SyntaxKind.Identifier:
                case SyntaxKind.UndefinedKeyword:
                    return true;
                case SyntaxKind.PropertyAccessExpression:
                case SyntaxKind.ParenthesizedExpression:
                    return isPossiblyDiscriminantValue(
                        (<PropertyAccessExpression
                            | ParenthesizedExpression> node).expression
                    );
                case SyntaxKind.JsxExpression:
                    return !(node as JsxExpression).expression
                        || isPossiblyDiscriminantValue(
                            (node as JsxExpression).expression!
                        );
            }
            return false;
        }

        function discriminateContextualTypeByObjectMembers(
            node: ObjectLiteralExpression,
            contextualType: UnionType
        ) {
            return discriminateTypeByDiscriminableItems(
                contextualType,
                map(
                    filter(
                        node.properties,
                        p => !!p.symbol
                            && p.kind === SyntaxKind.PropertyAssignment
                            && isPossiblyDiscriminantValue(p.initializer)
                            && isDiscriminantProperty(contextualType,
                                p.symbol.escapedName)
                    ),
                    prop => ([() => checkExpression(
                        (prop as PropertyAssignment).initializer
                    ), prop.symbol.escapedName] as [() => Type, __String])
                ),
                isTypeAssignableTo,
                contextualType
            );
        }

        function discriminateContextualTypeByJSXAttributes(
            node: JsxAttributes,
            contextualType: UnionType
        ) {
            return discriminateTypeByDiscriminableItems(
                contextualType,
                map(
                    filter(
                        node.properties,
                        p => !!p.symbol && p.kind === SyntaxKind.JsxAttribute
                            && isDiscriminantProperty(
                                contextualType,
                                p.symbol.escapedName
                            )
                            && (!p.initializer
                                || isPossiblyDiscriminantValue(p.initializer))
                    ),
                    prop => ([!(prop as JsxAttribute).initializer
                        ? (() => trueType)
                        : (() => checkExpression(
                            (prop as JsxAttribute).initializer!
                        )), prop.symbol.escapedName] as [() => Type, __String])
                ),
                isTypeAssignableTo,
                contextualType
            );
        }

        // Return the contextual type for a given expression node. During overload resolution, a contextual type may temporarily
        // be "pushed" onto a node using the contextualType property.
        function getApparentTypeOfContextualType(
            node: Expression | MethodDeclaration,
            contextFlags?: ContextFlags
        ): Type | undefined {
            const contextualType = isObjectLiteralMethod(node)
                ? getContextualTypeForObjectLiteralMethod(node, contextFlags)
                : getContextualType(node, contextFlags);
            const instantiatedType = instantiateContextualType(
                contextualType,
                node,
                contextFlags
            );
            if (instantiatedType
                && !(contextFlags && contextFlags & ContextFlags.NoConstraints
                    && instantiatedType.flags & TypeFlags.TypeVariable))
            {
                const apparentType = mapType(
                    instantiatedType,
                    getApparentType, /*noReductions*/
                    true
                );
                if (apparentType.flags & TypeFlags.Union) {
                    if (isObjectLiteralExpression(node)) {
                        return discriminateContextualTypeByObjectMembers(
                            node,
                            apparentType as UnionType
                        );
                    } else if (isJsxAttributes(node)) {
                        return discriminateContextualTypeByJSXAttributes(
                            node,
                            apparentType as UnionType
                        );
                    }
                }
                return apparentType;
            }
        }

        // If the given contextual type contains instantiable types and if a mapper representing
        // return type inferences is available, instantiate those types using that mapper.
        function instantiateContextualType(
            contextualType: Type | undefined,
            node: Node,
            contextFlags?: ContextFlags
        ): Type | undefined {
            if (contextualType
                && maybeTypeOfKind(contextualType, TypeFlags.Instantiable))
            {
                const inferenceContext = getInferenceContext(node);
                // If no inferences have been made, nothing is gained from instantiating as type parameters
                // would just be replaced with their defaults similar to the apparent type.
                if (inferenceContext
                    && some(
                        inferenceContext.inferences,
                        hasInferenceCandidates
                    ))
                {
                    // For contextual signatures we incorporate all inferences made so far, e.g. from return
                    // types as well as arguments to the left in a function call.
                    if (contextFlags
                        && contextFlags & ContextFlags.Signature)
                    {
                        return instantiateInstantiableTypes(
                            contextualType,
                            inferenceContext.nonFixingMapper
                        );
                    }
                    // For other purposes (e.g. determining whether to produce literal types) we only
                    // incorporate inferences made from the return type in a function call.
                    if (inferenceContext.returnMapper) {
                        return instantiateInstantiableTypes(
                            contextualType,
                            inferenceContext.returnMapper
                        );
                    }
                }
            }
            return contextualType;
        }

        // This function is similar to instantiateType, except that (a) it only instantiates types that
        // are classified as instantiable (i.e. it doesn't instantiate object types), and (b) it performs
        // no reductions on instantiated union types.
        function instantiateInstantiableTypes(
            type: Type,
            mapper: TypeMapper
        ): Type {
            if (type.flags & TypeFlags.Instantiable) {
                return instantiateType(type, mapper);
            }
            if (type.flags & TypeFlags.Union) {
                return getUnionType(
                    map(
                        (<UnionType> type).types,
                        t => instantiateInstantiableTypes(t, mapper)
                    ),
                    UnionReduction.None
                );
            }
            if (type.flags & TypeFlags.Intersection) {
                return getIntersectionType(
                    map(
                        (<IntersectionType> type).types,
                        t => instantiateInstantiableTypes(t, mapper)
                    )
                );
            }
            return type;
        }

        /**
         * Whoa! Do you really want to use this function?
         *
         * Unless you're trying to get the *non-apparent* type for a
         * value-literal type or you're authoring relevant portions of this algorithm,
         * you probably meant to use 'getApparentTypeOfContextualType'.
         * Otherwise this may not be very useful.
         *
         * In cases where you *are* working on this function, you should understand
         * when it is appropriate to use 'getContextualType' and 'getApparentTypeOfContextualType'.
         *
         *   - Use 'getContextualType' when you are simply going to propagate the result to the expression.
         *   - Use 'getApparentTypeOfContextualType' when you're going to need the members of the type.
         *
         * @param node the expression whose contextual type will be returned.
         * @returns the contextual type of an expression.
         */
        function getContextualType(
            node: Expression,
            contextFlags?: ContextFlags
        ): Type | undefined {
            if (node.flags & NodeFlags.InWithStatement) {
                // We cannot answer semantic questions within a with block, do not proceed any further
                return undefined;
            }
            if (node.contextualType) {
                return node.contextualType;
            }
            const { parent } = node;
            switch (parent.kind) {
                case SyntaxKind.VariableDeclaration:
                case SyntaxKind.Parameter:
                case SyntaxKind.PropertyDeclaration:
                case SyntaxKind.PropertySignature:
                case SyntaxKind.BindingElement:
                    return getContextualTypeForInitializerExpression(node);
                case SyntaxKind.ArrowFunction:
                case SyntaxKind.ReturnStatement:
                    return getContextualTypeForReturnExpression(node);
                case SyntaxKind.YieldExpression:
                    return getContextualTypeForYieldOperand(<YieldExpression> parent);
                case SyntaxKind.AwaitExpression:
                    return getContextualTypeForAwaitOperand(<AwaitExpression> parent);
                case SyntaxKind.CallExpression:
                    if ((<CallExpression> parent).expression.kind
                        === SyntaxKind.ImportKeyword)
                    {
                        return stringType;
                    }
                    /* falls through */
                case SyntaxKind.NewExpression:
                    return getContextualTypeForArgument(
                        <CallExpression | NewExpression> parent,
                        node,
                        contextFlags
                    );
                case SyntaxKind.TypeAssertionExpression:
                case SyntaxKind.AsExpression:
                    return isConstTypeReference(
                        (<AssertionExpression> parent).type
                    )
                        ? undefined
                        : getTypeFromTypeNode(
                            (<AssertionExpression> parent).type
                        );
                case SyntaxKind.BinaryExpression:
                    return getContextualTypeForBinaryOperand(
                        node,
                        contextFlags
                    );
                case SyntaxKind.PropertyAssignment:
                case SyntaxKind.ShorthandPropertyAssignment:
                    return getContextualTypeForObjectLiteralElement(
                        <PropertyAssignment
                            | ShorthandPropertyAssignment> parent,
                        contextFlags
                    );
                case SyntaxKind.SpreadAssignment:
                    return getApparentTypeOfContextualType(
                        parent.parent as ObjectLiteralExpression,
                        contextFlags
                    );
                case SyntaxKind.ArrayLiteralExpression: {
                    const arrayLiteral = <ArrayLiteralExpression> parent;
                    const type = getApparentTypeOfContextualType(
                        arrayLiteral,
                        contextFlags
                    );
                    return getContextualTypeForElementExpression(
                        type,
                        indexOfNode(arrayLiteral.elements, node)
                    );
                }
                case SyntaxKind.ConditionalExpression:
                    return getContextualTypeForConditionalOperand(
                        node,
                        contextFlags
                    );
                case SyntaxKind.TemplateSpan:
                    Debug
                        .assert(
                            parent.parent.kind
                                === SyntaxKind.TemplateExpression
                        );
                    return getContextualTypeForSubstitutionExpression(
                        <TemplateExpression> parent.parent,
                        node
                    );
                case SyntaxKind.ParenthesizedExpression: {
                    // Like in `checkParenthesizedExpression`, an `/** @type {xyz} */` comment before a parenthesized expression acts as a type cast.
                    const tag = isInJSFile(parent)
                        ? getJSDocTypeTag(parent)
                        : undefined;
                    return tag
                        ? getTypeFromTypeNode(tag.typeExpression.type)
                        : getContextualType(
                            <ParenthesizedExpression> parent,
                            contextFlags
                        );
                }
                case SyntaxKind.JsxExpression:
                    return getContextualTypeForJsxExpression(<JsxExpression> parent);
                case SyntaxKind.JsxAttribute:
                case SyntaxKind.JsxSpreadAttribute:
                    return getContextualTypeForJsxAttribute(
                        <JsxAttribute | JsxSpreadAttribute> parent
                    );
                case SyntaxKind.JsxOpeningElement:
                case SyntaxKind.JsxSelfClosingElement:
                    return getContextualJsxElementAttributesType(
                        <JsxOpeningLikeElement> parent,
                        contextFlags
                    );
            }
            return undefined;
        }

        function getInferenceContext(node: Node) {
            const ancestor = findAncestor(node, n => !!n.inferenceContext);
            return ancestor && ancestor.inferenceContext!;
        }

        function getContextualJsxElementAttributesType(
            node: JsxOpeningLikeElement,
            contextFlags?: ContextFlags
        ) {
            if (isJsxOpeningElement(node) && node.parent.contextualType
                && contextFlags !== ContextFlags.BaseConstraint)
            {
                // Contextually applied type is moved from attributes up to the outer jsx attributes so when walking up from the children they get hit
                // _However_ to hit them from the _attributes_ we must look for them here; otherwise we'll used the declared type
                // (as below) instead!
                return node.parent.contextualType;
            }
            return getContextualTypeForArgumentAtIndex(node, 0, contextFlags);
        }

        function getEffectiveFirstArgumentForJsxSignature(
            signature: Signature,
            node: JsxOpeningLikeElement
        ) {
            return getJsxReferenceKind(node) !== JsxReferenceKind.Component
                ? getJsxPropsTypeFromCallSignature(signature, node)
                : getJsxPropsTypeFromClassType(signature, node);
        }

        function getJsxPropsTypeFromCallSignature(
            sig: Signature,
            context: JsxOpeningLikeElement
        ) {
            let propsType = getTypeOfFirstParameterOfSignatureWithFallback(
                sig,
                unknownType
            );
            propsType = getJsxManagedAttributesFromLocatedAttributes(
                context,
                getJsxNamespaceAt(context),
                propsType
            );
            const intrinsicAttribs = getJsxType(
                JsxNames.IntrinsicAttributes,
                context
            );
            if (intrinsicAttribs !== errorType) {
                propsType = intersectTypes(intrinsicAttribs, propsType);
            }
            return propsType;
        }

        function getJsxPropsTypeForSignatureFromMember(
            sig: Signature,
            forcedLookupLocation: __String
        ) {
            if (sig.unionSignatures) {
                // JSX Elements using the legacy `props`-field based lookup (eg, react class components) need to treat the `props` member as an input
                // instead of an output position when resolving the signature. We need to go back to the input signatures of the composite signature,
                // get the type of `props` on each return type individually, and then _intersect them_, rather than union them (as would normally occur
                // for a union signature). It's an unfortunate quirk of looking in the output of the signature for the type we want to use for the input.
                // The default behavior of `getTypeOfFirstParameterOfSignatureWithFallback` when no `props` member name is defined is much more sane.
                const results: Type[] = [];
                for (const signature of sig.unionSignatures) {
                    const instance = getReturnTypeOfSignature(signature);
                    if (isTypeAny(instance)) {
                        return instance;
                    }
                    const propType = getTypeOfPropertyOfType(
                        instance,
                        forcedLookupLocation
                    );
                    if (!propType) {
                        return;
                    }
                    results.push(propType);
                }
                return getIntersectionType(results);
            }
            const instanceType = getReturnTypeOfSignature(sig);
            return isTypeAny(instanceType)
                ? instanceType
                : getTypeOfPropertyOfType(instanceType, forcedLookupLocation);
        }

        function getStaticTypeOfReferencedJsxConstructor(
            context: JsxOpeningLikeElement
        ) {
            if (isJsxIntrinsicIdentifier(context.tagName)) {
                const result = getIntrinsicAttributesTypeFromJsxOpeningLikeElement(context);
                const fakeSignature = createSignatureForJSXIntrinsic(
                    context,
                    result
                );
                return getOrCreateTypeFromSignature(fakeSignature);
            }
            const tagType = checkExpressionCached(context.tagName);
            if (tagType.flags & TypeFlags.StringLiteral) {
                const result = getIntrinsicAttributesTypeFromStringLiteralType(
                    tagType as StringLiteralType,
                    context
                );
                if (!result) {
                    return errorType;
                }
                const fakeSignature = createSignatureForJSXIntrinsic(
                    context,
                    result
                );
                return getOrCreateTypeFromSignature(fakeSignature);
            }
            return tagType;
        }

        function getJsxManagedAttributesFromLocatedAttributes(
            context: JsxOpeningLikeElement,
            ns: Symbol,
            attributesType: Type
        ) {
            const managedSym = getJsxLibraryManagedAttributes(ns);
            if (managedSym) {
                const declaredManagedType = getDeclaredTypeOfSymbol(managedSym);
                const ctorType = getStaticTypeOfReferencedJsxConstructor(context);
                if (length((declaredManagedType as GenericType).typeParameters)
                    >= 2)
                {
                    const args = fillMissingTypeArguments(
                        [ctorType, attributesType],
                        (declaredManagedType as GenericType).typeParameters,
                        2,
                        isInJSFile(context)
                    );
                    return createTypeReference(
                        (declaredManagedType as GenericType),
                        args
                    );
                } else if (length(declaredManagedType.aliasTypeArguments)
                    >= 2)
                {
                    const args = fillMissingTypeArguments(
                        [ctorType, attributesType],
                        declaredManagedType.aliasTypeArguments,
                        2,
                        isInJSFile(context)
                    );
                    return getTypeAliasInstantiation(
                        declaredManagedType.aliasSymbol!,
                        args
                    );
                }
            }
            return attributesType;
        }

        function getJsxPropsTypeFromClassType(
            sig: Signature,
            context: JsxOpeningLikeElement
        ) {
            const ns = getJsxNamespaceAt(context);
            const forcedLookupLocation = getJsxElementPropertiesName(ns);
            let attributesType = forcedLookupLocation === undefined
                ? // If there is no type ElementAttributesProperty, return the type of the first parameter of the signature, which should be the props type
                getTypeOfFirstParameterOfSignatureWithFallback(
                    sig,
                    unknownType
                )
                : forcedLookupLocation === ''
                    ? // If there is no e.g. 'props' member in ElementAttributesProperty, use the element class type instead
                    getReturnTypeOfSignature(sig)
                    : // Otherwise get the type of the property on the signature return type
                    getJsxPropsTypeForSignatureFromMember(
                        sig,
                        forcedLookupLocation
                    );

            if (!attributesType) {
                // There is no property named 'props' on this instance type
                if (!!forcedLookupLocation
                    && !!length(context.attributes.properties))
                {
                    error(
                        context,
                        Diagnostics
                            .JSX_element_class_does_not_support_attributes_because_it_does_not_have_a_0_property,
                        unescapeLeadingUnderscores(forcedLookupLocation)
                    );
                }
                return unknownType;
            }

            attributesType = getJsxManagedAttributesFromLocatedAttributes(
                context,
                ns,
                attributesType
            );

            if (isTypeAny(attributesType)) {
                // Props is of type 'any' or unknown
                return attributesType;
            } else {
                // Normal case -- add in IntrinsicClassElements<T> and IntrinsicElements
                let apparentAttributesType = attributesType;
                const intrinsicClassAttribs = getJsxType(
                    JsxNames.IntrinsicClassAttributes,
                    context
                );
                if (intrinsicClassAttribs !== errorType) {
                    const typeParams = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(
                        intrinsicClassAttribs.symbol
                    );
                    const hostClassType = getReturnTypeOfSignature(sig);
                    apparentAttributesType = intersectTypes(
                        typeParams
                            ? createTypeReference(
                                <GenericType> intrinsicClassAttribs,
                                fillMissingTypeArguments(
                                    [hostClassType],
                                    typeParams,
                                    getMinTypeArgumentCount(typeParams),
                                    isInJSFile(context)
                                )
                            )
                            : intrinsicClassAttribs,
                        apparentAttributesType
                    );
                }

                const intrinsicAttribs = getJsxType(
                    JsxNames.IntrinsicAttributes,
                    context
                );
                if (intrinsicAttribs !== errorType) {
                    apparentAttributesType = intersectTypes(
                        intrinsicAttribs,
                        apparentAttributesType
                    );
                }

                return apparentAttributesType;
            }
        }

        // If the given type is an object or union type with a single signature, and if that signature has at
        // least as many parameters as the given function, return the signature. Otherwise return undefined.
        function getContextualCallSignature(
            type: Type,
            node: SignatureDeclaration
        ): Signature | undefined {
            const signatures = getSignaturesOfType(type, SignatureKind.Call);
            if (signatures.length === 1) {
                const signature = signatures[0];
                if (!isAritySmaller(signature, node)) {
                    return signature;
                }
            }
        }

        /** If the contextual signature has fewer parameters than the function expression, do not use it */
        function isAritySmaller(
            signature: Signature,
            target: SignatureDeclaration
        ) {
            let targetParameterCount = 0;
            for (; targetParameterCount < target.parameters.length;
                targetParameterCount++)
            {
                const param = target.parameters[targetParameterCount];
                if (param.initializer || param.questionToken
                    || param.dotDotDotToken || isJSDocOptionalParameter(param))
                {
                    break;
                }
            }
            if (target.parameters.length
                && parameterIsThisKeyword(target.parameters[0]))
            {
                targetParameterCount--;
            }
            return !hasEffectiveRestParameter(signature)
                && getParameterCount(signature) < targetParameterCount;
        }

        function isFunctionExpressionOrArrowFunction(
            node: Node
        ): node is FunctionExpression | ArrowFunction {
            return node.kind === SyntaxKind.FunctionExpression
                || node.kind === SyntaxKind.ArrowFunction;
        }

        function getContextualSignatureForFunctionLikeDeclaration(
            node: FunctionLikeDeclaration
        ): Signature | undefined {
            // Only function expressions, arrow functions, and object literal methods are contextually typed.
            return isFunctionExpressionOrArrowFunction(node)
                || isObjectLiteralMethod(node)
                ? getContextualSignature(<FunctionExpression> node)
                : undefined;
        }

        // Return the contextual signature for a given expression node. A contextual type provides a
        // contextual signature if it has a single call signature and if that call signature is non-generic.
        // If the contextual type is a union type, get the signature from each type possible and if they are
        // all identical ignoring their return type, the result is same signature but with return type as
        // union type of return types from these signatures
        function getContextualSignature(
            node: FunctionExpression | ArrowFunction | MethodDeclaration
        ): Signature | undefined {
            Debug
                .assert(
                    node.kind !== SyntaxKind.MethodDeclaration
                        || isObjectLiteralMethod(node)
                );
            const typeTagSignature = getSignatureOfTypeTag(node);
            if (typeTagSignature) {
                return typeTagSignature;
            }
            const type = getApparentTypeOfContextualType(
                node,
                ContextFlags.Signature
            );
            if (!type) {
                return undefined;
            }
            if (!(type.flags & TypeFlags.Union)) {
                return getContextualCallSignature(type, node);
            }
            let signatureList: Signature[] | undefined;
            const types = (<UnionType> type).types;
            for (const current of types) {
                const signature = getContextualCallSignature(current, node);
                if (signature) {
                    if (!signatureList) {
                        // This signature will contribute to contextual union signature
                        signatureList = [signature];
                    } else if (!compareSignaturesIdentical(
                        signatureList[0],
                        signature, /*partialMatch*/
                        false, /*ignoreThisTypes*/
                        true, /*ignoreReturnTypes*/
                        true,
                        compareTypesIdentical
                    )) {
                        // Signatures aren't identical, do not use
                        return undefined;
                    } else {
                        // Use this signature for contextual union signature
                        signatureList.push(signature);
                    }
                }
            }
            // Result is union of signatures collected (return type is union of return types of this signature set)
            if (signatureList) {
                return signatureList.length === 1
                    ? signatureList[0]
                    : createUnionSignature(signatureList[0], signatureList);
            }
        }

        function checkSpreadExpression(
            node: SpreadElement,
            checkMode?: CheckMode
        ): Type {
            if (languageVersion < ScriptTarget.ES2015) {
                checkExternalEmitHelpers(
                    node,
                    compilerOptions.downlevelIteration
                        ? ExternalEmitHelpers.SpreadIncludes
                        : ExternalEmitHelpers.SpreadArrays
                );
            }

            const arrayOrIterableType = checkExpression(
                node.expression,
                checkMode
            );
            return checkIteratedTypeOrElementType(
                IterationUse.Spread,
                arrayOrIterableType,
                undefinedType,
                node.expression
            );
        }

        function hasDefaultValue(node: BindingElement | Expression): boolean {
            return (node.kind === SyntaxKind.BindingElement
                && !!(<BindingElement> node).initializer)
                || (node.kind === SyntaxKind.BinaryExpression
                    && (<BinaryExpression> node).operatorToken.kind
                    === SyntaxKind.EqualsToken);
        }

        function checkArrayLiteral(
            node: ArrayLiteralExpression,
            checkMode: CheckMode | undefined,
            forceTuple: boolean | undefined
        ): Type {
            const elements = node.elements;
            const elementCount = elements.length;
            let hasNonEndingSpreadElement = false;
            const elementTypes: Type[] = [];
            const inDestructuringPattern = isAssignmentTarget(node);
            const contextualType = getApparentTypeOfContextualType(node);
            const inConstContext = isConstContext(node);
            for (let index = 0; index < elementCount; index++) {
                const e = elements[index];
                if (inDestructuringPattern
                    && e.kind === SyntaxKind.SpreadElement)
                {
                    // Given the following situation:
                    //    var c: {};
                    //    [...c] = ["", 0];
                    //
                    // c is represented in the tree as a spread element in an array literal.
                    // But c really functions as a rest element, and its purpose is to provide
                    // a contextual type for the right hand side of the assignment. Therefore,
                    // instead of calling checkExpression on "...c", which will give an error
                    // if c is not iterable/array-like, we need to act as if we are trying to
                    // get the contextual element type from it. So we do something similar to
                    // getContextualTypeForElementExpression, which will crucially not error
                    // if there is no index type / iterated type.
                    const restArrayType = checkExpression(
                        (<SpreadElement> e).expression,
                        checkMode,
                        forceTuple
                    );
                    const restElementType = getIndexTypeOfType(
                        restArrayType,
                        IndexKind.Number
                    )
                        || getIteratedTypeOrElementType(
                            IterationUse.Destructuring,
                            restArrayType,
                            undefinedType, /*errorNode*/
                            undefined, /*checkAssignability*/
                            false
                        );
                    if (restElementType) {
                        elementTypes.push(restElementType);
                    }
                } else {
                    const elementContextualType = getContextualTypeForElementExpression(
                        contextualType,
                        index
                    );
                    const type = checkExpressionForMutableLocation(
                        e,
                        checkMode,
                        elementContextualType,
                        forceTuple
                    );
                    elementTypes.push(type);
                }
                if (index < elementCount - 1
                    && e.kind === SyntaxKind.SpreadElement)
                {
                    hasNonEndingSpreadElement = true;
                }
            }
            if (!hasNonEndingSpreadElement) {
                const hasRestElement = elementCount > 0
                    && elements[elementCount - 1].kind
                    === SyntaxKind.SpreadElement;
                const minLength = elementCount - (hasRestElement ? 1 : 0);
                // If array literal is actually a destructuring pattern, mark it as an implied type. We do this such
                // that we get the same behavior for "var [x, y] = []" and "[x, y] = []".
                let tupleResult;
                if (inDestructuringPattern && minLength > 0) {
                    const type = cloneTypeReference(
                        <TypeReference> createTupleType(
                            elementTypes,
                            minLength,
                            hasRestElement
                        )
                    );
                    type.pattern = node;
                    return type;
                } else if (tupleResult = getArrayLiteralTupleTypeIfApplicable(
                    elementTypes,
                    contextualType,
                    hasRestElement,
                    elementCount,
                    inConstContext
                )) {
                    return createArrayLiteralType(tupleResult);
                } else if (forceTuple) {
                    return createArrayLiteralType(
                        createTupleType(
                            elementTypes,
                            minLength,
                            hasRestElement
                        )
                    );
                }
            }
            return createArrayLiteralType(
                createArrayType(
                    elementTypes.length
                        ? getUnionType(elementTypes, UnionReduction.Subtype)
                        : strictNullChecks
                            ? implicitNeverType
                            : undefinedWideningType,
                    inConstContext
                )
            );
        }

        function createArrayLiteralType(type: ObjectType) {
            if (!(getObjectFlags(type) & ObjectFlags.Reference)) {
                return type;
            }
            let literalType = (<TypeReference> type).literalType;
            if (!literalType) {
                literalType = (<TypeReference> type)
                    .literalType = cloneTypeReference(<TypeReference> type);
                literalType
                    .objectFlags |= ObjectFlags.ArrayLiteral
                        | ObjectFlags.ContainsObjectOrArrayLiteral;
            }
            return literalType;
        }

        function getArrayLiteralTupleTypeIfApplicable(
            elementTypes: Type[],
            contextualType: Type | undefined,
            hasRestElement: boolean,
            elementCount = elementTypes.length,
            readonly = false
        ) {
            // Infer a tuple type when the contextual type is or contains a tuple-like type
            if (readonly
                || (contextualType
                    && forEachType(contextualType, isTupleLikeType)))
            {
                return createTupleType(
                    elementTypes,
                    elementCount - (hasRestElement ? 1 : 0),
                    hasRestElement,
                    readonly
                );
            }
        }

        function isNumericName(name: DeclarationName): boolean {
            switch (name.kind) {
                case SyntaxKind.ComputedPropertyName:
                    return isNumericComputedName(name);
                case SyntaxKind.Identifier:
                    return isNumericLiteralName(name.escapedText);
                case SyntaxKind.NumericLiteral:
                case SyntaxKind.StringLiteral:
                    return isNumericLiteralName(name.text);
                default:
                    return false;
            }
        }

        function isNumericComputedName(name: ComputedPropertyName): boolean {
            // It seems odd to consider an expression of type Any to result in a numeric name,
            // but this behavior is consistent with checkIndexedAccess
            return isTypeAssignableToKind(
                checkComputedPropertyName(name),
                TypeFlags.NumberLike
            );
        }

        function isInfinityOrNaNString(name: string | __String): boolean {
            return name === 'Infinity' || name === '-Infinity'
                || name === 'NaN';
        }

        function isNumericLiteralName(name: string | __String) {
            // The intent of numeric names is that
            //     - they are names with text in a numeric form, and that
            //     - setting properties/indexing with them is always equivalent to doing so with the numeric literal 'numLit',
            //         acquired by applying the abstract 'ToNumber' operation on the name's text.
            //
            // The subtlety is in the latter portion, as we cannot reliably say that anything that looks like a numeric literal is a numeric name.
            // In fact, it is the case that the text of the name must be equal to 'ToString(numLit)' for this to hold.
            //
            // Consider the property name '"0xF00D"'. When one indexes with '0xF00D', they are actually indexing with the value of 'ToString(0xF00D)'
            // according to the ECMAScript specification, so it is actually as if the user indexed with the string '"61453"'.
            // Thus, the text of all numeric literals equivalent to '61543' such as '0xF00D', '0xf00D', '0170015', etc. are not valid numeric names
            // because their 'ToString' representation is not equal to their original text.
            // This is motivated by ECMA-262 sections 9.3.1, 9.8.1, 11.1.5, and 11.2.1.
            //
            // Here, we test whether 'ToString(ToNumber(name))' is exactly equal to 'name'.
            // The '+' prefix operator is equivalent here to applying the abstract ToNumber operation.
            // Applying the 'toString()' method on a number gives us the abstract ToString operation on a number.
            //
            // Note that this accepts the values 'Infinity', '-Infinity', and 'NaN', and that this is intentional.
            // This is desired behavior, because when indexing with them as numeric entities, you are indexing
            // with the strings '"Infinity"', '"-Infinity"', and '"NaN"' respectively.
            return (+name).toString() === name;
        }

        function checkComputedPropertyName(node: ComputedPropertyName): Type {
            const links = getNodeLinks(node.expression);
            if (!links.resolvedType) {
                links.resolvedType = checkExpression(node.expression);
                // This will allow types number, string, symbol or any. It will also allow enums, the unknown
                // type, and any union of these types (like string | number).
                if (links.resolvedType.flags & TypeFlags.Nullable
                    || !isTypeAssignableToKind(
                        links.resolvedType,
                        TypeFlags.StringLike | TypeFlags.NumberLike
                            | TypeFlags.ESSymbolLike
                    )
                    && !isTypeAssignableTo(
                        links.resolvedType,
                        stringNumberSymbolType
                    ))
                {
                    error(
                        node,
                        Diagnostics
                            .A_computed_property_name_must_be_of_type_string_number_symbol_or_any
                    );
                } else {
                    checkThatExpressionIsProperSymbolReference(
                        node.expression,
                        links.resolvedType, /*reportError*/
                        true
                    );
                }
            }

            return links.resolvedType;
        }

        function getObjectLiteralIndexInfo(
            node: ObjectLiteralExpression,
            offset: number,
            properties: Symbol[],
            kind: IndexKind
        ): IndexInfo {
            const propTypes: Type[] = [];
            for (let i = 0; i < properties.length; i++) {
                if (kind === IndexKind.String
                    || isNumericName(node.properties[i + offset].name!))
                {
                    propTypes.push(getTypeOfSymbol(properties[i]));
                }
            }
            const unionType = propTypes.length
                ? getUnionType(propTypes, UnionReduction.Subtype)
                : undefinedType;
            return createIndexInfo(unionType, isConstContext(node));
        }

        function getImmediateAliasedSymbol(symbol: Symbol): Symbol
            | undefined
        {
            Debug.assert(
                (symbol.flags & SymbolFlags.Alias) !== 0,
                'Should only get Alias here.'
            );
            const links = getSymbolLinks(symbol);
            if (!links.immediateTarget) {
                const node = getDeclarationOfAliasSymbol(symbol);
                if (!node) return Debug.fail();
                links
                    .immediateTarget = getTargetOfAliasDeclaration(
                        node, /*dontRecursivelyResolve*/
                        true
                    );
            }

            return links.immediateTarget;
        }

        function checkObjectLiteral(
            node: ObjectLiteralExpression,
            checkMode?: CheckMode
        ): Type {
            const inDestructuringPattern = isAssignmentTarget(node);
            // Grammar checking
            checkGrammarObjectLiteralExpression(node, inDestructuringPattern);

            let propertiesTable: SymbolTable;
            let propertiesArray: Symbol[] = [];
            let spread: Type = emptyObjectType;

            const contextualType = getApparentTypeOfContextualType(node);
            const contextualTypeHasPattern = contextualType
                && contextualType.pattern
                && (contextualType.pattern.kind
                    === SyntaxKind.ObjectBindingPattern
                    || contextualType.pattern.kind
                    === SyntaxKind.ObjectLiteralExpression);
            const inConstContext = isConstContext(node);
            const checkFlags = inConstContext ? CheckFlags.Readonly : 0;
            const isInJavascript = isInJSFile(node) && !isInJsonFile(node);
            const enumTag = getJSDocEnumTag(node);
            const isJSObjectLiteral = !contextualType && isInJavascript
                && !enumTag;
            let objectFlags: ObjectFlags = freshObjectLiteralFlag;
            let patternWithComputedProperties = false;
            let hasComputedStringProperty = false;
            let hasComputedNumberProperty = false;
            propertiesTable = createSymbolTable();

            let offset = 0;
            for (let i = 0; i < node.properties.length; i++) {
                const memberDecl = node.properties[i];
                let member = getSymbolOfNode(memberDecl);
                const computedNameType = memberDecl.name
                    && memberDecl.name.kind === SyntaxKind.ComputedPropertyName
                    && !isWellKnownSymbolSyntactically(
                        memberDecl.name.expression
                    )
                    ? checkComputedPropertyName(memberDecl.name)
                    : undefined;
                if (memberDecl.kind === SyntaxKind.PropertyAssignment
                    || memberDecl.kind
                    === SyntaxKind.ShorthandPropertyAssignment
                    || isObjectLiteralMethod(memberDecl))
                {
                    let type = memberDecl.kind
                        === SyntaxKind.PropertyAssignment
                        ? checkPropertyAssignment(memberDecl, checkMode)
                        : memberDecl.kind
                            === SyntaxKind.ShorthandPropertyAssignment
                            ? checkExpressionForMutableLocation(
                                memberDecl.name,
                                checkMode
                            )
                            : checkObjectLiteralMethod(memberDecl, checkMode);
                    if (isInJavascript) {
                        const jsDocType = getTypeForDeclarationFromJSDocComment(memberDecl);
                        if (jsDocType) {
                            checkTypeAssignableTo(type, jsDocType, memberDecl);
                            type = jsDocType;
                        } else if (enumTag && enumTag.typeExpression) {
                            checkTypeAssignableTo(
                                type,
                                getTypeFromTypeNode(enumTag.typeExpression),
                                memberDecl
                            );
                        }
                    }
                    objectFlags |= getObjectFlags(type)
                        & ObjectFlags.PropagatingFlags;
                    const nameType = computedNameType
                        && isTypeUsableAsPropertyName(computedNameType)
                        ? computedNameType
                        : undefined;
                    const prop = nameType
                        ? createSymbol(
                            SymbolFlags.Property | member.flags,
                            getPropertyNameFromType(nameType),
                            checkFlags | CheckFlags.Late
                        )
                        : createSymbol(
                            SymbolFlags.Property | member.flags,
                            member.escapedName,
                            checkFlags
                        );
                    if (nameType) {
                        prop.nameType = nameType;
                    }

                    if (inDestructuringPattern) {
                        // If object literal is an assignment pattern and if the assignment pattern specifies a default value
                        // for the property, make the property optional.
                        const isOptional = (memberDecl.kind
                            === SyntaxKind.PropertyAssignment
                            && hasDefaultValue(memberDecl.initializer))
                            || (memberDecl.kind
                                === SyntaxKind.ShorthandPropertyAssignment
                                && memberDecl.objectAssignmentInitializer);
                        if (isOptional) {
                            prop.flags |= SymbolFlags.Optional;
                        }
                    } else if (contextualTypeHasPattern
                        && !(getObjectFlags(contextualType!)
                            & ObjectFlags
                                .ObjectLiteralPatternWithComputedProperties))
                    {
                        // If object literal is contextually typed by the implied type of a binding pattern, and if the
                        // binding pattern specifies a default value for the property, make the property optional.
                        const impliedProp = getPropertyOfType(
                            contextualType!,
                            member.escapedName
                        );
                        if (impliedProp) {
                            prop
                                .flags |= impliedProp.flags
                                    & SymbolFlags.Optional;
                        } else if (!compilerOptions
                            .suppressExcessPropertyErrors
                            && !getIndexInfoOfType(
                                contextualType!,
                                IndexKind.String
                            ))
                        {
                            error(
                                memberDecl.name,
                                Diagnostics
                                    .Object_literal_may_only_specify_known_properties_and_0_does_not_exist_in_type_1,
                                symbolToString(member),
                                typeToString(contextualType!)
                            );
                        }
                    }

                    prop.declarations = member.declarations;
                    prop.parent = member.parent;
                    if (member.valueDeclaration) {
                        prop.valueDeclaration = member.valueDeclaration;
                    }

                    prop.type = type;
                    prop.target = member;
                    member = prop;
                } else if (memberDecl.kind === SyntaxKind.SpreadAssignment) {
                    if (languageVersion < ScriptTarget.ES2015) {
                        checkExternalEmitHelpers(
                            memberDecl,
                            ExternalEmitHelpers.Assign
                        );
                    }
                    if (propertiesArray.length > 0) {
                        spread = getSpreadType(
                            spread,
                            createObjectLiteralType(),
                            node.symbol,
                            objectFlags,
                            inConstContext
                        );
                        propertiesArray = [];
                        propertiesTable = createSymbolTable();
                        hasComputedStringProperty = false;
                        hasComputedNumberProperty = false;
                    }
                    const type = checkExpression(memberDecl.expression);
                    if (!isValidSpreadType(type)) {
                        error(
                            memberDecl,
                            Diagnostics
                                .Spread_types_may_only_be_created_from_object_types
                        );
                        return errorType;
                    }
                    spread = getSpreadType(
                        spread,
                        type,
                        node.symbol,
                        objectFlags,
                        inConstContext
                    );
                    offset = i + 1;
                    continue;
                } else {
                    // TypeScript 1.0 spec (April 2014)
                    // A get accessor declaration is processed in the same manner as
                    // an ordinary function declaration(section 6.1) with no parameters.
                    // A set accessor declaration is processed in the same manner
                    // as an ordinary function declaration with a single parameter and a Void return type.
                    Debug
                        .assert(
                            memberDecl.kind === SyntaxKind.GetAccessor
                                || memberDecl.kind === SyntaxKind.SetAccessor
                        );
                    checkNodeDeferred(memberDecl);
                }

                if (computedNameType
                    && !(computedNameType.flags
                        & TypeFlags.StringOrNumberLiteralOrUnique))
                {
                    if (isTypeAssignableTo(
                        computedNameType,
                        stringNumberSymbolType
                    )) {
                        if (isTypeAssignableTo(computedNameType, numberType)) {
                            hasComputedNumberProperty = true;
                        } else {
                            hasComputedStringProperty = true;
                        }
                        if (inDestructuringPattern) {
                            patternWithComputedProperties = true;
                        }
                    }
                } else {
                    propertiesTable.set(member.escapedName, member);
                }
                propertiesArray.push(member);
            }

            // If object literal is contextually typed by the implied type of a binding pattern, augment the result
            // type with those properties for which the binding pattern specifies a default value.
            if (contextualTypeHasPattern) {
                for (const prop of getPropertiesOfType(contextualType!)) {
                    if (!propertiesTable.get(prop.escapedName)
                        && !(spread
                            && getPropertyOfType(spread, prop.escapedName)))
                    {
                        if (!(prop.flags & SymbolFlags.Optional)) {
                            error(
                                prop.valueDeclaration
                                    || (<TransientSymbol> prop).bindingElement,
                                Diagnostics
                                    .Initializer_provides_no_value_for_this_binding_element_and_the_binding_element_has_no_default_value
                            );
                        }
                        propertiesTable.set(prop.escapedName, prop);
                        propertiesArray.push(prop);
                    }
                }
            }

            if (spread !== emptyObjectType) {
                if (propertiesArray.length > 0) {
                    spread = getSpreadType(
                        spread,
                        createObjectLiteralType(),
                        node.symbol,
                        objectFlags,
                        inConstContext
                    );
                    propertiesArray = [];
                    propertiesTable = createSymbolTable();
                    hasComputedStringProperty = false;
                    hasComputedNumberProperty = false;
                }
                // remap the raw emptyObjectType fed in at the top into a fresh empty object literal type, unique to this use site
                return mapType(
                    spread,
                    t => t === emptyObjectType ? createObjectLiteralType() : t
                );
            }

            return createObjectLiteralType();

            function createObjectLiteralType() {
                const stringIndexInfo = hasComputedStringProperty
                    ? getObjectLiteralIndexInfo(
                        node,
                        offset,
                        propertiesArray,
                        IndexKind.String
                    )
                    : undefined;
                const numberIndexInfo = hasComputedNumberProperty
                    ? getObjectLiteralIndexInfo(
                        node,
                        offset,
                        propertiesArray,
                        IndexKind.Number
                    )
                    : undefined;
                const result = createAnonymousType(
                    node.symbol,
                    propertiesTable,
                    emptyArray,
                    emptyArray,
                    stringIndexInfo,
                    numberIndexInfo
                );
                result
                    .objectFlags |= objectFlags | ObjectFlags.ObjectLiteral
                        | ObjectFlags.ContainsObjectOrArrayLiteral;
                if (isJSObjectLiteral) {
                    result.objectFlags |= ObjectFlags.JSLiteral;
                }
                if (patternWithComputedProperties) {
                    result.objectFlags |= ObjectFlags
                        .ObjectLiteralPatternWithComputedProperties;
                }
                if (inDestructuringPattern) {
                    result.pattern = node;
                }
                return result;
            }
        }

        function isValidSpreadType(type: Type): boolean {
            if (type.flags & TypeFlags.Instantiable) {
                const constraint = getBaseConstraintOfType(type);
                if (constraint !== undefined) {
                    return isValidSpreadType(constraint);
                }
            }
            return !!(type.flags
                & (TypeFlags.Any | TypeFlags.NonPrimitive | TypeFlags.Object
                    | TypeFlags.InstantiableNonPrimitive)
                || getFalsyFlags(type) & TypeFlags.DefinitelyFalsy
                && isValidSpreadType(removeDefinitelyFalsyTypes(type))
                || type.flags & TypeFlags.UnionOrIntersection
                && every(
                    (<UnionOrIntersectionType> type).types,
                    isValidSpreadType
                ));
        }

        function checkJsxSelfClosingElementDeferred(
            node: JsxSelfClosingElement
        ) {
            checkJsxOpeningLikeElementOrOpeningFragment(node);
        }

        function checkJsxSelfClosingElement(
            node: JsxSelfClosingElement,
            _checkMode: CheckMode | undefined
        ): Type {
            checkNodeDeferred(node);
            return getJsxElementTypeAt(node) || anyType;
        }

        function checkJsxElementDeferred(node: JsxElement) {
            // Check attributes
            checkJsxOpeningLikeElementOrOpeningFragment(node.openingElement);

            // Perform resolution on the closing tag so that rename/go to definition/etc work
            if (isJsxIntrinsicIdentifier(node.closingElement.tagName)) {
                getIntrinsicTagSymbol(node.closingElement);
            } else {
                checkExpression(node.closingElement.tagName);
            }

            checkJsxChildren(node);
        }

        function checkJsxElement(
            node: JsxElement,
            _checkMode: CheckMode | undefined
        ): Type {
            checkNodeDeferred(node);

            return getJsxElementTypeAt(node) || anyType;
        }

        function checkJsxFragment(node: JsxFragment): Type {
            checkJsxOpeningLikeElementOrOpeningFragment(node.openingFragment);

            if (compilerOptions.jsx === JsxEmit.React
                && (compilerOptions.jsxFactory
                    || getSourceFileOfNode(node).pragmas.has('jsx')))
            {
                error(
                    node,
                    compilerOptions.jsxFactory
                        ? Diagnostics
                            .JSX_fragment_is_not_supported_when_using_jsxFactory
                        : Diagnostics
                            .JSX_fragment_is_not_supported_when_using_an_inline_JSX_factory_pragma
                );
            }

            checkJsxChildren(node);
            return getJsxElementTypeAt(node) || anyType;
        }

        /**
         * Returns true iff the JSX element name would be a valid JS identifier, ignoring restrictions about keywords not being identifiers
         */
        function isUnhyphenatedJsxName(name: string | __String) {
            // - is the only character supported in JSX attribute names that isn't valid in JavaScript identifiers
            return !stringContains(name as string, '-');
        }

        /**
         * Returns true iff React would emit this tag name as a string rather than an identifier or qualified name
         */
        function isJsxIntrinsicIdentifier(
            tagName: JsxTagNameExpression
        ): boolean {
            return tagName.kind === SyntaxKind.Identifier
                && isIntrinsicJsxName(tagName.escapedText);
        }

        function checkJsxAttribute(node: JsxAttribute, checkMode?: CheckMode) {
            return node.initializer
                ? checkExpressionForMutableLocation(
                    node.initializer,
                    checkMode
                )
                : trueType; // <Elem attr /> is sugar for <Elem attr={true} />
        }

        /**
         * Get attributes type of the JSX opening-like element. The result is from resolving "attributes" property of the opening-like element.
         *
         * @param openingLikeElement a JSX opening-like element
         * @param filter a function to remove attributes that will not participate in checking whether attributes are assignable
         * @return an anonymous type (similar to the one returned by checkObjectLiteral) in which its properties are attributes property.
         * @remarks Because this function calls getSpreadType, it needs to use the same checks as checkObjectLiteral,
         * which also calls getSpreadType.
         */
        function createJsxAttributesTypeFromAttributesProperty(
            openingLikeElement: JsxOpeningLikeElement,
            checkMode: CheckMode | undefined
        ) {
            const attributes = openingLikeElement.attributes;
            let attributesTable = createSymbolTable();
            let spread: Type = emptyJsxObjectType;
            let hasSpreadAnyType = false;
            let typeToIntersect: Type | undefined;
            let explicitlySpecifyChildrenAttribute = false;
            let objectFlags: ObjectFlags = ObjectFlags.JsxAttributes;
            const jsxChildrenPropertyName = getJsxElementChildrenPropertyName(getJsxNamespaceAt(openingLikeElement));

            for (const attributeDecl of attributes.properties) {
                const member = attributeDecl.symbol;
                if (isJsxAttribute(attributeDecl)) {
                    const exprType = checkJsxAttribute(
                        attributeDecl,
                        checkMode
                    );
                    objectFlags |= getObjectFlags(exprType)
                        & ObjectFlags.PropagatingFlags;

                    const attributeSymbol = createSymbol(
                        SymbolFlags.Property | SymbolFlags.Transient
                            | member.flags,
                        member.escapedName
                    );
                    attributeSymbol.declarations = member.declarations;
                    attributeSymbol.parent = member.parent;
                    if (member.valueDeclaration) {
                        attributeSymbol.valueDeclaration = member
                            .valueDeclaration;
                    }
                    attributeSymbol.type = exprType;
                    attributeSymbol.target = member;
                    attributesTable.set(
                        attributeSymbol.escapedName,
                        attributeSymbol
                    );
                    if (attributeDecl.name.escapedText
                        === jsxChildrenPropertyName)
                    {
                        explicitlySpecifyChildrenAttribute = true;
                    }
                } else {
                    Debug
                        .assert(
                            attributeDecl.kind
                                === SyntaxKind.JsxSpreadAttribute
                        );
                    if (attributesTable.size > 0) {
                        spread = getSpreadType(
                            spread,
                            createJsxAttributesType(),
                            attributes.symbol,
                            objectFlags, /*readonly*/
                            false
                        );
                        attributesTable = createSymbolTable();
                    }
                    const exprType = checkExpressionCached(
                        attributeDecl.expression,
                        checkMode
                    );
                    if (isTypeAny(exprType)) {
                        hasSpreadAnyType = true;
                    }
                    if (isValidSpreadType(exprType)) {
                        spread = getSpreadType(
                            spread,
                            exprType,
                            attributes.symbol,
                            objectFlags, /*readonly*/
                            false
                        );
                    } else {
                        typeToIntersect = typeToIntersect
                            ? getIntersectionType([typeToIntersect, exprType])
                            : exprType;
                    }
                }
            }

            if (!hasSpreadAnyType) {
                if (attributesTable.size > 0) {
                    spread = getSpreadType(
                        spread,
                        createJsxAttributesType(),
                        attributes.symbol,
                        objectFlags, /*readonly*/
                        false
                    );
                }
            }

            // Handle children attribute
            const parent = openingLikeElement.parent.kind
                === SyntaxKind.JsxElement
                ? openingLikeElement.parent as JsxElement
                : undefined;
            // We have to check that openingElement of the parent is the one we are visiting as this may not be true for selfClosingElement
            if (parent && parent.openingElement === openingLikeElement
                && parent.children.length > 0)
            {
                const childrenTypes: Type[] = checkJsxChildren(
                    parent,
                    checkMode
                );

                if (!hasSpreadAnyType && jsxChildrenPropertyName
                    && jsxChildrenPropertyName !== '')
                {
                    // Error if there is a attribute named "children" explicitly specified and children element.
                    // This is because children element will overwrite the value from attributes.
                    // Note: we will not warn "children" attribute overwritten if "children" attribute is specified in object spread.
                    if (explicitlySpecifyChildrenAttribute) {
                        error(
                            attributes,
                            Diagnostics
                                ._0_are_specified_twice_The_attribute_named_0_will_be_overwritten,
                            unescapeLeadingUnderscores(jsxChildrenPropertyName)
                        );
                    }

                    const contextualType = getApparentTypeOfContextualType(
                        openingLikeElement.attributes
                    );
                    const childrenContextualType = contextualType
                        && getTypeOfPropertyOfContextualType(
                            contextualType,
                            jsxChildrenPropertyName
                        );
                    // If there are children in the body of JSX element, create dummy attribute "children" with the union of children types so that it will pass the attribute checking process
                    const childrenPropSymbol = createSymbol(
                        SymbolFlags.Property | SymbolFlags.Transient,
                        jsxChildrenPropertyName
                    );
                    childrenPropSymbol.type = childrenTypes.length === 1
                        ? childrenTypes[0]
                        : (getArrayLiteralTupleTypeIfApplicable(
                            childrenTypes,
                            childrenContextualType, /*hasRestElement*/
                            false
                        ) || createArrayType(getUnionType(childrenTypes)));
                    // Fake up a property declaration for the children
                    childrenPropSymbol
                        .valueDeclaration = createPropertySignature(
                            /*modifiers*/ undefined,
                            unescapeLeadingUnderscores(jsxChildrenPropertyName), /*questionToken*/
                            undefined, /*type*/
                            undefined, /*initializer*/
                            undefined
                        );
                    childrenPropSymbol.valueDeclaration.parent = attributes;
                    childrenPropSymbol.valueDeclaration
                        .symbol = childrenPropSymbol;
                    const childPropMap = createSymbolTable();
                    childPropMap.set(
                        jsxChildrenPropertyName,
                        childrenPropSymbol
                    );
                    spread = getSpreadType(
                        spread,
                        createAnonymousType(
                            attributes.symbol,
                            childPropMap,
                            emptyArray,
                            emptyArray, /*stringIndexInfo*/
                            undefined, /*numberIndexInfo*/
                            undefined
                        ),
                        attributes.symbol,
                        objectFlags, /*readonly*/
                        false
                    );
                }
            }

            if (hasSpreadAnyType) {
                return anyType;
            }
            if (typeToIntersect && spread !== emptyJsxObjectType) {
                return getIntersectionType([typeToIntersect, spread]);
            }
            return typeToIntersect
                || (spread === emptyJsxObjectType
                    ? createJsxAttributesType()
                    : spread);

            /**
             * Create anonymous type from given attributes symbol table.
             * @param symbol a symbol of JsxAttributes containing attributes corresponding to attributesTable
             * @param attributesTable a symbol table of attributes property
             */
            function createJsxAttributesType() {
                objectFlags |= freshObjectLiteralFlag;
                const result = createAnonymousType(
                    attributes.symbol,
                    attributesTable,
                    emptyArray,
                    emptyArray, /*stringIndexInfo*/
                    undefined, /*numberIndexInfo*/
                    undefined
                );
                result
                    .objectFlags |= objectFlags | ObjectFlags.ObjectLiteral
                        | ObjectFlags.ContainsObjectOrArrayLiteral;
                return result;
            }
        }

        function checkJsxChildren(
            node: JsxElement | JsxFragment,
            checkMode?: CheckMode
        ) {
            const childrenTypes: Type[] = [];
            for (const child of node.children) {
                // In React, JSX text that contains only whitespaces will be ignored so we don't want to type-check that
                // because then type of children property will have constituent of string type.
                if (child.kind === SyntaxKind.JsxText) {
                    if (!child.containsOnlyTriviaWhiteSpaces) {
                        childrenTypes.push(stringType);
                    }
                } else {
                    childrenTypes
                        .push(
                            checkExpressionForMutableLocation(
                                child,
                                checkMode
                            )
                        );
                }
            }
            return childrenTypes;
        }

        /**
         * Check attributes property of opening-like element. This function is called during chooseOverload to get call signature of a JSX opening-like element.
         * (See "checkApplicableSignatureForJsxOpeningLikeElement" for how the function is used)
         * @param node a JSXAttributes to be resolved of its type
         */
        function checkJsxAttributes(
            node: JsxAttributes,
            checkMode: CheckMode | undefined
        ) {
            return createJsxAttributesTypeFromAttributesProperty(
                node.parent,
                checkMode
            );
        }

        function getJsxType(name: __String, location: Node | undefined) {
            const namespace = getJsxNamespaceAt(location);
            const exports = namespace && getExportsOfSymbol(namespace);
            const typeSymbol = exports
                && getSymbol(exports, name, SymbolFlags.Type);
            return typeSymbol
                ? getDeclaredTypeOfSymbol(typeSymbol)
                : errorType;
        }

        /**
         * Looks up an intrinsic tag name and returns a symbol that either points to an intrinsic
         * property (in which case nodeLinks.jsxFlags will be IntrinsicNamedElement) or an intrinsic
         * string index signature (in which case nodeLinks.jsxFlags will be IntrinsicIndexedElement).
         * May also return unknownSymbol if both of these lookups fail.
         */
        function getIntrinsicTagSymbol(
            node: JsxOpeningLikeElement | JsxClosingElement
        ): Symbol {
            const links = getNodeLinks(node);
            if (!links.resolvedSymbol) {
                const intrinsicElementsType = getJsxType(
                    JsxNames.IntrinsicElements,
                    node
                );
                if (intrinsicElementsType !== errorType) {
                    // Property case
                    if (!isIdentifier(node.tagName)) return Debug.fail();
                    const intrinsicProp = getPropertyOfType(
                        intrinsicElementsType,
                        node.tagName.escapedText
                    );
                    if (intrinsicProp) {
                        links.jsxFlags |= JsxFlags.IntrinsicNamedElement;
                        return links.resolvedSymbol = intrinsicProp;
                    }

                    // Intrinsic string indexer case
                    const indexSignatureType = getIndexTypeOfType(
                        intrinsicElementsType,
                        IndexKind.String
                    );
                    if (indexSignatureType) {
                        links.jsxFlags |= JsxFlags.IntrinsicIndexedElement;
                        return links.resolvedSymbol = intrinsicElementsType
                            .symbol;
                    }

                    // Wasn't found
                    error(
                        node,
                        Diagnostics.Property_0_does_not_exist_on_type_1,
                        idText(node.tagName),
                        'JSX.' + JsxNames.IntrinsicElements
                    );
                    return links.resolvedSymbol = unknownSymbol;
                } else {
                    if (noImplicitAny) {
                        error(
                            node,
                            Diagnostics
                                .JSX_element_implicitly_has_type_any_because_no_interface_JSX_0_exists,
                            unescapeLeadingUnderscores(
                                JsxNames.IntrinsicElements
                            )
                        );
                    }
                    return links.resolvedSymbol = unknownSymbol;
                }
            }
            return links.resolvedSymbol;
        }

        function getJsxNamespaceAt(location: Node | undefined): Symbol {
            const links = location && getNodeLinks(location);
            if (links && links.jsxNamespace) {
                return links.jsxNamespace;
            }
            if (!links || links.jsxNamespace !== false) {
                const namespaceName = getJsxNamespace(location);
                const resolvedNamespace = resolveName(
                    location,
                    namespaceName,
                    SymbolFlags.Namespace, /*diagnosticMessage*/
                    undefined,
                    namespaceName, /*isUse*/
                    false
                );
                if (resolvedNamespace) {
                    const candidate = resolveSymbol(
                        getSymbol(
                            getExportsOfSymbol(resolveSymbol(resolvedNamespace)),
                            JsxNames.JSX,
                            SymbolFlags.Namespace
                        )
                    );
                    if (candidate) {
                        if (links) {
                            links.jsxNamespace = candidate;
                        }
                        return candidate;
                    }
                    if (links) {
                        links.jsxNamespace = false;
                    }
                }
            }
            // JSX global fallback
            return getGlobalSymbol(
                JsxNames.JSX,
                SymbolFlags.Namespace, /*diagnosticMessage*/
                undefined
            )!; // TODO: GH#18217
        }

        /**
         * Look into JSX namespace and then look for container with matching name as nameOfAttribPropContainer.
         * Get a single property from that container if existed. Report an error if there are more than one property.
         *
         * @param nameOfAttribPropContainer a string of value JsxNames.ElementAttributesPropertyNameContainer or JsxNames.ElementChildrenAttributeNameContainer
         *          if other string is given or the container doesn't exist, return undefined.
         */
        function getNameFromJsxElementAttributesContainer(
            nameOfAttribPropContainer: __String,
            jsxNamespace: Symbol
        ): __String | undefined {
            // JSX.ElementAttributesProperty | JSX.ElementChildrenAttribute [symbol]
            const jsxElementAttribPropInterfaceSym = jsxNamespace
                && getSymbol(
                    jsxNamespace.exports!,
                    nameOfAttribPropContainer,
                    SymbolFlags.Type
                );
            // JSX.ElementAttributesProperty | JSX.ElementChildrenAttribute [type]
            const jsxElementAttribPropInterfaceType = jsxElementAttribPropInterfaceSym
                && getDeclaredTypeOfSymbol(jsxElementAttribPropInterfaceSym);
            // The properties of JSX.ElementAttributesProperty | JSX.ElementChildrenAttribute
            const propertiesOfJsxElementAttribPropInterface = jsxElementAttribPropInterfaceType
                && getPropertiesOfType(jsxElementAttribPropInterfaceType);
            if (propertiesOfJsxElementAttribPropInterface) {
                // Element Attributes has zero properties, so the element attributes type will be the class instance type
                if (propertiesOfJsxElementAttribPropInterface.length === 0) {
                    return '' as __String;
                } // Element Attributes has one property, so the element attributes type will be the type of the corresponding
                // property of the class instance type
                else if (propertiesOfJsxElementAttribPropInterface.length
                    === 1)
                {
                    return propertiesOfJsxElementAttribPropInterface[0]
                        .escapedName;
                } else if (propertiesOfJsxElementAttribPropInterface.length
                    > 1)
                {
                    // More than one property on ElementAttributesProperty is an error
                    error(
                        jsxElementAttribPropInterfaceSym!.declarations[0],
                        Diagnostics
                            .The_global_type_JSX_0_may_not_have_more_than_one_property,
                        unescapeLeadingUnderscores(nameOfAttribPropContainer)
                    );
                }
            }
            return undefined;
        }

        function getJsxLibraryManagedAttributes(jsxNamespace: Symbol) {
            // JSX.LibraryManagedAttributes [symbol]
            return jsxNamespace
                && getSymbol(
                    jsxNamespace.exports!,
                    JsxNames.LibraryManagedAttributes,
                    SymbolFlags.Type
                );
        }

        /// e.g. "props" for React.d.ts,
        /// or 'undefined' if ElementAttributesProperty doesn't exist (which means all
        ///     non-intrinsic elements' attributes type is 'any'),
        /// or '' if it has 0 properties (which means every
        ///     non-intrinsic elements' attributes type is the element instance type)
        function getJsxElementPropertiesName(jsxNamespace: Symbol) {
            return getNameFromJsxElementAttributesContainer(
                JsxNames.ElementAttributesPropertyNameContainer,
                jsxNamespace
            );
        }

        function getJsxElementChildrenPropertyName(
            jsxNamespace: Symbol
        ): __String | undefined {
            return getNameFromJsxElementAttributesContainer(
                JsxNames.ElementChildrenAttributeNameContainer,
                jsxNamespace
            );
        }

        function getUninstantiatedJsxSignaturesOfType(
            elementType: Type,
            caller: JsxOpeningLikeElement
        ): readonly Signature[] {
            if (elementType.flags & TypeFlags.String) {
                return [anySignature];
            } else if (elementType.flags & TypeFlags.StringLiteral) {
                const intrinsicType = getIntrinsicAttributesTypeFromStringLiteralType(
                    elementType as StringLiteralType,
                    caller
                );
                if (!intrinsicType) {
                    error(
                        caller,
                        Diagnostics.Property_0_does_not_exist_on_type_1,
                        (elementType as StringLiteralType).value,
                        'JSX.' + JsxNames.IntrinsicElements
                    );
                    return emptyArray;
                } else {
                    const fakeSignature = createSignatureForJSXIntrinsic(
                        caller,
                        intrinsicType
                    );
                    return [fakeSignature];
                }
            }
            const apparentElemType = getApparentType(elementType);
            // Resolve the signatures, preferring constructor
            let signatures = getSignaturesOfType(
                apparentElemType,
                SignatureKind.Construct
            );
            if (signatures.length === 0) {
                // No construct signatures, try call signatures
                signatures = getSignaturesOfType(
                    apparentElemType,
                    SignatureKind.Call
                );
            }
            if (signatures.length === 0
                && apparentElemType.flags & TypeFlags.Union)
            {
                // If each member has some combination of new/call signatures; make a union signature list for those
                signatures = getUnionSignatures(
                    map(
                        (apparentElemType as UnionType).types,
                        t => getUninstantiatedJsxSignaturesOfType(t, caller)
                    )
                );
            }
            return signatures;
        }

        function getIntrinsicAttributesTypeFromStringLiteralType(
            type: StringLiteralType,
            location: Node
        ): Type | undefined {
            // If the elemType is a stringLiteral type, we can then provide a check to make sure that the string literal type is one of the Jsx intrinsic element type
            // For example:
            //      var CustomTag: "h1" = "h1";
            //      <CustomTag> Hello World </CustomTag>
            const intrinsicElementsType = getJsxType(
                JsxNames.IntrinsicElements,
                location
            );
            if (intrinsicElementsType !== errorType) {
                const stringLiteralTypeName = type.value;
                const intrinsicProp = getPropertyOfType(
                    intrinsicElementsType,
                    escapeLeadingUnderscores(stringLiteralTypeName)
                );
                if (intrinsicProp) {
                    return getTypeOfSymbol(intrinsicProp);
                }
                const indexSignatureType = getIndexTypeOfType(
                    intrinsicElementsType,
                    IndexKind.String
                );
                if (indexSignatureType) {
                    return indexSignatureType;
                }
                return undefined;
            }
            // If we need to report an error, we already done so here. So just return any to prevent any more error downstream
            return anyType;
        }

        function checkJsxReturnAssignableToAppropriateBound(
            refKind: JsxReferenceKind,
            elemInstanceType: Type,
            openingLikeElement: Node
        ) {
            if (refKind === JsxReferenceKind.Function) {
                const sfcReturnConstraint = getJsxStatelessElementTypeAt(openingLikeElement);
                if (sfcReturnConstraint) {
                    checkTypeRelatedTo(
                        elemInstanceType,
                        sfcReturnConstraint,
                        assignableRelation,
                        openingLikeElement,
                        Diagnostics
                            .JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements
                    );
                }
            } else if (refKind === JsxReferenceKind.Component) {
                const classConstraint = getJsxElementClassTypeAt(openingLikeElement);
                if (classConstraint) {
                    // Issue an error if this return type isn't assignable to JSX.ElementClass or JSX.Element, failing that
                    checkTypeRelatedTo(
                        elemInstanceType,
                        classConstraint,
                        assignableRelation,
                        openingLikeElement,
                        Diagnostics
                            .JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements
                    );
                }
            } else { // Mixed
                const sfcReturnConstraint = getJsxStatelessElementTypeAt(openingLikeElement);
                const classConstraint = getJsxElementClassTypeAt(openingLikeElement);
                if (!sfcReturnConstraint || !classConstraint) {
                    return;
                }
                const combined = getUnionType(
                    [sfcReturnConstraint, classConstraint]
                );
                checkTypeRelatedTo(
                    elemInstanceType,
                    combined,
                    assignableRelation,
                    openingLikeElement,
                    Diagnostics
                        .JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements
                );
            }
        }

        /**
         * Get attributes type of the given intrinsic opening-like Jsx element by resolving the tag name.
         * The function is intended to be called from a function which has checked that the opening element is an intrinsic element.
         * @param node an intrinsic JSX opening-like element
         */
        function getIntrinsicAttributesTypeFromJsxOpeningLikeElement(
            node: JsxOpeningLikeElement
        ): Type {
            Debug.assert(isJsxIntrinsicIdentifier(node.tagName));
            const links = getNodeLinks(node);
            if (!links.resolvedJsxElementAttributesType) {
                const symbol = getIntrinsicTagSymbol(node);
                if (links.jsxFlags & JsxFlags.IntrinsicNamedElement) {
                    return links
                        .resolvedJsxElementAttributesType = getTypeOfSymbol(symbol);
                } else if (links.jsxFlags & JsxFlags.IntrinsicIndexedElement) {
                    return links
                        .resolvedJsxElementAttributesType = getIndexTypeOfType(
                            getDeclaredTypeOfSymbol(symbol),
                            IndexKind.String
                        )!;
                } else {
                    return links.resolvedJsxElementAttributesType = errorType;
                }
            }
            return links.resolvedJsxElementAttributesType;
        }

        function getJsxElementClassTypeAt(location: Node): Type | undefined {
            const type = getJsxType(JsxNames.ElementClass, location);
            if (type === errorType) return undefined;
            return type;
        }

        function getJsxElementTypeAt(location: Node): Type {
            return getJsxType(JsxNames.Element, location);
        }

        function getJsxStatelessElementTypeAt(location: Node): Type
            | undefined
        {
            const jsxElementType = getJsxElementTypeAt(location);
            if (jsxElementType) {
                return getUnionType([jsxElementType, nullType]);
            }
        }

        /**
         * Returns all the properties of the Jsx.IntrinsicElements interface
         */
        function getJsxIntrinsicTagNamesAt(location: Node): Symbol[] {
            const intrinsics = getJsxType(JsxNames.IntrinsicElements,
                location);
            return intrinsics ? getPropertiesOfType(intrinsics) : emptyArray;
        }

        function checkJsxPreconditions(errorNode: Node) {
            // Preconditions for using JSX
            if ((compilerOptions.jsx || JsxEmit.None) === JsxEmit.None) {
                error(
                    errorNode,
                    Diagnostics.Cannot_use_JSX_unless_the_jsx_flag_is_provided
                );
            }

            if (getJsxElementTypeAt(errorNode) === undefined) {
                if (noImplicitAny) {
                    error(
                        errorNode,
                        Diagnostics
                            .JSX_element_implicitly_has_type_any_because_the_global_type_JSX_Element_does_not_exist
                    );
                }
            }
        }

        function checkJsxOpeningLikeElementOrOpeningFragment(
            node: JsxOpeningLikeElement | JsxOpeningFragment
        ) {
            const isNodeOpeningLikeElement = isJsxOpeningLikeElement(node);

            if (isNodeOpeningLikeElement) {
                checkGrammarJsxElement(<JsxOpeningLikeElement> node);
            }
            checkJsxPreconditions(node);
            // The reactNamespace/jsxFactory's root symbol should be marked as 'used' so we don't incorrectly elide its import.
            // And if there is no reactNamespace/jsxFactory's symbol in scope when targeting React emit, we should issue an error.
            const reactRefErr = diagnostics
                && compilerOptions.jsx === JsxEmit.React
                ? Diagnostics.Cannot_find_name_0
                : undefined;
            const reactNamespace = getJsxNamespace(node);
            const reactLocation = isNodeOpeningLikeElement
                ? (<JsxOpeningLikeElement> node).tagName
                : node;
            const reactSym = resolveName(
                reactLocation,
                reactNamespace,
                SymbolFlags.Value,
                reactRefErr,
                reactNamespace, /*isUse*/
                true
            );
            if (reactSym) {
                // Mark local symbol as referenced here because it might not have been marked
                // if jsx emit was not react as there wont be error being emitted
                reactSym.isReferenced = SymbolFlags.All;

                // If react symbol is alias, mark it as refereced
                if (reactSym.flags & SymbolFlags.Alias) {
                    markAliasSymbolAsReferenced(reactSym);
                }
            }

            if (isNodeOpeningLikeElement) {
                const sig = getResolvedSignature(node as JsxOpeningLikeElement);
                checkJsxReturnAssignableToAppropriateBound(
                    getJsxReferenceKind(node as JsxOpeningLikeElement),
                    getReturnTypeOfSignature(sig),
                    node
                );
            }
        }

        /**
         * Check if a property with the given name is known anywhere in the given type. In an object type, a property
         * is considered known if
         * 1. the object type is empty and the check is for assignability, or
         * 2. if the object type has index signatures, or
         * 3. if the property is actually declared in the object type
         *    (this means that 'toString', for example, is not usually a known property).
         * 4. In a union or intersection type,
         *    a property is considered known if it is known in any constituent type.
         * @param targetType a type to search a given name in
         * @param name a property name to search
         * @param isComparingJsxAttributes a boolean flag indicating whether we are searching in JsxAttributesType
         */
        function isKnownProperty(
            targetType: Type,
            name: __String,
            isComparingJsxAttributes: boolean
        ): boolean {
            if (targetType.flags & TypeFlags.Object) {
                const resolved = resolveStructuredTypeMembers(targetType as ObjectType);
                if (resolved.stringIndexInfo
                    || resolved.numberIndexInfo && isNumericLiteralName(name)
                    || getPropertyOfObjectType(targetType, name)
                    || isComparingJsxAttributes
                    && !isUnhyphenatedJsxName(name))
                {
                    // For JSXAttributes, if the attribute has a hyphenated name, consider that the attribute to be known.
                    return true;
                }
            } else if (targetType.flags & TypeFlags.UnionOrIntersection
                && isExcessPropertyCheckTarget(targetType))
            {
                for (const t of (targetType as UnionOrIntersectionType)
                    .types)
                {
                    if (isKnownProperty(t, name, isComparingJsxAttributes)) {
                        return true;
                    }
                }
            }
            return false;
        }

        function isExcessPropertyCheckTarget(type: Type): boolean {
            return !!(type.flags & TypeFlags.Object
                && !(getObjectFlags(type)
                    & ObjectFlags.ObjectLiteralPatternWithComputedProperties)
                || type.flags & TypeFlags.NonPrimitive
                || type.flags & TypeFlags.Union
                && some((<UnionType> type).types, isExcessPropertyCheckTarget)
                || type.flags & TypeFlags.Intersection
                && every(
                    (<IntersectionType> type).types,
                    isExcessPropertyCheckTarget
                ));
        }

        function checkJsxExpression(node: JsxExpression,
            checkMode?: CheckMode)
        {
            checkGrammarJsxExpression(node);
            if (node.expression) {
                const type = checkExpression(node.expression, checkMode);
                if (node.dotDotDotToken && type !== anyType
                    && !isArrayType(type))
                {
                    error(
                        node,
                        Diagnostics.JSX_spread_child_must_be_an_array_type
                    );
                }
                return type;
            } else {
                return errorType;
            }
        }

        function getDeclarationNodeFlagsFromSymbol(s: Symbol): NodeFlags {
            return s.valueDeclaration
                ? getCombinedNodeFlags(s.valueDeclaration)
                : 0;
        }

        /**
         * Return whether this symbol is a member of a prototype somewhere
         * Note that this is not tracked well within the compiler, so the answer may be incorrect.
         */
        function isPrototypeProperty(symbol: Symbol) {
            if (symbol.flags & SymbolFlags.Method
                || getCheckFlags(symbol) & CheckFlags.SyntheticMethod)
            {
                return true;
            }
            if (isInJSFile(symbol.valueDeclaration)) {
                const parent = symbol.valueDeclaration.parent;
                return parent && isBinaryExpression(parent)
                    && getAssignmentDeclarationKind(parent)
                    === AssignmentDeclarationKind.PrototypeProperty;
            }
        }

        /**
         * Check whether the requested property access is valid.
         * Returns true if node is a valid property access, and false otherwise.
         * @param node The node to be checked.
         * @param isSuper True if the access is from `super.`.
         * @param type The type of the object whose property is being accessed. (Not the type of the property.)
         * @param prop The symbol for the property being accessed.
         */
        function checkPropertyAccessibility(
            node: PropertyAccessExpression | QualifiedName
                | PropertyAccessExpression | VariableDeclaration
                | ParameterDeclaration | ImportTypeNode | PropertyAssignment
                | ShorthandPropertyAssignment | BindingElement,
            isSuper: boolean,
            type: Type,
            prop: Symbol
        ): boolean {
            const flags = getDeclarationModifierFlagsFromSymbol(prop);
            const errorNode = node.kind === SyntaxKind.QualifiedName
                ? node.right
                : node.kind === SyntaxKind.ImportType ? node : node.name;

            if (getCheckFlags(prop) & CheckFlags.ContainsPrivate) {
                // Synthetic property with private constituent property
                error(
                    errorNode,
                    Diagnostics
                        .Property_0_has_conflicting_declarations_and_is_inaccessible_in_type_1,
                    symbolToString(prop),
                    typeToString(type)
                );
                return false;
            }

            if (isSuper) {
                // TS 1.0 spec (April 2014): 4.8.2
                // - In a constructor, instance member function, instance member accessor, or
                //   instance member variable initializer where this references a derived class instance,
                //   a super property access is permitted and must specify a public instance member function of the base class.
                // - In a static member function or static member accessor
                //   where this references the constructor function object of a derived class,
                //   a super property access is permitted and must specify a public static member function of the base class.
                if (languageVersion < ScriptTarget.ES2015) {
                    if (symbolHasNonMethodDeclaration(prop)) {
                        error(
                            errorNode,
                            Diagnostics
                                .Only_public_and_protected_methods_of_the_base_class_are_accessible_via_the_super_keyword
                        );
                        return false;
                    }
                }
                if (flags & ModifierFlags.Abstract) {
                    // A method cannot be accessed in a super property access if the method is abstract.
                    // This error could mask a private property access error. But, a member
                    // cannot simultaneously be private and abstract, so this will trigger an
                    // additional error elsewhere.
                    error(
                        errorNode,
                        Diagnostics
                            .Abstract_method_0_in_class_1_cannot_be_accessed_via_super_expression,
                        symbolToString(prop),
                        typeToString(getDeclaringClass(prop)!)
                    );
                    return false;
                }
            }

            // Referencing abstract properties within their own constructors is not allowed
            if ((flags & ModifierFlags.Abstract) && isThisProperty(node)
                && symbolHasNonMethodDeclaration(prop))
            {
                const declaringClassDeclaration = getClassLikeDeclarationOfSymbol(getParentOfSymbol(prop)!);
                if (declaringClassDeclaration
                    && isNodeUsedDuringClassInitialization(node))
                {
                    error(
                        errorNode,
                        Diagnostics
                            .Abstract_property_0_in_class_1_cannot_be_accessed_in_the_constructor,
                        symbolToString(prop),
                        getTextOfIdentifierOrLiteral(
                            declaringClassDeclaration.name!
                        )
                    ); // TODO: GH#18217
                    return false;
                }
            }

            if (isPropertyAccessExpression(node)
                && isPrivateIdentifier(node.name))
            {
                if (!getContainingClass(node)) {
                    error(
                        errorNode,
                        Diagnostics
                            .Private_identifiers_are_not_allowed_outside_class_bodies
                    );
                    return false;
                }
                return true;
            }

            // Public properties are otherwise accessible.
            if (!(flags & ModifierFlags.NonPublicAccessibilityModifier)) {
                return true;
            }

            // Property is known to be private or protected at this point

            // Private property is accessible if the property is within the declaring class
            if (flags & ModifierFlags.Private) {
                const declaringClassDeclaration = getClassLikeDeclarationOfSymbol(getParentOfSymbol(prop)!)!;
                if (!isNodeWithinClass(node, declaringClassDeclaration)) {
                    error(
                        errorNode,
                        Diagnostics
                            .Property_0_is_private_and_only_accessible_within_class_1,
                        symbolToString(prop),
                        typeToString(getDeclaringClass(prop)!)
                    );
                    return false;
                }
                return true;
            }

            // Property is known to be protected at this point

            // All protected properties of a supertype are accessible in a super access
            if (isSuper) {
                return true;
            }

            // Find the first enclosing class that has the declaring classes of the protected constituents
            // of the property as base classes
            let enclosingClass = forEachEnclosingClass(
                node,
                enclosingDeclaration => {
                    const enclosingClass = <InterfaceType> getDeclaredTypeOfSymbol(getSymbolOfNode(enclosingDeclaration)!);
                    return isClassDerivedFromDeclaringClasses(
                        enclosingClass,
                        prop
                    )
                        ? enclosingClass
                        : undefined;
                }
            );
            // A protected property is accessible if the property is within the declaring class or classes derived from it
            if (!enclosingClass) {
                // allow PropertyAccessibility if context is in function with this parameter
                // static member access is disallow
                let thisParameter: ParameterDeclaration | undefined;
                if (flags & ModifierFlags.Static
                    || !(thisParameter = getThisParameterFromNodeContext(node))
                    || !thisParameter.type)
                {
                    error(
                        errorNode,
                        Diagnostics
                            .Property_0_is_protected_and_only_accessible_within_class_1_and_its_subclasses,
                        symbolToString(prop),
                        typeToString(getDeclaringClass(prop) || type)
                    );
                    return false;
                }

                const thisType = getTypeFromTypeNode(thisParameter.type);
                enclosingClass = ((thisType.flags & TypeFlags.TypeParameter)
                    ? getConstraintOfTypeParameter(<TypeParameter> thisType)
                    : thisType) as InterfaceType;
            }
            // No further restrictions for static properties
            if (flags & ModifierFlags.Static) {
                return true;
            }
            if (type.flags & TypeFlags.TypeParameter) {
                // get the original type -- represented as the type constraint of the 'this' type
                type = (type as TypeParameter).isThisType
                    ? getConstraintOfTypeParameter(<TypeParameter> type)!
                    : getBaseConstraintOfType(<TypeParameter> type)!; // TODO: GH#18217 Use a different variable that's allowed to be undefined
            }
            if (!type || !hasBaseType(type, enclosingClass)) {
                error(
                    errorNode,
                    Diagnostics
                        .Property_0_is_protected_and_only_accessible_through_an_instance_of_class_1,
                    symbolToString(prop),
                    typeToString(enclosingClass)
                );
                return false;
            }
            return true;
        }

        function getThisParameterFromNodeContext(node: Node) {
            const thisContainer = getThisContainer(
                node, /* includeArrowFunctions */
                false
            );
            return thisContainer && isFunctionLike(thisContainer)
                ? getThisParameter(thisContainer)
                : undefined;
        }

        function symbolHasNonMethodDeclaration(symbol: Symbol) {
            return !!forEachProperty(
                symbol,
                prop => !(prop.flags & SymbolFlags.Method)
            );
        }

        function checkNonNullExpression(node: Expression | QualifiedName) {
            return checkNonNullType(checkExpression(node), node);
        }

        function isNullableType(type: Type) {
            return !!((strictNullChecks ? getFalsyFlags(type) : type.flags)
                & TypeFlags.Nullable);
        }

        function getNonNullableTypeIfNeeded(type: Type) {
            return isNullableType(type) ? getNonNullableType(type) : type;
        }

        function reportObjectPossiblyNullOrUndefinedError(
            node: Node,
            flags: TypeFlags
        ) {
            error(
                node,
                flags & TypeFlags.Undefined
                    ? flags & TypeFlags.Null
                        ? Diagnostics.Object_is_possibly_null_or_undefined
                        : Diagnostics.Object_is_possibly_undefined
                    : Diagnostics.Object_is_possibly_null
            );
        }

        function reportCannotInvokePossiblyNullOrUndefinedError(
            node: Node,
            flags: TypeFlags
        ) {
            error(
                node,
                flags & TypeFlags.Undefined
                    ? flags & TypeFlags.Null
                        ? Diagnostics
                            .Cannot_invoke_an_object_which_is_possibly_null_or_undefined
                        : Diagnostics
                            .Cannot_invoke_an_object_which_is_possibly_undefined
                    : Diagnostics
                        .Cannot_invoke_an_object_which_is_possibly_null
            );
        }

        function checkNonNullTypeWithReporter(
            type: Type,
            node: Node,
            reportError: (node: Node, kind: TypeFlags) => void
        ): Type {
            if (strictNullChecks && type.flags & TypeFlags.Unknown) {
                error(node, Diagnostics.Object_is_of_type_unknown);
                return errorType;
            }
            const kind = (strictNullChecks ? getFalsyFlags(type) : type.flags)
                & TypeFlags.Nullable;
            if (kind) {
                reportError(node, kind);
                const t = getNonNullableType(type);
                return t.flags & (TypeFlags.Nullable | TypeFlags.Never)
                    ? errorType
                    : t;
            }
            return type;
        }

        function checkNonNullType(type: Type, node: Node) {
            return checkNonNullTypeWithReporter(
                type,
                node,
                reportObjectPossiblyNullOrUndefinedError
            );
        }

        function checkNonNullNonVoidType(type: Type, node: Node): Type {
            const nonNullType = checkNonNullType(type, node);
            if (nonNullType !== errorType
                && nonNullType.flags & TypeFlags.Void)
            {
                error(node, Diagnostics.Object_is_possibly_undefined);
            }
            return nonNullType;
        }

        function checkPropertyAccessExpression(node:
            PropertyAccessExpression)
        {
            return node.flags & NodeFlags.OptionalChain
                ? checkPropertyAccessChain(node as PropertyAccessChain)
                : checkPropertyAccessExpressionOrQualifiedName(
                    node,
                    node.expression,
                    checkNonNullExpression(node.expression),
                    node.name
                );
        }

        function checkPropertyAccessChain(node: PropertyAccessChain) {
            const leftType = checkExpression(node.expression);
            const nonOptionalType = getOptionalExpressionType(
                leftType,
                node.expression
            );
            return propagateOptionalTypeMarker(
                checkPropertyAccessExpressionOrQualifiedName(
                    node,
                    node.expression,
                    checkNonNullType(nonOptionalType, node.expression),
                    node.name
                ),
                node,
                nonOptionalType !== leftType
            );
        }

        function checkQualifiedName(node: QualifiedName) {
            return checkPropertyAccessExpressionOrQualifiedName(
                node,
                node.left,
                checkNonNullExpression(node.left),
                node.right
            );
        }

        function isMethodAccessForCall(node: Node) {
            while (node.parent.kind === SyntaxKind.ParenthesizedExpression) {
                node = node.parent;
            }
            return isCallOrNewExpression(node.parent)
                && node.parent.expression === node;
        }

        // Lookup the private identifier lexically.
        function lookupSymbolForPrivateIdentifierDeclaration(
            propName: __String,
            location: Node
        ): Symbol | undefined {
            for (let containingClass = getContainingClass(location);
                !!containingClass;
                containingClass = getContainingClass(containingClass))
            {
                const { symbol } = containingClass;
                const name = getSymbolNameForPrivateIdentifier(
                    symbol,
                    propName
                );
                const prop = (symbol.members && symbol.members.get(name))
                    || (symbol.exports && symbol.exports.get(name));
                if (prop) {
                    return prop;
                }
            }
        }

        function getPrivateIdentifierPropertyOfType(
            leftType: Type,
            lexicallyScopedIdentifier: Symbol
        ): Symbol | undefined {
            return getPropertyOfType(
                leftType,
                lexicallyScopedIdentifier.escapedName
            );
        }

        function checkPrivateIdentifierPropertyAccess(
            leftType: Type,
            right: PrivateIdentifier,
            lexicallyScopedIdentifier: Symbol | undefined
        ): boolean {
            // Either the identifier could not be looked up in the lexical scope OR the lexically scoped identifier did not exist on the type.
            // Find a private identifier with the same description on the type.
            let propertyOnType: Symbol | undefined;
            const properties = getPropertiesOfType(leftType);
            if (properties) {
                forEach(
                    properties,
                    (symbol: Symbol) => {
                        const decl = symbol.valueDeclaration;
                        if (decl && isNamedDeclaration(decl)
                            && isPrivateIdentifier(decl.name)
                            && decl.name.escapedText === right.escapedText)
                        {
                            propertyOnType = symbol;
                            return true;
                        }
                    }
                );
            }
            const diagName = diagnosticName(right);
            if (propertyOnType) {
                const typeValueDecl = propertyOnType.valueDeclaration;
                const typeClass = getContainingClass(typeValueDecl);
                Debug.assert(!!typeClass);
                // We found a private identifier property with the same description.
                // Either:
                // - There is a lexically scoped private identifier AND it shadows the one we found on the type.
                // - It is an attempt to access the private identifier outside of the class.
                if (lexicallyScopedIdentifier) {
                    const lexicalValueDecl = lexicallyScopedIdentifier
                        .valueDeclaration;
                    const lexicalClass = getContainingClass(lexicalValueDecl);
                    Debug.assert(!!lexicalClass);
                    if (findAncestor(lexicalClass, n => typeClass === n)) {
                        const diagnostic = error(
                            right,
                            Diagnostics
                                .The_property_0_cannot_be_accessed_on_type_1_within_this_class_because_it_is_shadowed_by_another_private_identifier_with_the_same_spelling,
                            diagName,
                            typeToString(leftType)
                        );

                        addRelatedInfo(
                            diagnostic,
                            createDiagnosticForNode(
                                lexicalValueDecl,
                                Diagnostics
                                    .The_shadowing_declaration_of_0_is_defined_here,
                                diagName
                            ),
                            createDiagnosticForNode(
                                typeValueDecl,
                                Diagnostics
                                    .The_declaration_of_0_that_you_probably_intended_to_use_is_defined_here,
                                diagName
                            )
                        );
                        return true;
                    }
                }
                error(
                    right,
                    Diagnostics
                        .Property_0_is_not_accessible_outside_class_1_because_it_has_a_private_identifier,
                    diagName,
                    diagnosticName(typeClass!.name || anon)
                );
                return true;
            }
            return false;
        }

        function checkPropertyAccessExpressionOrQualifiedName(
            node: PropertyAccessExpression | QualifiedName,
            left: Expression | QualifiedName,
            leftType: Type,
            right: Identifier | PrivateIdentifier
        ) {
            const parentSymbol = getNodeLinks(left).resolvedSymbol;
            const assignmentKind = getAssignmentTargetKind(node);
            const apparentType = getApparentType(
                assignmentKind !== AssignmentKind.None
                    || isMethodAccessForCall(node)
                    ? getWidenedType(leftType)
                    : leftType
            );
            if (isPrivateIdentifier(right)) {
                if (isOptionalChain(node)) {
                    grammarErrorOnNode(
                        right,
                        Diagnostics
                            .An_optional_chain_cannot_contain_private_identifiers
                    );
                    return anyType;
                }
                checkExternalEmitHelpers(
                    node,
                    ExternalEmitHelpers.ClassPrivateFieldGet
                );
            }
            const isAnyLike = isTypeAny(apparentType)
                || apparentType === silentNeverType;
            let prop: Symbol | undefined;
            if (isPrivateIdentifier(right)) {
                const lexicallyScopedSymbol = lookupSymbolForPrivateIdentifierDeclaration(
                    right.escapedText,
                    right
                );
                if (isAnyLike) {
                    if (lexicallyScopedSymbol) {
                        return apparentType;
                    }
                    if (!getContainingClass(right)) {
                        grammarErrorOnNode(
                            right,
                            Diagnostics
                                .Private_identifiers_are_not_allowed_outside_class_bodies
                        );
                        return anyType;
                    }
                }
                prop = lexicallyScopedSymbol
                    ? getPrivateIdentifierPropertyOfType(
                        leftType,
                        lexicallyScopedSymbol
                    )
                    : undefined;
                // Check for private-identifier-specific shadowing and lexical-scoping errors.
                if (!prop
                    && checkPrivateIdentifierPropertyAccess(
                        leftType,
                        right,
                        lexicallyScopedSymbol
                    ))
                {
                    return errorType;
                }
            } else {
                if (isAnyLike) {
                    if (isIdentifier(left) && parentSymbol) {
                        markAliasReferenced(parentSymbol, node);
                    }
                    return apparentType;
                }
                prop = getPropertyOfType(apparentType, right.escapedText);
            }
            if (isIdentifier(left) && parentSymbol
                && !(prop && isConstEnumOrConstEnumOnlyModule(prop)))
            {
                markAliasReferenced(parentSymbol, node);
            }

            let propType: Type;
            if (!prop) {
                const indexInfo = !isPrivateIdentifier(right)
                    && (assignmentKind === AssignmentKind.None
                        || !isGenericObjectType(leftType)
                        || isThisTypeParameter(leftType))
                    ? getIndexInfoOfType(apparentType, IndexKind.String)
                    : undefined;
                if (!(indexInfo && indexInfo.type)) {
                    if (isJSLiteralType(leftType)) {
                        return anyType;
                    }
                    if (leftType.symbol === globalThisSymbol) {
                        if (globalThisSymbol.exports!.has(right.escapedText)
                            && (globalThisSymbol.exports!
                                .get(right.escapedText)!.flags
                                & SymbolFlags.BlockScoped))
                        {
                            error(
                                right,
                                Diagnostics
                                    .Property_0_does_not_exist_on_type_1,
                                unescapeLeadingUnderscores(right.escapedText),
                                typeToString(leftType)
                            );
                        } else if (noImplicitAny) {
                            error(
                                right,
                                Diagnostics
                                    .Element_implicitly_has_an_any_type_because_type_0_has_no_index_signature,
                                typeToString(leftType)
                            );
                        }
                        return anyType;
                    }
                    if (right.escapedText
                        && !checkAndReportErrorForExtendingInterface(node))
                    {
                        reportNonexistentProperty(
                            right,
                            isThisTypeParameter(leftType)
                                ? apparentType
                                : leftType
                        );
                    }
                    return errorType;
                }
                if (indexInfo.isReadonly
                    && (isAssignmentTarget(node) || isDeleteTarget(node)))
                {
                    error(
                        node,
                        Diagnostics
                            .Index_signature_in_type_0_only_permits_reading,
                        typeToString(apparentType)
                    );
                }
                propType = indexInfo.type;
            } else {
                checkPropertyNotUsedBeforeDeclaration(prop, node, right);
                markPropertyAsReferenced(
                    prop,
                    node,
                    left.kind === SyntaxKind.ThisKeyword
                );
                getNodeLinks(node).resolvedSymbol = prop;
                checkPropertyAccessibility(
                    node,
                    left.kind === SyntaxKind.SuperKeyword,
                    apparentType,
                    prop
                );
                if (isAssignmentToReadonlyEntity(
                    node as Expression,
                    prop,
                    assignmentKind
                )) {
                    error(
                        right,
                        Diagnostics
                            .Cannot_assign_to_0_because_it_is_a_read_only_property,
                        idText(right)
                    );
                    return errorType;
                }
                propType = getConstraintForLocation(
                    getTypeOfSymbol(prop),
                    node
                );
            }
            return getFlowTypeOfAccessExpression(node, prop, propType, right);
        }

        function getFlowTypeOfAccessExpression(
            node: ElementAccessExpression | PropertyAccessExpression
                | QualifiedName,
            prop: Symbol | undefined,
            propType: Type,
            errorNode: Node
        ) {
            // Only compute control flow type if this is a property access expression that isn't an
            // assignment target, and the referenced property was declared as a variable, property,
            // accessor, or optional method.
            const assignmentKind = getAssignmentTargetKind(node);
            if (!isAccessExpression(node)
                || assignmentKind === AssignmentKind.Definite
                || prop
                && !(prop.flags
                    & (SymbolFlags.Variable | SymbolFlags.Property
                        | SymbolFlags.Accessor))
                && !(prop.flags & SymbolFlags.Method
                    && propType.flags & TypeFlags.Union))
            {
                return propType;
            }
            // If strict null checks and strict property initialization checks are enabled, if we have
            // a this.xxx property access, if the property is an instance property without an initializer,
            // and if we are in a constructor of the same class as the property declaration, assume that
            // the property is uninitialized at the top of the control flow.
            let assumeUninitialized = false;
            if (strictNullChecks && strictPropertyInitialization
                && node.expression.kind === SyntaxKind.ThisKeyword)
            {
                const declaration = prop && prop.valueDeclaration;
                if (declaration
                    && isInstancePropertyWithoutInitializer(declaration))
                {
                    const flowContainer = getControlFlowContainer(node);
                    if (flowContainer.kind === SyntaxKind.Constructor
                        && flowContainer.parent === declaration.parent)
                    {
                        assumeUninitialized = true;
                    }
                }
            } else if (strictNullChecks && prop && prop.valueDeclaration
                && isPropertyAccessExpression(prop.valueDeclaration)
                && getAssignmentDeclarationPropertyAccessKind(
                    prop.valueDeclaration
                )
                && getControlFlowContainer(node)
                === getControlFlowContainer(prop.valueDeclaration))
            {
                assumeUninitialized = true;
            }
            const flowType = getFlowTypeOfReference(
                node,
                propType,
                assumeUninitialized ? getOptionalType(propType) : propType
            );
            if (assumeUninitialized
                && !(getFalsyFlags(propType) & TypeFlags.Undefined)
                && getFalsyFlags(flowType) & TypeFlags.Undefined)
            {
                error(
                    errorNode,
                    Diagnostics.Property_0_is_used_before_being_assigned,
                    symbolToString(prop!)
                ); // TODO: GH#18217
                // Return the declared type to reduce follow-on errors
                return propType;
            }
            return assignmentKind
                ? getBaseTypeOfLiteralType(flowType)
                : flowType;
        }

        function checkPropertyNotUsedBeforeDeclaration(
            prop: Symbol,
            node: PropertyAccessExpression | QualifiedName,
            right: Identifier | PrivateIdentifier
        ): void {
            const { valueDeclaration } = prop;
            if (!valueDeclaration
                || getSourceFileOfNode(node).isDeclarationFile)
            {
                return;
            }

            let diagnosticMessage;
            const declarationName = idText(right);
            if (isInPropertyInitializer(node)
                && !(isAccessExpression(node)
                    && isAccessExpression(node.expression))
                && !isBlockScopedNameDeclaredBeforeUse(valueDeclaration, right)
                && !isPropertyDeclaredInAncestorClass(prop))
            {
                diagnosticMessage = error(
                    right,
                    Diagnostics.Property_0_is_used_before_its_initialization,
                    declarationName
                );
            } else if (valueDeclaration.kind === SyntaxKind.ClassDeclaration
                && node.parent.kind !== SyntaxKind.TypeReference
                && !(valueDeclaration.flags & NodeFlags.Ambient)
                && !isBlockScopedNameDeclaredBeforeUse(valueDeclaration,
                    right))
            {
                diagnosticMessage = error(
                    right,
                    Diagnostics.Class_0_used_before_its_declaration,
                    declarationName
                );
            }

            if (diagnosticMessage) {
                addRelatedInfo(
                    diagnosticMessage,
                    createDiagnosticForNode(
                        valueDeclaration,
                        Diagnostics._0_is_declared_here,
                        declarationName
                    )
                );
            }
        }

        function isInPropertyInitializer(node: Node): boolean {
            return !!findAncestor(
                node,
                node => {
                    switch (node.kind) {
                        case SyntaxKind.PropertyDeclaration:
                            return true;
                        case SyntaxKind.PropertyAssignment:
                        case SyntaxKind.MethodDeclaration:
                        case SyntaxKind.GetAccessor:
                        case SyntaxKind.SetAccessor:
                        case SyntaxKind.SpreadAssignment:
                        case SyntaxKind.ComputedPropertyName:
                        case SyntaxKind.TemplateSpan:
                        case SyntaxKind.JsxExpression:
                        case SyntaxKind.JsxAttribute:
                        case SyntaxKind.JsxAttributes:
                        case SyntaxKind.JsxSpreadAttribute:
                        case SyntaxKind.JsxOpeningElement:
                        case SyntaxKind.ExpressionWithTypeArguments:
                        case SyntaxKind.HeritageClause:
                            return false;
                        default:
                            return isExpressionNode(node) ? false : 'quit';
                    }
                }
            );
        }

        /**
         * It's possible that "prop.valueDeclaration" is a local declaration, but the property was also declared in a superclass.
         * In that case we won't consider it used before its declaration, because it gets its value from the superclass' declaration.
         */
        function isPropertyDeclaredInAncestorClass(prop: Symbol): boolean {
            if (!(prop.parent!.flags & SymbolFlags.Class)) {
                return false;
            }
            let classType: InterfaceType
                | undefined = getTypeOfSymbol(prop.parent!) as InterfaceType;
            while (true) {
                classType = classType.symbol
                    && getSuperClass(classType) as InterfaceType | undefined;
                if (!classType) {
                    return false;
                }
                const superProperty = getPropertyOfType(
                    classType,
                    prop.escapedName
                );
                if (superProperty && superProperty.valueDeclaration) {
                    return true;
                }
            }
        }

        function getSuperClass(classType: InterfaceType): Type | undefined {
            const x = getBaseTypes(classType);
            if (x.length === 0) {
                return undefined;
            }
            return getIntersectionType(x);
        }

        function reportNonexistentProperty(
            propNode: Identifier | PrivateIdentifier,
            containingType: Type
        ) {
            let errorInfo: DiagnosticMessageChain | undefined;
            let relatedInfo: Diagnostic | undefined;
            if (!isPrivateIdentifier(propNode)
                && containingType.flags & TypeFlags.Union
                && !(containingType.flags & TypeFlags.Primitive))
            {
                for (const subtype of (containingType as UnionType).types) {
                    if (!getPropertyOfType(subtype, propNode.escapedText)
                        && !getIndexInfoOfType(subtype, IndexKind.String))
                    {
                        errorInfo = chainDiagnosticMessages(
                            errorInfo,
                            Diagnostics.Property_0_does_not_exist_on_type_1,
                            declarationNameToString(propNode),
                            typeToString(subtype)
                        );
                        break;
                    }
                }
            }
            if (typeHasStaticProperty(propNode.escapedText, containingType)) {
                errorInfo = chainDiagnosticMessages(
                    errorInfo,
                    Diagnostics.Property_0_is_a_static_member_of_type_1,
                    declarationNameToString(propNode),
                    typeToString(containingType)
                );
            } else {
                const promisedType = getPromisedTypeOfPromise(containingType);
                if (promisedType
                    && getPropertyOfType(promisedType, propNode.escapedText))
                {
                    errorInfo = chainDiagnosticMessages(
                        errorInfo,
                        Diagnostics.Property_0_does_not_exist_on_type_1,
                        declarationNameToString(propNode),
                        typeToString(containingType)
                    );
                    relatedInfo = createDiagnosticForNode(
                        propNode,
                        Diagnostics.Did_you_forget_to_use_await
                    );
                } else {
                    const suggestion = getSuggestedSymbolForNonexistentProperty(
                        propNode,
                        containingType
                    );
                    if (suggestion !== undefined) {
                        const suggestedName = symbolName(suggestion);
                        errorInfo = chainDiagnosticMessages(
                            errorInfo,
                            Diagnostics
                                .Property_0_does_not_exist_on_type_1_Did_you_mean_2,
                            declarationNameToString(propNode),
                            typeToString(containingType),
                            suggestedName
                        );
                        relatedInfo = suggestion.valueDeclaration
                            && createDiagnosticForNode(
                                suggestion.valueDeclaration,
                                Diagnostics._0_is_declared_here,
                                suggestedName
                            );
                    } else {
                        errorInfo = chainDiagnosticMessages(
                            errorInfo,
                            Diagnostics.Property_0_does_not_exist_on_type_1,
                            declarationNameToString(propNode),
                            typeToString(containingType)
                        );
                    }
                }
            }
            const resultDiagnostic = createDiagnosticForNodeFromMessageChain(
                propNode,
                errorInfo
            );
            if (relatedInfo) {
                addRelatedInfo(resultDiagnostic, relatedInfo);
            }
            diagnostics.add(resultDiagnostic);
        }

        function typeHasStaticProperty(
            propName: __String,
            containingType: Type
        ): boolean {
            const prop = containingType.symbol
                && getPropertyOfType(
                    getTypeOfSymbol(containingType.symbol),
                    propName
                );
            return prop !== undefined && prop.valueDeclaration
                && hasModifier(prop.valueDeclaration, ModifierFlags.Static);
        }

        function getSuggestedSymbolForNonexistentProperty(
            name: Identifier | PrivateIdentifier | string,
            containingType: Type
        ): Symbol | undefined {
            return getSpellingSuggestionForName(
                isString(name) ? name : idText(name),
                getPropertiesOfType(containingType),
                SymbolFlags.Value
            );
        }

        function getSuggestionForNonexistentProperty(
            name: Identifier | PrivateIdentifier | string,
            containingType: Type
        ): string | undefined {
            const suggestion = getSuggestedSymbolForNonexistentProperty(
                name,
                containingType
            );
            return suggestion && symbolName(suggestion);
        }

        function getSuggestedSymbolForNonexistentSymbol(
            location: Node | undefined,
            outerName: __String,
            meaning: SymbolFlags
        ): Symbol | undefined {
            Debug.assert(
                outerName !== undefined,
                'outername should always be defined'
            );
            const result = resolveNameHelper(
                location,
                outerName,
                meaning, /*nameNotFoundMessage*/
                undefined,
                outerName, /*isUse*/
                false, /*excludeGlobals*/
                false,
                (symbols, name, meaning) => {
                    Debug.assertEqual(outerName, name,
                        'name should equal outerName');
                    const symbol = getSymbol(symbols, name, meaning);
                    // Sometimes the symbol is found when location is a return type of a function: `typeof x` and `x` is declared in the body of the function
                    // So the table *contains* `x` but `x` isn't actually in scope.
                    // However, resolveNameHelper will continue and call this callback again, so we'll eventually get a correct suggestion.
                    return symbol || getSpellingSuggestionForName(
                        unescapeLeadingUnderscores(name),
                        arrayFrom(symbols.values()),
                        meaning
                    );
                }
            );
            return result;
        }

        function getSuggestionForNonexistentSymbol(
            location: Node | undefined,
            outerName: __String,
            meaning: SymbolFlags
        ): string | undefined {
            const symbolResult = getSuggestedSymbolForNonexistentSymbol(
                location,
                outerName,
                meaning
            );
            return symbolResult && symbolName(symbolResult);
        }

        function getSuggestedSymbolForNonexistentModule(
            name: Identifier,
            targetModule: Symbol
        ): Symbol | undefined {
            return targetModule.exports
                && getSpellingSuggestionForName(
                    idText(name),
                    getExportsOfModuleAsArray(targetModule),
                    SymbolFlags.ModuleMember
                );
        }

        function getSuggestionForNonexistentExport(
            name: Identifier,
            targetModule: Symbol
        ): string | undefined {
            const suggestion = getSuggestedSymbolForNonexistentModule(
                name,
                targetModule
            );
            return suggestion && symbolName(suggestion);
        }

        function getSuggestionForNonexistentIndexSignature(
            objectType: Type,
            expr: ElementAccessExpression,
            keyedType: Type
        ): string | undefined {
            // check if object type has setter or getter
            function hasProp(name: 'set' | 'get') {
                const prop = getPropertyOfObjectType(
                    objectType,
                    <__String> name
                );
                if (prop) {
                    const s = getSingleCallSignature(getTypeOfSymbol(prop));
                    return !!s && getMinArgumentCount(s) >= 1
                        && isTypeAssignableTo(
                            keyedType,
                            getTypeAtPosition(s, 0)
                        );
                }
                return false;
            }
            ;

            const suggestedMethod = isAssignmentTarget(expr) ? 'set' : 'get';
            if (!hasProp(suggestedMethod)) {
                return undefined;
            }

            let suggestion = tryGetPropertyAccessOrIdentifierToString(
                expr.expression
            );
            if (suggestion === undefined) {
                suggestion = suggestedMethod;
            } else {
                suggestion += '.' + suggestedMethod;
            }

            return suggestion;
        }

        /**
         * Given a name and a list of symbols whose names are *not* equal to the name, return a spelling suggestion if there is one that is close enough.
         * Names less than length 3 only check for case-insensitive equality, not levenshtein distance.
         *
         * If there is a candidate that's the same except for case, return that.
         * If there is a candidate that's within one edit of the name, return that.
         * Otherwise, return the candidate with the smallest Levenshtein distance,
         *    except for candidates:
         *      * With no name
         *      * Whose meaning doesn't match the `meaning` parameter.
         *      * Whose length differs from the target name by more than 0.34 of the length of the name.
         *      * Whose levenshtein distance is more than 0.4 of the length of the name
         *        (0.4 allows 1 substitution/transposition for every 5 characters,
         *         and 1 insertion/deletion at 3 characters)
         */
        function getSpellingSuggestionForName(
            name: string,
            symbols: Symbol[],
            meaning: SymbolFlags
        ): Symbol | undefined {
            return getSpellingSuggestion(name, symbols, getCandidateName);
            function getCandidateName(candidate: Symbol) {
                const candidateName = symbolName(candidate);
                return !startsWith(candidateName, '"')
                    && candidate.flags & meaning
                    ? candidateName
                    : undefined;
            }
        }

        function markPropertyAsReferenced(
            prop: Symbol,
            nodeForCheckWriteOnly: Node | undefined,
            isThisAccess: boolean
        ) {
            const valueDeclaration = prop
                && (prop.flags & SymbolFlags.ClassMember)
                && prop.valueDeclaration;
            if (!valueDeclaration) {
                return;
            }
            const hasPrivateModifier = hasModifier(
                valueDeclaration,
                ModifierFlags.Private
            );
            const hasPrivateIdentifier = isNamedDeclaration(
                prop.valueDeclaration
            ) && isPrivateIdentifier(prop.valueDeclaration.name);
            if (!hasPrivateModifier && !hasPrivateIdentifier) {
                return;
            }
            if (nodeForCheckWriteOnly
                && isWriteOnlyAccess(nodeForCheckWriteOnly)
                && !(prop.flags & SymbolFlags.SetAccessor
                    && !(prop.flags & SymbolFlags.GetAccessor)))
            {
                return;
            }

            if (isThisAccess) {
                // Find any FunctionLikeDeclaration because those create a new 'this' binding. But this should only matter for methods (or getters/setters).
                const containingMethod = findAncestor(
                    nodeForCheckWriteOnly,
                    isFunctionLikeDeclaration
                );
                if (containingMethod && containingMethod.symbol === prop) {
                    return;
                }
            }

            (getCheckFlags(prop) & CheckFlags.Instantiated
                ? getSymbolLinks(prop).target
                : prop)!.isReferenced = SymbolFlags.All;
        }

        function isValidPropertyAccess(
            node: PropertyAccessExpression | QualifiedName | ImportTypeNode,
            propertyName: __String
        ): boolean {
            switch (node.kind) {
                case SyntaxKind.PropertyAccessExpression:
                    return isValidPropertyAccessWithType(
                        node,
                        node.expression.kind === SyntaxKind.SuperKeyword,
                        propertyName,
                        getWidenedType(checkExpression(node.expression))
                    );
                case SyntaxKind.QualifiedName:
                    return isValidPropertyAccessWithType(
                        node, /*isSuper*/
                        false,
                        propertyName,
                        getWidenedType(checkExpression(node.left))
                    );
                case SyntaxKind.ImportType:
                    return isValidPropertyAccessWithType(
                        node, /*isSuper*/
                        false,
                        propertyName,
                        getTypeFromTypeNode(node)
                    );
            }
        }

        function isValidPropertyAccessForCompletions(
            node: PropertyAccessExpression | ImportTypeNode | QualifiedName,
            type: Type,
            property: Symbol
        ): boolean {
            return isValidPropertyAccessWithType(
                node,
                node.kind === SyntaxKind.PropertyAccessExpression
                    && node.expression.kind === SyntaxKind.SuperKeyword,
                property.escapedName,
                type
            );
            // Previously we validated the 'this' type of methods but this adversely affected performance. See #31377 for more context.
        }

        function isValidPropertyAccessWithType(
            node: PropertyAccessExpression | QualifiedName | ImportTypeNode,
            isSuper: boolean,
            propertyName: __String,
            type: Type
        ): boolean {
            if (type === errorType || isTypeAny(type)) {
                return true;
            }
            const prop = getPropertyOfType(type, propertyName);
            if (prop) {
                if (isPropertyAccessExpression(node) && prop.valueDeclaration
                    && isPrivateIdentifierPropertyDeclaration(
                        prop.valueDeclaration
                    ))
                {
                    const declClass = getContainingClass(prop
                        .valueDeclaration);
                    return !isOptionalChain(node)
                        && !!findAncestor(node,
                            parent => parent === declClass);
                }
                return checkPropertyAccessibility(node, isSuper, type, prop);
            }
            // In js files properties of unions are allowed in completion
            return isInJSFile(node) && (type.flags & TypeFlags.Union) !== 0
                && (<UnionType> type).types
                    .some(elementType => isValidPropertyAccessWithType(
                        node,
                        isSuper,
                        propertyName,
                        elementType
                    ));
        }

        /**
         * Return the symbol of the for-in variable declared or referenced by the given for-in statement.
         */
        function getForInVariableSymbol(
            node: ForInStatement
        ): Symbol | undefined {
            const initializer = node.initializer;
            if (initializer.kind === SyntaxKind.VariableDeclarationList) {
                const variable = (<VariableDeclarationList> initializer)
                    .declarations[0];
                if (variable && !isBindingPattern(variable.name)) {
                    return getSymbolOfNode(variable);
                }
            } else if (initializer.kind === SyntaxKind.Identifier) {
                return getResolvedSymbol(<Identifier> initializer);
            }
            return undefined;
        }

        /**
         * Return true if the given type is considered to have numeric property names.
         */
        function hasNumericPropertyNames(type: Type) {
            return getIndexTypeOfType(type, IndexKind.Number)
                && !getIndexTypeOfType(type, IndexKind.String);
        }

        /**
         * Return true if given node is an expression consisting of an identifier (possibly parenthesized)
         * that references a for-in variable for an object with numeric property names.
         */
        function isForInVariableForNumericPropertyNames(expr: Expression) {
            const e = skipParentheses(expr);
            if (e.kind === SyntaxKind.Identifier) {
                const symbol = getResolvedSymbol(<Identifier> e);
                if (symbol.flags & SymbolFlags.Variable) {
                    let child: Node = expr;
                    let node = expr.parent;
                    while (node) {
                        if (node.kind === SyntaxKind.ForInStatement
                            && child === (<ForInStatement> node).statement
                            && getForInVariableSymbol(<ForInStatement> node)
                            === symbol
                            && hasNumericPropertyNames(
                                getTypeOfExpression(
                                    (<ForInStatement> node).expression
                                )
                            ))
                        {
                            return true;
                        }
                        child = node;
                        node = node.parent;
                    }
                }
            }
            return false;
        }

        function checkIndexedAccess(node: ElementAccessExpression): Type {
            return node.flags & NodeFlags.OptionalChain
                ? checkElementAccessChain(node as ElementAccessChain)
                : checkElementAccessExpression(
                    node,
                    checkNonNullExpression(node.expression)
                );
        }

        function checkElementAccessChain(node: ElementAccessChain) {
            const exprType = checkExpression(node.expression);
            const nonOptionalType = getOptionalExpressionType(
                exprType,
                node.expression
            );
            return propagateOptionalTypeMarker(
                checkElementAccessExpression(
                    node,
                    checkNonNullType(nonOptionalType, node.expression)
                ),
                node,
                nonOptionalType !== exprType
            );
        }

        function checkElementAccessExpression(
            node: ElementAccessExpression,
            exprType: Type
        ): Type {
            const objectType = getAssignmentTargetKind(node)
                !== AssignmentKind.None || isMethodAccessForCall(node)
                ? getWidenedType(exprType)
                : exprType;
            const indexExpression = node.argumentExpression;
            const indexType = checkExpression(indexExpression);

            if (objectType === errorType || objectType === silentNeverType) {
                return objectType;
            }

            if (isConstEnumObjectType(objectType)
                && !isStringLiteralLike(indexExpression))
            {
                error(
                    indexExpression,
                    Diagnostics
                        .A_const_enum_member_can_only_be_accessed_using_a_string_literal
                );
                return errorType;
            }

            const effectiveIndexType = isForInVariableForNumericPropertyNames(indexExpression)
                ? numberType
                : indexType;
            const accessFlags = isAssignmentTarget(node)
                ? AccessFlags.Writing | (isGenericObjectType(
                    objectType
                ) && !isThisTypeParameter(objectType)
                    ? AccessFlags.NoIndexSignatures
                    : 0)
                : AccessFlags.None;
            const indexedAccessType = getIndexedAccessTypeOrUndefined(
                objectType,
                effectiveIndexType,
                node,
                accessFlags
            ) || errorType;
            return checkIndexedAccessIndexType(
                getFlowTypeOfAccessExpression(
                    node,
                    indexedAccessType.symbol,
                    indexedAccessType,
                    indexExpression
                ),
                node
            );
        }

        function checkThatExpressionIsProperSymbolReference(
            expression: Expression,
            expressionType: Type,
            reportError: boolean
        ): boolean {
            if (expressionType === errorType) {
                // There is already an error, so no need to report one.
                return false;
            }

            if (!isWellKnownSymbolSyntactically(expression)) {
                return false;
            }

            // Make sure the property type is the primitive symbol type
            if ((expressionType.flags & TypeFlags.ESSymbolLike) === 0) {
                if (reportError) {
                    error(
                        expression,
                        Diagnostics
                            .A_computed_property_name_of_the_form_0_must_be_of_type_symbol,
                        getTextOfNode(expression)
                    );
                }
                return false;
            }

            // The name is Symbol.<someName>, so make sure Symbol actually resolves to the
            // global Symbol object
            const leftHandSide = <Identifier> (<PropertyAccessExpression> expression)
                .expression;
            const leftHandSideSymbol = getResolvedSymbol(leftHandSide);
            if (!leftHandSideSymbol) {
                return false;
            }

            const globalESSymbol = getGlobalESSymbolConstructorSymbol(/*reportErrors*/ true);
            if (!globalESSymbol) {
                // Already errored when we tried to look up the symbol
                return false;
            }

            if (leftHandSideSymbol !== globalESSymbol) {
                if (reportError) {
                    error(
                        leftHandSide,
                        Diagnostics
                            .Symbol_reference_does_not_refer_to_the_global_Symbol_constructor_object
                    );
                }
                return false;
            }

            return true;
        }

        function callLikeExpressionMayHaveTypeArguments(
            node: CallLikeExpression
        ): node is CallExpression | NewExpression | TaggedTemplateExpression
            | JsxOpeningElement
        {
            return isCallOrNewExpression(node)
                || isTaggedTemplateExpression(node)
                || isJsxOpeningLikeElement(node);
        }

        function resolveUntypedCall(node: CallLikeExpression): Signature {
            if (callLikeExpressionMayHaveTypeArguments(node)) {
                // Check type arguments even though we will give an error that untyped calls may not accept type arguments.
                // This gets us diagnostics for the type arguments and marks them as referenced.
                forEach(node.typeArguments, checkSourceElement);
            }

            if (node.kind === SyntaxKind.TaggedTemplateExpression) {
                checkExpression(node.template);
            } else if (isJsxOpeningLikeElement(node)) {
                checkExpression(node.attributes);
            } else if (node.kind !== SyntaxKind.Decorator) {
                forEach(
                    (<CallExpression> node).arguments,
                    argument => {
                        checkExpression(argument);
                    }
                );
            }
            return anySignature;
        }

        function resolveErrorCall(node: CallLikeExpression): Signature {
            resolveUntypedCall(node);
            return unknownSignature;
        }

        // Re-order candidate signatures into the result array. Assumes the result array to be empty.
        // The candidate list orders groups in reverse, but within a group signatures are kept in declaration order
        // A nit here is that we reorder only signatures that belong to the same symbol,
        // so order how inherited signatures are processed is still preserved.
        // interface A { (x: string): void }
        // interface B extends A { (x: 'foo'): string }
        // const b: B;
        // b('foo') // <- here overloads should be processed as [(x:'foo'): string, (x: string): void]
        function reorderCandidates(
            signatures: readonly Signature[],
            result: Signature[],
            callChainFlags: SignatureFlags
        ): void {
            let lastParent: Node | undefined;
            let lastSymbol: Symbol | undefined;
            let cutoffIndex = 0;
            let index: number | undefined;
            let specializedIndex = -1;
            let spliceIndex: number;
            Debug.assert(!result.length);
            for (const signature of signatures) {
                const symbol = signature.declaration
                    && getSymbolOfNode(signature.declaration);
                const parent = signature.declaration
                    && signature.declaration.parent;
                if (!lastSymbol || symbol === lastSymbol) {
                    if (lastParent && parent === lastParent) {
                        index = index! + 1;
                    } else {
                        lastParent = parent;
                        index = cutoffIndex;
                    }
                } else {
                    // current declaration belongs to a different symbol
                    // set cutoffIndex so re-orderings in the future won't change result set from 0 to cutoffIndex
                    index = cutoffIndex = result.length;
                    lastParent = parent;
                }
                lastSymbol = symbol;

                // specialized signatures always need to be placed before non-specialized signatures regardless
                // of the cutoff position; see GH#1133
                if (signatureHasLiteralTypes(signature)) {
                    specializedIndex++;
                    spliceIndex = specializedIndex;
                    // The cutoff index always needs to be greater than or equal to the specialized signature index
                    // in order to prevent non-specialized signatures from being added before a specialized
                    // signature.
                    cutoffIndex++;
                } else {
                    spliceIndex = index;
                }

                result.splice(
                    spliceIndex,
                    0,
                    callChainFlags
                        ? getOptionalCallSignature(signature, callChainFlags)
                        : signature
                );
            }
        }

        function isSpreadArgument(
            arg: Expression | undefined
        ): arg is Expression {
            return !!arg
                && (arg.kind === SyntaxKind.SpreadElement
                    || arg.kind === SyntaxKind.SyntheticExpression
                    && (<SyntheticExpression> arg).isSpread);
        }

        function getSpreadArgumentIndex(args: readonly Expression[]): number {
            return findIndex(args, isSpreadArgument);
        }

        function acceptsVoid(t: Type): boolean {
            return !!(t.flags & TypeFlags.Void);
        }

        function hasCorrectArity(
            node: CallLikeExpression,
            args: readonly Expression[],
            signature: Signature,
            signatureHelpTrailingComma = false
        ) {
            let argCount: number;
            let callIsIncomplete = false; // In incomplete call we want to be lenient when we have too few arguments
            let effectiveParameterCount = getParameterCount(signature);
            let effectiveMinimumArguments = getMinArgumentCount(signature);

            if (node.kind === SyntaxKind.TaggedTemplateExpression) {
                argCount = args.length;
                if (node.template.kind === SyntaxKind.TemplateExpression) {
                    // If a tagged template expression lacks a tail literal, the call is incomplete.
                    // Specifically, a template only can end in a TemplateTail or a Missing literal.
                    const lastSpan = last(node.template
                        .templateSpans); // we should always have at least one span.
                    callIsIncomplete = nodeIsMissing(lastSpan.literal)
                        || !!lastSpan.literal.isUnterminated;
                } else {
                    // If the template didn't end in a backtick, or its beginning occurred right prior to EOF,
                    // then this might actually turn out to be a TemplateHead in the future;
                    // so we consider the call to be incomplete.
                    const templateLiteral = <LiteralExpression> node.template;
                    Debug
                        .assert(
                            templateLiteral.kind
                                === SyntaxKind.NoSubstitutionTemplateLiteral
                        );
                    callIsIncomplete = !!templateLiteral.isUnterminated;
                }
            } else if (node.kind === SyntaxKind.Decorator) {
                argCount = getDecoratorArgumentCount(node, signature);
            } else if (isJsxOpeningLikeElement(node)) {
                callIsIncomplete = node.attributes.end === node.end;
                if (callIsIncomplete) {
                    return true;
                }
                argCount = effectiveMinimumArguments === 0 ? args.length : 1;
                effectiveParameterCount = args.length === 0
                    ? effectiveParameterCount
                    : 1; // class may have argumentless ctor functions - still resolve ctor and compare vs props member type
                effectiveMinimumArguments = Math.min(
                    effectiveMinimumArguments,
                    1
                ); // sfc may specify context argument - handled by framework and not typechecked
            } else {
                if (!node.arguments) {
                    // This only happens when we have something of the form: 'new C'
                    Debug.assert(node.kind === SyntaxKind.NewExpression);
                    return getMinArgumentCount(signature) === 0;
                }

                argCount = signatureHelpTrailingComma
                    ? args.length + 1
                    : args.length;

                // If we are missing the close parenthesis, the call is incomplete.
                callIsIncomplete = node.arguments.end === node.end;

                // If a spread argument is present, check that it corresponds to a rest parameter or at least that it's in the valid range.
                const spreadArgIndex = getSpreadArgumentIndex(args);
                if (spreadArgIndex >= 0) {
                    return spreadArgIndex >= getMinArgumentCount(signature)
                        && (hasEffectiveRestParameter(signature)
                            || spreadArgIndex < getParameterCount(signature));
                }
            }

            // Too many arguments implies incorrect arity.
            if (!hasEffectiveRestParameter(signature)
                && argCount > effectiveParameterCount)
            {
                return false;
            }

            // If the call is incomplete, we should skip the lower bound check.
            // JSX signatures can have extra parameters provided by the library which we don't check
            if (callIsIncomplete || argCount >= effectiveMinimumArguments) {
                return true;
            }
            for (let i = argCount; i < effectiveMinimumArguments; i++) {
                const type = getTypeAtPosition(signature, i);
                if (filterType(type, acceptsVoid).flags & TypeFlags.Never) {
                    return false;
                }
            }
            return true;
        }

        function hasCorrectTypeArgumentArity(
            signature: Signature,
            typeArguments: NodeArray<TypeNode> | undefined
        ) {
            // If the user supplied type arguments, but the number of type arguments does not match
            // the declared number of type parameters, the call has an incorrect arity.
            const numTypeParameters = length(signature.typeParameters);
            const minTypeArgumentCount = getMinTypeArgumentCount(
                signature.typeParameters
            );
            return !some(typeArguments)
                || (typeArguments.length >= minTypeArgumentCount
                    && typeArguments.length <= numTypeParameters);
        }

        // If type has a single call signature and no other members, return that signature. Otherwise, return undefined.
        function getSingleCallSignature(type: Type): Signature | undefined {
            return getSingleSignature(
                type,
                SignatureKind.Call, /*allowMembers*/
                false
            );
        }

        function getSingleCallOrConstructSignature(
            type: Type
        ): Signature | undefined {
            return getSingleSignature(
                type,
                SignatureKind.Call, /*allowMembers*/
                false
            )
                || getSingleSignature(
                    type,
                    SignatureKind.Construct, /*allowMembers*/
                    false
                );
        }

        function getSingleSignature(
            type: Type,
            kind: SignatureKind,
            allowMembers: boolean
        ): Signature | undefined {
            if (type.flags & TypeFlags.Object) {
                const resolved = resolveStructuredTypeMembers(<ObjectType> type);
                if (allowMembers || resolved.properties.length === 0
                    && !resolved.stringIndexInfo && !resolved.numberIndexInfo)
                {
                    if (kind === SignatureKind.Call
                        && resolved.callSignatures.length === 1
                        && resolved.constructSignatures.length === 0)
                    {
                        return resolved.callSignatures[0];
                    }
                    if (kind === SignatureKind.Construct
                        && resolved.constructSignatures.length === 1
                        && resolved.callSignatures.length === 0)
                    {
                        return resolved.constructSignatures[0];
                    }
                }
            }
            return undefined;
        }

        // Instantiate a generic signature in the context of a non-generic signature (section 3.8.5 in TypeScript spec)
        function instantiateSignatureInContextOf(
            signature: Signature,
            contextualSignature: Signature,
            inferenceContext?: InferenceContext,
            compareTypes?: TypeComparer
        ): Signature {
            const context = createInferenceContext(
                signature.typeParameters!,
                signature,
                InferenceFlags.None,
                compareTypes
            );
            // We clone the inferenceContext to avoid fixing. For example, when the source signature is <T>(x: T) => T[] and
            // the contextual signature is (...args: A) => B, we want to infer the element type of A's constraint (say 'any')
            // for T but leave it possible to later infer '[any]' back to A.
            const restType = getEffectiveRestType(contextualSignature);
            const mapper = inferenceContext
                && (restType && restType.flags & TypeFlags.TypeParameter
                    ? inferenceContext.nonFixingMapper
                    : inferenceContext.mapper);
            const sourceSignature = mapper
                ? instantiateSignature(contextualSignature, mapper)
                : contextualSignature;
            applyToParameterTypes(
                sourceSignature,
                signature,
                (source, target) => {
                    // Type parameters from outer context referenced by source type are fixed by instantiation of the source type
                    inferTypes(context.inferences, source, target);
                }
            );
            if (!inferenceContext) {
                applyToReturnTypes(
                    contextualSignature,
                    signature,
                    (source, target) => {
                        inferTypes(
                            context.inferences,
                            source,
                            target,
                            InferencePriority.ReturnType
                        );
                    }
                );
            }
            return getSignatureInstantiation(
                signature,
                getInferredTypes(context),
                isInJSFile(contextualSignature.declaration)
            );
        }

        function inferJsxTypeArguments(
            node: JsxOpeningLikeElement,
            signature: Signature,
            checkMode: CheckMode,
            context: InferenceContext
        ): Type[] {
            const paramType = getEffectiveFirstArgumentForJsxSignature(
                signature,
                node
            );
            const checkAttrType = checkExpressionWithContextualType(
                node.attributes,
                paramType,
                context,
                checkMode
            );
            inferTypes(context.inferences, checkAttrType, paramType);
            return getInferredTypes(context);
        }

        function inferTypeArguments(
            node: CallLikeExpression,
            signature: Signature,
            args: readonly Expression[],
            checkMode: CheckMode,
            context: InferenceContext
        ): Type[] {
            if (isJsxOpeningLikeElement(node)) {
                return inferJsxTypeArguments(
                    node,
                    signature,
                    checkMode,
                    context
                );
            }

            // If a contextual type is available, infer from that type to the return type of the call expression. For
            // example, given a 'function wrap<T, U>(cb: (x: T) => U): (x: T) => U' and a call expression
            // 'let f: (x: string) => number = wrap(s => s.length)', we infer from the declared type of 'f' to the
            // return type of 'wrap'.
            if (node.kind !== SyntaxKind.Decorator) {
                const contextualType = getContextualType(node);
                if (contextualType) {
                    // We clone the inference context to avoid disturbing a resolution in progress for an
                    // outer call expression. Effectively we just want a snapshot of whatever has been
                    // inferred for any outer call expression so far.
                    const outerContext = getInferenceContext(node);
                    const outerMapper = getMapperFromContext(
                        cloneInferenceContext(
                            outerContext,
                            InferenceFlags.NoDefault
                        )
                    );
                    const instantiatedType = instantiateType(
                        contextualType,
                        outerMapper
                    );
                    // If the contextual type is a generic function type with a single call signature, we
                    // instantiate the type with its own type parameters and type arguments. This ensures that
                    // the type parameters are not erased to type any during type inference such that they can
                    // be inferred as actual types from the contextual type. For example:
                    //   declare function arrayMap<T, U>(f: (x: T) => U): (a: T[]) => U[];
                    //   const boxElements: <A>(a: A[]) => { value: A }[] = arrayMap(value => ({ value }));
                    // Above, the type of the 'value' parameter is inferred to be 'A'.
                    const contextualSignature = getSingleCallSignature(instantiatedType);
                    const inferenceSourceType = contextualSignature
                        && contextualSignature.typeParameters
                        ? getOrCreateTypeFromSignature(
                            getSignatureInstantiationWithoutFillingInTypeArguments(
                                contextualSignature,
                                contextualSignature.typeParameters
                            )
                        )
                        : instantiatedType;
                    const inferenceTargetType = getReturnTypeOfSignature(signature);
                    // Inferences made from return types have lower priority than all other inferences.
                    inferTypes(
                        context.inferences,
                        inferenceSourceType,
                        inferenceTargetType,
                        InferencePriority.ReturnType
                    );
                    // Create a type mapper for instantiating generic contextual types using the inferences made
                    // from the return type. We need a separate inference pass here because (a) instantiation of
                    // the source type uses the outer context's return mapper (which excludes inferences made from
                    // outer arguments), and (b) we don't want any further inferences going into this context.
                    const returnContext = createInferenceContext(
                        signature.typeParameters!,
                        signature,
                        context.flags
                    );
                    const returnSourceType = instantiateType(
                        contextualType,
                        outerContext && outerContext.returnMapper
                    );
                    inferTypes(
                        returnContext.inferences,
                        returnSourceType,
                        inferenceTargetType
                    );
                    context
                        .returnMapper = some(
                            returnContext.inferences,
                            hasInferenceCandidates
                        )
                            ? getMapperFromContext(cloneInferredPartOfContext(returnContext))
                            : undefined;
                }
            }

            const thisType = getThisTypeOfSignature(signature);
            if (thisType) {
                const thisArgumentNode = getThisArgumentOfCall(node);
                const thisArgumentType = thisArgumentNode
                    ? checkExpression(thisArgumentNode)
                    : voidType;
                inferTypes(context.inferences, thisArgumentType, thisType);
            }

            const restType = getNonArrayRestType(signature);
            const argCount = restType
                ? Math.min(getParameterCount(signature) - 1, args.length)
                : args.length;
            for (let i = 0; i < argCount; i++) {
                const arg = args[i];
                if (arg.kind !== SyntaxKind.OmittedExpression) {
                    const paramType = getTypeAtPosition(signature, i);
                    const argType = checkExpressionWithContextualType(
                        arg,
                        paramType,
                        context,
                        checkMode
                    );
                    inferTypes(context.inferences, argType, paramType);
                }
            }

            if (restType) {
                const spreadType = getSpreadArgumentType(
                    args,
                    argCount,
                    args.length,
                    restType,
                    context
                );
                inferTypes(context.inferences, spreadType, restType);
            }

            return getInferredTypes(context);
        }

        function getArrayifiedType(type: Type) {
            return type.flags & TypeFlags.Union
                ? mapType(type, getArrayifiedType)
                : type.flags & (TypeFlags.Any | TypeFlags.Instantiable)
                    || isMutableArrayOrTuple(type)
                    ? type
                    : isTupleType(type)
                        ? createTupleType(
                            getTypeArguments(type),
                            type.target.minLength,
                            type.target.hasRestElement, /*readonly*/
                            false,
                            type.target.associatedNames
                        )
                        : createArrayType(
                            getIndexedAccessType(
                                type,
                                numberType
                            )
                        );
        }

        function getSpreadArgumentType(
            args: readonly Expression[],
            index: number,
            argCount: number,
            restType: Type,
            context: InferenceContext | undefined
        ) {
            if (index >= argCount - 1) {
                const arg = args[argCount - 1];
                if (isSpreadArgument(arg)) {
                    // We are inferring from a spread expression in the last argument position, i.e. both the parameter
                    // and the argument are ...x forms.
                    return arg.kind === SyntaxKind.SyntheticExpression
                        ? createArrayType((<SyntheticExpression> arg).type)
                        : getArrayifiedType(
                            checkExpressionWithContextualType(
                                (<SpreadElement> arg).expression,
                                restType,
                                context,
                                CheckMode.Normal
                            )
                        );
                }
            }
            const types = [];
            let spreadIndex = -1;
            for (let i = index; i < argCount; i++) {
                const contextualType = getIndexedAccessType(
                    restType,
                    getLiteralType(i - index)
                );
                const argType = checkExpressionWithContextualType(
                    args[i],
                    contextualType,
                    context,
                    CheckMode.Normal
                );
                if (spreadIndex < 0 && isSpreadArgument(args[i])) {
                    spreadIndex = i - index;
                }
                const hasPrimitiveContextualType = maybeTypeOfKind(
                    contextualType,
                    TypeFlags.Primitive | TypeFlags.Index
                );
                types
                    .push(
                        hasPrimitiveContextualType
                            ? getRegularTypeOfLiteralType(argType)
                            : getWidenedLiteralType(argType)
                    );
            }
            return spreadIndex < 0
                ? createTupleType(types)
                : createTupleType(
                    append(
                        types.slice(0, spreadIndex),
                        getUnionType(types.slice(spreadIndex))
                    ),
                    spreadIndex, /*hasRestElement*/
                    true
                );
        }

        function checkTypeArguments(
            signature: Signature,
            typeArgumentNodes: readonly TypeNode[],
            reportErrors: boolean,
            headMessage?: DiagnosticMessage
        ): Type[] | undefined {
            const isJavascript = isInJSFile(signature.declaration);
            const typeParameters = signature.typeParameters!;
            const typeArgumentTypes = fillMissingTypeArguments(
                map(
                    typeArgumentNodes,
                    getTypeFromTypeNode
                ),
                typeParameters,
                getMinTypeArgumentCount(typeParameters),
                isJavascript
            );
            let mapper: TypeMapper | undefined;
            for (let i = 0; i < typeArgumentNodes.length; i++) {
                Debug.assert(
                    typeParameters[i] !== undefined,
                    'Should not call checkTypeArguments with too many type arguments'
                );
                const constraint = getConstraintOfTypeParameter(
                    typeParameters[i]
                );
                if (constraint) {
                    const errorInfo = reportErrors && headMessage
                        ? (() => chainDiagnosticMessages(
                            /*details*/ undefined,
                            Diagnostics
                                .Type_0_does_not_satisfy_the_constraint_1
                        ))
                        : undefined;
                    const typeArgumentHeadMessage = headMessage
                        || Diagnostics
                            .Type_0_does_not_satisfy_the_constraint_1;
                    if (!mapper) {
                        mapper = createTypeMapper(
                            typeParameters,
                            typeArgumentTypes
                        );
                    }
                    const typeArgument = typeArgumentTypes[i];
                    if (!checkTypeAssignableTo(
                        typeArgument,
                        getTypeWithThisArgument(
                            instantiateType(
                                constraint,
                                mapper
                            ),
                            typeArgument
                        ),
                        reportErrors ? typeArgumentNodes[i] : undefined,
                        typeArgumentHeadMessage,
                        errorInfo
                    )) {
                        return undefined;
                    }
                }
            }
            return typeArgumentTypes;
        }

        function getJsxReferenceKind(
            node: JsxOpeningLikeElement
        ): JsxReferenceKind {
            if (isJsxIntrinsicIdentifier(node.tagName)) {
                return JsxReferenceKind.Mixed;
            }
            const tagType = getApparentType(checkExpression(node.tagName));
            if (length(getSignaturesOfType(tagType,
                SignatureKind.Construct)))
            {
                return JsxReferenceKind.Component;
            }
            if (length(getSignaturesOfType(tagType, SignatureKind.Call))) {
                return JsxReferenceKind.Function;
            }
            return JsxReferenceKind.Mixed;
        }

        /**
         * Check if the given signature can possibly be a signature called by the JSX opening-like element.
         * @param node a JSX opening-like element we are trying to figure its call signature
         * @param signature a candidate signature we are trying whether it is a call signature
         * @param relation a relationship to check parameter and argument type
         */
        function checkApplicableSignatureForJsxOpeningLikeElement(
            node: JsxOpeningLikeElement,
            signature: Signature,
            relation: Map<RelationComparisonResult>,
            checkMode: CheckMode,
            reportErrors: boolean,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined,
            errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; }
        ) {
            // Stateless function components can have maximum of three arguments: "props", "context", and "updater".
            // However "context" and "updater" are implicit and can't be specify by users. Only the first parameter, props,
            // can be specified by users through attributes property.
            const paramType = getEffectiveFirstArgumentForJsxSignature(
                signature,
                node
            );
            const attributesType = checkExpressionWithContextualType(
                node.attributes,
                paramType, /*inferenceContext*/
                undefined,
                checkMode
            );
            return checkTypeRelatedToAndOptionallyElaborate(
                attributesType,
                paramType,
                relation,
                reportErrors ? node.tagName : undefined,
                node.attributes,
                /*headMessage*/ undefined,
                containingMessageChain,
                errorOutputContainer
            );
        }

        function getSignatureApplicabilityError(
            node: CallLikeExpression,
            args: readonly Expression[],
            signature: Signature,
            relation: Map<RelationComparisonResult>,
            checkMode: CheckMode,
            reportErrors: boolean,
            containingMessageChain: (() => DiagnosticMessageChain | undefined)
                | undefined
        ): readonly Diagnostic[] | undefined {
            const errorOutputContainer: { errors?: Diagnostic[];
                skipLogging?: boolean; } = { errors: undefined,
                skipLogging: true };
            if (isJsxOpeningLikeElement(node)) {
                if (!checkApplicableSignatureForJsxOpeningLikeElement(
                    node,
                    signature,
                    relation,
                    checkMode,
                    reportErrors,
                    containingMessageChain,
                    errorOutputContainer
                )) {
                    Debug
                        .assert(
                            !reportErrors || !!errorOutputContainer.errors,
                            'jsx should have errors when reporting errors'
                        );
                    return errorOutputContainer.errors || emptyArray;
                }
                return undefined;
            }
            const thisType = getThisTypeOfSignature(signature);
            if (thisType && thisType !== voidType
                && node.kind !== SyntaxKind.NewExpression)
            {
                // If the called expression is not of the form `x.f` or `x["f"]`, then sourceType = voidType
                // If the signature's 'this' type is voidType, then the check is skipped -- anything is compatible.
                // If the expression is a new expression, then the check is skipped.
                const thisArgumentNode = getThisArgumentOfCall(node);
                let thisArgumentType: Type;
                if (thisArgumentNode) {
                    thisArgumentType = checkExpression(thisArgumentNode);
                    if (isOptionalChainRoot(thisArgumentNode.parent)) {
                        thisArgumentType = getNonNullableType(thisArgumentType);
                    } else if (isOptionalChain(thisArgumentNode.parent)) {
                        thisArgumentType = removeOptionalTypeMarker(thisArgumentType);
                    }
                } else {
                    thisArgumentType = voidType;
                }

                const errorNode = reportErrors
                    ? (thisArgumentNode || node)
                    : undefined;
                const headMessage = Diagnostics
                    .The_this_context_of_type_0_is_not_assignable_to_method_s_this_of_type_1;
                if (!checkTypeRelatedTo(
                    thisArgumentType,
                    thisType,
                    relation,
                    errorNode,
                    headMessage,
                    containingMessageChain,
                    errorOutputContainer
                )) {
                    Debug
                        .assert(
                            !reportErrors || !!errorOutputContainer.errors,
                            'this parameter should have errors when reporting errors'
                        );
                    return errorOutputContainer.errors || emptyArray;
                }
            }
            const headMessage = Diagnostics
                .Argument_of_type_0_is_not_assignable_to_parameter_of_type_1;
            const restType = getNonArrayRestType(signature);
            const argCount = restType
                ? Math.min(getParameterCount(signature) - 1, args.length)
                : args.length;
            for (let i = 0; i < argCount; i++) {
                const arg = args[i];
                if (arg.kind !== SyntaxKind.OmittedExpression) {
                    const paramType = getTypeAtPosition(signature, i);
                    const argType = checkExpressionWithContextualType(
                        arg,
                        paramType, /*inferenceContext*/
                        undefined,
                        checkMode
                    );
                    // If one or more arguments are still excluded (as indicated by CheckMode.SkipContextSensitive),
                    // we obtain the regular type of any object literal arguments because we may not have inferred complete
                    // parameter types yet and therefore excess property checks may yield false positives (see #17041).
                    const checkArgType = checkMode
                        & CheckMode.SkipContextSensitive
                        ? getRegularTypeOfObjectLiteral(argType)
                        : argType;
                    if (!checkTypeRelatedToAndOptionallyElaborate(
                        checkArgType,
                        paramType,
                        relation,
                        reportErrors ? arg : undefined,
                        arg,
                        headMessage,
                        containingMessageChain,
                        errorOutputContainer
                    )) {
                        Debug.assert(
                            !reportErrors || !!errorOutputContainer.errors,
                            'parameter should have errors when reporting errors'
                        );
                        maybeAddMissingAwaitInfo(
                            arg,
                            checkArgType,
                            paramType
                        );
                        return errorOutputContainer.errors || emptyArray;
                    }
                }
            }
            if (restType) {
                const spreadType = getSpreadArgumentType(
                    args,
                    argCount,
                    args.length,
                    restType, /*context*/
                    undefined
                );
                const errorNode = reportErrors
                    ? argCount < args.length ? args[argCount] : node
                    : undefined;
                if (!checkTypeRelatedTo(
                    spreadType,
                    restType,
                    relation,
                    errorNode,
                    headMessage, /*containingMessageChain*/
                    undefined,
                    errorOutputContainer
                )) {
                    Debug
                        .assert(
                            !reportErrors || !!errorOutputContainer.errors,
                            'rest parameter should have errors when reporting errors'
                        );
                    maybeAddMissingAwaitInfo(errorNode, spreadType, restType);
                    return errorOutputContainer.errors || emptyArray;
                }
            }
            return undefined;

            function maybeAddMissingAwaitInfo(
                errorNode: Node | undefined,
                source: Type,
                target: Type
            ) {
                if (errorNode && reportErrors && errorOutputContainer.errors
                    && errorOutputContainer.errors.length)
                {
                    // Bail if target is Promise-like---something else is wrong
                    if (getAwaitedTypeOfPromise(target)) {
                        return;
                    }
                    const awaitedTypeOfSource = getAwaitedTypeOfPromise(source);
                    if (awaitedTypeOfSource
                        && isTypeRelatedTo(
                            awaitedTypeOfSource,
                            target,
                            relation
                        ))
                    {
                        addRelatedInfo(
                            errorOutputContainer.errors[0],
                            createDiagnosticForNode(
                                errorNode,
                                Diagnostics.Did_you_forget_to_use_await
                            )
                        );
                    }
                }
            }
        }

        /**
         * Returns the this argument in calls like x.f(...) and x[f](...). Undefined otherwise.
         */
        function getThisArgumentOfCall(
            node: CallLikeExpression
        ): LeftHandSideExpression | undefined {
            if (node.kind === SyntaxKind.CallExpression) {
                const callee = skipOuterExpressions(node.expression);
                if (isAccessExpression(callee)) {
                    return callee.expression;
                }
            }
        }

        function createSyntheticExpression(
            parent: Node,
            type: Type,
            isSpread?: boolean
        ) {
            const result = <SyntheticExpression> createNode(
                SyntaxKind.SyntheticExpression,
                parent.pos,
                parent.end
            );
            result.parent = parent;
            result.type = type;
            result.isSpread = isSpread || false;
            return result;
        }

        /**
         * Returns the effective arguments for an expression that works like a function invocation.
         */
        function getEffectiveCallArguments(
            node: CallLikeExpression
        ): readonly Expression[] {
            if (node.kind === SyntaxKind.TaggedTemplateExpression) {
                const template = node.template;
                const args:
                    Expression[] = [createSyntheticExpression(
                        template,
                        getGlobalTemplateStringsArrayType()
                    )];
                if (template.kind === SyntaxKind.TemplateExpression) {
                    forEach(
                        template.templateSpans,
                        span => {
                            args.push(span.expression);
                        }
                    );
                }
                return args;
            }
            if (node.kind === SyntaxKind.Decorator) {
                return getEffectiveDecoratorArguments(node);
            }
            if (isJsxOpeningLikeElement(node)) {
                return node.attributes.properties.length > 0
                    || (isJsxOpeningElement(node)
                        && node.parent.children.length > 0)
                    ? [node.attributes]
                    : emptyArray;
            }
            const args = node.arguments || emptyArray;
            const length = args.length;
            if (length && isSpreadArgument(args[length - 1])
                && getSpreadArgumentIndex(args) === length - 1)
            {
                // We have a spread argument in the last position and no other spread arguments. If the type
                // of the argument is a tuple type, spread the tuple elements into the argument list. We can
                // call checkExpressionCached because spread expressions never have a contextual type.
                const spreadArgument = <SpreadElement> args[length - 1];
                const type = flowLoopCount
                    ? checkExpression(spreadArgument.expression)
                    : checkExpressionCached(spreadArgument.expression);
                if (isTupleType(type)) {
                    const typeArguments = getTypeArguments(<TypeReference> type);
                    const restIndex = type.target.hasRestElement
                        ? typeArguments.length - 1
                        : -1;
                    const syntheticArgs = map(
                        typeArguments,
                        (t, i) => createSyntheticExpression(
                            spreadArgument,
                            t, /*isSpread*/
                            i === restIndex
                        )
                    );
                    return concatenate(
                        args.slice(0, length - 1),
                        syntheticArgs
                    );
                }
            }
            return args;
        }

        /**
         * Returns the synthetic argument list for a decorator invocation.
         */
        function getEffectiveDecoratorArguments(
            node: Decorator
        ): readonly Expression[] {
            const parent = node.parent;
            const expr = node.expression;
            switch (parent.kind) {
                case SyntaxKind.ClassDeclaration:
                case SyntaxKind.ClassExpression:
                    // For a class decorator, the `target` is the type of the class (e.g. the
                    // "static" or "constructor" side of the class).
                    return [
                        createSyntheticExpression(
                            expr,
                            getTypeOfSymbol(getSymbolOfNode(parent))
                        )
                    ];
                case SyntaxKind.Parameter:
                    // A parameter declaration decorator will have three arguments (see
                    // `ParameterDecorator` in core.d.ts).
                    const func = <FunctionLikeDeclaration> parent.parent;
                    return [
                        createSyntheticExpression(
                            expr,
                            parent.parent.kind === SyntaxKind.Constructor
                                ? getTypeOfSymbol(getSymbolOfNode(func))
                                : errorType
                        ),
                        createSyntheticExpression(expr, anyType),
                        createSyntheticExpression(expr, numberType)
                    ];
                case SyntaxKind.PropertyDeclaration:
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.GetAccessor:
                case SyntaxKind.SetAccessor:
                    // A method or accessor declaration decorator will have two or three arguments (see
                    // `PropertyDecorator` and `MethodDecorator` in core.d.ts). If we are emitting decorators
                    // for ES3, we will only pass two arguments.
                    const hasPropDesc = parent.kind
                        !== SyntaxKind.PropertyDeclaration
                        && languageVersion !== ScriptTarget.ES3;
                    return [
                        createSyntheticExpression(
                            expr,
                            getParentTypeOfClassElement(<ClassElement> parent)
                        ),
                        createSyntheticExpression(
                            expr,
                            getClassElementPropertyKeyType(<ClassElement> parent)
                        ),
                        createSyntheticExpression(
                            expr,
                            hasPropDesc
                                ? createTypedPropertyDescriptorType(getTypeOfNode(parent))
                                : anyType
                        )
                    ];
            }
            return Debug.fail();
        }

        /**
         * Returns the argument count for a decorator node that works like a function invocation.
         */
        function getDecoratorArgumentCount(
            node: Decorator,
            signature: Signature
        ) {
            switch (node.parent.kind) {
                case SyntaxKind.ClassDeclaration:
                case SyntaxKind.ClassExpression:
                    return 1;
                case SyntaxKind.PropertyDeclaration:
                    return 2;
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.GetAccessor:
                case SyntaxKind.SetAccessor:
                    // For ES3 or decorators with only two parameters we supply only two arguments
                    return languageVersion === ScriptTarget.ES3
                        || signature.parameters.length <= 2
                        ? 2
                        : 3;
                case SyntaxKind.Parameter:
                    return 3;
                default:
                    return Debug.fail();
            }
        }
        function getDiagnosticSpanForCallNode(
            node: CallExpression,
            doNotIncludeArguments?: boolean
        ) {
            let start: number;
            let length: number;
            const sourceFile = getSourceFileOfNode(node);

            if (isPropertyAccessExpression(node.expression)) {
                const nameSpan = getErrorSpanForNode(
                    sourceFile,
                    node.expression.name
                );
                start = nameSpan.start;
                length = doNotIncludeArguments
                    ? nameSpan.length
                    : node.end - start;
            } else {
                const expressionSpan = getErrorSpanForNode(
                    sourceFile,
                    node.expression
                );
                start = expressionSpan.start;
                length = doNotIncludeArguments
                    ? expressionSpan.length
                    : node.end - start;
            }
            return { start, length, sourceFile };
        }
        function getDiagnosticForCallNode(
            node: CallLikeExpression,
            message: DiagnosticMessage,
            arg0?: string | number,
            arg1?: string | number,
            arg2?: string | number,
            arg3?: string | number
        ): DiagnosticWithLocation {
            if (isCallExpression(node)) {
                const { sourceFile, start,
                    length } = getDiagnosticSpanForCallNode(node);
                return createFileDiagnostic(
                    sourceFile,
                    start,
                    length,
                    message,
                    arg0,
                    arg1,
                    arg2,
                    arg3
                );
            } else {
                return createDiagnosticForNode(
                    node,
                    message,
                    arg0,
                    arg1,
                    arg2,
                    arg3
                );
            }
        }

        function getArgumentArityError(
            node: CallLikeExpression,
            signatures: readonly Signature[],
            args: readonly Expression[]
        ) {
            let min = Number.POSITIVE_INFINITY;
            let max = Number.NEGATIVE_INFINITY;
            let belowArgCount = Number.NEGATIVE_INFINITY;
            let aboveArgCount = Number.POSITIVE_INFINITY;

            let argCount = args.length;
            let closestSignature: Signature | undefined;
            for (const sig of signatures) {
                const minCount = getMinArgumentCount(sig);
                const maxCount = getParameterCount(sig);
                if (minCount < argCount
                    && minCount > belowArgCount)
                    belowArgCount = minCount;
                if (argCount < maxCount
                    && maxCount < aboveArgCount)
                    aboveArgCount = maxCount;
                if (minCount < min) {
                    min = minCount;
                    closestSignature = sig;
                }
                max = Math.max(max, maxCount);
            }

            const hasRestParameter = some(
                signatures,
                hasEffectiveRestParameter
            );
            const paramRange = hasRestParameter
                ? min
                : min < max
                    ? min + '-' + max
                    : min;
            const hasSpreadArgument = getSpreadArgumentIndex(args) > -1;
            if (argCount <= max && hasSpreadArgument) {
                argCount--;
            }

            let spanArray: NodeArray<Node>;
            let related: DiagnosticWithLocation | undefined;

            const error = hasRestParameter || hasSpreadArgument
                ? hasRestParameter && hasSpreadArgument
                    ? Diagnostics
                        .Expected_at_least_0_arguments_but_got_1_or_more
                    : hasRestParameter
                        ? Diagnostics.Expected_at_least_0_arguments_but_got_1
                        : Diagnostics.Expected_0_arguments_but_got_1_or_more
                : Diagnostics.Expected_0_arguments_but_got_1;

            if (closestSignature
                && getMinArgumentCount(closestSignature) > argCount
                && closestSignature.declaration)
            {
                const paramDecl = closestSignature.declaration.parameters
                    [closestSignature.thisParameter ? argCount + 1 : argCount];
                if (paramDecl) {
                    related = createDiagnosticForNode(
                        paramDecl,
                        isBindingPattern(paramDecl.name)
                            ? Diagnostics
                                .An_argument_matching_this_binding_pattern_was_not_provided
                            : Diagnostics.An_argument_for_0_was_not_provided,
                        !paramDecl.name
                            ? argCount
                            : !isBindingPattern(paramDecl.name)
                                ? idText(getFirstIdentifier(paramDecl.name))
                                : undefined
                    );
                }
            }
            if (min < argCount && argCount < max) {
                return getDiagnosticForCallNode(
                    node,
                    Diagnostics
                        .No_overload_expects_0_arguments_but_overloads_do_exist_that_expect_either_1_or_2_arguments,
                    argCount,
                    belowArgCount,
                    aboveArgCount
                );
            }

            if (!hasSpreadArgument && argCount < min) {
                const diagnostic = getDiagnosticForCallNode(
                    node,
                    error,
                    paramRange,
                    argCount
                );
                return related
                    ? addRelatedInfo(diagnostic, related)
                    : diagnostic;
            }

            if (hasRestParameter || hasSpreadArgument) {
                spanArray = createNodeArray(args);
                if (hasSpreadArgument && argCount) {
                    const nextArg = elementAt(
                        args,
                        getSpreadArgumentIndex(args) + 1
                    ) || undefined;
                    spanArray = createNodeArray(
                        args.slice(
                            max > argCount && nextArg
                                ? args.indexOf(nextArg)
                                : Math.min(max, args.length - 1)
                        )
                    );
                }
            } else {
                spanArray = createNodeArray(args.slice(max));
            }

            spanArray.pos = first(spanArray).pos;
            spanArray.end = last(spanArray).end;
            if (spanArray.end === spanArray.pos) {
                spanArray.end++;
            }
            const diagnostic = createDiagnosticForNodeArray(
                getSourceFileOfNode(node),
                spanArray,
                error,
                paramRange,
                argCount
            );
            return related ? addRelatedInfo(diagnostic, related) : diagnostic;
        }

        function getTypeArgumentArityError(
            node: Node,
            signatures: readonly Signature[],
            typeArguments: NodeArray<TypeNode>
        ) {
            const argCount = typeArguments.length;
            // No overloads exist
            if (signatures.length === 1) {
                const sig = signatures[0];
                const min = getMinTypeArgumentCount(sig.typeParameters);
                const max = length(sig.typeParameters);
                return createDiagnosticForNodeArray(
                    getSourceFileOfNode(node),
                    typeArguments,
                    Diagnostics.Expected_0_type_arguments_but_got_1,
                    min < max ? min + '-' + max : min,
                    argCount
                );
            }
            // Overloads exist
            let belowArgCount = -Infinity;
            let aboveArgCount = Infinity;
            for (const sig of signatures) {
                const min = getMinTypeArgumentCount(sig.typeParameters);
                const max = length(sig.typeParameters);
                if (min > argCount) {
                    aboveArgCount = Math.min(aboveArgCount, min);
                } else if (max < argCount) {
                    belowArgCount = Math.max(belowArgCount, max);
                }
            }
            if (belowArgCount !== -Infinity && aboveArgCount !== Infinity) {
                return createDiagnosticForNodeArray(
                    getSourceFileOfNode(node),
                    typeArguments,
                    Diagnostics
                        .No_overload_expects_0_type_arguments_but_overloads_do_exist_that_expect_either_1_or_2_type_arguments,
                    argCount,
                    belowArgCount,
                    aboveArgCount
                );
            }
            return createDiagnosticForNodeArray(
                getSourceFileOfNode(node),
                typeArguments,
                Diagnostics.Expected_0_type_arguments_but_got_1,
                belowArgCount === -Infinity ? aboveArgCount : belowArgCount,
                argCount
            );
        }

        function resolveCall(
            node: CallLikeExpression,
            signatures: readonly Signature[],
            candidatesOutArray: Signature[] | undefined,
            checkMode: CheckMode,
            callChainFlags: SignatureFlags,
            fallbackError?: DiagnosticMessage
        ): Signature {
            const isTaggedTemplate = node.kind
                === SyntaxKind.TaggedTemplateExpression;
            const isDecorator = node.kind === SyntaxKind.Decorator;
            const isJsxOpeningOrSelfClosingElement = isJsxOpeningLikeElement(node);
            const reportErrors = !candidatesOutArray;

            let typeArguments: NodeArray<TypeNode> | undefined;

            if (!isDecorator) {
                typeArguments = (<CallExpression> node).typeArguments;

                // We already perform checking on the type arguments on the class declaration itself.
                if (isTaggedTemplate || isJsxOpeningOrSelfClosingElement
                    || (<CallExpression> node).expression.kind
                    !== SyntaxKind.SuperKeyword)
                {
                    forEach(typeArguments, checkSourceElement);
                }
            }

            const candidates = candidatesOutArray || [];
            // reorderCandidates fills up the candidates array directly
            reorderCandidates(signatures, candidates, callChainFlags);
            if (!candidates.length) {
                if (reportErrors) {
                    diagnostics
                        .add(
                            getDiagnosticForCallNode(
                                node,
                                Diagnostics
                                    .Call_target_does_not_contain_any_signatures
                            )
                        );
                }
                return resolveErrorCall(node);
            }

            const args = getEffectiveCallArguments(node);

            // The excludeArgument array contains true for each context sensitive argument (an argument
            // is context sensitive it is susceptible to a one-time permanent contextual typing).
            //
            // The idea is that we will perform type argument inference & assignability checking once
            // without using the susceptible parameters that are functions, and once more for those
            // parameters, contextually typing each as we go along.
            //
            // For a tagged template, then the first argument be 'undefined' if necessary because it
            // represents a TemplateStringsArray.
            //
            // For a decorator, no arguments are susceptible to contextual typing due to the fact
            // decorators are applied to a declaration by the emitter, and not to an expression.
            const isSingleNonGenericCandidate = candidates.length === 1
                && !candidates[0].typeParameters;
            let argCheckMode = !isDecorator && !isSingleNonGenericCandidate
                && some(args, isContextSensitive)
                ? CheckMode.SkipContextSensitive
                : CheckMode.Normal;

            // The following variables are captured and modified by calls to chooseOverload.
            // If overload resolution or type argument inference fails, we want to report the
            // best error possible. The best error is one which says that an argument was not
            // assignable to a parameter. This implies that everything else about the overload
            // was fine. So if there is any overload that is only incorrect because of an
            // argument, we will report an error on that one.
            //
            //     function foo(s: string): void;
            //     function foo(n: number): void; // Report argument error on this overload
            //     function foo(): void;
            //     foo(true);
            //
            // If none of the overloads even made it that far, there are two possibilities.
            // There was a problem with type arguments for some overload, in which case
            // report an error on that. Or none of the overloads even had correct arity,
            // in which case give an arity error.
            //
            //     function foo<T extends string>(x: T): void; // Report type argument error
            //     function foo(): void;
            //     foo<number>(0);
            //
            let candidatesForArgumentError: Signature[] | undefined;
            let candidateForArgumentArityError: Signature | undefined;
            let candidateForTypeArgumentError: Signature | undefined;
            let result: Signature | undefined;

            // If we are in signature help, a trailing comma indicates that we intend to provide another argument,
            // so we will only accept overloads with arity at least 1 higher than the current number of provided arguments.
            const signatureHelpTrailingComma = !!(checkMode
                & CheckMode.IsForSignatureHelp)
                && node.kind === SyntaxKind.CallExpression
                && node.arguments.hasTrailingComma;

            // Section 4.12.1:
            // if the candidate list contains one or more signatures for which the type of each argument
            // expression is a subtype of each corresponding parameter type, the return type of the first
            // of those signatures becomes the return type of the function call.
            // Otherwise, the return type of the first signature in the candidate list becomes the return
            // type of the function call.
            //
            // Whether the call is an error is determined by assignability of the arguments. The subtype pass
            // is just important for choosing the best signature. So in the case where there is only one
            // signature, the subtype pass is useless. So skipping it is an optimization.
            if (candidates.length > 1) {
                result = chooseOverload(
                    candidates,
                    subtypeRelation,
                    signatureHelpTrailingComma
                );
            }
            if (!result) {
                result = chooseOverload(
                    candidates,
                    assignableRelation,
                    signatureHelpTrailingComma
                );
            }
            if (result) {
                return result;
            }

            // No signatures were applicable. Now report errors based on the last applicable signature with
            // no arguments excluded from assignability checks.
            // If candidate is undefined, it means that no candidates had a suitable arity. In that case,
            // skip the checkApplicableSignature check.
            if (reportErrors) {
                if (candidatesForArgumentError) {
                    if (candidatesForArgumentError.length === 1
                        || candidatesForArgumentError.length > 3)
                    {
                        const last = candidatesForArgumentError
                            [candidatesForArgumentError.length - 1];
                        let chain: DiagnosticMessageChain | undefined;
                        if (candidatesForArgumentError.length > 3) {
                            chain = chainDiagnosticMessages(
                                chain,
                                Diagnostics
                                    .The_last_overload_gave_the_following_error
                            );
                            chain = chainDiagnosticMessages(
                                chain,
                                Diagnostics.No_overload_matches_this_call
                            );
                        }
                        const diags = getSignatureApplicabilityError(
                            node,
                            args,
                            last,
                            assignableRelation,
                            CheckMode.Normal, /*reportErrors*/
                            true,
                            () => chain
                        );
                        if (diags) {
                            for (const d of diags) {
                                if (last.declaration
                                    && candidatesForArgumentError.length > 3)
                                {
                                    addRelatedInfo(
                                        d,
                                        createDiagnosticForNode(
                                            last.declaration,
                                            Diagnostics
                                                .The_last_overload_is_declared_here
                                        )
                                    );
                                }
                                diagnostics.add(d);
                            }
                        } else {
                            Debug.fail('No error for last overload signature');
                        }
                    } else {
                        const allDiagnostics:
                            (readonly DiagnosticRelatedInformation[])[] = [];
                        let max = 0;
                        let min = Number.MAX_VALUE;
                        let minIndex = 0;
                        let i = 0;
                        for (const c of candidatesForArgumentError) {
                            const chain = () => chainDiagnosticMessages(
                                /*details*/ undefined,
                                Diagnostics
                                    .Overload_0_of_1_2_gave_the_following_error,
                                i + 1,
                                candidates.length,
                                signatureToString(c)
                            );
                            const diags = getSignatureApplicabilityError(
                                node,
                                args,
                                c,
                                assignableRelation,
                                CheckMode.Normal, /*reportErrors*/
                                true,
                                chain
                            );
                            if (diags) {
                                if (diags.length <= min) {
                                    min = diags.length;
                                    minIndex = i;
                                }
                                max = Math.max(max, diags.length);
                                allDiagnostics.push(diags);
                            } else {
                                Debug
                                    .fail('No error for 3 or fewer overload signatures');
                            }
                            i++;
                        }

                        const diags = max > 1
                            ? allDiagnostics[minIndex]
                            : flatten(allDiagnostics);
                        Debug.assert(
                            diags.length > 0,
                            'No errors reported for 3 or fewer overload signatures'
                        );
                        const chain = chainDiagnosticMessages(
                            map(
                                diags,
                                d => typeof d.messageText === 'string'
                                    ? (d as DiagnosticMessageChain)
                                    : d.messageText
                            ),
                            Diagnostics.No_overload_matches_this_call
                        );
                        const related = flatMap(
                            diags,
                            d => (d as Diagnostic).relatedInformation
                        ) as DiagnosticRelatedInformation[];
                        if (every(
                            diags,
                            d => d.start === diags[0].start
                                && d.length === diags[0].length
                                && d.file === diags[0].file
                        )) {
                            const { file, start, length } = diags[0];
                            diagnostics
                                .add(
                                    { file, start, length, code: chain.code,
                                        category: chain.category,
                                        messageText: chain,
                                        relatedInformation: related }
                                );
                        } else {
                            diagnostics
                                .add(
                                    createDiagnosticForNodeFromMessageChain(
                                        node,
                                        chain,
                                        related
                                    )
                                );
                        }
                    }
                } else if (candidateForArgumentArityError) {
                    diagnostics
                        .add(
                            getArgumentArityError(
                                node,
                                [candidateForArgumentArityError],
                                args
                            )
                        );
                } else if (candidateForTypeArgumentError) {
                    checkTypeArguments(
                        candidateForTypeArgumentError,
                        (node as CallExpression | TaggedTemplateExpression
                            | JsxOpeningLikeElement)
                            .typeArguments!, /*reportErrors*/
                        true,
                        fallbackError
                    );
                } else {
                    const signaturesWithCorrectTypeArgumentArity = filter(
                        signatures,
                        s => hasCorrectTypeArgumentArity(s, typeArguments)
                    );
                    if (signaturesWithCorrectTypeArgumentArity.length === 0) {
                        diagnostics
                            .add(
                                getTypeArgumentArityError(
                                    node,
                                    signatures,
                                    typeArguments!
                                )
                            );
                    } else if (!isDecorator) {
                        diagnostics
                            .add(
                                getArgumentArityError(
                                    node,
                                    signaturesWithCorrectTypeArgumentArity,
                                    args
                                )
                            );
                    } else if (fallbackError) {
                        diagnostics
                            .add(getDiagnosticForCallNode(node,
                                fallbackError));
                    }
                }
            }

            return produceDiagnostics || !args
                ? resolveErrorCall(node)
                : getCandidateForOverloadFailure(
                    node,
                    candidates,
                    args,
                    !!candidatesOutArray
                );

            function chooseOverload(
                candidates: Signature[],
                relation: Map<RelationComparisonResult>,
                signatureHelpTrailingComma = false
            ) {
                candidatesForArgumentError = undefined;
                candidateForArgumentArityError = undefined;
                candidateForTypeArgumentError = undefined;

                if (isSingleNonGenericCandidate) {
                    const candidate = candidates[0];
                    if (some(typeArguments)
                        || !hasCorrectArity(
                            node,
                            args,
                            candidate,
                            signatureHelpTrailingComma
                        ))
                    {
                        return undefined;
                    }
                    if (getSignatureApplicabilityError(
                        node,
                        args,
                        candidate,
                        relation,
                        CheckMode.Normal, /*reportErrors*/
                        false, /*containingMessageChain*/
                        undefined
                    )) {
                        candidatesForArgumentError = [candidate];
                        return undefined;
                    }
                    return candidate;
                }

                for (let candidateIndex = 0;
                    candidateIndex < candidates.length; candidateIndex++)
                {
                    const candidate = candidates[candidateIndex];
                    if (!hasCorrectTypeArgumentArity(candidate, typeArguments)
                        || !hasCorrectArity(
                            node,
                            args,
                            candidate,
                            signatureHelpTrailingComma
                        ))
                    {
                        continue;
                    }

                    let checkCandidate: Signature;
                    let inferenceContext: InferenceContext | undefined;

                    if (candidate.typeParameters) {
                        let typeArgumentTypes: Type[] | undefined;
                        if (some(typeArguments)) {
                            typeArgumentTypes = checkTypeArguments(
                                candidate,
                                typeArguments, /*reportErrors*/
                                false
                            );
                            if (!typeArgumentTypes) {
                                candidateForTypeArgumentError = candidate;
                                continue;
                            }
                        } else {
                            inferenceContext = createInferenceContext(
                                candidate.typeParameters,
                                candidate, /*flags*/
                                isInJSFile(node)
                                    ? InferenceFlags.AnyDefault
                                    : InferenceFlags.None
                            );
                            typeArgumentTypes = inferTypeArguments(
                                node,
                                candidate,
                                args,
                                argCheckMode | CheckMode.SkipGenericFunctions,
                                inferenceContext
                            );
                            argCheckMode |= inferenceContext.flags
                                & InferenceFlags.SkippedGenericFunction
                                ? CheckMode.SkipGenericFunctions
                                : CheckMode.Normal;
                        }
                        checkCandidate = getSignatureInstantiation(
                            candidate,
                            typeArgumentTypes,
                            isInJSFile(candidate.declaration),
                            inferenceContext
                                && inferenceContext.inferredTypeParameters
                        );
                        // If the original signature has a generic rest type, instantiation may produce a
                        // signature with different arity and we need to perform another arity check.
                        if (getNonArrayRestType(candidate)
                            && !hasCorrectArity(
                                node,
                                args,
                                checkCandidate,
                                signatureHelpTrailingComma
                            ))
                        {
                            candidateForArgumentArityError = checkCandidate;
                            continue;
                        }
                    } else {
                        checkCandidate = candidate;
                    }
                    if (getSignatureApplicabilityError(
                        node,
                        args,
                        checkCandidate,
                        relation,
                        argCheckMode, /*reportErrors*/
                        false, /*containingMessageChain*/
                        undefined
                    )) {
                        // Give preference to error candidates that have no rest parameters (as they are more specific)
                        (candidatesForArgumentError
                            || (candidatesForArgumentError = []))
                            .push(checkCandidate);
                        continue;
                    }
                    if (argCheckMode) {
                        // If one or more context sensitive arguments were excluded, we start including
                        // them now (and keeping do so for any subsequent candidates) and perform a second
                        // round of type inference and applicability checking for this particular candidate.
                        argCheckMode = CheckMode.Normal;
                        if (inferenceContext) {
                            const typeArgumentTypes = inferTypeArguments(
                                node,
                                candidate,
                                args,
                                argCheckMode,
                                inferenceContext
                            );
                            checkCandidate = getSignatureInstantiation(
                                candidate,
                                typeArgumentTypes,
                                isInJSFile(candidate.declaration),
                                inferenceContext
                                    && inferenceContext.inferredTypeParameters
                            );
                            // If the original signature has a generic rest type, instantiation may produce a
                            // signature with different arity and we need to perform another arity check.
                            if (getNonArrayRestType(candidate)
                                && !hasCorrectArity(
                                    node,
                                    args,
                                    checkCandidate,
                                    signatureHelpTrailingComma
                                ))
                            {
                                candidateForArgumentArityError = checkCandidate;
                                continue;
                            }
                        }
                        if (getSignatureApplicabilityError(
                            node,
                            args,
                            checkCandidate,
                            relation,
                            argCheckMode, /*reportErrors*/
                            false, /*containingMessageChain*/
                            undefined
                        )) {
                            // Give preference to error candidates that have no rest parameters (as they are more specific)
                            (candidatesForArgumentError
                                || (candidatesForArgumentError = []))
                                .push(checkCandidate);
                            continue;
                        }
                    }
                    candidates[candidateIndex] = checkCandidate;
                    return checkCandidate;
                }

                return undefined;
            }
        }

        // No signature was applicable. We have already reported the errors for the invalid signature.
        // If this is a type resolution session, e.g. Language Service, try to get better information than anySignature.
        function getCandidateForOverloadFailure(
            node: CallLikeExpression,
            candidates: Signature[],
            args: readonly Expression[],
            hasCandidatesOutArray: boolean
        ): Signature {
            Debug
                .assert(candidates.length
                    > 0); // Else should not have called this.
            // Normally we will combine overloads. Skip this if they have type parameters since that's hard to combine.
            // Don't do this if there is a `candidatesOutArray`,
            // because then we want the chosen best candidate to be one of the overloads, not a combination.
            return hasCandidatesOutArray || candidates.length === 1
                || candidates.some(c => !!c.typeParameters)
                ? pickLongestCandidateSignature(node, candidates, args)
                : createUnionOfSignaturesForOverloadFailure(candidates);
        }

        function createUnionOfSignaturesForOverloadFailure(
            candidates: readonly Signature[]
        ): Signature {
            const thisParameters = mapDefined(candidates,
                c => c.thisParameter);
            let thisParameter: Symbol | undefined;
            if (thisParameters.length) {
                thisParameter = createCombinedSymbolFromTypes(
                    thisParameters,
                    thisParameters.map(getTypeOfParameter)
                );
            }
            const { min: minArgumentCount,
                max: maxNonRestParam } = minAndMax(
                    candidates,
                    getNumNonRestParameters
                );
            const parameters: Symbol[] = [];
            for (let i = 0; i < maxNonRestParam; i++) {
                const symbols = mapDefined(
                    candidates,
                    s => signatureHasRestParameter(s)
                        ? i < s.parameters.length - 1
                            ? s.parameters[i]
                            : last(s.parameters)
                        : i < s.parameters.length ? s.parameters[i] : undefined
                );
                Debug.assert(symbols.length !== 0);
                parameters
                    .push(
                        createCombinedSymbolFromTypes(
                            symbols,
                            mapDefined(
                                candidates,
                                candidate => tryGetTypeAtPosition(candidate, i)
                            )
                        )
                    );
            }
            const restParameterSymbols = mapDefined(
                candidates,
                c => signatureHasRestParameter(c)
                    ? last(c.parameters)
                    : undefined
            );
            let flags = SignatureFlags.None;
            if (restParameterSymbols.length !== 0) {
                const type = createArrayType(
                    getUnionType(
                        mapDefined(
                            candidates,
                            tryGetRestTypeOfSignature
                        ),
                        UnionReduction.Subtype
                    )
                );
                parameters
                    .push(
                        createCombinedSymbolForOverloadFailure(
                            restParameterSymbols,
                            type
                        )
                    );
                flags |= SignatureFlags.HasRestParameter;
            }
            if (candidates.some(signatureHasLiteralTypes)) {
                flags |= SignatureFlags.HasLiteralTypes;
            }
            return createSignature(
                candidates[0].declaration,
                /*typeParameters*/ undefined, // Before calling this we tested for `!candidates.some(c => !!c.typeParameters)`.
                thisParameter,
                parameters,
                /*resolvedReturnType*/ getIntersectionType(
                    candidates.map(getReturnTypeOfSignature)
                ),
                /*typePredicate*/ undefined,
                minArgumentCount,
                flags
            );
        }

        function getNumNonRestParameters(signature: Signature): number {
            const numParams = signature.parameters.length;
            return signatureHasRestParameter(signature)
                ? numParams - 1
                : numParams;
        }

        function createCombinedSymbolFromTypes(
            sources: readonly Symbol[],
            types: Type[]
        ): Symbol {
            return createCombinedSymbolForOverloadFailure(
                sources,
                getUnionType(types, UnionReduction.Subtype)
            );
        }

        function createCombinedSymbolForOverloadFailure(
            sources: readonly Symbol[],
            type: Type
        ): Symbol {
            // This function is currently only used for erroneous overloads, so it's good enough to just use the first source.
            return createSymbolWithType(first(sources), type);
        }

        function pickLongestCandidateSignature(
            node: CallLikeExpression,
            candidates: Signature[],
            args: readonly Expression[]
        ): Signature {
            // Pick the longest signature. This way we can get a contextual type for cases like:
            //     declare function f(a: { xa: number; xb: number; }, b: number);
            //     f({ |
            // Also, use explicitly-supplied type arguments if they are provided, so we can get a contextual signature in cases like:
            //     declare function f<T>(k: keyof T);
            //     f<Foo>("
            const bestIndex = getLongestCandidateIndex(
                candidates,
                apparentArgumentCount === undefined
                    ? args.length
                    : apparentArgumentCount
            );
            const candidate = candidates[bestIndex];
            const { typeParameters } = candidate;
            if (!typeParameters) {
                return candidate;
            }

            const typeArgumentNodes: readonly TypeNode[]
                | undefined = callLikeExpressionMayHaveTypeArguments(node)
                ? node.typeArguments
                : undefined;
            const instantiated = typeArgumentNodes
                ? createSignatureInstantiation(
                    candidate,
                    getTypeArgumentsFromNodes(
                        typeArgumentNodes,
                        typeParameters,
                        isInJSFile(node)
                    )
                )
                : inferSignatureInstantiationForOverloadFailure(
                    node,
                    typeParameters,
                    candidate,
                    args
                );
            candidates[bestIndex] = instantiated;
            return instantiated;
        }

        function getTypeArgumentsFromNodes(
            typeArgumentNodes: readonly TypeNode[],
            typeParameters: readonly TypeParameter[],
            isJs: boolean
        ): readonly Type[] {
            const typeArguments = typeArgumentNodes.map(getTypeOfNode);
            while (typeArguments.length > typeParameters.length) {
                typeArguments.pop();
            }
            while (typeArguments.length < typeParameters.length) {
                typeArguments
                    .push(
                        getConstraintOfTypeParameter(
                            typeParameters[typeArguments.length]
                        ) || getDefaultTypeArgumentType(isJs)
                    );
            }
            return typeArguments;
        }

        function inferSignatureInstantiationForOverloadFailure(
            node: CallLikeExpression,
            typeParameters: readonly TypeParameter[],
            candidate: Signature,
            args: readonly Expression[]
        ): Signature {
            const inferenceContext = createInferenceContext(
                typeParameters,
                candidate, /*flags*/
                isInJSFile(node)
                    ? InferenceFlags.AnyDefault
                    : InferenceFlags.None
            );
            const typeArgumentTypes = inferTypeArguments(
                node,
                candidate,
                args,
                CheckMode.SkipContextSensitive
                    | CheckMode.SkipGenericFunctions,
                inferenceContext
            );
            return createSignatureInstantiation(candidate, typeArgumentTypes);
        }

        function getLongestCandidateIndex(
            candidates: Signature[],
            argsCount: number
        ): number {
            let maxParamsIndex = -1;
            let maxParams = -1;

            for (let i = 0; i < candidates.length; i++) {
                const candidate = candidates[i];
                const paramCount = getParameterCount(candidate);
                if (hasEffectiveRestParameter(candidate)
                    || paramCount >= argsCount)
                {
                    return i;
                }
                if (paramCount > maxParams) {
                    maxParams = paramCount;
                    maxParamsIndex = i;
                }
            }

            return maxParamsIndex;
        }

        function resolveCallExpression(
            node: CallExpression,
            candidatesOutArray: Signature[] | undefined,
            checkMode: CheckMode
        ): Signature {
            if (node.expression.kind === SyntaxKind.SuperKeyword) {
                const superType = checkSuperExpression(node.expression);
                if (isTypeAny(superType)) {
                    for (const arg of node.arguments) {
                        checkExpression(arg); // Still visit arguments so they get marked for visibility, etc
                    }
                    return anySignature;
                }
                if (superType !== errorType) {
                    // In super call, the candidate signatures are the matching arity signatures of the base constructor function instantiated
                    // with the type arguments specified in the extends clause.
                    const baseTypeNode = getEffectiveBaseTypeNode(getContainingClass(node)!);
                    if (baseTypeNode) {
                        const baseConstructors = getInstantiatedConstructorsForTypeArguments(
                            superType,
                            baseTypeNode.typeArguments,
                            baseTypeNode
                        );
                        return resolveCall(
                            node,
                            baseConstructors,
                            candidatesOutArray,
                            checkMode,
                            SignatureFlags.None
                        );
                    }
                }
                return resolveUntypedCall(node);
            }

            let callChainFlags: SignatureFlags;
            let funcType = checkExpression(node.expression);
            if (isCallChain(node)) {
                const nonOptionalType = getOptionalExpressionType(
                    funcType,
                    node.expression
                );
                callChainFlags = nonOptionalType === funcType
                    ? SignatureFlags.None
                    : isOutermostOptionalChain(node)
                        ? SignatureFlags.IsOuterCallChain
                        : SignatureFlags.IsInnerCallChain;
                funcType = nonOptionalType;
            } else {
                callChainFlags = SignatureFlags.None;
            }

            funcType = checkNonNullTypeWithReporter(
                funcType,
                node.expression,
                reportCannotInvokePossiblyNullOrUndefinedError
            );

            if (funcType === silentNeverType) {
                return silentNeverSignature;
            }

            const apparentType = getApparentType(funcType);
            if (apparentType === errorType) {
                // Another error has already been reported
                return resolveErrorCall(node);
            }

            // Technically, this signatures list may be incomplete. We are taking the apparent type,
            // but we are not including call signatures that may have been added to the Object or
            // Function interface, since they have none by default. This is a bit of a leap of faith
            // that the user will not add any.
            const callSignatures = getSignaturesOfType(
                apparentType,
                SignatureKind.Call
            );
            const numConstructSignatures = getSignaturesOfType(
                apparentType,
                SignatureKind.Construct
            ).length;

            // TS 1.0 Spec: 4.12
            // In an untyped function call no TypeArgs are permitted, Args can be any argument list, no contextual
            // types are provided for the argument expressions, and the result is always of type Any.
            if (isUntypedFunctionCall(
                funcType,
                apparentType,
                callSignatures.length,
                numConstructSignatures
            )) {
                // The unknownType indicates that an error already occurred (and was reported).  No
                // need to report another error in this case.
                if (funcType !== errorType && node.typeArguments) {
                    error(
                        node,
                        Diagnostics
                            .Untyped_function_calls_may_not_accept_type_arguments
                    );
                }
                return resolveUntypedCall(node);
            }
            // If FuncExpr's apparent type(section 3.8.1) is a function type, the call is a typed function call.
            // TypeScript employs overload resolution in typed function calls in order to support functions
            // with multiple call signatures.
            if (!callSignatures.length) {
                if (numConstructSignatures) {
                    error(
                        node,
                        Diagnostics
                            .Value_of_type_0_is_not_callable_Did_you_mean_to_include_new,
                        typeToString(funcType)
                    );
                } else {
                    let relatedInformation: DiagnosticRelatedInformation
                        | undefined;
                    if (node.arguments.length === 1) {
                        const text = getSourceFileOfNode(node).text;
                        if (isLineBreak(
                            text.charCodeAt(
                                skipTrivia(
                                    text,
                                    node.expression
                                        .end, /* stopAfterLineBreak */
                                    true
                                ) - 1
                            )
                        )) {
                            relatedInformation = createDiagnosticForNode(
                                node.expression,
                                Diagnostics
                                    .It_is_highly_likely_that_you_are_missing_a_semicolon
                            );
                        }
                    }
                    invocationError(
                        node.expression,
                        apparentType,
                        SignatureKind.Call,
                        relatedInformation
                    );
                }
                return resolveErrorCall(node);
            }
            // When a call to a generic function is an argument to an outer call to a generic function for which
            // inference is in process, we have a choice to make. If the inner call relies on inferences made from
            // its contextual type to its return type, deferring the inner call processing allows the best possible
            // contextual type to accumulate. But if the outer call relies on inferences made from the return type of
            // the inner call, the inner call should be processed early. There's no sure way to know which choice is
            // right (only a full unification algorithm can determine that), so we resort to the following heuristic:
            // If no type arguments are specified in the inner call and at least one call signature is generic and
            // returns a function type, we choose to defer processing. This narrowly permits function composition
            // operators to flow inferences through return types, but otherwise processes calls right away. We
            // use the resolvingSignature singleton to indicate that we deferred processing. This result will be
            // propagated out and eventually turned into nonInferrableType (a type that is assignable to anything and
            // from which we never make inferences).
            if (checkMode & CheckMode.SkipGenericFunctions
                && !node.typeArguments
                && callSignatures.some(isGenericFunctionReturningFunction))
            {
                skippedGenericFunction(node, checkMode);
                return resolvingSignature;
            }
            // If the function is explicitly marked with `@class`, then it must be constructed.
            if (callSignatures
                .some(sig => isInJSFile(sig.declaration)
                    && !!getJSDocClassTag(sig.declaration!)))
            {
                error(
                    node,
                    Diagnostics
                        .Value_of_type_0_is_not_callable_Did_you_mean_to_include_new,
                    typeToString(funcType)
                );
                return resolveErrorCall(node);
            }

            return resolveCall(
                node,
                callSignatures,
                candidatesOutArray,
                checkMode,
                callChainFlags
            );
        }

        function isGenericFunctionReturningFunction(signature: Signature) {
            return !!(signature.typeParameters
                && isFunctionType(getReturnTypeOfSignature(signature)));
        }

        /**
         * TS 1.0 spec: 4.12
         * If FuncExpr is of type Any, or of an object type that has no call or construct signatures
         * but is a subtype of the Function interface, the call is an untyped function call.
         */
        function isUntypedFunctionCall(
            funcType: Type,
            apparentFuncType: Type,
            numCallSignatures: number,
            numConstructSignatures: number
        ): boolean {
            // We exclude union types because we may have a union of function types that happen to have no common signatures.
            return isTypeAny(funcType) || isTypeAny(apparentFuncType)
                && !!(funcType.flags & TypeFlags.TypeParameter)
                || !numCallSignatures && !numConstructSignatures
                && !(apparentFuncType.flags
                    & (TypeFlags.Union | TypeFlags.Never))
                && isTypeAssignableTo(funcType, globalFunctionType);
        }

        function resolveNewExpression(
            node: NewExpression,
            candidatesOutArray: Signature[] | undefined,
            checkMode: CheckMode
        ): Signature {
            if (node.arguments && languageVersion < ScriptTarget.ES5) {
                const spreadIndex = getSpreadArgumentIndex(node.arguments);
                if (spreadIndex >= 0) {
                    error(
                        node.arguments[spreadIndex],
                        Diagnostics
                            .Spread_operator_in_new_expressions_is_only_available_when_targeting_ECMAScript_5_and_higher
                    );
                }
            }

            let expressionType = checkNonNullExpression(node.expression);
            if (expressionType === silentNeverType) {
                return silentNeverSignature;
            }

            // If expressionType's apparent type(section 3.8.1) is an object type with one or
            // more construct signatures, the expression is processed in the same manner as a
            // function call, but using the construct signatures as the initial set of candidate
            // signatures for overload resolution. The result type of the function call becomes
            // the result type of the operation.
            expressionType = getApparentType(expressionType);
            if (expressionType === errorType) {
                // Another error has already been reported
                return resolveErrorCall(node);
            }

            // TS 1.0 spec: 4.11
            // If expressionType is of type Any, Args can be any argument
            // list and the result of the operation is of type Any.
            if (isTypeAny(expressionType)) {
                if (node.typeArguments) {
                    error(
                        node,
                        Diagnostics
                            .Untyped_function_calls_may_not_accept_type_arguments
                    );
                }
                return resolveUntypedCall(node);
            }

            // Technically, this signatures list may be incomplete. We are taking the apparent type,
            // but we are not including construct signatures that may have been added to the Object or
            // Function interface, since they have none by default. This is a bit of a leap of faith
            // that the user will not add any.
            const constructSignatures = getSignaturesOfType(
                expressionType,
                SignatureKind.Construct
            );
            if (constructSignatures.length) {
                if (!isConstructorAccessible(node, constructSignatures[0])) {
                    return resolveErrorCall(node);
                }
                // If the expression is a class of abstract type, then it cannot be instantiated.
                // Note, only class declarations can be declared abstract.
                // In the case of a merged class-module or class-interface declaration,
                // only the class declaration node will have the Abstract flag set.
                const valueDecl = expressionType.symbol
                    && getClassLikeDeclarationOfSymbol(expressionType.symbol);
                if (valueDecl
                    && hasModifier(valueDecl, ModifierFlags.Abstract))
                {
                    error(
                        node,
                        Diagnostics
                            .Cannot_create_an_instance_of_an_abstract_class
                    );
                    return resolveErrorCall(node);
                }

                return resolveCall(
                    node,
                    constructSignatures,
                    candidatesOutArray,
                    checkMode,
                    SignatureFlags.None
                );
            }

            // If expressionType's apparent type is an object type with no construct signatures but
            // one or more call signatures, the expression is processed as a function call. A compile-time
            // error occurs if the result of the function call is not Void. The type of the result of the
            // operation is Any. It is an error to have a Void this type.
            const callSignatures = getSignaturesOfType(
                expressionType,
                SignatureKind.Call
            );
            if (callSignatures.length) {
                const signature = resolveCall(
                    node,
                    callSignatures,
                    candidatesOutArray,
                    checkMode,
                    SignatureFlags.None
                );
                if (!noImplicitAny) {
                    if (signature.declaration
                        && !isJSConstructor(signature.declaration)
                        && getReturnTypeOfSignature(signature) !== voidType)
                    {
                        error(
                            node,
                            Diagnostics
                                .Only_a_void_function_can_be_called_with_the_new_keyword
                        );
                    }
                    if (getThisTypeOfSignature(signature) === voidType) {
                        error(
                            node,
                            Diagnostics
                                .A_function_that_is_called_with_the_new_keyword_cannot_have_a_this_type_that_is_void
                        );
                    }
                }
                return signature;
            }

            invocationError(
                node.expression,
                expressionType,
                SignatureKind.Construct
            );
            return resolveErrorCall(node);
        }

        function typeHasProtectedAccessibleBase(
            target: Symbol,
            type: InterfaceType
        ): boolean {
            const baseTypes = getBaseTypes(type);
            if (!length(baseTypes)) {
                return false;
            }
            const firstBase = baseTypes[0];
            if (firstBase.flags & TypeFlags.Intersection) {
                const types = (firstBase as IntersectionType).types;
                const mixinFlags = findMixins(types);
                let i = 0;
                for (const intersectionMember
                    of (firstBase as IntersectionType).types)
                {
                    // We want to ignore mixin ctors
                    if (!mixinFlags[i]) {
                        if (getObjectFlags(intersectionMember)
                            & (ObjectFlags.Class | ObjectFlags.Interface))
                        {
                            if (intersectionMember.symbol === target) {
                                return true;
                            }
                            if (typeHasProtectedAccessibleBase(
                                target,
                                intersectionMember as InterfaceType
                            )) {
                                return true;
                            }
                        }
                    }
                    i++;
                }
                return false;
            }
            if (firstBase.symbol === target) {
                return true;
            }
            return typeHasProtectedAccessibleBase(
                target,
                firstBase as InterfaceType
            );
        }

        function isConstructorAccessible(
            node: NewExpression,
            signature: Signature
        ) {
            if (!signature || !signature.declaration) {
                return true;
            }

            const declaration = signature.declaration;
            const modifiers = getSelectedModifierFlags(
                declaration,
                ModifierFlags.NonPublicAccessibilityModifier
            );

            // (1) Public constructors and (2) constructor functions are always accessible.
            if (!modifiers || declaration.kind !== SyntaxKind.Constructor) {
                return true;
            }

            const declaringClassDeclaration = getClassLikeDeclarationOfSymbol(
                declaration.parent.symbol
            )!;
            const declaringClass = <InterfaceType> getDeclaredTypeOfSymbol(
                declaration.parent.symbol
            );

            // A private or protected constructor can only be instantiated within its own class (or a subclass, for protected)
            if (!isNodeWithinClass(node, declaringClassDeclaration)) {
                const containingClass = getContainingClass(node);
                if (containingClass && modifiers & ModifierFlags.Protected) {
                    const containingType = getTypeOfNode(containingClass);
                    if (typeHasProtectedAccessibleBase(
                        declaration.parent.symbol,
                        containingType as InterfaceType
                    )) {
                        return true;
                    }
                }
                if (modifiers & ModifierFlags.Private) {
                    error(
                        node,
                        Diagnostics
                            .Constructor_of_class_0_is_private_and_only_accessible_within_the_class_declaration,
                        typeToString(declaringClass)
                    );
                }
                if (modifiers & ModifierFlags.Protected) {
                    error(
                        node,
                        Diagnostics
                            .Constructor_of_class_0_is_protected_and_only_accessible_within_the_class_declaration,
                        typeToString(declaringClass)
                    );
                }
                return false;
            }

            return true;
        }

        function invocationErrorDetails(
            apparentType: Type,
            kind: SignatureKind
        ): { messageChain: DiagnosticMessageChain;
            relatedMessage: DiagnosticMessage | undefined; }
        {
            let errorInfo: DiagnosticMessageChain | undefined;
            const isCall = kind === SignatureKind.Call;
            const awaitedType = getAwaitedType(apparentType);
            const maybeMissingAwait = awaitedType
                && getSignaturesOfType(awaitedType, kind).length > 0;
            if (apparentType.flags & TypeFlags.Union) {
                const types = (apparentType as UnionType).types;
                let hasSignatures = false;
                for (const constituent of types) {
                    const signatures = getSignaturesOfType(constituent, kind);
                    if (signatures.length !== 0) {
                        hasSignatures = true;
                        if (errorInfo) {
                            // Bail early if we already have an error, no chance of "No constituent of type is callable"
                            break;
                        }
                    } else {
                        // Error on the first non callable constituent only
                        if (!errorInfo) {
                            errorInfo = chainDiagnosticMessages(
                                errorInfo,
                                isCall
                                    ? Diagnostics.Type_0_has_no_call_signatures
                                    : Diagnostics
                                        .Type_0_has_no_construct_signatures,
                                typeToString(constituent)
                            );
                            errorInfo = chainDiagnosticMessages(
                                errorInfo,
                                isCall
                                    ? Diagnostics
                                        .Not_all_constituents_of_type_0_are_callable
                                    : Diagnostics
                                        .Not_all_constituents_of_type_0_are_constructable,
                                typeToString(apparentType)
                            );
                        }
                        if (hasSignatures) {
                            // Bail early if we already found a siganture, no chance of "No constituent of type is callable"
                            break;
                        }
                    }
                }
                if (!hasSignatures) {
                    errorInfo = chainDiagnosticMessages(
                        /* detials */ undefined,
                        isCall
                            ? Diagnostics.No_constituent_of_type_0_is_callable
                            : Diagnostics
                                .No_constituent_of_type_0_is_constructable,
                        typeToString(apparentType)
                    );
                }
                if (!errorInfo) {
                    errorInfo = chainDiagnosticMessages(
                        errorInfo,
                        isCall
                            ? Diagnostics
                                .Each_member_of_the_union_type_0_has_signatures_but_none_of_those_signatures_are_compatible_with_each_other
                            : Diagnostics
                                .Each_member_of_the_union_type_0_has_construct_signatures_but_none_of_those_signatures_are_compatible_with_each_other,
                        typeToString(apparentType)
                    );
                }
            } else {
                errorInfo = chainDiagnosticMessages(
                    errorInfo,
                    isCall
                        ? Diagnostics.Type_0_has_no_call_signatures
                        : Diagnostics.Type_0_has_no_construct_signatures,
                    typeToString(apparentType)
                );
            }
            return {
                messageChain: chainDiagnosticMessages(
                    errorInfo,
                    isCall
                        ? Diagnostics.This_expression_is_not_callable
                        : Diagnostics.This_expression_is_not_constructable
                ),
                relatedMessage: maybeMissingAwait
                    ? Diagnostics.Did_you_forget_to_use_await
                    : undefined
            };
        }
        function invocationError(
            errorTarget: Node,
            apparentType: Type,
            kind: SignatureKind,
            relatedInformation?: DiagnosticRelatedInformation
        ) {
            const { messageChain,
                relatedMessage: relatedInfo } = invocationErrorDetails(
                    apparentType,
                    kind
                );
            const diagnostic = createDiagnosticForNodeFromMessageChain(
                errorTarget,
                messageChain
            );
            if (relatedInfo) {
                addRelatedInfo(
                    diagnostic,
                    createDiagnosticForNode(errorTarget, relatedInfo)
                );
            }
            if (isCallExpression(errorTarget.parent)) {
                const { start,
                    length } = getDiagnosticSpanForCallNode(
                        errorTarget.parent, /* doNotIncludeArguments */
                        true
                    );
                diagnostic.start = start;
                diagnostic.length = length;
            }
            diagnostics.add(diagnostic);
            invocationErrorRecovery(
                apparentType,
                kind,
                relatedInformation
                    ? addRelatedInfo(diagnostic, relatedInformation)
                    : diagnostic
            );
        }

        function invocationErrorRecovery(
            apparentType: Type,
            kind: SignatureKind,
            diagnostic: Diagnostic
        ) {
            if (!apparentType.symbol) {
                return;
            }
            const importNode = getSymbolLinks(apparentType.symbol)
                .originatingImport;
            // Create a diagnostic on the originating import if possible onto which we can attach a quickfix
            //  An import call expression cannot be rewritten into another form to correct the error - the only solution is to use `.default` at the use-site
            if (importNode && !isImportCall(importNode)) {
                const sigs = getSignaturesOfType(
                    getTypeOfSymbol(
                        getSymbolLinks(
                            apparentType.symbol
                        ).target!
                    ),
                    kind
                );
                if (!sigs || !sigs.length) return;

                addRelatedInfo(
                    diagnostic,
                    createDiagnosticForNode(
                        importNode,
                        Diagnostics
                            .Type_originates_at_this_import_A_namespace_style_import_cannot_be_called_or_constructed_and_will_cause_a_failure_at_runtime_Consider_using_a_default_import_or_import_require_here_instead
                    )
                );
            }
        }

        function resolveTaggedTemplateExpression(
            node: TaggedTemplateExpression,
            candidatesOutArray: Signature[] | undefined,
            checkMode: CheckMode
        ): Signature {
            const tagType = checkExpression(node.tag);
            const apparentType = getApparentType(tagType);

            if (apparentType === errorType) {
                // Another error has already been reported
                return resolveErrorCall(node);
            }

            const callSignatures = getSignaturesOfType(
                apparentType,
                SignatureKind.Call
            );
            const numConstructSignatures = getSignaturesOfType(
                apparentType,
                SignatureKind.Construct
            ).length;

            if (isUntypedFunctionCall(
                tagType,
                apparentType,
                callSignatures.length,
                numConstructSignatures
            )) {
                return resolveUntypedCall(node);
            }

            if (!callSignatures.length) {
                invocationError(node.tag, apparentType, SignatureKind.Call);
                return resolveErrorCall(node);
            }

            return resolveCall(
                node,
                callSignatures,
                candidatesOutArray,
                checkMode,
                SignatureFlags.None
            );
        }

        /**
         * Gets the localized diagnostic head message to use for errors when resolving a decorator as a call expression.
         */
        function getDiagnosticHeadMessageForDecoratorResolution(
            node: Decorator
        ) {
            switch (node.parent.kind) {
                case SyntaxKind.ClassDeclaration:
                case SyntaxKind.ClassExpression:
                    return Diagnostics
                        .Unable_to_resolve_signature_of_class_decorator_when_called_as_an_expression;
                case SyntaxKind.Parameter:
                    return Diagnostics
                        .Unable_to_resolve_signature_of_parameter_decorator_when_called_as_an_expression;
                case SyntaxKind.PropertyDeclaration:
                    return Diagnostics
                        .Unable_to_resolve_signature_of_property_decorator_when_called_as_an_expression;
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.GetAccessor:
                case SyntaxKind.SetAccessor:
                    return Diagnostics
                        .Unable_to_resolve_signature_of_method_decorator_when_called_as_an_expression;
                default:
                    return Debug.fail();
            }
        }

        /**
         * Resolves a decorator as if it were a call expression.
         */
        function resolveDecorator(
            node: Decorator,
            candidatesOutArray: Signature[] | undefined,
            checkMode: CheckMode
        ): Signature {
            const funcType = checkExpression(node.expression);
            const apparentType = getApparentType(funcType);
            if (apparentType === errorType) {
                return resolveErrorCall(node);
            }

            const callSignatures = getSignaturesOfType(
                apparentType,
                SignatureKind.Call
            );
            const numConstructSignatures = getSignaturesOfType(
                apparentType,
                SignatureKind.Construct
            ).length;
            if (isUntypedFunctionCall(
                funcType,
                apparentType,
                callSignatures.length,
                numConstructSignatures
            )) {
                return resolveUntypedCall(node);
            }

            if (isPotentiallyUncalledDecorator(node, callSignatures)) {
                const nodeStr = getTextOfNode(
                    node.expression, /*includeTrivia*/
                    false
                );
                error(
                    node,
                    Diagnostics
                        ._0_accepts_too_few_arguments_to_be_used_as_a_decorator_here_Did_you_mean_to_call_it_first_and_write_0,
                    nodeStr
                );
                return resolveErrorCall(node);
            }

            const headMessage = getDiagnosticHeadMessageForDecoratorResolution(node);
            if (!callSignatures.length) {
                const errorDetails = invocationErrorDetails(
                    apparentType,
                    SignatureKind.Call
                );
                const messageChain = chainDiagnosticMessages(
                    errorDetails.messageChain,
                    headMessage
                );
                const diag = createDiagnosticForNodeFromMessageChain(
                    node.expression,
                    messageChain
                );
                if (errorDetails.relatedMessage) {
                    addRelatedInfo(
                        diag,
                        createDiagnosticForNode(
                            node.expression,
                            errorDetails.relatedMessage
                        )
                    );
                }
                diagnostics.add(diag);
                invocationErrorRecovery(apparentType, SignatureKind.Call,
                    diag);
                return resolveErrorCall(node);
            }

            return resolveCall(
                node,
                callSignatures,
                candidatesOutArray,
                checkMode,
                SignatureFlags.None,
                headMessage
            );
        }

        function createSignatureForJSXIntrinsic(
            node: JsxOpeningLikeElement,
            result: Type
        ): Signature {
            const namespace = getJsxNamespaceAt(node);
            const exports = namespace && getExportsOfSymbol(namespace);
            // We fake up a SFC signature for each intrinsic, however a more specific per-element signature drawn from the JSX declaration
            // file would probably be preferable.
            const typeSymbol = exports
                && getSymbol(exports, JsxNames.Element, SymbolFlags.Type);
            const returnNode = typeSymbol
                && nodeBuilder.symbolToEntityName(
                    typeSymbol,
                    SymbolFlags.Type,
                    node
                );
            const declaration = createFunctionTypeNode(
                /*typeParameters*/ undefined,
                [createParameter(
                    /*decorators*/ undefined, /*modifiers*/
                    undefined, /*dotdotdot*/
                    undefined,
                    'props', /*questionMark*/
                    undefined,
                    nodeBuilder.typeToTypeNode(result, node)
                )],
                returnNode
                    ? createTypeReferenceNode(
                        returnNode, /*typeArguments*/
                        undefined
                    )
                    : createKeywordTypeNode(SyntaxKind.AnyKeyword)
            );
            const parameterSymbol = createSymbol(
                SymbolFlags.FunctionScopedVariable,
                'props' as __String
            );
            parameterSymbol.type = result;
            return createSignature(
                declaration,
                /*typeParameters*/ undefined,
                /*thisParameter*/ undefined,
                [parameterSymbol],
                typeSymbol ? getDeclaredTypeOfSymbol(typeSymbol) : errorType,
                /*returnTypePredicate*/ undefined,
                1,
                SignatureFlags.None
            );
        }

        function resolveJsxOpeningLikeElement(
            node: JsxOpeningLikeElement,
            candidatesOutArray: Signature[] | undefined,
            checkMode: CheckMode
        ): Signature {
            if (isJsxIntrinsicIdentifier(node.tagName)) {
                const result = getIntrinsicAttributesTypeFromJsxOpeningLikeElement(node);
                const fakeSignature = createSignatureForJSXIntrinsic(
                    node,
                    result
                );
                checkTypeAssignableToAndOptionallyElaborate(
                    checkExpressionWithContextualType(
                        node.attributes,
                        getEffectiveFirstArgumentForJsxSignature(
                            fakeSignature,
                            node
                        ), /*mapper*/
                        undefined,
                        CheckMode.Normal
                    ),
                    result,
                    node.tagName,
                    node.attributes
                );
                return fakeSignature;
            }
            const exprTypes = checkExpression(node.tagName);
            const apparentType = getApparentType(exprTypes);
            if (apparentType === errorType) {
                return resolveErrorCall(node);
            }

            const signatures = getUninstantiatedJsxSignaturesOfType(
                exprTypes,
                node
            );
            if (isUntypedFunctionCall(
                exprTypes,
                apparentType,
                signatures.length, /*constructSignatures*/
                0
            )) {
                return resolveUntypedCall(node);
            }

            if (signatures.length === 0) {
                // We found no signatures at all, which is an error
                error(
                    node.tagName,
                    Diagnostics
                        .JSX_element_type_0_does_not_have_any_construct_or_call_signatures,
                    getTextOfNode(node.tagName)
                );
                return resolveErrorCall(node);
            }

            return resolveCall(
                node,
                signatures,
                candidatesOutArray,
                checkMode,
                SignatureFlags.None
            );
        }

        /**
         * Sometimes, we have a decorator that could accept zero arguments,
         * but is receiving too many arguments as part of the decorator invocation.
         * In those cases, a user may have meant to *call* the expression before using it as a decorator.
         */
        function isPotentiallyUncalledDecorator(
            decorator: Decorator,
            signatures: readonly Signature[]
        ) {
            return signatures.length
                && every(
                    signatures,
                    signature => signature.minArgumentCount === 0
                        && !signatureHasRestParameter(signature)
                        && signature.parameters.length
                        < getDecoratorArgumentCount(decorator, signature)
                );
        }

        function resolveSignature(
            node: CallLikeExpression,
            candidatesOutArray: Signature[] | undefined,
            checkMode: CheckMode
        ): Signature {
            switch (node.kind) {
                case SyntaxKind.CallExpression:
                    return resolveCallExpression(
                        node,
                        candidatesOutArray,
                        checkMode
                    );
                case SyntaxKind.NewExpression:
                    return resolveNewExpression(
                        node,
                        candidatesOutArray,
                        checkMode
                    );
                case SyntaxKind.TaggedTemplateExpression:
                    return resolveTaggedTemplateExpression(
                        node,
                        candidatesOutArray,
                        checkMode
                    );
                case SyntaxKind.Decorator:
                    return resolveDecorator(
                        node,
                        candidatesOutArray,
                        checkMode
                    );
                case SyntaxKind.JsxOpeningElement:
                case SyntaxKind.JsxSelfClosingElement:
                    return resolveJsxOpeningLikeElement(
                        node,
                        candidatesOutArray,
                        checkMode
                    );
            }
            throw Debug.assertNever(
                node,
                'Branch in \'resolveSignature\' should be unreachable.'
            );
        }

        /**
         * Resolve a signature of a given call-like expression.
         * @param node a call-like expression to try resolve a signature for
         * @param candidatesOutArray an array of signature to be filled in by the function. It is passed by signature help in the language service;
         *                           the function will fill it up with appropriate candidate signatures
         * @return a signature of the call-like expression or undefined if one can't be found
         */
        function getResolvedSignature(
            node: CallLikeExpression,
            candidatesOutArray?: Signature[] | undefined,
            checkMode?: CheckMode
        ): Signature {
            const links = getNodeLinks(node);
            // If getResolvedSignature has already been called, we will have cached the resolvedSignature.
            // However, it is possible that either candidatesOutArray was not passed in the first time,
            // or that a different candidatesOutArray was passed in. Therefore, we need to redo the work
            // to correctly fill the candidatesOutArray.
            const cached = links.resolvedSignature;
            if (cached && cached !== resolvingSignature
                && !candidatesOutArray)
            {
                return cached;
            }
            links.resolvedSignature = resolvingSignature;
            const result = resolveSignature(
                node,
                candidatesOutArray,
                checkMode || CheckMode.Normal
            );
            // When CheckMode.SkipGenericFunctions is set we use resolvingSignature to indicate that call
            // resolution should be deferred.
            if (result !== resolvingSignature) {
                // If signature resolution originated in control flow type analysis (for example to compute the
                // assigned type in a flow assignment) we don't cache the result as it may be based on temporary
                // types from the control flow analysis.
                links.resolvedSignature = flowLoopStart === flowLoopCount
                    ? result
                    : cached;
            }
            return result;
        }

        /**
         * Indicates whether a declaration can be treated as a constructor in a JavaScript
         * file.
         */
        function isJSConstructor(
            node: Node | undefined
        ): node is FunctionDeclaration | FunctionExpression {
            if (!node || !isInJSFile(node)) {
                return false;
            }
            const func = isFunctionDeclaration(node)
                || isFunctionExpression(node)
                ? node
                : isVariableDeclaration(node) && node.initializer
                    && isFunctionExpression(node.initializer)
                    ? node.initializer
                    : undefined;
            if (func) {
                // If the node has a @class tag, treat it like a constructor.
                if (getJSDocClassTag(node)) return true;

                // If the symbol of the node has members, treat it like a constructor.
                const symbol = getSymbolOfNode(func);
                return !!symbol && hasEntries(symbol.members);
            }
            return false;
        }

        function mergeJSSymbols(target: Symbol, source: Symbol | undefined) {
            if (source) {
                const links = getSymbolLinks(source);
                if (!links.inferredClassSymbol
                    || !links.inferredClassSymbol
                        .has('' + getSymbolId(target)))
                {
                    const inferred = isTransientSymbol(target)
                        ? target
                        : cloneSymbol(target) as TransientSymbol;
                    inferred.exports = inferred.exports || createSymbolTable();
                    inferred.members = inferred.members || createSymbolTable();
                    inferred.flags |= source.flags & SymbolFlags.Class;
                    if (hasEntries(source.exports)) {
                        mergeSymbolTable(inferred.exports, source.exports);
                    }
                    if (hasEntries(source.members)) {
                        mergeSymbolTable(inferred.members, source.members);
                    }
                    (links.inferredClassSymbol
                        || (links
                            .inferredClassSymbol = createMap<TransientSymbol>()))
                        .set('' + getSymbolId(inferred), inferred);
                    return inferred;
                }
                return links.inferredClassSymbol.get('' + getSymbolId(target));
            }
        }

        function getAssignedClassSymbol(decl: Declaration): Symbol
            | undefined
        {
            const assignmentSymbol = decl && decl.parent
                && (isFunctionDeclaration(decl) && getSymbolOfNode(decl)
                    || isBinaryExpression(decl.parent)
                    && getSymbolOfNode(decl.parent.left)
                    || isVariableDeclaration(decl.parent)
                    && getSymbolOfNode(decl.parent));
            const prototype = assignmentSymbol && assignmentSymbol.exports
                && assignmentSymbol.exports.get('prototype' as __String);
            const init = prototype && prototype.valueDeclaration
                && getAssignedJSPrototype(prototype.valueDeclaration);
            return init ? getSymbolOfNode(init) : undefined;
        }

        function getAssignedJSPrototype(node: Node) {
            if (!node.parent) {
                return false;
            }
            let parent: Node = node.parent;
            while (parent
                && parent.kind === SyntaxKind.PropertyAccessExpression)
            {
                parent = parent.parent;
            }
            if (parent && isBinaryExpression(parent)
                && isPrototypeAccess(parent.left)
                && parent.operatorToken.kind === SyntaxKind.EqualsToken)
            {
                const right = getInitializerOfBinaryExpression(parent);
                return isObjectLiteralExpression(right) && right;
            }
        }

        /**
         * Syntactically and semantically checks a call or new expression.
         * @param node The call/new expression to be checked.
         * @returns On success, the expression's signature's return type. On failure, anyType.
         */
        function checkCallExpression(
            node: CallExpression | NewExpression,
            checkMode?: CheckMode
        ): Type {
            if (!checkGrammarTypeArguments(node,
                node.typeArguments))
                checkGrammarArguments(node.arguments);

            const signature = getResolvedSignature(
                node, /*candidatesOutArray*/
                undefined,
                checkMode
            );
            if (signature === resolvingSignature) {
                // CheckMode.SkipGenericFunctions is enabled and this is a call to a generic function that
                // returns a function type. We defer checking and return nonInferrableType.
                return nonInferrableType;
            }

            if (node.expression.kind === SyntaxKind.SuperKeyword) {
                return voidType;
            }

            if (node.kind === SyntaxKind.NewExpression) {
                const declaration = signature.declaration;

                if (declaration
                    && declaration.kind !== SyntaxKind.Constructor
                    && declaration.kind !== SyntaxKind.ConstructSignature
                    && declaration.kind !== SyntaxKind.ConstructorType
                    && !isJSDocConstructSignature(declaration)
                    && !isJSConstructor(declaration))
                {
                    // When resolved signature is a call signature (and not a construct signature) the result type is any
                    if (noImplicitAny) {
                        error(
                            node,
                            Diagnostics
                                .new_expression_whose_target_lacks_a_construct_signature_implicitly_has_an_any_type
                        );
                    }
                    return anyType;
                }
            }

            // In JavaScript files, calls to any identifier 'require' are treated as external module imports
            if (isInJSFile(node) && isCommonJsRequire(node)) {
                return resolveExternalModuleTypeByLiteral(
                    node.arguments![0] as StringLiteral
                );
            }

            const returnType = getReturnTypeOfSignature(signature);
            // Treat any call to the global 'Symbol' function that is part of a const variable or readonly property
            // as a fresh unique symbol literal type.
            if (returnType.flags & TypeFlags.ESSymbolLike
                && isSymbolOrSymbolForCall(node))
            {
                return getESSymbolLikeTypeForNode(
                    walkUpParenthesizedExpressions(
                        node.parent
                    )
                );
            }
            if (node.kind === SyntaxKind.CallExpression
                && node.parent.kind === SyntaxKind.ExpressionStatement
                && returnType.flags & TypeFlags.Void
                && getTypePredicateOfSignature(signature))
            {
                if (!isDottedName(node.expression)) {
                    error(
                        node.expression,
                        Diagnostics
                            .Assertions_require_the_call_target_to_be_an_identifier_or_qualified_name
                    );
                } else if (!getEffectsSignature(node)) {
                    const diagnostic = error(
                        node.expression,
                        Diagnostics
                            .Assertions_require_every_name_in_the_call_target_to_be_declared_with_an_explicit_type_annotation
                    );
                    getTypeOfDottedName(node.expression, diagnostic);
                }
            }

            if (isInJSFile(node)) {
                const decl = getDeclarationOfExpando(node);
                if (decl) {
                    const jsSymbol = getSymbolOfNode(decl);
                    if (jsSymbol && hasEntries(jsSymbol.exports)) {
                        const jsAssignmentType = createAnonymousType(
                            jsSymbol,
                            jsSymbol.exports,
                            emptyArray,
                            emptyArray,
                            undefined,
                            undefined
                        );
                        jsAssignmentType.objectFlags |= ObjectFlags.JSLiteral;
                        return getIntersectionType(
                            [returnType, jsAssignmentType]
                        );
                    }
                }
            }

            return returnType;
        }

        function isSymbolOrSymbolForCall(node: Node) {
            if (!isCallExpression(node)) return false;
            let left = node.expression;
            if (isPropertyAccessExpression(left)
                && left.name.escapedText === 'for')
            {
                left = left.expression;
            }
            if (!isIdentifier(left) || left.escapedText !== 'Symbol') {
                return false;
            }

            // make sure `Symbol` is the global symbol
            const globalESSymbol = getGlobalESSymbolConstructorSymbol(/*reportErrors*/ false);
            if (!globalESSymbol) {
                return false;
            }

            return globalESSymbol
                === resolveName(
                    left,
                    'Symbol' as __String,
                    SymbolFlags.Value, /*nameNotFoundMessage*/
                    undefined, /*nameArg*/
                    undefined, /*isUse*/
                    false
                );
        }

        function checkImportCallExpression(node: ImportCall): Type {
            // Check grammar of dynamic import
            if (!checkGrammarArguments(node
                .arguments))
                checkGrammarImportCallExpression(node);

            if (node.arguments.length === 0) {
                return createPromiseReturnType(node, anyType);
            }
            const specifier = node.arguments[0];
            const specifierType = checkExpressionCached(specifier);
            // Even though multiple arguments is grammatically incorrect, type-check extra arguments for completion
            for (let i = 1; i < node.arguments.length; ++i) {
                checkExpressionCached(node.arguments[i]);
            }

            if (specifierType.flags & TypeFlags.Undefined
                || specifierType.flags & TypeFlags.Null
                || !isTypeAssignableTo(specifierType, stringType))
            {
                error(
                    specifier,
                    Diagnostics
                        .Dynamic_import_s_specifier_must_be_of_type_string_but_here_has_type_0,
                    typeToString(specifierType)
                );
            }

            // resolveExternalModuleName will return undefined if the moduleReferenceExpression is not a string literal
            const moduleSymbol = resolveExternalModuleName(node, specifier);
            if (moduleSymbol) {
                const esModuleSymbol = resolveESModuleSymbol(
                    moduleSymbol,
                    specifier, /*dontRecursivelyResolve*/
                    true, /*suppressUsageError*/
                    false
                );
                if (esModuleSymbol) {
                    return createPromiseReturnType(
                        node,
                        getTypeWithSyntheticDefaultImportType(
                            getTypeOfSymbol(esModuleSymbol),
                            esModuleSymbol,
                            moduleSymbol
                        )
                    );
                }
            }
            return createPromiseReturnType(node, anyType);
        }

        function getTypeWithSyntheticDefaultImportType(
            type: Type,
            symbol: Symbol,
            originalSymbol: Symbol
        ): Type {
            if (allowSyntheticDefaultImports && type && type !== errorType) {
                const synthType = type as SyntheticDefaultModuleType;
                if (!synthType.syntheticType) {
                    const file = find(
                        originalSymbol.declarations,
                        isSourceFile
                    );
                    const hasSyntheticDefault = canHaveSyntheticDefault(
                        file,
                        originalSymbol, /*dontResolveAlias*/
                        false
                    );
                    if (hasSyntheticDefault) {
                        const memberTable = createSymbolTable();
                        const newSymbol = createSymbol(
                            SymbolFlags.Alias,
                            InternalSymbolName.Default
                        );
                        newSymbol.nameType = getLiteralType('default');
                        newSymbol.target = resolveSymbol(symbol);
                        memberTable.set(InternalSymbolName.Default, newSymbol);
                        const anonymousSymbol = createSymbol(
                            SymbolFlags.TypeLiteral,
                            InternalSymbolName.Type
                        );
                        const defaultContainingObject = createAnonymousType(
                            anonymousSymbol,
                            memberTable,
                            emptyArray,
                            emptyArray, /*stringIndexInfo*/
                            undefined, /*numberIndexInfo*/
                            undefined
                        );
                        anonymousSymbol.type = defaultContainingObject;
                        synthType.syntheticType = isValidSpreadType(type)
                            ? getSpreadType(
                                type,
                                defaultContainingObject,
                                anonymousSymbol, /*objectFlags*/
                                0, /*readonly*/
                                false
                            )
                            : defaultContainingObject;
                    } else {
                        synthType.syntheticType = type;
                    }
                }
                return synthType.syntheticType;
            }
            return type;
        }

        function isCommonJsRequire(node: Node): boolean {
            if (!isRequireCall(node, /*checkArgumentIsStringLiteralLike*/
                true))
            {
                return false;
            }

            // Make sure require is not a local function
            if (!isIdentifier(node.expression)) return Debug.fail();
            const resolvedRequire = resolveName(
                node.expression,
                node.expression.escapedText,
                SymbolFlags.Value, /*nameNotFoundMessage*/
                undefined, /*nameArg*/
                undefined, /*isUse*/
                true
            )!; // TODO: GH#18217
            if (resolvedRequire === requireSymbol) {
                return true;
            }
            // project includes symbol named 'require' - make sure that it is ambient and local non-alias
            if (resolvedRequire.flags & SymbolFlags.Alias) {
                return false;
            }

            const targetDeclarationKind = resolvedRequire.flags
                & SymbolFlags.Function
                ? SyntaxKind.FunctionDeclaration
                : resolvedRequire.flags & SymbolFlags.Variable
                    ? SyntaxKind.VariableDeclaration
                    : SyntaxKind.Unknown;
            if (targetDeclarationKind !== SyntaxKind.Unknown) {
                const decl = getDeclarationOfKind(
                    resolvedRequire,
                    targetDeclarationKind
                )!;
                // function/variable declaration should be ambient
                return !!decl && !!(decl.flags & NodeFlags.Ambient);
            }
            return false;
        }

        function checkTaggedTemplateExpression(
            node: TaggedTemplateExpression
        ): Type {
            if (!checkGrammarTaggedTemplateChain(node)) {
                checkGrammarTypeArguments(
                    node,
                    node.typeArguments
                );
            }
            if (languageVersion < ScriptTarget.ES2015) {
                checkExternalEmitHelpers(
                    node,
                    ExternalEmitHelpers.MakeTemplateObject
                );
            }
            return getReturnTypeOfSignature(getResolvedSignature(node));
        }

        function checkAssertion(node: AssertionExpression) {
            return checkAssertionWorker(node, node.type, node.expression);
        }

        function isValidConstAssertionArgument(node: Node): boolean {
            switch (node.kind) {
                case SyntaxKind.StringLiteral:
                case SyntaxKind.NoSubstitutionTemplateLiteral:
                case SyntaxKind.NumericLiteral:
                case SyntaxKind.BigIntLiteral:
                case SyntaxKind.TrueKeyword:
                case SyntaxKind.FalseKeyword:
                case SyntaxKind.ArrayLiteralExpression:
                case SyntaxKind.ObjectLiteralExpression:
                    return true;
                case SyntaxKind.ParenthesizedExpression:
                    return isValidConstAssertionArgument(
                        (<ParenthesizedExpression> node).expression
                    );
                case SyntaxKind.PrefixUnaryExpression:
                    const op = (<PrefixUnaryExpression> node).operator;
                    const arg = (<PrefixUnaryExpression> node).operand;
                    return op === SyntaxKind.MinusToken
                        && (arg.kind === SyntaxKind.NumericLiteral
                            || arg.kind === SyntaxKind.BigIntLiteral)
                        || op === SyntaxKind.PlusToken
                        && arg.kind === SyntaxKind.NumericLiteral;
                case SyntaxKind.PropertyAccessExpression:
                case SyntaxKind.ElementAccessExpression:
                    const expr = (<PropertyAccessExpression
                        | ElementAccessExpression> node).expression;
                    if (isIdentifier(expr)) {
                        let symbol = getSymbolAtLocation(expr);
                        if (symbol && symbol.flags & SymbolFlags.Alias) {
                            symbol = resolveAlias(symbol);
                        }
                        return !!(symbol && (symbol.flags & SymbolFlags.Enum)
                            && getEnumKind(symbol) === EnumKind.Literal);
                    }
            }
            return false;
        }

        function checkAssertionWorker(
            errNode: Node,
            type: TypeNode,
            expression: UnaryExpression | Expression,
            checkMode?: CheckMode
        ) {
            let exprType = checkExpression(expression, checkMode);
            if (isConstTypeReference(type)) {
                if (!isValidConstAssertionArgument(expression)) {
                    error(
                        expression,
                        Diagnostics
                            .A_const_assertions_can_only_be_applied_to_references_to_enum_members_or_string_number_boolean_array_or_object_literals
                    );
                }
                return getRegularTypeOfLiteralType(exprType);
            }
            checkSourceElement(type);
            exprType = getRegularTypeOfObjectLiteral(getBaseTypeOfLiteralType(exprType));
            const targetType = getTypeFromTypeNode(type);
            if (produceDiagnostics && targetType !== errorType) {
                const widenedType = getWidenedType(exprType);
                if (!isTypeComparableTo(targetType, widenedType)) {
                    checkTypeComparableTo(
                        exprType,
                        targetType,
                        errNode,
                        Diagnostics
                            .Conversion_of_type_0_to_type_1_may_be_a_mistake_because_neither_type_sufficiently_overlaps_with_the_other_If_this_was_intentional_convert_the_expression_to_unknown_first
                    );
                }
            }
            return targetType;
        }

        function checkNonNullAssertion(node: NonNullExpression) {
            return getNonNullableType(checkExpression(node.expression));
        }

        function checkMetaProperty(node: MetaProperty): Type {
            checkGrammarMetaProperty(node);

            if (node.keywordToken === SyntaxKind.NewKeyword) {
                return checkNewTargetMetaProperty(node);
            }

            if (node.keywordToken === SyntaxKind.ImportKeyword) {
                return checkImportMetaProperty(node);
            }

            return Debug.assertNever(node.keywordToken);
        }

        function checkNewTargetMetaProperty(node: MetaProperty) {
            const container = getNewTargetContainer(node);
            if (!container) {
                error(
                    node,
                    Diagnostics
                        .Meta_property_0_is_only_allowed_in_the_body_of_a_function_declaration_function_expression_or_constructor,
                    'new.target'
                );
                return errorType;
            } else if (container.kind === SyntaxKind.Constructor) {
                const symbol = getSymbolOfNode(
                    container.parent as ClassLikeDeclaration
                );
                return getTypeOfSymbol(symbol);
            } else {
                const symbol = getSymbolOfNode(container)!;
                return getTypeOfSymbol(symbol);
            }
        }

        function checkImportMetaProperty(node: MetaProperty) {
            if (moduleKind !== ModuleKind.ESNext
                && moduleKind !== ModuleKind.System)
            {
                error(
                    node,
                    Diagnostics
                        .The_import_meta_meta_property_is_only_allowed_when_the_module_option_is_esnext_or_system
                );
            }
            const file = getSourceFileOfNode(node);
            Debug.assert(
                !!(file.flags & NodeFlags.PossiblyContainsImportMeta),
                'Containing file is missing import meta node flag.'
            );
            Debug.assert(
                !!file.externalModuleIndicator,
                'Containing file should be a module.'
            );
            return node.name.escapedText === 'meta'
                ? getGlobalImportMetaType()
                : errorType;
        }

        function getTypeOfParameter(symbol: Symbol) {
            const type = getTypeOfSymbol(symbol);
            if (strictNullChecks) {
                const declaration = symbol.valueDeclaration;
                if (declaration && hasInitializer(declaration)) {
                    return getOptionalType(type);
                }
            }
            return type;
        }

        function getParameterNameAtPosition(signature: Signature,
            pos: number)
        {
            const paramCount = signature.parameters.length
                - (signatureHasRestParameter(signature) ? 1 : 0);
            if (pos < paramCount) {
                return signature.parameters[pos].escapedName;
            }
            const restParameter = signature.parameters[paramCount]
                || unknownSymbol;
            const restType = getTypeOfSymbol(restParameter);
            if (isTupleType(restType)) {
                const associatedNames = (<TupleType> (<TypeReference> restType)
                    .target).associatedNames;
                const index = pos - paramCount;
                return associatedNames && associatedNames[index]
                    || restParameter.escapedName + '_' + index as __String;
            }
            return restParameter.escapedName;
        }

        function getTypeAtPosition(signature: Signature, pos: number): Type {
            return tryGetTypeAtPosition(signature, pos) || anyType;
        }

        function tryGetTypeAtPosition(
            signature: Signature,
            pos: number
        ): Type | undefined {
            const paramCount = signature.parameters.length
                - (signatureHasRestParameter(signature) ? 1 : 0);
            if (pos < paramCount) {
                return getTypeOfParameter(signature.parameters[pos]);
            }
            if (signatureHasRestParameter(signature)) {
                // We want to return the value undefined for an out of bounds parameter position,
                // so we need to check bounds here before calling getIndexedAccessType (which
                // otherwise would return the type 'undefined').
                const restType = getTypeOfSymbol(
                    signature.parameters[paramCount]
                );
                const index = pos - paramCount;
                if (!isTupleType(restType) || restType.target.hasRestElement
                    || index < getTypeArguments(restType).length)
                {
                    return getIndexedAccessType(
                        restType,
                        getLiteralType(index)
                    );
                }
            }
            return undefined;
        }

        function getRestTypeAtPosition(source: Signature, pos: number): Type {
            const paramCount = getParameterCount(source);
            const restType = getEffectiveRestType(source);
            const nonRestCount = paramCount - (restType ? 1 : 0);
            if (restType && pos === nonRestCount) {
                return restType;
            }
            const types = [];
            const names = [];
            for (let i = pos; i < nonRestCount; i++) {
                types.push(getTypeAtPosition(source, i));
                names.push(getParameterNameAtPosition(source, i));
            }
            if (restType) {
                types.push(getIndexedAccessType(restType, numberType));
                names.push(getParameterNameAtPosition(source, nonRestCount));
            }
            const minArgumentCount = getMinArgumentCount(source);
            const minLength = minArgumentCount < pos
                ? 0
                : minArgumentCount - pos;
            return createTupleType(
                types,
                minLength,
                !!restType, /*readonly*/
                false,
                names
            );
        }

        function getParameterCount(signature: Signature) {
            const length = signature.parameters.length;
            if (signatureHasRestParameter(signature)) {
                const restType = getTypeOfSymbol(
                    signature.parameters[length - 1]
                );
                if (isTupleType(restType)) {
                    return length + getTypeArguments(restType).length - 1;
                }
            }
            return length;
        }

        function getMinArgumentCount(signature: Signature) {
            if (signatureHasRestParameter(signature)) {
                const restType = getTypeOfSymbol(
                    signature.parameters[signature.parameters.length - 1]
                );
                if (isTupleType(restType)) {
                    const minLength = restType.target.minLength;
                    if (minLength > 0) {
                        return signature.parameters.length - 1 + minLength;
                    }
                }
            }
            return signature.minArgumentCount;
        }

        function hasEffectiveRestParameter(signature: Signature) {
            if (signatureHasRestParameter(signature)) {
                const restType = getTypeOfSymbol(
                    signature.parameters[signature.parameters.length - 1]
                );
                return !isTupleType(restType)
                    || restType.target.hasRestElement;
            }
            return false;
        }

        function getEffectiveRestType(signature: Signature) {
            if (signatureHasRestParameter(signature)) {
                const restType = getTypeOfSymbol(
                    signature.parameters[signature.parameters.length - 1]
                );
                return isTupleType(restType)
                    ? getRestArrayTypeOfTupleType(restType)
                    : restType;
            }
            return undefined;
        }

        function getNonArrayRestType(signature: Signature) {
            const restType = getEffectiveRestType(signature);
            return restType && !isArrayType(restType) && !isTypeAny(restType)
                ? restType
                : undefined;
        }

        function getTypeOfFirstParameterOfSignature(signature: Signature) {
            return getTypeOfFirstParameterOfSignatureWithFallback(
                signature,
                neverType
            );
        }

        function getTypeOfFirstParameterOfSignatureWithFallback(
            signature: Signature,
            fallbackType: Type
        ) {
            return signature.parameters.length > 0
                ? getTypeAtPosition(signature, 0)
                : fallbackType;
        }

        function inferFromAnnotatedParameters(
            signature: Signature,
            context: Signature,
            inferenceContext: InferenceContext
        ) {
            const len = signature.parameters.length
                - (signatureHasRestParameter(signature) ? 1 : 0);
            for (let i = 0; i < len; i++) {
                const declaration = <ParameterDeclaration> signature.parameters
                    [i].valueDeclaration;
                if (declaration.type) {
                    const typeNode = getEffectiveTypeAnnotationNode(declaration);
                    if (typeNode) {
                        inferTypes(
                            inferenceContext.inferences,
                            getTypeFromTypeNode(typeNode),
                            getTypeAtPosition(context, i)
                        );
                    }
                }
            }
            const restType = getEffectiveRestType(context);
            if (restType && restType.flags & TypeFlags.TypeParameter) {
                // The contextual signature has a generic rest parameter. We first instantiate the contextual
                // signature (without fixing type parameters) and assign types to contextually typed parameters.
                const instantiatedContext = instantiateSignature(
                    context,
                    inferenceContext.nonFixingMapper
                );
                assignContextualParameterTypes(signature, instantiatedContext);
                // We then infer from a tuple type representing the parameters that correspond to the contextual
                // rest parameter.
                const restPos = getParameterCount(context) - 1;
                inferTypes(
                    inferenceContext.inferences,
                    getRestTypeAtPosition(signature, restPos),
                    restType
                );
            }
        }

        function assignContextualParameterTypes(
            signature: Signature,
            context: Signature
        ) {
            signature.typeParameters = context.typeParameters;
            if (context.thisParameter) {
                const parameter = signature.thisParameter;
                if (!parameter || parameter.valueDeclaration
                    && !(<ParameterDeclaration> parameter.valueDeclaration)
                        .type)
                {
                    if (!parameter) {
                        signature
                            .thisParameter = createSymbolWithType(
                                context.thisParameter, /*type*/
                                undefined
                            );
                    }
                    assignTypeToParameterAndFixTypeParameters(
                        signature.thisParameter!,
                        getTypeOfSymbol(context.thisParameter)
                    );
                }
            }
            const len = signature.parameters.length
                - (signatureHasRestParameter(signature) ? 1 : 0);
            for (let i = 0; i < len; i++) {
                const parameter = signature.parameters[i];
                if (!getEffectiveTypeAnnotationNode(
                    <ParameterDeclaration> parameter.valueDeclaration
                )) {
                    const contextualParameterType = getTypeAtPosition(
                        context,
                        i
                    );
                    assignTypeToParameterAndFixTypeParameters(
                        parameter,
                        contextualParameterType
                    );
                }
            }
            if (signatureHasRestParameter(signature)) {
                // parameter might be a transient symbol generated by use of `arguments` in the function body.
                const parameter = last(signature.parameters);
                if (isTransientSymbol(parameter)
                    || !getEffectiveTypeAnnotationNode(
                        <ParameterDeclaration> parameter.valueDeclaration
                    ))
                {
                    const contextualParameterType = getRestTypeAtPosition(
                        context,
                        len
                    );
                    assignTypeToParameterAndFixTypeParameters(
                        parameter,
                        contextualParameterType
                    );
                }
            }
        }

        // When contextual typing assigns a type to a parameter that contains a binding pattern, we also need to push
        // the destructured type into the contained binding elements.
        function assignBindingElementTypes(pattern: BindingPattern) {
            for (const element of pattern.elements) {
                if (!isOmittedExpression(element)) {
                    if (element.name.kind === SyntaxKind.Identifier) {
                        getSymbolLinks(getSymbolOfNode(element))
                            .type = getTypeForBindingElement(element);
                    } else {
                        assignBindingElementTypes(element.name);
                    }
                }
            }
        }

        function assignTypeToParameterAndFixTypeParameters(
            parameter: Symbol,
            contextualType: Type
        ) {
            const links = getSymbolLinks(parameter);
            if (!links.type) {
                links.type = contextualType;
                const decl = parameter
                    .valueDeclaration as ParameterDeclaration;
                if (decl.name.kind !== SyntaxKind.Identifier) {
                    // if inference didn't come up with anything but unknown, fall back to the binding pattern if present.
                    if (links.type === unknownType) {
                        links.type = getTypeFromBindingPattern(decl.name);
                    }
                    assignBindingElementTypes(decl.name);
                }
            }
        }

        function createPromiseType(promisedType: Type): Type {
            // creates a `Promise<T>` type where `T` is the promisedType argument
            const globalPromiseType = getGlobalPromiseType(/*reportErrors*/ true);
            if (globalPromiseType !== emptyGenericType) {
                // if the promised type is itself a promise, get the underlying type; otherwise, fallback to the promised type
                promisedType = getAwaitedType(promisedType) || unknownType;
                return createTypeReference(globalPromiseType, [promisedType]);
            }

            return unknownType;
        }

        function createPromiseLikeType(promisedType: Type): Type {
            // creates a `PromiseLike<T>` type where `T` is the promisedType argument
            const globalPromiseLikeType = getGlobalPromiseLikeType(/*reportErrors*/ true);
            if (globalPromiseLikeType !== emptyGenericType) {
                // if the promised type is itself a promise, get the underlying type; otherwise, fallback to the promised type
                promisedType = getAwaitedType(promisedType) || unknownType;
                return createTypeReference(
                    globalPromiseLikeType,
                    [promisedType]
                );
            }

            return unknownType;
        }

        function createPromiseReturnType(
            func: FunctionLikeDeclaration | ImportCall,
            promisedType: Type
        ) {
            const promiseType = createPromiseType(promisedType);
            if (promiseType === unknownType) {
                error(
                    func,
                    isImportCall(func)
                        ? Diagnostics
                            .A_dynamic_import_call_returns_a_Promise_Make_sure_you_have_a_declaration_for_Promise_or_include_ES2015_in_your_lib_option
                        : Diagnostics
                            .An_async_function_or_method_must_return_a_Promise_Make_sure_you_have_a_declaration_for_Promise_or_include_ES2015_in_your_lib_option
                );
                return errorType;
            } else if (!getGlobalPromiseConstructorSymbol(/*reportErrors*/ true)) {
                error(
                    func,
                    isImportCall(func)
                        ? Diagnostics
                            .A_dynamic_import_call_in_ES5_SlashES3_requires_the_Promise_constructor_Make_sure_you_have_a_declaration_for_the_Promise_constructor_or_include_ES2015_in_your_lib_option
                        : Diagnostics
                            .An_async_function_or_method_in_ES5_SlashES3_requires_the_Promise_constructor_Make_sure_you_have_a_declaration_for_the_Promise_constructor_or_include_ES2015_in_your_lib_option
                );
            }

            return promiseType;
        }

        function getReturnTypeFromBody(
            func: FunctionLikeDeclaration,
            checkMode?: CheckMode
        ): Type {
            if (!func.body) {
                return errorType;
            }

            const functionFlags = getFunctionFlags(func);
            const isAsync = (functionFlags & FunctionFlags.Async) !== 0;
            const isGenerator = (functionFlags & FunctionFlags.Generator)
                !== 0;

            let returnType: Type | undefined;
            let yieldType: Type | undefined;
            let nextType: Type | undefined;
            let fallbackReturnType: Type = voidType;
            if (func.body.kind
                !== SyntaxKind.Block)
            { // Async or normal arrow function
                returnType = checkExpressionCached(
                    func.body,
                    checkMode && checkMode & ~CheckMode.SkipGenericFunctions
                );
                if (isAsync) {
                    // From within an async function you can return either a non-promise value or a promise. Any
                    // Promise/A+ compatible implementation will always assimilate any foreign promise, so the
                    // return type of the body should be unwrapped to its awaited type, which we will wrap in
                    // the native Promise<T> type later in this function.
                    returnType = checkAwaitedType(
                        returnType, /*errorNode*/
                        func,
                        Diagnostics
                            .The_return_type_of_an_async_function_must_either_be_a_valid_promise_or_must_not_contain_a_callable_then_member
                    );
                }
            } else if (isGenerator) { // Generator or AsyncGenerator function
                const returnTypes = checkAndAggregateReturnExpressionTypes(
                    func,
                    checkMode
                );
                if (!returnTypes) {
                    fallbackReturnType = neverType;
                } else if (returnTypes.length > 0) {
                    returnType = getUnionType(
                        returnTypes,
                        UnionReduction.Subtype
                    );
                }
                const { yieldTypes,
                    nextTypes } = checkAndAggregateYieldOperandTypes(
                        func,
                        checkMode
                    );
                yieldType = some(yieldTypes)
                    ? getUnionType(yieldTypes, UnionReduction.Subtype)
                    : undefined;
                nextType = some(nextTypes)
                    ? getIntersectionType(nextTypes)
                    : undefined;
            } else { // Async or normal function
                const types = checkAndAggregateReturnExpressionTypes(
                    func,
                    checkMode
                );
                if (!types) {
                    // For an async function, the return type will not be never, but rather a Promise for never.
                    return functionFlags & FunctionFlags.Async
                        ? createPromiseReturnType(
                            func,
                            neverType
                        ) // Async function
                        : neverType; // Normal function
                }
                if (types.length === 0) {
                    // For an async function, the return type will not be void, but rather a Promise for void.
                    return functionFlags & FunctionFlags.Async
                        ? createPromiseReturnType(
                            func,
                            voidType
                        ) // Async function
                        : voidType; // Normal function
                }

                // Return a union of the return expression types.
                returnType = getUnionType(types, UnionReduction.Subtype);
            }

            if (returnType || yieldType || nextType) {
                const contextualSignature = getContextualSignatureForFunctionLikeDeclaration(func);
                if (!contextualSignature) {
                    if (yieldType) {
                        reportErrorsFromWidening(
                            func,
                            yieldType,
                            WideningKind.GeneratorYield
                        );
                    }
                    if (returnType) reportErrorsFromWidening(func, returnType);
                    if (nextType) reportErrorsFromWidening(func, nextType);
                }
                if (returnType && isUnitType(returnType)
                    || yieldType && isUnitType(yieldType)
                    || nextType && isUnitType(nextType))
                {
                    const contextualType = !contextualSignature
                        ? undefined
                        : contextualSignature === getSignatureFromDeclaration(
                            func
                        )
                            ? isGenerator ? undefined : returnType
                            : instantiateContextualType(
                                getReturnTypeOfSignature(contextualSignature),
                                func
                            );
                    if (isGenerator) {
                        yieldType = getWidenedLiteralLikeTypeForContextualIterationTypeIfNeeded(
                            yieldType,
                            contextualType,
                            IterationTypeKind.Yield,
                            isAsync
                        );
                        returnType = getWidenedLiteralLikeTypeForContextualIterationTypeIfNeeded(
                            returnType,
                            contextualType,
                            IterationTypeKind.Return,
                            isAsync
                        );
                        nextType = getWidenedLiteralLikeTypeForContextualIterationTypeIfNeeded(
                            nextType,
                            contextualType,
                            IterationTypeKind.Next,
                            isAsync
                        );
                    } else {
                        returnType = getWidenedLiteralLikeTypeForContextualReturnTypeIfNeeded(
                            returnType,
                            contextualType,
                            isAsync
                        );
                    }
                }

                if (yieldType) yieldType = getWidenedType(yieldType);
                if (returnType) returnType = getWidenedType(returnType);
                if (nextType) nextType = getWidenedType(nextType);
            }

            if (isGenerator) {
                return createGeneratorReturnType(
                    yieldType || neverType,
                    returnType || fallbackReturnType,
                    nextType
                        || getContextualIterationType(
                            IterationTypeKind.Next,
                            func
                        ) || unknownType,
                    isAsync
                );
            } else {
                // From within an async function you can return either a non-promise value or a promise. Any
                // Promise/A+ compatible implementation will always assimilate any foreign promise, so the
                // return type of the body is awaited type of the body, wrapped in a native Promise<T> type.
                return isAsync
                    ? createPromiseType(returnType || fallbackReturnType)
                    : returnType || fallbackReturnType;
            }
        }

        function createGeneratorReturnType(
            yieldType: Type,
            returnType: Type,
            nextType: Type,
            isAsyncGenerator: boolean
        ) {
            const resolver = isAsyncGenerator
                ? asyncIterationTypesResolver
                : syncIterationTypesResolver;
            const globalGeneratorType = resolver
                .getGlobalGeneratorType(/*reportErrors*/ false);
            yieldType = resolver.resolveIterationType(
                yieldType, /*errorNode*/
                undefined
            ) || unknownType;
            returnType = resolver
                .resolveIterationType(returnType, /*errorNode*/ undefined)
                || unknownType;
            nextType = resolver.resolveIterationType(
                nextType, /*errorNode*/
                undefined
            ) || unknownType;
            if (globalGeneratorType === emptyGenericType) {
                // Fall back to the global IterableIterator if returnType is assignable to the expected return iteration
                // type of IterableIterator, and the expected next iteration type of IterableIterator is assignable to
                // nextType.
                const globalType = resolver
                    .getGlobalIterableIteratorType(/*reportErrors*/ false);
                const iterationTypes = globalType !== emptyGenericType
                    ? getIterationTypesOfGlobalIterableType(
                        globalType,
                        resolver
                    )
                    : undefined;
                const iterableIteratorReturnType = iterationTypes
                    ? iterationTypes.returnType
                    : anyType;
                const iterableIteratorNextType = iterationTypes
                    ? iterationTypes.nextType
                    : undefinedType;
                if (isTypeAssignableTo(returnType, iterableIteratorReturnType)
                    && isTypeAssignableTo(iterableIteratorNextType, nextType))
                {
                    if (globalType !== emptyGenericType) {
                        return createTypeFromGenericGlobalType(
                            globalType,
                            [yieldType]
                        );
                    }

                    // The global IterableIterator type doesn't exist, so report an error
                    resolver
                        .getGlobalIterableIteratorType(/*reportErrors*/ true);
                    return emptyObjectType;
                }

                // The global Generator type doesn't exist, so report an error
                resolver.getGlobalGeneratorType(/*reportErrors*/ true);
                return emptyObjectType;
            }

            return createTypeFromGenericGlobalType(
                globalGeneratorType,
                [yieldType, returnType, nextType]
            );
        }

        function checkAndAggregateYieldOperandTypes(
            func: FunctionLikeDeclaration,
            checkMode: CheckMode | undefined
        ) {
            const yieldTypes: Type[] = [];
            const nextTypes: Type[] = [];
            const isAsync = (getFunctionFlags(func) & FunctionFlags.Async)
                !== 0;
            forEachYieldExpression(
                <Block> func.body,
                yieldExpression => {
                    const yieldExpressionType = yieldExpression.expression
                        ? checkExpression(yieldExpression.expression,
                            checkMode) : undefinedWideningType;
                    pushIfUnique(
                        yieldTypes,
                        getYieldedTypeOfYieldExpression(
                            yieldExpression,
                            yieldExpressionType,
                            anyType,
                            isAsync
                        )
                    );
                    let nextType: Type | undefined;
                    if (yieldExpression.asteriskToken) {
                        const iterationTypes = getIterationTypesOfIterable(
                            yieldExpressionType,
                            isAsync ? IterationUse.AsyncYieldStar
                                : IterationUse.YieldStar,
                            yieldExpression.expression
                        );
                        nextType = iterationTypes && iterationTypes.nextType;
                    } else {
                        nextType = getContextualType(yieldExpression);
                    }
                    if (nextType) pushIfUnique(nextTypes, nextType);
                }
            );
            return { yieldTypes, nextTypes };
        }

        function getYieldedTypeOfYieldExpression(
            node: YieldExpression,
            expressionType: Type,
            sentType: Type,
            isAsync: boolean
        ): Type | undefined {
            const errorNode = node.expression || node;
            // A `yield*` expression effectively yields everything that its operand yields
            const yieldedType = node.asteriskToken
                ? checkIteratedTypeOrElementType(
                    isAsync
                        ? IterationUse.AsyncYieldStar
                        : IterationUse.YieldStar,
                    expressionType,
                    sentType,
                    errorNode
                )
                : expressionType;
            return !isAsync
                ? yieldedType
                : getAwaitedType(
                    yieldedType,
                    errorNode,
                    node.asteriskToken
                        ? Diagnostics
                            .Type_of_iterated_elements_of_a_yield_Asterisk_operand_must_either_be_a_valid_promise_or_must_not_contain_a_callable_then_member
                        : Diagnostics
                            .Type_of_yield_operand_in_an_async_generator_must_either_be_a_valid_promise_or_must_not_contain_a_callable_then_member
                );
        }

        /**
         * Collect the TypeFacts learned from a typeof switch with
         * total clauses `witnesses`, and the active clause ranging
         * from `start` to `end`. Parameter `hasDefault` denotes
         * whether the active clause contains a default clause.
         */
        function getFactsFromTypeofSwitch(
            start: number,
            end: number,
            witnesses: string[],
            hasDefault: boolean
        ): TypeFacts {
            let facts: TypeFacts = TypeFacts.None;
            // When in the default we only collect inequality facts
            // because default is 'in theory' a set of infinite
            // equalities.
            if (hasDefault) {
                // Value is not equal to any types after the active clause.
                for (let i = end; i < witnesses.length; i++) {
                    facts |= typeofNEFacts.get(witnesses[i])
                        || TypeFacts.TypeofNEHostObject;
                }
                // Remove inequalities for types that appear in the
                // active clause because they appear before other
                // types collected so far.
                for (let i = start; i < end; i++) {
                    facts &= ~(typeofNEFacts.get(witnesses[i]) || 0);
                }
                // Add inequalities for types before the active clause unconditionally.
                for (let i = 0; i < start; i++) {
                    facts |= typeofNEFacts.get(witnesses[i])
                        || TypeFacts.TypeofNEHostObject;
                }
            } // When in an active clause without default the set of
            // equalities is finite.
            else {
                // Add equalities for all types in the active clause.
                for (let i = start; i < end; i++) {
                    facts |= typeofEQFacts.get(witnesses[i])
                        || TypeFacts.TypeofEQHostObject;
                }
                // Remove equalities for types that appear before the
                // active clause.
                for (let i = 0; i < start; i++) {
                    facts &= ~(typeofEQFacts.get(witnesses[i]) || 0);
                }
            }
            return facts;
        }

        function isExhaustiveSwitchStatement(node: SwitchStatement): boolean {
            const links = getNodeLinks(node);
            return links.isExhaustive !== undefined
                ? links.isExhaustive
                : (links
                    .isExhaustive = computeExhaustiveSwitchStatement(node));
        }

        function computeExhaustiveSwitchStatement(
            node: SwitchStatement
        ): boolean {
            if (node.expression.kind === SyntaxKind.TypeOfExpression) {
                const operandType = getTypeOfExpression(
                    (node.expression as TypeOfExpression).expression
                );
                // This cast is safe because the switch is possibly exhaustive and does not contain a default case, so there can be no undefined.
                const witnesses = <string[]> getSwitchClauseTypeOfWitnesses(node);
                // notEqualFacts states that the type of the switched value is not equal to every type in the switch.
                const notEqualFacts = getFactsFromTypeofSwitch(
                    0,
                    0,
                    witnesses, /*hasDefault*/
                    true
                );
                const type = getBaseConstraintOfType(operandType)
                    || operandType;
                return !!(filterType(
                    type,
                    t => (getTypeFacts(t) & notEqualFacts) === notEqualFacts
                ).flags & TypeFlags.Never);
            }
            const type = getTypeOfExpression(node.expression);
            if (!isLiteralType(type)) {
                return false;
            }
            const switchTypes = getSwitchClauseTypes(node);
            if (!switchTypes.length
                || some(switchTypes, isNeitherUnitTypeNorNever))
            {
                return false;
            }
            return eachTypeContainedIn(
                mapType(
                    type,
                    getRegularTypeOfLiteralType
                ),
                switchTypes
            );
        }

        function functionHasImplicitReturn(func: FunctionLikeDeclaration) {
            return func.endFlowNode && isReachableFlowNode(func.endFlowNode);
        }

        /** NOTE: Return value of `[]` means a different thing than `undefined`. `[]` means func returns `void`, `undefined` means it returns `never`. */
        function checkAndAggregateReturnExpressionTypes(
            func: FunctionLikeDeclaration,
            checkMode: CheckMode | undefined
        ): Type[] | undefined {
            const functionFlags = getFunctionFlags(func);
            const aggregatedTypes: Type[] = [];
            let hasReturnWithNoExpression = functionHasImplicitReturn(func);
            let hasReturnOfTypeNever = false;
            forEachReturnStatement(
                <Block> func.body,
                returnStatement => {
                    const expr = returnStatement.expression;
                    if (expr) {
                        let type = checkExpressionCached(
                            expr,
                            checkMode
                                && checkMode & ~CheckMode.SkipGenericFunctions
                        );
                        if (functionFlags & FunctionFlags.Async) {
                            // From within an async function you can return either a non-promise value or a promise. Any
                            // Promise/A+ compatible implementation will always assimilate any foreign promise, so the
                            // return type of the body should be unwrapped to its awaited type, which should be wrapped in
                            // the native Promise<T> type by the caller.
                            type = checkAwaitedType(
                                type,
                                func,
                                Diagnostics
                                    .The_return_type_of_an_async_function_must_either_be_a_valid_promise_or_must_not_contain_a_callable_then_member
                            );
                        }
                        if (type.flags & TypeFlags.Never) {
                            hasReturnOfTypeNever = true;
                        }
                        pushIfUnique(aggregatedTypes, type);
                    } else {
                        hasReturnWithNoExpression = true;
                    }
                }
            );
            if (aggregatedTypes.length === 0 && !hasReturnWithNoExpression
                && (hasReturnOfTypeNever || mayReturnNever(func)))
            {
                return undefined;
            }
            if (strictNullChecks && aggregatedTypes.length
                && hasReturnWithNoExpression
                && !(isJSConstructor(func)
                    && aggregatedTypes.some(t => t.symbol === func.symbol)))
            {
                // Javascript "callable constructors", containing eg `if (!(this instanceof A)) return new A()` should not add undefined
                pushIfUnique(aggregatedTypes, undefinedType);
            }
            return aggregatedTypes;
        }
        function mayReturnNever(func: FunctionLikeDeclaration): boolean {
            switch (func.kind) {
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.ArrowFunction:
                    return true;
                case SyntaxKind.MethodDeclaration:
                    return func.parent.kind
                        === SyntaxKind.ObjectLiteralExpression;
                default:
                    return false;
            }
        }

        /**
         * TypeScript Specification 1.0 (6.3) - July 2014
         *   An explicitly typed function whose return type isn't the Void type,
         *   the Any type, or a union type containing the Void or Any type as a constituent
         *   must have at least one return statement somewhere in its body.
         *   An exception to this rule is if the function implementation consists of a single 'throw' statement.
         *
         * @param returnType - return type of the function, can be undefined if return type is not explicitly specified
         */
        function checkAllCodePathsInNonVoidFunctionReturnOrThrow(
            func: FunctionLikeDeclaration | MethodSignature,
            returnType: Type | undefined
        ): void {
            if (!produceDiagnostics) {
                return;
            }

            const functionFlags = getFunctionFlags(func);
            const type = returnType
                && getReturnOrPromisedType(returnType, functionFlags);

            // Functions with with an explicitly specified 'void' or 'any' return type don't need any return expressions.
            if (type
                && maybeTypeOfKind(type, TypeFlags.Any | TypeFlags.Void))
            {
                return;
            }

            // If all we have is a function signature, or an arrow function with an expression body, then there is nothing to check.
            // also if HasImplicitReturn flag is not set this means that all codepaths in function body end with return or throw
            if (func.kind === SyntaxKind.MethodSignature
                || nodeIsMissing(func.body)
                || func.body!.kind !== SyntaxKind.Block
                || !functionHasImplicitReturn(func))
            {
                return;
            }

            const hasExplicitReturn = func.flags & NodeFlags.HasExplicitReturn;

            if (type && type.flags & TypeFlags.Never) {
                error(
                    getEffectiveReturnTypeNode(func),
                    Diagnostics
                        .A_function_returning_never_cannot_have_a_reachable_end_point
                );
            } else if (type && !hasExplicitReturn) {
                // minimal check: function has syntactic return type annotation and no explicit return statements in the body
                // this function does not conform to the specification.
                // NOTE: having returnType !== undefined is a precondition for entering this branch so func.type will always be present
                error(
                    getEffectiveReturnTypeNode(func),
                    Diagnostics
                        .A_function_whose_declared_type_is_neither_void_nor_any_must_return_a_value
                );
            } else if (type && strictNullChecks
                && !isTypeAssignableTo(undefinedType, type))
            {
                error(
                    getEffectiveReturnTypeNode(func) || func,
                    Diagnostics
                        .Function_lacks_ending_return_statement_and_return_type_does_not_include_undefined
                );
            } else if (compilerOptions.noImplicitReturns) {
                if (!type) {
                    // If return type annotation is omitted check if function has any explicit return statements.
                    // If it does not have any - its inferred return type is void - don't do any checks.
                    // Otherwise get inferred return type from function body and report error only if it is not void / anytype
                    if (!hasExplicitReturn) {
                        return;
                    }
                    const inferredReturnType = getReturnTypeOfSignature(getSignatureFromDeclaration(func));
                    if (isUnwrappedReturnTypeVoidOrAny(
                        func,
                        inferredReturnType
                    )) {
                        return;
                    }
                }
                error(
                    getEffectiveReturnTypeNode(func) || func,
                    Diagnostics.Not_all_code_paths_return_a_value
                );
            }
        }

        function checkFunctionExpressionOrObjectLiteralMethod(
            node: FunctionExpression | MethodDeclaration,
            checkMode?: CheckMode
        ): Type {
            Debug
                .assert(
                    node.kind !== SyntaxKind.MethodDeclaration
                        || isObjectLiteralMethod(node)
                );
            checkNodeDeferred(node);

            // The identityMapper object is used to indicate that function expressions are wildcards
            if (checkMode && checkMode & CheckMode.SkipContextSensitive
                && isContextSensitive(node))
            {
                // Skip parameters, return signature with return type that retains noncontextual parts so inferences can still be drawn in an early stage
                if (!getEffectiveReturnTypeNode(node)
                    && hasContextSensitiveReturnExpression(node))
                {
                    // Return plain anyFunctionType if there is no possibility we'll make inferences from the return type
                    const contextualSignature = getContextualSignature(node);
                    if (contextualSignature
                        && couldContainTypeVariables(getReturnTypeOfSignature(contextualSignature)))
                    {
                        const links = getNodeLinks(node);
                        if (links.contextFreeType) {
                            return links.contextFreeType;
                        }
                        const returnType = getReturnTypeFromBody(
                            node,
                            checkMode
                        );
                        const returnOnlySignature = createSignature(
                            undefined,
                            undefined,
                            undefined,
                            emptyArray,
                            returnType, /*resolvedTypePredicate*/
                            undefined,
                            0,
                            SignatureFlags.None
                        );
                        const returnOnlyType = createAnonymousType(
                            node.symbol,
                            emptySymbols,
                            [returnOnlySignature],
                            emptyArray,
                            undefined,
                            undefined
                        );
                        returnOnlyType.objectFlags |= ObjectFlags
                            .NonInferrableType;
                        return links.contextFreeType = returnOnlyType;
                    }
                }
                return anyFunctionType;
            }

            // Grammar checking
            const hasGrammarError = checkGrammarFunctionLikeDeclaration(node);
            if (!hasGrammarError
                && node.kind === SyntaxKind.FunctionExpression)
            {
                checkGrammarForGenerator(node);
            }

            const type = getTypeOfSymbol(getMergedSymbol(node.symbol));
            if (isTypeAny(type)) {
                return type;
            }

            contextuallyCheckFunctionExpressionOrObjectLiteralMethod(
                node,
                checkMode
            );

            return type;
        }

        function contextuallyCheckFunctionExpressionOrObjectLiteralMethod(
            node: FunctionExpression | ArrowFunction | MethodDeclaration,
            checkMode?: CheckMode
        ) {
            const links = getNodeLinks(node);
            // Check if function expression is contextually typed and assign parameter types if so.
            if (!(links.flags & NodeCheckFlags.ContextChecked)) {
                const contextualSignature = getContextualSignature(node);
                // If a type check is started at a function expression that is an argument of a function call, obtaining the
                // contextual type may recursively get back to here during overload resolution of the call. If so, we will have
                // already assigned contextual types.
                if (!(links.flags & NodeCheckFlags.ContextChecked)) {
                    links.flags |= NodeCheckFlags.ContextChecked;
                    if (contextualSignature) {
                        const type = getTypeOfSymbol(
                            getMergedSymbol(
                                node.symbol
                            )
                        );
                        if (isTypeAny(type)) {
                            return;
                        }
                        const signature = getSignaturesOfType(
                            type,
                            SignatureKind.Call
                        )[0];
                        if (isContextSensitive(node)) {
                            const inferenceContext = getInferenceContext(node);
                            if (checkMode
                                && checkMode & CheckMode.Inferential)
                            {
                                inferFromAnnotatedParameters(
                                    signature,
                                    contextualSignature,
                                    inferenceContext!
                                );
                            }
                            const instantiatedContextualSignature = inferenceContext
                                ? instantiateSignature(
                                    contextualSignature,
                                    inferenceContext.mapper
                                )
                                : contextualSignature;
                            assignContextualParameterTypes(
                                signature,
                                instantiatedContextualSignature
                            );
                        }
                        if (!getReturnTypeFromAnnotation(node)
                            && !signature.resolvedReturnType)
                        {
                            const returnType = getReturnTypeFromBody(
                                node,
                                checkMode
                            );
                            if (!signature.resolvedReturnType) {
                                signature.resolvedReturnType = returnType;
                            }
                        }
                    }
                    checkSignatureDeclaration(node);
                }
            }
        }

        function getReturnOrPromisedType(
            type: Type | undefined,
            functionFlags: FunctionFlags
        ) {
            const isGenerator = !!(functionFlags & FunctionFlags.Generator);
            const isAsync = !!(functionFlags & FunctionFlags.Async);
            return type && isGenerator
                ? getIterationTypeOfGeneratorFunctionReturnType(
                    IterationTypeKind.Return,
                    type,
                    isAsync
                ) || errorType
                : type && isAsync
                    ? getAwaitedType(type) || errorType
                    : type;
        }

        function checkFunctionExpressionOrObjectLiteralMethodDeferred(
            node: ArrowFunction | FunctionExpression | MethodDeclaration
        ) {
            Debug
                .assert(
                    node.kind !== SyntaxKind.MethodDeclaration
                        || isObjectLiteralMethod(node)
                );

            const functionFlags = getFunctionFlags(node);
            const returnType = getReturnTypeFromAnnotation(node);
            checkAllCodePathsInNonVoidFunctionReturnOrThrow(node, returnType);

            if (node.body) {
                if (!getEffectiveReturnTypeNode(node)) {
                    // There are some checks that are only performed in getReturnTypeFromBody, that may produce errors
                    // we need. An example is the noImplicitAny errors resulting from widening the return expression
                    // of a function. Because checking of function expression bodies is deferred, there was never an
                    // appropriate time to do this during the main walk of the file (see the comment at the top of
                    // checkFunctionExpressionBodies). So it must be done now.
                    getReturnTypeOfSignature(getSignatureFromDeclaration(node));
                }

                if (node.body.kind === SyntaxKind.Block) {
                    checkSourceElement(node.body);
                } else {
                    // From within an async function you can return either a non-promise value or a promise. Any
                    // Promise/A+ compatible implementation will always assimilate any foreign promise, so we
                    // should not be checking assignability of a promise to the return type. Instead, we need to
                    // check assignability of the awaited type of the expression body against the promised type of
                    // its return type annotation.
                    const exprType = checkExpression(node.body);
                    const returnOrPromisedType = getReturnOrPromisedType(
                        returnType,
                        functionFlags
                    );
                    if (returnOrPromisedType) {
                        if ((functionFlags & FunctionFlags.AsyncGenerator)
                            === FunctionFlags.Async)
                        { // Async function
                            const awaitedType = checkAwaitedType(
                                exprType,
                                node.body,
                                Diagnostics
                                    .The_return_type_of_an_async_function_must_either_be_a_valid_promise_or_must_not_contain_a_callable_then_member
                            );
                            checkTypeAssignableToAndOptionallyElaborate(
                                awaitedType,
                                returnOrPromisedType,
                                node.body,
                                node.body
                            );
                        } else { // Normal function
                            checkTypeAssignableToAndOptionallyElaborate(
                                exprType,
                                returnOrPromisedType,
                                node.body,
                                node.body
                            );
                        }
                    }
                }
            }
        }

        function checkArithmeticOperandType(
            operand: Node,
            type: Type,
            diagnostic: DiagnosticMessage,
            isAwaitValid = false
        ): boolean {
            if (!isTypeAssignableTo(type, numberOrBigIntType)) {
                const awaitedType = isAwaitValid
                    && getAwaitedTypeOfPromise(type);
                errorAndMaybeSuggestAwait(
                    operand,
                    !!awaitedType
                        && isTypeAssignableTo(awaitedType, numberOrBigIntType),
                    diagnostic
                );
                return false;
            }
            return true;
        }

        function isReadonlyAssignmentDeclaration(d: Declaration) {
            if (!isCallExpression(d)) {
                return false;
            }
            if (!isBindableObjectDefinePropertyCall(d)) {
                return false;
            }
            const objectLitType = checkExpressionCached(d.arguments[2]);
            const valueType = getTypeOfPropertyOfType(
                objectLitType,
                'value' as __String
            );
            if (valueType) {
                const writableProp = getPropertyOfType(
                    objectLitType,
                    'writable' as __String
                );
                const writableType = writableProp
                    && getTypeOfSymbol(writableProp);
                if (!writableType || writableType === falseType
                    || writableType === regularFalseType)
                {
                    return true;
                }
                // We include this definition whereupon we walk back and check the type at the declaration because
                // The usual definition of `Object.defineProperty` will _not_ cause literal types to be preserved in the
                // argument types, should the type be contextualized by the call itself.
                if (writableProp && writableProp.valueDeclaration
                    && isPropertyAssignment(writableProp.valueDeclaration))
                {
                    const initializer = writableProp.valueDeclaration
                        .initializer;
                    const rawOriginalType = checkExpression(initializer);
                    if (rawOriginalType === falseType
                        || rawOriginalType === regularFalseType)
                    {
                        return true;
                    }
                }
                return false;
            }
            const setProp = getPropertyOfType(objectLitType,
                'set' as __String);
            return !setProp;
        }

        function isReadonlySymbol(symbol: Symbol): boolean {
            // The following symbols are considered read-only:
            // Properties with a 'readonly' modifier
            // Variables declared with 'const'
            // Get accessors without matching set accessors
            // Enum members
            // Object.defineProperty assignments with writable false or no setter
            // Unions and intersections of the above (unions and intersections eagerly set isReadonly on creation)
            return !!(getCheckFlags(symbol) & CheckFlags.Readonly
                || symbol.flags & SymbolFlags.Property
                && getDeclarationModifierFlagsFromSymbol(symbol)
                & ModifierFlags.Readonly
                || symbol.flags & SymbolFlags.Variable
                && getDeclarationNodeFlagsFromSymbol(symbol) & NodeFlags.Const
                || symbol.flags & SymbolFlags.Accessor
                && !(symbol.flags & SymbolFlags.SetAccessor)
                || symbol.flags & SymbolFlags.EnumMember
                || some(symbol.declarations, isReadonlyAssignmentDeclaration));
        }

        function isAssignmentToReadonlyEntity(
            expr: Expression,
            symbol: Symbol,
            assignmentKind: AssignmentKind
        ) {
            if (assignmentKind === AssignmentKind.None) {
                // no assigment means it doesn't matter whether the entity is readonly
                return false;
            }
            if (isReadonlySymbol(symbol)) {
                // Allow assignments to readonly properties within constructors of the same class declaration.
                if (symbol.flags & SymbolFlags.Property
                    && isAccessExpression(expr)
                    && expr.expression.kind === SyntaxKind.ThisKeyword)
                {
                    // Look for if this is the constructor for the class that `symbol` is a property of.
                    const ctor = getContainingFunction(expr);
                    if (!(ctor && ctor.kind === SyntaxKind.Constructor)) {
                        return true;
                    }
                    if (symbol.valueDeclaration) {
                        const isAssignmentDeclaration = isBinaryExpression(
                            symbol.valueDeclaration
                        );
                        const isLocalPropertyDeclaration = ctor.parent
                            === symbol.valueDeclaration.parent;
                        const isLocalParameterProperty = ctor
                            === symbol.valueDeclaration.parent;
                        const isLocalThisPropertyAssignment = isAssignmentDeclaration
                            && symbol.parent?.valueDeclaration === ctor.parent;
                        const isLocalThisPropertyAssignmentConstructorFunction = isAssignmentDeclaration
                            && symbol.parent?.valueDeclaration === ctor;
                        const isWriteableSymbol = isLocalPropertyDeclaration
                            || isLocalParameterProperty
                            || isLocalThisPropertyAssignment
                            || isLocalThisPropertyAssignmentConstructorFunction;
                        return !isWriteableSymbol;
                    }
                }
                return true;
            }
            if (isAccessExpression(expr)) {
                // references through namespace import should be readonly
                const node = skipParentheses(expr.expression);
                if (node.kind === SyntaxKind.Identifier) {
                    const symbol = getNodeLinks(node).resolvedSymbol!;
                    if (symbol.flags & SymbolFlags.Alias) {
                        const declaration = getDeclarationOfAliasSymbol(symbol);
                        return !!declaration
                            && declaration.kind === SyntaxKind.NamespaceImport;
                    }
                }
            }
            return false;
        }

        function checkReferenceExpression(
            expr: Expression,
            invalidReferenceMessage: DiagnosticMessage,
            invalidOptionalChainMessage: DiagnosticMessage
        ): boolean {
            // References are combinations of identifiers, parentheses, and property accesses.
            const node = skipOuterExpressions(
                expr,
                OuterExpressionKinds.Assertions
                    | OuterExpressionKinds.Parentheses
            );
            if (node.kind !== SyntaxKind.Identifier
                && !isAccessExpression(node))
            {
                error(expr, invalidReferenceMessage);
                return false;
            }
            if (node.flags & NodeFlags.OptionalChain) {
                error(expr, invalidOptionalChainMessage);
                return false;
            }
            return true;
        }

        function checkDeleteExpression(node: DeleteExpression): Type {
            checkExpression(node.expression);
            const expr = skipParentheses(node.expression);
            if (!isAccessExpression(expr)) {
                error(
                    expr,
                    Diagnostics
                        .The_operand_of_a_delete_operator_must_be_a_property_reference
                );
                return booleanType;
            }
            if (expr.kind === SyntaxKind.PropertyAccessExpression
                && isPrivateIdentifier((expr as PropertyAccessExpression)
                    .name))
            {
                error(
                    expr,
                    Diagnostics
                        .The_operand_of_a_delete_operator_cannot_be_a_private_identifier
                );
            }
            const links = getNodeLinks(expr);
            const symbol = getExportSymbolOfValueSymbolIfExported(
                links.resolvedSymbol
            );
            if (symbol && isReadonlySymbol(symbol)) {
                error(
                    expr,
                    Diagnostics
                        .The_operand_of_a_delete_operator_cannot_be_a_read_only_property
                );
            }
            return booleanType;
        }

        function checkTypeOfExpression(node: TypeOfExpression): Type {
            checkExpression(node.expression);
            return typeofType;
        }

        function checkVoidExpression(node: VoidExpression): Type {
            checkExpression(node.expression);
            return undefinedWideningType;
        }

        function isTopLevelAwait(node: AwaitExpression) {
            const container = getThisContainer(
                node, /*includeArrowFunctions*/
                true
            );
            return isSourceFile(container);
        }

        function checkAwaitExpression(node: AwaitExpression): Type {
            // Grammar checking
            if (produceDiagnostics) {
                if (!(node.flags & NodeFlags.AwaitContext)) {
                    if (isTopLevelAwait(node)) {
                        const sourceFile = getSourceFileOfNode(node);
                        if ((moduleKind !== ModuleKind.ESNext
                            && moduleKind !== ModuleKind.System)
                            || languageVersion < ScriptTarget.ES2017
                            || !isEffectiveExternalModule(
                                sourceFile,
                                compilerOptions
                            ))
                        {
                            if (!hasParseDiagnostics(sourceFile)) {
                                const span = getSpanOfTokenAtPosition(
                                    sourceFile,
                                    node.pos
                                );
                                const diagnostic = createFileDiagnostic(
                                    sourceFile,
                                    span.start,
                                    span.length,
                                    Diagnostics
                                        .await_outside_of_an_async_function_is_only_allowed_at_the_top_level_of_a_module_when_module_is_esnext_or_system_and_target_is_es2017_or_higher
                                );
                                diagnostics.add(diagnostic);
                            }
                        }
                    } else {
                        // use of 'await' in non-async function
                        const sourceFile = getSourceFileOfNode(node);
                        if (!hasParseDiagnostics(sourceFile)) {
                            const span = getSpanOfTokenAtPosition(
                                sourceFile,
                                node.pos
                            );
                            const diagnostic = createFileDiagnostic(
                                sourceFile,
                                span.start,
                                span.length,
                                Diagnostics
                                    .await_expression_is_only_allowed_within_an_async_function
                            );
                            const func = getContainingFunction(node);
                            if (func && func.kind !== SyntaxKind.Constructor
                                && (getFunctionFlags(func)
                                    & FunctionFlags.Async) === 0)
                            {
                                const relatedInfo = createDiagnosticForNode(
                                    func,
                                    Diagnostics
                                        .Did_you_mean_to_mark_this_function_as_async
                                );
                                addRelatedInfo(diagnostic, relatedInfo);
                            }
                            diagnostics.add(diagnostic);
                        }
                    }
                }

                if (isInParameterInitializerBeforeContainingFunction(node)) {
                    error(
                        node,
                        Diagnostics
                            .await_expressions_cannot_be_used_in_a_parameter_initializer
                    );
                }
            }

            const operandType = checkExpression(node.expression);
            const awaitedType = checkAwaitedType(
                operandType,
                node,
                Diagnostics
                    .Type_of_await_operand_must_either_be_a_valid_promise_or_must_not_contain_a_callable_then_member
            );
            if (awaitedType === operandType && awaitedType !== errorType
                && !(operandType.flags & TypeFlags.AnyOrUnknown))
            {
                addErrorOrSuggestion(
                    /*isError*/ false,
                    createDiagnosticForNode(
                        node,
                        Diagnostics
                            .await_has_no_effect_on_the_type_of_this_expression
                    )
                );
            }
            return awaitedType;
        }

        function checkPrefixUnaryExpression(node:
            PrefixUnaryExpression): Type
        {
            const operandType = checkExpression(node.operand);
            if (operandType === silentNeverType) {
                return silentNeverType;
            }
            switch (node.operand.kind) {
                case SyntaxKind.NumericLiteral:
                    switch (node.operator) {
                        case SyntaxKind.MinusToken:
                            return getFreshTypeOfLiteralType(
                                getLiteralType(
                                    -(node.operand as NumericLiteral).text
                                )
                            );
                        case SyntaxKind.PlusToken:
                            return getFreshTypeOfLiteralType(
                                getLiteralType(
                                    +(node.operand as NumericLiteral).text
                                )
                            );
                    }
                    break;
                case SyntaxKind.BigIntLiteral:
                    if (node.operator === SyntaxKind.MinusToken) {
                        return getFreshTypeOfLiteralType(
                            getLiteralType(
                                {
                                    negative: true,
                                    base10Value: parsePseudoBigInt(
                                        (node.operand as BigIntLiteral).text
                                    )
                                }
                            )
                        );
                    }
            }
            switch (node.operator) {
                case SyntaxKind.PlusToken:
                case SyntaxKind.MinusToken:
                case SyntaxKind.TildeToken:
                    checkNonNullType(operandType, node.operand);
                    if (maybeTypeOfKind(operandType, TypeFlags.ESSymbolLike)) {
                        error(
                            node.operand,
                            Diagnostics
                                .The_0_operator_cannot_be_applied_to_type_symbol,
                            tokenToString(node.operator)
                        );
                    }
                    if (node.operator === SyntaxKind.PlusToken) {
                        if (maybeTypeOfKind(operandType,
                            TypeFlags.BigIntLike))
                        {
                            error(
                                node.operand,
                                Diagnostics
                                    .Operator_0_cannot_be_applied_to_type_1,
                                tokenToString(node.operator),
                                typeToString(getBaseTypeOfLiteralType(operandType))
                            );
                        }
                        return numberType;
                    }
                    return getUnaryResultType(operandType);
                case SyntaxKind.ExclamationToken:
                    checkTruthinessExpression(node.operand);
                    const facts = getTypeFacts(operandType)
                        & (TypeFacts.Truthy | TypeFacts.Falsy);
                    return facts === TypeFacts.Truthy
                        ? falseType
                        : facts === TypeFacts.Falsy
                            ? trueType
                            : booleanType;
                case SyntaxKind.PlusPlusToken:
                case SyntaxKind.MinusMinusToken:
                    const ok = checkArithmeticOperandType(
                        node.operand,
                        checkNonNullType(operandType, node.operand),
                        Diagnostics
                            .An_arithmetic_operand_must_be_of_type_any_number_bigint_or_an_enum_type
                    );
                    if (ok) {
                        // run check only if former checks succeeded to avoid reporting cascading errors
                        checkReferenceExpression(
                            node.operand,
                            Diagnostics
                                .The_operand_of_an_increment_or_decrement_operator_must_be_a_variable_or_a_property_access,
                            Diagnostics
                                .The_operand_of_an_increment_or_decrement_operator_may_not_be_an_optional_property_access
                        );
                    }
                    return getUnaryResultType(operandType);
            }
            return errorType;
        }

        function checkPostfixUnaryExpression(
            node: PostfixUnaryExpression
        ): Type {
            const operandType = checkExpression(node.operand);
            if (operandType === silentNeverType) {
                return silentNeverType;
            }
            const ok = checkArithmeticOperandType(
                node.operand,
                checkNonNullType(operandType, node.operand),
                Diagnostics
                    .An_arithmetic_operand_must_be_of_type_any_number_bigint_or_an_enum_type
            );
            if (ok) {
                // run check only if former checks succeeded to avoid reporting cascading errors
                checkReferenceExpression(
                    node.operand,
                    Diagnostics
                        .The_operand_of_an_increment_or_decrement_operator_must_be_a_variable_or_a_property_access,
                    Diagnostics
                        .The_operand_of_an_increment_or_decrement_operator_may_not_be_an_optional_property_access
                );
            }
            return getUnaryResultType(operandType);
        }

        function getUnaryResultType(operandType: Type): Type {
            if (maybeTypeOfKind(operandType, TypeFlags.BigIntLike)) {
                return isTypeAssignableToKind(
                    operandType,
                    TypeFlags.AnyOrUnknown
                ) || maybeTypeOfKind(operandType, TypeFlags.NumberLike)
                    ? numberOrBigIntType
                    : bigintType;
            }
            // If it's not a bigint type, implicit coercion will result in a number
            return numberType;
        }

        // Return true if type might be of the given kind. A union or intersection type might be of a given
        // kind if at least one constituent type is of the given kind.
        function maybeTypeOfKind(type: Type, kind: TypeFlags): boolean {
            if (type.flags & kind & ~TypeFlags.GenericMappedType
                || kind & TypeFlags.GenericMappedType
                && isGenericMappedType(type))
            {
                return true;
            }
            if (type.flags & TypeFlags.UnionOrIntersection) {
                const types = (<UnionOrIntersectionType> type).types;
                for (const t of types) {
                    if (maybeTypeOfKind(t, kind)) {
                        return true;
                    }
                }
            }
            return false;
        }

        function isTypeAssignableToKind(
            source: Type,
            kind: TypeFlags,
            strict?: boolean
        ): boolean {
            if (source.flags & kind) {
                return true;
            }
            if (strict
                && source.flags
                & (TypeFlags.AnyOrUnknown | TypeFlags.Void
                    | TypeFlags.Undefined | TypeFlags.Null))
            {
                return false;
            }
            return !!(kind & TypeFlags.NumberLike)
                && isTypeAssignableTo(source, numberType)
                || !!(kind & TypeFlags.BigIntLike)
                && isTypeAssignableTo(source, bigintType)
                || !!(kind & TypeFlags.StringLike)
                && isTypeAssignableTo(source, stringType)
                || !!(kind & TypeFlags.BooleanLike)
                && isTypeAssignableTo(source, booleanType)
                || !!(kind & TypeFlags.Void)
                && isTypeAssignableTo(source, voidType)
                || !!(kind & TypeFlags.Never)
                && isTypeAssignableTo(source, neverType)
                || !!(kind & TypeFlags.Null)
                && isTypeAssignableTo(source, nullType)
                || !!(kind & TypeFlags.Undefined)
                && isTypeAssignableTo(source, undefinedType)
                || !!(kind & TypeFlags.ESSymbol)
                && isTypeAssignableTo(source, esSymbolType)
                || !!(kind & TypeFlags.NonPrimitive)
                && isTypeAssignableTo(source, nonPrimitiveType);
        }

        function allTypesAssignableToKind(
            source: Type,
            kind: TypeFlags,
            strict?: boolean
        ): boolean {
            return source.flags & TypeFlags.Union
                ? every(
                    (source as UnionType).types,
                    subType => allTypesAssignableToKind(subType, kind, strict)
                )
                : isTypeAssignableToKind(source, kind, strict);
        }

        function isConstEnumObjectType(type: Type): boolean {
            return !!(getObjectFlags(type) & ObjectFlags.Anonymous)
                && !!type.symbol && isConstEnumSymbol(type.symbol);
        }

        function isConstEnumSymbol(symbol: Symbol): boolean {
            return (symbol.flags & SymbolFlags.ConstEnum) !== 0;
        }

        function checkInstanceOfExpression(
            left: Expression,
            right: Expression,
            leftType: Type,
            rightType: Type
        ): Type {
            if (leftType === silentNeverType
                || rightType === silentNeverType)
            {
                return silentNeverType;
            }
            // TypeScript 1.0 spec (April 2014): 4.15.4
            // The instanceof operator requires the left operand to be of type Any, an object type, or a type parameter type,
            // and the right operand to be of type Any, a subtype of the 'Function' interface type, or have a call or construct signature.
            // The result is always of the Boolean primitive type.
            // NOTE: do not raise error if leftType is unknown as related error was already reported
            if (!isTypeAny(leftType)
                && allTypesAssignableToKind(leftType, TypeFlags.Primitive))
            {
                error(
                    left,
                    Diagnostics
                        .The_left_hand_side_of_an_instanceof_expression_must_be_of_type_any_an_object_type_or_a_type_parameter
                );
            }
            // NOTE: do not raise error if right is unknown as related error was already reported
            if (!(isTypeAny(rightType)
                || typeHasCallOrConstructSignatures(rightType)
                || isTypeSubtypeOf(rightType, globalFunctionType)))
            {
                error(
                    right,
                    Diagnostics
                        .The_right_hand_side_of_an_instanceof_expression_must_be_of_type_any_or_of_a_type_assignable_to_the_Function_interface_type
                );
            }
            return booleanType;
        }

        function checkInExpression(
            left: Expression,
            right: Expression,
            leftType: Type,
            rightType: Type
        ): Type {
            if (leftType === silentNeverType
                || rightType === silentNeverType)
            {
                return silentNeverType;
            }
            leftType = checkNonNullType(leftType, left);
            rightType = checkNonNullType(rightType, right);
            // TypeScript 1.0 spec (April 2014): 4.15.5
            // The in operator requires the left operand to be of type Any, the String primitive type, or the Number primitive type,
            // and the right operand to be of type Any, an object type, or a type parameter type.
            // The result is always of the Boolean primitive type.
            if (!(isTypeComparableTo(leftType, stringType)
                || isTypeAssignableToKind(
                    leftType,
                    TypeFlags.NumberLike | TypeFlags.ESSymbolLike
                )))
            {
                error(
                    left,
                    Diagnostics
                        .The_left_hand_side_of_an_in_expression_must_be_of_type_any_string_number_or_symbol
                );
            }
            if (!allTypesAssignableToKind(
                rightType,
                TypeFlags.NonPrimitive | TypeFlags.InstantiableNonPrimitive
            )) {
                error(
                    right,
                    Diagnostics
                        .The_right_hand_side_of_an_in_expression_must_be_of_type_any_an_object_type_or_a_type_parameter
                );
            }
            return booleanType;
        }

        function checkObjectLiteralAssignment(
            node: ObjectLiteralExpression,
            sourceType: Type,
            rightIsThis?: boolean
        ): Type {
            const properties = node.properties;
            if (strictNullChecks && properties.length === 0) {
                return checkNonNullType(sourceType, node);
            }
            for (let i = 0; i < properties.length; i++) {
                checkObjectLiteralDestructuringPropertyAssignment(
                    node,
                    sourceType,
                    i,
                    properties,
                    rightIsThis
                );
            }
            return sourceType;
        }

        /** Note: If property cannot be a SpreadAssignment, then allProperties does not need to be provided */
        function checkObjectLiteralDestructuringPropertyAssignment(
            node: ObjectLiteralExpression,
            objectLiteralType: Type,
            propertyIndex: number,
            allProperties?: NodeArray<ObjectLiteralElementLike>,
            rightIsThis = false
        ) {
            const properties = node.properties;
            const property = properties[propertyIndex];
            if (property.kind === SyntaxKind.PropertyAssignment
                || property.kind === SyntaxKind.ShorthandPropertyAssignment)
            {
                const name = property.name;
                const exprType = getLiteralTypeFromPropertyName(name);
                if (isTypeUsableAsPropertyName(exprType)) {
                    const text = getPropertyNameFromType(exprType);
                    const prop = getPropertyOfType(objectLiteralType, text);
                    if (prop) {
                        markPropertyAsReferenced(prop, property, rightIsThis);
                        checkPropertyAccessibility(
                            property, /*isSuper*/
                            false,
                            objectLiteralType,
                            prop
                        );
                    }
                }
                const elementType = getIndexedAccessType(
                    objectLiteralType,
                    exprType,
                    name
                );
                const type = getFlowTypeOfDestructuring(property, elementType);
                return checkDestructuringAssignment(
                    property.kind === SyntaxKind.ShorthandPropertyAssignment
                        ? property
                        : property.initializer,
                    type
                );
            } else if (property.kind === SyntaxKind.SpreadAssignment) {
                if (propertyIndex < properties.length - 1) {
                    error(
                        property,
                        Diagnostics
                            .A_rest_element_must_be_last_in_a_destructuring_pattern
                    );
                } else {
                    if (languageVersion < ScriptTarget.ESNext) {
                        checkExternalEmitHelpers(
                            property,
                            ExternalEmitHelpers.Rest
                        );
                    }
                    const nonRestNames: PropertyName[] = [];
                    if (allProperties) {
                        for (const otherProperty of allProperties) {
                            if (!isSpreadAssignment(otherProperty)) {
                                nonRestNames.push(otherProperty.name);
                            }
                        }
                    }
                    const type = getRestType(
                        objectLiteralType,
                        nonRestNames,
                        objectLiteralType.symbol
                    );
                    checkGrammarForDisallowedTrailingComma(
                        allProperties,
                        Diagnostics
                            .A_rest_parameter_or_binding_pattern_may_not_have_a_trailing_comma
                    );
                    return checkDestructuringAssignment(
                        property.expression,
                        type
                    );
                }
            } else {
                error(property, Diagnostics.Property_assignment_expected);
            }
        }

        function checkArrayLiteralAssignment(
            node: ArrayLiteralExpression,
            sourceType: Type,
            checkMode?: CheckMode
        ): Type {
            const elements = node.elements;
            if (languageVersion < ScriptTarget.ES2015
                && compilerOptions.downlevelIteration)
            {
                checkExternalEmitHelpers(node, ExternalEmitHelpers.Read);
            }
            // This elementType will be used if the specific property corresponding to this index is not
            // present (aka the tuple element property). This call also checks that the parentType is in
            // fact an iterable or array (depending on target language).
            const elementType = checkIteratedTypeOrElementType(
                IterationUse.Destructuring,
                sourceType,
                undefinedType,
                node
            ) || errorType;
            for (let i = 0; i < elements.length; i++) {
                checkArrayLiteralDestructuringElementAssignment(
                    node,
                    sourceType,
                    i,
                    elementType,
                    checkMode
                );
            }
            return sourceType;
        }

        function checkArrayLiteralDestructuringElementAssignment(
            node: ArrayLiteralExpression,
            sourceType: Type,
            elementIndex: number,
            elementType: Type,
            checkMode?: CheckMode
        ) {
            const elements = node.elements;
            const element = elements[elementIndex];
            if (element.kind !== SyntaxKind.OmittedExpression) {
                if (element.kind !== SyntaxKind.SpreadElement) {
                    const indexType = getLiteralType(elementIndex);
                    if (isArrayLikeType(sourceType)) {
                        // We create a synthetic expression so that getIndexedAccessType doesn't get confused
                        // when the element is a SyntaxKind.ElementAccessExpression.
                        const accessFlags = hasDefaultValue(element)
                            ? AccessFlags.NoTupleBoundsCheck
                            : 0;
                        const elementType = getIndexedAccessTypeOrUndefined(
                            sourceType,
                            indexType,
                            createSyntheticExpression(element, indexType),
                            accessFlags
                        ) || errorType;
                        const assignedType = hasDefaultValue(element)
                            ? getTypeWithFacts(
                                elementType,
                                TypeFacts.NEUndefined
                            )
                            : elementType;
                        const type = getFlowTypeOfDestructuring(
                            element,
                            assignedType
                        );
                        return checkDestructuringAssignment(
                            element,
                            type,
                            checkMode
                        );
                    }
                    return checkDestructuringAssignment(
                        element,
                        elementType,
                        checkMode
                    );
                }
                if (elementIndex < elements.length - 1) {
                    error(
                        element,
                        Diagnostics
                            .A_rest_element_must_be_last_in_a_destructuring_pattern
                    );
                } else {
                    const restExpression = (<SpreadElement> element)
                        .expression;
                    if (restExpression.kind === SyntaxKind.BinaryExpression
                        && (<BinaryExpression> restExpression).operatorToken
                            .kind === SyntaxKind.EqualsToken)
                    {
                        error(
                            (<BinaryExpression> restExpression).operatorToken,
                            Diagnostics
                                .A_rest_element_cannot_have_an_initializer
                        );
                    } else {
                        checkGrammarForDisallowedTrailingComma(
                            node.elements,
                            Diagnostics
                                .A_rest_parameter_or_binding_pattern_may_not_have_a_trailing_comma
                        );
                        const type = everyType(sourceType, isTupleType)
                            ? mapType(
                                sourceType,
                                t => sliceTupleType(
                                    <TupleTypeReference> t,
                                    elementIndex
                                )
                            )
                            : createArrayType(elementType);
                        return checkDestructuringAssignment(
                            restExpression,
                            type,
                            checkMode
                        );
                    }
                }
            }
            return undefined;
        }

        function checkDestructuringAssignment(
            exprOrAssignment: Expression | ShorthandPropertyAssignment,
            sourceType: Type,
            checkMode?: CheckMode,
            rightIsThis?: boolean
        ): Type {
            let target: Expression;
            if (exprOrAssignment.kind
                === SyntaxKind.ShorthandPropertyAssignment)
            {
                const prop = <ShorthandPropertyAssignment> exprOrAssignment;
                if (prop.objectAssignmentInitializer) {
                    // In strict null checking mode, if a default value of a non-undefined type is specified, remove
                    // undefined from the final type.
                    if (strictNullChecks
                        && !(getFalsyFlags(
                            checkExpression(
                                prop.objectAssignmentInitializer
                            )
                        ) & TypeFlags.Undefined))
                    {
                        sourceType = getTypeWithFacts(
                            sourceType,
                            TypeFacts.NEUndefined
                        );
                    }
                    checkBinaryLikeExpression(
                        prop.name,
                        prop.equalsToken!,
                        prop.objectAssignmentInitializer,
                        checkMode
                    );
                }
                target = (<ShorthandPropertyAssignment> exprOrAssignment).name;
            } else {
                target = exprOrAssignment;
            }

            if (target.kind === SyntaxKind.BinaryExpression
                && (<BinaryExpression> target).operatorToken.kind
                === SyntaxKind.EqualsToken)
            {
                checkBinaryExpression(<BinaryExpression> target, checkMode);
                target = (<BinaryExpression> target).left;
            }
            if (target.kind === SyntaxKind.ObjectLiteralExpression) {
                return checkObjectLiteralAssignment(
                    <ObjectLiteralExpression> target,
                    sourceType,
                    rightIsThis
                );
            }
            if (target.kind === SyntaxKind.ArrayLiteralExpression) {
                return checkArrayLiteralAssignment(
                    <ArrayLiteralExpression> target,
                    sourceType,
                    checkMode
                );
            }
            return checkReferenceAssignment(target, sourceType, checkMode);
        }

        function checkReferenceAssignment(
            target: Expression,
            sourceType: Type,
            checkMode?: CheckMode
        ): Type {
            const targetType = checkExpression(target, checkMode);
            const error = target.parent.kind === SyntaxKind.SpreadAssignment
                ? Diagnostics
                    .The_target_of_an_object_rest_assignment_must_be_a_variable_or_a_property_access
                : Diagnostics
                    .The_left_hand_side_of_an_assignment_expression_must_be_a_variable_or_a_property_access;
            const optionalError = target.parent.kind
                === SyntaxKind.SpreadAssignment
                ? Diagnostics
                    .The_target_of_an_object_rest_assignment_may_not_be_an_optional_property_access
                : Diagnostics
                    .The_left_hand_side_of_an_assignment_expression_may_not_be_an_optional_property_access;
            if (checkReferenceExpression(target, error, optionalError)) {
                checkTypeAssignableToAndOptionallyElaborate(
                    sourceType,
                    targetType,
                    target,
                    target
                );
            }
            if (isPrivateIdentifierPropertyAccessExpression(target)) {
                checkExternalEmitHelpers(
                    target.parent,
                    ExternalEmitHelpers.ClassPrivateFieldSet
                );
            }
            return sourceType;
        }

        /**
         * This is a *shallow* check: An expression is side-effect-free if the
         * evaluation of the expression *itself* cannot produce side effects.
         * For example, x++ / 3 is side-effect free because the / operator
         * does not have side effects.
         * The intent is to "smell test" an expression for correctness in positions where
         * its value is discarded (e.g. the left side of the comma operator).
         */
        function isSideEffectFree(node: Node): boolean {
            node = skipParentheses(node);
            switch (node.kind) {
                case SyntaxKind.Identifier:
                case SyntaxKind.StringLiteral:
                case SyntaxKind.RegularExpressionLiteral:
                case SyntaxKind.TaggedTemplateExpression:
                case SyntaxKind.TemplateExpression:
                case SyntaxKind.NoSubstitutionTemplateLiteral:
                case SyntaxKind.NumericLiteral:
                case SyntaxKind.BigIntLiteral:
                case SyntaxKind.TrueKeyword:
                case SyntaxKind.FalseKeyword:
                case SyntaxKind.NullKeyword:
                case SyntaxKind.UndefinedKeyword:
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.ClassExpression:
                case SyntaxKind.ArrowFunction:
                case SyntaxKind.ArrayLiteralExpression:
                case SyntaxKind.ObjectLiteralExpression:
                case SyntaxKind.TypeOfExpression:
                case SyntaxKind.NonNullExpression:
                case SyntaxKind.JsxSelfClosingElement:
                case SyntaxKind.JsxElement:
                    return true;
                case SyntaxKind.ConditionalExpression:
                    return isSideEffectFree(
                        (node as ConditionalExpression).whenTrue
                    )
                        && isSideEffectFree(
                            (node as ConditionalExpression).whenFalse
                        );
                case SyntaxKind.BinaryExpression:
                    if (isAssignmentOperator(
                        (node as BinaryExpression).operatorToken.kind
                    )) {
                        return false;
                    }
                    return isSideEffectFree((node as BinaryExpression).left)
                        && isSideEffectFree((node as BinaryExpression).right);
                case SyntaxKind.PrefixUnaryExpression:
                case SyntaxKind.PostfixUnaryExpression:
                    // Unary operators ~, !, +, and - have no side effects.
                    // The rest do.
                    switch ((node as PrefixUnaryExpression).operator) {
                        case SyntaxKind.ExclamationToken:
                        case SyntaxKind.PlusToken:
                        case SyntaxKind.MinusToken:
                        case SyntaxKind.TildeToken:
                            return true;
                    }
                    return false;

                // Some forms listed here for clarity
                case SyntaxKind.VoidExpression: // Explicit opt-out
                case SyntaxKind
                    .TypeAssertionExpression: // Not SEF, but can produce useful type warnings
                case SyntaxKind
                    .AsExpression: // Not SEF, but can produce useful type warnings
                default:
                    return false;
            }
        }

        function isTypeEqualityComparableTo(source: Type, target: Type) {
            return (target.flags & TypeFlags.Nullable) !== 0
                || isTypeComparableTo(source, target);
        }

        function checkBinaryExpression(
            node: BinaryExpression,
            checkMode?: CheckMode
        ) {
            if (isInJSFile(node) && getAssignedExpandoInitializer(node)) {
                return checkExpression(node.right, checkMode);
            }
            checkGrammarNullishCoalesceWithLogicalExpression(node);
            return checkBinaryLikeExpression(
                node.left,
                node.operatorToken,
                node.right,
                checkMode,
                node
            );
        }

        function checkGrammarNullishCoalesceWithLogicalExpression(
            node: BinaryExpression
        ) {
            const { left, operatorToken, right } = node;
            if (operatorToken.kind === SyntaxKind.QuestionQuestionToken) {
                if (isBinaryExpression(left)
                    && (left.operatorToken.kind === SyntaxKind.BarBarToken
                        || left.operatorToken.kind
                        === SyntaxKind.AmpersandAmpersandToken))
                {
                    grammarErrorOnNode(
                        left,
                        Diagnostics
                            ._0_and_1_operations_cannot_be_mixed_without_parentheses,
                        tokenToString(left.operatorToken.kind),
                        tokenToString(operatorToken.kind)
                    );
                }
                if (isBinaryExpression(right)
                    && (right.operatorToken.kind === SyntaxKind.BarBarToken
                        || right.operatorToken.kind
                        === SyntaxKind.AmpersandAmpersandToken))
                {
                    grammarErrorOnNode(
                        right,
                        Diagnostics
                            ._0_and_1_operations_cannot_be_mixed_without_parentheses,
                        tokenToString(right.operatorToken.kind),
                        tokenToString(operatorToken.kind)
                    );
                }
            }
        }

        function checkBinaryLikeExpression(
            left: Expression,
            operatorToken: Node,
            right: Expression,
            checkMode?: CheckMode,
            errorNode?: Node
        ): Type {
            const operator = operatorToken.kind;
            if (operator === SyntaxKind.EqualsToken
                && (left.kind === SyntaxKind.ObjectLiteralExpression
                    || left.kind === SyntaxKind.ArrayLiteralExpression))
            {
                return checkDestructuringAssignment(
                    left,
                    checkExpression(right, checkMode),
                    checkMode,
                    right.kind === SyntaxKind.ThisKeyword
                );
            }
            let leftType: Type;
            if (operator === SyntaxKind.AmpersandAmpersandToken
                || operator === SyntaxKind.BarBarToken
                || operator === SyntaxKind.QuestionQuestionToken)
            {
                leftType = checkTruthinessExpression(left, checkMode);
            } else {
                leftType = checkExpression(left, checkMode);
            }

            let rightType = checkExpression(right, checkMode);
            switch (operator) {
                case SyntaxKind.AsteriskToken:
                case SyntaxKind.AsteriskAsteriskToken:
                case SyntaxKind.AsteriskEqualsToken:
                case SyntaxKind.AsteriskAsteriskEqualsToken:
                case SyntaxKind.SlashToken:
                case SyntaxKind.SlashEqualsToken:
                case SyntaxKind.PercentToken:
                case SyntaxKind.PercentEqualsToken:
                case SyntaxKind.MinusToken:
                case SyntaxKind.MinusEqualsToken:
                case SyntaxKind.LessThanLessThanToken:
                case SyntaxKind.LessThanLessThanEqualsToken:
                case SyntaxKind.GreaterThanGreaterThanToken:
                case SyntaxKind.GreaterThanGreaterThanEqualsToken:
                case SyntaxKind.GreaterThanGreaterThanGreaterThanToken:
                case SyntaxKind.GreaterThanGreaterThanGreaterThanEqualsToken:
                case SyntaxKind.BarToken:
                case SyntaxKind.BarEqualsToken:
                case SyntaxKind.CaretToken:
                case SyntaxKind.CaretEqualsToken:
                case SyntaxKind.AmpersandToken:
                case SyntaxKind.AmpersandEqualsToken:
                    if (leftType === silentNeverType
                        || rightType === silentNeverType)
                    {
                        return silentNeverType;
                    }

                    leftType = checkNonNullType(leftType, left);
                    rightType = checkNonNullType(rightType, right);

                    let suggestedOperator: SyntaxKind | undefined;
                    // if a user tries to apply a bitwise operator to 2 boolean operands
                    // try and return them a helpful suggestion
                    if ((leftType.flags & TypeFlags.BooleanLike)
                        && (rightType.flags & TypeFlags.BooleanLike)
                        && (suggestedOperator = getSuggestedBooleanOperator(
                            operatorToken.kind
                        )) !== undefined)
                    {
                        error(
                            errorNode || operatorToken,
                            Diagnostics
                                .The_0_operator_is_not_allowed_for_boolean_types_Consider_using_1_instead,
                            tokenToString(operatorToken.kind),
                            tokenToString(suggestedOperator)
                        );
                        return numberType;
                    } else {
                        // otherwise just check each operand separately and report errors as normal
                        const leftOk = checkArithmeticOperandType(
                            left,
                            leftType,
                            Diagnostics
                                .The_left_hand_side_of_an_arithmetic_operation_must_be_of_type_any_number_bigint_or_an_enum_type, /*isAwaitValid*/
                            true
                        );
                        const rightOk = checkArithmeticOperandType(
                            right,
                            rightType,
                            Diagnostics
                                .The_right_hand_side_of_an_arithmetic_operation_must_be_of_type_any_number_bigint_or_an_enum_type, /*isAwaitValid*/
                            true
                        );
                        let resultType: Type;
                        // If both are any or unknown, allow operation; assume it will resolve to number
                        if ((isTypeAssignableToKind(
                            leftType,
                            TypeFlags.AnyOrUnknown
                        )
                            && isTypeAssignableToKind(
                                rightType,
                                TypeFlags.AnyOrUnknown
                            ))
                            // Or, if neither could be bigint, implicit coercion results in a number result
                            || !(maybeTypeOfKind(
                                leftType,
                                TypeFlags.BigIntLike
                            )
                                || maybeTypeOfKind(
                                    rightType,
                                    TypeFlags.BigIntLike
                                )))
                        {
                            resultType = numberType;
                        } // At least one is assignable to bigint, so check that both are
                        else if (bothAreBigIntLike(leftType, rightType)) {
                            switch (operator) {
                                case SyntaxKind
                                    .GreaterThanGreaterThanGreaterThanToken:
                                case SyntaxKind
                                    .GreaterThanGreaterThanGreaterThanEqualsToken:
                                    reportOperatorError();
                            }
                            resultType = bigintType;
                        } // Exactly one of leftType/rightType is assignable to bigint
                        else {
                            reportOperatorError(bothAreBigIntLike);
                            resultType = errorType;
                        }
                        if (leftOk && rightOk) {
                            checkAssignmentOperator(resultType);
                        }
                        return resultType;
                    }
                case SyntaxKind.PlusToken:
                case SyntaxKind.PlusEqualsToken:
                    if (leftType === silentNeverType
                        || rightType === silentNeverType)
                    {
                        return silentNeverType;
                    }

                    if (!isTypeAssignableToKind(leftType, TypeFlags.StringLike)
                        && !isTypeAssignableToKind(
                            rightType,
                            TypeFlags.StringLike
                        ))
                    {
                        leftType = checkNonNullType(leftType, left);
                        rightType = checkNonNullType(rightType, right);
                    }

                    let resultType: Type | undefined;
                    if (isTypeAssignableToKind(
                        leftType,
                        TypeFlags.NumberLike, /*strict*/
                        true
                    )
                        && isTypeAssignableToKind(
                            rightType,
                            TypeFlags.NumberLike, /*strict*/
                            true
                        ))
                    {
                        // Operands of an enum type are treated as having the primitive type Number.
                        // If both operands are of the Number primitive type, the result is of the Number primitive type.
                        resultType = numberType;
                    } else if (isTypeAssignableToKind(
                        leftType,
                        TypeFlags.BigIntLike, /*strict*/
                        true
                    )
                        && isTypeAssignableToKind(
                            rightType,
                            TypeFlags.BigIntLike, /*strict*/
                            true
                        ))
                    {
                        // If both operands are of the BigInt primitive type, the result is of the BigInt primitive type.
                        resultType = bigintType;
                    } else if (isTypeAssignableToKind(
                        leftType,
                        TypeFlags.StringLike, /*strict*/
                        true
                    )
                        || isTypeAssignableToKind(
                            rightType,
                            TypeFlags.StringLike, /*strict*/
                            true
                        ))
                    {
                        // If one or both operands are of the String primitive type, the result is of the String primitive type.
                        resultType = stringType;
                    } else if (isTypeAny(leftType) || isTypeAny(rightType)) {
                        // Otherwise, the result is of type Any.
                        // NOTE: unknown type here denotes error type. Old compiler treated this case as any type so do we.
                        resultType = leftType === errorType
                            || rightType === errorType
                            ? errorType
                            : anyType;
                    }

                    // Symbols are not allowed at all in arithmetic expressions
                    if (resultType
                        && !checkForDisallowedESSymbolOperand(operator))
                    {
                        return resultType;
                    }

                    if (!resultType) {
                        // Types that have a reasonably good chance of being a valid operand type.
                        // If both types have an awaited type of one of these, we'll assume the user
                        // might be missing an await without doing an exhaustive check that inserting
                        // await(s) will actually be a completely valid binary expression.
                        const closeEnoughKind = TypeFlags.NumberLike
                            | TypeFlags.BigIntLike | TypeFlags.StringLike
                            | TypeFlags.AnyOrUnknown;
                        reportOperatorError((left,
                            right) =>
                        isTypeAssignableToKind(left, closeEnoughKind)
                            && isTypeAssignableToKind(right, closeEnoughKind));
                        return anyType;
                    }

                    if (operator === SyntaxKind.PlusEqualsToken) {
                        checkAssignmentOperator(resultType);
                    }
                    return resultType;
                case SyntaxKind.LessThanToken:
                case SyntaxKind.GreaterThanToken:
                case SyntaxKind.LessThanEqualsToken:
                case SyntaxKind.GreaterThanEqualsToken:
                    if (checkForDisallowedESSymbolOperand(operator)) {
                        leftType = getBaseTypeOfLiteralType(
                            checkNonNullType(
                                leftType,
                                left
                            )
                        );
                        rightType = getBaseTypeOfLiteralType(
                            checkNonNullType(
                                rightType,
                                right
                            )
                        );
                        reportOperatorErrorUnless((left,
                            right) =>
                        isTypeComparableTo(left, right)
                            || isTypeComparableTo(right, left) || (
                                isTypeAssignableTo(left, numberOrBigIntType)
                                && isTypeAssignableTo(
                                    right,
                                    numberOrBigIntType
                                )
                            ));
                    }
                    return booleanType;
                case SyntaxKind.EqualsEqualsToken:
                case SyntaxKind.ExclamationEqualsToken:
                case SyntaxKind.EqualsEqualsEqualsToken:
                case SyntaxKind.ExclamationEqualsEqualsToken:
                    reportOperatorErrorUnless((left,
                        right) =>
                    isTypeEqualityComparableTo(left, right)
                        || isTypeEqualityComparableTo(right, left));
                    return booleanType;
                case SyntaxKind.InstanceOfKeyword:
                    return checkInstanceOfExpression(
                        left,
                        right,
                        leftType,
                        rightType
                    );
                case SyntaxKind.InKeyword:
                    return checkInExpression(left, right, leftType, rightType);
                case SyntaxKind.AmpersandAmpersandToken:
                    return getTypeFacts(leftType) & TypeFacts.Truthy
                        ? getUnionType(
                            [extractDefinitelyFalsyTypes(
                                strictNullChecks
                                    ? leftType
                                    : getBaseTypeOfLiteralType(rightType)
                            ), rightType]
                        )
                        : leftType;
                case SyntaxKind.BarBarToken:
                    return getTypeFacts(leftType) & TypeFacts.Falsy
                        ? getUnionType(
                            [removeDefinitelyFalsyTypes(leftType), rightType],
                            UnionReduction.Subtype
                        )
                        : leftType;
                case SyntaxKind.QuestionQuestionToken:
                    return getTypeFacts(leftType) & TypeFacts.EQUndefinedOrNull
                        ? getUnionType(
                            [getNonNullableType(leftType), rightType],
                            UnionReduction.Subtype
                        )
                        : leftType;
                case SyntaxKind.EqualsToken:
                    const declKind = isBinaryExpression(left.parent)
                        ? getAssignmentDeclarationKind(left.parent)
                        : AssignmentDeclarationKind.None;
                    checkAssignmentDeclaration(declKind, rightType);
                    if (isAssignmentDeclaration(declKind)) {
                        if (!(rightType.flags & TypeFlags.Object)
                            || declKind
                            !== AssignmentDeclarationKind.ModuleExports
                            && declKind !== AssignmentDeclarationKind.Prototype
                            && !isEmptyObjectType(rightType)
                            && !isFunctionObjectType(rightType as ObjectType)
                            && !(getObjectFlags(rightType)
                                & ObjectFlags.Class))
                        {
                            // don't check assignability of module.exports=, C.prototype=, or expando types because they will necessarily be incomplete
                            checkAssignmentOperator(rightType);
                        }
                        return leftType;
                    } else {
                        checkAssignmentOperator(rightType);
                        return getRegularTypeOfObjectLiteral(rightType);
                    }
                case SyntaxKind.CommaToken:
                    if (!compilerOptions.allowUnreachableCode
                        && isSideEffectFree(left) && !isEvalNode(right))
                    {
                        error(
                            left,
                            Diagnostics
                                .Left_side_of_comma_operator_is_unused_and_has_no_side_effects
                        );
                    }
                    return rightType;
                default:
                    return Debug.fail();
            }

            function bothAreBigIntLike(left: Type, right: Type): boolean {
                return isTypeAssignableToKind(left, TypeFlags.BigIntLike)
                    && isTypeAssignableToKind(right, TypeFlags.BigIntLike);
            }

            function checkAssignmentDeclaration(
                kind: AssignmentDeclarationKind,
                rightType: Type
            ) {
                if (kind === AssignmentDeclarationKind.ModuleExports) {
                    for (const prop of getPropertiesOfObjectType(rightType)) {
                        const propType = getTypeOfSymbol(prop);
                        if (propType.symbol
                            && propType.symbol.flags & SymbolFlags.Class)
                        {
                            const name = prop.escapedName;
                            const symbol = resolveName(
                                prop.valueDeclaration,
                                name,
                                SymbolFlags.Type,
                                undefined,
                                name, /*isUse*/
                                false
                            );
                            if (symbol
                                && symbol.declarations.some(isJSDocTypedefTag))
                            {
                                grammarErrorOnNode(
                                    symbol.declarations[0],
                                    Diagnostics.Duplicate_identifier_0,
                                    unescapeLeadingUnderscores(name)
                                );
                                return grammarErrorOnNode(
                                    prop.valueDeclaration,
                                    Diagnostics.Duplicate_identifier_0,
                                    unescapeLeadingUnderscores(name)
                                );
                            }
                        }
                    }
                }
            }

            function isEvalNode(node: Expression) {
                return node.kind === SyntaxKind.Identifier
                    && (node as Identifier).escapedText === 'eval';
            }

            // Return true if there was no error, false if there was an error.
            function checkForDisallowedESSymbolOperand(
                operator: SyntaxKind
            ): boolean {
                const offendingSymbolOperand = maybeTypeOfKind(
                    leftType,
                    TypeFlags.ESSymbolLike
                )
                    ? left
                    : maybeTypeOfKind(rightType, TypeFlags.ESSymbolLike)
                        ? right
                        : undefined;

                if (offendingSymbolOperand) {
                    error(
                        offendingSymbolOperand,
                        Diagnostics
                            .The_0_operator_cannot_be_applied_to_type_symbol,
                        tokenToString(operator)
                    );
                    return false;
                }

                return true;
            }

            function getSuggestedBooleanOperator(
                operator: SyntaxKind
            ): SyntaxKind | undefined {
                switch (operator) {
                    case SyntaxKind.BarToken:
                    case SyntaxKind.BarEqualsToken:
                        return SyntaxKind.BarBarToken;
                    case SyntaxKind.CaretToken:
                    case SyntaxKind.CaretEqualsToken:
                        return SyntaxKind.ExclamationEqualsEqualsToken;
                    case SyntaxKind.AmpersandToken:
                    case SyntaxKind.AmpersandEqualsToken:
                        return SyntaxKind.AmpersandAmpersandToken;
                    default:
                        return undefined;
                }
            }

            function checkAssignmentOperator(valueType: Type): void {
                if (produceDiagnostics && isAssignmentOperator(operator)) {
                    // TypeScript 1.0 spec (April 2014): 4.17
                    // An assignment of the form
                    //    VarExpr = ValueExpr
                    // requires VarExpr to be classified as a reference
                    // A compound assignment furthermore requires VarExpr to be classified as a reference (section 4.1)
                    // and the type of the non-compound operation to be assignable to the type of VarExpr.

                    if (checkReferenceExpression(
                        left,
                        Diagnostics
                            .The_left_hand_side_of_an_assignment_expression_must_be_a_variable_or_a_property_access,
                        Diagnostics
                            .The_left_hand_side_of_an_assignment_expression_may_not_be_an_optional_property_access
                    )
                        && (!isIdentifier(left)
                            || unescapeLeadingUnderscores(left.escapedText)
                            !== 'exports'))
                    {
                        // to avoid cascading errors check assignability only if 'isReference' check succeeded and no errors were reported
                        checkTypeAssignableToAndOptionallyElaborate(
                            valueType,
                            leftType,
                            left,
                            right
                        );
                    }
                }
            }

            function isAssignmentDeclaration(kind: AssignmentDeclarationKind) {
                switch (kind) {
                    case AssignmentDeclarationKind.ModuleExports:
                        return true;
                    case AssignmentDeclarationKind.ExportsProperty:
                    case AssignmentDeclarationKind.Property:
                    case AssignmentDeclarationKind.Prototype:
                    case AssignmentDeclarationKind.PrototypeProperty:
                    case AssignmentDeclarationKind.ThisProperty:
                        const symbol = getSymbolOfNode(left);
                        const init = getAssignedExpandoInitializer(right);
                        return init && isObjectLiteralExpression(init)
                            && symbol && hasEntries(symbol.exports);
                    default:
                        return false;
                }
            }

            /**
             * Returns true if an error is reported
             */
            function reportOperatorErrorUnless(
                typesAreCompatible: (
                    left: Type,
                    right: Type
                ) => boolean
            ): boolean {
                if (!typesAreCompatible(leftType, rightType)) {
                    reportOperatorError(typesAreCompatible);
                    return true;
                }
                return false;
            }

            function reportOperatorError(
                isRelated?: (
                    left: Type,
                    right: Type
                ) => boolean
            ) {
                let wouldWorkWithAwait = false;
                const errNode = errorNode || operatorToken;
                if (isRelated) {
                    const awaitedLeftType = getAwaitedType(leftType);
                    const awaitedRightType = getAwaitedType(rightType);
                    wouldWorkWithAwait = !(awaitedLeftType === leftType
                        && awaitedRightType === rightType)
                        && !!(awaitedLeftType && awaitedRightType)
                        && isRelated(awaitedLeftType, awaitedRightType);
                }

                let effectiveLeft = leftType;
                let effectiveRight = rightType;
                if (!wouldWorkWithAwait && isRelated) {
                    [effectiveLeft,
                        effectiveRight] = getBaseTypesIfUnrelated(
                            leftType,
                            rightType,
                            isRelated
                        );
                }
                const [leftStr,
                    rightStr] = getTypeNamesForErrorDisplay(
                        effectiveLeft,
                        effectiveRight
                    );
                if (!tryGiveBetterPrimaryError(
                    errNode,
                    wouldWorkWithAwait,
                    leftStr,
                    rightStr
                )) {
                    errorAndMaybeSuggestAwait(
                        errNode,
                        wouldWorkWithAwait,
                        Diagnostics
                            .Operator_0_cannot_be_applied_to_types_1_and_2,
                        tokenToString(operatorToken.kind),
                        leftStr,
                        rightStr
                    );
                }
            }

            function tryGiveBetterPrimaryError(
                errNode: Node,
                maybeMissingAwait: boolean,
                leftStr: string,
                rightStr: string
            ) {
                let typeName: string | undefined;
                switch (operatorToken.kind) {
                    case SyntaxKind.EqualsEqualsEqualsToken:
                    case SyntaxKind.EqualsEqualsToken:
                        typeName = 'false';
                        break;
                    case SyntaxKind.ExclamationEqualsEqualsToken:
                    case SyntaxKind.ExclamationEqualsToken:
                        typeName = 'true';
                }

                if (typeName) {
                    return errorAndMaybeSuggestAwait(
                        errNode,
                        maybeMissingAwait,
                        Diagnostics
                            .This_condition_will_always_return_0_since_the_types_1_and_2_have_no_overlap,
                        typeName,
                        leftStr,
                        rightStr
                    );
                }

                return undefined;
            }
        }

        function getBaseTypesIfUnrelated(
            leftType: Type,
            rightType: Type,
            isRelated: (left: Type, right: Type) => boolean
        ): [Type, Type] {
            let effectiveLeft = leftType;
            let effectiveRight = rightType;
            const leftBase = getBaseTypeOfLiteralType(leftType);
            const rightBase = getBaseTypeOfLiteralType(rightType);
            if (!isRelated(leftBase, rightBase)) {
                effectiveLeft = leftBase;
                effectiveRight = rightBase;
            }
            return [effectiveLeft, effectiveRight];
        }

        function checkYieldExpression(node: YieldExpression): Type {
            // Grammar checking
            if (produceDiagnostics) {
                if (!(node.flags & NodeFlags.YieldContext)) {
                    grammarErrorOnFirstToken(
                        node,
                        Diagnostics
                            .A_yield_expression_is_only_allowed_in_a_generator_body
                    );
                }

                if (isInParameterInitializerBeforeContainingFunction(node)) {
                    error(
                        node,
                        Diagnostics
                            .yield_expressions_cannot_be_used_in_a_parameter_initializer
                    );
                }
            }

            const func = getContainingFunction(node);
            if (!func) return anyType;
            const functionFlags = getFunctionFlags(func);

            if (!(functionFlags & FunctionFlags.Generator)) {
                // If the user's code is syntactically correct, the func should always have a star. After all, we are in a yield context.
                return anyType;
            }

            const isAsync = (functionFlags & FunctionFlags.Async) !== 0;
            if (node.asteriskToken) {
                // Async generator functions prior to ESNext require the __await, __asyncDelegator,
                // and __asyncValues helpers
                if (isAsync && languageVersion < ScriptTarget.ESNext) {
                    checkExternalEmitHelpers(
                        node,
                        ExternalEmitHelpers.AsyncDelegatorIncludes
                    );
                }

                // Generator functions prior to ES2015 require the __values helper
                if (!isAsync && languageVersion < ScriptTarget.ES2015
                    && compilerOptions.downlevelIteration)
                {
                    checkExternalEmitHelpers(node, ExternalEmitHelpers.Values);
                }
            }

            // There is no point in doing an assignability check if the function
            // has no explicit return type because the return type is directly computed
            // from the yield expressions.
            const returnType = getReturnTypeFromAnnotation(func);
            const iterationTypes = returnType
                && getIterationTypesOfGeneratorFunctionReturnType(
                    returnType,
                    isAsync
                );
            const signatureYieldType = iterationTypes
                && iterationTypes.yieldType || anyType;
            const signatureNextType = iterationTypes && iterationTypes.nextType
                || anyType;
            const resolvedSignatureNextType = isAsync
                ? getAwaitedType(signatureNextType) || anyType
                : signatureNextType;
            const yieldExpressionType = node.expression
                ? checkExpression(node.expression)
                : undefinedWideningType;
            const yieldedType = getYieldedTypeOfYieldExpression(
                node,
                yieldExpressionType,
                resolvedSignatureNextType,
                isAsync
            );
            if (returnType && yieldedType) {
                checkTypeAssignableToAndOptionallyElaborate(
                    yieldedType,
                    signatureYieldType,
                    node.expression || node,
                    node.expression
                );
            }

            if (node.asteriskToken) {
                const use = isAsync
                    ? IterationUse.AsyncYieldStar
                    : IterationUse.YieldStar;
                return getIterationTypeOfIterable(
                    use,
                    IterationTypeKind.Return,
                    yieldExpressionType,
                    node.expression
                )
                    || anyType;
            } else if (returnType) {
                return getIterationTypeOfGeneratorFunctionReturnType(
                    IterationTypeKind.Next,
                    returnType,
                    isAsync
                )
                    || anyType;
            }

            return getContextualIterationType(IterationTypeKind.Next, func)
                || anyType;
        }

        function checkConditionalExpression(
            node: ConditionalExpression,
            checkMode?: CheckMode
        ): Type {
            checkTruthinessExpression(node.condition);
            const type1 = checkExpression(node.whenTrue, checkMode);
            const type2 = checkExpression(node.whenFalse, checkMode);
            return getUnionType([type1, type2], UnionReduction.Subtype);
        }

        function checkTemplateExpression(node: TemplateExpression): Type {
            // We just want to check each expressions, but we are unconcerned with
            // the type of each expression, as any value may be coerced into a string.
            // It is worth asking whether this is what we really want though.
            // A place where we actually *are* concerned with the expressions' types are
            // in tagged templates.
            forEach(
                node.templateSpans,
                templateSpan => {
                    if (maybeTypeOfKind(
                        checkExpression(templateSpan.expression),
                        TypeFlags.ESSymbolLike
                    )) {
                        error(
                            templateSpan.expression,
                            Diagnostics
                                .Implicit_conversion_of_a_symbol_to_a_string_will_fail_at_runtime_Consider_wrapping_this_expression_in_String
                        );
                    }
                }
            );

            return stringType;
        }

        function getContextNode(node: Expression): Node {
            if (node.kind === SyntaxKind.JsxAttributes
                && !isJsxSelfClosingElement(node.parent))
            {
                return node.parent
                    .parent; // Needs to be the root JsxElement, so it encompasses the attributes _and_ the children (which are essentially part of the attributes)
            }
            return node;
        }

        function checkExpressionWithContextualType(
            node: Expression,
            contextualType: Type,
            inferenceContext: InferenceContext | undefined,
            checkMode: CheckMode
        ): Type {
            const context = getContextNode(node);
            const saveContextualType = context.contextualType;
            const saveInferenceContext = context.inferenceContext;
            context.contextualType = contextualType;
            context.inferenceContext = inferenceContext;
            const type = checkExpression(
                node,
                checkMode | CheckMode.Contextual
                    | (inferenceContext ? CheckMode.Inferential : 0)
            );
            // We strip literal freshness when an appropriate contextual type is present such that contextually typed
            // literals always preserve their literal types (otherwise they might widen during type inference). An alternative
            // here would be to not mark contextually typed literals as fresh in the first place.
            const result = maybeTypeOfKind(type, TypeFlags.Literal)
                && isLiteralOfContextualType(
                    type,
                    instantiateContextualType(contextualType, node)
                )
                ? getRegularTypeOfLiteralType(type)
                : type;
            context.contextualType = saveContextualType;
            context.inferenceContext = saveInferenceContext;
            return result;
        }

        function checkExpressionCached(
            node: Expression | QualifiedName,
            checkMode?: CheckMode
        ): Type {
            const links = getNodeLinks(node);
            if (!links.resolvedType) {
                if (checkMode && checkMode !== CheckMode.Normal) {
                    return checkExpression(node, checkMode);
                }
                // When computing a type that we're going to cache, we need to ignore any ongoing control flow
                // analysis because variables may have transient types in indeterminable states. Moving flowLoopStart
                // to the top of the stack ensures all transient types are computed from a known point.
                const saveFlowLoopStart = flowLoopStart;
                const saveFlowTypeCache = flowTypeCache;
                flowLoopStart = flowLoopCount;
                flowTypeCache = undefined;
                links.resolvedType = checkExpression(node, checkMode);
                flowTypeCache = saveFlowTypeCache;
                flowLoopStart = saveFlowLoopStart;
            }
            return links.resolvedType;
        }

        function isTypeAssertion(node: Expression) {
            node = skipParentheses(node);
            return node.kind === SyntaxKind.TypeAssertionExpression
                || node.kind === SyntaxKind.AsExpression;
        }

        function checkDeclarationInitializer(
            declaration: HasExpressionInitializer
        ) {
            const initializer = getEffectiveInitializer(declaration)!;
            const type = getQuickTypeOfExpression(initializer)
                || checkExpressionCached(initializer);
            const padded = isParameter(declaration)
                && declaration.name.kind === SyntaxKind.ArrayBindingPattern
                && isTupleType(type) && !type.target.hasRestElement
                && getTypeReferenceArity(type)
                < declaration.name.elements.length
                ? padTupleType(type, declaration.name)
                : type;
            const widened = getCombinedNodeFlags(declaration) & NodeFlags.Const
                || isDeclarationReadonly(declaration)
                || isTypeAssertion(initializer)
                || isLiteralOfContextualType(
                    padded,
                    getContextualType(initializer)
                )
                ? padded
                : getWidenedLiteralType(padded);
            if (isInJSFile(declaration)) {
                if (widened.flags & TypeFlags.Nullable) {
                    reportImplicitAny(declaration, anyType);
                    return anyType;
                } else if (isEmptyArrayLiteralType(widened)) {
                    reportImplicitAny(declaration, anyArrayType);
                    return anyArrayType;
                }
            }
            return widened;
        }

        function padTupleType(
            type: TupleTypeReference,
            pattern: ArrayBindingPattern
        ) {
            const patternElements = pattern.elements;
            const arity = getTypeReferenceArity(type);
            const elementTypes = arity ? getTypeArguments(type).slice() : [];
            for (let i = arity; i < patternElements.length; i++) {
                const e = patternElements[i];
                if (i < patternElements.length - 1
                    || !(e.kind === SyntaxKind.BindingElement
                        && e.dotDotDotToken))
                {
                    elementTypes
                        .push(
                            !isOmittedExpression(e) && hasDefaultValue(e)
                                ? getTypeFromBindingElement(
                                    e, /*includePatternInType*/
                                    false, /*reportErrors*/
                                    false
                                )
                                : anyType
                        );
                    if (!isOmittedExpression(e) && !hasDefaultValue(e)) {
                        reportImplicitAny(e, anyType);
                    }
                }
            }
            return createTupleType(
                elementTypes,
                type.target.minLength, /*hasRestElement*/
                false,
                type.target.readonly
            );
        }

        function isLiteralOfContextualType(
            candidateType: Type,
            contextualType: Type | undefined
        ): boolean {
            if (contextualType) {
                if (contextualType.flags & TypeFlags.UnionOrIntersection) {
                    const types = (<UnionType> contextualType).types;
                    return some(
                        types,
                        t => isLiteralOfContextualType(candidateType, t)
                    );
                }
                if (contextualType.flags
                    & TypeFlags.InstantiableNonPrimitive)
                {
                    // If the contextual type is a type variable constrained to a primitive type, consider
                    // this a literal context for literals of that primitive type. For example, given a
                    // type parameter 'T extends string', infer string literal types for T.
                    const constraint = getBaseConstraintOfType(contextualType)
                        || unknownType;
                    return maybeTypeOfKind(constraint, TypeFlags.String)
                        && maybeTypeOfKind(
                            candidateType,
                            TypeFlags.StringLiteral
                        )
                        || maybeTypeOfKind(constraint, TypeFlags.Number)
                        && maybeTypeOfKind(
                            candidateType,
                            TypeFlags.NumberLiteral
                        )
                        || maybeTypeOfKind(constraint, TypeFlags.BigInt)
                        && maybeTypeOfKind(
                            candidateType,
                            TypeFlags.BigIntLiteral
                        )
                        || maybeTypeOfKind(constraint, TypeFlags.ESSymbol)
                        && maybeTypeOfKind(
                            candidateType,
                            TypeFlags.UniqueESSymbol
                        )
                        || isLiteralOfContextualType(candidateType,
                            constraint);
                }
                // If the contextual type is a literal of a particular primitive type, we consider this a
                // literal context for all literals of that primitive type.
                return !!(contextualType.flags
                    & (TypeFlags.StringLiteral | TypeFlags.Index)
                    && maybeTypeOfKind(candidateType, TypeFlags.StringLiteral)
                    || contextualType.flags & TypeFlags.NumberLiteral
                    && maybeTypeOfKind(candidateType, TypeFlags.NumberLiteral)
                    || contextualType.flags & TypeFlags.BigIntLiteral
                    && maybeTypeOfKind(candidateType, TypeFlags.BigIntLiteral)
                    || contextualType.flags & TypeFlags.BooleanLiteral
                    && maybeTypeOfKind(candidateType, TypeFlags.BooleanLiteral)
                    || contextualType.flags & TypeFlags.UniqueESSymbol
                    && maybeTypeOfKind(candidateType,
                        TypeFlags.UniqueESSymbol));
            }
            return false;
        }

        function isConstContext(node: Expression): boolean {
            const parent = node.parent;
            return isAssertionExpression(parent)
                && isConstTypeReference(parent.type)
                || (isParenthesizedExpression(parent)
                    || isArrayLiteralExpression(parent)
                    || isSpreadElement(parent)) && isConstContext(parent)
                || (isPropertyAssignment(parent)
                    || isShorthandPropertyAssignment(parent))
                && isConstContext(parent.parent);
        }

        function checkExpressionForMutableLocation(
            node: Expression,
            checkMode: CheckMode | undefined,
            contextualType?: Type,
            forceTuple?: boolean
        ): Type {
            const type = checkExpression(node, checkMode, forceTuple);
            return isConstContext(node)
                ? getRegularTypeOfLiteralType(type)
                : isTypeAssertion(node)
                    ? type
                    : getWidenedLiteralLikeTypeForContextualType(
                        type,
                        instantiateContextualType(
                            arguments.length === 2
                                ? getContextualType(node)
                                : contextualType,
                            node
                        )
                    );
        }

        function checkPropertyAssignment(
            node: PropertyAssignment,
            checkMode?: CheckMode
        ): Type {
            // Do not use hasDynamicName here, because that returns false for well known symbols.
            // We want to perform checkComputedPropertyName for all computed properties, including
            // well known symbols.
            if (node.name.kind === SyntaxKind.ComputedPropertyName) {
                checkComputedPropertyName(node.name);
            }

            return checkExpressionForMutableLocation(
                node.initializer,
                checkMode
            );
        }

        function checkObjectLiteralMethod(
            node: MethodDeclaration,
            checkMode?: CheckMode
        ): Type {
            // Grammar checking
            checkGrammarMethod(node);

            // Do not use hasDynamicName here, because that returns false for well known symbols.
            // We want to perform checkComputedPropertyName for all computed properties, including
            // well known symbols.
            if (node.name.kind === SyntaxKind.ComputedPropertyName) {
                checkComputedPropertyName(node.name);
            }

            const uninstantiatedType = checkFunctionExpressionOrObjectLiteralMethod(
                node,
                checkMode
            );
            return instantiateTypeWithSingleGenericCallSignature(
                node,
                uninstantiatedType,
                checkMode
            );
        }

        function instantiateTypeWithSingleGenericCallSignature(
            node: Expression | MethodDeclaration | QualifiedName,
            type: Type,
            checkMode?: CheckMode
        ) {
            if (checkMode
                && checkMode
                & (CheckMode.Inferential | CheckMode.SkipGenericFunctions))
            {
                const callSignature = getSingleSignature(
                    type,
                    SignatureKind.Call, /*allowMembers*/
                    true
                );
                const constructSignature = getSingleSignature(
                    type,
                    SignatureKind.Construct, /*allowMembers*/
                    true
                );
                const signature = callSignature || constructSignature;
                if (signature && signature.typeParameters) {
                    const contextualType = getApparentTypeOfContextualType(
                        <Expression> node,
                        ContextFlags.NoConstraints
                    );
                    if (contextualType) {
                        const contextualSignature = getSingleSignature(
                            getNonNullableType(contextualType),
                            callSignature
                                ? SignatureKind.Call
                                : SignatureKind.Construct, /*allowMembers*/
                            false
                        );
                        if (contextualSignature
                            && !contextualSignature.typeParameters)
                        {
                            if (checkMode & CheckMode.SkipGenericFunctions) {
                                skippedGenericFunction(node, checkMode);
                                return anyFunctionType;
                            }
                            const context = getInferenceContext(node)!;
                            // We have an expression that is an argument of a generic function for which we are performing
                            // type argument inference. The expression is of a function type with a single generic call
                            // signature and a contextual function type with a single non-generic call signature. Now check
                            // if the outer function returns a function type with a single non-generic call signature and
                            // if some of the outer function type parameters have no inferences so far. If so, we can
                            // potentially add inferred type parameters to the outer function return type.
                            const returnType = context.signature
                                && getReturnTypeOfSignature(context.signature);
                            const returnSignature = returnType
                                && getSingleCallOrConstructSignature(returnType);
                            if (returnSignature
                                && !returnSignature.typeParameters
                                && !every(
                                    context.inferences,
                                    hasInferenceCandidates
                                ))
                            {
                                // Instantiate the signature with its own type parameters as type arguments, possibly
                                // renaming the type parameters to ensure they have unique names.
                                const uniqueTypeParameters = getUniqueTypeParameters(
                                    context,
                                    signature.typeParameters
                                );
                                const instantiatedSignature = getSignatureInstantiationWithoutFillingInTypeArguments(
                                    signature,
                                    uniqueTypeParameters
                                );
                                // Infer from the parameters of the instantiated signature to the parameters of the
                                // contextual signature starting with an empty set of inference candidates.
                                const inferences = map(
                                    context.inferences,
                                    info => createInferenceInfo(
                                        info.typeParameter
                                    )
                                );
                                applyToParameterTypes(
                                    instantiatedSignature,
                                    contextualSignature,
                                    (source, target) => {
                                        inferTypes(
                                            inferences,
                                            source,
                                            target, /*priority*/
                                            0, /*contravariant*/
                                            true
                                        );
                                    }
                                );
                                if (some(inferences, hasInferenceCandidates)) {
                                    // We have inference candidates, indicating that one or more type parameters are referenced
                                    // in the parameter types of the contextual signature. Now also infer from the return type.
                                    applyToReturnTypes(
                                        instantiatedSignature,
                                        contextualSignature,
                                        (source, target) => {
                                            inferTypes(
                                                inferences,
                                                source,
                                                target
                                            );
                                        }
                                    );
                                    // If the type parameters for which we produced candidates do not have any inferences yet,
                                    // we adopt the new inference candidates and add the type parameters of the expression type
                                    // to the set of inferred type parameters for the outer function return type.
                                    if (!hasOverlappingInferences(
                                        context.inferences,
                                        inferences
                                    )) {
                                        mergeInferences(
                                            context.inferences,
                                            inferences
                                        );
                                        context
                                            .inferredTypeParameters = concatenate(
                                                context.inferredTypeParameters,
                                                uniqueTypeParameters
                                            );
                                        return getOrCreateTypeFromSignature(instantiatedSignature);
                                    }
                                }
                            }
                            return getOrCreateTypeFromSignature(
                                instantiateSignatureInContextOf(
                                    signature,
                                    contextualSignature,
                                    context
                                )
                            );
                        }
                    }
                }
            }
            return type;
        }

        function skippedGenericFunction(node: Node, checkMode: CheckMode) {
            if (checkMode & CheckMode.Inferential) {
                // We have skipped a generic function during inferential typing. Obtain the inference context and
                // indicate this has occurred such that we know a second pass of inference is be needed.
                const context = getInferenceContext(node)!;
                context.flags |= InferenceFlags.SkippedGenericFunction;
            }
        }

        function hasInferenceCandidates(info: InferenceInfo) {
            return !!(info.candidates || info.contraCandidates);
        }

        function hasOverlappingInferences(
            a: InferenceInfo[],
            b: InferenceInfo[]
        ) {
            for (let i = 0; i < a.length; i++) {
                if (hasInferenceCandidates(a[i])
                    && hasInferenceCandidates(b[i]))
                {
                    return true;
                }
            }
            return false;
        }

        function mergeInferences(
            target: InferenceInfo[],
            source: InferenceInfo[]
        ) {
            for (let i = 0; i < target.length; i++) {
                if (!hasInferenceCandidates(target[i])
                    && hasInferenceCandidates(source[i]))
                {
                    target[i] = source[i];
                }
            }
        }

        function getUniqueTypeParameters(
            context: InferenceContext,
            typeParameters: readonly TypeParameter[]
        ): readonly TypeParameter[] {
            const result: TypeParameter[] = [];
            let oldTypeParameters: TypeParameter[] | undefined;
            let newTypeParameters: TypeParameter[] | undefined;
            for (const tp of typeParameters) {
                const name = tp.symbol.escapedName;
                if (hasTypeParameterByName(
                    context.inferredTypeParameters,
                    name
                ) || hasTypeParameterByName(result, name)) {
                    const newName = getUniqueTypeParameterName(
                        concatenate(
                            context.inferredTypeParameters,
                            result
                        ),
                        name
                    );
                    const symbol = createSymbol(
                        SymbolFlags.TypeParameter,
                        newName
                    );
                    const newTypeParameter = createTypeParameter(symbol);
                    newTypeParameter.target = tp;
                    oldTypeParameters = append(oldTypeParameters, tp);
                    newTypeParameters = append(
                        newTypeParameters,
                        newTypeParameter
                    );
                    result.push(newTypeParameter);
                } else {
                    result.push(tp);
                }
            }
            if (newTypeParameters) {
                const mapper = createTypeMapper(
                    oldTypeParameters!,
                    newTypeParameters
                );
                for (const tp of newTypeParameters) {
                    tp.mapper = mapper;
                }
            }
            return result;
        }

        function hasTypeParameterByName(
            typeParameters: readonly TypeParameter[] | undefined,
            name: __String
        ) {
            return some(typeParameters, tp => tp.symbol.escapedName === name);
        }

        function getUniqueTypeParameterName(
            typeParameters: readonly TypeParameter[],
            baseName: __String
        ) {
            let len = (<string> baseName).length;
            while (len > 1
                && (<string> baseName).charCodeAt(len - 1) >= CharacterCodes._0
                && (<string> baseName).charCodeAt(len - 1)
                <= CharacterCodes._9)
            {
                len--;
            }
            const s = (<string> baseName).slice(0, len);
            for (let index = 1; true; index++) {
                const augmentedName = <__String> (s + index);
                if (!hasTypeParameterByName(typeParameters, augmentedName)) {
                    return augmentedName;
                }
            }
        }

        function getReturnTypeOfSingleNonGenericCallSignature(funcType: Type) {
            const signature = getSingleCallSignature(funcType);
            if (signature && !signature.typeParameters) {
                return getReturnTypeOfSignature(signature);
            }
        }

        function getReturnTypeOfSingleNonGenericSignatureOfCallChain(
            expr: CallChain
        ) {
            const funcType = checkExpression(expr.expression);
            const nonOptionalType = getOptionalExpressionType(
                funcType,
                expr.expression
            );
            const returnType = getReturnTypeOfSingleNonGenericCallSignature(funcType);
            return returnType
                && propagateOptionalTypeMarker(
                    returnType,
                    expr,
                    nonOptionalType !== funcType
                );
        }

        /**
         * Returns the type of an expression. Unlike checkExpression, this function is simply concerned
         * with computing the type and may not fully check all contained sub-expressions for errors.
         */
        function getTypeOfExpression(node: Expression) {
            // Don't bother caching types that require no flow analysis and are quick to compute.
            const quickType = getQuickTypeOfExpression(node);
            if (quickType) {
                return quickType;
            }
            // If a type has been cached for the node, return it.
            if (node.flags & NodeFlags.TypeCached && flowTypeCache) {
                const cachedType = flowTypeCache[getNodeId(node)];
                if (cachedType) {
                    return cachedType;
                }
            }
            const startInvocationCount = flowInvocationCount;
            const type = checkExpression(node);
            // If control flow analysis was required to determine the type, it is worth caching.
            if (flowInvocationCount !== startInvocationCount) {
                const cache = flowTypeCache || (flowTypeCache = []);
                cache[getNodeId(node)] = type;
                node.flags |= NodeFlags.TypeCached;
            }
            return type;
        }

        function getQuickTypeOfExpression(node: Expression) {
            const expr = skipParentheses(node);
            // Optimize for the common case of a call to a function with a single non-generic call
            // signature where we can just fetch the return type without checking the arguments.
            if (isCallExpression(expr)
                && expr.expression.kind !== SyntaxKind.SuperKeyword
                && !isRequireCall(
                    expr, /*checkArgumentIsStringLiteralLike*/
                    true
                ) && !isSymbolOrSymbolForCall(expr))
            {
                const type = isCallChain(expr)
                    ? getReturnTypeOfSingleNonGenericSignatureOfCallChain(expr)
                    : getReturnTypeOfSingleNonGenericCallSignature(
                        checkNonNullExpression(
                            expr.expression
                        )
                    );
                if (type) {
                    return type;
                }
            } else if (isAssertionExpression(expr)
                && !isConstTypeReference(expr.type))
            {
                return getTypeFromTypeNode((<TypeAssertion> expr).type);
            } else if (node.kind === SyntaxKind.NumericLiteral
                || node.kind === SyntaxKind.StringLiteral
                || node.kind === SyntaxKind.TrueKeyword
                || node.kind === SyntaxKind.FalseKeyword)
            {
                return checkExpression(node);
            }
            return undefined;
        }

        /**
         * Returns the type of an expression. Unlike checkExpression, this function is simply concerned
         * with computing the type and may not fully check all contained sub-expressions for errors.
         * It is intended for uses where you know there is no contextual type,
         * and requesting the contextual type might cause a circularity or other bad behaviour.
         * It sets the contextual type of the node to any before calling getTypeOfExpression.
         */
        function getContextFreeTypeOfExpression(node: Expression) {
            const links = getNodeLinks(node);
            if (links.contextFreeType) {
                return links.contextFreeType;
            }
            const saveContextualType = node.contextualType;
            node.contextualType = anyType;
            const type = links.contextFreeType = checkExpression(
                node,
                CheckMode.SkipContextSensitive
            );
            node.contextualType = saveContextualType;
            return type;
        }

        function checkExpression(
            node: Expression | QualifiedName,
            checkMode?: CheckMode,
            forceTuple?: boolean
        ): Type {
            const saveCurrentNode = currentNode;
            currentNode = node;
            instantiationCount = 0;
            const uninstantiatedType = checkExpressionWorker(
                node,
                checkMode,
                forceTuple
            );
            const type = instantiateTypeWithSingleGenericCallSignature(
                node,
                uninstantiatedType,
                checkMode
            );
            if (isConstEnumObjectType(type)) {
                checkConstEnumAccess(node, type);
            }
            currentNode = saveCurrentNode;
            return type;
        }

        function checkConstEnumAccess(
            node: Expression | QualifiedName,
            type: Type
        ) {
            // enum object type for const enums are only permitted in:
            // - 'left' in property access
            // - 'object' in indexed access
            // - target in rhs of import statement
            const ok = (node.parent.kind
                === SyntaxKind.PropertyAccessExpression
                && (<PropertyAccessExpression> node.parent).expression
                === node)
                || (node.parent.kind === SyntaxKind.ElementAccessExpression
                    && (<ElementAccessExpression> node.parent).expression
                    === node)
                || ((node.kind === SyntaxKind.Identifier
                    || node.kind === SyntaxKind.QualifiedName)
                    && isInRightSideOfImportOrExportAssignment(<Identifier> node)
                    || (node.parent.kind === SyntaxKind.TypeQuery
                        && (<TypeQueryNode> node.parent).exprName === node))
                || (node.parent.kind
                    === SyntaxKind
                        .ExportSpecifier); // We allow reexporting const enums

            if (!ok) {
                error(
                    node,
                    Diagnostics
                        .const_enums_can_only_be_used_in_property_or_index_access_expressions_or_the_right_hand_side_of_an_import_declaration_or_export_assignment_or_type_query
                );
            }

            if (compilerOptions.isolatedModules) {
                Debug.assert(!!(type.symbol.flags & SymbolFlags.ConstEnum));
                const constEnumDeclaration = type.symbol
                    .valueDeclaration as EnumDeclaration;
                if (constEnumDeclaration.flags & NodeFlags.Ambient) {
                    error(
                        node,
                        Diagnostics
                            .Cannot_access_ambient_const_enums_when_the_isolatedModules_flag_is_provided
                    );
                }
            }
        }

        function checkParenthesizedExpression(
            node: ParenthesizedExpression,
            checkMode?: CheckMode
        ): Type {
            const tag = isInJSFile(node) ? getJSDocTypeTag(node) : undefined;
            if (tag) {
                return checkAssertionWorker(
                    tag,
                    tag.typeExpression.type,
                    node.expression,
                    checkMode
                );
            }
            return checkExpression(node.expression, checkMode);
        }

        function checkExpressionWorker(
            node: Expression | QualifiedName,
            checkMode: CheckMode | undefined,
            forceTuple?: boolean
        ): Type {
            const kind = node.kind;
            if (cancellationToken) {
                // Only bother checking on a few construct kinds.  We don't want to be excessively
                // hitting the cancellation token on every node we check.
                switch (kind) {
                    case SyntaxKind.ClassExpression:
                    case SyntaxKind.FunctionExpression:
                    case SyntaxKind.ArrowFunction:
                        cancellationToken.throwIfCancellationRequested();
                }
            }
            switch (kind) {
                case SyntaxKind.Identifier:
                    return checkIdentifier(<Identifier> node);
                case SyntaxKind.ThisKeyword:
                    return checkThisExpression(node);
                case SyntaxKind.SuperKeyword:
                    return checkSuperExpression(node);
                case SyntaxKind.NullKeyword:
                    return nullWideningType;
                case SyntaxKind.NoSubstitutionTemplateLiteral:
                case SyntaxKind.StringLiteral:
                    return getFreshTypeOfLiteralType(
                        getLiteralType(
                            (node as StringLiteralLike).text
                        )
                    );
                case SyntaxKind.NumericLiteral:
                    checkGrammarNumericLiteral(node as NumericLiteral);
                    return getFreshTypeOfLiteralType(
                        getLiteralType(
                            +(node as NumericLiteral).text
                        )
                    );
                case SyntaxKind.BigIntLiteral:
                    checkGrammarBigIntLiteral(node as BigIntLiteral);
                    return getFreshTypeOfLiteralType(getBigIntLiteralType(node as BigIntLiteral));
                case SyntaxKind.TrueKeyword:
                    return trueType;
                case SyntaxKind.FalseKeyword:
                    return falseType;
                case SyntaxKind.TemplateExpression:
                    return checkTemplateExpression(<TemplateExpression> node);
                case SyntaxKind.RegularExpressionLiteral:
                    return globalRegExpType;
                case SyntaxKind.ArrayLiteralExpression:
                    return checkArrayLiteral(
                        <ArrayLiteralExpression> node,
                        checkMode,
                        forceTuple
                    );
                case SyntaxKind.ObjectLiteralExpression:
                    return checkObjectLiteral(
                        <ObjectLiteralExpression> node,
                        checkMode
                    );
                case SyntaxKind.PropertyAccessExpression:
                    return checkPropertyAccessExpression(<PropertyAccessExpression> node);
                case SyntaxKind.QualifiedName:
                    return checkQualifiedName(<QualifiedName> node);
                case SyntaxKind.ElementAccessExpression:
                    return checkIndexedAccess(<ElementAccessExpression> node);
                case SyntaxKind.CallExpression:
                    if ((<CallExpression> node).expression.kind
                        === SyntaxKind.ImportKeyword)
                    {
                        return checkImportCallExpression(<ImportCall> node);
                    }
                    // falls through
                case SyntaxKind.NewExpression:
                    return checkCallExpression(
                        <CallExpression> node,
                        checkMode
                    );
                case SyntaxKind.TaggedTemplateExpression:
                    return checkTaggedTemplateExpression(<TaggedTemplateExpression> node);
                case SyntaxKind.ParenthesizedExpression:
                    return checkParenthesizedExpression(
                        <ParenthesizedExpression> node,
                        checkMode
                    );
                case SyntaxKind.ClassExpression:
                    return checkClassExpression(<ClassExpression> node);
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.ArrowFunction:
                    return checkFunctionExpressionOrObjectLiteralMethod(
                        <FunctionExpression> node,
                        checkMode
                    );
                case SyntaxKind.TypeOfExpression:
                    return checkTypeOfExpression(<TypeOfExpression> node);
                case SyntaxKind.TypeAssertionExpression:
                case SyntaxKind.AsExpression:
                    return checkAssertion(<AssertionExpression> node);
                case SyntaxKind.NonNullExpression:
                    return checkNonNullAssertion(<NonNullExpression> node);
                case SyntaxKind.MetaProperty:
                    return checkMetaProperty(<MetaProperty> node);
                case SyntaxKind.DeleteExpression:
                    return checkDeleteExpression(<DeleteExpression> node);
                case SyntaxKind.VoidExpression:
                    return checkVoidExpression(<VoidExpression> node);
                case SyntaxKind.AwaitExpression:
                    return checkAwaitExpression(<AwaitExpression> node);
                case SyntaxKind.PrefixUnaryExpression:
                    return checkPrefixUnaryExpression(<PrefixUnaryExpression> node);
                case SyntaxKind.PostfixUnaryExpression:
                    return checkPostfixUnaryExpression(<PostfixUnaryExpression> node);
                case SyntaxKind.BinaryExpression:
                    return checkBinaryExpression(
                        <BinaryExpression> node,
                        checkMode
                    );
                case SyntaxKind.ConditionalExpression:
                    return checkConditionalExpression(
                        <ConditionalExpression> node,
                        checkMode
                    );
                case SyntaxKind.SpreadElement:
                    return checkSpreadExpression(
                        <SpreadElement> node,
                        checkMode
                    );
                case SyntaxKind.OmittedExpression:
                    return undefinedWideningType;
                case SyntaxKind.YieldExpression:
                    return checkYieldExpression(<YieldExpression> node);
                case SyntaxKind.SyntheticExpression:
                    return (<SyntheticExpression> node).type;
                case SyntaxKind.JsxExpression:
                    return checkJsxExpression(<JsxExpression> node, checkMode);
                case SyntaxKind.JsxElement:
                    return checkJsxElement(<JsxElement> node, checkMode);
                case SyntaxKind.JsxSelfClosingElement:
                    return checkJsxSelfClosingElement(
                        <JsxSelfClosingElement> node,
                        checkMode
                    );
                case SyntaxKind.JsxFragment:
                    return checkJsxFragment(<JsxFragment> node);
                case SyntaxKind.JsxAttributes:
                    return checkJsxAttributes(<JsxAttributes> node, checkMode);
                case SyntaxKind.JsxOpeningElement:
                    Debug
                        .fail('Shouldn\'t ever directly check a JsxOpeningElement');
            }
            return errorType;
        }

        // DECLARATION AND STATEMENT TYPE CHECKING

        function checkTypeParameter(node: TypeParameterDeclaration) {
            // Grammar Checking
            if (node.expression) {
                grammarErrorOnFirstToken(
                    node.expression,
                    Diagnostics.Type_expected
                );
            }

            checkSourceElement(node.constraint);
            checkSourceElement(node.default);
            const typeParameter = getDeclaredTypeOfTypeParameter(getSymbolOfNode(node));
            // Resolve base constraint to reveal circularity errors
            getBaseConstraintOfType(typeParameter);
            if (!hasNonCircularTypeParameterDefault(typeParameter)) {
                error(
                    node.default,
                    Diagnostics.Type_parameter_0_has_a_circular_default,
                    typeToString(typeParameter)
                );
            }
            const constraintType = getConstraintOfTypeParameter(typeParameter);
            const defaultType = getDefaultFromTypeParameter(typeParameter);
            if (constraintType && defaultType) {
                checkTypeAssignableTo(
                    defaultType,
                    getTypeWithThisArgument(
                        instantiateType(
                            constraintType,
                            makeUnaryTypeMapper(typeParameter, defaultType)
                        ),
                        defaultType
                    ),
                    node.default,
                    Diagnostics.Type_0_does_not_satisfy_the_constraint_1
                );
            }
            if (produceDiagnostics) {
                checkTypeNameIsReserved(
                    node.name,
                    Diagnostics.Type_parameter_name_cannot_be_0
                );
            }
        }

        function checkParameter(node: ParameterDeclaration) {
            // Grammar checking
            // It is a SyntaxError if the Identifier "eval" or the Identifier "arguments" occurs as the
            // Identifier in a PropertySetParameterList of a PropertyAssignment that is contained in strict code
            // or if its FunctionBody is strict code(11.1.5).
            checkGrammarDecoratorsAndModifiers(node);

            checkVariableLikeDeclaration(node);
            const func = getContainingFunction(node)!;
            if (hasModifier(node, ModifierFlags.ParameterPropertyModifier)) {
                if (!(func.kind === SyntaxKind.Constructor
                    && nodeIsPresent(func.body)))
                {
                    error(
                        node,
                        Diagnostics
                            .A_parameter_property_is_only_allowed_in_a_constructor_implementation
                    );
                }
            }
            if (node.questionToken && isBindingPattern(node.name)
                && (func as FunctionLikeDeclaration).body)
            {
                error(
                    node,
                    Diagnostics
                        .A_binding_pattern_parameter_cannot_be_optional_in_an_implementation_signature
                );
            }
            if (node.name && isIdentifier(node.name)
                && (node.name.escapedText === 'this'
                    || node.name.escapedText === 'new'))
            {
                if (func.parameters.indexOf(node) !== 0) {
                    error(
                        node,
                        Diagnostics.A_0_parameter_must_be_the_first_parameter,
                        node.name.escapedText as string
                    );
                }
                if (func.kind === SyntaxKind.Constructor
                    || func.kind === SyntaxKind.ConstructSignature
                    || func.kind === SyntaxKind.ConstructorType)
                {
                    error(
                        node,
                        Diagnostics.A_constructor_cannot_have_a_this_parameter
                    );
                }
                if (func.kind === SyntaxKind.ArrowFunction) {
                    error(
                        node,
                        Diagnostics
                            .An_arrow_function_cannot_have_a_this_parameter
                    );
                }
            }

            // Only check rest parameter type if it's not a binding pattern. Since binding patterns are
            // not allowed in a rest parameter, we already have an error from checkGrammarParameterList.
            if (node.dotDotDotToken && !isBindingPattern(node.name)
                && !isTypeAssignableTo(
                    getTypeOfSymbol(node.symbol),
                    anyReadonlyArrayType
                ))
            {
                error(
                    node,
                    Diagnostics.A_rest_parameter_must_be_of_an_array_type
                );
            }
        }

        function checkTypePredicate(node: TypePredicateNode): void {
            const parent = getTypePredicateParent(node);
            if (!parent) {
                // The parent must not be valid.
                error(
                    node,
                    Diagnostics
                        .A_type_predicate_is_only_allowed_in_return_type_position_for_functions_and_methods
                );
                return;
            }

            const signature = getSignatureFromDeclaration(parent);
            const typePredicate = getTypePredicateOfSignature(signature);
            if (!typePredicate) {
                return;
            }

            checkSourceElement(node.type);

            const { parameterName } = node;
            if (typePredicate.kind === TypePredicateKind.This
                || typePredicate.kind === TypePredicateKind.AssertsThis)
            {
                getTypeFromThisTypeNode(parameterName as ThisTypeNode);
            } else {
                if (typePredicate.parameterIndex >= 0) {
                    if (signatureHasRestParameter(signature)
                        && typePredicate.parameterIndex
                        === signature.parameters.length - 1)
                    {
                        error(
                            parameterName,
                            Diagnostics
                                .A_type_predicate_cannot_reference_a_rest_parameter
                        );
                    } else {
                        if (typePredicate.type) {
                            const leadingError = () => chainDiagnosticMessages(
                                /*details*/ undefined,
                                Diagnostics
                                    .A_type_predicate_s_type_must_be_assignable_to_its_parameter_s_type
                            );
                            checkTypeAssignableTo(
                                typePredicate.type,
                                getTypeOfSymbol(
                                    signature.parameters[typePredicate
                                        .parameterIndex]
                                ),
                                node.type,
                                /*headMessage*/ undefined,
                                leadingError
                            );
                        }
                    }
                } else if (parameterName) {
                    let hasReportedError = false;
                    for (const { name } of parent.parameters) {
                        if (isBindingPattern(name)
                            && checkIfTypePredicateVariableIsDeclaredInBindingPattern(
                                name,
                                parameterName,
                                typePredicate.parameterName
                            ))
                        {
                            hasReportedError = true;
                            break;
                        }
                    }
                    if (!hasReportedError) {
                        error(
                            node.parameterName,
                            Diagnostics.Cannot_find_parameter_0,
                            typePredicate.parameterName
                        );
                    }
                }
            }
        }

        function getTypePredicateParent(
            node: Node
        ): SignatureDeclaration | undefined {
            switch (node.parent.kind) {
                case SyntaxKind.ArrowFunction:
                case SyntaxKind.CallSignature:
                case SyntaxKind.FunctionDeclaration:
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.FunctionType:
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.MethodSignature:
                    const parent = <SignatureDeclaration> node.parent;
                    if (node === parent.type) {
                        return parent;
                    }
            }
        }

        function checkIfTypePredicateVariableIsDeclaredInBindingPattern(
            pattern: BindingPattern,
            predicateVariableNode: Node,
            predicateVariableName: string
        ) {
            for (const element of pattern.elements) {
                if (isOmittedExpression(element)) {
                    continue;
                }

                const name = element.name;
                if (name.kind === SyntaxKind.Identifier
                    && name.escapedText === predicateVariableName)
                {
                    error(
                        predicateVariableNode,
                        Diagnostics
                            .A_type_predicate_cannot_reference_element_0_in_a_binding_pattern,
                        predicateVariableName
                    );
                    return true;
                } else if (name.kind === SyntaxKind.ArrayBindingPattern
                    || name.kind === SyntaxKind.ObjectBindingPattern)
                {
                    if (checkIfTypePredicateVariableIsDeclaredInBindingPattern(
                        name,
                        predicateVariableNode,
                        predicateVariableName
                    )) {
                        return true;
                    }
                }
            }
        }

        function checkSignatureDeclaration(node: SignatureDeclaration) {
            // Grammar checking
            if (node.kind === SyntaxKind.IndexSignature) {
                checkGrammarIndexSignature(<SignatureDeclaration> node);
            } // TODO (yuisu): Remove this check in else-if when SyntaxKind.Construct is moved and ambient context is handled
            else if (node.kind === SyntaxKind.FunctionType
                || node.kind === SyntaxKind.FunctionDeclaration
                || node.kind === SyntaxKind.ConstructorType
                || node.kind === SyntaxKind.CallSignature
                || node.kind === SyntaxKind.Constructor
                || node.kind === SyntaxKind.ConstructSignature)
            {
                checkGrammarFunctionLikeDeclaration(<FunctionLikeDeclaration> node);
            }

            const functionFlags = getFunctionFlags(<FunctionLikeDeclaration> node);
            if (!(functionFlags & FunctionFlags.Invalid)) {
                // Async generators prior to ESNext require the __await and __asyncGenerator helpers
                if ((functionFlags & FunctionFlags.AsyncGenerator)
                    === FunctionFlags.AsyncGenerator
                    && languageVersion < ScriptTarget.ESNext)
                {
                    checkExternalEmitHelpers(
                        node,
                        ExternalEmitHelpers.AsyncGeneratorIncludes
                    );
                }

                // Async functions prior to ES2017 require the __awaiter helper
                if ((functionFlags & FunctionFlags.AsyncGenerator)
                    === FunctionFlags.Async
                    && languageVersion < ScriptTarget.ES2017)
                {
                    checkExternalEmitHelpers(node,
                        ExternalEmitHelpers.Awaiter);
                }

                // Generator functions, Async functions, and Async Generator functions prior to
                // ES2015 require the __generator helper
                if ((functionFlags & FunctionFlags.AsyncGenerator)
                    !== FunctionFlags.Normal
                    && languageVersion < ScriptTarget.ES2015)
                {
                    checkExternalEmitHelpers(
                        node,
                        ExternalEmitHelpers.Generator
                    );
                }
            }

            checkTypeParameters(node.typeParameters);

            forEach(node.parameters, checkParameter);

            // TODO(rbuckton): Should we start checking JSDoc types?
            if (node.type) {
                checkSourceElement(node.type);
            }

            if (produceDiagnostics) {
                checkCollisionWithArgumentsInGeneratedCode(node);
                const returnTypeNode = getEffectiveReturnTypeNode(node);
                if (noImplicitAny && !returnTypeNode) {
                    switch (node.kind) {
                        case SyntaxKind.ConstructSignature:
                            error(
                                node,
                                Diagnostics
                                    .Construct_signature_which_lacks_return_type_annotation_implicitly_has_an_any_return_type
                            );
                            break;
                        case SyntaxKind.CallSignature:
                            error(
                                node,
                                Diagnostics
                                    .Call_signature_which_lacks_return_type_annotation_implicitly_has_an_any_return_type
                            );
                            break;
                    }
                }

                if (returnTypeNode) {
                    const functionFlags = getFunctionFlags(<FunctionDeclaration> node);
                    if ((functionFlags
                        & (FunctionFlags.Invalid | FunctionFlags.Generator))
                        === FunctionFlags.Generator)
                    {
                        const returnType = getTypeFromTypeNode(returnTypeNode);
                        if (returnType === voidType) {
                            error(
                                returnTypeNode,
                                Diagnostics
                                    .A_generator_cannot_have_a_void_type_annotation
                            );
                        } else {
                            // Naively, one could check that Generator<any, any, any> is assignable to the return type annotation.
                            // However, that would not catch the error in the following case.
                            //
                            //    interface BadGenerator extends Iterable<number>, Iterator<string> { }
                            //    function* g(): BadGenerator { } // Iterable and Iterator have different types!
                            //
                            const generatorYieldType = getIterationTypeOfGeneratorFunctionReturnType(
                                IterationTypeKind.Yield,
                                returnType,
                                (functionFlags & FunctionFlags.Async) !== 0
                            ) || anyType;
                            const generatorReturnType = getIterationTypeOfGeneratorFunctionReturnType(
                                IterationTypeKind.Return,
                                returnType,
                                (functionFlags & FunctionFlags.Async) !== 0
                            ) || generatorYieldType;
                            const generatorNextType = getIterationTypeOfGeneratorFunctionReturnType(
                                IterationTypeKind.Next,
                                returnType,
                                (functionFlags & FunctionFlags.Async) !== 0
                            ) || unknownType;
                            const generatorInstantiation = createGeneratorReturnType(
                                generatorYieldType,
                                generatorReturnType,
                                generatorNextType,
                                !!(functionFlags & FunctionFlags.Async)
                            );
                            checkTypeAssignableTo(
                                generatorInstantiation,
                                returnType,
                                returnTypeNode
                            );
                        }
                    } else if ((functionFlags & FunctionFlags.AsyncGenerator)
                        === FunctionFlags.Async)
                    {
                        checkAsyncFunctionReturnType(
                            <FunctionLikeDeclaration> node,
                            returnTypeNode
                        );
                    }
                }
                if (node.kind !== SyntaxKind.IndexSignature
                    && node.kind !== SyntaxKind.JSDocFunctionType)
                {
                    registerForUnusedIdentifiersCheck(node);
                }
            }
        }

        function checkClassForDuplicateDeclarations(node:
            ClassLikeDeclaration)
        {
            const instanceNames = createUnderscoreEscapedMap<DeclarationMeaning>();
            const staticNames = createUnderscoreEscapedMap<DeclarationMeaning>();
            // instance and static private identifiers share the same scope
            const privateIdentifiers = createUnderscoreEscapedMap<DeclarationMeaning>();
            for (const member of node.members) {
                if (member.kind === SyntaxKind.Constructor) {
                    for (const param of (member as ConstructorDeclaration)
                        .parameters)
                    {
                        if (isParameterPropertyDeclaration(param, member)
                            && !isBindingPattern(param.name))
                        {
                            addName(
                                instanceNames,
                                param.name,
                                param.name.escapedText,
                                DeclarationMeaning.GetOrSetAccessor
                            );
                        }
                    }
                } else {
                    const isStatic = hasModifier(member, ModifierFlags.Static);
                    const name = member.name;
                    if (!name) {
                        return;
                    }
                    const names = isPrivateIdentifier(name)
                        ? privateIdentifiers
                        : isStatic
                            ? staticNames
                            : instanceNames;
                    const memberName = name
                        && getPropertyNameForPropertyNameNode(name);
                    if (memberName) {
                        switch (member.kind) {
                            case SyntaxKind.GetAccessor:
                                addName(
                                    names,
                                    name,
                                    memberName,
                                    DeclarationMeaning.GetAccessor
                                );
                                break;
                            case SyntaxKind.SetAccessor:
                                addName(
                                    names,
                                    name,
                                    memberName,
                                    DeclarationMeaning.SetAccessor
                                );
                                break;
                            case SyntaxKind.PropertyDeclaration:
                                addName(
                                    names,
                                    name,
                                    memberName,
                                    DeclarationMeaning.GetOrSetAccessor
                                );
                                break;
                            case SyntaxKind.MethodDeclaration:
                                addName(
                                    names,
                                    name,
                                    memberName,
                                    DeclarationMeaning.Method
                                );
                                break;
                        }
                    }
                }
            }

            function addName(
                names: UnderscoreEscapedMap<DeclarationMeaning>,
                location: Node,
                name: __String,
                meaning: DeclarationMeaning
            ) {
                const prev = names.get(name);
                if (prev) {
                    if (prev & DeclarationMeaning.Method) {
                        if (meaning !== DeclarationMeaning.Method) {
                            error(
                                location,
                                Diagnostics.Duplicate_identifier_0,
                                getTextOfNode(location)
                            );
                        }
                    } else if (prev & meaning) {
                        error(
                            location,
                            Diagnostics.Duplicate_identifier_0,
                            getTextOfNode(location)
                        );
                    } else {
                        names.set(name, prev | meaning);
                    }
                } else {
                    names.set(name, meaning);
                }
            }
        }

        /**
         * Static members being set on a constructor function may conflict with built-in properties
         * of Function. Esp. in ECMAScript 5 there are non-configurable and non-writable
         * built-in properties. This check issues a transpile error when a class has a static
         * member with the same name as a non-writable built-in property.
         *
         * @see http://www.ecma-international.org/ecma-262/5.1/#sec-15.3.3
         * @see http://www.ecma-international.org/ecma-262/5.1/#sec-15.3.5
         * @see http://www.ecma-international.org/ecma-262/6.0/#sec-properties-of-the-function-constructor
         * @see http://www.ecma-international.org/ecma-262/6.0/#sec-function-instances
         */
        function checkClassForStaticPropertyNameConflicts(
            node: ClassLikeDeclaration
        ) {
            for (const member of node.members) {
                const memberNameNode = member.name;
                const isStatic = hasModifier(member, ModifierFlags.Static);
                if (isStatic && memberNameNode) {
                    const memberName = getPropertyNameForPropertyNameNode(memberNameNode);
                    switch (memberName) {
                        case 'name':
                        case 'length':
                        case 'caller':
                        case 'arguments':
                        case 'prototype':
                            const message = Diagnostics
                                .Static_property_0_conflicts_with_built_in_property_Function_0_of_constructor_function_1;
                            const className = getNameOfSymbolAsWritten(getSymbolOfNode(node));
                            error(
                                memberNameNode,
                                message,
                                memberName,
                                className
                            );
                            break;
                    }
                }
            }
        }

        function checkObjectTypeForDuplicateDeclarations(
            node: TypeLiteralNode | InterfaceDeclaration
        ) {
            const names = createMap<boolean>();
            for (const member of node.members) {
                if (member.kind === SyntaxKind.PropertySignature) {
                    let memberName: string;
                    const name = member.name!;
                    switch (name.kind) {
                        case SyntaxKind.StringLiteral:
                        case SyntaxKind.NumericLiteral:
                            memberName = name.text;
                            break;
                        case SyntaxKind.Identifier:
                            memberName = idText(name);
                            break;
                        default:
                            continue;
                    }

                    if (names.get(memberName)) {
                        error(
                            getNameOfDeclaration(
                                member.symbol.valueDeclaration
                            ),
                            Diagnostics.Duplicate_identifier_0,
                            memberName
                        );
                        error(
                            member.name,
                            Diagnostics.Duplicate_identifier_0,
                            memberName
                        );
                    } else {
                        names.set(memberName, true);
                    }
                }
            }
        }

        function checkTypeForDuplicateIndexSignatures(node: Node) {
            if (node.kind === SyntaxKind.InterfaceDeclaration) {
                const nodeSymbol = getSymbolOfNode(node as InterfaceDeclaration);
                // in case of merging interface declaration it is possible that we'll enter this check procedure several times for every declaration
                // to prevent this run check only for the first declaration of a given kind
                if (nodeSymbol.declarations.length > 0
                    && nodeSymbol.declarations[0] !== node)
                {
                    return;
                }
            }

            // TypeScript 1.0 spec (April 2014)
            // 3.7.4: An object type can contain at most one string index signature and one numeric index signature.
            // 8.5: A class declaration can have at most one string index member declaration and one numeric index member declaration
            const indexSymbol = getIndexSymbol(getSymbolOfNode(node)!);
            if (indexSymbol) {
                let seenNumericIndexer = false;
                let seenStringIndexer = false;
                for (const decl of indexSymbol.declarations) {
                    const declaration = <SignatureDeclaration> decl;
                    if (declaration.parameters.length === 1
                        && declaration.parameters[0].type)
                    {
                        switch (declaration.parameters[0].type.kind) {
                            case SyntaxKind.StringKeyword:
                                if (!seenStringIndexer) {
                                    seenStringIndexer = true;
                                } else {
                                    error(
                                        declaration,
                                        Diagnostics
                                            .Duplicate_string_index_signature
                                    );
                                }
                                break;
                            case SyntaxKind.NumberKeyword:
                                if (!seenNumericIndexer) {
                                    seenNumericIndexer = true;
                                } else {
                                    error(
                                        declaration,
                                        Diagnostics
                                            .Duplicate_number_index_signature
                                    );
                                }
                                break;
                        }
                    }
                }
            }
        }

        function checkPropertyDeclaration(
            node: PropertyDeclaration | PropertySignature
        ) {
            // Grammar checking
            if (!checkGrammarDecoratorsAndModifiers(node)
                && !checkGrammarProperty(node))
            {
                checkGrammarComputedPropertyName(node.name);
            }
            checkVariableLikeDeclaration(node);

            // Private class fields transformation relies on WeakMaps.
            if (isPrivateIdentifier(node.name)
                && languageVersion < ScriptTarget.ESNext)
            {
                for (let lexicalScope = getEnclosingBlockScopeContainer(node);
                    !!lexicalScope;
                    lexicalScope = getEnclosingBlockScopeContainer(lexicalScope))
                {
                    getNodeLinks(lexicalScope).flags |= NodeCheckFlags
                        .ContainsClassWithPrivateIdentifiers;
                }
            }
        }

        function checkPropertySignature(node: PropertySignature) {
            if (isPrivateIdentifier(node.name)) {
                error(
                    node,
                    Diagnostics
                        .Private_identifiers_are_not_allowed_outside_class_bodies
                );
            }
            return checkPropertyDeclaration(node);
        }

        function checkMethodDeclaration(
            node: MethodDeclaration | MethodSignature
        ) {
            // Grammar checking
            if (!checkGrammarMethod(node)) {
                checkGrammarComputedPropertyName(
                    node.name
                );
            }

            if (isPrivateIdentifier(node.name)) {
                error(
                    node,
                    Diagnostics
                        .A_method_cannot_be_named_with_a_private_identifier
                );
            }

            // Grammar checking for modifiers is done inside the function checkGrammarFunctionLikeDeclaration
            checkFunctionOrMethodDeclaration(node);

            // Abstract methods cannot have an implementation.
            // Extra checks are to avoid reporting multiple errors relating to the "abstractness" of the node.
            if (hasModifier(node, ModifierFlags.Abstract)
                && node.kind === SyntaxKind.MethodDeclaration && node.body)
            {
                error(
                    node,
                    Diagnostics
                        .Method_0_cannot_have_an_implementation_because_it_is_marked_abstract,
                    declarationNameToString(node.name)
                );
            }
        }

        function checkConstructorDeclaration(node: ConstructorDeclaration) {
            // Grammar check on signature of constructor and modifier of the constructor is done in checkSignatureDeclaration function.
            checkSignatureDeclaration(node);
            // Grammar check for checking only related to constructorDeclaration
            if (!checkGrammarConstructorTypeParameters(node)) checkGrammarConstructorTypeAnnotation(node);

            checkSourceElement(node.body);

            const symbol = getSymbolOfNode(node);
            const firstDeclaration = getDeclarationOfKind(symbol, node.kind);

            // Only type check the symbol once
            if (node === firstDeclaration) {
                checkFunctionOrConstructorSymbol(symbol);
            }

            // exit early in the case of signature - super checks are not relevant to them
            if (nodeIsMissing(node.body)) {
                return;
            }

            if (!produceDiagnostics) {
                return;
            }

            function isInstancePropertyWithInitializerOrPrivateIdentifierProperty(
                n: Node
            ): boolean {
                if (isPrivateIdentifierPropertyDeclaration(n)) {
                    return true;
                }
                return n.kind === SyntaxKind.PropertyDeclaration
                    && !hasModifier(n, ModifierFlags.Static)
                    && !!(<PropertyDeclaration> n).initializer;
            }

            // TS 1.0 spec (April 2014): 8.3.2
            // Constructors of classes with no extends clause may not contain super calls, whereas
            // constructors of derived classes must contain at least one super call somewhere in their function body.
            const containingClassDecl = <ClassDeclaration> node.parent;
            if (getClassExtendsHeritageElement(containingClassDecl)) {
                captureLexicalThis(node.parent, containingClassDecl);
                const classExtendsNull = classDeclarationExtendsNull(containingClassDecl);
                const superCall = getSuperCallInConstructor(node);
                if (superCall) {
                    if (classExtendsNull) {
                        error(
                            superCall,
                            Diagnostics
                                .A_constructor_cannot_contain_a_super_call_when_its_class_extends_null
                        );
                    }

                    // The first statement in the body of a constructor (excluding prologue directives) must be a super call
                    // if both of the following are true:
                    // - The containing class is a derived class.
                    // - The constructor declares parameter properties
                    //   or the containing class declares instance member variables with initializers.
                    const superCallShouldBeFirst = some(
                        (<ClassDeclaration> node.parent).members,
                        isInstancePropertyWithInitializerOrPrivateIdentifierProperty
                    )
                        || some(
                            node.parameters,
                            p => hasModifier(
                                p,
                                ModifierFlags.ParameterPropertyModifier
                            )
                        );

                    // Skip past any prologue directives to find the first statement
                    // to ensure that it was a super call.
                    if (superCallShouldBeFirst) {
                        const statements = node.body!.statements;
                        let superCallStatement: ExpressionStatement
                            | undefined;

                        for (const statement of statements) {
                            if (statement.kind
                                === SyntaxKind.ExpressionStatement
                                && isSuperCall(
                                    (<ExpressionStatement> statement)
                                        .expression
                                ))
                            {
                                superCallStatement = <ExpressionStatement> statement;
                                break;
                            }
                            if (!isPrologueDirective(statement)) {
                                break;
                            }
                        }
                        if (!superCallStatement) {
                            error(
                                node,
                                Diagnostics
                                    .A_super_call_must_be_the_first_statement_in_the_constructor_when_a_class_contains_initialized_properties_parameter_properties_or_private_identifiers
                            );
                        }
                    }
                } else if (!classExtendsNull) {
                    error(
                        node,
                        Diagnostics
                            .Constructors_for_derived_classes_must_contain_a_super_call
                    );
                }
            }
        }

        function checkAccessorDeclaration(node: AccessorDeclaration) {
            if (produceDiagnostics) {
                // Grammar checking accessors
                if (!checkGrammarFunctionLikeDeclaration(node)
                    && !checkGrammarAccessor(node))
                {
                    checkGrammarComputedPropertyName(node.name);
                }

                checkDecorators(node);
                checkSignatureDeclaration(node);
                if (node.kind === SyntaxKind.GetAccessor) {
                    if (!(node.flags & NodeFlags.Ambient)
                        && nodeIsPresent(node.body)
                        && (node.flags & NodeFlags.HasImplicitReturn))
                    {
                        if (!(node.flags & NodeFlags.HasExplicitReturn)) {
                            error(
                                node.name,
                                Diagnostics.A_get_accessor_must_return_a_value
                            );
                        }
                    }
                }
                // Do not use hasDynamicName here, because that returns false for well known symbols.
                // We want to perform checkComputedPropertyName for all computed properties, including
                // well known symbols.
                if (node.name.kind === SyntaxKind.ComputedPropertyName) {
                    checkComputedPropertyName(node.name);
                }
                if (isPrivateIdentifier(node.name)) {
                    error(
                        node.name,
                        Diagnostics
                            .An_accessor_cannot_be_named_with_a_private_identifier
                    );
                }
                if (!hasNonBindableDynamicName(node)) {
                    // TypeScript 1.0 spec (April 2014): 8.4.3
                    // Accessors for the same member name must specify the same accessibility.
                    const otherKind = node.kind === SyntaxKind.GetAccessor
                        ? SyntaxKind.SetAccessor
                        : SyntaxKind.GetAccessor;
                    const otherAccessor = getDeclarationOfKind<AccessorDeclaration>(
                        getSymbolOfNode(node),
                        otherKind
                    );
                    if (otherAccessor) {
                        const nodeFlags = getModifierFlags(node);
                        const otherFlags = getModifierFlags(otherAccessor);
                        if ((nodeFlags & ModifierFlags.AccessibilityModifier)
                            !== (otherFlags
                                & ModifierFlags.AccessibilityModifier))
                        {
                            error(
                                node.name,
                                Diagnostics
                                    .Getter_and_setter_accessors_do_not_agree_in_visibility
                            );
                        }
                        if ((nodeFlags & ModifierFlags.Abstract)
                            !== (otherFlags & ModifierFlags.Abstract))
                        {
                            error(
                                node.name,
                                Diagnostics
                                    .Accessors_must_both_be_abstract_or_non_abstract
                            );
                        }

                        // TypeScript 1.0 spec (April 2014): 4.5
                        // If both accessors include type annotations, the specified types must be identical.
                        checkAccessorDeclarationTypesIdentical(
                            node,
                            otherAccessor,
                            getAnnotatedAccessorType,
                            Diagnostics
                                .get_and_set_accessor_must_have_the_same_type
                        );
                        checkAccessorDeclarationTypesIdentical(
                            node,
                            otherAccessor,
                            getThisTypeOfDeclaration,
                            Diagnostics
                                .get_and_set_accessor_must_have_the_same_this_type
                        );
                    }
                }
                const returnType = getTypeOfAccessors(getSymbolOfNode(node));
                if (node.kind === SyntaxKind.GetAccessor) {
                    checkAllCodePathsInNonVoidFunctionReturnOrThrow(
                        node,
                        returnType
                    );
                }
            }
            checkSourceElement(node.body);
        }

        function checkAccessorDeclarationTypesIdentical(
            first: AccessorDeclaration,
            second: AccessorDeclaration,
            getAnnotatedType: (a: AccessorDeclaration) => Type | undefined,
            message: DiagnosticMessage
        ) {
            const firstType = getAnnotatedType(first);
            const secondType = getAnnotatedType(second);
            if (firstType && secondType
                && !isTypeIdenticalTo(firstType, secondType))
            {
                error(first, message);
            }
        }

        function checkMissingDeclaration(node: Node) {
            checkDecorators(node);
        }

        function getEffectiveTypeArguments(
            node: TypeReferenceNode | ExpressionWithTypeArguments,
            typeParameters: readonly TypeParameter[]
        ): Type[] {
            return fillMissingTypeArguments(
                map(
                    node.typeArguments!,
                    getTypeFromTypeNode
                ),
                typeParameters,
                getMinTypeArgumentCount(typeParameters),
                isInJSFile(node)
            );
        }

        function checkTypeArgumentConstraints(
            node: TypeReferenceNode | ExpressionWithTypeArguments,
            typeParameters: readonly TypeParameter[]
        ): boolean {
            let typeArguments: Type[] | undefined;
            let mapper: TypeMapper | undefined;
            let result = true;
            for (let i = 0; i < typeParameters.length; i++) {
                const constraint = getConstraintOfTypeParameter(
                    typeParameters[i]
                );
                if (constraint) {
                    if (!typeArguments) {
                        typeArguments = getEffectiveTypeArguments(
                            node,
                            typeParameters
                        );
                        mapper = createTypeMapper(
                            typeParameters,
                            typeArguments
                        );
                    }
                    result = result && checkTypeAssignableTo(
                        typeArguments[i],
                        instantiateType(constraint, mapper),
                        node.typeArguments![i],
                        Diagnostics.Type_0_does_not_satisfy_the_constraint_1
                    );
                }
            }
            return result;
        }

        function getTypeParametersForTypeReference(
            node: TypeReferenceNode | ExpressionWithTypeArguments
        ) {
            const type = getTypeFromTypeReference(node);
            if (type !== errorType) {
                const symbol = getNodeLinks(node).resolvedSymbol;
                if (symbol) {
                    return symbol.flags & SymbolFlags.TypeAlias
                        && getSymbolLinks(symbol).typeParameters
                        || (getObjectFlags(type) & ObjectFlags.Reference
                            ? (<TypeReference> type).target.localTypeParameters
                            : undefined);
                }
            }
            return undefined;
        }

        function checkTypeReferenceNode(
            node: TypeReferenceNode | ExpressionWithTypeArguments
        ) {
            checkGrammarTypeArguments(node, node.typeArguments);
            if (node.kind === SyntaxKind.TypeReference
                && node.typeName.jsdocDotPos !== undefined && !isInJSFile(node)
                && !isInJSDoc(node))
            {
                grammarErrorAtPos(
                    node,
                    node.typeName.jsdocDotPos,
                    1,
                    Diagnostics
                        .JSDoc_types_can_only_be_used_inside_documentation_comments
                );
            }
            forEach(node.typeArguments, checkSourceElement);
            const type = getTypeFromTypeReference(node);
            if (type !== errorType) {
                if (node.typeArguments && produceDiagnostics) {
                    const typeParameters = getTypeParametersForTypeReference(node);
                    if (typeParameters) {
                        checkTypeArgumentConstraints(node, typeParameters);
                    }
                }
                if (type.flags & TypeFlags.Enum
                    && getNodeLinks(node).resolvedSymbol!.flags
                    & SymbolFlags.EnumMember)
                {
                    error(
                        node,
                        Diagnostics
                            .Enum_type_0_has_members_with_initializers_that_are_not_literals,
                        typeToString(type)
                    );
                }
            }
        }

        function getTypeArgumentConstraint(node: TypeNode): Type | undefined {
            const typeReferenceNode = tryCast(node.parent,
                isTypeReferenceType);
            if (!typeReferenceNode) return undefined;
            const typeParameters = getTypeParametersForTypeReference(typeReferenceNode)!; // TODO: GH#18217
            const constraint = getConstraintOfTypeParameter(
                typeParameters[typeReferenceNode.typeArguments!.indexOf(node)]
            );
            return constraint
                && instantiateType(
                    constraint,
                    createTypeMapper(
                        typeParameters,
                        getEffectiveTypeArguments(
                            typeReferenceNode,
                            typeParameters
                        )
                    )
                );
        }

        function checkTypeQuery(node: TypeQueryNode) {
            getTypeFromTypeQueryNode(node);
        }

        function checkTypeLiteral(node: TypeLiteralNode) {
            forEach(node.members, checkSourceElement);
            if (produceDiagnostics) {
                const type = getTypeFromTypeLiteralOrFunctionOrConstructorTypeNode(node);
                checkIndexConstraints(type);
                checkTypeForDuplicateIndexSignatures(node);
                checkObjectTypeForDuplicateDeclarations(node);
            }
        }

        function checkArrayType(node: ArrayTypeNode) {
            checkSourceElement(node.elementType);
        }

        function checkTupleType(node: TupleTypeNode) {
            const elementTypes = node.elementTypes;
            let seenOptionalElement = false;
            for (let i = 0; i < elementTypes.length; i++) {
                const e = elementTypes[i];
                if (e.kind === SyntaxKind.RestType) {
                    if (i !== elementTypes.length - 1) {
                        grammarErrorOnNode(
                            e,
                            Diagnostics
                                .A_rest_element_must_be_last_in_a_tuple_type
                        );
                        break;
                    }
                    if (!isArrayType(
                        getTypeFromTypeNode(
                            (<RestTypeNode> e).type
                        )
                    )) {
                        error(
                            e,
                            Diagnostics
                                .A_rest_element_type_must_be_an_array_type
                        );
                    }
                } else if (e.kind === SyntaxKind.OptionalType) {
                    seenOptionalElement = true;
                } else if (seenOptionalElement) {
                    grammarErrorOnNode(
                        e,
                        Diagnostics
                            .A_required_element_cannot_follow_an_optional_element
                    );
                    break;
                }
            }
            forEach(node.elementTypes, checkSourceElement);
        }

        function checkUnionOrIntersectionType(
            node: UnionOrIntersectionTypeNode
        ) {
            forEach(node.types, checkSourceElement);
        }

        function checkIndexedAccessIndexType(
            type: Type,
            accessNode: IndexedAccessTypeNode | ElementAccessExpression
        ) {
            if (!(type.flags & TypeFlags.IndexedAccess)) {
                return type;
            }
            // Check if the index type is assignable to 'keyof T' for the object type.
            const objectType = (<IndexedAccessType> type).objectType;
            const indexType = (<IndexedAccessType> type).indexType;
            if (isTypeAssignableTo(
                indexType,
                getIndexType(objectType, /*stringsOnly*/ false)
            )) {
                if (accessNode.kind === SyntaxKind.ElementAccessExpression
                    && isAssignmentTarget(accessNode)
                    && getObjectFlags(objectType) & ObjectFlags.Mapped
                    && getMappedTypeModifiers(<MappedType> objectType)
                    & MappedTypeModifiers.IncludeReadonly)
                {
                    error(
                        accessNode,
                        Diagnostics
                            .Index_signature_in_type_0_only_permits_reading,
                        typeToString(objectType)
                    );
                }
                return type;
            }
            // Check if we're indexing with a numeric type and if either object or index types
            // is a generic type with a constraint that has a numeric index signature.
            const apparentObjectType = getApparentType(objectType);
            if (getIndexInfoOfType(apparentObjectType, IndexKind.Number)
                && isTypeAssignableToKind(indexType, TypeFlags.NumberLike))
            {
                return type;
            }
            if (isGenericObjectType(objectType)) {
                const propertyName = getPropertyNameFromIndex(
                    indexType,
                    accessNode
                );
                if (propertyName) {
                    const propertySymbol = forEachType(
                        apparentObjectType,
                        t => getPropertyOfType(t, propertyName)
                    );
                    if (propertySymbol
                        && getDeclarationModifierFlagsFromSymbol(propertySymbol)
                        & ModifierFlags.NonPublicAccessibilityModifier)
                    {
                        error(
                            accessNode,
                            Diagnostics
                                .Private_or_protected_member_0_cannot_be_accessed_on_a_type_parameter,
                            unescapeLeadingUnderscores(propertyName)
                        );
                        return errorType;
                    }
                }
            }
            error(
                accessNode,
                Diagnostics.Type_0_cannot_be_used_to_index_type_1,
                typeToString(indexType),
                typeToString(objectType)
            );
            return errorType;
        }

        function checkIndexedAccessType(node: IndexedAccessTypeNode) {
            checkSourceElement(node.objectType);
            checkSourceElement(node.indexType);
            checkIndexedAccessIndexType(
                getTypeFromIndexedAccessTypeNode(node),
                node
            );
        }

        function checkMappedType(node: MappedTypeNode) {
            checkSourceElement(node.typeParameter);
            checkSourceElement(node.type);

            if (!node.type) {
                reportImplicitAny(node, anyType);
            }

            const type = <MappedType> getTypeFromMappedTypeNode(node);
            const constraintType = getConstraintTypeFromMappedType(type);
            checkTypeAssignableTo(
                constraintType,
                keyofConstraintType,
                getEffectiveConstraintOfTypeParameter(node.typeParameter)
            );
        }

        function checkThisType(node: ThisTypeNode) {
            getTypeFromThisTypeNode(node);
        }

        function checkTypeOperator(node: TypeOperatorNode) {
            checkGrammarTypeOperatorNode(node);
            checkSourceElement(node.type);
        }

        function checkConditionalType(node: ConditionalTypeNode) {
            forEachChild(node, checkSourceElement);
        }

        function checkInferType(node: InferTypeNode) {
            if (!findAncestor(
                node,
                n => n.parent && n.parent.kind === SyntaxKind.ConditionalType
                    && (<ConditionalTypeNode> n.parent).extendsType === n
            )) {
                grammarErrorOnNode(
                    node,
                    Diagnostics
                        .infer_declarations_are_only_permitted_in_the_extends_clause_of_a_conditional_type
                );
            }
            checkSourceElement(node.typeParameter);
            registerForUnusedIdentifiersCheck(node);
        }

        function checkImportType(node: ImportTypeNode) {
            checkSourceElement(node.argument);
            getTypeFromTypeNode(node);
        }

        function isPrivateWithinAmbient(node: Node): boolean {
            return hasModifier(node, ModifierFlags.Private)
                && !!(node.flags & NodeFlags.Ambient);
        }

        function getEffectiveDeclarationFlags(
            n: Declaration,
            flagsToCheck: ModifierFlags
        ): ModifierFlags {
            let flags = getCombinedModifierFlags(n);

            // children of classes (even ambient classes) should not be marked as ambient or export
            // because those flags have no useful semantics there.
            if (n.parent.kind !== SyntaxKind.InterfaceDeclaration
                && n.parent.kind !== SyntaxKind.ClassDeclaration
                && n.parent.kind !== SyntaxKind.ClassExpression
                && n.flags & NodeFlags.Ambient)
            {
                if (!(flags & ModifierFlags.Ambient)
                    && !(isModuleBlock(n.parent)
                        && isModuleDeclaration(n.parent.parent)
                        && isGlobalScopeAugmentation(n.parent.parent)))
                {
                    // It is nested in an ambient context, which means it is automatically exported
                    flags |= ModifierFlags.Export;
                }
                flags |= ModifierFlags.Ambient;
            }

            return flags & flagsToCheck;
        }

        function checkFunctionOrConstructorSymbol(symbol: Symbol): void {
            if (!produceDiagnostics) {
                return;
            }

            function getCanonicalOverload(
                overloads: Declaration[],
                implementation: FunctionLikeDeclaration | undefined
            ): Declaration {
                // Consider the canonical set of flags to be the flags of the bodyDeclaration or the first declaration
                // Error on all deviations from this canonical set of flags
                // The caveat is that if some overloads are defined in lib.d.ts, we don't want to
                // report the errors on those. To achieve this, we will say that the implementation is
                // the canonical signature only if it is in the same container as the first overload
                const implementationSharesContainerWithFirstOverload = implementation
                    !== undefined
                    && implementation.parent === overloads[0].parent;
                return implementationSharesContainerWithFirstOverload
                    ? implementation!
                    : overloads[0];
            }

            function checkFlagAgreementBetweenOverloads(
                overloads: Declaration[],
                implementation: FunctionLikeDeclaration | undefined,
                flagsToCheck: ModifierFlags,
                someOverloadFlags: ModifierFlags,
                allOverloadFlags: ModifierFlags
            ): void {
                // Error if some overloads have a flag that is not shared by all overloads. To find the
                // deviations, we XOR someOverloadFlags with allOverloadFlags
                const someButNotAllOverloadFlags = someOverloadFlags
                    ^ allOverloadFlags;
                if (someButNotAllOverloadFlags !== 0) {
                    const canonicalFlags = getEffectiveDeclarationFlags(
                        getCanonicalOverload(
                            overloads,
                            implementation
                        ),
                        flagsToCheck
                    );

                    forEach(
                        overloads,
                        o => {
                            const deviation = getEffectiveDeclarationFlags(
                                o,
                                flagsToCheck
                            ) ^ canonicalFlags;
                            if (deviation & ModifierFlags.Export) {
                                error(
                                    getNameOfDeclaration(o),
                                    Diagnostics
                                        .Overload_signatures_must_all_be_exported_or_non_exported
                                );
                            } else if (deviation & ModifierFlags.Ambient) {
                                error(
                                    getNameOfDeclaration(o),
                                    Diagnostics
                                        .Overload_signatures_must_all_be_ambient_or_non_ambient
                                );
                            } else if (deviation
                                & (ModifierFlags.Private
                                    | ModifierFlags.Protected))
                            {
                                error(
                                    getNameOfDeclaration(o) || o,
                                    Diagnostics
                                        .Overload_signatures_must_all_be_public_private_or_protected
                                );
                            } else if (deviation & ModifierFlags.Abstract) {
                                error(
                                    getNameOfDeclaration(o),
                                    Diagnostics
                                        .Overload_signatures_must_all_be_abstract_or_non_abstract
                                );
                            }
                        }
                    );
                }
            }

            function checkQuestionTokenAgreementBetweenOverloads(
                overloads: Declaration[],
                implementation: FunctionLikeDeclaration | undefined,
                someHaveQuestionToken: boolean,
                allHaveQuestionToken: boolean
            ): void {
                if (someHaveQuestionToken !== allHaveQuestionToken) {
                    const canonicalHasQuestionToken = hasQuestionToken(
                        getCanonicalOverload(
                            overloads,
                            implementation
                        )
                    );
                    forEach(
                        overloads,
                        o => {
                            const deviation = hasQuestionToken(o)
                                !== canonicalHasQuestionToken;
                            if (deviation) {
                                error(
                                    getNameOfDeclaration(o),
                                    Diagnostics
                                        .Overload_signatures_must_all_be_optional_or_required
                                );
                            }
                        }
                    );
                }
            }

            const flagsToCheck:
                ModifierFlags = ModifierFlags.Export | ModifierFlags.Ambient
                | ModifierFlags.Private | ModifierFlags.Protected
                | ModifierFlags.Abstract;
            let someNodeFlags: ModifierFlags = ModifierFlags.None;
            let allNodeFlags = flagsToCheck;
            let someHaveQuestionToken = false;
            let allHaveQuestionToken = true;
            let hasOverloads = false;
            let bodyDeclaration: FunctionLikeDeclaration | undefined;
            let lastSeenNonAmbientDeclaration: FunctionLikeDeclaration
                | undefined;
            let previousDeclaration: SignatureDeclaration | undefined;

            const declarations = symbol.declarations;
            const isConstructor = (symbol.flags & SymbolFlags.Constructor)
                !== 0;

            function reportImplementationExpectedError(
                node: SignatureDeclaration
            ): void {
                if (node.name && nodeIsMissing(node.name)) {
                    return;
                }

                let seen = false;
                const subsequentNode = forEachChild(
                    node.parent,
                    c => {
                        if (seen) {
                            return c;
                        } else {
                            seen = c === node;
                        }
                    }
                );
                // We may be here because of some extra nodes between overloads that could not be parsed into a valid node.
                // In this case the subsequent node is not really consecutive (.pos !== node.end), and we must ignore it here.
                if (subsequentNode && subsequentNode.pos === node.end) {
                    if (subsequentNode.kind === node.kind) {
                        const errorNode:
                            Node = (<FunctionLikeDeclaration> subsequentNode)
                            .name || subsequentNode;
                        const subsequentName = (<FunctionLikeDeclaration> subsequentNode)
                            .name;
                        if (node.name && subsequentName && (
                            // both are private identifiers
                            isPrivateIdentifier(node.name)
                            && isPrivateIdentifier(subsequentName)
                            && node.name.escapedText
                            === subsequentName.escapedText
                            // Both are computed property names
                            // TODO: GH#17345: These are methods, so handle computed name case. (`Always allowing computed property names is *not* the correct behavior!)
                            || isComputedPropertyName(node.name)
                            && isComputedPropertyName(subsequentName)
                            // Both are literal property names that are the same.
                            || isPropertyNameLiteral(node.name)
                            && isPropertyNameLiteral(subsequentName)
                            && getEscapedTextOfIdentifierOrLiteral(node.name)
                            === getEscapedTextOfIdentifierOrLiteral(subsequentName)
                        )) {
                            const reportError = (node.kind
                                === SyntaxKind.MethodDeclaration
                                || node.kind === SyntaxKind.MethodSignature)
                                && hasModifier(node, ModifierFlags.Static)
                                !== hasModifier(
                                    subsequentNode,
                                    ModifierFlags.Static
                                );
                            // we can get here in two cases
                            // 1. mixed static and instance class members
                            // 2. something with the same name was defined before the set of overloads that prevents them from merging
                            // here we'll report error only for the first case since for second we should already report error in binder
                            if (reportError) {
                                const diagnostic = hasModifier(
                                    node,
                                    ModifierFlags.Static
                                )
                                    ? Diagnostics
                                        .Function_overload_must_be_static
                                    : Diagnostics
                                        .Function_overload_must_not_be_static;
                                error(errorNode, diagnostic);
                            }
                            return;
                        }
                        if (nodeIsPresent(
                            (<FunctionLikeDeclaration> subsequentNode).body
                        )) {
                            error(
                                errorNode,
                                Diagnostics
                                    .Function_implementation_name_must_be_0,
                                declarationNameToString(node.name)
                            );
                            return;
                        }
                    }
                }
                const errorNode: Node = node.name || node;
                if (isConstructor) {
                    error(
                        errorNode,
                        Diagnostics.Constructor_implementation_is_missing
                    );
                } else {
                    // Report different errors regarding non-consecutive blocks of declarations depending on whether
                    // the node in question is abstract.
                    if (hasModifier(node, ModifierFlags.Abstract)) {
                        error(
                            errorNode,
                            Diagnostics
                                .All_declarations_of_an_abstract_method_must_be_consecutive
                        );
                    } else {
                        error(
                            errorNode,
                            Diagnostics
                                .Function_implementation_is_missing_or_not_immediately_following_the_declaration
                        );
                    }
                }
            }

            let duplicateFunctionDeclaration = false;
            let multipleConstructorImplementation = false;
            let hasNonAmbientClass = false;
            for (const current of declarations) {
                const node = <SignatureDeclaration | ClassDeclaration
                    | ClassExpression> current;
                const inAmbientContext = node.flags & NodeFlags.Ambient;
                const inAmbientContextOrInterface = node.parent.kind
                    === SyntaxKind.InterfaceDeclaration
                    || node.parent.kind === SyntaxKind.TypeLiteral
                    || inAmbientContext;
                if (inAmbientContextOrInterface) {
                    // check if declarations are consecutive only if they are non-ambient
                    // 1. ambient declarations can be interleaved
                    // i.e. this is legal
                    //     declare function foo();
                    //     declare function bar();
                    //     declare function foo();
                    // 2. mixing ambient and non-ambient declarations is a separate error that will be reported - do not want to report an extra one
                    previousDeclaration = undefined;
                }

                if ((node.kind === SyntaxKind.ClassDeclaration
                    || node.kind === SyntaxKind.ClassExpression)
                    && !inAmbientContext)
                {
                    hasNonAmbientClass = true;
                }

                if (node.kind === SyntaxKind.FunctionDeclaration
                    || node.kind === SyntaxKind.MethodDeclaration
                    || node.kind === SyntaxKind.MethodSignature
                    || node.kind === SyntaxKind.Constructor)
                {
                    const currentNodeFlags = getEffectiveDeclarationFlags(
                        node,
                        flagsToCheck
                    );
                    someNodeFlags |= currentNodeFlags;
                    allNodeFlags &= currentNodeFlags;
                    someHaveQuestionToken = someHaveQuestionToken
                        || hasQuestionToken(node);
                    allHaveQuestionToken = allHaveQuestionToken
                        && hasQuestionToken(node);

                    if (nodeIsPresent((node as FunctionLikeDeclaration).body)
                        && bodyDeclaration)
                    {
                        if (isConstructor) {
                            multipleConstructorImplementation = true;
                        } else {
                            duplicateFunctionDeclaration = true;
                        }
                    } else if (previousDeclaration
                        && previousDeclaration.parent === node.parent
                        && previousDeclaration.end !== node.pos)
                    {
                        reportImplementationExpectedError(previousDeclaration);
                    }

                    if (nodeIsPresent((node as FunctionLikeDeclaration)
                        .body))
                    {
                        if (!bodyDeclaration) {
                            bodyDeclaration = node as FunctionLikeDeclaration;
                        }
                    } else {
                        hasOverloads = true;
                    }

                    previousDeclaration = node;

                    if (!inAmbientContextOrInterface) {
                        lastSeenNonAmbientDeclaration = node as FunctionLikeDeclaration;
                    }
                }
            }

            if (multipleConstructorImplementation) {
                forEach(
                    declarations,
                    declaration => {
                        error(
                            declaration,
                            Diagnostics
                                .Multiple_constructor_implementations_are_not_allowed
                        );
                    }
                );
            }

            if (duplicateFunctionDeclaration) {
                forEach(
                    declarations,
                    declaration => {
                        error(
                            getNameOfDeclaration(declaration),
                            Diagnostics.Duplicate_function_implementation
                        );
                    }
                );
            }

            if (hasNonAmbientClass && !isConstructor
                && symbol.flags & SymbolFlags.Function)
            {
                // A non-ambient class cannot be an implementation for a non-constructor function/class merge
                // TODO: The below just replicates our older error from when classes and functions were
                // entirely unable to merge - a more helpful message like "Class declaration cannot implement overload list"
                // might be warranted. :shrug:
                forEach(
                    declarations,
                    declaration => {
                        addDuplicateDeclarationError(
                            getNameOfDeclaration(declaration) || declaration,
                            Diagnostics.Duplicate_identifier_0,
                            symbolName(symbol),
                            filter(declarations, d => d !== declaration)
                        );
                    }
                );
            }

            // Abstract methods can't have an implementation -- in particular, they don't need one.
            if (lastSeenNonAmbientDeclaration
                && !lastSeenNonAmbientDeclaration.body
                && !hasModifier(
                    lastSeenNonAmbientDeclaration,
                    ModifierFlags.Abstract
                ) && !lastSeenNonAmbientDeclaration.questionToken)
            {
                reportImplementationExpectedError(lastSeenNonAmbientDeclaration);
            }

            if (hasOverloads) {
                checkFlagAgreementBetweenOverloads(
                    declarations,
                    bodyDeclaration,
                    flagsToCheck,
                    someNodeFlags,
                    allNodeFlags
                );
                checkQuestionTokenAgreementBetweenOverloads(
                    declarations,
                    bodyDeclaration,
                    someHaveQuestionToken,
                    allHaveQuestionToken
                );

                if (bodyDeclaration) {
                    const signatures = getSignaturesOfSymbol(symbol);
                    const bodySignature = getSignatureFromDeclaration(bodyDeclaration);
                    for (const signature of signatures) {
                        if (!isImplementationCompatibleWithOverload(
                            bodySignature,
                            signature
                        )) {
                            addRelatedInfo(
                                error(
                                    signature.declaration,
                                    Diagnostics
                                        .This_overload_signature_is_not_compatible_with_its_implementation_signature
                                ),
                                createDiagnosticForNode(
                                    bodyDeclaration,
                                    Diagnostics
                                        .The_implementation_signature_is_declared_here
                                )
                            );
                            break;
                        }
                    }
                }
            }
        }

        function checkExportsOnMergedDeclarations(node: Node): void {
            if (!produceDiagnostics) {
                return;
            }

            // if localSymbol is defined on node then node itself is exported - check is required
            let symbol = node.localSymbol;
            if (!symbol) {
                // local symbol is undefined => this declaration is non-exported.
                // however symbol might contain other declarations that are exported
                symbol = getSymbolOfNode(node)!;
                if (!symbol.exportSymbol) {
                    // this is a pure local symbol (all declarations are non-exported) - no need to check anything
                    return;
                }
            }

            // run the check only for the first declaration in the list
            if (getDeclarationOfKind(symbol, node.kind) !== node) {
                return;
            }

            let exportedDeclarationSpaces = DeclarationSpaces.None;
            let nonExportedDeclarationSpaces = DeclarationSpaces.None;
            let defaultExportedDeclarationSpaces = DeclarationSpaces.None;
            for (const d of symbol.declarations) {
                const declarationSpaces = getDeclarationSpaces(d);
                const effectiveDeclarationFlags = getEffectiveDeclarationFlags(
                    d,
                    ModifierFlags.Export | ModifierFlags.Default
                );

                if (effectiveDeclarationFlags & ModifierFlags.Export) {
                    if (effectiveDeclarationFlags & ModifierFlags.Default) {
                        defaultExportedDeclarationSpaces |= declarationSpaces;
                    } else {
                        exportedDeclarationSpaces |= declarationSpaces;
                    }
                } else {
                    nonExportedDeclarationSpaces |= declarationSpaces;
                }
            }

            // Spaces for anything not declared a 'default export'.
            const nonDefaultExportedDeclarationSpaces = exportedDeclarationSpaces
                | nonExportedDeclarationSpaces;

            const commonDeclarationSpacesForExportsAndLocals = exportedDeclarationSpaces
                & nonExportedDeclarationSpaces;
            const commonDeclarationSpacesForDefaultAndNonDefault = defaultExportedDeclarationSpaces
                & nonDefaultExportedDeclarationSpaces;

            if (commonDeclarationSpacesForExportsAndLocals
                || commonDeclarationSpacesForDefaultAndNonDefault)
            {
                // declaration spaces for exported and non-exported declarations intersect
                for (const d of symbol.declarations) {
                    const declarationSpaces = getDeclarationSpaces(d);

                    const name = getNameOfDeclaration(d);
                    // Only error on the declarations that contributed to the intersecting spaces.
                    if (declarationSpaces
                        & commonDeclarationSpacesForDefaultAndNonDefault)
                    {
                        error(
                            name,
                            Diagnostics
                                .Merged_declaration_0_cannot_include_a_default_export_declaration_Consider_adding_a_separate_export_default_0_declaration_instead,
                            declarationNameToString(name)
                        );
                    } else if (declarationSpaces
                        & commonDeclarationSpacesForExportsAndLocals)
                    {
                        error(
                            name,
                            Diagnostics
                                .Individual_declarations_in_merged_declaration_0_must_be_all_exported_or_all_local,
                            declarationNameToString(name)
                        );
                    }
                }
            }

            function getDeclarationSpaces(decl:
                Declaration): DeclarationSpaces
            {
                let d = decl as Node;
                switch (d.kind) {
                    case SyntaxKind.InterfaceDeclaration:
                    case SyntaxKind.TypeAliasDeclaration:

                    // A jsdoc typedef and callback are, by definition, type aliases.
                    // falls through
                    case SyntaxKind.JSDocTypedefTag:
                    case SyntaxKind.JSDocCallbackTag:
                    case SyntaxKind.JSDocEnumTag:
                        return DeclarationSpaces.ExportType;
                    case SyntaxKind.ModuleDeclaration:
                        return isAmbientModule(d as ModuleDeclaration)
                            || getModuleInstanceState(d as ModuleDeclaration)
                            !== ModuleInstanceState.NonInstantiated
                            ? DeclarationSpaces.ExportNamespace
                                | DeclarationSpaces.ExportValue
                            : DeclarationSpaces.ExportNamespace;
                    case SyntaxKind.ClassDeclaration:
                    case SyntaxKind.EnumDeclaration:
                        return DeclarationSpaces.ExportType
                            | DeclarationSpaces.ExportValue;
                    case SyntaxKind.SourceFile:
                        return DeclarationSpaces.ExportType
                            | DeclarationSpaces.ExportValue
                            | DeclarationSpaces.ExportNamespace;
                    case SyntaxKind.ExportAssignment:
                        // Export assigned entity name expressions act as aliases and should fall through, otherwise they export values
                        if (!isEntityNameExpression(
                            (d as ExportAssignment).expression
                        )) {
                            return DeclarationSpaces.ExportValue;
                        }
                        d = (d as ExportAssignment).expression;

                    // The below options all declare an Alias, which is allowed to merge with other values within the importing module.
                    // falls through
                    case SyntaxKind.ImportEqualsDeclaration:
                    case SyntaxKind.NamespaceImport:
                    case SyntaxKind.ImportClause:
                        let result = DeclarationSpaces.None;
                        const target = resolveAlias(getSymbolOfNode(d)!);
                        forEach(
                            target.declarations,
                            d => {
                                result |= getDeclarationSpaces(d);
                            }
                        );
                        return result;
                    case SyntaxKind.VariableDeclaration:
                    case SyntaxKind.BindingElement:
                    case SyntaxKind.FunctionDeclaration:
                    case SyntaxKind
                        .ImportSpecifier: // https://github.com/Microsoft/TypeScript/pull/7591
                        return DeclarationSpaces.ExportValue;
                    default:
                        return Debug.failBadSyntaxKind(d);
                }
            }
        }

        function getAwaitedTypeOfPromise(
            type: Type,
            errorNode?: Node,
            diagnosticMessage?: DiagnosticMessage,
            arg0?: string | number
        ): Type | undefined {
            const promisedType = getPromisedTypeOfPromise(type, errorNode);
            return promisedType
                && getAwaitedType(
                    promisedType,
                    errorNode,
                    diagnosticMessage,
                    arg0
                );
        }

        /**
         * Gets the "promised type" of a promise.
         * @param type The type of the promise.
         * @remarks The "promised type" of a type is the type of the "value" parameter of the "onfulfilled" callback.
         */
        function getPromisedTypeOfPromise(
            promise: Type,
            errorNode?: Node
        ): Type | undefined {
            //
            //  { // promise
            //      then( // thenFunction
            //          onfulfilled: ( // onfulfilledParameterType
            //              value: T // valueParameterType
            //          ) => any
            //      ): any;
            //  }
            //

            if (isTypeAny(promise)) {
                return undefined;
            }

            const typeAsPromise = <PromiseOrAwaitableType> promise;
            if (typeAsPromise.promisedTypeOfPromise) {
                return typeAsPromise.promisedTypeOfPromise;
            }

            if (isReferenceToType(
                promise,
                getGlobalPromiseType(/*reportErrors*/ false)
            )) {
                return typeAsPromise
                    .promisedTypeOfPromise = getTypeArguments(<GenericType> promise)
                        [0];
            }

            const thenFunction = getTypeOfPropertyOfType(
                promise,
                'then' as __String
            )!; // TODO: GH#18217
            if (isTypeAny(thenFunction)) {
                return undefined;
            }

            const thenSignatures = thenFunction
                ? getSignaturesOfType(thenFunction, SignatureKind.Call)
                : emptyArray;
            if (thenSignatures.length === 0) {
                if (errorNode) {
                    error(
                        errorNode,
                        Diagnostics.A_promise_must_have_a_then_method
                    );
                }
                return undefined;
            }

            const onfulfilledParameterType = getTypeWithFacts(
                getUnionType(
                    map(
                        thenSignatures,
                        getTypeOfFirstParameterOfSignature
                    )
                ),
                TypeFacts.NEUndefinedOrNull
            );
            if (isTypeAny(onfulfilledParameterType)) {
                return undefined;
            }

            const onfulfilledParameterSignatures = getSignaturesOfType(
                onfulfilledParameterType,
                SignatureKind.Call
            );
            if (onfulfilledParameterSignatures.length === 0) {
                if (errorNode) {
                    error(
                        errorNode,
                        Diagnostics
                            .The_first_parameter_of_the_then_method_of_a_promise_must_be_a_callback
                    );
                }
                return undefined;
            }

            return typeAsPromise
                .promisedTypeOfPromise = getUnionType(
                    map(
                        onfulfilledParameterSignatures,
                        getTypeOfFirstParameterOfSignature
                    ),
                    UnionReduction.Subtype
                );
        }

        /**
         * Gets the "awaited type" of a type.
         * @param type The type to await.
         * @remarks The "awaited type" of an expression is its "promised type" if the expression is a
         * Promise-like type; otherwise, it is the type of the expression. This is used to reflect
         * The runtime behavior of the `await` keyword.
         */
        function checkAwaitedType(
            type: Type,
            errorNode: Node,
            diagnosticMessage: DiagnosticMessage,
            arg0?: string | number
        ): Type {
            const awaitedType = getAwaitedType(
                type,
                errorNode,
                diagnosticMessage,
                arg0
            );
            return awaitedType || errorType;
        }

        function getAwaitedType(
            type: Type,
            errorNode?: Node,
            diagnosticMessage?: DiagnosticMessage,
            arg0?: string | number
        ): Type | undefined {
            const typeAsAwaitable = <PromiseOrAwaitableType> type;
            if (typeAsAwaitable.awaitedTypeOfType) {
                return typeAsAwaitable.awaitedTypeOfType;
            }

            if (isTypeAny(type)) {
                return typeAsAwaitable.awaitedTypeOfType = type;
            }

            if (type.flags & TypeFlags.Union) {
                let types: Type[] | undefined;
                for (const constituentType of (<UnionType> type).types) {
                    types = append<Type>(
                        types,
                        getAwaitedType(
                            constituentType,
                            errorNode,
                            diagnosticMessage,
                            arg0
                        )
                    );
                }

                if (!types) {
                    return undefined;
                }

                return typeAsAwaitable.awaitedTypeOfType = getUnionType(types);
            }

            const promisedType = getPromisedTypeOfPromise(type);
            if (promisedType) {
                if (type.id === promisedType.id
                    || awaitedTypeStack.indexOf(promisedType.id) >= 0)
                {
                    // Verify that we don't have a bad actor in the form of a promise whose
                    // promised type is the same as the promise type, or a mutually recursive
                    // promise. If so, we return undefined as we cannot guess the shape. If this
                    // were the actual case in the JavaScript, this Promise would never resolve.
                    //
                    // An example of a bad actor with a singly-recursive promise type might
                    // be:
                    //
                    //  interface BadPromise {
                    //      then(
                    //          onfulfilled: (value: BadPromise) => any,
                    //          onrejected: (error: any) => any): BadPromise;
                    //  }
                    // The above interface will pass the PromiseLike check, and return a
                    // promised type of `BadPromise`. Since this is a self reference, we
                    // don't want to keep recursing ad infinitum.
                    //
                    // An example of a bad actor in the form of a mutually-recursive
                    // promise type might be:
                    //
                    //  interface BadPromiseA {
                    //      then(
                    //          onfulfilled: (value: BadPromiseB) => any,
                    //          onrejected: (error: any) => any): BadPromiseB;
                    //  }
                    //
                    //  interface BadPromiseB {
                    //      then(
                    //          onfulfilled: (value: BadPromiseA) => any,
                    //          onrejected: (error: any) => any): BadPromiseA;
                    //  }
                    //
                    if (errorNode) {
                        error(
                            errorNode,
                            Diagnostics
                                .Type_is_referenced_directly_or_indirectly_in_the_fulfillment_callback_of_its_own_then_method
                        );
                    }
                    return undefined;
                }

                // Keep track of the type we're about to unwrap to avoid bad recursive promise types.
                // See the comments above for more information.
                awaitedTypeStack.push(type.id);
                const awaitedType = getAwaitedType(
                    promisedType,
                    errorNode,
                    diagnosticMessage,
                    arg0
                );
                awaitedTypeStack.pop();

                if (!awaitedType) {
                    return undefined;
                }

                return typeAsAwaitable.awaitedTypeOfType = awaitedType;
            }

            // The type was not a promise, so it could not be unwrapped any further.
            // As long as the type does not have a callable "then" property, it is
            // safe to return the type; otherwise, an error will be reported in
            // the call to getNonThenableType and we will return undefined.
            //
            // An example of a non-promise "thenable" might be:
            //
            //  await { then(): void {} }
            //
            // The "thenable" does not match the minimal definition for a promise. When
            // a Promise/A+-compatible or ES6 promise tries to adopt this value, the promise
            // will never settle. We treat this as an error to help flag an early indicator
            // of a runtime problem. If the user wants to return this value from an async
            // function, they would need to wrap it in some other value. If they want it to
            // be treated as a promise, they can cast to <any>.
            const thenFunction = getTypeOfPropertyOfType(
                type,
                'then' as __String
            );
            if (thenFunction
                && getSignaturesOfType(thenFunction, SignatureKind.Call).length
                > 0)
            {
                if (errorNode) {
                    if (!diagnosticMessage) return Debug.fail();
                    error(errorNode, diagnosticMessage, arg0);
                }
                return undefined;
            }

            return typeAsAwaitable.awaitedTypeOfType = type;
        }

        /**
         * Checks the return type of an async function to ensure it is a compatible
         * Promise implementation.
         *
         * This checks that an async function has a valid Promise-compatible return type.
         * An async function has a valid Promise-compatible return type if the resolved value
         * of the return type has a construct signature that takes in an `initializer` function
         * that in turn supplies a `resolve` function as one of its arguments and results in an
         * object with a callable `then` signature.
         *
         * @param node The signature to check
         */
        function checkAsyncFunctionReturnType(
            node: FunctionLikeDeclaration | MethodSignature,
            returnTypeNode: TypeNode
        ) {
            // As part of our emit for an async function, we will need to emit the entity name of
            // the return type annotation as an expression. To meet the necessary runtime semantics
            // for __awaiter, we must also check that the type of the declaration (e.g. the static
            // side or "constructor" of the promise type) is compatible `PromiseConstructorLike`.
            //
            // An example might be (from lib.es6.d.ts):
            //
            //  interface Promise<T> { ... }
            //  interface PromiseConstructor {
            //      new <T>(...): Promise<T>;
            //  }
            //  declare var Promise: PromiseConstructor;
            //
            // When an async function declares a return type annotation of `Promise<T>`, we
            // need to get the type of the `Promise` variable declaration above, which would
            // be `PromiseConstructor`.
            //
            // The same case applies to a class:
            //
            //  declare class Promise<T> {
            //      constructor(...);
            //      then<U>(...): Promise<U>;
            //  }
            //
            const returnType = getTypeFromTypeNode(returnTypeNode);

            if (languageVersion >= ScriptTarget.ES2015) {
                if (returnType === errorType) {
                    return;
                }
                const globalPromiseType = getGlobalPromiseType(/*reportErrors*/ true);
                if (globalPromiseType !== emptyGenericType
                    && !isReferenceToType(returnType, globalPromiseType))
                {
                    // The promise type was not a valid type reference to the global promise type, so we
                    // report an error and return the unknown type.
                    error(
                        returnTypeNode,
                        Diagnostics
                            .The_return_type_of_an_async_function_or_method_must_be_the_global_Promise_T_type
                    );
                    return;
                }
            } else {
                // Always mark the type node as referenced if it points to a value
                markTypeNodeAsReferenced(returnTypeNode);

                if (returnType === errorType) {
                    return;
                }

                const promiseConstructorName = getEntityNameFromTypeNode(returnTypeNode);
                if (promiseConstructorName === undefined) {
                    error(
                        returnTypeNode,
                        Diagnostics
                            .Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value,
                        typeToString(returnType)
                    );
                    return;
                }

                const promiseConstructorSymbol = resolveEntityName(
                    promiseConstructorName,
                    SymbolFlags.Value, /*ignoreErrors*/
                    true
                );
                const promiseConstructorType = promiseConstructorSymbol
                    ? getTypeOfSymbol(promiseConstructorSymbol)
                    : errorType;
                if (promiseConstructorType === errorType) {
                    if (promiseConstructorName.kind === SyntaxKind.Identifier
                        && promiseConstructorName.escapedText === 'Promise'
                        && getTargetType(returnType)
                        === getGlobalPromiseType(/*reportErrors*/ false))
                    {
                        error(
                            returnTypeNode,
                            Diagnostics
                                .An_async_function_or_method_in_ES5_SlashES3_requires_the_Promise_constructor_Make_sure_you_have_a_declaration_for_the_Promise_constructor_or_include_ES2015_in_your_lib_option
                        );
                    } else {
                        error(
                            returnTypeNode,
                            Diagnostics
                                .Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value,
                            entityNameToString(promiseConstructorName)
                        );
                    }
                    return;
                }

                const globalPromiseConstructorLikeType = getGlobalPromiseConstructorLikeType(/*reportErrors*/ true);
                if (globalPromiseConstructorLikeType === emptyObjectType) {
                    // If we couldn't resolve the global PromiseConstructorLike type we cannot verify
                    // compatibility with __awaiter.
                    error(
                        returnTypeNode,
                        Diagnostics
                            .Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value,
                        entityNameToString(promiseConstructorName)
                    );
                    return;
                }

                if (!checkTypeAssignableTo(
                    promiseConstructorType,
                    globalPromiseConstructorLikeType,
                    returnTypeNode,
                    Diagnostics
                        .Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value
                )) {
                    return;
                }

                // Verify there is no local declaration that could collide with the promise constructor.
                const rootName = promiseConstructorName
                    && getFirstIdentifier(promiseConstructorName);
                const collidingSymbol = getSymbol(
                    node.locals!,
                    rootName.escapedText,
                    SymbolFlags.Value
                );
                if (collidingSymbol) {
                    error(
                        collidingSymbol.valueDeclaration,
                        Diagnostics
                            .Duplicate_identifier_0_Compiler_uses_declaration_1_to_support_async_functions,
                        idText(rootName),
                        entityNameToString(promiseConstructorName)
                    );
                    return;
                }
            }
            checkAwaitedType(
                returnType,
                node,
                Diagnostics
                    .The_return_type_of_an_async_function_must_either_be_a_valid_promise_or_must_not_contain_a_callable_then_member
            );
        }

        /** Check a decorator */
        function checkDecorator(node: Decorator): void {
            const signature = getResolvedSignature(node);
            const returnType = getReturnTypeOfSignature(signature);
            if (returnType.flags & TypeFlags.Any) {
                return;
            }

            let expectedReturnType: Type;
            const headMessage = getDiagnosticHeadMessageForDecoratorResolution(node);
            let errorInfo: DiagnosticMessageChain | undefined;
            switch (node.parent.kind) {
                case SyntaxKind.ClassDeclaration:
                    const classSymbol = getSymbolOfNode(node.parent);
                    const classConstructorType = getTypeOfSymbol(classSymbol);
                    expectedReturnType = getUnionType(
                        [classConstructorType, voidType]
                    );
                    break;
                case SyntaxKind.Parameter:
                    expectedReturnType = voidType;
                    errorInfo = chainDiagnosticMessages(
                        /*details*/ undefined,
                        Diagnostics
                            .The_return_type_of_a_parameter_decorator_function_must_be_either_void_or_any
                    );

                    break;
                case SyntaxKind.PropertyDeclaration:
                    expectedReturnType = voidType;
                    errorInfo = chainDiagnosticMessages(
                        /*details*/ undefined,
                        Diagnostics
                            .The_return_type_of_a_property_decorator_function_must_be_either_void_or_any
                    );
                    break;
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.GetAccessor:
                case SyntaxKind.SetAccessor:
                    const methodType = getTypeOfNode(node.parent);
                    const descriptorType = createTypedPropertyDescriptorType(methodType);
                    expectedReturnType = getUnionType(
                        [descriptorType, voidType]
                    );
                    break;
                default:
                    return Debug.fail();
            }

            checkTypeAssignableTo(
                returnType,
                expectedReturnType,
                node,
                headMessage,
                () => errorInfo
            );
        }

        /**
         * If a TypeNode can be resolved to a value symbol imported from an external module, it is
         * marked as referenced to prevent import elision.
         */
        function markTypeNodeAsReferenced(node: TypeNode) {
            markEntityNameOrEntityExpressionAsReference(
                node && getEntityNameFromTypeNode(node)
            );
        }

        function markEntityNameOrEntityExpressionAsReference(
            typeName: EntityNameOrEntityNameExpression | undefined
        ) {
            if (!typeName) return;

            const rootName = getFirstIdentifier(typeName);
            const meaning = (typeName.kind === SyntaxKind.Identifier
                ? SymbolFlags.Type
                : SymbolFlags.Namespace) | SymbolFlags.Alias;
            const rootSymbol = resolveName(
                rootName,
                rootName.escapedText,
                meaning, /*nameNotFoundMessage*/
                undefined, /*nameArg*/
                undefined, /*isRefernce*/
                true
            );
            if (rootSymbol
                && rootSymbol.flags & SymbolFlags.Alias
                && symbolIsValue(rootSymbol)
                && !isConstEnumOrConstEnumOnlyModule(resolveAlias(rootSymbol)))
            {
                markAliasSymbolAsReferenced(rootSymbol);
            }
        }

        /**
         * This function marks the type used for metadata decorator as referenced if it is import
         * from external module.
         * This is different from markTypeNodeAsReferenced because it tries to simplify type nodes in
         * union and intersection type
         * @param node
         */
        function markDecoratorMedataDataTypeNodeAsReferenced(
            node: TypeNode | undefined
        ): void {
            const entityName = getEntityNameForDecoratorMetadata(node);
            if (entityName && isEntityName(entityName)) {
                markEntityNameOrEntityExpressionAsReference(entityName);
            }
        }

        function getEntityNameForDecoratorMetadata(
            node: TypeNode | undefined
        ): EntityName | undefined {
            if (node) {
                switch (node.kind) {
                    case SyntaxKind.IntersectionType:
                    case SyntaxKind.UnionType:
                        return getEntityNameForDecoratorMetadataFromTypeList(
                            (<UnionOrIntersectionTypeNode> node).types
                        );
                    case SyntaxKind.ConditionalType:
                        return getEntityNameForDecoratorMetadataFromTypeList(
                            [(<ConditionalTypeNode> node).trueType,
                                (<ConditionalTypeNode> node).falseType]
                        );
                    case SyntaxKind.ParenthesizedType:
                        return getEntityNameForDecoratorMetadata(
                            (<ParenthesizedTypeNode> node).type
                        );
                    case SyntaxKind.TypeReference:
                        return (<TypeReferenceNode> node).typeName;
                }
            }
        }

        function getEntityNameForDecoratorMetadataFromTypeList(
            types: readonly TypeNode[]
        ): EntityName | undefined {
            let commonEntityName: EntityName | undefined;
            for (let typeNode of types) {
                while (typeNode.kind === SyntaxKind.ParenthesizedType) {
                    typeNode = (typeNode as ParenthesizedTypeNode)
                        .type; // Skip parens if need be
                }
                if (typeNode.kind === SyntaxKind.NeverKeyword) {
                    continue; // Always elide `never` from the union/intersection if possible
                }
                if (!strictNullChecks
                    && (typeNode.kind === SyntaxKind.NullKeyword
                        || typeNode.kind === SyntaxKind.UndefinedKeyword))
                {
                    continue; // Elide null and undefined from unions for metadata, just like what we did prior to the implementation of strict null checks
                }
                const individualEntityName = getEntityNameForDecoratorMetadata(typeNode);
                if (!individualEntityName) {
                    // Individual is something like string number
                    // So it would be serialized to either that type or object
                    // Safe to return here
                    return undefined;
                }

                if (commonEntityName) {
                    // Note this is in sync with the transformation that happens for type node.
                    // Keep this in sync with serializeUnionOrIntersectionType
                    // Verify if they refer to same entity and is identifier
                    // return undefined if they dont match because we would emit object
                    if (!isIdentifier(commonEntityName)
                        || !isIdentifier(individualEntityName)
                        || commonEntityName.escapedText
                        !== individualEntityName.escapedText)
                    {
                        return undefined;
                    }
                } else {
                    commonEntityName = individualEntityName;
                }
            }
            return commonEntityName;
        }

        function getParameterTypeNodeForDecoratorCheck(
            node: ParameterDeclaration
        ): TypeNode | undefined {
            const typeNode = getEffectiveTypeAnnotationNode(node);
            return isRestParameter(node)
                ? getRestParameterElementType(typeNode)
                : typeNode;
        }

        /** Check the decorators of a node */
        function checkDecorators(node: Node): void {
            if (!node.decorators) {
                return;
            }

            // skip this check for nodes that cannot have decorators. These should have already had an error reported by
            // checkGrammarDecorators.
            if (!nodeCanBeDecorated(node, node.parent, node.parent.parent)) {
                return;
            }

            if (!compilerOptions.experimentalDecorators) {
                error(
                    node,
                    Diagnostics
                        .Experimental_support_for_decorators_is_a_feature_that_is_subject_to_change_in_a_future_release_Set_the_experimentalDecorators_option_in_your_tsconfig_or_jsconfig_to_remove_this_warning
                );
            }

            const firstDecorator = node.decorators[0];
            checkExternalEmitHelpers(
                firstDecorator,
                ExternalEmitHelpers.Decorate
            );
            if (node.kind === SyntaxKind.Parameter) {
                checkExternalEmitHelpers(
                    firstDecorator,
                    ExternalEmitHelpers.Param
                );
            }

            if (compilerOptions.emitDecoratorMetadata) {
                checkExternalEmitHelpers(
                    firstDecorator,
                    ExternalEmitHelpers.Metadata
                );

                // we only need to perform these checks if we are emitting serialized type metadata for the target of a decorator.
                switch (node.kind) {
                    case SyntaxKind.ClassDeclaration:
                        const constructor = getFirstConstructorWithBody(<ClassDeclaration> node);
                        if (constructor) {
                            for (const parameter of constructor.parameters) {
                                markDecoratorMedataDataTypeNodeAsReferenced(getParameterTypeNodeForDecoratorCheck(parameter));
                            }
                        }
                        break;
                    case SyntaxKind.GetAccessor:
                    case SyntaxKind.SetAccessor:
                        const otherKind = node.kind === SyntaxKind.GetAccessor
                            ? SyntaxKind.SetAccessor
                            : SyntaxKind.GetAccessor;
                        const otherAccessor = getDeclarationOfKind<AccessorDeclaration>(
                            getSymbolOfNode(node as AccessorDeclaration),
                            otherKind
                        );
                        markDecoratorMedataDataTypeNodeAsReferenced(
                            getAnnotatedAccessorTypeNode(node as AccessorDeclaration)
                                || otherAccessor
                                && getAnnotatedAccessorTypeNode(otherAccessor)
                        );
                        break;
                    case SyntaxKind.MethodDeclaration:
                        for (const parameter
                            of (<FunctionLikeDeclaration> node).parameters)
                        {
                            markDecoratorMedataDataTypeNodeAsReferenced(getParameterTypeNodeForDecoratorCheck(parameter));
                        }

                        markDecoratorMedataDataTypeNodeAsReferenced(getEffectiveReturnTypeNode(<FunctionLikeDeclaration> node));
                        break;
                    case SyntaxKind.PropertyDeclaration:
                        markDecoratorMedataDataTypeNodeAsReferenced(getEffectiveTypeAnnotationNode(<ParameterDeclaration> node));
                        break;
                    case SyntaxKind.Parameter:
                        markDecoratorMedataDataTypeNodeAsReferenced(getParameterTypeNodeForDecoratorCheck(<ParameterDeclaration> node));
                        const containingSignature = (node as ParameterDeclaration)
                            .parent;
                        for (const parameter of containingSignature
                            .parameters)
                        {
                            markDecoratorMedataDataTypeNodeAsReferenced(getParameterTypeNodeForDecoratorCheck(parameter));
                        }
                        break;
                }
            }

            forEach(node.decorators, checkDecorator);
        }

        function checkFunctionDeclaration(node: FunctionDeclaration): void {
            if (produceDiagnostics) {
                checkFunctionOrMethodDeclaration(node);
                checkGrammarForGenerator(node);
                checkCollisionWithRequireExportsInGeneratedCode(
                    node,
                    node.name!
                );
                checkCollisionWithGlobalPromiseInGeneratedCode(
                    node,
                    node.name!
                );
            }
        }

        function checkJSDocTypeAliasTag(
            node: JSDocTypedefTag | JSDocCallbackTag
        ) {
            if (!node.typeExpression) {
                // If the node had `@property` tags, `typeExpression` would have been set to the first property tag.
                error(
                    node.name,
                    Diagnostics
                        .JSDoc_typedef_tag_should_either_have_a_type_annotation_or_be_followed_by_property_or_member_tags
                );
            }

            if (node.name) {
                checkTypeNameIsReserved(
                    node.name,
                    Diagnostics.Type_alias_name_cannot_be_0
                );
            }
            checkSourceElement(node.typeExpression);
        }

        function checkJSDocTemplateTag(node: JSDocTemplateTag): void {
            checkSourceElement(node.constraint);
            for (const tp of node.typeParameters) {
                checkSourceElement(tp);
            }
        }

        function checkJSDocTypeTag(node: JSDocTypeTag) {
            checkSourceElement(node.typeExpression);
        }

        function checkJSDocParameterTag(node: JSDocParameterTag) {
            checkSourceElement(node.typeExpression);
            if (!getParameterSymbolFromJSDoc(node)) {
                const decl = getHostSignatureFromJSDoc(node);
                // don't issue an error for invalid hosts -- just functions --
                // and give a better error message when the host function mentions `arguments`
                // but the tag doesn't have an array type
                if (decl) {
                    const i = getJSDocTags(decl).filter(isJSDocParameterTag)
                        .indexOf(node);
                    if (i > -1 && i < decl.parameters.length
                        && isBindingPattern(decl.parameters[i].name))
                    {
                        return;
                    }
                    if (!containsArgumentsReference(decl)) {
                        if (isQualifiedName(node.name)) {
                            error(
                                node.name,
                                Diagnostics
                                    .Qualified_name_0_is_not_allowed_without_a_leading_param_object_1,
                                entityNameToString(node.name),
                                entityNameToString(node.name.left)
                            );
                        } else {
                            error(
                                node.name,
                                Diagnostics
                                    .JSDoc_param_tag_has_name_0_but_there_is_no_parameter_with_that_name,
                                idText(node.name)
                            );
                        }
                    } else if (findLast(
                        getJSDocTags(decl),
                        isJSDocParameterTag
                    ) === node
                        && node.typeExpression && node.typeExpression.type
                        && !isArrayType(
                            getTypeFromTypeNode(
                                node.typeExpression.type
                            )
                        ))
                    {
                        error(
                            node.name,
                            Diagnostics
                                .JSDoc_param_tag_has_name_0_but_there_is_no_parameter_with_that_name_It_would_match_arguments_if_it_had_an_array_type,
                            idText(
                                node.name.kind === SyntaxKind.QualifiedName
                                    ? node.name.right
                                    : node.name
                            )
                        );
                    }
                }
            }
        }

        function checkJSDocFunctionType(node: JSDocFunctionType): void {
            if (produceDiagnostics && !node.type
                && !isJSDocConstructSignature(node))
            {
                reportImplicitAny(node, anyType);
            }
            checkSignatureDeclaration(node);
        }

        function checkJSDocAugmentsTag(node: JSDocAugmentsTag): void {
            const classLike = getJSDocHost(node);
            if (!isClassDeclaration(classLike)
                && !isClassExpression(classLike))
            {
                error(
                    classLike,
                    Diagnostics.JSDoc_0_is_not_attached_to_a_class,
                    idText(node.tagName)
                );
                return;
            }

            const augmentsTags = getJSDocTags(classLike)
                .filter(isJSDocAugmentsTag);
            Debug.assert(augmentsTags.length > 0);
            if (augmentsTags.length > 1) {
                error(
                    augmentsTags[1],
                    Diagnostics
                        .Class_declarations_cannot_have_more_than_one_augments_or_extends_tag
                );
            }

            const name = getIdentifierFromEntityNameExpression(
                node.class.expression
            );
            const extend = getClassExtendsHeritageElement(classLike);
            if (extend) {
                const className = getIdentifierFromEntityNameExpression(
                    extend.expression
                );
                if (className && name.escapedText !== className.escapedText) {
                    error(
                        name,
                        Diagnostics
                            .JSDoc_0_1_does_not_match_the_extends_2_clause,
                        idText(node.tagName),
                        idText(name),
                        idText(className)
                    );
                }
            }
        }

        function getIdentifierFromEntityNameExpression(
            node: Identifier | PropertyAccessExpression
        ): Identifier | PrivateIdentifier;
        function getIdentifierFromEntityNameExpression(
            node: Expression
        ): Identifier | PrivateIdentifier | undefined;
        function getIdentifierFromEntityNameExpression(
            node: Expression
        ): Identifier | PrivateIdentifier | undefined {
            switch (node.kind) {
                case SyntaxKind.Identifier:
                    return node as Identifier;
                case SyntaxKind.PropertyAccessExpression:
                    return (node as PropertyAccessExpression).name;
                default:
                    return undefined;
            }
        }

        function checkFunctionOrMethodDeclaration(
            node: FunctionDeclaration | MethodDeclaration | MethodSignature
        ): void {
            checkDecorators(node);
            checkSignatureDeclaration(node);
            const functionFlags = getFunctionFlags(node);

            // Do not use hasDynamicName here, because that returns false for well known symbols.
            // We want to perform checkComputedPropertyName for all computed properties, including
            // well known symbols.
            if (node.name
                && node.name.kind === SyntaxKind.ComputedPropertyName)
            {
                // This check will account for methods in class/interface declarations,
                // as well as accessors in classes/object literals
                checkComputedPropertyName(node.name);
            }

            if (!hasNonBindableDynamicName(node)) {
                // first we want to check the local symbol that contain this declaration
                // - if node.localSymbol !== undefined - this is current declaration is exported and localSymbol points to the local symbol
                // - if node.localSymbol === undefined - this node is non-exported so we can just pick the result of getSymbolOfNode
                const symbol = getSymbolOfNode(node);
                const localSymbol = node.localSymbol || symbol;

                // Since the javascript won't do semantic analysis like typescript,
                // if the javascript file comes before the typescript file and both contain same name functions,
                // checkFunctionOrConstructorSymbol wouldn't be called if we didnt ignore javascript function.
                const firstDeclaration = find(
                    localSymbol.declarations,
                    // Get first non javascript function declaration
                    declaration => declaration.kind === node.kind
                        && !(declaration.flags & NodeFlags.JavaScriptFile)
                );

                // Only type check the symbol once
                if (node === firstDeclaration) {
                    checkFunctionOrConstructorSymbol(localSymbol);
                }

                if (symbol.parent) {
                    // run check once for the first declaration
                    if (getDeclarationOfKind(symbol, node.kind) === node) {
                        // run check on export symbol to check that modifiers agree across all exported declarations
                        checkFunctionOrConstructorSymbol(symbol);
                    }
                }
            }

            const body = node.kind === SyntaxKind.MethodSignature
                ? undefined
                : node.body;
            checkSourceElement(body);
            checkAllCodePathsInNonVoidFunctionReturnOrThrow(
                node,
                getReturnTypeFromAnnotation(node)
            );

            if (produceDiagnostics && !getEffectiveReturnTypeNode(node)) {
                // Report an implicit any error if there is no body, no explicit return type, and node is not a private method
                // in an ambient context
                if (nodeIsMissing(body) && !isPrivateWithinAmbient(node)) {
                    reportImplicitAny(node, anyType);
                }

                if (functionFlags & FunctionFlags.Generator
                    && nodeIsPresent(body))
                {
                    // A generator with a body and no type annotation can still cause errors. It can error if the
                    // yielded values have no common supertype, or it can give an implicit any error if it has no
                    // yielded values. The only way to trigger these errors is to try checking its return type.
                    getReturnTypeOfSignature(getSignatureFromDeclaration(node));
                }
            }

            // A js function declaration can have a @type tag instead of a return type node, but that type must have a call signature
            if (isInJSFile(node)) {
                const typeTag = getJSDocTypeTag(node);
                if (typeTag && typeTag.typeExpression
                    && !getContextualCallSignature(
                        getTypeFromTypeNode(
                            typeTag.typeExpression
                        ),
                        node
                    ))
                {
                    error(
                        typeTag,
                        Diagnostics
                            .The_type_of_a_function_declaration_must_match_the_function_s_signature
                    );
                }
            }
        }

        function registerForUnusedIdentifiersCheck(
            node: PotentiallyUnusedIdentifier
        ): void {
            // May be in a call such as getTypeOfNode that happened to call this. But potentiallyUnusedIdentifiers is only defined in the scope of `checkSourceFile`.
            if (produceDiagnostics) {
                const sourceFile = getSourceFileOfNode(node);
                let potentiallyUnusedIdentifiers = allPotentiallyUnusedIdentifiers
                    .get(sourceFile.path);
                if (!potentiallyUnusedIdentifiers) {
                    potentiallyUnusedIdentifiers = [];
                    allPotentiallyUnusedIdentifiers.set(
                        sourceFile.path,
                        potentiallyUnusedIdentifiers
                    );
                }
                // TODO: GH#22580
                // Debug.assert(addToSeen(seenPotentiallyUnusedIdentifiers, getNodeId(node)), "Adding potentially-unused identifier twice");
                potentiallyUnusedIdentifiers.push(node);
            }
        }

        type PotentiallyUnusedIdentifier = SourceFile | ModuleDeclaration
            | ClassLikeDeclaration | InterfaceDeclaration | Block | CaseBlock
            | ForStatement | ForInStatement | ForOfStatement
            | Exclude<SignatureDeclaration,
                IndexSignatureDeclaration | JSDocFunctionType>
            | TypeAliasDeclaration | InferTypeNode;

        function checkUnusedIdentifiers(
            potentiallyUnusedIdentifiers:
                readonly PotentiallyUnusedIdentifier[],
            addDiagnostic: AddUnusedDiagnostic
        ) {
            for (const node of potentiallyUnusedIdentifiers) {
                switch (node.kind) {
                    case SyntaxKind.ClassDeclaration:
                    case SyntaxKind.ClassExpression:
                        checkUnusedClassMembers(node, addDiagnostic);
                        checkUnusedTypeParameters(node, addDiagnostic);
                        break;
                    case SyntaxKind.SourceFile:
                    case SyntaxKind.ModuleDeclaration:
                    case SyntaxKind.Block:
                    case SyntaxKind.CaseBlock:
                    case SyntaxKind.ForStatement:
                    case SyntaxKind.ForInStatement:
                    case SyntaxKind.ForOfStatement:
                        checkUnusedLocalsAndParameters(node, addDiagnostic);
                        break;
                    case SyntaxKind.Constructor:
                    case SyntaxKind.FunctionExpression:
                    case SyntaxKind.FunctionDeclaration:
                    case SyntaxKind.ArrowFunction:
                    case SyntaxKind.MethodDeclaration:
                    case SyntaxKind.GetAccessor:
                    case SyntaxKind.SetAccessor:
                        if (node
                            .body)
                        { // Don't report unused parameters in overloads
                            checkUnusedLocalsAndParameters(node,
                                addDiagnostic);
                        }
                        checkUnusedTypeParameters(node, addDiagnostic);
                        break;
                    case SyntaxKind.MethodSignature:
                    case SyntaxKind.CallSignature:
                    case SyntaxKind.ConstructSignature:
                    case SyntaxKind.FunctionType:
                    case SyntaxKind.ConstructorType:
                    case SyntaxKind.TypeAliasDeclaration:
                    case SyntaxKind.InterfaceDeclaration:
                        checkUnusedTypeParameters(node, addDiagnostic);
                        break;
                    case SyntaxKind.InferType:
                        checkUnusedInferTypeParameter(node, addDiagnostic);
                        break;
                    default:
                        Debug.assertNever(
                            node,
                            'Node should not have been registered for unused identifiers check'
                        );
                }
            }
        }

        function errorUnusedLocal(
            declaration: Declaration,
            name: string,
            addDiagnostic: AddUnusedDiagnostic
        ) {
            const node = getNameOfDeclaration(declaration) || declaration;
            const message = isTypeDeclaration(declaration)
                ? Diagnostics._0_is_declared_but_never_used
                : Diagnostics._0_is_declared_but_its_value_is_never_read;
            addDiagnostic(
                declaration,
                UnusedKind.Local,
                createDiagnosticForNode(node, message, name)
            );
        }

        function isIdentifierThatStartsWithUnderscore(node: Node) {
            return isIdentifier(node)
                && idText(node).charCodeAt(0) === CharacterCodes._;
        }

        function checkUnusedClassMembers(
            node: ClassDeclaration | ClassExpression,
            addDiagnostic: AddUnusedDiagnostic
        ): void {
            for (const member of node.members) {
                switch (member.kind) {
                    case SyntaxKind.MethodDeclaration:
                    case SyntaxKind.PropertyDeclaration:
                    case SyntaxKind.GetAccessor:
                    case SyntaxKind.SetAccessor:
                        if (member.kind === SyntaxKind.SetAccessor
                            && member.symbol.flags & SymbolFlags.GetAccessor)
                        {
                            // Already would have reported an error on the getter.
                            break;
                        }
                        const symbol = getSymbolOfNode(member);
                        if (!symbol.isReferenced
                            && (hasModifier(member, ModifierFlags.Private)
                                || isNamedDeclaration(member)
                                && isPrivateIdentifier(member.name)))
                        {
                            addDiagnostic(
                                member,
                                UnusedKind.Local,
                                createDiagnosticForNode(
                                    member.name!,
                                    Diagnostics
                                        ._0_is_declared_but_its_value_is_never_read,
                                    symbolToString(symbol)
                                )
                            );
                        }
                        break;
                    case SyntaxKind.Constructor:
                        for (const parameter
                            of (<ConstructorDeclaration> member).parameters)
                        {
                            if (!parameter.symbol.isReferenced
                                && hasModifier(
                                    parameter,
                                    ModifierFlags.Private
                                ))
                            {
                                addDiagnostic(
                                    parameter,
                                    UnusedKind.Local,
                                    createDiagnosticForNode(
                                        parameter.name,
                                        Diagnostics
                                            .Property_0_is_declared_but_its_value_is_never_read,
                                        symbolName(parameter.symbol)
                                    )
                                );
                            }
                        }
                        break;
                    case SyntaxKind.IndexSignature:
                    case SyntaxKind.SemicolonClassElement:
                        // Can't be private
                        break;
                    default:
                        Debug.fail();
                }
            }
        }

        function checkUnusedInferTypeParameter(
            node: InferTypeNode,
            addDiagnostic: AddUnusedDiagnostic
        ): void {
            const { typeParameter } = node;
            if (isTypeParameterUnused(typeParameter)) {
                addDiagnostic(
                    node,
                    UnusedKind.Parameter,
                    createDiagnosticForNode(
                        node,
                        Diagnostics._0_is_declared_but_its_value_is_never_read,
                        idText(typeParameter.name)
                    )
                );
            }
        }

        function checkUnusedTypeParameters(
            node: ClassLikeDeclaration | SignatureDeclaration
                | InterfaceDeclaration | TypeAliasDeclaration,
            addDiagnostic: AddUnusedDiagnostic
        ): void {
            // Only report errors on the last declaration for the type parameter container;
            // this ensures that all uses have been accounted for.
            if (last(getSymbolOfNode(node).declarations) !== node) return;

            const typeParameters = getEffectiveTypeParameterDeclarations(node);
            const seenParentsWithEveryUnused = new NodeSet<DeclarationWithTypeParameterChildren>();

            for (const typeParameter of typeParameters) {
                if (!isTypeParameterUnused(typeParameter)) continue;

                const name = idText(typeParameter.name);
                const { parent } = typeParameter;
                if (parent.kind !== SyntaxKind.InferType
                    && parent.typeParameters!.every(isTypeParameterUnused))
                {
                    if (seenParentsWithEveryUnused.tryAdd(parent)) {
                        const range = isJSDocTemplateTag(parent)
                            ? // Whole @template tag
                            rangeOfNode(parent)
                            : // Include the `<>` in the error message
                            rangeOfTypeParameters(parent.typeParameters!);
                        const only = typeParameters.length === 1;
                        const message = only
                            ? Diagnostics
                                ._0_is_declared_but_its_value_is_never_read
                            : Diagnostics.All_type_parameters_are_unused;
                        const arg0 = only ? name : undefined;
                        addDiagnostic(
                            typeParameter,
                            UnusedKind.Parameter,
                            createFileDiagnostic(
                                getSourceFileOfNode(parent),
                                range.pos,
                                range.end - range.pos,
                                message,
                                arg0
                            )
                        );
                    }
                } else {
                    addDiagnostic(
                        typeParameter,
                        UnusedKind.Parameter,
                        createDiagnosticForNode(
                            typeParameter,
                            Diagnostics
                                ._0_is_declared_but_its_value_is_never_read,
                            name
                        )
                    );
                }
            }
        }
        function isTypeParameterUnused(
            typeParameter: TypeParameterDeclaration
        ): boolean {
            return !(getMergedSymbol(typeParameter.symbol).isReferenced!
                & SymbolFlags.TypeParameter)
                && !isIdentifierThatStartsWithUnderscore(typeParameter.name);
        }

        function addToGroup<K, V>(
            map: Map<[K, V[]]>,
            key: K,
            value: V,
            getKey: (key: K) => number | string
        ): void {
            const keyString = String(getKey(key));
            const group = map.get(keyString);
            if (group) {
                group[1].push(value);
            } else {
                map.set(keyString, [key, [value]]);
            }
        }

        function tryGetRootParameterDeclaration(
            node: Node
        ): ParameterDeclaration | undefined {
            return tryCast(getRootDeclaration(node), isParameter);
        }

        function checkUnusedLocalsAndParameters(
            nodeWithLocals: Node,
            addDiagnostic: AddUnusedDiagnostic
        ): void {
            // Ideally we could use the ImportClause directly as a key, but must wait until we have full ES6 maps. So must store key along with value.
            const unusedImports = createMap<[ImportClause,
                ImportedDeclaration[]]>();
            const unusedDestructures = createMap<[ObjectBindingPattern,
                BindingElement[]]>();
            const unusedVariables = createMap<[VariableDeclarationList,
                VariableDeclaration[]]>();
            nodeWithLocals.locals!.forEach(local => {
                // If it's purely a type parameter, ignore, will be checked in `checkUnusedTypeParameters`.
                // If it's a type parameter merged with a parameter, check if the parameter-side is used.
                if (local.flags & SymbolFlags.TypeParameter
                    ? !(local.flags & SymbolFlags.Variable
                        && !(local.isReferenced! & SymbolFlags.Variable))
                    : local.isReferenced || local.exportSymbol)
                {
                    return;
                }

                for (const declaration of local.declarations) {
                    if (isAmbientModule(declaration)
                        || (isVariableDeclaration(declaration)
                            && isForInOrOfStatement(declaration.parent.parent)
                            || isImportedDeclaration(declaration))
                        && isIdentifierThatStartsWithUnderscore(
                            declaration.name!
                        ))
                    {
                        continue;
                    }

                    if (isImportedDeclaration(declaration)) {
                        addToGroup(
                            unusedImports,
                            importClauseFromImported(declaration),
                            declaration,
                            getNodeId
                        );
                    } else if (isBindingElement(declaration)
                        && isObjectBindingPattern(declaration.parent))
                    {
                        // In `{ a, ...b }, `a` is considered used since it removes a property from `b`. `b` may still be unused though.
                        const lastElement = last(declaration.parent.elements);
                        if (declaration === lastElement
                            || !last(declaration.parent.elements)
                                .dotDotDotToken)
                        {
                            addToGroup(
                                unusedDestructures,
                                declaration.parent,
                                declaration,
                                getNodeId
                            );
                        }
                    } else if (isVariableDeclaration(declaration)) {
                        addToGroup(
                            unusedVariables,
                            declaration.parent,
                            declaration,
                            getNodeId
                        );
                    } else {
                        const parameter = local.valueDeclaration
                            && tryGetRootParameterDeclaration(
                                local.valueDeclaration
                            );
                        const name = local.valueDeclaration
                            && getNameOfDeclaration(local.valueDeclaration);
                        if (parameter && name) {
                            if (!isParameterPropertyDeclaration(
                                parameter,
                                parameter.parent
                            ) && !parameterIsThisKeyword(parameter)
                                && !isIdentifierThatStartsWithUnderscore(name))
                            {
                                addDiagnostic(
                                    parameter,
                                    UnusedKind.Parameter,
                                    createDiagnosticForNode(
                                        name,
                                        Diagnostics
                                            ._0_is_declared_but_its_value_is_never_read,
                                        symbolName(local)
                                    )
                                );
                            }
                        } else {
                            errorUnusedLocal(
                                declaration,
                                symbolName(local),
                                addDiagnostic
                            );
                        }
                    }
                }
            });
            unusedImports.forEach(([importClause, unuseds]) => {
                const importDecl = importClause.parent;
                const nDeclarations = (importClause.name ? 1 : 0)
                    + (importClause.namedBindings
                        ? (importClause.namedBindings.kind
                            === SyntaxKind.NamespaceImport
                            ? 1
                            : importClause.namedBindings.elements.length)
                        : 0);
                if (nDeclarations === unuseds.length) {
                    addDiagnostic(
                        importDecl,
                        UnusedKind.Local,
                        unuseds.length === 1
                            ? createDiagnosticForNode(
                                importDecl,
                                Diagnostics
                                    ._0_is_declared_but_its_value_is_never_read,
                                idText(first(unuseds).name!)
                            )
                            : createDiagnosticForNode(
                                importDecl,
                                Diagnostics
                                    .All_imports_in_import_declaration_are_unused
                            )
                    );
                } else {
                    for (const unused of unuseds) {
                        errorUnusedLocal(
                            unused,
                            idText(unused.name!),
                            addDiagnostic
                        );
                    }
                }
            });
            unusedDestructures.forEach(([bindingPattern, bindingElements]) => {
                const kind = tryGetRootParameterDeclaration(
                    bindingPattern.parent
                )
                    ? UnusedKind.Parameter
                    : UnusedKind.Local;
                if (bindingPattern.elements.length
                    === bindingElements.length)
                {
                    if (bindingElements.length === 1
                        && bindingPattern.parent.kind
                        === SyntaxKind.VariableDeclaration
                        && bindingPattern.parent.parent.kind
                        === SyntaxKind.VariableDeclarationList)
                    {
                        addToGroup(
                            unusedVariables,
                            bindingPattern.parent.parent,
                            bindingPattern.parent,
                            getNodeId
                        );
                    } else {
                        addDiagnostic(
                            bindingPattern,
                            kind,
                            bindingElements.length === 1
                                ? createDiagnosticForNode(
                                    bindingPattern,
                                    Diagnostics
                                        ._0_is_declared_but_its_value_is_never_read,
                                    bindingNameText(
                                        first(bindingElements).name
                                    )
                                )
                                : createDiagnosticForNode(
                                    bindingPattern,
                                    Diagnostics
                                        .All_destructured_elements_are_unused
                                )
                        );
                    }
                } else {
                    for (const e of bindingElements) {
                        addDiagnostic(
                            e,
                            kind,
                            createDiagnosticForNode(
                                e,
                                Diagnostics
                                    ._0_is_declared_but_its_value_is_never_read,
                                bindingNameText(e.name)
                            )
                        );
                    }
                }
            });
            unusedVariables.forEach(([declarationList, declarations]) => {
                if (declarationList.declarations.length
                    === declarations.length)
                {
                    addDiagnostic(
                        declarationList,
                        UnusedKind.Local,
                        declarations.length === 1
                            ? createDiagnosticForNode(
                                first(declarations).name,
                                Diagnostics
                                    ._0_is_declared_but_its_value_is_never_read,
                                bindingNameText(first(declarations).name)
                            )
                            : createDiagnosticForNode(
                                declarationList.parent.kind
                                    === SyntaxKind.VariableStatement
                                    ? declarationList.parent
                                    : declarationList,
                                Diagnostics.All_variables_are_unused
                            )
                    );
                } else {
                    for (const decl of declarations) {
                        addDiagnostic(
                            decl,
                            UnusedKind.Local,
                            createDiagnosticForNode(
                                decl,
                                Diagnostics
                                    ._0_is_declared_but_its_value_is_never_read,
                                bindingNameText(decl.name)
                            )
                        );
                    }
                }
            });
        }

        function bindingNameText(name: BindingName): string {
            switch (name.kind) {
                case SyntaxKind.Identifier:
                    return idText(name);
                case SyntaxKind.ArrayBindingPattern:
                case SyntaxKind.ObjectBindingPattern:
                    return bindingNameText(
                        cast(
                            first(name.elements),
                            isBindingElement
                        ).name
                    );
                default:
                    return Debug.assertNever(name);
            }
        }

        type ImportedDeclaration = ImportClause | ImportSpecifier
            | NamespaceImport;
        function isImportedDeclaration(node:
            Node): node is ImportedDeclaration
        {
            return node.kind === SyntaxKind.ImportClause
                || node.kind === SyntaxKind.ImportSpecifier
                || node.kind === SyntaxKind.NamespaceImport;
        }
        function importClauseFromImported(
            decl: ImportedDeclaration
        ): ImportClause {
            return decl.kind === SyntaxKind.ImportClause
                ? decl
                : decl.kind === SyntaxKind.NamespaceImport ? decl.parent
                    : decl.parent.parent;
        }

        function checkBlock(node: Block) {
            // Grammar checking for SyntaxKind.Block
            if (node.kind === SyntaxKind.Block) {
                checkGrammarStatementInAmbientContext(node);
            }
            if (isFunctionOrModuleBlock(node)) {
                const saveFlowAnalysisDisabled = flowAnalysisDisabled;
                forEach(node.statements, checkSourceElement);
                flowAnalysisDisabled = saveFlowAnalysisDisabled;
            } else {
                forEach(node.statements, checkSourceElement);
            }
            if (node.locals) {
                registerForUnusedIdentifiersCheck(node);
            }
        }

        function checkCollisionWithArgumentsInGeneratedCode(
            node: SignatureDeclaration
        ) {
            // no rest parameters \ declaration context \ overload - no codegen impact
            if (languageVersion >= ScriptTarget.ES2015
                || compilerOptions.noEmit || !hasRestParameter(node)
                || node.flags & NodeFlags.Ambient
                || nodeIsMissing((<FunctionLikeDeclaration> node).body))
            {
                return;
            }

            forEach(
                node.parameters,
                p => {
                    if (p.name && !isBindingPattern(p.name)
                        && p.name.escapedText === argumentsSymbol.escapedName)
                    {
                        error(
                            p,
                            Diagnostics
                                .Duplicate_identifier_arguments_Compiler_uses_arguments_to_initialize_rest_parameters
                        );
                    }
                }
            );
        }

        function needCollisionCheckForIdentifier(
            node: Node,
            identifier: Identifier | undefined,
            name: string
        ): boolean {
            if (!(identifier && identifier.escapedText === name)) {
                return false;
            }

            if (node.kind === SyntaxKind.PropertyDeclaration
                || node.kind === SyntaxKind.PropertySignature
                || node.kind === SyntaxKind.MethodDeclaration
                || node.kind === SyntaxKind.MethodSignature
                || node.kind === SyntaxKind.GetAccessor
                || node.kind === SyntaxKind.SetAccessor)
            {
                // it is ok to have member named '_super' or '_this' - member access is always qualified
                return false;
            }

            if (node.flags & NodeFlags.Ambient) {
                // ambient context - no codegen impact
                return false;
            }

            const root = getRootDeclaration(node);
            if (root.kind === SyntaxKind.Parameter
                && nodeIsMissing((<FunctionLikeDeclaration> root.parent).body))
            {
                // just an overload - no codegen impact
                return false;
            }

            return true;
        }

        // this function will run after checking the source file so 'CaptureThis' is correct for all nodes
        function checkIfThisIsCapturedInEnclosingScope(node: Node): void {
            findAncestor(
                node,
                current => {
                    if (getNodeCheckFlags(current)
                        & NodeCheckFlags.CaptureThis)
                    {
                        const isDeclaration = node.kind
                            !== SyntaxKind.Identifier;
                        if (isDeclaration) {
                            error(getNameOfDeclaration(<Declaration> node),
                                Diagnostics
                                    .Duplicate_identifier_this_Compiler_uses_variable_declaration_this_to_capture_this_reference);
                        } else {
                            error(
                                node,
                                Diagnostics
                                    .Expression_resolves_to_variable_declaration_this_that_compiler_uses_to_capture_this_reference
                            );
                        }
                        return true;
                    }
                    return false;
                }
            );
        }

        function checkIfNewTargetIsCapturedInEnclosingScope(node: Node): void {
            findAncestor(
                node,
                current => {
                    if (getNodeCheckFlags(current)
                        & NodeCheckFlags.CaptureNewTarget)
                    {
                        const isDeclaration = node.kind
                            !== SyntaxKind.Identifier;
                        if (isDeclaration) {
                            error(
                                getNameOfDeclaration(<Declaration> node),
                                Diagnostics
                                    .Duplicate_identifier_newTarget_Compiler_uses_variable_declaration_newTarget_to_capture_new_target_meta_property_reference
                            );
                        } else {
                            error(
                                node,
                                Diagnostics
                                    .Expression_resolves_to_variable_declaration_newTarget_that_compiler_uses_to_capture_new_target_meta_property_reference
                            );
                        }
                        return true;
                    }
                    return false;
                }
            );
        }

        function checkWeakMapCollision(node: Node) {
            const enclosingBlockScope = getEnclosingBlockScopeContainer(node);
            if (getNodeCheckFlags(enclosingBlockScope)
                & NodeCheckFlags.ContainsClassWithPrivateIdentifiers)
            {
                error(
                    node,
                    Diagnostics
                        .Compiler_reserves_name_0_when_emitting_private_identifier_downlevel,
                    'WeakMap'
                );
            }
        }

        function checkCollisionWithRequireExportsInGeneratedCode(
            node: Node,
            name: Identifier
        ) {
            // No need to check for require or exports for ES6 modules and later
            if (moduleKind >= ModuleKind.ES2015 || compilerOptions.noEmit) {
                return;
            }

            if (!needCollisionCheckForIdentifier(node, name, 'require')
                && !needCollisionCheckForIdentifier(node, name, 'exports'))
            {
                return;
            }

            // Uninstantiated modules shouldnt do this check
            if (isModuleDeclaration(node)
                && getModuleInstanceState(node)
                !== ModuleInstanceState.Instantiated)
            {
                return;
            }

            // In case of variable declaration, node.parent is variable statement so look at the variable statement's parent
            const parent = getDeclarationContainer(node);
            if (parent.kind === SyntaxKind.SourceFile
                && isExternalOrCommonJsModule(<SourceFile> parent))
            {
                // If the declaration happens to be in external module, report error that require and exports are reserved keywords
                error(
                    name,
                    Diagnostics
                        .Duplicate_identifier_0_Compiler_reserves_name_1_in_top_level_scope_of_a_module,
                    declarationNameToString(name),
                    declarationNameToString(name)
                );
            }
        }

        function checkCollisionWithGlobalPromiseInGeneratedCode(
            node: Node,
            name: Identifier
        ): void {
            if (languageVersion >= ScriptTarget.ES2017
                || compilerOptions.noEmit
                || !needCollisionCheckForIdentifier(node, name, 'Promise'))
            {
                return;
            }

            // Uninstantiated modules shouldnt do this check
            if (isModuleDeclaration(node)
                && getModuleInstanceState(node)
                !== ModuleInstanceState.Instantiated)
            {
                return;
            }

            // In case of variable declaration, node.parent is variable statement so look at the variable statement's parent
            const parent = getDeclarationContainer(node);
            if (parent.kind === SyntaxKind.SourceFile
                && isExternalOrCommonJsModule(<SourceFile> parent)
                && parent.flags & NodeFlags.HasAsyncFunctions)
            {
                // If the declaration happens to be in external module, report error that Promise is a reserved identifier.
                error(
                    name,
                    Diagnostics
                        .Duplicate_identifier_0_Compiler_reserves_name_1_in_top_level_scope_of_a_module_containing_async_functions,
                    declarationNameToString(name),
                    declarationNameToString(name)
                );
            }
        }

        function checkVarDeclaredNamesNotShadowed(
            node: VariableDeclaration | BindingElement
        ) {
            // - ScriptBody : StatementList
            // It is a Syntax Error if any element of the LexicallyDeclaredNames of StatementList
            // also occurs in the VarDeclaredNames of StatementList.

            // - Block : { StatementList }
            // It is a Syntax Error if any element of the LexicallyDeclaredNames of StatementList
            // also occurs in the VarDeclaredNames of StatementList.

            // Variable declarations are hoisted to the top of their function scope. They can shadow
            // block scoped declarations, which bind tighter. this will not be flagged as duplicate definition
            // by the binder as the declaration scope is different.
            // A non-initialized declaration is a no-op as the block declaration will resolve before the var
            // declaration. the problem is if the declaration has an initializer. this will act as a write to the
            // block declared value. this is fine for let, but not const.
            // Only consider declarations with initializers, uninitialized const declarations will not
            // step on a let/const variable.
            // Do not consider const and const declarations, as duplicate block-scoped declarations
            // are handled by the binder.
            // We are only looking for const declarations that step on let\const declarations from a
            // different scope. e.g.:
            //      {
            //          const x = 0; // localDeclarationSymbol obtained after name resolution will correspond to this declaration
            //          const x = 0; // symbol for this declaration will be 'symbol'
            //      }

            // skip block-scoped variables and parameters
            if ((getCombinedNodeFlags(node) & NodeFlags.BlockScoped) !== 0
                || isParameterDeclaration(node))
            {
                return;
            }

            // skip variable declarations that don't have initializers
            // NOTE: in ES6 spec initializer is required in variable declarations where name is binding pattern
            // so we'll always treat binding elements as initialized
            if (node.kind === SyntaxKind.VariableDeclaration
                && !node.initializer)
            {
                return;
            }

            const symbol = getSymbolOfNode(node);
            if (symbol.flags & SymbolFlags.FunctionScopedVariable) {
                if (!isIdentifier(node.name)) return Debug.fail();
                const localDeclarationSymbol = resolveName(
                    node,
                    node.name.escapedText,
                    SymbolFlags.Variable, /*nodeNotFoundErrorMessage*/
                    undefined, /*nameArg*/
                    undefined, /*isUse*/
                    false
                );
                if (localDeclarationSymbol
                    && localDeclarationSymbol !== symbol
                    && localDeclarationSymbol.flags
                    & SymbolFlags.BlockScopedVariable)
                {
                    if (getDeclarationNodeFlagsFromSymbol(localDeclarationSymbol)
                        & NodeFlags.BlockScoped)
                    {
                        const varDeclList = getAncestor(
                            localDeclarationSymbol.valueDeclaration,
                            SyntaxKind.VariableDeclarationList
                        )!;
                        const container = varDeclList.parent.kind
                            === SyntaxKind.VariableStatement
                            && varDeclList.parent.parent
                            ? varDeclList.parent.parent
                            : undefined;

                        // names of block-scoped and function scoped variables can collide only
                        // if block scoped variable is defined in the function\module\source file scope (because of variable hoisting)
                        const namesShareScope = container
                            && (container.kind === SyntaxKind.Block
                                && isFunctionLike(container.parent)
                                || container.kind === SyntaxKind.ModuleBlock
                                || container.kind
                                === SyntaxKind.ModuleDeclaration
                                || container.kind === SyntaxKind.SourceFile);

                        // here we know that function scoped variable is shadowed by block scoped one
                        // if they are defined in the same scope - binder has already reported redeclaration error
                        // otherwise if variable has an initializer - show error that initialization will fail
                        // since LHS will be block scoped name instead of function scoped
                        if (!namesShareScope) {
                            const name = symbolToString(localDeclarationSymbol);
                            error(
                                node,
                                Diagnostics
                                    .Cannot_initialize_outer_scoped_variable_0_in_the_same_scope_as_block_scoped_declaration_1,
                                name,
                                name
                            );
                        }
                    }
                }
            }
        }

        function convertAutoToAny(type: Type) {
            return type === autoType
                ? anyType
                : type === autoArrayType ? anyArrayType : type;
        }

        // Check variable, parameter, or property declaration
        function checkVariableLikeDeclaration(
            node: ParameterDeclaration | PropertyDeclaration
                | PropertySignature | VariableDeclaration | BindingElement
        ) {
            checkDecorators(node);
            if (!isBindingElement(node)) {
                checkSourceElement(node.type);
            }

            // JSDoc `function(string, string): string` syntax results in parameters with no name
            if (!node.name) {
                return;
            }
            // For a computed property, just check the initializer and exit
            // Do not use hasDynamicName here, because that returns false for well known symbols.
            // We want to perform checkComputedPropertyName for all computed properties, including
            // well known symbols.
            if (node.name.kind === SyntaxKind.ComputedPropertyName) {
                checkComputedPropertyName(node.name);
                if (node.initializer) {
                    checkExpressionCached(node.initializer);
                }
            }

            if (node.kind === SyntaxKind.BindingElement) {
                if (node.parent.kind === SyntaxKind.ObjectBindingPattern
                    && languageVersion < ScriptTarget.ESNext)
                {
                    checkExternalEmitHelpers(node, ExternalEmitHelpers.Rest);
                }
                // check computed properties inside property names of binding elements
                if (node.propertyName
                    && node.propertyName.kind
                    === SyntaxKind.ComputedPropertyName)
                {
                    checkComputedPropertyName(node.propertyName);
                }

                // check private/protected variable access
                const parent = node.parent.parent;
                const parentType = getTypeForBindingElementParent(parent);
                const name = node.propertyName || node.name;
                if (parentType && !isBindingPattern(name)) {
                    const exprType = getLiteralTypeFromPropertyName(name);
                    if (isTypeUsableAsPropertyName(exprType)) {
                        const nameText = getPropertyNameFromType(exprType);
                        const property = getPropertyOfType(
                            parentType,
                            nameText
                        );
                        if (property) {
                            markPropertyAsReferenced(
                                property, /*nodeForCheckWriteOnly*/
                                undefined, /*isThisAccess*/
                                false
                            ); // A destructuring is never a write-only reference.
                            checkPropertyAccessibility(
                                parent,
                                !!parent.initializer
                                    && parent.initializer.kind
                                    === SyntaxKind.SuperKeyword,
                                parentType,
                                property
                            );
                        }
                    }
                }
            }

            // For a binding pattern, check contained binding elements
            if (isBindingPattern(node.name)) {
                if (node.name.kind === SyntaxKind.ArrayBindingPattern
                    && languageVersion < ScriptTarget.ES2015
                    && compilerOptions.downlevelIteration)
                {
                    checkExternalEmitHelpers(node, ExternalEmitHelpers.Read);
                }

                forEach(node.name.elements, checkSourceElement);
            }
            // For a parameter declaration with an initializer, error and exit if the containing function doesn't have a body
            if (node.initializer
                && getRootDeclaration(node).kind === SyntaxKind.Parameter
                && nodeIsMissing(
                    (getContainingFunction(node) as FunctionLikeDeclaration)
                        .body
                ))
            {
                error(
                    node,
                    Diagnostics
                        .A_parameter_initializer_is_only_allowed_in_a_function_or_constructor_implementation
                );
                return;
            }
            // For a binding pattern, validate the initializer and exit
            if (isBindingPattern(node.name)) {
                const needCheckInitializer = node.initializer
                    && node.parent.parent.kind !== SyntaxKind.ForInStatement;
                const needCheckWidenedType = node.name.elements.length === 0;
                if (needCheckInitializer || needCheckWidenedType) {
                    // Don't validate for-in initializer as it is already an error
                    const widenedType = getWidenedTypeForVariableLikeDeclaration(node);
                    if (needCheckInitializer) {
                        const initializerType = checkExpressionCached(
                            node.initializer!
                        );
                        if (strictNullChecks && needCheckWidenedType) {
                            checkNonNullNonVoidType(initializerType, node);
                        } else {
                            checkTypeAssignableToAndOptionallyElaborate(
                                initializerType,
                                getWidenedTypeForVariableLikeDeclaration(node),
                                node,
                                node.initializer
                            );
                        }
                    }
                    // check the binding pattern with empty elements
                    if (needCheckWidenedType) {
                        if (isArrayBindingPattern(node.name)) {
                            checkIteratedTypeOrElementType(
                                IterationUse.Destructuring,
                                widenedType,
                                undefinedType,
                                node
                            );
                        } else if (strictNullChecks) {
                            checkNonNullNonVoidType(widenedType, node);
                        }
                    }
                }
                return;
            }
            const symbol = getSymbolOfNode(node);
            const type = convertAutoToAny(getTypeOfSymbol(symbol));
            if (node === symbol.valueDeclaration) {
                // Node is the primary declaration of the symbol, just validate the initializer
                // Don't validate for-in initializer as it is already an error
                const initializer = getEffectiveInitializer(node);
                if (initializer) {
                    const isJSObjectLiteralInitializer = isInJSFile(node)
                        && isObjectLiteralExpression(initializer)
                        && (initializer.properties.length === 0
                            || isPrototypeAccess(node.name))
                        && hasEntries(symbol.exports);
                    if (!isJSObjectLiteralInitializer
                        && node.parent.parent.kind
                        !== SyntaxKind.ForInStatement)
                    {
                        checkTypeAssignableToAndOptionallyElaborate(
                            checkExpressionCached(initializer),
                            type,
                            node,
                            initializer, /*headMessage*/
                            undefined
                        );
                    }
                }
                if (symbol.declarations.length > 1) {
                    if (some(
                        symbol.declarations,
                        d => d !== node && isVariableLike(d)
                            && !areDeclarationFlagsIdentical(d, node)
                    )) {
                        error(
                            node.name,
                            Diagnostics
                                .All_declarations_of_0_must_have_identical_modifiers,
                            declarationNameToString(node.name)
                        );
                    }
                }
            } else {
                // Node is a secondary declaration, check that type is identical to primary declaration and check that
                // initializer is consistent with type associated with the node
                const declarationType = convertAutoToAny(getWidenedTypeForVariableLikeDeclaration(node));

                if (type !== errorType && declarationType !== errorType
                    && !isTypeIdenticalTo(type, declarationType)
                    && !(symbol.flags & SymbolFlags.Assignment))
                {
                    errorNextVariableOrPropertyDeclarationMustHaveSameType(
                        symbol.valueDeclaration,
                        type,
                        node,
                        declarationType
                    );
                }
                if (node.initializer) {
                    checkTypeAssignableToAndOptionallyElaborate(
                        checkExpressionCached(
                            node.initializer
                        ),
                        declarationType,
                        node,
                        node.initializer, /*headMessage*/
                        undefined
                    );
                }
                if (!areDeclarationFlagsIdentical(
                    node,
                    symbol.valueDeclaration
                )) {
                    error(
                        node.name,
                        Diagnostics
                            .All_declarations_of_0_must_have_identical_modifiers,
                        declarationNameToString(node.name)
                    );
                }
            }
            if (node.kind !== SyntaxKind.PropertyDeclaration
                && node.kind !== SyntaxKind.PropertySignature)
            {
                // We know we don't have a binding pattern or computed name here
                checkExportsOnMergedDeclarations(node);
                if (node.kind === SyntaxKind.VariableDeclaration
                    || node.kind === SyntaxKind.BindingElement)
                {
                    checkVarDeclaredNamesNotShadowed(node);
                }
                checkCollisionWithRequireExportsInGeneratedCode(
                    node,
                    <Identifier> node.name
                );
                checkCollisionWithGlobalPromiseInGeneratedCode(
                    node,
                    <Identifier> node.name
                );
                if (!compilerOptions.noEmit
                    && languageVersion < ScriptTarget.ESNext
                    && needCollisionCheckForIdentifier(
                        node,
                        node.name as Identifier,
                        'WeakMap'
                    ))
                {
                    potentialWeakMapCollisions.push(node);
                }
            }
        }

        function errorNextVariableOrPropertyDeclarationMustHaveSameType(
            firstDeclaration: Declaration | undefined,
            firstType: Type,
            nextDeclaration: Declaration,
            nextType: Type
        ): void {
            const nextDeclarationName = getNameOfDeclaration(nextDeclaration);
            const message = nextDeclaration.kind
                === SyntaxKind.PropertyDeclaration
                || nextDeclaration.kind === SyntaxKind.PropertySignature
                ? Diagnostics
                    .Subsequent_property_declarations_must_have_the_same_type_Property_0_must_be_of_type_1_but_here_has_type_2
                : Diagnostics
                    .Subsequent_variable_declarations_must_have_the_same_type_Variable_0_must_be_of_type_1_but_here_has_type_2;
            const declName = declarationNameToString(nextDeclarationName);
            const err = error(
                nextDeclarationName,
                message,
                declName,
                typeToString(firstType),
                typeToString(nextType)
            );
            if (firstDeclaration) {
                addRelatedInfo(
                    err,
                    createDiagnosticForNode(
                        firstDeclaration,
                        Diagnostics._0_was_also_declared_here,
                        declName
                    )
                );
            }
        }

        function areDeclarationFlagsIdentical(
            left: Declaration,
            right: Declaration
        ) {
            if ((left.kind === SyntaxKind.Parameter
                && right.kind === SyntaxKind.VariableDeclaration)
                || (left.kind === SyntaxKind.VariableDeclaration
                    && right.kind === SyntaxKind.Parameter))
            {
                // Differences in optionality between parameters and variables are allowed.
                return true;
            }

            if (hasQuestionToken(left) !== hasQuestionToken(right)) {
                return false;
            }

            const interestingFlags = ModifierFlags.Private
                | ModifierFlags.Protected
                | ModifierFlags.Async
                | ModifierFlags.Abstract
                | ModifierFlags.Readonly
                | ModifierFlags.Static;

            return getSelectedModifierFlags(left, interestingFlags)
                === getSelectedModifierFlags(right, interestingFlags);
        }

        function checkVariableDeclaration(node: VariableDeclaration) {
            checkGrammarVariableDeclaration(node);
            return checkVariableLikeDeclaration(node);
        }

        function checkBindingElement(node: BindingElement) {
            checkGrammarBindingElement(node);
            return checkVariableLikeDeclaration(node);
        }

        function checkVariableStatement(node: VariableStatement) {
            // Grammar checking
            if (!checkGrammarDecoratorsAndModifiers(node)
                && !checkGrammarVariableDeclarationList(node.declarationList))
            {
                checkGrammarForDisallowedLetOrConstStatement(node);
            }
            forEach(node.declarationList.declarations, checkSourceElement);
        }

        function checkExpressionStatement(node: ExpressionStatement) {
            // Grammar checking
            checkGrammarStatementInAmbientContext(node);

            checkExpression(node.expression);
        }

        function checkIfStatement(node: IfStatement) {
            // Grammar checking
            checkGrammarStatementInAmbientContext(node);

            const type = checkTruthinessExpression(node.expression);
            checkTestingKnownTruthyCallableType(node, type);
            checkSourceElement(node.thenStatement);

            if (node.thenStatement.kind === SyntaxKind.EmptyStatement) {
                error(
                    node.thenStatement,
                    Diagnostics
                        .The_body_of_an_if_statement_cannot_be_the_empty_statement
                );
            }

            checkSourceElement(node.elseStatement);
        }

        function checkTestingKnownTruthyCallableType(
            ifStatement: IfStatement,
            type: Type
        ) {
            if (!strictNullChecks) {
                return;
            }

            const testedNode = isIdentifier(ifStatement.expression)
                ? ifStatement.expression
                : isPropertyAccessExpression(ifStatement.expression)
                    ? ifStatement.expression.name
                    : undefined;

            if (!testedNode) {
                return;
            }

            const possiblyFalsy = getFalsyFlags(type);
            if (possiblyFalsy) {
                return;
            }

            // While it technically should be invalid for any known-truthy value
            // to be tested, we de-scope to functions unrefenced in the block as a
            // heuristic to identify the most common bugs. There are too many
            // false positives for values sourced from type definitions without
            // strictNullChecks otherwise.
            const callSignatures = getSignaturesOfType(
                type,
                SignatureKind.Call
            );
            if (callSignatures.length === 0) {
                return;
            }

            const testedFunctionSymbol = getSymbolAtLocation(testedNode);
            if (!testedFunctionSymbol) {
                return;
            }

            const functionIsUsedInBody = forEachChild(
                ifStatement.thenStatement,
                function check(childNode): boolean | undefined {
                    if (isIdentifier(childNode)) {
                        const childSymbol = getSymbolAtLocation(childNode);
                        if (childSymbol
                            && childSymbol.id === testedFunctionSymbol.id)
                        {
                            return true;
                        }
                    }

                    return forEachChild(childNode, check);
                }
            );

            if (!functionIsUsedInBody) {
                error(
                    ifStatement.expression,
                    Diagnostics
                        .This_condition_will_always_return_true_since_the_function_is_always_defined_Did_you_mean_to_call_it_instead
                );
            }
        }

        function checkDoStatement(node: DoStatement) {
            // Grammar checking
            checkGrammarStatementInAmbientContext(node);

            checkSourceElement(node.statement);
            checkTruthinessExpression(node.expression);
        }

        function checkWhileStatement(node: WhileStatement) {
            // Grammar checking
            checkGrammarStatementInAmbientContext(node);

            checkTruthinessExpression(node.expression);
            checkSourceElement(node.statement);
        }

        function checkTruthinessExpression(
            node: Expression,
            checkMode?: CheckMode
        ) {
            const type = checkExpression(node, checkMode);
            if (type.flags & TypeFlags.Void) {
                error(
                    node,
                    Diagnostics
                        .An_expression_of_type_void_cannot_be_tested_for_truthiness
                );
            }
            return type;
        }

        function checkForStatement(node: ForStatement) {
            // Grammar checking
            if (!checkGrammarStatementInAmbientContext(node)) {
                if (node.initializer
                    && node.initializer.kind
                    === SyntaxKind.VariableDeclarationList)
                {
                    checkGrammarVariableDeclarationList(
                        <VariableDeclarationList> node.initializer
                    );
                }
            }

            if (node.initializer) {
                if (node.initializer.kind
                    === SyntaxKind.VariableDeclarationList)
                {
                    forEach(
                        (<VariableDeclarationList> node.initializer)
                            .declarations,
                        checkVariableDeclaration
                    );
                } else {
                    checkExpression(node.initializer);
                }
            }

            if (node.condition) checkTruthinessExpression(node.condition);
            if (node.incrementor) checkExpression(node.incrementor);
            checkSourceElement(node.statement);
            if (node.locals) {
                registerForUnusedIdentifiersCheck(node);
            }
        }

        function checkForOfStatement(node: ForOfStatement): void {
            checkGrammarForInOrForOfStatement(node);

            if (node.awaitModifier) {
                const functionFlags = getFunctionFlags(getContainingFunction(node));
                if ((functionFlags
                    & (FunctionFlags.Invalid | FunctionFlags.Async))
                    === FunctionFlags.Async
                    && languageVersion < ScriptTarget.ESNext)
                {
                    // for..await..of in an async function or async generator function prior to ESNext requires the __asyncValues helper
                    checkExternalEmitHelpers(
                        node,
                        ExternalEmitHelpers.ForAwaitOfIncludes
                    );
                }
            } else if (compilerOptions.downlevelIteration
                && languageVersion < ScriptTarget.ES2015)
            {
                // for..of prior to ES2015 requires the __values helper when downlevelIteration is enabled
                checkExternalEmitHelpers(
                    node,
                    ExternalEmitHelpers.ForOfIncludes
                );
            }

            // Check the LHS and RHS
            // If the LHS is a declaration, just check it as a variable declaration, which will in turn check the RHS
            // via checkRightHandSideOfForOf.
            // If the LHS is an expression, check the LHS, as a destructuring assignment or as a reference.
            // Then check that the RHS is assignable to it.
            if (node.initializer.kind === SyntaxKind.VariableDeclarationList) {
                checkForInOrForOfVariableDeclaration(node);
            } else {
                const varExpr = node.initializer;
                const iteratedType = checkRightHandSideOfForOf(
                    node.expression,
                    node.awaitModifier
                );

                // There may be a destructuring assignment on the left side
                if (varExpr.kind === SyntaxKind.ArrayLiteralExpression
                    || varExpr.kind === SyntaxKind.ObjectLiteralExpression)
                {
                    // iteratedType may be undefined. In this case, we still want to check the structure of
                    // varExpr, in particular making sure it's a valid LeftHandSideExpression. But we'd like
                    // to short circuit the type relation checking as much as possible, so we pass the unknownType.
                    checkDestructuringAssignment(
                        varExpr,
                        iteratedType || errorType
                    );
                } else {
                    const leftType = checkExpression(varExpr);
                    checkReferenceExpression(
                        varExpr,
                        Diagnostics
                            .The_left_hand_side_of_a_for_of_statement_must_be_a_variable_or_a_property_access,
                        Diagnostics
                            .The_left_hand_side_of_a_for_of_statement_may_not_be_an_optional_property_access
                    );

                    // iteratedType will be undefined if the rightType was missing properties/signatures
                    // required to get its iteratedType (like [Symbol.iterator] or next). This may be
                    // because we accessed properties from anyType, or it may have led to an error inside
                    // getElementTypeOfIterable.
                    if (iteratedType) {
                        checkTypeAssignableToAndOptionallyElaborate(
                            iteratedType,
                            leftType,
                            varExpr,
                            node.expression
                        );
                    }
                }
            }

            checkSourceElement(node.statement);
            if (node.locals) {
                registerForUnusedIdentifiersCheck(node);
            }
        }

        function checkForInStatement(node: ForInStatement) {
            // Grammar checking
            checkGrammarForInOrForOfStatement(node);

            const rightType = getNonNullableTypeIfNeeded(
                checkExpression(
                    node.expression
                )
            );
            // TypeScript 1.0 spec (April 2014): 5.4
            // In a 'for-in' statement of the form
            // for (let VarDecl in Expr) Statement
            //   VarDecl must be a variable declaration without a type annotation that declares a variable of type Any,
            //   and Expr must be an expression of type Any, an object type, or a type parameter type.
            if (node.initializer.kind === SyntaxKind.VariableDeclarationList) {
                const variable = (<VariableDeclarationList> node.initializer)
                    .declarations[0];
                if (variable && isBindingPattern(variable.name)) {
                    error(
                        variable.name,
                        Diagnostics
                            .The_left_hand_side_of_a_for_in_statement_cannot_be_a_destructuring_pattern
                    );
                }
                checkForInOrForOfVariableDeclaration(node);
            } else {
                // In a 'for-in' statement of the form
                // for (Var in Expr) Statement
                //   Var must be an expression classified as a reference of type Any or the String primitive type,
                //   and Expr must be an expression of type Any, an object type, or a type parameter type.
                const varExpr = node.initializer;
                const leftType = checkExpression(varExpr);
                if (varExpr.kind === SyntaxKind.ArrayLiteralExpression
                    || varExpr.kind === SyntaxKind.ObjectLiteralExpression)
                {
                    error(
                        varExpr,
                        Diagnostics
                            .The_left_hand_side_of_a_for_in_statement_cannot_be_a_destructuring_pattern
                    );
                } else if (!isTypeAssignableTo(
                    getIndexTypeOrString(rightType),
                    leftType
                )) {
                    error(
                        varExpr,
                        Diagnostics
                            .The_left_hand_side_of_a_for_in_statement_must_be_of_type_string_or_any
                    );
                } else {
                    // run check only former check succeeded to avoid cascading errors
                    checkReferenceExpression(
                        varExpr,
                        Diagnostics
                            .The_left_hand_side_of_a_for_in_statement_must_be_a_variable_or_a_property_access,
                        Diagnostics
                            .The_left_hand_side_of_a_for_in_statement_may_not_be_an_optional_property_access
                    );
                }
            }

            // unknownType is returned i.e. if node.expression is identifier whose name cannot be resolved
            // in this case error about missing name is already reported - do not report extra one
            if (rightType === neverType
                || !isTypeAssignableToKind(
                    rightType,
                    TypeFlags.NonPrimitive | TypeFlags.InstantiableNonPrimitive
                ))
            {
                error(
                    node.expression,
                    Diagnostics
                        .The_right_hand_side_of_a_for_in_statement_must_be_of_type_any_an_object_type_or_a_type_parameter_but_here_has_type_0,
                    typeToString(rightType)
                );
            }

            checkSourceElement(node.statement);
            if (node.locals) {
                registerForUnusedIdentifiersCheck(node);
            }
        }

        function checkForInOrForOfVariableDeclaration(
            iterationStatement: ForInOrOfStatement
        ): void {
            const variableDeclarationList = <VariableDeclarationList> iterationStatement
                .initializer;
            // checkGrammarForInOrForOfStatement will check that there is exactly one declaration.
            if (variableDeclarationList.declarations.length >= 1) {
                const decl = variableDeclarationList.declarations[0];
                checkVariableDeclaration(decl);
            }
        }

        function checkRightHandSideOfForOf(
            rhsExpression: Expression,
            awaitModifier: AwaitKeywordToken | undefined
        ): Type {
            const expressionType = checkNonNullExpression(rhsExpression);
            const use = awaitModifier
                ? IterationUse.ForAwaitOf
                : IterationUse.ForOf;
            return checkIteratedTypeOrElementType(
                use,
                expressionType,
                undefinedType,
                rhsExpression
            );
        }

        function checkIteratedTypeOrElementType(
            use: IterationUse,
            inputType: Type,
            sentType: Type,
            errorNode: Node | undefined
        ): Type {
            if (isTypeAny(inputType)) {
                return inputType;
            }

            return getIteratedTypeOrElementType(
                use,
                inputType,
                sentType,
                errorNode, /*checkAssignability*/
                true
            ) || anyType;
        }

        /**
         * When consuming an iterable type in a for..of, spread, or iterator destructuring assignment
         * we want to get the iterated type of an iterable for ES2015 or later, or the iterated type
         * of a iterable (if defined globally) or element type of an array like for ES2015 or earlier.
         */
        function getIteratedTypeOrElementType(
            use: IterationUse,
            inputType: Type,
            sentType: Type,
            errorNode: Node | undefined,
            checkAssignability: boolean
        ): Type | undefined {
            const allowAsyncIterables = (use
                & IterationUse.AllowsAsyncIterablesFlag) !== 0;
            if (inputType === neverType) {
                reportTypeNotIterableError(
                    errorNode!,
                    inputType,
                    allowAsyncIterables
                ); // TODO: GH#18217
                return undefined;
            }

            const uplevelIteration = languageVersion >= ScriptTarget.ES2015;
            const downlevelIteration = !uplevelIteration
                && compilerOptions.downlevelIteration;

            // Get the iterated type of an `Iterable<T>` or `IterableIterator<T>` only in ES2015
            // or higher, when inside of an async generator or for-await-if, or when
            // downlevelIteration is requested.
            if (uplevelIteration || downlevelIteration
                || allowAsyncIterables)
            {
                // We only report errors for an invalid iterable type in ES2015 or higher.
                const iterationTypes = getIterationTypesOfIterable(
                    inputType,
                    use,
                    uplevelIteration ? errorNode : undefined
                );
                if (checkAssignability) {
                    if (iterationTypes) {
                        const diagnostic = use & IterationUse.ForOfFlag
                            ? Diagnostics
                                .Cannot_iterate_value_because_the_next_method_of_its_iterator_expects_type_1_but_for_of_will_always_send_0
                            : use & IterationUse.SpreadFlag
                                ? Diagnostics
                                    .Cannot_iterate_value_because_the_next_method_of_its_iterator_expects_type_1_but_array_spread_will_always_send_0
                                : use & IterationUse.DestructuringFlag
                                    ? Diagnostics
                                        .Cannot_iterate_value_because_the_next_method_of_its_iterator_expects_type_1_but_array_destructuring_will_always_send_0
                                    : use & IterationUse.YieldStarFlag
                                        ? Diagnostics
                                            .Cannot_delegate_iteration_to_value_because_the_next_method_of_its_iterator_expects_type_1_but_the_containing_generator_will_always_send_0
                                        : undefined;
                        if (diagnostic) {
                            checkTypeAssignableTo(
                                sentType,
                                iterationTypes.nextType,
                                errorNode,
                                diagnostic
                            );
                        }
                    }
                }
                if (iterationTypes || uplevelIteration) {
                    return iterationTypes && iterationTypes.yieldType;
                }
            }

            let arrayType = inputType;
            let reportedError = false;
            let hasStringConstituent = false;

            // If strings are permitted, remove any string-like constituents from the array type.
            // This allows us to find other non-string element types from an array unioned with
            // a string.
            if (use & IterationUse.AllowsStringInputFlag) {
                if (arrayType.flags & TypeFlags.Union) {
                    // After we remove all types that are StringLike, we will know if there was a string constituent
                    // based on whether the result of filter is a new array.
                    const arrayTypes = (<UnionType> inputType).types;
                    const filteredTypes = filter(
                        arrayTypes,
                        t => !(t.flags & TypeFlags.StringLike)
                    );
                    if (filteredTypes !== arrayTypes) {
                        arrayType = getUnionType(
                            filteredTypes,
                            UnionReduction.Subtype
                        );
                    }
                } else if (arrayType.flags & TypeFlags.StringLike) {
                    arrayType = neverType;
                }

                hasStringConstituent = arrayType !== inputType;
                if (hasStringConstituent) {
                    if (languageVersion < ScriptTarget.ES5) {
                        if (errorNode) {
                            error(
                                errorNode,
                                Diagnostics
                                    .Using_a_string_in_a_for_of_statement_is_only_supported_in_ECMAScript_5_and_higher
                            );
                            reportedError = true;
                        }
                    }

                    // Now that we've removed all the StringLike types, if no constituents remain, then the entire
                    // arrayOrStringType was a string.
                    if (arrayType.flags & TypeFlags.Never) {
                        return stringType;
                    }
                }
            }

            if (!isArrayLikeType(arrayType)) {
                if (errorNode && !reportedError) {
                    // Which error we report depends on whether we allow strings or if there was a
                    // string constituent. For example, if the input type is number | string, we
                    // want to say that number is not an array type. But if the input was just
                    // number and string input is allowed, we want to say that number is not an
                    // array type or a string type.
                    const yieldType = getIterationTypeOfIterable(
                        use,
                        IterationTypeKind.Yield,
                        inputType, /*errorNode*/
                        undefined
                    );
                    const [defaultDiagnostic, maybeMissingAwait]:
                        [DiagnosticMessage,
                            boolean] = !(use
                            & IterationUse.AllowsStringInputFlag)
                        || hasStringConstituent
                        ? downlevelIteration
                            ? [Diagnostics
                                .Type_0_is_not_an_array_type_or_does_not_have_a_Symbol_iterator_method_that_returns_an_iterator,
                                true]
                            : yieldType
                                ? [Diagnostics
                                    .Type_0_is_not_an_array_type_or_a_string_type_Use_compiler_option_downlevelIteration_to_allow_iterating_of_iterators,
                                    false]
                                : [Diagnostics.Type_0_is_not_an_array_type,
                                    true]
                        : downlevelIteration
                            ? [Diagnostics
                                .Type_0_is_not_an_array_type_or_a_string_type_or_does_not_have_a_Symbol_iterator_method_that_returns_an_iterator,
                                true]
                            : yieldType
                                ? [Diagnostics
                                    .Type_0_is_not_an_array_type_or_a_string_type_Use_compiler_option_downlevelIteration_to_allow_iterating_of_iterators,
                                    false]
                                : [Diagnostics
                                    .Type_0_is_not_an_array_type_or_a_string_type,
                                    true];
                    errorAndMaybeSuggestAwait(
                        errorNode,
                        maybeMissingAwait
                            && !!getAwaitedTypeOfPromise(arrayType),
                        defaultDiagnostic,
                        typeToString(arrayType)
                    );
                }
                return hasStringConstituent ? stringType : undefined;
            }

            const arrayElementType = getIndexTypeOfType(
                arrayType,
                IndexKind.Number
            );
            if (hasStringConstituent && arrayElementType) {
                // This is just an optimization for the case where arrayOrStringType is string | string[]
                if (arrayElementType.flags & TypeFlags.StringLike) {
                    return stringType;
                }

                return getUnionType(
                    [arrayElementType, stringType],
                    UnionReduction.Subtype
                );
            }

            return arrayElementType;
        }

        /**
         * Gets the requested "iteration type" from an `Iterable`-like or `AsyncIterable`-like type.
         */
        function getIterationTypeOfIterable(
            use: IterationUse,
            typeKind: IterationTypeKind,
            inputType: Type,
            errorNode: Node | undefined
        ): Type | undefined {
            if (isTypeAny(inputType)) {
                return undefined;
            }

            const iterationTypes = getIterationTypesOfIterable(
                inputType,
                use,
                errorNode
            );
            return iterationTypes
                && iterationTypes
                    [getIterationTypesKeyFromIterationTypeKind(typeKind)];
        }

        function createIterationTypes(
            yieldType: Type = neverType,
            returnType: Type = neverType,
            nextType: Type = unknownType
        ): IterationTypes {
            // `yieldType` and `returnType` are defaulted to `neverType` they each will be combined
            // via `getUnionType` when merging iteration types. `nextType` is defined as `unknownType`
            // as it is combined via `getIntersectionType` when merging iteration types.

            // Use the cache only for intrinsic types to keep it small as they are likely to be
            // more frequently created (i.e. `Iterator<number, void, unknown>`). Iteration types
            // are also cached on the type they are requested for, so we shouldn't need to maintain
            // the cache for less-frequently used types.
            if (yieldType.flags & TypeFlags.Intrinsic
                && returnType.flags
                & (TypeFlags.Any | TypeFlags.Never | TypeFlags.Unknown
                    | TypeFlags.Void | TypeFlags.Undefined)
                && nextType.flags
                & (TypeFlags.Any | TypeFlags.Never | TypeFlags.Unknown
                    | TypeFlags.Void | TypeFlags.Undefined))
            {
                const id = getTypeListId([yieldType, returnType, nextType]);
                let iterationTypes = iterationTypesCache.get(id);
                if (!iterationTypes) {
                    iterationTypes = { yieldType, returnType, nextType };
                    iterationTypesCache.set(id, iterationTypes);
                }
                return iterationTypes;
            }
            return { yieldType, returnType, nextType };
        }

        /**
         * Combines multiple `IterationTypes` records.
         *
         * If `array` is empty or all elements are missing or are references to `noIterationTypes`,
         * then `noIterationTypes` is returned. Otherwise, an `IterationTypes` record is returned
         * for the combined iteration types.
         */
        function combineIterationTypes(array: (IterationTypes | undefined)[]) {
            let yieldTypes: Type[] | undefined;
            let returnTypes: Type[] | undefined;
            let nextTypes: Type[] | undefined;
            for (const iterationTypes of array) {
                if (iterationTypes === undefined
                    || iterationTypes === noIterationTypes)
                {
                    continue;
                }
                if (iterationTypes === anyIterationTypes) {
                    return anyIterationTypes;
                }
                yieldTypes = append(yieldTypes, iterationTypes.yieldType);
                returnTypes = append(returnTypes, iterationTypes.returnType);
                nextTypes = append(nextTypes, iterationTypes.nextType);
            }
            if (yieldTypes || returnTypes || nextTypes) {
                return createIterationTypes(
                    yieldTypes && getUnionType(yieldTypes),
                    returnTypes && getUnionType(returnTypes),
                    nextTypes && getIntersectionType(nextTypes)
                );
            }
            return noIterationTypes;
        }

        /**
         * Gets the *yield*, *return*, and *next* types from an `Iterable`-like or `AsyncIterable`-like type.
         *
         * At every level that involves analyzing return types of signatures, we union the return types of all the signatures.
         *
         * Another thing to note is that at any step of this process, we could run into a dead end,
         * meaning either the property is missing, or we run into the anyType. If either of these things
         * happens, we return `undefined` to signal that we could not find the iteration type. If a property
         * is missing, and the previous step did not result in `any`, then we also give an error if the
         * caller requested it. Then the caller can decide what to do in the case where there is no iterated
         * type.
         *
         * For a **for-of** statement, `yield*` (in a normal generator), spread, array
         * destructuring, or normal generator we will only ever look for a `[Symbol.iterator]()`
         * method.
         *
         * For an async generator we will only ever look at the `[Symbol.asyncIterator]()` method.
         *
         * For a **for-await-of** statement or a `yield*` in an async generator we will look for
         * the `[Symbol.asyncIterator]()` method first, and then the `[Symbol.iterator]()` method.
         */
        function getIterationTypesOfIterable(
            type: Type,
            use: IterationUse,
            errorNode: Node | undefined
        ) {
            if (isTypeAny(type)) {
                return anyIterationTypes;
            }

            if (!(type.flags & TypeFlags.Union)) {
                const iterationTypes = getIterationTypesOfIterableWorker(
                    type,
                    use,
                    errorNode
                );
                if (iterationTypes === noIterationTypes) {
                    if (errorNode) {
                        reportTypeNotIterableError(
                            errorNode,
                            type,
                            !!(use & IterationUse.AllowsAsyncIterablesFlag)
                        );
                    }
                    return undefined;
                }
                return iterationTypes;
            }

            const cacheKey = use & IterationUse.AllowsAsyncIterablesFlag
                ? 'iterationTypesOfAsyncIterable'
                : 'iterationTypesOfIterable';
            const cachedTypes = (type as IterableOrIteratorType)[cacheKey];
            if (cachedTypes) {
                return cachedTypes === noIterationTypes
                    ? undefined
                    : cachedTypes;
            }

            let allIterationTypes: IterationTypes[] | undefined;
            for (const constituent of (type as UnionType).types) {
                const iterationTypes = getIterationTypesOfIterableWorker(
                    constituent,
                    use,
                    errorNode
                );
                if (iterationTypes === noIterationTypes) {
                    if (errorNode) {
                        reportTypeNotIterableError(
                            errorNode,
                            type,
                            !!(use & IterationUse.AllowsAsyncIterablesFlag)
                        );
                        errorNode = undefined;
                    }
                } else {
                    allIterationTypes = append(
                        allIterationTypes,
                        iterationTypes
                    );
                }
            }

            const iterationTypes = allIterationTypes
                ? combineIterationTypes(allIterationTypes)
                : noIterationTypes;
            (type as IterableOrIteratorType)[cacheKey] = iterationTypes;
            return iterationTypes === noIterationTypes
                ? undefined
                : iterationTypes;
        }

        function getAsyncFromSyncIterationTypes(
            iterationTypes: IterationTypes,
            errorNode: Node | undefined
        ) {
            if (iterationTypes === noIterationTypes) return noIterationTypes;
            if (iterationTypes === anyIterationTypes) return anyIterationTypes;
            const { yieldType, returnType, nextType } = iterationTypes;
            return createIterationTypes(
                getAwaitedType(yieldType, errorNode) || anyType,
                getAwaitedType(returnType, errorNode) || anyType,
                nextType
            );
        }

        /**
         * Gets the *yield*, *return*, and *next* types from a non-union type.
         *
         * If we are unable to find the *yield*, *return*, and *next* types, `noIterationTypes` is
         * returned to indicate to the caller that it should report an error. Otherwise, an
         * `IterationTypes` record is returned.
         *
         * NOTE: You probably don't want to call this directly and should be calling
         * `getIterationTypesOfIterable` instead.
         */
        function getIterationTypesOfIterableWorker(
            type: Type,
            use: IterationUse,
            errorNode: Node | undefined
        ) {
            if (isTypeAny(type)) {
                return anyIterationTypes;
            }

            if (use & IterationUse.AllowsAsyncIterablesFlag) {
                const iterationTypes = getIterationTypesOfIterableCached(
                    type,
                    asyncIterationTypesResolver
                )
                    || getIterationTypesOfIterableFast(
                        type,
                        asyncIterationTypesResolver
                    );
                if (iterationTypes) {
                    return iterationTypes;
                }
            }

            if (use & IterationUse.AllowsSyncIterablesFlag) {
                const iterationTypes = getIterationTypesOfIterableCached(
                    type,
                    syncIterationTypesResolver
                )
                    || getIterationTypesOfIterableFast(
                        type,
                        syncIterationTypesResolver
                    );
                if (iterationTypes) {
                    if (use & IterationUse.AllowsAsyncIterablesFlag) {
                        // for a sync iterable in an async context, only use the cached types if they are valid.
                        if (iterationTypes !== noIterationTypes) {
                            return (type as IterableOrIteratorType)
                                .iterationTypesOfAsyncIterable = getAsyncFromSyncIterationTypes(
                                    iterationTypes,
                                    errorNode
                                );
                        }
                    } else {
                        return iterationTypes;
                    }
                }
            }

            if (use & IterationUse.AllowsAsyncIterablesFlag) {
                const iterationTypes = getIterationTypesOfIterableSlow(
                    type,
                    asyncIterationTypesResolver,
                    errorNode
                );
                if (iterationTypes !== noIterationTypes) {
                    return iterationTypes;
                }
            }

            if (use & IterationUse.AllowsSyncIterablesFlag) {
                const iterationTypes = getIterationTypesOfIterableSlow(
                    type,
                    syncIterationTypesResolver,
                    errorNode
                );
                if (iterationTypes !== noIterationTypes) {
                    if (use & IterationUse.AllowsAsyncIterablesFlag) {
                        return (type as IterableOrIteratorType)
                            .iterationTypesOfAsyncIterable = iterationTypes
                                ? getAsyncFromSyncIterationTypes(
                                    iterationTypes,
                                    errorNode
                                )
                                : noIterationTypes;
                    } else {
                        return iterationTypes;
                    }
                }
            }

            return noIterationTypes;
        }

        /**
         * Gets the *yield*, *return*, and *next* types of an `Iterable`-like or
         * `AsyncIterable`-like type from the cache.
         *
         * NOTE: You probably don't want to call this directly and should be calling
         * `getIterationTypesOfIterable` instead.
         */
        function getIterationTypesOfIterableCached(
            type: Type,
            resolver: IterationTypesResolver
        ) {
            return (type as IterableOrIteratorType)[resolver.iterableCacheKey];
        }

        function getIterationTypesOfGlobalIterableType(
            globalType: Type,
            resolver: IterationTypesResolver
        ) {
            const globalIterationTypes = getIterationTypesOfIterableCached(
                globalType,
                resolver
            )
                || getIterationTypesOfIterableSlow(
                    globalType,
                    resolver, /*errorNode*/
                    undefined
                );
            return globalIterationTypes === noIterationTypes
                ? defaultIterationTypes
                : globalIterationTypes;
        }

        /**
         * Gets the *yield*, *return*, and *next* types of an `Iterable`-like or `AsyncIterable`-like
         * type from from common heuristics.
         *
         * If we previously analyzed this type and found no iteration types, `noIterationTypes` is
         * returned. If we found iteration types, an `IterationTypes` record is returned.
         * Otherwise, we return `undefined` to indicate to the caller it should perform a more
         * exhaustive analysis.
         *
         * NOTE: You probably don't want to call this directly and should be calling
         * `getIterationTypesOfIterable` instead.
         */
        function getIterationTypesOfIterableFast(
            type: Type,
            resolver: IterationTypesResolver
        ) {
            // As an optimization, if the type is an instantiation of one of the following global types, then
            // just grab its related type argument:
            // - `Iterable<T>` or `AsyncIterable<T>`
            // - `IterableIterator<T>` or `AsyncIterableIterator<T>`
            let globalType: Type;
            if (isReferenceToType(
                type,
                globalType = resolver
                    .getGlobalIterableType(/*reportErrors*/ false)
            )
                || isReferenceToType(
                    type,
                    globalType = resolver
                        .getGlobalIterableIteratorType(/*reportErrors*/ false)
                ))
            {
                const [yieldType] = getTypeArguments(type as GenericType);
                // The "return" and "next" types of `Iterable` and `IterableIterator` are defined by the
                // iteration types of their `[Symbol.iterator]()` method. The same is true for their async cousins.
                // While we define these as `any` and `undefined` in our libs by default, a custom lib *could* use
                // different definitions.
                const { returnType,
                    nextType } = getIterationTypesOfGlobalIterableType(
                        globalType,
                        resolver
                    );
                return (type as IterableOrIteratorType)[resolver
                    .iterableCacheKey] = createIterationTypes(
                        yieldType,
                        returnType,
                        nextType
                    );
            }

            // As an optimization, if the type is an instantiation of the following global type, then
            // just grab its related type arguments:
            // - `Generator<T, TReturn, TNext>` or `AsyncGenerator<T, TReturn, TNext>`
            if (isReferenceToType(
                type,
                resolver.getGlobalGeneratorType(/*reportErrors*/ false)
            )) {
                const [yieldType, returnType,
                    nextType] = getTypeArguments(type as GenericType);
                return (type as IterableOrIteratorType)[resolver
                    .iterableCacheKey] = createIterationTypes(
                        yieldType,
                        returnType,
                        nextType
                    );
            }
        }

        /**
         * Gets the *yield*, *return*, and *next* types of an `Iterable`-like or `AsyncIterable`-like
         * type from its members.
         *
         * If we successfully found the *yield*, *return*, and *next* types, an `IterationTypes`
         * record is returned. Otherwise, `noIterationTypes` is returned.
         *
         * NOTE: You probably don't want to call this directly and should be calling
         * `getIterationTypesOfIterable` instead.
         */
        function getIterationTypesOfIterableSlow(
            type: Type,
            resolver: IterationTypesResolver,
            errorNode: Node | undefined
        ) {
            const method = getPropertyOfType(
                type,
                getPropertyNameForKnownSymbolName(resolver.iteratorSymbolName)
            );
            const methodType = method && !(method.flags & SymbolFlags.Optional)
                ? getTypeOfSymbol(method)
                : undefined;
            if (isTypeAny(methodType)) {
                return (type as IterableOrIteratorType)[resolver
                    .iterableCacheKey] = anyIterationTypes;
            }

            const signatures = methodType
                ? getSignaturesOfType(methodType, SignatureKind.Call)
                : undefined;
            if (!some(signatures)) {
                return (type as IterableOrIteratorType)[resolver
                    .iterableCacheKey] = noIterationTypes;
            }

            const iteratorType = getUnionType(
                map(
                    signatures,
                    getReturnTypeOfSignature
                ),
                UnionReduction.Subtype
            );
            const iterationTypes = getIterationTypesOfIterator(
                iteratorType,
                resolver,
                errorNode
            ) || noIterationTypes;
            return (type as IterableOrIteratorType)[resolver
                .iterableCacheKey] = iterationTypes;
        }

        function reportTypeNotIterableError(
            errorNode: Node,
            type: Type,
            allowAsyncIterables: boolean
        ): void {
            const message = allowAsyncIterables
                ? Diagnostics
                    .Type_0_must_have_a_Symbol_asyncIterator_method_that_returns_an_async_iterator
                : Diagnostics
                    .Type_0_must_have_a_Symbol_iterator_method_that_returns_an_iterator;
            errorAndMaybeSuggestAwait(
                errorNode,
                !!getAwaitedTypeOfPromise(type),
                message,
                typeToString(type)
            );
        }

        /**
         * Gets the *yield*, *return*, and *next* types from an `Iterator`-like or `AsyncIterator`-like type.
         *
         * If we successfully found the *yield*, *return*, and *next* types, an `IterationTypes`
         * record is returned. Otherwise, `undefined` is returned.
         */
        function getIterationTypesOfIterator(
            type: Type,
            resolver: IterationTypesResolver,
            errorNode: Node | undefined
        ) {
            if (isTypeAny(type)) {
                return anyIterationTypes;
            }

            const iterationTypes = getIterationTypesOfIteratorCached(
                type,
                resolver
            )
                || getIterationTypesOfIteratorFast(type, resolver)
                || getIterationTypesOfIteratorSlow(type, resolver, errorNode);
            return iterationTypes === noIterationTypes
                ? undefined
                : iterationTypes;
        }

        /**
         * Gets the iteration types of an `Iterator`-like or `AsyncIterator`-like type from the
         * cache.
         *
         * NOTE: You probably don't want to call this directly and should be calling
         * `getIterationTypesOfIterator` instead.
         */
        function getIterationTypesOfIteratorCached(
            type: Type,
            resolver: IterationTypesResolver
        ) {
            return (type as IterableOrIteratorType)[resolver.iteratorCacheKey];
        }

        /**
         * Gets the iteration types of an `Iterator`-like or `AsyncIterator`-like type from the
         * cache or from common heuristics.
         *
         * If we previously analyzed this type and found no iteration types, `noIterationTypes` is
         * returned. If we found iteration types, an `IterationTypes` record is returned.
         * Otherwise, we return `undefined` to indicate to the caller it should perform a more
         * exhaustive analysis.
         *
         * NOTE: You probably don't want to call this directly and should be calling
         * `getIterationTypesOfIterator` instead.
         */
        function getIterationTypesOfIteratorFast(
            type: Type,
            resolver: IterationTypesResolver
        ) {
            // As an optimization, if the type is an instantiation of one of the following global types,
            // then just grab its related type argument:
            // - `IterableIterator<T>` or `AsyncIterableIterator<T>`
            // - `Iterator<T, TReturn, TNext>` or `AsyncIterator<T, TReturn, TNext>`
            // - `Generator<T, TReturn, TNext>` or `AsyncGenerator<T, TReturn, TNext>`
            const globalType = resolver
                .getGlobalIterableIteratorType(/*reportErrors*/ false);
            if (isReferenceToType(type, globalType)) {
                const [yieldType] = getTypeArguments(type as GenericType);
                // The "return" and "next" types of `IterableIterator` and `AsyncIterableIterator` are defined by the
                // iteration types of their `next`, `return`, and `throw` methods. While we define these as `any`
                // and `undefined` in our libs by default, a custom lib *could* use different definitions.
                const globalIterationTypes = getIterationTypesOfIteratorCached(
                    globalType,
                    resolver
                )
                    || getIterationTypesOfIteratorSlow(
                        globalType,
                        resolver, /*errorNode*/
                        undefined
                    );
                const { returnType,
                    nextType } = globalIterationTypes === noIterationTypes
                    ? defaultIterationTypes
                    : globalIterationTypes;
                return (type as IterableOrIteratorType)[resolver
                    .iteratorCacheKey] = createIterationTypes(
                        yieldType,
                        returnType,
                        nextType
                    );
            }
            if (isReferenceToType(
                type,
                resolver.getGlobalIteratorType(/*reportErrors*/ false)
            )
                || isReferenceToType(
                    type,
                    resolver.getGlobalGeneratorType(/*reportErrors*/ false)
                ))
            {
                const [yieldType, returnType,
                    nextType] = getTypeArguments(type as GenericType);
                return (type as IterableOrIteratorType)[resolver
                    .iteratorCacheKey] = createIterationTypes(
                        yieldType,
                        returnType,
                        nextType
                    );
            }
        }

        function isIteratorResult(
            type: Type,
            kind: IterationTypeKind.Yield | IterationTypeKind.Return
        ) {
            // From https://tc39.github.io/ecma262/#sec-iteratorresult-interface:
            // > [done] is the result status of an iterator `next` method call. If the end of the iterator was reached `done` is `true`.
            // > If the end was not reached `done` is `false` and a value is available.
            // > If a `done` property (either own or inherited) does not exist, it is consider to have the value `false`.
            const doneType = getTypeOfPropertyOfType(type, 'done' as __String)
                || falseType;
            return isTypeAssignableTo(
                kind === IterationTypeKind.Yield
                    ? falseType
                    : trueType,
                doneType
            );
        }

        function isYieldIteratorResult(type: Type) {
            return isIteratorResult(type, IterationTypeKind.Yield);
        }

        function isReturnIteratorResult(type: Type) {
            return isIteratorResult(type, IterationTypeKind.Return);
        }

        /**
         * Gets the *yield* and *return* types of an `IteratorResult`-like type.
         *
         * If we are unable to determine a *yield* or a *return* type, `noIterationTypes` is
         * returned to indicate to the caller that it should handle the error. Otherwise, an
         * `IterationTypes` record is returned.
         */
        function getIterationTypesOfIteratorResult(type: Type) {
            if (isTypeAny(type)) {
                return anyIterationTypes;
            }

            const cachedTypes = (type as IterableOrIteratorType)
                .iterationTypesOfIteratorResult;
            if (cachedTypes) {
                return cachedTypes;
            }

            // As an optimization, if the type is an instantiation of one of the global `IteratorYieldResult<T>`
            // or `IteratorReturnResult<TReturn>` types, then just grab its type argument.
            if (isReferenceToType(
                type,
                getGlobalIteratorYieldResultType(/*reportErrors*/ false)
            )) {
                const yieldType = getTypeArguments(type as GenericType)[0];
                return (type as IterableOrIteratorType)
                    .iterationTypesOfIteratorResult = createIterationTypes(
                        yieldType, /*returnType*/
                        undefined, /*nextType*/
                        undefined
                    );
            }
            if (isReferenceToType(
                type,
                getGlobalIteratorReturnResultType(/*reportErrors*/ false)
            )) {
                const returnType = getTypeArguments(type as GenericType)[0];
                return (type as IterableOrIteratorType)
                    .iterationTypesOfIteratorResult = createIterationTypes(
                        /*yieldType*/ undefined,
                        returnType, /*nextType*/
                        undefined
                    );
            }

            // Choose any constituents that can produce the requested iteration type.
            const yieldIteratorResult = filterType(type,
                isYieldIteratorResult);
            const yieldType = yieldIteratorResult !== neverType
                ? getTypeOfPropertyOfType(
                    yieldIteratorResult,
                    'value' as __String
                )
                : undefined;

            const returnIteratorResult = filterType(
                type,
                isReturnIteratorResult
            );
            const returnType = returnIteratorResult !== neverType
                ? getTypeOfPropertyOfType(
                    returnIteratorResult,
                    'value' as __String
                )
                : undefined;

            if (!yieldType && !returnType) {
                return (type as IterableOrIteratorType)
                    .iterationTypesOfIteratorResult = noIterationTypes;
            }

            // From https://tc39.github.io/ecma262/#sec-iteratorresult-interface
            // > ... If the iterator does not have a return value, `value` is `undefined`. In that case, the
            // > `value` property may be absent from the conforming object if it does not inherit an explicit
            // > `value` property.
            return (type as IterableOrIteratorType)
                .iterationTypesOfIteratorResult = createIterationTypes(
                    yieldType,
                    returnType || voidType, /*nextType*/
                    undefined
                );
        }

        /**
         * Gets the *yield*, *return*, and *next* types of a the `next()`, `return()`, or
         * `throw()` method of an `Iterator`-like or `AsyncIterator`-like type.
         *
         * If we successfully found the *yield*, *return*, and *next* types, an `IterationTypes`
         * record is returned. Otherwise, we return `undefined`.
         */
        function getIterationTypesOfMethod(
            type: Type,
            resolver: IterationTypesResolver,
            methodName: 'next' | 'return' | 'throw',
            errorNode: Node | undefined
        ): IterationTypes | undefined {
            const method = getPropertyOfType(type, methodName as __String);

            // Ignore 'return' or 'throw' if they are missing.
            if (!method && methodName !== 'next') {
                return undefined;
            }

            const methodType = method
                && !(methodName === 'next'
                    && (method.flags & SymbolFlags.Optional))
                ? methodName === 'next'
                    ? getTypeOfSymbol(method)
                    : getTypeWithFacts(
                        getTypeOfSymbol(method),
                        TypeFacts.NEUndefinedOrNull
                    )
                : undefined;

            if (isTypeAny(methodType)) {
                // `return()` and `throw()` don't provide a *next* type.
                return methodName === 'next'
                    ? anyIterationTypes
                    : anyIterationTypesExceptNext;
            }

            // Both async and non-async iterators *must* have a `next` method.
            const methodSignatures = methodType
                ? getSignaturesOfType(methodType, SignatureKind.Call)
                : emptyArray;
            if (methodSignatures.length === 0) {
                if (errorNode) {
                    const diagnostic = methodName === 'next'
                        ? resolver.mustHaveANextMethodDiagnostic
                        : resolver.mustBeAMethodDiagnostic;
                    error(errorNode, diagnostic, methodName);
                }
                return methodName === 'next' ? anyIterationTypes : undefined;
            }

            // Extract the first parameter and return type of each signature.
            let methodParameterTypes: Type[] | undefined;
            let methodReturnTypes: Type[] | undefined;
            for (const signature of methodSignatures) {
                if (methodName !== 'throw' && some(signature.parameters)) {
                    methodParameterTypes = append(
                        methodParameterTypes,
                        getTypeAtPosition(signature, 0)
                    );
                }
                methodReturnTypes = append(
                    methodReturnTypes,
                    getReturnTypeOfSignature(signature)
                );
            }

            // Resolve the *next* or *return* type from the first parameter of a `next()` or
            // `return()` method, respectively.
            let returnTypes: Type[] | undefined;
            let nextType: Type | undefined;
            if (methodName !== 'throw') {
                const methodParameterType = methodParameterTypes
                    ? getUnionType(methodParameterTypes)
                    : unknownType;
                if (methodName === 'next') {
                    // The value of `next(value)` is *not* awaited by async generators
                    nextType = methodParameterType;
                } else if (methodName === 'return') {
                    // The value of `return(value)` *is* awaited by async generators
                    const resolvedMethodParameterType = resolver
                        .resolveIterationType(methodParameterType, errorNode)
                        || anyType;
                    returnTypes = append(
                        returnTypes,
                        resolvedMethodParameterType
                    );
                }
            }

            // Resolve the *yield* and *return* types from the return type of the method (i.e. `IteratorResult`)
            let yieldType: Type;
            const methodReturnType = methodReturnTypes
                ? getUnionType(methodReturnTypes, UnionReduction.Subtype)
                : neverType;
            const resolvedMethodReturnType = resolver
                .resolveIterationType(methodReturnType, errorNode) || anyType;
            const iterationTypes = getIterationTypesOfIteratorResult(resolvedMethodReturnType);
            if (iterationTypes === noIterationTypes) {
                if (errorNode) {
                    error(
                        errorNode,
                        resolver.mustHaveAValueDiagnostic,
                        methodName
                    );
                }
                yieldType = anyType;
                returnTypes = append(returnTypes, anyType);
            } else {
                yieldType = iterationTypes.yieldType;
                returnTypes = append(returnTypes, iterationTypes.returnType);
            }

            return createIterationTypes(
                yieldType,
                getUnionType(returnTypes),
                nextType
            );
        }

        /**
         * Gets the *yield*, *return*, and *next* types of an `Iterator`-like or `AsyncIterator`-like
         * type from its members.
         *
         * If we successfully found the *yield*, *return*, and *next* types, an `IterationTypes`
         * record is returned. Otherwise, `noIterationTypes` is returned.
         *
         * NOTE: You probably don't want to call this directly and should be calling
         * `getIterationTypesOfIterator` instead.
         */
        function getIterationTypesOfIteratorSlow(
            type: Type,
            resolver: IterationTypesResolver,
            errorNode: Node | undefined
        ) {
            const iterationTypes = combineIterationTypes(
                [
                    getIterationTypesOfMethod(type, resolver, 'next',
                        errorNode),
                    getIterationTypesOfMethod(type, resolver, 'return',
                        errorNode),
                    getIterationTypesOfMethod(type, resolver, 'throw',
                        errorNode)
                ]
            );
            return (type as IterableOrIteratorType)[resolver
                .iteratorCacheKey] = iterationTypes;
        }

        /**
         * Gets the requested "iteration type" from a type that is either `Iterable`-like, `Iterator`-like,
         * `IterableIterator`-like, or `Generator`-like (for a non-async generator); or `AsyncIterable`-like,
         * `AsyncIterator`-like, `AsyncIterableIterator`-like, or `AsyncGenerator`-like (for an async generator).
         */
        function getIterationTypeOfGeneratorFunctionReturnType(
            kind: IterationTypeKind,
            returnType: Type,
            isAsyncGenerator: boolean
        ): Type | undefined {
            if (isTypeAny(returnType)) {
                return undefined;
            }

            const iterationTypes = getIterationTypesOfGeneratorFunctionReturnType(
                returnType,
                isAsyncGenerator
            );
            return iterationTypes
                && iterationTypes
                    [getIterationTypesKeyFromIterationTypeKind(kind)];
        }

        function getIterationTypesOfGeneratorFunctionReturnType(
            type: Type,
            isAsyncGenerator: boolean
        ) {
            if (isTypeAny(type)) {
                return anyIterationTypes;
            }

            const use = isAsyncGenerator
                ? IterationUse.AsyncGeneratorReturnType
                : IterationUse.GeneratorReturnType;
            const resolver = isAsyncGenerator
                ? asyncIterationTypesResolver
                : syncIterationTypesResolver;
            return getIterationTypesOfIterable(
                type,
                use, /*errorNode*/
                undefined
            )
                || getIterationTypesOfIterator(
                    type,
                    resolver, /*errorNode*/
                    undefined
                );
        }

        function checkBreakOrContinueStatement(node:
            BreakOrContinueStatement)
        {
            // Grammar checking
            if (!checkGrammarStatementInAmbientContext(node)) checkGrammarBreakOrContinueStatement(node);

            // TODO: Check that target label is valid
        }

        function unwrapReturnType(
            returnType: Type,
            functionFlags: FunctionFlags
        ) {
            const isGenerator = !!(functionFlags & FunctionFlags.Generator);
            const isAsync = !!(functionFlags & FunctionFlags.Async);
            return isGenerator
                ? getIterationTypeOfGeneratorFunctionReturnType(
                    IterationTypeKind.Return,
                    returnType,
                    isAsync
                ) || errorType
                : isAsync
                    ? getPromisedTypeOfPromise(returnType) || errorType
                    : returnType;
        }

        function isUnwrappedReturnTypeVoidOrAny(
            func: SignatureDeclaration,
            returnType: Type
        ): boolean {
            const unwrappedReturnType = unwrapReturnType(
                returnType,
                getFunctionFlags(func)
            );
            return !!unwrappedReturnType
                && maybeTypeOfKind(
                    unwrappedReturnType,
                    TypeFlags.Void | TypeFlags.AnyOrUnknown
                );
        }

        function checkReturnStatement(node: ReturnStatement) {
            // Grammar checking
            if (checkGrammarStatementInAmbientContext(node)) {
                return;
            }

            const func = getContainingFunction(node);
            if (!func) {
                grammarErrorOnFirstToken(
                    node,
                    Diagnostics
                        .A_return_statement_can_only_be_used_within_a_function_body
                );
                return;
            }

            const signature = getSignatureFromDeclaration(func);
            const returnType = getReturnTypeOfSignature(signature);
            const functionFlags = getFunctionFlags(func);
            if (strictNullChecks || node.expression
                || returnType.flags & TypeFlags.Never)
            {
                const exprType = node.expression
                    ? checkExpressionCached(node.expression)
                    : undefinedType;
                if (func.kind === SyntaxKind.SetAccessor) {
                    if (node.expression) {
                        error(node, Diagnostics.Setters_cannot_return_a_value);
                    }
                } else if (func.kind === SyntaxKind.Constructor) {
                    if (node.expression
                        && !checkTypeAssignableToAndOptionallyElaborate(
                            exprType,
                            returnType,
                            node,
                            node.expression
                        ))
                    {
                        error(
                            node,
                            Diagnostics
                                .Return_type_of_constructor_signature_must_be_assignable_to_the_instance_type_of_the_class
                        );
                    }
                } else if (getReturnTypeFromAnnotation(func)) {
                    const unwrappedReturnType = unwrapReturnType(
                        returnType,
                        functionFlags
                    );
                    const unwrappedExprType = functionFlags
                        & FunctionFlags.Async
                        ? checkAwaitedType(
                            exprType,
                            node,
                            Diagnostics
                                .The_return_type_of_an_async_function_must_either_be_a_valid_promise_or_must_not_contain_a_callable_then_member
                        )
                        : exprType;
                    if (unwrappedReturnType) {
                        // If the function has a return type, but promisedType is
                        // undefined, an error will be reported in checkAsyncFunctionReturnType
                        // so we don't need to report one here.
                        checkTypeAssignableToAndOptionallyElaborate(
                            unwrappedExprType,
                            unwrappedReturnType,
                            node,
                            node.expression
                        );
                    }
                }
            } else if (func.kind !== SyntaxKind.Constructor
                && compilerOptions.noImplicitReturns
                && !isUnwrappedReturnTypeVoidOrAny(func, returnType))
            {
                // The function has a return type, but the return statement doesn't have an expression.
                error(node, Diagnostics.Not_all_code_paths_return_a_value);
            }
        }

        function checkWithStatement(node: WithStatement) {
            // Grammar checking for withStatement
            if (!checkGrammarStatementInAmbientContext(node)) {
                if (node.flags & NodeFlags.AwaitContext) {
                    grammarErrorOnFirstToken(
                        node,
                        Diagnostics
                            .with_statements_are_not_allowed_in_an_async_function_block
                    );
                }
            }

            checkExpression(node.expression);

            const sourceFile = getSourceFileOfNode(node);
            if (!hasParseDiagnostics(sourceFile)) {
                const start = getSpanOfTokenAtPosition(sourceFile, node.pos)
                    .start;
                const end = node.statement.pos;
                grammarErrorAtPos(
                    sourceFile,
                    start,
                    end - start,
                    Diagnostics
                        .The_with_statement_is_not_supported_All_symbols_in_a_with_block_will_have_type_any
                );
            }
        }

        function checkSwitchStatement(node: SwitchStatement) {
            // Grammar checking
            checkGrammarStatementInAmbientContext(node);

            let firstDefaultClause: CaseOrDefaultClause;
            let hasDuplicateDefaultClause = false;

            const expressionType = checkExpression(node.expression);
            const expressionIsLiteral = isLiteralType(expressionType);
            forEach(
                node.caseBlock.clauses,
                clause => {
                    // Grammar check for duplicate default clauses, skip if we already report duplicate default clause
                    if (clause.kind === SyntaxKind.DefaultClause
                        && !hasDuplicateDefaultClause)
                    {
                        if (firstDefaultClause === undefined) {
                            firstDefaultClause = clause;
                        } else {
                            grammarErrorOnNode(
                                clause,
                                Diagnostics
                                    .A_default_clause_cannot_appear_more_than_once_in_a_switch_statement
                            );
                            hasDuplicateDefaultClause = true;
                        }
                    }

                    if (produceDiagnostics
                        && clause.kind === SyntaxKind.CaseClause)
                    {
                        // TypeScript 1.0 spec (April 2014): 5.9
                        // In a 'switch' statement, each 'case' expression must be of a type that is comparable
                        // to or from the type of the 'switch' expression.
                        let caseType = checkExpression(clause.expression);
                        const caseIsLiteral = isLiteralType(caseType);
                        let comparedExpressionType = expressionType;
                        if (!caseIsLiteral || !expressionIsLiteral) {
                            caseType = caseIsLiteral
                                ? getBaseTypeOfLiteralType(caseType)
                                : caseType;
                            comparedExpressionType = getBaseTypeOfLiteralType(expressionType);
                        }
                        if (!isTypeEqualityComparableTo(
                            comparedExpressionType,
                            caseType
                        )) {
                            // expressionType is not comparable to caseType, try the reversed check and report errors if it fails
                            checkTypeComparableTo(
                                caseType,
                                comparedExpressionType,
                                clause.expression, /*headMessage*/
                                undefined
                            );
                        }
                    }
                    forEach(clause.statements, checkSourceElement);
                    if (compilerOptions.noFallthroughCasesInSwitch
                        && clause.fallthroughFlowNode
                        && isReachableFlowNode(clause.fallthroughFlowNode))
                    {
                        error(clause, Diagnostics.Fallthrough_case_in_switch);
                    }
                }
            );
            if (node.caseBlock.locals) {
                registerForUnusedIdentifiersCheck(node.caseBlock);
            }
        }

        function checkLabeledStatement(node: LabeledStatement) {
            // Grammar checking
            if (!checkGrammarStatementInAmbientContext(node)) {
                findAncestor(
                    node.parent,
                    current => {
                        if (isFunctionLike(current)) {
                            return 'quit';
                        }
                        if (current.kind === SyntaxKind.LabeledStatement
                            && (<LabeledStatement> current).label.escapedText
                            === node.label.escapedText)
                        {
                            grammarErrorOnNode(
                                node.label,
                                Diagnostics.Duplicate_label_0,
                                getTextOfNode(node.label)
                            );
                            return true;
                        }
                        return false;
                    }
                );
            }

            // ensure that label is unique
            checkSourceElement(node.statement);
        }

        function checkThrowStatement(node: ThrowStatement) {
            // Grammar checking
            if (!checkGrammarStatementInAmbientContext(node)) {
                if (node.expression === undefined) {
                    grammarErrorAfterFirstToken(
                        node,
                        Diagnostics.Line_break_not_permitted_here
                    );
                }
            }

            if (node.expression) {
                checkExpression(node.expression);
            }
        }

        function checkTryStatement(node: TryStatement) {
            // Grammar checking
            checkGrammarStatementInAmbientContext(node);

            checkBlock(node.tryBlock);
            const catchClause = node.catchClause;
            if (catchClause) {
                // Grammar checking
                if (catchClause.variableDeclaration) {
                    if (catchClause.variableDeclaration.type) {
                        grammarErrorOnFirstToken(
                            catchClause.variableDeclaration.type,
                            Diagnostics
                                .Catch_clause_variable_cannot_have_a_type_annotation
                        );
                    } else if (catchClause.variableDeclaration.initializer) {
                        grammarErrorOnFirstToken(
                            catchClause.variableDeclaration.initializer,
                            Diagnostics
                                .Catch_clause_variable_cannot_have_an_initializer
                        );
                    } else {
                        const blockLocals = catchClause.block.locals;
                        if (blockLocals) {
                            forEachKey(
                                catchClause.locals!,
                                caughtName => {
                                    const blockLocal = blockLocals
                                        .get(caughtName);
                                    if (blockLocal
                                        && (blockLocal.flags
                                            & SymbolFlags.BlockScopedVariable)
                                        !== 0)
                                    {
                                        grammarErrorOnNode(
                                            blockLocal.valueDeclaration,
                                            Diagnostics
                                                .Cannot_redeclare_identifier_0_in_catch_clause,
                                            caughtName
                                        );
                                    }
                                }
                            );
                        }
                    }
                }

                checkBlock(catchClause.block);
            }

            if (node.finallyBlock) {
                checkBlock(node.finallyBlock);
            }
        }

        function checkIndexConstraints(type: Type) {
            const declaredNumberIndexer = getIndexDeclarationOfSymbol(
                type.symbol,
                IndexKind.Number
            );
            const declaredStringIndexer = getIndexDeclarationOfSymbol(
                type.symbol,
                IndexKind.String
            );

            const stringIndexType = getIndexTypeOfType(type, IndexKind.String);
            const numberIndexType = getIndexTypeOfType(type, IndexKind.Number);

            if (stringIndexType || numberIndexType) {
                forEach(
                    getPropertiesOfObjectType(type),
                    prop => {
                        const propType = getTypeOfSymbol(prop);
                        checkIndexConstraintForProperty(
                            prop,
                            propType,
                            type,
                            declaredStringIndexer,
                            stringIndexType,
                            IndexKind.String
                        );
                        checkIndexConstraintForProperty(
                            prop,
                            propType,
                            type,
                            declaredNumberIndexer,
                            numberIndexType,
                            IndexKind.Number
                        );
                    }
                );

                const classDeclaration = type.symbol.valueDeclaration;
                if (getObjectFlags(type) & ObjectFlags.Class
                    && isClassLike(classDeclaration))
                {
                    for (const member of classDeclaration.members) {
                        // Only process instance properties with computed names here.
                        // Static properties cannot be in conflict with indexers,
                        // and properties with literal names were already checked.
                        if (!hasModifier(member, ModifierFlags.Static)
                            && hasNonBindableDynamicName(member))
                        {
                            const symbol = getSymbolOfNode(member);
                            const propType = getTypeOfSymbol(symbol);
                            checkIndexConstraintForProperty(
                                symbol,
                                propType,
                                type,
                                declaredStringIndexer,
                                stringIndexType,
                                IndexKind.String
                            );
                            checkIndexConstraintForProperty(
                                symbol,
                                propType,
                                type,
                                declaredNumberIndexer,
                                numberIndexType,
                                IndexKind.Number
                            );
                        }
                    }
                }
            }

            let errorNode: Node | undefined;
            if (stringIndexType && numberIndexType) {
                errorNode = declaredNumberIndexer || declaredStringIndexer;
                // condition 'errorNode === undefined' may appear if types does not declare nor string neither number indexer
                if (!errorNode
                    && (getObjectFlags(type) & ObjectFlags.Interface))
                {
                    const someBaseTypeHasBothIndexers = forEach(
                        getBaseTypes(<InterfaceType> type),
                        base => getIndexTypeOfType(base, IndexKind.String)
                            && getIndexTypeOfType(base, IndexKind.Number)
                    );
                    errorNode = someBaseTypeHasBothIndexers
                        ? undefined
                        : type.symbol.declarations[0];
                }
            }

            if (errorNode
                && !isTypeAssignableTo(numberIndexType!,
                    stringIndexType!))
            { // TODO: GH#18217
                error(
                    errorNode,
                    Diagnostics
                        .Numeric_index_type_0_is_not_assignable_to_string_index_type_1,
                    typeToString(numberIndexType!),
                    typeToString(stringIndexType!)
                );
            }

            function checkIndexConstraintForProperty(
                prop: Symbol,
                propertyType: Type,
                containingType: Type,
                indexDeclaration: Declaration | undefined,
                indexType: Type | undefined,
                indexKind: IndexKind
            ): void {
                // ESSymbol properties apply to neither string nor numeric indexers.
                if (!indexType || isKnownSymbol(prop)) {
                    return;
                }

                const propDeclaration = prop.valueDeclaration;
                const name = propDeclaration
                    && getNameOfDeclaration(propDeclaration);

                // index is numeric and property name is not valid numeric literal
                if (indexKind === IndexKind.Number
                    && !(name
                        ? isNumericName(name)
                        : isNumericLiteralName(prop.escapedName)))
                {
                    return;
                }

                // perform property check if property or indexer is declared in 'type'
                // this allows us to rule out cases when both property and indexer are inherited from the base class
                let errorNode: Node | undefined;
                if (propDeclaration && name
                    && (propDeclaration.kind === SyntaxKind.BinaryExpression
                        || name.kind === SyntaxKind.ComputedPropertyName
                        || prop.parent === containingType.symbol))
                {
                    errorNode = propDeclaration;
                } else if (indexDeclaration) {
                    errorNode = indexDeclaration;
                } else if (getObjectFlags(containingType)
                    & ObjectFlags.Interface)
                {
                    // for interfaces property and indexer might be inherited from different bases
                    // check if any base class already has both property and indexer.
                    // check should be performed only if 'type' is the first type that brings property\indexer together
                    const someBaseClassHasBothPropertyAndIndexer = forEach(
                        getBaseTypes(<InterfaceType> containingType),
                        base => getPropertyOfObjectType(base, prop.escapedName)
                            && getIndexTypeOfType(base, indexKind)
                    );
                    errorNode = someBaseClassHasBothPropertyAndIndexer
                        ? undefined
                        : containingType.symbol.declarations[0];
                }

                if (errorNode
                    && !isTypeAssignableTo(propertyType, indexType))
                {
                    const errorMessage = indexKind === IndexKind.String
                        ? Diagnostics
                            .Property_0_of_type_1_is_not_assignable_to_string_index_type_2
                        : Diagnostics
                            .Property_0_of_type_1_is_not_assignable_to_numeric_index_type_2;
                    error(
                        errorNode,
                        errorMessage,
                        symbolToString(prop),
                        typeToString(propertyType),
                        typeToString(indexType)
                    );
                }
            }
        }

        function checkTypeNameIsReserved(
            name: Identifier,
            message: DiagnosticMessage
        ): void {
            // TS 1.0 spec (April 2014): 3.6.1
            // The predefined type keywords are reserved and cannot be used as names of user defined types.
            switch (name.escapedText) {
                case 'any':
                case 'unknown':
                case 'number':
                case 'bigint':
                case 'boolean':
                case 'string':
                case 'symbol':
                case 'void':
                case 'object':
                    error(name, message, name.escapedText as string);
            }
        }

        /**
         * The name cannot be used as 'Object' of user defined types with special target.
         */
        function checkClassNameCollisionWithObject(name: Identifier): void {
            if (languageVersion === ScriptTarget.ES5
                && name.escapedText === 'Object'
                && moduleKind < ModuleKind.ES2015)
            {
                error(
                    name,
                    Diagnostics
                        .Class_name_cannot_be_Object_when_targeting_ES5_with_module_0,
                    ModuleKind[moduleKind]
                ); // https://github.com/Microsoft/TypeScript/issues/17494
            }
        }

        /**
         * Check each type parameter and check that type parameters have no duplicate type parameter declarations
         */
        function checkTypeParameters(
            typeParameterDeclarations: readonly TypeParameterDeclaration[]
                | undefined
        ) {
            if (typeParameterDeclarations) {
                let seenDefault = false;
                for (let i = 0; i < typeParameterDeclarations.length; i++) {
                    const node = typeParameterDeclarations[i];
                    checkTypeParameter(node);

                    if (produceDiagnostics) {
                        if (node.default) {
                            seenDefault = true;
                            checkTypeParametersNotReferenced(
                                node.default,
                                typeParameterDeclarations,
                                i
                            );
                        } else if (seenDefault) {
                            error(
                                node,
                                Diagnostics
                                    .Required_type_parameters_may_not_follow_optional_type_parameters
                            );
                        }
                        for (let j = 0; j < i; j++) {
                            if (typeParameterDeclarations[j].symbol
                                === node.symbol)
                            {
                                error(
                                    node.name,
                                    Diagnostics.Duplicate_identifier_0,
                                    declarationNameToString(node.name)
                                );
                            }
                        }
                    }
                }
            }
        }

        /** Check that type parameter defaults only reference previously declared type parameters */
        function checkTypeParametersNotReferenced(
            root: TypeNode,
            typeParameters: readonly TypeParameterDeclaration[],
            index: number
        ) {
            visit(root);
            function visit(node: Node) {
                if (node.kind === SyntaxKind.TypeReference) {
                    const type = getTypeFromTypeReference(<TypeReferenceNode> node);
                    if (type.flags & TypeFlags.TypeParameter) {
                        for (let i = index; i < typeParameters.length; i++) {
                            if (type.symbol
                                === getSymbolOfNode(typeParameters[i]))
                            {
                                error(
                                    node,
                                    Diagnostics
                                        .Type_parameter_defaults_can_only_reference_previously_declared_type_parameters
                                );
                            }
                        }
                    }
                }
                forEachChild(node, visit);
            }
        }

        /** Check that type parameter lists are identical across multiple declarations */
        function checkTypeParameterListsIdentical(symbol: Symbol) {
            if (symbol.declarations.length === 1) {
                return;
            }

            const links = getSymbolLinks(symbol);
            if (!links.typeParametersChecked) {
                links.typeParametersChecked = true;
                const declarations = getClassOrInterfaceDeclarationsOfSymbol(symbol);
                if (declarations.length <= 1) {
                    return;
                }

                const type = <InterfaceType> getDeclaredTypeOfSymbol(symbol);
                if (!areTypeParametersIdentical(
                    declarations,
                    type.localTypeParameters!
                )) {
                    // Report an error on every conflicting declaration.
                    const name = symbolToString(symbol);
                    for (const declaration of declarations) {
                        error(
                            declaration.name,
                            Diagnostics
                                .All_declarations_of_0_must_have_identical_type_parameters,
                            name
                        );
                    }
                }
            }
        }

        function areTypeParametersIdentical(
            declarations: readonly (ClassDeclaration | InterfaceDeclaration)[],
            targetParameters: TypeParameter[]
        ) {
            const maxTypeArgumentCount = length(targetParameters);
            const minTypeArgumentCount = getMinTypeArgumentCount(targetParameters);

            for (const declaration of declarations) {
                // If this declaration has too few or too many type parameters, we report an error
                const sourceParameters = getEffectiveTypeParameterDeclarations(declaration);
                const numTypeParameters = sourceParameters.length;
                if (numTypeParameters < minTypeArgumentCount
                    || numTypeParameters > maxTypeArgumentCount)
                {
                    return false;
                }

                for (let i = 0; i < numTypeParameters; i++) {
                    const source = sourceParameters[i];
                    const target = targetParameters[i];

                    // If the type parameter node does not have the same as the resolved type
                    // parameter at this position, we report an error.
                    if (source.name.escapedText
                        !== target.symbol.escapedName)
                    {
                        return false;
                    }

                    // If the type parameter node does not have an identical constraint as the resolved
                    // type parameter at this position, we report an error.
                    const constraint = getEffectiveConstraintOfTypeParameter(source);
                    const sourceConstraint = constraint
                        && getTypeFromTypeNode(constraint);
                    const targetConstraint = getConstraintOfTypeParameter(target);
                    // relax check if later interface augmentation has no constraint, it's more broad and is OK to merge with
                    // a more constrained interface (this could be generalized to a full heirarchy check, but that's maybe overkill)
                    if (sourceConstraint && targetConstraint
                        && !isTypeIdenticalTo(
                            sourceConstraint,
                            targetConstraint
                        ))
                    {
                        return false;
                    }

                    // If the type parameter node has a default and it is not identical to the default
                    // for the type parameter at this position, we report an error.
                    const sourceDefault = source.default
                        && getTypeFromTypeNode(source.default);
                    const targetDefault = getDefaultFromTypeParameter(target);
                    if (sourceDefault && targetDefault
                        && !isTypeIdenticalTo(sourceDefault, targetDefault))
                    {
                        return false;
                    }
                }
            }

            return true;
        }

        function checkClassExpression(node: ClassExpression): Type {
            checkClassLikeDeclaration(node);
            checkNodeDeferred(node);
            return getTypeOfSymbol(getSymbolOfNode(node));
        }

        function checkClassExpressionDeferred(node: ClassExpression) {
            forEach(node.members, checkSourceElement);
            registerForUnusedIdentifiersCheck(node);
        }

        function checkClassDeclaration(node: ClassDeclaration) {
            if (!node.name && !hasModifier(node, ModifierFlags.Default)) {
                grammarErrorOnFirstToken(
                    node,
                    Diagnostics
                        .A_class_declaration_without_the_default_modifier_must_have_a_name
                );
            }
            checkClassLikeDeclaration(node);
            forEach(node.members, checkSourceElement);

            registerForUnusedIdentifiersCheck(node);
        }

        function checkClassLikeDeclaration(node: ClassLikeDeclaration) {
            checkGrammarClassLikeDeclaration(node);
            checkDecorators(node);
            if (node.name) {
                checkTypeNameIsReserved(
                    node.name,
                    Diagnostics.Class_name_cannot_be_0
                );
                checkCollisionWithRequireExportsInGeneratedCode(
                    node,
                    node.name
                );
                checkCollisionWithGlobalPromiseInGeneratedCode(node,
                    node.name);
                if (!(node.flags & NodeFlags.Ambient)) {
                    checkClassNameCollisionWithObject(node.name);
                }
            }
            checkTypeParameters(getEffectiveTypeParameterDeclarations(node));
            checkExportsOnMergedDeclarations(node);
            const symbol = getSymbolOfNode(node);
            const type = <InterfaceType> getDeclaredTypeOfSymbol(symbol);
            const typeWithThis = getTypeWithThisArgument(type);
            const staticType = <ObjectType> getTypeOfSymbol(symbol);
            checkTypeParameterListsIdentical(symbol);
            checkClassForDuplicateDeclarations(node);

            // Only check for reserved static identifiers on non-ambient context.
            if (!(node.flags & NodeFlags.Ambient)) {
                checkClassForStaticPropertyNameConflicts(node);
            }

            const baseTypeNode = getEffectiveBaseTypeNode(node);
            if (baseTypeNode) {
                forEach(baseTypeNode.typeArguments, checkSourceElement);
                if (languageVersion < ScriptTarget.ES2015) {
                    checkExternalEmitHelpers(
                        baseTypeNode.parent,
                        ExternalEmitHelpers.Extends
                    );
                }
                // check both @extends and extends if both are specified.
                const extendsNode = getClassExtendsHeritageElement(node);
                if (extendsNode && extendsNode !== baseTypeNode) {
                    checkExpression(extendsNode.expression);
                }

                const baseTypes = getBaseTypes(type);
                if (baseTypes.length && produceDiagnostics) {
                    const baseType = baseTypes[0];
                    const baseConstructorType = getBaseConstructorTypeOfClass(type);
                    const staticBaseType = getApparentType(baseConstructorType);
                    checkBaseTypeAccessibility(staticBaseType, baseTypeNode);
                    checkSourceElement(baseTypeNode.expression);
                    if (some(baseTypeNode.typeArguments)) {
                        forEach(baseTypeNode.typeArguments,
                            checkSourceElement);
                        for (const constructor
                            of getConstructorsForTypeArguments(
                                staticBaseType,
                                baseTypeNode.typeArguments,
                                baseTypeNode
                            ))
                        {
                            if (!checkTypeArgumentConstraints(
                                baseTypeNode,
                                constructor.typeParameters!
                            )) {
                                break;
                            }
                        }
                    }
                    const baseWithThis = getTypeWithThisArgument(
                        baseType,
                        type.thisType
                    );
                    if (!checkTypeAssignableTo(
                        typeWithThis,
                        baseWithThis, /*errorNode*/
                        undefined
                    )) {
                        issueMemberSpecificError(
                            node,
                            typeWithThis,
                            baseWithThis,
                            Diagnostics
                                .Class_0_incorrectly_extends_base_class_1
                        );
                    } else {
                        // Report static side error only when instance type is assignable
                        checkTypeAssignableTo(
                            staticType,
                            getTypeWithoutSignatures(staticBaseType),
                            node.name || node,
                            Diagnostics
                                .Class_static_side_0_incorrectly_extends_base_class_static_side_1
                        );
                    }
                    if (baseConstructorType.flags & TypeFlags.TypeVariable
                        && !isMixinConstructorType(staticType))
                    {
                        error(
                            node.name || node,
                            Diagnostics
                                .A_mixin_class_must_have_a_constructor_with_a_single_rest_parameter_of_type_any
                        );
                    }

                    if (!(staticBaseType.symbol
                        && staticBaseType.symbol.flags & SymbolFlags.Class)
                        && !(baseConstructorType.flags
                            & TypeFlags.TypeVariable))
                    {
                        // When the static base type is a "class-like" constructor function (but not actually a class), we verify
                        // that all instantiated base constructor signatures return the same type.
                        const constructors = getInstantiatedConstructorsForTypeArguments(
                            staticBaseType,
                            baseTypeNode.typeArguments,
                            baseTypeNode
                        );
                        if (forEach(
                            constructors,
                            sig => !isJSConstructor(sig.declaration)
                                && !isTypeIdenticalTo(
                                    getReturnTypeOfSignature(sig),
                                    baseType
                                )
                        )) {
                            error(
                                baseTypeNode.expression,
                                Diagnostics
                                    .Base_constructors_must_all_have_the_same_return_type
                            );
                        }
                    }
                    checkKindsOfPropertyMemberOverrides(type, baseType);
                }
            }

            const implementedTypeNodes = getClassImplementsHeritageClauseElements(node);
            if (implementedTypeNodes) {
                for (const typeRefNode of implementedTypeNodes) {
                    if (!isEntityNameExpression(typeRefNode.expression)) {
                        error(
                            typeRefNode.expression,
                            Diagnostics
                                .A_class_can_only_implement_an_identifier_Slashqualified_name_with_optional_type_arguments
                        );
                    }
                    checkTypeReferenceNode(typeRefNode);
                    if (produceDiagnostics) {
                        const t = getTypeFromTypeNode(typeRefNode);
                        if (t !== errorType) {
                            if (isValidBaseType(t)) {
                                const genericDiag = t.symbol
                                    && t.symbol.flags & SymbolFlags.Class
                                    ? Diagnostics
                                        .Class_0_incorrectly_implements_class_1_Did_you_mean_to_extend_1_and_inherit_its_members_as_a_subclass
                                    : Diagnostics
                                        .Class_0_incorrectly_implements_interface_1;
                                const baseWithThis = getTypeWithThisArgument(
                                    t,
                                    type.thisType
                                );
                                if (!checkTypeAssignableTo(
                                    typeWithThis,
                                    baseWithThis, /*errorNode*/
                                    undefined
                                )) {
                                    issueMemberSpecificError(
                                        node,
                                        typeWithThis,
                                        baseWithThis,
                                        genericDiag
                                    );
                                }
                            } else {
                                error(
                                    typeRefNode,
                                    Diagnostics
                                        .A_class_can_only_implement_an_object_type_or_intersection_of_object_types_with_statically_known_members
                                );
                            }
                        }
                    }
                }
            }

            if (produceDiagnostics) {
                checkIndexConstraints(type);
                checkTypeForDuplicateIndexSignatures(node);
                checkPropertyInitialization(node);
            }
        }

        function issueMemberSpecificError(
            node: ClassLikeDeclaration,
            typeWithThis: Type,
            baseWithThis: Type,
            broadDiag: DiagnosticMessage
        ) {
            // iterate over all implemented properties and issue errors on each one which isn't compatible, rather than the class as a whole, if possible
            let issuedMemberError = false;
            for (const member of node.members) {
                if (hasStaticModifier(member)) {
                    continue;
                }
                const declaredProp = member.name
                    && getSymbolAtLocation(member.name)
                    || getSymbolAtLocation(member);
                if (declaredProp) {
                    const prop = getPropertyOfType(
                        typeWithThis,
                        declaredProp.escapedName
                    );
                    const baseProp = getPropertyOfType(
                        baseWithThis,
                        declaredProp.escapedName
                    );
                    if (prop && baseProp) {
                        const rootChain = () => chainDiagnosticMessages(
                            /*details*/ undefined,
                            Diagnostics
                                .Property_0_in_type_1_is_not_assignable_to_the_same_property_in_base_type_2,
                            symbolToString(declaredProp),
                            typeToString(typeWithThis),
                            typeToString(baseWithThis)
                        );
                        if (!checkTypeAssignableTo(
                            getTypeOfSymbol(prop),
                            getTypeOfSymbol(baseProp),
                            member.name || member, /*message*/
                            undefined,
                            rootChain
                        )) {
                            issuedMemberError = true;
                        }
                    }
                }
            }
            if (!issuedMemberError) {
                // check again with diagnostics to generate a less-specific error
                checkTypeAssignableTo(
                    typeWithThis,
                    baseWithThis,
                    node.name || node,
                    broadDiag
                );
            }
        }

        function checkBaseTypeAccessibility(
            type: Type,
            node: ExpressionWithTypeArguments
        ) {
            const signatures = getSignaturesOfType(
                type,
                SignatureKind.Construct
            );
            if (signatures.length) {
                const declaration = signatures[0].declaration;
                if (declaration
                    && hasModifier(declaration, ModifierFlags.Private))
                {
                    const typeClassDeclaration = getClassLikeDeclarationOfSymbol(
                        type.symbol
                    )!;
                    if (!isNodeWithinClass(node, typeClassDeclaration)) {
                        error(
                            node,
                            Diagnostics
                                .Cannot_extend_a_class_0_Class_constructor_is_marked_as_private,
                            getFullyQualifiedName(type.symbol)
                        );
                    }
                }
            }
        }

        function getTargetSymbol(s: Symbol) {
            // if symbol is instantiated its flags are not copied from the 'target'
            // so we'll need to get back original 'target' symbol to work with correct set of flags
            return getCheckFlags(s) & CheckFlags.Instantiated
                ? (<TransientSymbol> s).target!
                : s;
        }

        function getClassOrInterfaceDeclarationsOfSymbol(symbol: Symbol) {
            return filter(
                symbol.declarations,
                (d: Declaration): d is ClassDeclaration
                    | InterfaceDeclaration =>
                d.kind === SyntaxKind.ClassDeclaration
                    || d.kind === SyntaxKind.InterfaceDeclaration
            );
        }

        function checkKindsOfPropertyMemberOverrides(
            type: InterfaceType,
            baseType: BaseType
        ): void {
            // TypeScript 1.0 spec (April 2014): 8.2.3
            // A derived class inherits all members from its base class it doesn't override.
            // Inheritance means that a derived class implicitly contains all non - overridden members of the base class.
            // Both public and private property members are inherited, but only public property members can be overridden.
            // A property member in a derived class is said to override a property member in a base class
            // when the derived class property member has the same name and kind(instance or static)
            // as the base class property member.
            // The type of an overriding property member must be assignable(section 3.8.4)
            // to the type of the overridden property member, or otherwise a compile - time error occurs.
            // Base class instance member functions can be overridden by derived class instance member functions,
            // but not by other kinds of members.
            // Base class instance member variables and accessors can be overridden by
            // derived class instance member variables and accessors, but not by other kinds of members.

            // NOTE: assignability is checked in checkClassDeclaration
            const baseProperties = getPropertiesOfType(baseType);
            basePropertyCheck:
            for (const baseProperty of baseProperties) {
                const base = getTargetSymbol(baseProperty);

                if (base.flags & SymbolFlags.Prototype) {
                    continue;
                }
                const baseSymbol = getPropertyOfObjectType(
                    type,
                    base.escapedName
                );
                if (!baseSymbol) {
                    continue;
                }
                const derived = getTargetSymbol(baseSymbol);
                const baseDeclarationFlags = getDeclarationModifierFlagsFromSymbol(base);

                Debug.assert(
                    !!derived,
                    'derived should point to something, even if it is the base class\' declaration.'
                );

                // In order to resolve whether the inherited method was overridden in the base class or not,
                // we compare the Symbols obtained. Since getTargetSymbol returns the symbol on the *uninstantiated*
                // type declaration, derived and base resolve to the same symbol even in the case of generic classes.
                if (derived === base) {
                    // derived class inherits base without override/redeclaration
                    const derivedClassDecl = getClassLikeDeclarationOfSymbol(
                        type.symbol
                    )!;

                    // It is an error to inherit an abstract member without implementing it or being declared abstract.
                    // If there is no declaration for the derived class (as in the case of class expressions),
                    // then the class cannot be declared abstract.
                    if (baseDeclarationFlags & ModifierFlags.Abstract
                        && (!derivedClassDecl
                            || !hasModifier(
                                derivedClassDecl,
                                ModifierFlags.Abstract
                            )))
                    {
                        // Searches other base types for a declaration that would satisfy the inherited abstract member.
                        // (The class may have more than one base type via declaration merging with an interface with the
                        // same name.)
                        for (const otherBaseType of getBaseTypes(type)) {
                            if (otherBaseType === baseType) continue;
                            const baseSymbol = getPropertyOfObjectType(
                                otherBaseType,
                                base.escapedName
                            );
                            const derivedElsewhere = baseSymbol
                                && getTargetSymbol(baseSymbol);
                            if (derivedElsewhere
                                && derivedElsewhere !== base)
                            {
                                continue basePropertyCheck;
                            }
                        }

                        if (derivedClassDecl.kind
                            === SyntaxKind.ClassExpression)
                        {
                            error(
                                derivedClassDecl,
                                Diagnostics
                                    .Non_abstract_class_expression_does_not_implement_inherited_abstract_member_0_from_class_1,
                                symbolToString(baseProperty),
                                typeToString(baseType)
                            );
                        } else {
                            error(
                                derivedClassDecl,
                                Diagnostics
                                    .Non_abstract_class_0_does_not_implement_inherited_abstract_member_1_from_class_2,
                                typeToString(type),
                                symbolToString(baseProperty),
                                typeToString(baseType)
                            );
                        }
                    }
                } else {
                    // derived overrides base.
                    const derivedDeclarationFlags = getDeclarationModifierFlagsFromSymbol(derived);
                    if (baseDeclarationFlags & ModifierFlags.Private
                        || derivedDeclarationFlags & ModifierFlags.Private)
                    {
                        // either base or derived property is private - not override, skip it
                        continue;
                    }

                    let errorMessage: DiagnosticMessage;
                    const basePropertyFlags = base.flags
                        & SymbolFlags.PropertyOrAccessor;
                    const derivedPropertyFlags = derived.flags
                        & SymbolFlags.PropertyOrAccessor;
                    if (basePropertyFlags && derivedPropertyFlags) {
                        // property/accessor is overridden with property/accessor
                        if (!compilerOptions.useDefineForClassFields
                            || baseDeclarationFlags & ModifierFlags.Abstract
                            && !(base.valueDeclaration
                                && isPropertyDeclaration(base.valueDeclaration)
                                && base.valueDeclaration.initializer)
                            || base.valueDeclaration
                            && base.valueDeclaration.parent.kind
                            === SyntaxKind.InterfaceDeclaration
                            || derived.valueDeclaration
                            && isBinaryExpression(derived.valueDeclaration))
                        {
                            // when the base property is abstract or from an interface, base/derived flags don't need to match
                            // same when the derived property is from an assignment
                            continue;
                        }

                        const overriddenInstanceProperty = basePropertyFlags
                            !== SymbolFlags.Property
                            && derivedPropertyFlags === SymbolFlags.Property;
                        const overriddenInstanceAccessor = basePropertyFlags
                            === SymbolFlags.Property
                            && derivedPropertyFlags !== SymbolFlags.Property;
                        if (overriddenInstanceProperty
                            || overriddenInstanceAccessor)
                        {
                            const errorMessage = overriddenInstanceProperty
                                ? Diagnostics
                                    ._0_is_defined_as_an_accessor_in_class_1_but_is_overridden_here_in_2_as_an_instance_property
                                : Diagnostics
                                    ._0_is_defined_as_a_property_in_class_1_but_is_overridden_here_in_2_as_an_accessor;
                            error(
                                getNameOfDeclaration(
                                    derived.valueDeclaration
                                ) || derived.valueDeclaration,
                                errorMessage,
                                symbolToString(base),
                                typeToString(baseType),
                                typeToString(type)
                            );
                        } else {
                            const uninitialized = find(
                                derived.declarations,
                                d => d.kind === SyntaxKind.PropertyDeclaration
                                    && !(d as PropertyDeclaration).initializer
                            );
                            if (uninitialized
                                && !(derived.flags & SymbolFlags.Transient)
                                && !(baseDeclarationFlags
                                    & ModifierFlags.Abstract)
                                && !(derivedDeclarationFlags
                                    & ModifierFlags.Abstract)
                                && !derived.declarations
                                    .some(d => !!(d.flags
                                        & NodeFlags.Ambient)))
                            {
                                const constructor = findConstructorDeclaration(
                                    getClassLikeDeclarationOfSymbol(
                                        type.symbol
                                    )!
                                );
                                const propName = (uninitialized as PropertyDeclaration)
                                    .name;
                                if ((uninitialized as PropertyDeclaration)
                                    .exclamationToken
                                    || !constructor
                                    || !isIdentifier(propName)
                                    || !strictNullChecks
                                    || !isPropertyInitializedInConstructor(
                                        propName,
                                        type,
                                        constructor
                                    ))
                                {
                                    const errorMessage = Diagnostics
                                        .Property_0_will_overwrite_the_base_property_in_1_If_this_is_intentional_add_an_initializer_Otherwise_add_a_declare_modifier_or_remove_the_redundant_declaration;
                                    error(
                                        getNameOfDeclaration(
                                            derived.valueDeclaration
                                        ) || derived.valueDeclaration,
                                        errorMessage,
                                        symbolToString(base),
                                        typeToString(baseType)
                                    );
                                }
                            }
                        }

                        // correct case
                        continue;
                    } else if (isPrototypeProperty(base)) {
                        if (isPrototypeProperty(derived)
                            || derived.flags & SymbolFlags.Property)
                        {
                            // method is overridden with method or property -- correct case
                            continue;
                        } else {
                            Debug
                                .assert(
                                    !!(derived.flags & SymbolFlags.Accessor)
                                );
                            errorMessage = Diagnostics
                                .Class_0_defines_instance_member_function_1_but_extended_class_2_defines_it_as_instance_member_accessor;
                        }
                    } else if (base.flags & SymbolFlags.Accessor) {
                        errorMessage = Diagnostics
                            .Class_0_defines_instance_member_accessor_1_but_extended_class_2_defines_it_as_instance_member_function;
                    } else {
                        errorMessage = Diagnostics
                            .Class_0_defines_instance_member_property_1_but_extended_class_2_defines_it_as_instance_member_function;
                    }

                    error(
                        getNameOfDeclaration(derived.valueDeclaration)
                            || derived.valueDeclaration,
                        errorMessage,
                        typeToString(baseType),
                        symbolToString(base),
                        typeToString(type)
                    );
                }
            }
        }

        function checkInheritedPropertiesAreIdentical(
            type: InterfaceType,
            typeNode: Node
        ): boolean {
            const baseTypes = getBaseTypes(type);
            if (baseTypes.length < 2) {
                return true;
            }

            interface InheritanceInfoMap {
                prop: Symbol;
                containingType: Type;
            }
            const seen = createUnderscoreEscapedMap<InheritanceInfoMap>();
            forEach(
                resolveDeclaredMembers(type).declaredProperties,
                p => {
                    seen.set(p.escapedName, { prop: p, containingType: type });
                }
            );
            let ok = true;

            for (const base of baseTypes) {
                const properties = getPropertiesOfType(
                    getTypeWithThisArgument(
                        base,
                        type.thisType
                    )
                );
                for (const prop of properties) {
                    const existing = seen.get(prop.escapedName);
                    if (!existing) {
                        seen.set(
                            prop.escapedName,
                            { prop, containingType: base }
                        );
                    } else {
                        const isInheritedProperty = existing.containingType
                            !== type;
                        if (isInheritedProperty
                            && !isPropertyIdenticalTo(existing.prop, prop))
                        {
                            ok = false;

                            const typeName1 = typeToString(
                                existing.containingType
                            );
                            const typeName2 = typeToString(base);

                            let errorInfo = chainDiagnosticMessages(
                                /*details*/ undefined,
                                Diagnostics
                                    .Named_property_0_of_types_1_and_2_are_not_identical,
                                symbolToString(prop),
                                typeName1,
                                typeName2
                            );
                            errorInfo = chainDiagnosticMessages(
                                errorInfo,
                                Diagnostics
                                    .Interface_0_cannot_simultaneously_extend_types_1_and_2,
                                typeToString(type),
                                typeName1,
                                typeName2
                            );
                            diagnostics
                                .add(
                                    createDiagnosticForNodeFromMessageChain(
                                        typeNode,
                                        errorInfo
                                    )
                                );
                        }
                    }
                }
            }

            return ok;
        }

        function checkPropertyInitialization(node: ClassLikeDeclaration) {
            if (!strictNullChecks || !strictPropertyInitialization
                || node.flags & NodeFlags.Ambient)
            {
                return;
            }
            const constructor = findConstructorDeclaration(node);
            for (const member of node.members) {
                if (getModifierFlags(member) & ModifierFlags.Ambient) {
                    continue;
                }
                if (isInstancePropertyWithoutInitializer(member)) {
                    const propName = (<PropertyDeclaration> member).name;
                    if (isIdentifier(propName)) {
                        const type = getTypeOfSymbol(getSymbolOfNode(member));
                        if (!(type.flags & TypeFlags.AnyOrUnknown
                            || getFalsyFlags(type) & TypeFlags.Undefined))
                        {
                            if (!constructor
                                || !isPropertyInitializedInConstructor(
                                    propName,
                                    type,
                                    constructor
                                ))
                            {
                                error(
                                    member.name,
                                    Diagnostics
                                        .Property_0_has_no_initializer_and_is_not_definitely_assigned_in_the_constructor,
                                    declarationNameToString(propName)
                                );
                            }
                        }
                    }
                }
            }
        }

        function isInstancePropertyWithoutInitializer(node: Node) {
            return node.kind === SyntaxKind.PropertyDeclaration
                && !hasModifier(
                    node,
                    ModifierFlags.Static | ModifierFlags.Abstract
                )
                && !(<PropertyDeclaration> node).exclamationToken
                && !(<PropertyDeclaration> node).initializer;
        }

        function isPropertyInitializedInConstructor(
            propName: Identifier,
            propType: Type,
            constructor: ConstructorDeclaration
        ) {
            const reference = createPropertyAccess(createThis(), propName);
            reference.expression.parent = reference;
            reference.parent = constructor;
            reference.flowNode = constructor.returnFlowNode;
            const flowType = getFlowTypeOfReference(
                reference,
                propType,
                getOptionalType(propType)
            );
            return !(getFalsyFlags(flowType) & TypeFlags.Undefined);
        }

        function checkInterfaceDeclaration(node: InterfaceDeclaration) {
            // Grammar checking
            if (!checkGrammarDecoratorsAndModifiers(node)) checkGrammarInterfaceDeclaration(node);

            checkTypeParameters(node.typeParameters);
            if (produceDiagnostics) {
                checkTypeNameIsReserved(
                    node.name,
                    Diagnostics.Interface_name_cannot_be_0
                );

                checkExportsOnMergedDeclarations(node);
                const symbol = getSymbolOfNode(node);
                checkTypeParameterListsIdentical(symbol);

                // Only check this symbol once
                const firstInterfaceDecl = getDeclarationOfKind<InterfaceDeclaration>(
                    symbol,
                    SyntaxKind.InterfaceDeclaration
                );
                if (node === firstInterfaceDecl) {
                    const type = <InterfaceType> getDeclaredTypeOfSymbol(symbol);
                    const typeWithThis = getTypeWithThisArgument(type);
                    // run subsequent checks only if first set succeeded
                    if (checkInheritedPropertiesAreIdentical(type,
                        node.name))
                    {
                        for (const baseType of getBaseTypes(type)) {
                            checkTypeAssignableTo(
                                typeWithThis,
                                getTypeWithThisArgument(
                                    baseType,
                                    type.thisType
                                ),
                                node.name,
                                Diagnostics
                                    .Interface_0_incorrectly_extends_interface_1
                            );
                        }
                        checkIndexConstraints(type);
                    }
                }
                checkObjectTypeForDuplicateDeclarations(node);
            }
            forEach(
                getInterfaceBaseTypeNodes(node),
                heritageElement => {
                    if (!isEntityNameExpression(heritageElement.expression)) {
                        error(
                            heritageElement.expression,
                            Diagnostics
                                .An_interface_can_only_extend_an_identifier_Slashqualified_name_with_optional_type_arguments
                        );
                    }
                    checkTypeReferenceNode(heritageElement);
                }
            );

            forEach(node.members, checkSourceElement);

            if (produceDiagnostics) {
                checkTypeForDuplicateIndexSignatures(node);
                registerForUnusedIdentifiersCheck(node);
            }
        }

        function checkTypeAliasDeclaration(node: TypeAliasDeclaration) {
            // Grammar checking
            checkGrammarDecoratorsAndModifiers(node);

            checkTypeNameIsReserved(
                node.name,
                Diagnostics.Type_alias_name_cannot_be_0
            );
            checkTypeParameters(node.typeParameters);
            checkSourceElement(node.type);
            registerForUnusedIdentifiersCheck(node);
        }

        function computeEnumMemberValues(node: EnumDeclaration) {
            const nodeLinks = getNodeLinks(node);
            if (!(nodeLinks.flags & NodeCheckFlags.EnumValuesComputed)) {
                nodeLinks.flags |= NodeCheckFlags.EnumValuesComputed;
                let autoValue: number | undefined = 0;
                for (const member of node.members) {
                    const value = computeMemberValue(member, autoValue);
                    getNodeLinks(member).enumMemberValue = value;
                    autoValue = typeof value === 'number'
                        ? value + 1
                        : undefined;
                }
            }
        }

        function computeMemberValue(
            member: EnumMember,
            autoValue: number | undefined
        ) {
            if (isComputedNonLiteralName(member.name)) {
                error(
                    member.name,
                    Diagnostics
                        .Computed_property_names_are_not_allowed_in_enums
                );
            } else {
                const text = getTextOfPropertyName(member.name);
                if (isNumericLiteralName(text)
                    && !isInfinityOrNaNString(text))
                {
                    error(
                        member.name,
                        Diagnostics.An_enum_member_cannot_have_a_numeric_name
                    );
                }
            }
            if (member.initializer) {
                return computeConstantValue(member);
            }
            // In ambient non-const numeric enum declarations, enum members without initializers are
            // considered computed members (as opposed to having auto-incremented values).
            if (member.parent.flags & NodeFlags.Ambient
                && !isEnumConst(member.parent)
                && getEnumKind(getSymbolOfNode(member.parent))
                === EnumKind.Numeric)
            {
                return undefined;
            }
            // If the member declaration specifies no value, the member is considered a constant enum member.
            // If the member is the first member in the enum declaration, it is assigned the value zero.
            // Otherwise, it is assigned the value of the immediately preceding member plus one, and an error
            // occurs if the immediately preceding member is not a constant enum member.
            if (autoValue !== undefined) {
                return autoValue;
            }
            error(member.name, Diagnostics.Enum_member_must_have_initializer);
            return undefined;
        }

        function computeConstantValue(
            member: EnumMember
        ): string | number | undefined {
            const enumKind = getEnumKind(getSymbolOfNode(member.parent));
            const isConstEnum = isEnumConst(member.parent);
            const initializer = member.initializer!;
            const value = enumKind === EnumKind.Literal
                && !isLiteralEnumMember(member)
                ? undefined
                : evaluate(initializer);
            if (value !== undefined) {
                if (isConstEnum && typeof value === 'number'
                    && !isFinite(value))
                {
                    error(
                        initializer,
                        isNaN(value)
                            ? Diagnostics
                                .const_enum_member_initializer_was_evaluated_to_disallowed_value_NaN
                            : Diagnostics
                                .const_enum_member_initializer_was_evaluated_to_a_non_finite_value
                    );
                }
            } else if (enumKind === EnumKind.Literal) {
                error(
                    initializer,
                    Diagnostics
                        .Computed_values_are_not_permitted_in_an_enum_with_string_valued_members
                );
                return 0;
            } else if (isConstEnum) {
                error(
                    initializer,
                    Diagnostics
                        .const_enum_member_initializers_can_only_contain_literal_values_and_other_computed_enum_values
                );
            } else if (member.parent.flags & NodeFlags.Ambient) {
                error(
                    initializer,
                    Diagnostics
                        .In_ambient_enum_declarations_member_initializer_must_be_constant_expression
                );
            } else {
                // Only here do we need to check that the initializer is assignable to the enum type.
                checkTypeAssignableTo(
                    checkExpression(initializer),
                    getDeclaredTypeOfSymbol(getSymbolOfNode(member.parent)),
                    initializer, /*headMessage*/
                    undefined
                );
            }
            return value;

            function evaluate(expr: Expression): string | number | undefined {
                switch (expr.kind) {
                    case SyntaxKind.PrefixUnaryExpression:
                        const value = evaluate(
                            (<PrefixUnaryExpression> expr).operand
                        );
                        if (typeof value === 'number') {
                            switch ((<PrefixUnaryExpression> expr).operator) {
                                case SyntaxKind.PlusToken:
                                    return value;
                                case SyntaxKind.MinusToken:
                                    return -value;
                                case SyntaxKind.TildeToken:
                                    return ~value;
                            }
                        }
                        break;
                    case SyntaxKind.BinaryExpression:
                        const left = evaluate((<BinaryExpression> expr).left);
                        const right = evaluate((<BinaryExpression> expr)
                            .right);
                        if (typeof left === 'number'
                            && typeof right === 'number')
                        {
                            switch ((<BinaryExpression> expr).operatorToken
                                .kind)
                            {
                                case SyntaxKind.BarToken:
                                    return left | right;
                                case SyntaxKind.AmpersandToken:
                                    return left & right;
                                case SyntaxKind.GreaterThanGreaterThanToken:
                                    return left >> right;
                                case SyntaxKind
                                    .GreaterThanGreaterThanGreaterThanToken:
                                    return left >>> right;
                                case SyntaxKind.LessThanLessThanToken:
                                    return left << right;
                                case SyntaxKind.CaretToken:
                                    return left ^ right;
                                case SyntaxKind.AsteriskToken:
                                    return left * right;
                                case SyntaxKind.SlashToken:
                                    return left / right;
                                case SyntaxKind.PlusToken:
                                    return left + right;
                                case SyntaxKind.MinusToken:
                                    return left - right;
                                case SyntaxKind.PercentToken:
                                    return left % right;
                                case SyntaxKind.AsteriskAsteriskToken:
                                    return left ** right;
                            }
                        } else if (typeof left === 'string'
                            && typeof right === 'string'
                            && (<BinaryExpression> expr).operatorToken.kind
                            === SyntaxKind.PlusToken)
                        {
                            return left + right;
                        }
                        break;
                    case SyntaxKind.StringLiteral:
                    case SyntaxKind.NoSubstitutionTemplateLiteral:
                        return (<StringLiteralLike> expr).text;
                    case SyntaxKind.NumericLiteral:
                        checkGrammarNumericLiteral(<NumericLiteral> expr);
                        return +(<NumericLiteral> expr).text;
                    case SyntaxKind.ParenthesizedExpression:
                        return evaluate(
                            (<ParenthesizedExpression> expr).expression
                        );
                    case SyntaxKind.Identifier:
                        const identifier = <Identifier> expr;
                        if (isInfinityOrNaNString(identifier.escapedText)) {
                            return +(identifier.escapedText);
                        }
                        return nodeIsMissing(expr)
                            ? 0
                            : evaluateEnumMember(
                                expr,
                                getSymbolOfNode(member.parent),
                                identifier.escapedText
                            );
                    case SyntaxKind.ElementAccessExpression:
                    case SyntaxKind.PropertyAccessExpression:
                        const ex = <AccessExpression> expr;
                        if (isConstantMemberAccess(ex)) {
                            const type = getTypeOfExpression(ex.expression);
                            if (type.symbol
                                && type.symbol.flags & SymbolFlags.Enum)
                            {
                                let name: __String;
                                if (ex.kind
                                    === SyntaxKind.PropertyAccessExpression)
                                {
                                    name = ex.name.escapedText;
                                } else {
                                    name = escapeLeadingUnderscores(
                                        cast(
                                            ex.argumentExpression,
                                            isLiteralExpression
                                        ).text
                                    );
                                }
                                return evaluateEnumMember(
                                    expr,
                                    type.symbol,
                                    name
                                );
                            }
                        }
                        break;
                }
                return undefined;
            }

            function evaluateEnumMember(
                expr: Expression,
                enumSymbol: Symbol,
                name: __String
            ) {
                const memberSymbol = enumSymbol.exports!.get(name);
                if (memberSymbol) {
                    const declaration = memberSymbol.valueDeclaration;
                    if (declaration !== member) {
                        if (isBlockScopedNameDeclaredBeforeUse(
                            declaration,
                            member
                        )) {
                            return getEnumMemberValue(declaration as EnumMember);
                        }
                        error(
                            expr,
                            Diagnostics
                                .A_member_initializer_in_a_enum_declaration_cannot_reference_members_declared_after_it_including_members_defined_in_other_enums
                        );
                        return 0;
                    }
                }
                return undefined;
            }
        }

        function isConstantMemberAccess(node: Expression): boolean {
            return node.kind === SyntaxKind.Identifier
                || node.kind === SyntaxKind.PropertyAccessExpression
                && isConstantMemberAccess(
                    (<PropertyAccessExpression> node).expression
                )
                || node.kind === SyntaxKind.ElementAccessExpression
                && isConstantMemberAccess(
                    (<ElementAccessExpression> node).expression
                )
                && isStringLiteralLike(
                    (<ElementAccessExpression> node).argumentExpression
                );
        }

        function checkEnumDeclaration(node: EnumDeclaration) {
            if (!produceDiagnostics) {
                return;
            }

            // Grammar checking
            checkGrammarDecoratorsAndModifiers(node);

            checkTypeNameIsReserved(
                node.name,
                Diagnostics.Enum_name_cannot_be_0
            );
            checkCollisionWithRequireExportsInGeneratedCode(node, node.name);
            checkCollisionWithGlobalPromiseInGeneratedCode(node, node.name);
            checkExportsOnMergedDeclarations(node);
            node.members.forEach(checkEnumMember);

            computeEnumMemberValues(node);

            // Spec 2014 - Section 9.3:
            // It isn't possible for one enum declaration to continue the automatic numbering sequence of another,
            // and when an enum type has multiple declarations, only one declaration is permitted to omit a value
            // for the first member.
            //
            // Only perform this check once per symbol
            const enumSymbol = getSymbolOfNode(node);
            const firstDeclaration = getDeclarationOfKind(
                enumSymbol,
                node.kind
            );
            if (node === firstDeclaration) {
                if (enumSymbol.declarations.length > 1) {
                    const enumIsConst = isEnumConst(node);
                    // check that const is placed\omitted on all enum declarations
                    forEach(
                        enumSymbol.declarations,
                        decl => {
                            if (isEnumDeclaration(decl)
                                && isEnumConst(decl) !== enumIsConst)
                            {
                                error(
                                    getNameOfDeclaration(decl),
                                    Diagnostics
                                        .Enum_declarations_must_all_be_const_or_non_const
                                );
                            }
                        }
                    );
                }

                let seenEnumMissingInitialInitializer = false;
                forEach(
                    enumSymbol.declarations,
                    declaration => {
                        // return true if we hit a violation of the rule, false otherwise
                        if (declaration.kind !== SyntaxKind.EnumDeclaration) {
                            return false;
                        }

                        const enumDeclaration = <EnumDeclaration> declaration;
                        if (!enumDeclaration.members.length) {
                            return false;
                        }

                        const firstEnumMember = enumDeclaration.members[0];
                        if (!firstEnumMember.initializer) {
                            if (seenEnumMissingInitialInitializer) {
                                error(
                                    firstEnumMember.name,
                                    Diagnostics
                                        .In_an_enum_with_multiple_declarations_only_one_declaration_can_omit_an_initializer_for_its_first_enum_element
                                );
                            } else {
                                seenEnumMissingInitialInitializer = true;
                            }
                        }
                    }
                );
            }
        }

        function checkEnumMember(node: EnumMember) {
            if (isPrivateIdentifier(node.name)) {
                error(
                    node,
                    Diagnostics
                        .An_enum_member_cannot_be_named_with_a_private_identifier
                );
            }
        }

        function getFirstNonAmbientClassOrFunctionDeclaration(
            symbol: Symbol
        ): Declaration | undefined {
            const declarations = symbol.declarations;
            for (const declaration of declarations) {
                if ((declaration.kind === SyntaxKind.ClassDeclaration
                    || (declaration.kind === SyntaxKind.FunctionDeclaration
                        && nodeIsPresent(
                            (<FunctionLikeDeclaration> declaration).body
                        )))
                    && !(declaration.flags & NodeFlags.Ambient))
                {
                    return declaration;
                }
            }
            return undefined;
        }

        function inSameLexicalScope(node1: Node, node2: Node) {
            const container1 = getEnclosingBlockScopeContainer(node1);
            const container2 = getEnclosingBlockScopeContainer(node2);
            if (isGlobalSourceFile(container1)) {
                return isGlobalSourceFile(container2);
            } else if (isGlobalSourceFile(container2)) {
                return false;
            } else {
                return container1 === container2;
            }
        }

        function checkModuleDeclaration(node: ModuleDeclaration) {
            if (produceDiagnostics) {
                // Grammar checking
                const isGlobalAugmentation = isGlobalScopeAugmentation(node);
                const inAmbientContext = node.flags & NodeFlags.Ambient;
                if (isGlobalAugmentation && !inAmbientContext) {
                    error(
                        node.name,
                        Diagnostics
                            .Augmentations_for_the_global_scope_should_have_declare_modifier_unless_they_appear_in_already_ambient_context
                    );
                }

                const isAmbientExternalModule = isAmbientModule(node);
                const contextErrorMessage = isAmbientExternalModule
                    ? Diagnostics
                        .An_ambient_module_declaration_is_only_allowed_at_the_top_level_in_a_file
                    : Diagnostics
                        .A_namespace_declaration_is_only_allowed_in_a_namespace_or_module;
                if (checkGrammarModuleElementContext(node,
                    contextErrorMessage))
                {
                    // If we hit a module declaration in an illegal context, just bail out to avoid cascading errors.
                    return;
                }

                if (!checkGrammarDecoratorsAndModifiers(node)) {
                    if (!inAmbientContext
                        && node.name.kind === SyntaxKind.StringLiteral)
                    {
                        grammarErrorOnNode(
                            node.name,
                            Diagnostics
                                .Only_ambient_modules_can_use_quoted_names
                        );
                    }
                }

                if (isIdentifier(node.name)) {
                    checkCollisionWithRequireExportsInGeneratedCode(
                        node,
                        node.name
                    );
                    checkCollisionWithGlobalPromiseInGeneratedCode(
                        node,
                        node.name
                    );
                }

                checkExportsOnMergedDeclarations(node);
                const symbol = getSymbolOfNode(node);

                // The following checks only apply on a non-ambient instantiated module declaration.
                if (symbol.flags & SymbolFlags.ValueModule
                    && !inAmbientContext
                    && symbol.declarations.length > 1
                    && isInstantiatedModule(
                        node,
                        !!compilerOptions.preserveConstEnums
                            || !!compilerOptions.isolatedModules
                    ))
                {
                    const firstNonAmbientClassOrFunc = getFirstNonAmbientClassOrFunctionDeclaration(symbol);
                    if (firstNonAmbientClassOrFunc) {
                        if (getSourceFileOfNode(node)
                            !== getSourceFileOfNode(firstNonAmbientClassOrFunc))
                        {
                            error(
                                node.name,
                                Diagnostics
                                    .A_namespace_declaration_cannot_be_in_a_different_file_from_a_class_or_function_with_which_it_is_merged
                            );
                        } else if (node.pos < firstNonAmbientClassOrFunc.pos) {
                            error(
                                node.name,
                                Diagnostics
                                    .A_namespace_declaration_cannot_be_located_prior_to_a_class_or_function_with_which_it_is_merged
                            );
                        }
                    }

                    // if the module merges with a class declaration in the same lexical scope,
                    // we need to track this to ensure the correct emit.
                    const mergedClass = getDeclarationOfKind(
                        symbol,
                        SyntaxKind.ClassDeclaration
                    );
                    if (mergedClass
                        && inSameLexicalScope(node, mergedClass))
                    {
                        getNodeLinks(node).flags |= NodeCheckFlags
                            .LexicalModuleMergesWithClass;
                    }
                }

                if (isAmbientExternalModule) {
                    if (isExternalModuleAugmentation(node)) {
                        // body of the augmentation should be checked for consistency only if augmentation was applied to its target (either global scope or module)
                        // otherwise we'll be swamped in cascading errors.
                        // We can detect if augmentation was applied using following rules:
                        // - augmentation for a global scope is always applied
                        // - augmentation for some external module is applied if symbol for augmentation is merged (it was combined with target module).
                        const checkBody = isGlobalAugmentation
                            || (getSymbolOfNode(node).flags
                                & SymbolFlags.Transient);
                        if (checkBody && node.body) {
                            for (const statement of node.body.statements) {
                                checkModuleAugmentationElement(
                                    statement,
                                    isGlobalAugmentation
                                );
                            }
                        }
                    } else if (isGlobalSourceFile(node.parent)) {
                        if (isGlobalAugmentation) {
                            error(
                                node.name,
                                Diagnostics
                                    .Augmentations_for_the_global_scope_can_only_be_directly_nested_in_external_modules_or_ambient_module_declarations
                            );
                        } else if (isExternalModuleNameRelative(
                            getTextOfIdentifierOrLiteral(
                                node.name
                            )
                        )) {
                            error(
                                node.name,
                                Diagnostics
                                    .Ambient_module_declaration_cannot_specify_relative_module_name
                            );
                        }
                    } else {
                        if (isGlobalAugmentation) {
                            error(
                                node.name,
                                Diagnostics
                                    .Augmentations_for_the_global_scope_can_only_be_directly_nested_in_external_modules_or_ambient_module_declarations
                            );
                        } else {
                            // Node is not an augmentation and is not located on the script level.
                            // This means that this is declaration of ambient module that is located in other module or namespace which is prohibited.
                            error(
                                node.name,
                                Diagnostics
                                    .Ambient_modules_cannot_be_nested_in_other_modules_or_namespaces
                            );
                        }
                    }
                }
            }

            if (node.body) {
                checkSourceElement(node.body);
                if (!isGlobalScopeAugmentation(node)) {
                    registerForUnusedIdentifiersCheck(node);
                }
            }
        }

        function checkModuleAugmentationElement(
            node: Node,
            isGlobalAugmentation: boolean
        ): void {
            switch (node.kind) {
                case SyntaxKind.VariableStatement:
                    // error each individual name in variable statement instead of marking the entire variable statement
                    for (const decl of (<VariableStatement> node)
                        .declarationList.declarations)
                    {
                        checkModuleAugmentationElement(
                            decl,
                            isGlobalAugmentation
                        );
                    }
                    break;
                case SyntaxKind.ExportAssignment:
                case SyntaxKind.ExportDeclaration:
                    grammarErrorOnFirstToken(
                        node,
                        Diagnostics
                            .Exports_and_export_assignments_are_not_permitted_in_module_augmentations
                    );
                    break;
                case SyntaxKind.ImportEqualsDeclaration:
                case SyntaxKind.ImportDeclaration:
                    grammarErrorOnFirstToken(
                        node,
                        Diagnostics
                            .Imports_are_not_permitted_in_module_augmentations_Consider_moving_them_to_the_enclosing_external_module
                    );
                    break;
                case SyntaxKind.BindingElement:
                case SyntaxKind.VariableDeclaration:
                    const name = (<VariableDeclaration | BindingElement> node)
                        .name;
                    if (isBindingPattern(name)) {
                        for (const el of name.elements) {
                            // mark individual names in binding pattern
                            checkModuleAugmentationElement(
                                el,
                                isGlobalAugmentation
                            );
                        }
                        break;
                    }
                    // falls through
                case SyntaxKind.ClassDeclaration:
                case SyntaxKind.EnumDeclaration:
                case SyntaxKind.FunctionDeclaration:
                case SyntaxKind.InterfaceDeclaration:
                case SyntaxKind.ModuleDeclaration:
                case SyntaxKind.TypeAliasDeclaration:
                    if (isGlobalAugmentation) {
                        return;
                    }
                    const symbol = getSymbolOfNode(node);
                    if (symbol) {
                        // module augmentations cannot introduce new names on the top level scope of the module
                        // this is done it two steps
                        // 1. quick check - if symbol for node is not merged - this is local symbol to this augmentation - report error
                        // 2. main check - report error if value declaration of the parent symbol is module augmentation)
                        let reportError = !(symbol.flags
                            & SymbolFlags.Transient);
                        if (!reportError) {
                            // symbol should not originate in augmentation
                            reportError = !!symbol.parent
                                && isExternalModuleAugmentation(
                                    symbol.parent.declarations[0]
                                );
                        }
                    }
                    break;
            }
        }

        function getFirstNonModuleExportsIdentifier(
            node: EntityNameOrEntityNameExpression
        ): Identifier {
            switch (node.kind) {
                case SyntaxKind.Identifier:
                    return node;
                case SyntaxKind.QualifiedName:
                    do {
                        node = node.left;
                    } while (node.kind !== SyntaxKind.Identifier);
                    return node;
                case SyntaxKind.PropertyAccessExpression:
                    do {
                        if (isModuleExportsAccessExpression(node.expression)
                            && !isPrivateIdentifier(node.name))
                        {
                            return node.name;
                        }
                        node = node.expression;
                    } while (node.kind !== SyntaxKind.Identifier);
                    return node;
            }
        }

        function checkExternalImportOrExportDeclaration(
            node: ImportDeclaration | ImportEqualsDeclaration
                | ExportDeclaration
        ): boolean {
            const moduleName = getExternalModuleName(node);
            if (!moduleName || nodeIsMissing(moduleName)) {
                // Should be a parse error.
                return false;
            }
            if (!isStringLiteral(moduleName)) {
                error(moduleName, Diagnostics.String_literal_expected);
                return false;
            }
            const inAmbientExternalModule = node.parent.kind
                === SyntaxKind.ModuleBlock
                && isAmbientModule(node.parent.parent);
            if (node.parent.kind !== SyntaxKind.SourceFile
                && !inAmbientExternalModule)
            {
                error(
                    moduleName,
                    node.kind === SyntaxKind.ExportDeclaration
                        ? Diagnostics
                            .Export_declarations_are_not_permitted_in_a_namespace
                        : Diagnostics
                            .Import_declarations_in_a_namespace_cannot_reference_a_module
                );
                return false;
            }
            if (inAmbientExternalModule
                && isExternalModuleNameRelative(moduleName.text))
            {
                // we have already reported errors on top level imports\exports in external module augmentations in checkModuleDeclaration
                // no need to do this again.
                if (!isTopLevelInExternalModuleAugmentation(node)) {
                    // TypeScript 1.0 spec (April 2013): 12.1.6
                    // An ExternalImportDeclaration in an AmbientExternalModuleDeclaration may reference
                    // other external modules only through top - level external module names.
                    // Relative external module names are not permitted.
                    error(
                        node,
                        Diagnostics
                            .Import_or_export_declaration_in_an_ambient_module_declaration_cannot_reference_module_through_relative_module_name
                    );
                    return false;
                }
            }
            return true;
        }

        function checkAliasSymbol(
            node: ImportEqualsDeclaration | ImportClause | NamespaceImport
                | ImportSpecifier | ExportSpecifier | NamespaceExport
        ) {
            let symbol = getSymbolOfNode(node);
            const target = resolveAlias(symbol);

            const shouldSkipWithJSExpandoTargets = symbol.flags
                & SymbolFlags.Assignment;
            if (!shouldSkipWithJSExpandoTargets && target !== unknownSymbol) {
                // For external modules symbol represents local symbol for an alias.
                // This local symbol will merge any other local declarations (excluding other aliases)
                // and symbol.flags will contains combined representation for all merged declaration.
                // Based on symbol.flags we can compute a set of excluded meanings (meaning that resolved alias should not have,
                // otherwise it will conflict with some local declaration). Note that in addition to normal flags we include matching SymbolFlags.Export*
                // in order to prevent collisions with declarations that were exported from the current module (they still contribute to local names).
                symbol = getMergedSymbol(symbol.exportSymbol || symbol);
                const excludedMeanings = (symbol.flags
                    & (SymbolFlags.Value | SymbolFlags.ExportValue)
                    ? SymbolFlags.Value
                    : 0)
                    | (symbol.flags & SymbolFlags.Type ? SymbolFlags.Type : 0)
                    | (symbol.flags & SymbolFlags.Namespace
                        ? SymbolFlags.Namespace
                        : 0);
                if (target.flags & excludedMeanings) {
                    const message = node.kind === SyntaxKind.ExportSpecifier
                        ? Diagnostics
                            .Export_declaration_conflicts_with_exported_declaration_of_0
                        : Diagnostics
                            .Import_declaration_conflicts_with_local_declaration_of_0;
                    error(node, message, symbolToString(symbol));
                }

                // Don't allow to re-export something with no value side when `--isolatedModules` is set.
                if (compilerOptions.isolatedModules
                    && node.kind === SyntaxKind.ExportSpecifier
                    && !node.parent.parent.isTypeOnly
                    && !(target.flags & SymbolFlags.Value)
                    && !(node.flags & NodeFlags.Ambient))
                {
                    error(
                        node,
                        Diagnostics
                            .Re_exporting_a_type_when_the_isolatedModules_flag_is_provided_requires_using_export_type
                    );
                }
            }
        }

        function checkImportBinding(
            node: ImportEqualsDeclaration | ImportClause | NamespaceImport
                | ImportSpecifier
        ) {
            checkCollisionWithRequireExportsInGeneratedCode(node, node.name!);
            checkCollisionWithGlobalPromiseInGeneratedCode(node, node.name!);
            checkAliasSymbol(node);
        }

        function checkImportDeclaration(node: ImportDeclaration) {
            if (checkGrammarModuleElementContext(
                node,
                Diagnostics
                    .An_import_declaration_can_only_be_used_in_a_namespace_or_module
            )) {
                // If we hit an import declaration in an illegal context, just bail out to avoid cascading errors.
                return;
            }
            if (!checkGrammarDecoratorsAndModifiers(node)
                && hasModifiers(node))
            {
                grammarErrorOnFirstToken(
                    node,
                    Diagnostics.An_import_declaration_cannot_have_modifiers
                );
            }
            if (checkExternalImportOrExportDeclaration(node)) {
                const importClause = node.importClause;
                if (importClause && !checkGrammarImportClause(importClause)) {
                    if (importClause.name) {
                        checkImportBinding(importClause);
                    }
                    if (importClause.namedBindings) {
                        if (importClause.namedBindings.kind
                            === SyntaxKind.NamespaceImport)
                        {
                            checkImportBinding(importClause.namedBindings);
                        } else {
                            const moduleExisted = resolveExternalModuleName(
                                node,
                                node.moduleSpecifier
                            );
                            if (moduleExisted) {
                                forEach(
                                    importClause.namedBindings.elements,
                                    checkImportBinding
                                );
                            }
                        }
                    }
                }
            }
        }

        function checkImportEqualsDeclaration(node: ImportEqualsDeclaration) {
            if (checkGrammarModuleElementContext(
                node,
                Diagnostics
                    .An_import_declaration_can_only_be_used_in_a_namespace_or_module
            )) {
                // If we hit an import declaration in an illegal context, just bail out to avoid cascading errors.
                return;
            }

            checkGrammarDecoratorsAndModifiers(node);
            if (isInternalModuleImportEqualsDeclaration(node)
                || checkExternalImportOrExportDeclaration(node))
            {
                checkImportBinding(node);
                if (hasModifier(node, ModifierFlags.Export)) {
                    markExportAsReferenced(node);
                }
                if (node.moduleReference.kind
                    !== SyntaxKind.ExternalModuleReference)
                {
                    const target = resolveAlias(getSymbolOfNode(node));
                    if (target !== unknownSymbol) {
                        if (target.flags & SymbolFlags.Value) {
                            // Target is a value symbol, check that it is not hidden by a local declaration with the same name
                            const moduleName = getFirstIdentifier(
                                node.moduleReference
                            );
                            if (!(resolveEntityName(
                                moduleName,
                                SymbolFlags.Value | SymbolFlags.Namespace
                            )!.flags & SymbolFlags.Namespace)) {
                                error(
                                    moduleName,
                                    Diagnostics
                                        .Module_0_is_hidden_by_a_local_declaration_with_the_same_name,
                                    declarationNameToString(moduleName)
                                );
                            }
                        }
                        if (target.flags & SymbolFlags.Type) {
                            checkTypeNameIsReserved(
                                node.name,
                                Diagnostics.Import_name_cannot_be_0
                            );
                        }
                    }
                } else {
                    if (moduleKind >= ModuleKind.ES2015
                        && !(node.flags & NodeFlags.Ambient))
                    {
                        // Import equals declaration is deprecated in es6 or above
                        grammarErrorOnNode(
                            node,
                            Diagnostics
                                .Import_assignment_cannot_be_used_when_targeting_ECMAScript_modules_Consider_using_import_Asterisk_as_ns_from_mod_import_a_from_mod_import_d_from_mod_or_another_module_format_instead
                        );
                    }
                }
            }
        }

        function checkExportDeclaration(node: ExportDeclaration) {
            if (checkGrammarModuleElementContext(
                node,
                Diagnostics.An_export_declaration_can_only_be_used_in_a_module
            )) {
                // If we hit an export in an illegal context, just bail out to avoid cascading errors.
                return;
            }

            if (!checkGrammarDecoratorsAndModifiers(node)
                && hasModifiers(node))
            {
                grammarErrorOnFirstToken(
                    node,
                    Diagnostics.An_export_declaration_cannot_have_modifiers
                );
            }

            if (!node.moduleSpecifier
                || checkExternalImportOrExportDeclaration(node))
            {
                if (node.exportClause) {
                    // export { x, y }
                    // export { x, y } from "foo"
                    if (isNamedExports(node.exportClause)) {
                        forEach(
                            node.exportClause.elements,
                            checkExportSpecifier
                        );
                    } else if (!isNamespaceExport(node.exportClause)) {
                        checkImportBinding(node.exportClause);
                    }

                    const inAmbientExternalModule = node.parent.kind
                        === SyntaxKind.ModuleBlock
                        && isAmbientModule(node.parent.parent);
                    const inAmbientNamespaceDeclaration = !inAmbientExternalModule
                        && node.parent.kind === SyntaxKind.ModuleBlock
                        && !node.moduleSpecifier
                        && node.flags & NodeFlags.Ambient;
                    if (node.parent.kind !== SyntaxKind.SourceFile
                        && !inAmbientExternalModule
                        && !inAmbientNamespaceDeclaration)
                    {
                        error(
                            node,
                            Diagnostics
                                .Export_declarations_are_not_permitted_in_a_namespace
                        );
                    }
                } else {
                    // export * from "foo"
                    const moduleSymbol = resolveExternalModuleName(
                        node,
                        node.moduleSpecifier!
                    );
                    if (moduleSymbol
                        && hasExportAssignmentSymbol(moduleSymbol))
                    {
                        error(
                            node.moduleSpecifier,
                            Diagnostics
                                .Module_0_uses_export_and_cannot_be_used_with_export_Asterisk,
                            symbolToString(moduleSymbol)
                        );
                    }

                    if (moduleKind !== ModuleKind.System
                        && moduleKind < ModuleKind.ES2015)
                    {
                        checkExternalEmitHelpers(
                            node,
                            ExternalEmitHelpers.ExportStar
                        );
                    }
                }
            }
        }

        function checkGrammarModuleElementContext(
            node: Statement,
            errorMessage: DiagnosticMessage
        ): boolean {
            const isInAppropriateContext = node.parent.kind
                === SyntaxKind.SourceFile
                || node.parent.kind === SyntaxKind.ModuleBlock
                || node.parent.kind === SyntaxKind.ModuleDeclaration;
            if (!isInAppropriateContext) {
                grammarErrorOnFirstToken(node, errorMessage);
            }
            return !isInAppropriateContext;
        }

        function importClauseContainsReferencedImport(
            importClause: ImportClause
        ) {
            return importClause.name && isReferenced(importClause)
                || importClause.namedBindings
                && namedBindingsContainsReferencedImport(
                    importClause.namedBindings
                );

            function isReferenced(declaration: Declaration) {
                return !!getMergedSymbol(getSymbolOfNode(declaration))
                    .isReferenced;
            }
            function namedBindingsContainsReferencedImport(
                namedBindings: NamedImportBindings
            ) {
                return isNamespaceImport(namedBindings)
                    ? isReferenced(namedBindings)
                    : some(namedBindings.elements, isReferenced);
            }
        }

        function checkImportsForTypeOnlyConversion(sourceFile: SourceFile) {
            for (const statement of sourceFile.statements) {
                if (
                    isImportDeclaration(statement)
                    && statement.importClause
                    && !statement.importClause.isTypeOnly
                    && importClauseContainsReferencedImport(
                        statement.importClause
                    )
                    && !isReferencedAliasDeclaration(
                        statement.importClause, /*checkChildren*/
                        true
                    )
                ) {
                    const isError = compilerOptions.importsNotUsedAsValue
                        === ImportsNotUsedAsValue.Error;
                    errorOrSuggestion(
                        isError,
                        statement,
                        isError
                            ? Diagnostics
                                .This_import_is_never_used_as_a_value_and_must_use_import_type_because_the_importsNotUsedAsValue_is_set_to_error
                            : Diagnostics
                                .This_import_may_be_converted_to_a_type_only_import
                    );
                }
            }
        }

        function checkExportSpecifier(node: ExportSpecifier) {
            checkAliasSymbol(node);
            if (getEmitDeclarations(compilerOptions)) {
                collectLinkedAliases(
                    node.propertyName || node.name, /*setVisibility*/
                    true
                );
            }
            if (!node.parent.parent.moduleSpecifier) {
                const exportedName = node.propertyName || node.name;
                // find immediate value referenced by exported name (SymbolFlags.Alias is set so we don't chase down aliases)
                const symbol = resolveName(
                    exportedName,
                    exportedName.escapedText,
                    SymbolFlags.Value | SymbolFlags.Type
                        | SymbolFlags.Namespace | SymbolFlags.Alias,
                    /*nameNotFoundMessage*/ undefined, /*nameArg*/
                    undefined, /*isUse*/
                    true
                );
                if (symbol
                    && (symbol === undefinedSymbol
                        || symbol === globalThisSymbol
                        || isGlobalSourceFile(
                            getDeclarationContainer(
                                symbol.declarations[0]
                            )
                        )))
                {
                    error(
                        exportedName,
                        Diagnostics
                            .Cannot_export_0_Only_local_declarations_can_be_exported_from_a_module,
                        idText(exportedName)
                    );
                } else {
                    markExportAsReferenced(node);
                    const target = symbol
                        && (symbol.flags & SymbolFlags.Alias
                            ? resolveAlias(symbol)
                            : symbol);
                    if (!target || target === unknownSymbol
                        || target.flags & SymbolFlags.Value)
                    {
                        checkExpressionCached(node.propertyName || node.name);
                    }
                }
            }
        }

        function checkExportAssignment(node: ExportAssignment) {
            if (checkGrammarModuleElementContext(
                node,
                Diagnostics.An_export_assignment_can_only_be_used_in_a_module
            )) {
                // If we hit an export assignment in an illegal context, just bail out to avoid cascading errors.
                return;
            }

            const container = node.parent.kind === SyntaxKind.SourceFile
                ? node.parent
                : <ModuleDeclaration> node.parent.parent;
            if (container.kind === SyntaxKind.ModuleDeclaration
                && !isAmbientModule(container))
            {
                if (node.isExportEquals) {
                    error(
                        node,
                        Diagnostics
                            .An_export_assignment_cannot_be_used_in_a_namespace
                    );
                } else {
                    error(
                        node,
                        Diagnostics
                            .A_default_export_can_only_be_used_in_an_ECMAScript_style_module
                    );
                }

                return;
            }
            // Grammar checking
            if (!checkGrammarDecoratorsAndModifiers(node)
                && hasModifiers(node))
            {
                grammarErrorOnFirstToken(
                    node,
                    Diagnostics.An_export_assignment_cannot_have_modifiers
                );
            }
            if (node.expression.kind === SyntaxKind.Identifier) {
                const id = node.expression as Identifier;
                const sym = resolveEntityName(
                    id,
                    SymbolFlags.All, /*ignoreErrors*/
                    true, /*dontResolveAlias*/
                    true,
                    node
                );
                if (sym) {
                    markAliasReferenced(sym, id);
                    // If not a value, we're interpreting the identifier as a type export, along the lines of (`export { Id as default }`)
                    const target = sym.flags & SymbolFlags.Alias
                        ? resolveAlias(sym)
                        : sym;
                    if (target === unknownSymbol
                        || target.flags & SymbolFlags.Value)
                    {
                        // However if it is a value, we need to check it's being used correctly
                        checkExpressionCached(node.expression);
                    }
                }

                if (getEmitDeclarations(compilerOptions)) {
                    collectLinkedAliases(
                        node.expression as Identifier /*setVisibility*/,
                        true
                    );
                }
            } else {
                checkExpressionCached(node.expression);
            }

            checkExternalModuleExports(container);

            if ((node.flags & NodeFlags.Ambient)
                && !isEntityNameExpression(node.expression))
            {
                grammarErrorOnNode(
                    node.expression,
                    Diagnostics
                        .The_expression_of_an_export_assignment_must_be_an_identifier_or_qualified_name_in_an_ambient_context
                );
            }

            if (node.isExportEquals && !(node.flags & NodeFlags.Ambient)) {
                if (moduleKind >= ModuleKind.ES2015) {
                    // export assignment is not supported in es6 modules
                    grammarErrorOnNode(
                        node,
                        Diagnostics
                            .Export_assignment_cannot_be_used_when_targeting_ECMAScript_modules_Consider_using_export_default_or_another_module_format_instead
                    );
                } else if (moduleKind === ModuleKind.System) {
                    // system modules does not support export assignment
                    grammarErrorOnNode(
                        node,
                        Diagnostics
                            .Export_assignment_is_not_supported_when_module_flag_is_system
                    );
                }
            }
        }

        function hasExportedMembers(moduleSymbol: Symbol) {
            return forEachEntry(
                moduleSymbol.exports!,
                (_, id) => id !== 'export='
            );
        }

        function checkExternalModuleExports(
            node: SourceFile | ModuleDeclaration
        ) {
            const moduleSymbol = getSymbolOfNode(node);
            const links = getSymbolLinks(moduleSymbol);
            if (!links.exportsChecked) {
                const exportEqualsSymbol = moduleSymbol.exports!
                    .get('export=' as __String);
                if (exportEqualsSymbol && hasExportedMembers(moduleSymbol)) {
                    const declaration = getDeclarationOfAliasSymbol(exportEqualsSymbol)
                        || exportEqualsSymbol.valueDeclaration;
                    if (!isTopLevelInExternalModuleAugmentation(declaration)
                        && !isInJSFile(declaration))
                    {
                        error(
                            declaration,
                            Diagnostics
                                .An_export_assignment_cannot_be_used_in_a_module_with_other_exported_elements
                        );
                    }
                }
                // Checks for export * conflicts
                const exports = getExportsOfModule(moduleSymbol);
                if (exports) {
                    exports.forEach(({ declarations, flags }, id) => {
                        if (id === '__export') {
                            return;
                        }
                        // ECMA262: 15.2.1.1 It is a Syntax Error if the ExportedNames of ModuleItemList contains any duplicate entries.
                        // (TS Exceptions: namespaces, function overloads, enums, and interfaces)
                        if (flags
                            & (SymbolFlags.Namespace | SymbolFlags.Interface
                                | SymbolFlags.Enum))
                        {
                            return;
                        }
                        const exportedDeclarationsCount = countWhere(
                            declarations,
                            isNotOverloadAndNotAccessor
                        );
                        if (flags & SymbolFlags.TypeAlias
                            && exportedDeclarationsCount <= 2)
                        {
                            // it is legal to merge type alias with other values
                            // so count should be either 1 (just type alias) or 2 (type alias + merged value)
                            return;
                        }
                        if (exportedDeclarationsCount > 1) {
                            for (const declaration of declarations) {
                                if (isNotOverload(declaration)) {
                                    diagnostics
                                        .add(
                                            createDiagnosticForNode(
                                                declaration,
                                                Diagnostics
                                                    .Cannot_redeclare_exported_variable_0,
                                                unescapeLeadingUnderscores(id)
                                            )
                                        );
                                }
                            }
                        }
                    });
                }
                links.exportsChecked = true;
            }
        }

        function checkSourceElement(node: Node | undefined): void {
            if (node) {
                const saveCurrentNode = currentNode;
                currentNode = node;
                instantiationCount = 0;
                checkSourceElementWorker(node);
                currentNode = saveCurrentNode;
            }
        }

        function checkSourceElementWorker(node: Node): void {
            if (isInJSFile(node)) {
                forEach(
                    (node as JSDocContainer).jsDoc,
                    ({ tags }) => forEach(tags, checkSourceElement)
                );
            }

            const kind = node.kind;
            if (cancellationToken) {
                // Only bother checking on a few construct kinds.  We don't want to be excessively
                // hitting the cancellation token on every node we check.
                switch (kind) {
                    case SyntaxKind.ModuleDeclaration:
                    case SyntaxKind.ClassDeclaration:
                    case SyntaxKind.InterfaceDeclaration:
                    case SyntaxKind.FunctionDeclaration:
                        cancellationToken.throwIfCancellationRequested();
                }
            }
            if (kind >= SyntaxKind.FirstStatement
                && kind <= SyntaxKind.LastStatement && node.flowNode
                && !isReachableFlowNode(node.flowNode))
            {
                errorOrSuggestion(
                    compilerOptions.allowUnreachableCode === false,
                    node,
                    Diagnostics.Unreachable_code_detected
                );
            }

            switch (kind) {
                case SyntaxKind.TypeParameter:
                    return checkTypeParameter(<TypeParameterDeclaration> node);
                case SyntaxKind.Parameter:
                    return checkParameter(<ParameterDeclaration> node);
                case SyntaxKind.PropertyDeclaration:
                    return checkPropertyDeclaration(<PropertyDeclaration> node);
                case SyntaxKind.PropertySignature:
                    return checkPropertySignature(<PropertySignature> node);
                case SyntaxKind.FunctionType:
                case SyntaxKind.ConstructorType:
                case SyntaxKind.CallSignature:
                case SyntaxKind.ConstructSignature:
                case SyntaxKind.IndexSignature:
                    return checkSignatureDeclaration(<SignatureDeclaration> node);
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.MethodSignature:
                    return checkMethodDeclaration(
                        <MethodDeclaration | MethodSignature> node
                    );
                case SyntaxKind.Constructor:
                    return checkConstructorDeclaration(<ConstructorDeclaration> node);
                case SyntaxKind.GetAccessor:
                case SyntaxKind.SetAccessor:
                    return checkAccessorDeclaration(<AccessorDeclaration> node);
                case SyntaxKind.TypeReference:
                    return checkTypeReferenceNode(<TypeReferenceNode> node);
                case SyntaxKind.TypePredicate:
                    return checkTypePredicate(<TypePredicateNode> node);
                case SyntaxKind.TypeQuery:
                    return checkTypeQuery(<TypeQueryNode> node);
                case SyntaxKind.TypeLiteral:
                    return checkTypeLiteral(<TypeLiteralNode> node);
                case SyntaxKind.ArrayType:
                    return checkArrayType(<ArrayTypeNode> node);
                case SyntaxKind.TupleType:
                    return checkTupleType(<TupleTypeNode> node);
                case SyntaxKind.UnionType:
                case SyntaxKind.IntersectionType:
                    return checkUnionOrIntersectionType(<UnionOrIntersectionTypeNode> node);
                case SyntaxKind.ParenthesizedType:
                case SyntaxKind.OptionalType:
                case SyntaxKind.RestType:
                    return checkSourceElement(
                        (<ParenthesizedTypeNode | OptionalTypeNode
                            | RestTypeNode> node).type
                    );
                case SyntaxKind.ThisType:
                    return checkThisType(<ThisTypeNode> node);
                case SyntaxKind.TypeOperator:
                    return checkTypeOperator(<TypeOperatorNode> node);
                case SyntaxKind.ConditionalType:
                    return checkConditionalType(<ConditionalTypeNode> node);
                case SyntaxKind.InferType:
                    return checkInferType(<InferTypeNode> node);
                case SyntaxKind.ImportType:
                    return checkImportType(<ImportTypeNode> node);
                case SyntaxKind.JSDocAugmentsTag:
                    return checkJSDocAugmentsTag(node as JSDocAugmentsTag);
                case SyntaxKind.JSDocTypedefTag:
                case SyntaxKind.JSDocCallbackTag:
                case SyntaxKind.JSDocEnumTag:
                    return checkJSDocTypeAliasTag(node as JSDocTypedefTag);
                case SyntaxKind.JSDocTemplateTag:
                    return checkJSDocTemplateTag(node as JSDocTemplateTag);
                case SyntaxKind.JSDocTypeTag:
                    return checkJSDocTypeTag(node as JSDocTypeTag);
                case SyntaxKind.JSDocParameterTag:
                    return checkJSDocParameterTag(node as JSDocParameterTag);
                case SyntaxKind.JSDocFunctionType:
                    checkJSDocFunctionType(node as JSDocFunctionType);
                    // falls through
                case SyntaxKind.JSDocNonNullableType:
                case SyntaxKind.JSDocNullableType:
                case SyntaxKind.JSDocAllType:
                case SyntaxKind.JSDocUnknownType:
                case SyntaxKind.JSDocTypeLiteral:
                    checkJSDocTypeIsInJsFile(node);
                    forEachChild(node, checkSourceElement);
                    return;
                case SyntaxKind.JSDocVariadicType:
                    checkJSDocVariadicType(node as JSDocVariadicType);
                    return;
                case SyntaxKind.JSDocTypeExpression:
                    return checkSourceElement(
                        (node as JSDocTypeExpression).type
                    );
                case SyntaxKind.IndexedAccessType:
                    return checkIndexedAccessType(<IndexedAccessTypeNode> node);
                case SyntaxKind.MappedType:
                    return checkMappedType(<MappedTypeNode> node);
                case SyntaxKind.FunctionDeclaration:
                    return checkFunctionDeclaration(<FunctionDeclaration> node);
                case SyntaxKind.Block:
                case SyntaxKind.ModuleBlock:
                    return checkBlock(<Block> node);
                case SyntaxKind.VariableStatement:
                    return checkVariableStatement(<VariableStatement> node);
                case SyntaxKind.ExpressionStatement:
                    return checkExpressionStatement(<ExpressionStatement> node);
                case SyntaxKind.IfStatement:
                    return checkIfStatement(<IfStatement> node);
                case SyntaxKind.DoStatement:
                    return checkDoStatement(<DoStatement> node);
                case SyntaxKind.WhileStatement:
                    return checkWhileStatement(<WhileStatement> node);
                case SyntaxKind.ForStatement:
                    return checkForStatement(<ForStatement> node);
                case SyntaxKind.ForInStatement:
                    return checkForInStatement(<ForInStatement> node);
                case SyntaxKind.ForOfStatement:
                    return checkForOfStatement(<ForOfStatement> node);
                case SyntaxKind.ContinueStatement:
                case SyntaxKind.BreakStatement:
                    return checkBreakOrContinueStatement(<BreakOrContinueStatement> node);
                case SyntaxKind.ReturnStatement:
                    return checkReturnStatement(<ReturnStatement> node);
                case SyntaxKind.WithStatement:
                    return checkWithStatement(<WithStatement> node);
                case SyntaxKind.SwitchStatement:
                    return checkSwitchStatement(<SwitchStatement> node);
                case SyntaxKind.LabeledStatement:
                    return checkLabeledStatement(<LabeledStatement> node);
                case SyntaxKind.ThrowStatement:
                    return checkThrowStatement(<ThrowStatement> node);
                case SyntaxKind.TryStatement:
                    return checkTryStatement(<TryStatement> node);
                case SyntaxKind.VariableDeclaration:
                    return checkVariableDeclaration(<VariableDeclaration> node);
                case SyntaxKind.BindingElement:
                    return checkBindingElement(<BindingElement> node);
                case SyntaxKind.ClassDeclaration:
                    return checkClassDeclaration(<ClassDeclaration> node);
                case SyntaxKind.InterfaceDeclaration:
                    return checkInterfaceDeclaration(<InterfaceDeclaration> node);
                case SyntaxKind.TypeAliasDeclaration:
                    return checkTypeAliasDeclaration(<TypeAliasDeclaration> node);
                case SyntaxKind.EnumDeclaration:
                    return checkEnumDeclaration(<EnumDeclaration> node);
                case SyntaxKind.ModuleDeclaration:
                    return checkModuleDeclaration(<ModuleDeclaration> node);
                case SyntaxKind.ImportDeclaration:
                    return checkImportDeclaration(<ImportDeclaration> node);
                case SyntaxKind.ImportEqualsDeclaration:
                    return checkImportEqualsDeclaration(<ImportEqualsDeclaration> node);
                case SyntaxKind.ExportDeclaration:
                    return checkExportDeclaration(<ExportDeclaration> node);
                case SyntaxKind.ExportAssignment:
                    return checkExportAssignment(<ExportAssignment> node);
                case SyntaxKind.EmptyStatement:
                case SyntaxKind.DebuggerStatement:
                    checkGrammarStatementInAmbientContext(node);
                    return;
                case SyntaxKind.MissingDeclaration:
                    return checkMissingDeclaration(node);
            }
        }

        function checkJSDocTypeIsInJsFile(node: Node): void {
            if (!isInJSFile(node)) {
                grammarErrorOnNode(
                    node,
                    Diagnostics
                        .JSDoc_types_can_only_be_used_inside_documentation_comments
                );
            }
        }

        function checkJSDocVariadicType(node: JSDocVariadicType): void {
            checkJSDocTypeIsInJsFile(node);
            checkSourceElement(node.type);

            // Only legal location is in the *last* parameter tag or last parameter of a JSDoc function.
            const { parent } = node;
            if (isParameter(parent) && isJSDocFunctionType(parent.parent)) {
                if (last(parent.parent.parameters) !== parent) {
                    error(
                        node,
                        Diagnostics
                            .A_rest_parameter_must_be_last_in_a_parameter_list
                    );
                }
                return;
            }

            if (!isJSDocTypeExpression(parent)) {
                error(
                    node,
                    Diagnostics
                        .JSDoc_may_only_appear_in_the_last_parameter_of_a_signature
                );
            }

            const paramTag = node.parent.parent;
            if (!isJSDocParameterTag(paramTag)) {
                error(
                    node,
                    Diagnostics
                        .JSDoc_may_only_appear_in_the_last_parameter_of_a_signature
                );
                return;
            }

            const param = getParameterSymbolFromJSDoc(paramTag);
            if (!param) {
                // We will error in `checkJSDocParameterTag`.
                return;
            }

            const host = getHostSignatureFromJSDoc(paramTag);
            if (!host || last(host.parameters).symbol !== param) {
                error(
                    node,
                    Diagnostics
                        .A_rest_parameter_must_be_last_in_a_parameter_list
                );
            }
        }

        function getTypeFromJSDocVariadicType(node: JSDocVariadicType): Type {
            const type = getTypeFromTypeNode(node.type);
            const { parent } = node;
            const paramTag = node.parent.parent;
            if (isJSDocTypeExpression(node.parent)
                && isJSDocParameterTag(paramTag))
            {
                // Else we will add a diagnostic, see `checkJSDocVariadicType`.
                const host = getHostSignatureFromJSDoc(paramTag);
                if (host) {
                    /*
                    Only return an array type if the corresponding parameter is marked as a rest parameter, or if there are no parameters.
                    So in the following situation we will not create an array type:
                        /** @param {...number} a * /
                        function f(a) {}
                    Because `a` will just be of type `number | undefined`. A synthetic `...args` will also be added, which *will* get an array type.
                    */
                    const lastParamDeclaration = lastOrUndefined(
                        host.parameters
                    );
                    const symbol = getParameterSymbolFromJSDoc(paramTag);
                    if (!lastParamDeclaration
                        || symbol && lastParamDeclaration.symbol === symbol
                        && isRestParameter(lastParamDeclaration))
                    {
                        return createArrayType(type);
                    }
                }
            }
            if (isParameter(parent) && isJSDocFunctionType(parent.parent)) {
                return createArrayType(type);
            }
            return addOptionality(type);
        }

        // Function and class expression bodies are checked after all statements in the enclosing body. This is
        // to ensure constructs like the following are permitted:
        //     const foo = function () {
        //        const s = foo();
        //        return "hello";
        //     }
        // Here, performing a full type check of the body of the function expression whilst in the process of
        // determining the type of foo would cause foo to be given type any because of the recursive reference.
        // Delaying the type check of the body ensures foo has been assigned a type.
        function checkNodeDeferred(node: Node) {
            const enclosingFile = getSourceFileOfNode(node);
            const links = getNodeLinks(enclosingFile);
            if (!(links.flags & NodeCheckFlags.TypeChecked)) {
                links.deferredNodes = links.deferredNodes || createMap();
                const id = '' + getNodeId(node);
                links.deferredNodes.set(id, node);
            }
        }

        function checkDeferredNodes(context: SourceFile) {
            const links = getNodeLinks(context);
            if (links.deferredNodes) {
                links.deferredNodes.forEach(checkDeferredNode);
            }
        }

        function checkDeferredNode(node: Node) {
            const saveCurrentNode = currentNode;
            currentNode = node;
            instantiationCount = 0;
            switch (node.kind) {
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.ArrowFunction:
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.MethodSignature:
                    checkFunctionExpressionOrObjectLiteralMethodDeferred(<FunctionExpression> node);
                    break;
                case SyntaxKind.GetAccessor:
                case SyntaxKind.SetAccessor:
                    checkAccessorDeclaration(<AccessorDeclaration> node);
                    break;
                case SyntaxKind.ClassExpression:
                    checkClassExpressionDeferred(<ClassExpression> node);
                    break;
                case SyntaxKind.JsxSelfClosingElement:
                    checkJsxSelfClosingElementDeferred(<JsxSelfClosingElement> node);
                    break;
                case SyntaxKind.JsxElement:
                    checkJsxElementDeferred(<JsxElement> node);
                    break;
            }
            currentNode = saveCurrentNode;
        }

        function checkSourceFile(node: SourceFile) {
            performance.mark('beforeCheck');
            checkSourceFileWorker(node);
            performance.mark('afterCheck');
            performance.measure('Check', 'beforeCheck', 'afterCheck');
        }

        function unusedIsError(kind: UnusedKind, isAmbient: boolean): boolean {
            if (isAmbient) {
                return false;
            }
            switch (kind) {
                case UnusedKind.Local:
                    return !!compilerOptions.noUnusedLocals;
                case UnusedKind.Parameter:
                    return !!compilerOptions.noUnusedParameters;
                default:
                    return Debug.assertNever(kind);
            }
        }

        function getPotentiallyUnusedIdentifiers(
            sourceFile: SourceFile
        ): readonly PotentiallyUnusedIdentifier[] {
            return allPotentiallyUnusedIdentifiers.get(sourceFile.path)
                || emptyArray;
        }

        // Fully type check a source file and collect the relevant diagnostics.
        function checkSourceFileWorker(node: SourceFile) {
            const links = getNodeLinks(node);
            if (!(links.flags & NodeCheckFlags.TypeChecked)) {
                if (skipTypeChecking(node, compilerOptions, host)) {
                    return;
                }

                // Grammar checking
                checkGrammarSourceFile(node);

                clear(potentialThisCollisions);
                clear(potentialNewTargetCollisions);
                clear(potentialWeakMapCollisions);

                forEach(node.statements, checkSourceElement);
                checkSourceElement(node.endOfFileToken);

                checkDeferredNodes(node);

                if (isExternalOrCommonJsModule(node)) {
                    registerForUnusedIdentifiersCheck(node);
                }

                if (!node.isDeclarationFile
                    && (compilerOptions.noUnusedLocals
                        || compilerOptions.noUnusedParameters))
                {
                    checkUnusedIdentifiers(
                        getPotentiallyUnusedIdentifiers(node),
                        (containingNode, kind, diag) => {
                            if (!containsParseError(containingNode)
                                && unusedIsError(
                                    kind,
                                    !!(containingNode.flags
                                        & NodeFlags.Ambient)
                                ))
                            {
                                diagnostics.add(diag);
                            }
                        }
                    );
                }

                if (!node.isDeclarationFile && isExternalModule(node)) {
                    checkImportsForTypeOnlyConversion(node);
                }

                if (isExternalOrCommonJsModule(node)) {
                    checkExternalModuleExports(node);
                }

                if (potentialThisCollisions.length) {
                    forEach(
                        potentialThisCollisions,
                        checkIfThisIsCapturedInEnclosingScope
                    );
                    clear(potentialThisCollisions);
                }

                if (potentialNewTargetCollisions.length) {
                    forEach(
                        potentialNewTargetCollisions,
                        checkIfNewTargetIsCapturedInEnclosingScope
                    );
                    clear(potentialNewTargetCollisions);
                }

                if (potentialWeakMapCollisions.length) {
                    forEach(potentialWeakMapCollisions, checkWeakMapCollision);
                    clear(potentialWeakMapCollisions);
                }

                links.flags |= NodeCheckFlags.TypeChecked;
            }
        }

        function getDiagnostics(
            sourceFile: SourceFile,
            ct: CancellationToken
        ): Diagnostic[] {
            try {
                // Record the cancellation token so it can be checked later on during checkSourceElement.
                // Do this in a finally block so we can ensure that it gets reset back to nothing after
                // this call is done.
                cancellationToken = ct;
                return getDiagnosticsWorker(sourceFile);
            } finally {
                cancellationToken = undefined;
            }
        }

        function getDiagnosticsWorker(sourceFile: SourceFile): Diagnostic[] {
            throwIfNonDiagnosticsProducing();
            if (sourceFile) {
                // Some global diagnostics are deferred until they are needed and
                // may not be reported in the first call to getGlobalDiagnostics.
                // We should catch these changes and report them.
                const previousGlobalDiagnostics = diagnostics
                    .getGlobalDiagnostics();
                const previousGlobalDiagnosticsSize = previousGlobalDiagnostics
                    .length;

                checkSourceFile(sourceFile);

                const semanticDiagnostics = diagnostics
                    .getDiagnostics(sourceFile.fileName);
                const currentGlobalDiagnostics = diagnostics
                    .getGlobalDiagnostics();
                if (currentGlobalDiagnostics !== previousGlobalDiagnostics) {
                    // If the arrays are not the same reference, new diagnostics were added.
                    const deferredGlobalDiagnostics = relativeComplement(
                        previousGlobalDiagnostics,
                        currentGlobalDiagnostics,
                        compareDiagnostics
                    );
                    return concatenate(
                        deferredGlobalDiagnostics,
                        semanticDiagnostics
                    );
                } else if (previousGlobalDiagnosticsSize === 0
                    && currentGlobalDiagnostics.length > 0)
                {
                    // If the arrays are the same reference, but the length has changed, a single
                    // new diagnostic was added as DiagnosticCollection attempts to reuse the
                    // same array.
                    return concatenate(
                        currentGlobalDiagnostics,
                        semanticDiagnostics
                    );
                }

                return semanticDiagnostics;
            }

            // Global diagnostics are always added when a file is not provided to
            // getDiagnostics
            forEach(host.getSourceFiles(), checkSourceFile);
            return diagnostics.getDiagnostics();
        }

        function getGlobalDiagnostics(): Diagnostic[] {
            throwIfNonDiagnosticsProducing();
            return diagnostics.getGlobalDiagnostics();
        }

        function throwIfNonDiagnosticsProducing() {
            if (!produceDiagnostics) {
                throw new Error('Trying to get diagnostics from a type checker that does not produce them.');
            }
        }

        // Language service support

        function getSymbolsInScope(
            location: Node,
            meaning: SymbolFlags
        ): Symbol[] {
            if (location.flags & NodeFlags.InWithStatement) {
                // We cannot answer semantic questions within a with block, do not proceed any further
                return [];
            }

            const symbols = createSymbolTable();
            let isStatic = false;

            populateSymbols();

            symbols.delete(InternalSymbolName.This); // Not a symbol, a keyword
            return symbolsToArray(symbols);

            function populateSymbols() {
                while (location) {
                    if (location.locals && !isGlobalSourceFile(location)) {
                        copySymbols(location.locals, meaning);
                    }

                    switch (location.kind) {
                        case SyntaxKind.SourceFile:
                            if (!isExternalOrCommonJsModule(<SourceFile> location)) break;
                            // falls through
                        case SyntaxKind.ModuleDeclaration:
                            copySymbols(
                                getSymbolOfNode(
                                    location as ModuleDeclaration | SourceFile
                                ).exports!,
                                meaning & SymbolFlags.ModuleMember
                            );
                            break;
                        case SyntaxKind.EnumDeclaration:
                            copySymbols(
                                getSymbolOfNode(location as EnumDeclaration)
                                    .exports!,
                                meaning & SymbolFlags.EnumMember
                            );
                            break;
                        case SyntaxKind.ClassExpression:
                            const className = (location as ClassExpression)
                                .name;
                            if (className) {
                                copySymbol(location.symbol, meaning);
                            }

                        // this fall-through is necessary because we would like to handle
                        // type parameter inside class expression similar to how we handle it in classDeclaration and interface Declaration.
                        // falls through
                        case SyntaxKind.ClassDeclaration:
                        case SyntaxKind.InterfaceDeclaration:
                            // If we didn't come from static member of class or interface,
                            // add the type parameters into the symbol table
                            // (type parameters of classDeclaration/classExpression and interface are in member property of the symbol.
                            // Note: that the memberFlags come from previous iteration.
                            if (!isStatic) {
                                copySymbols(
                                    getMembersOfSymbol(
                                        getSymbolOfNode(
                                            location as ClassDeclaration
                                                | InterfaceDeclaration
                                        )
                                    ),
                                    meaning & SymbolFlags.Type
                                );
                            }
                            break;
                        case SyntaxKind.FunctionExpression:
                            const funcName = (location as FunctionExpression)
                                .name;
                            if (funcName) {
                                copySymbol(location.symbol, meaning);
                            }
                            break;
                    }

                    if (introducesArgumentsExoticObject(location)) {
                        copySymbol(argumentsSymbol, meaning);
                    }

                    isStatic = hasModifier(location, ModifierFlags.Static);
                    location = location.parent;
                }

                copySymbols(globals, meaning);
            }

            /**
             * Copy the given symbol into symbol tables if the symbol has the given meaning
             * and it doesn't already existed in the symbol table
             * @param key a key for storing in symbol table; if undefined, use symbol.name
             * @param symbol the symbol to be added into symbol table
             * @param meaning meaning of symbol to filter by before adding to symbol table
             */
            function copySymbol(symbol: Symbol, meaning: SymbolFlags): void {
                if (getCombinedLocalAndExportSymbolFlags(symbol) & meaning) {
                    const id = symbol.escapedName;
                    // We will copy all symbol regardless of its reserved name because
                    // symbolsToArray will check whether the key is a reserved name and
                    // it will not copy symbol with reserved name to the array
                    if (!symbols.has(id)) {
                        symbols.set(id, symbol);
                    }
                }
            }

            function copySymbols(
                source: SymbolTable,
                meaning: SymbolFlags
            ): void {
                if (meaning) {
                    source.forEach(symbol => {
                        copySymbol(symbol, meaning);
                    });
                }
            }
        }

        function isTypeDeclarationName(name: Node): boolean {
            return name.kind === SyntaxKind.Identifier
                && isTypeDeclaration(name.parent)
                && name.parent.name === name;
        }

        function isTypeDeclaration(
            node: Node
        ): node is TypeParameterDeclaration | ClassDeclaration
            | InterfaceDeclaration | TypeAliasDeclaration | EnumDeclaration
            | ImportClause | ImportSpecifier | ExportSpecifier
        {
            switch (node.kind) {
                case SyntaxKind.TypeParameter:
                case SyntaxKind.ClassDeclaration:
                case SyntaxKind.InterfaceDeclaration:
                case SyntaxKind.TypeAliasDeclaration:
                case SyntaxKind.EnumDeclaration:
                    return true;
                case SyntaxKind.ImportClause:
                    return (node as ImportClause).isTypeOnly;
                case SyntaxKind.ImportSpecifier:
                case SyntaxKind.ExportSpecifier:
                    return (node as ImportSpecifier | ExportSpecifier).parent
                        .parent.isTypeOnly;
                default:
                    return false;
            }
        }

        // True if the given identifier is part of a type reference
        function isTypeReferenceIdentifier(node: EntityName): boolean {
            while (node.parent.kind === SyntaxKind.QualifiedName) {
                node = node.parent as QualifiedName;
            }

            return node.parent.kind === SyntaxKind.TypeReference;
        }

        function isHeritageClauseElementIdentifier(node: Node): boolean {
            while (node.parent.kind === SyntaxKind.PropertyAccessExpression) {
                node = node.parent;
            }

            return node.parent.kind === SyntaxKind.ExpressionWithTypeArguments;
        }

        function forEachEnclosingClass<T>(
            node: Node,
            callback: (node: Node) => T | undefined
        ): T | undefined {
            let result: T | undefined;

            while (true) {
                node = getContainingClass(node)!;
                if (!node) break;
                if (result = callback(node)) break;
            }

            return result;
        }

        function isNodeUsedDuringClassInitialization(node: Node) {
            return !!findAncestor(
                node,
                element => {
                    if (isConstructorDeclaration(element)
                        && nodeIsPresent(element.body)
                        || isPropertyDeclaration(element))
                    {
                        return true;
                    } else if (isClassLike(element)
                        || isFunctionLikeDeclaration(element))
                    {
                        return 'quit';
                    }

                    return false;
                }
            );
        }

        function isNodeWithinClass(
            node: Node,
            classDeclaration: ClassLikeDeclaration
        ) {
            return !!forEachEnclosingClass(node, n => n === classDeclaration);
        }

        function getLeftSideOfImportEqualsOrExportAssignment(
            nodeOnRightSide: EntityName
        ): ImportEqualsDeclaration | ExportAssignment | undefined {
            while (nodeOnRightSide.parent.kind === SyntaxKind.QualifiedName) {
                nodeOnRightSide = <QualifiedName> nodeOnRightSide.parent;
            }

            if (nodeOnRightSide.parent.kind
                === SyntaxKind.ImportEqualsDeclaration)
            {
                return (<ImportEqualsDeclaration> nodeOnRightSide.parent)
                    .moduleReference === nodeOnRightSide
                    ? <ImportEqualsDeclaration> nodeOnRightSide.parent
                    : undefined;
            }

            if (nodeOnRightSide.parent.kind === SyntaxKind.ExportAssignment) {
                return (<ExportAssignment> nodeOnRightSide.parent).expression
                    === <Node> nodeOnRightSide
                    ? <ExportAssignment> nodeOnRightSide.parent
                    : undefined;
            }

            return undefined;
        }

        function isInRightSideOfImportOrExportAssignment(node: EntityName) {
            return getLeftSideOfImportEqualsOrExportAssignment(node)
                !== undefined;
        }

        function getSpecialPropertyAssignmentSymbolFromEntityName(
            entityName: EntityName | PropertyAccessExpression
        ) {
            const specialPropertyAssignmentKind = getAssignmentDeclarationKind(
                entityName.parent.parent as BinaryExpression
            );
            switch (specialPropertyAssignmentKind) {
                case AssignmentDeclarationKind.ExportsProperty:
                case AssignmentDeclarationKind.PrototypeProperty:
                    return getSymbolOfNode(entityName.parent);
                case AssignmentDeclarationKind.ThisProperty:
                case AssignmentDeclarationKind.ModuleExports:
                case AssignmentDeclarationKind.Property:
                    return getSymbolOfNode(entityName.parent.parent);
            }
        }

        function isImportTypeQualifierPart(
            node: EntityName
        ): ImportTypeNode | undefined {
            let parent = node.parent;
            while (isQualifiedName(parent)) {
                node = parent;
                parent = parent.parent;
            }
            if (parent && parent.kind === SyntaxKind.ImportType
                && (parent as ImportTypeNode).qualifier === node)
            {
                return parent as ImportTypeNode;
            }
            return undefined;
        }

        function getSymbolOfNameOrPropertyAccessExpression(
            name: EntityName | PrivateIdentifier | PropertyAccessExpression
        ): Symbol | undefined {
            if (isDeclarationName(name)) {
                return getSymbolOfNode(name.parent);
            }

            if (isInJSFile(name)
                && name.parent.kind === SyntaxKind.PropertyAccessExpression
                && name.parent
                === (name.parent.parent as BinaryExpression).left)
            {
                // Check if this is a special property assignment
                if (!isPrivateIdentifier(name)) {
                    const specialPropertyAssignmentSymbol = getSpecialPropertyAssignmentSymbolFromEntityName(name);
                    if (specialPropertyAssignmentSymbol) {
                        return specialPropertyAssignmentSymbol;
                    }
                }
            }

            if (name.parent.kind === SyntaxKind.ExportAssignment
                && isEntityNameExpression(name))
            {
                // Even an entity name expression that doesn't resolve as an entityname may still typecheck as a property access expression
                const success = resolveEntityName(
                    name,
                    /*all meanings*/ SymbolFlags.Value | SymbolFlags.Type
                        | SymbolFlags.Namespace
                        | SymbolFlags.Alias, /*ignoreErrors*/
                    true
                );
                if (success && success !== unknownSymbol) {
                    return success;
                }
            } else if (!isPropertyAccessExpression(name)
                && !isPrivateIdentifier(name)
                && isInRightSideOfImportOrExportAssignment(name))
            {
                // Since we already checked for ExportAssignment, this really could only be an Import
                const importEqualsDeclaration = getAncestor(
                    name,
                    SyntaxKind.ImportEqualsDeclaration
                );
                Debug.assert(importEqualsDeclaration !== undefined);
                return getSymbolOfPartOfRightHandSideOfImportEquals(
                    name, /*dontResolveAlias*/
                    true
                );
            }

            if (!isPropertyAccessExpression(name)
                && !isPrivateIdentifier(name))
            {
                const possibleImportNode = isImportTypeQualifierPart(name);
                if (possibleImportNode) {
                    getTypeFromTypeNode(possibleImportNode);
                    const sym = getNodeLinks(name).resolvedSymbol;
                    return sym === unknownSymbol ? undefined : sym;
                }
            }

            while (isRightSideOfQualifiedNameOrPropertyAccess(name)) {
                name = <QualifiedName
                    | PropertyAccessEntityNameExpression> name.parent;
            }

            if (isHeritageClauseElementIdentifier(name)) {
                let meaning = SymbolFlags.None;
                // In an interface or class, we're definitely interested in a type.
                if (name.parent.kind
                    === SyntaxKind.ExpressionWithTypeArguments)
                {
                    meaning = SymbolFlags.Type;

                    // In a class 'extends' clause we are also looking for a value.
                    if (isExpressionWithTypeArgumentsInClassExtendsClause(
                        name.parent
                    )) {
                        meaning |= SymbolFlags.Value;
                    }
                } else {
                    meaning = SymbolFlags.Namespace;
                }

                meaning |= SymbolFlags.Alias;
                const entityNameSymbol = isEntityNameExpression(name)
                    ? resolveEntityName(name, meaning)
                    : undefined;
                if (entityNameSymbol) {
                    return entityNameSymbol;
                }
            }

            if (name.parent.kind === SyntaxKind.JSDocParameterTag) {
                return getParameterSymbolFromJSDoc(
                    name.parent as JSDocParameterTag
                );
            }

            if (name.parent.kind === SyntaxKind.TypeParameter
                && name.parent.parent.kind === SyntaxKind.JSDocTemplateTag)
            {
                Debug
                    .assert(!isInJSFile(name)); // Otherwise `isDeclarationName` would have been true.
                const typeParameter = getTypeParameterFromJsDoc(
                    name.parent as TypeParameterDeclaration
                        & { parent: JSDocTemplateTag; }
                );
                return typeParameter && typeParameter.symbol;
            }

            if (isExpressionNode(name)) {
                if (nodeIsMissing(name)) {
                    // Missing entity name.
                    return undefined;
                }

                if (name.kind === SyntaxKind.Identifier) {
                    if (isJSXTagName(name) && isJsxIntrinsicIdentifier(name)) {
                        const symbol = getIntrinsicTagSymbol(
                            <JsxOpeningLikeElement> name.parent
                        );
                        return symbol === unknownSymbol ? undefined : symbol;
                    }

                    return resolveEntityName(
                        name,
                        SymbolFlags.Value, /*ignoreErrors*/
                        false, /*dontResolveAlias*/
                        true
                    );
                } else if (name.kind === SyntaxKind.PropertyAccessExpression
                    || name.kind === SyntaxKind.QualifiedName)
                {
                    const links = getNodeLinks(name);
                    if (links.resolvedSymbol) {
                        return links.resolvedSymbol;
                    }

                    if (name.kind === SyntaxKind.PropertyAccessExpression) {
                        checkPropertyAccessExpression(name);
                    } else {
                        checkQualifiedName(name);
                    }
                    return links.resolvedSymbol;
                }
            } else if (isTypeReferenceIdentifier(<EntityName> name)) {
                const meaning = name.parent.kind === SyntaxKind.TypeReference
                    ? SymbolFlags.Type
                    : SymbolFlags.Namespace;
                return resolveEntityName(
                    <EntityName> name,
                    meaning, /*ignoreErrors*/
                    false, /*dontResolveAlias*/
                    true
                );
            }

            if (name.parent.kind === SyntaxKind.TypePredicate) {
                return resolveEntityName(
                    <Identifier> name, /*meaning*/
                    SymbolFlags.FunctionScopedVariable
                );
            }

            // Do we want to return undefined here?
            return undefined;
        }

        function getSymbolAtLocation(node: Node): Symbol | undefined {
            if (node.kind === SyntaxKind.SourceFile) {
                return isExternalModule(<SourceFile> node)
                    ? getMergedSymbol(node.symbol)
                    : undefined;
            }
            const { parent } = node;
            const grandParent = parent.parent;

            if (node.flags & NodeFlags.InWithStatement) {
                // We cannot answer semantic questions within a with block, do not proceed any further
                return undefined;
            }

            if (isDeclarationNameOrImportPropertyName(node)) {
                // This is a declaration, call getSymbolOfNode
                const parentSymbol = getSymbolOfNode(parent)!;
                return isImportOrExportSpecifier(node.parent)
                    && node.parent.propertyName === node
                    ? getImmediateAliasedSymbol(parentSymbol)
                    : parentSymbol;
            } else if (isLiteralComputedPropertyDeclarationName(node)) {
                return getSymbolOfNode(parent.parent);
            }

            if (node.kind === SyntaxKind.Identifier) {
                if (isInRightSideOfImportOrExportAssignment(<Identifier> node)) {
                    return getSymbolOfNameOrPropertyAccessExpression(<Identifier> node);
                } else if (parent.kind === SyntaxKind.BindingElement
                    && grandParent.kind === SyntaxKind.ObjectBindingPattern
                    && node === (<BindingElement> parent).propertyName)
                {
                    const typeOfPattern = getTypeOfNode(grandParent);
                    const propertyDeclaration = getPropertyOfType(
                        typeOfPattern,
                        (<Identifier> node).escapedText
                    );

                    if (propertyDeclaration) {
                        return propertyDeclaration;
                    }
                }
            }

            switch (node.kind) {
                case SyntaxKind.Identifier:
                case SyntaxKind.PrivateIdentifier:
                case SyntaxKind.PropertyAccessExpression:
                case SyntaxKind.QualifiedName:
                    return getSymbolOfNameOrPropertyAccessExpression(
                        <EntityName | PrivateIdentifier
                            | PropertyAccessExpression> node
                    );
                case SyntaxKind.ThisKeyword:
                    const container = getThisContainer(
                        node, /*includeArrowFunctions*/
                        false
                    );
                    if (isFunctionLike(container)) {
                        const sig = getSignatureFromDeclaration(container);
                        if (sig.thisParameter) {
                            return sig.thisParameter;
                        }
                    }
                    if (isInExpressionContext(node)) {
                        return checkExpression(node as Expression).symbol;
                    }
                    // falls through
                case SyntaxKind.ThisType:
                    return getTypeFromThisTypeNode(
                        node as ThisExpression | ThisTypeNode
                    ).symbol;
                case SyntaxKind.SuperKeyword:
                    return checkExpression(node as Expression).symbol;
                case SyntaxKind.ConstructorKeyword:
                    // constructor keyword for an overload, should take us to the definition if it exist
                    const constructorDeclaration = node.parent;
                    if (constructorDeclaration
                        && constructorDeclaration.kind
                        === SyntaxKind.Constructor)
                    {
                        return (<ClassDeclaration> constructorDeclaration
                            .parent).symbol;
                    }
                    return undefined;
                case SyntaxKind.StringLiteral:
                case SyntaxKind.NoSubstitutionTemplateLiteral:
                    // 1). import x = require("./mo/*gotToDefinitionHere*/d")
                    // 2). External module name in an import declaration
                    // 3). Dynamic import call or require in javascript
                    // 4). type A = import("./f/*gotToDefinitionHere*/oo")
                    if ((isExternalModuleImportEqualsDeclaration(
                        node.parent.parent
                    )
                        && getExternalModuleImportEqualsDeclarationExpression(
                            node.parent.parent
                        ) === node)
                        || ((node.parent.kind === SyntaxKind.ImportDeclaration
                            || node.parent.kind
                            === SyntaxKind.ExportDeclaration)
                            && (<ImportDeclaration> node.parent)
                                .moduleSpecifier === node)
                        || ((isInJSFile(node)
                            && isRequireCall(
                                node
                                    .parent, /*checkArgumentIsStringLiteralLike*/
                                false
                            )) || isImportCall(node.parent))
                        || (isLiteralTypeNode(node.parent)
                            && isLiteralImportTypeNode(node.parent.parent)
                            && node.parent.parent.argument === node.parent))
                    {
                        return resolveExternalModuleName(
                            node,
                            <LiteralExpression> node
                        );
                    }
                    if (isCallExpression(parent)
                        && isBindableObjectDefinePropertyCall(parent)
                        && parent.arguments[1] === node)
                    {
                        return getSymbolOfNode(parent);
                    }
                    // falls through
                case SyntaxKind.NumericLiteral:
                    // index access
                    const objectType = isElementAccessExpression(parent)
                        ? parent.argumentExpression === node
                            ? getTypeOfExpression(parent.expression)
                            : undefined
                        : isLiteralTypeNode(parent) && isIndexedAccessTypeNode(
                            grandParent
                        )
                            ? getTypeFromTypeNode(grandParent.objectType)
                            : undefined;
                    return objectType
                        && getPropertyOfType(
                            objectType,
                            escapeLeadingUnderscores(
                                (node as StringLiteral | NumericLiteral).text
                            )
                        );
                case SyntaxKind.DefaultKeyword:
                case SyntaxKind.FunctionKeyword:
                case SyntaxKind.EqualsGreaterThanToken:
                case SyntaxKind.ClassKeyword:
                    return getSymbolOfNode(node.parent);
                case SyntaxKind.ImportType:
                    return isLiteralImportTypeNode(node)
                        ? getSymbolAtLocation(node.argument.literal)
                        : undefined;
                case SyntaxKind.ExportKeyword:
                    return isExportAssignment(node.parent)
                        ? Debug.assertDefined(node.parent.symbol)
                        : undefined;
                default:
                    return undefined;
            }
        }

        function getShorthandAssignmentValueSymbol(
            location: Node
        ): Symbol | undefined {
            if (location
                && location.kind === SyntaxKind.ShorthandPropertyAssignment)
            {
                return resolveEntityName(
                    (<ShorthandPropertyAssignment> location).name,
                    SymbolFlags.Value | SymbolFlags.Alias
                );
            }
            return undefined;
        }

        /** Returns the target of an export specifier without following aliases */
        function getExportSpecifierLocalTargetSymbol(
            node: ExportSpecifier
        ): Symbol | undefined {
            return node.parent.parent.moduleSpecifier
                ? getExternalModuleMember(node.parent.parent, node)
                : resolveEntityName(
                    node.propertyName || node.name,
                    SymbolFlags.Value | SymbolFlags.Type
                        | SymbolFlags.Namespace | SymbolFlags.Alias
                );
        }

        function getTypeOfNode(node: Node): Type {
            if (node.flags & NodeFlags.InWithStatement) {
                // We cannot answer semantic questions within a with block, do not proceed any further
                return errorType;
            }

            const classDecl = tryGetClassImplementingOrExtendingExpressionWithTypeArguments(node);
            const classType = classDecl
                && getDeclaredTypeOfClassOrInterface(
                    getSymbolOfNode(
                        classDecl.class
                    )
                );
            if (isPartOfTypeNode(node)) {
                const typeFromTypeNode = getTypeFromTypeNode(<TypeNode> node);
                return classType
                    ? getTypeWithThisArgument(
                        typeFromTypeNode,
                        classType.thisType
                    )
                    : typeFromTypeNode;
            }

            if (isExpressionNode(node)) {
                return getRegularTypeOfExpression(<Expression> node);
            }

            if (classType && !classDecl!.isImplements) {
                // A SyntaxKind.ExpressionWithTypeArguments is considered a type node, except when it occurs in the
                // extends clause of a class. We handle that case here.
                const baseType = firstOrUndefined(getBaseTypes(classType));
                return baseType
                    ? getTypeWithThisArgument(baseType, classType.thisType)
                    : errorType;
            }

            if (isTypeDeclaration(node)) {
                // In this case, we call getSymbolOfNode instead of getSymbolAtLocation because it is a declaration
                const symbol = getSymbolOfNode(node);
                return getDeclaredTypeOfSymbol(symbol);
            }

            if (isTypeDeclarationName(node)) {
                const symbol = getSymbolAtLocation(node);
                return symbol ? getDeclaredTypeOfSymbol(symbol) : errorType;
            }

            if (isDeclaration(node)) {
                // In this case, we call getSymbolOfNode instead of getSymbolAtLocation because it is a declaration
                const symbol = getSymbolOfNode(node);
                return getTypeOfSymbol(symbol);
            }

            if (isDeclarationNameOrImportPropertyName(node)) {
                const symbol = getSymbolAtLocation(node);
                if (symbol) {
                    return isTypeOnlyImportOrExportName(node)
                        ? getDeclaredTypeOfSymbol(symbol)
                        : getTypeOfSymbol(symbol);
                }
                return errorType;
            }

            if (isBindingPattern(node)) {
                return getTypeForVariableLikeDeclaration(
                    node.parent, /*includeOptionality*/
                    true
                ) || errorType;
            }

            if (isInRightSideOfImportOrExportAssignment(<Identifier> node)) {
                const symbol = getSymbolAtLocation(node);
                if (symbol) {
                    const declaredType = getDeclaredTypeOfSymbol(symbol);
                    return declaredType !== errorType
                        ? declaredType
                        : getTypeOfSymbol(symbol);
                }
            }

            return errorType;
        }

        // Gets the type of object literal or array literal of destructuring assignment.
        // { a } from
        //     for ( { a } of elems) {
        //     }
        // [ a ] from
        //     [a] = [ some array ...]
        function getTypeOfAssignmentPattern(
            expr: AssignmentPattern
        ): Type | undefined {
            Debug
                .assert(
                    expr.kind === SyntaxKind.ObjectLiteralExpression
                        || expr.kind === SyntaxKind.ArrayLiteralExpression
                );
            // If this is from "for of"
            //     for ( { a } of elems) {
            //     }
            if (expr.parent.kind === SyntaxKind.ForOfStatement) {
                const iteratedType = checkRightHandSideOfForOf(
                    (<ForOfStatement> expr.parent).expression,
                    (<ForOfStatement> expr.parent).awaitModifier
                );
                return checkDestructuringAssignment(
                    expr,
                    iteratedType || errorType
                );
            }
            // If this is from "for" initializer
            //     for ({a } = elems[0];.....) { }
            if (expr.parent.kind === SyntaxKind.BinaryExpression) {
                const iteratedType = getTypeOfExpression(
                    (<BinaryExpression> expr.parent).right
                );
                return checkDestructuringAssignment(
                    expr,
                    iteratedType || errorType
                );
            }
            // If this is from nested object binding pattern
            //     for ({ skills: { primary, secondary } } = multiRobot, i = 0; i < 1; i++) {
            if (expr.parent.kind === SyntaxKind.PropertyAssignment) {
                const node = cast(
                    expr.parent.parent,
                    isObjectLiteralExpression
                );
                const typeOfParentObjectLiteral = getTypeOfAssignmentPattern(node)
                    || errorType;
                const propertyIndex = indexOfNode(node.properties,
                    expr.parent);
                return checkObjectLiteralDestructuringPropertyAssignment(
                    node,
                    typeOfParentObjectLiteral,
                    propertyIndex
                );
            }
            // Array literal assignment - array destructuring pattern
            const node = cast(expr.parent, isArrayLiteralExpression);
            //    [{ property1: p1, property2 }] = elems;
            const typeOfArrayLiteral = getTypeOfAssignmentPattern(node)
                || errorType;
            const elementType = checkIteratedTypeOrElementType(
                IterationUse.Destructuring,
                typeOfArrayLiteral,
                undefinedType,
                expr.parent
            ) || errorType;
            return checkArrayLiteralDestructuringElementAssignment(
                node,
                typeOfArrayLiteral,
                node.elements.indexOf(expr),
                elementType
            );
        }

        // Gets the property symbol corresponding to the property in destructuring assignment
        // 'property1' from
        //     for ( { property1: a } of elems) {
        //     }
        // 'property1' at location 'a' from:
        //     [a] = [ property1, property2 ]
        function getPropertySymbolOfDestructuringAssignment(
            location: Identifier
        ) {
            // Get the type of the object or array literal and then look for property of given name in the type
            const typeOfObjectLiteral = getTypeOfAssignmentPattern(
                cast(
                    location.parent.parent,
                    isAssignmentPattern
                )
            );
            return typeOfObjectLiteral
                && getPropertyOfType(typeOfObjectLiteral,
                    location.escapedText);
        }

        function getRegularTypeOfExpression(expr: Expression): Type {
            if (isRightSideOfQualifiedNameOrPropertyAccess(expr)) {
                expr = <Expression> expr.parent;
            }
            return getRegularTypeOfLiteralType(getTypeOfExpression(expr));
        }

        /**
         * Gets either the static or instance type of a class element, based on
         * whether the element is declared as "static".
         */
        function getParentTypeOfClassElement(node: ClassElement) {
            const classSymbol = getSymbolOfNode(node.parent)!;
            return hasModifier(node, ModifierFlags.Static)
                ? getTypeOfSymbol(classSymbol)
                : getDeclaredTypeOfSymbol(classSymbol);
        }

        function getClassElementPropertyKeyType(element: ClassElement) {
            const name = element.name!;
            switch (name.kind) {
                case SyntaxKind.Identifier:
                    return getLiteralType(idText(name));
                case SyntaxKind.NumericLiteral:
                case SyntaxKind.StringLiteral:
                    return getLiteralType(name.text);
                case SyntaxKind.ComputedPropertyName:
                    const nameType = checkComputedPropertyName(name);
                    return isTypeAssignableToKind(
                        nameType,
                        TypeFlags.ESSymbolLike
                    )
                        ? nameType
                        : stringType;
                default:
                    return Debug.fail('Unsupported property name.');
            }
        }

        // Return the list of properties of the given type, augmented with properties from Function
        // if the type has call or construct signatures
        function getAugmentedPropertiesOfType(type: Type): Symbol[] {
            type = getApparentType(type);
            const propsByName = createSymbolTable(getPropertiesOfType(type));
            const functionType = getSignaturesOfType(type, SignatureKind.Call)
                .length
                ? globalCallableFunctionType
                : getSignaturesOfType(type, SignatureKind.Construct).length
                    ? globalNewableFunctionType
                    : undefined;
            if (functionType) {
                forEach(
                    getPropertiesOfType(functionType),
                    p => {
                        if (!propsByName.has(p.escapedName)) {
                            propsByName.set(p.escapedName, p);
                        }
                    }
                );
            }
            return getNamedMembers(propsByName);
        }

        function typeHasCallOrConstructSignatures(type: Type): boolean {
            return ts.typeHasCallOrConstructSignatures(type, checker);
        }

        function getRootSymbols(symbol: Symbol): readonly Symbol[] {
            const roots = getImmediateRootSymbols(symbol);
            return roots ? flatMap(roots, getRootSymbols) : [symbol];
        }
        function getImmediateRootSymbols(
            symbol: Symbol
        ): readonly Symbol[] | undefined {
            if (getCheckFlags(symbol) & CheckFlags.Synthetic) {
                return mapDefined(
                    getSymbolLinks(symbol).containingType!.types,
                    type => getPropertyOfType(type, symbol.escapedName)
                );
            } else if (symbol.flags & SymbolFlags.Transient) {
                const { leftSpread, rightSpread,
                    syntheticOrigin } = symbol as TransientSymbol;
                return leftSpread
                    ? [leftSpread, rightSpread!]
                    : syntheticOrigin
                        ? [syntheticOrigin]
                        : singleElementArray(tryGetAliasTarget(symbol));
            }
            return undefined;
        }
        function tryGetAliasTarget(symbol: Symbol): Symbol | undefined {
            let target: Symbol | undefined;
            let next: Symbol | undefined = symbol;
            while (next = getSymbolLinks(next).target) {
                target = next;
            }
            return target;
        }

        // Emitter support

        function isArgumentsLocalBinding(nodeIn: Identifier): boolean {
            if (!isGeneratedIdentifier(nodeIn)) {
                const node = getParseTreeNode(nodeIn, isIdentifier);
                if (node) {
                    const isPropertyName = node.parent.kind
                        === SyntaxKind.PropertyAccessExpression
                        && (<PropertyAccessExpression> node.parent).name
                        === node;
                    return !isPropertyName
                        && getReferencedValueSymbol(node) === argumentsSymbol;
                }
            }

            return false;
        }

        function moduleExportsSomeValue(
            moduleReferenceExpression: Expression
        ): boolean {
            let moduleSymbol = resolveExternalModuleName(
                moduleReferenceExpression.parent,
                moduleReferenceExpression
            );
            if (!moduleSymbol
                || isShorthandAmbientModuleSymbol(moduleSymbol))
            {
                // If the module is not found or is shorthand, assume that it may export a value.
                return true;
            }

            const hasExportAssignment = hasExportAssignmentSymbol(moduleSymbol);
            // if module has export assignment then 'resolveExternalModuleSymbol' will return resolved symbol for export assignment
            // otherwise it will return moduleSymbol itself
            moduleSymbol = resolveExternalModuleSymbol(moduleSymbol);

            const symbolLinks = getSymbolLinks(moduleSymbol);
            if (symbolLinks.exportsSomeValue === undefined) {
                // for export assignments - check if resolved symbol for RHS is itself a value
                // otherwise - check if at least one export is value
                symbolLinks.exportsSomeValue = hasExportAssignment
                    ? !!(moduleSymbol.flags & SymbolFlags.Value)
                    : forEachEntry(getExportsOfModule(moduleSymbol), isValue);
            }

            return symbolLinks.exportsSomeValue!;

            function isValue(s: Symbol): boolean {
                s = resolveSymbol(s);
                return s && !!(s.flags & SymbolFlags.Value);
            }
        }

        function isNameOfModuleOrEnumDeclaration(node: Identifier) {
            return isModuleOrEnumDeclaration(node.parent)
                && node === node.parent.name;
        }

        // When resolved as an expression identifier, if the given node references an exported entity, return the declaration
        // node of the exported entity's container. Otherwise, return undefined.
        function getReferencedExportContainer(
            nodeIn: Identifier,
            prefixLocals?: boolean
        ): SourceFile | ModuleDeclaration | EnumDeclaration | undefined {
            const node = getParseTreeNode(nodeIn, isIdentifier);
            if (node) {
                // When resolving the export container for the name of a module or enum
                // declaration, we need to start resolution at the declaration's container.
                // Otherwise, we could incorrectly resolve the export container as the
                // declaration if it contains an exported member with the same name.
                let symbol = getReferencedValueSymbol(
                    node, /*startInDeclarationContainer*/
                    isNameOfModuleOrEnumDeclaration(node)
                );
                if (symbol) {
                    if (symbol.flags & SymbolFlags.ExportValue) {
                        // If we reference an exported entity within the same module declaration, then whether
                        // we prefix depends on the kind of entity. SymbolFlags.ExportHasLocal encompasses all the
                        // kinds that we do NOT prefix.
                        const exportSymbol = getMergedSymbol(
                            symbol.exportSymbol!
                        );
                        if (!prefixLocals
                            && exportSymbol.flags & SymbolFlags.ExportHasLocal
                            && !(exportSymbol.flags & SymbolFlags.Variable))
                        {
                            return undefined;
                        }
                        symbol = exportSymbol;
                    }
                    const parentSymbol = getParentOfSymbol(symbol);
                    if (parentSymbol) {
                        if (parentSymbol.flags & SymbolFlags.ValueModule
                            && parentSymbol.valueDeclaration.kind
                            === SyntaxKind.SourceFile)
                        {
                            const symbolFile = <SourceFile> parentSymbol
                                .valueDeclaration;
                            const referenceFile = getSourceFileOfNode(node);
                            // If `node` accesses an export and that export isn't in the same file, then symbol is a namespace export, so return undefined.
                            const symbolIsUmdExport = symbolFile
                                !== referenceFile;
                            return symbolIsUmdExport ? undefined : symbolFile;
                        }
                        return findAncestor(
                            node.parent,
                            (n): n is ModuleDeclaration
                                | EnumDeclaration =>
                            isModuleOrEnumDeclaration(n)
                                && getSymbolOfNode(n) === parentSymbol
                        );
                    }
                }
            }
        }

        // When resolved as an expression identifier, if the given node references an import, return the declaration of
        // that import. Otherwise, return undefined.
        function getReferencedImportDeclaration(
            nodeIn: Identifier
        ): Declaration | undefined {
            const node = getParseTreeNode(nodeIn, isIdentifier);
            if (node) {
                const symbol = getReferencedValueSymbol(node);
                // We should only get the declaration of an alias if there isn't a local value
                // declaration for the symbol
                if (isNonLocalAlias(symbol, /*excludes*/ SymbolFlags.Value)) {
                    return getDeclarationOfAliasSymbol(symbol);
                }
            }

            return undefined;
        }

        function isSymbolOfDestructuredElementOfCatchBinding(symbol: Symbol) {
            return isBindingElement(symbol.valueDeclaration)
                && walkUpBindingElementsAndPatterns(symbol.valueDeclaration)
                    .parent.kind === SyntaxKind.CatchClause;
        }

        function isSymbolOfDeclarationWithCollidingName(
            symbol: Symbol
        ): boolean {
            if (symbol.flags & SymbolFlags.BlockScoped
                && !isSourceFile(symbol.valueDeclaration))
            {
                const links = getSymbolLinks(symbol);
                if (links.isDeclarationWithCollidingName === undefined) {
                    const container = getEnclosingBlockScopeContainer(
                        symbol.valueDeclaration
                    );
                    if (isStatementWithLocals(container)
                        || isSymbolOfDestructuredElementOfCatchBinding(symbol))
                    {
                        const nodeLinks = getNodeLinks(symbol
                            .valueDeclaration);
                        if (resolveName(
                            container.parent,
                            symbol.escapedName,
                            SymbolFlags.Value, /*nameNotFoundMessage*/
                            undefined, /*nameArg*/
                            undefined, /*isUse*/
                            false
                        )) {
                            // redeclaration - always should be renamed
                            links.isDeclarationWithCollidingName = true;
                        } else if (nodeLinks.flags
                            & NodeCheckFlags.CapturedBlockScopedBinding)
                        {
                            // binding is captured in the function
                            // should be renamed if:
                            // - binding is not top level - top level bindings never collide with anything
                            // AND
                            //   - binding is not declared in loop, should be renamed to avoid name reuse across siblings
                            //     let a, b
                            //     { let x = 1; a = () => x; }
                            //     { let x = 100; b = () => x; }
                            //     console.log(a()); // should print '1'
                            //     console.log(b()); // should print '100'
                            //     OR
                            //   - binding is declared inside loop but not in inside initializer of iteration statement or directly inside loop body
                            //     * variables from initializer are passed to rewritten loop body as parameters so they are not captured directly
                            //     * variables that are declared immediately in loop body will become top level variable after loop is rewritten and thus
                            //       they will not collide with anything
                            const isDeclaredInLoop = nodeLinks.flags
                                & NodeCheckFlags.BlockScopedBindingInLoop;
                            const inLoopInitializer = isIterationStatement(
                                container, /*lookInLabeledStatements*/
                                false
                            );
                            const inLoopBodyBlock = container.kind
                                === SyntaxKind.Block
                                && isIterationStatement(
                                    container
                                        .parent, /*lookInLabeledStatements*/
                                    false
                                );

                            links
                                .isDeclarationWithCollidingName = !isBlockScopedContainerTopLevel(container)
                                    && (!isDeclaredInLoop
                                        || (!inLoopInitializer
                                            && !inLoopBodyBlock));
                        } else {
                            links.isDeclarationWithCollidingName = false;
                        }
                    }
                }
                return links.isDeclarationWithCollidingName!;
            }
            return false;
        }

        // When resolved as an expression identifier, if the given node references a nested block scoped entity with
        // a name that either hides an existing name or might hide it when compiled downlevel,
        // return the declaration of that entity. Otherwise, return undefined.
        function getReferencedDeclarationWithCollidingName(
            nodeIn: Identifier
        ): Declaration | undefined {
            if (!isGeneratedIdentifier(nodeIn)) {
                const node = getParseTreeNode(nodeIn, isIdentifier);
                if (node) {
                    const symbol = getReferencedValueSymbol(node);
                    if (symbol
                        && isSymbolOfDeclarationWithCollidingName(symbol))
                    {
                        return symbol.valueDeclaration;
                    }
                }
            }

            return undefined;
        }

        // Return true if the given node is a declaration of a nested block scoped entity with a name that either hides an
        // existing name or might hide a name when compiled downlevel
        function isDeclarationWithCollidingName(nodeIn: Declaration): boolean {
            const node = getParseTreeNode(nodeIn, isDeclaration);
            if (node) {
                const symbol = getSymbolOfNode(node);
                if (symbol) {
                    return isSymbolOfDeclarationWithCollidingName(symbol);
                }
            }

            return false;
        }

        function isValueAliasDeclaration(node: Node): boolean {
            switch (node.kind) {
                case SyntaxKind.ImportEqualsDeclaration:
                case SyntaxKind.ImportClause:
                case SyntaxKind.NamespaceImport:
                case SyntaxKind.ImportSpecifier:
                case SyntaxKind.ExportSpecifier:
                    return isAliasResolvedToValue(
                        getSymbolOfNode(node) || unknownSymbol
                    );
                case SyntaxKind.ExportDeclaration:
                    const exportClause = (<ExportDeclaration> node)
                        .exportClause;
                    return !!exportClause && (
                        isNamespaceExport(exportClause)
                        || some(exportClause.elements, isValueAliasDeclaration)
                    );
                case SyntaxKind.ExportAssignment:
                    return (<ExportAssignment> node).expression
                        && (<ExportAssignment> node).expression.kind
                        === SyntaxKind.Identifier
                        ? isAliasResolvedToValue(
                            getSymbolOfNode(node) || unknownSymbol
                        )
                        : true;
            }
            return false;
        }

        function isTopLevelValueImportEqualsWithEntityName(
            nodeIn: ImportEqualsDeclaration
        ): boolean {
            const node = getParseTreeNode(nodeIn, isImportEqualsDeclaration);
            if (node === undefined
                || node.parent.kind !== SyntaxKind.SourceFile
                || !isInternalModuleImportEqualsDeclaration(node))
            {
                // parent is not source file or it is not reference to internal module
                return false;
            }

            const isValue = isAliasResolvedToValue(getSymbolOfNode(node));
            return isValue && node.moduleReference
                && !nodeIsMissing(node.moduleReference);
        }

        function isAliasResolvedToValue(symbol: Symbol): boolean {
            const target = resolveAlias(symbol);
            if (target === unknownSymbol) {
                return true;
            }
            // const enums and modules that contain only const enums are not considered values from the emit perspective
            // unless 'preserveConstEnums' option is set to true
            return !!(target.flags & SymbolFlags.Value)
                && (compilerOptions.preserveConstEnums
                    || !isConstEnumOrConstEnumOnlyModule(target));
        }

        function isConstEnumOrConstEnumOnlyModule(s: Symbol): boolean {
            return isConstEnumSymbol(s) || !!s.constEnumOnlyModule;
        }

        function isReferencedAliasDeclaration(
            node: Node,
            checkChildren?: boolean
        ): boolean {
            if (isAliasSymbolDeclaration(node)) {
                const symbol = getSymbolOfNode(node);
                if (symbol && getSymbolLinks(symbol).referenced) {
                    return true;
                }
                const target = getSymbolLinks(symbol!)
                    .target; // TODO: GH#18217
                if (target && getModifierFlags(node) & ModifierFlags.Export
                    && target.flags & SymbolFlags.Value
                    && (compilerOptions.preserveConstEnums
                        || !isConstEnumOrConstEnumOnlyModule(target)))
                {
                    // An `export import ... =` of a value symbol is always considered referenced
                    return true;
                }
            }

            if (checkChildren) {
                return !!forEachChild(
                    node,
                    node => isReferencedAliasDeclaration(node, checkChildren)
                );
            }
            return false;
        }

        function isImplementationOfOverload(node: SignatureDeclaration) {
            if (nodeIsPresent((node as FunctionLikeDeclaration).body)) {
                if (isGetAccessor(node)
                    || isSetAccessor(node))
                    return false; // Get or set accessors can never be overload implementations, but can have up to 2 signatures
                const symbol = getSymbolOfNode(node);
                const signaturesOfSymbol = getSignaturesOfSymbol(symbol);
                // If this function body corresponds to function with multiple signature, it is implementation of overload
                // e.g.: function foo(a: string): string;
                //       function foo(a: number): number;
                //       function foo(a: any) { // This is implementation of the overloads
                //           return a;
                //       }
                return signaturesOfSymbol.length > 1
                    // If there is single signature for the symbol, it is overload if that signature isn't coming from the node
                    // e.g.: function foo(a: string): string;
                    //       function foo(a: any) { // This is implementation of the overloads
                    //           return a;
                    //       }
                    || (signaturesOfSymbol.length === 1
                        && signaturesOfSymbol[0].declaration !== node);
            }
            return false;
        }

        function isRequiredInitializedParameter(
            parameter: ParameterDeclaration | JSDocParameterTag
        ): boolean {
            return !!strictNullChecks
                && !isOptionalParameter(parameter)
                && !isJSDocParameterTag(parameter)
                && !!parameter.initializer
                && !hasModifier(
                    parameter,
                    ModifierFlags.ParameterPropertyModifier
                );
        }

        function isOptionalUninitializedParameterProperty(
            parameter: ParameterDeclaration
        ) {
            return strictNullChecks
                && isOptionalParameter(parameter)
                && !parameter.initializer
                && hasModifier(
                    parameter,
                    ModifierFlags.ParameterPropertyModifier
                );
        }

        function isExpandoFunctionDeclaration(node: Declaration): boolean {
            const declaration = getParseTreeNode(node, isFunctionDeclaration);
            if (!declaration) {
                return false;
            }
            const symbol = getSymbolOfNode(declaration);
            if (!symbol || !(symbol.flags & SymbolFlags.Function)) {
                return false;
            }
            return !!forEachEntry(
                getExportsOfSymbol(symbol),
                p => p.flags & SymbolFlags.Value && p.valueDeclaration
                    && isPropertyAccessExpression(p.valueDeclaration)
            );
        }

        function getPropertiesOfContainerFunction(node:
            Declaration): Symbol[]
        {
            const declaration = getParseTreeNode(node, isFunctionDeclaration);
            if (!declaration) {
                return emptyArray;
            }
            const symbol = getSymbolOfNode(declaration);
            return symbol && getPropertiesOfType(getTypeOfSymbol(symbol))
                || emptyArray;
        }

        function getNodeCheckFlags(node: Node): NodeCheckFlags {
            return getNodeLinks(node).flags || 0;
        }

        function getEnumMemberValue(
            node: EnumMember
        ): string | number | undefined {
            computeEnumMemberValues(node.parent);
            return getNodeLinks(node).enumMemberValue;
        }

        function canHaveConstantValue(
            node: Node
        ): node is EnumMember | AccessExpression {
            switch (node.kind) {
                case SyntaxKind.EnumMember:
                case SyntaxKind.PropertyAccessExpression:
                case SyntaxKind.ElementAccessExpression:
                    return true;
            }
            return false;
        }

        function getConstantValue(
            node: EnumMember | AccessExpression
        ): string | number | undefined {
            if (node.kind === SyntaxKind.EnumMember) {
                return getEnumMemberValue(node);
            }

            const symbol = getNodeLinks(node).resolvedSymbol;
            if (symbol && (symbol.flags & SymbolFlags.EnumMember)) {
                // inline property\index accesses only for const enums
                const member = symbol.valueDeclaration as EnumMember;
                if (isEnumConst(member.parent)) {
                    return getEnumMemberValue(member);
                }
            }

            return undefined;
        }

        function isFunctionType(type: Type): boolean {
            return !!(type.flags & TypeFlags.Object)
                && getSignaturesOfType(type, SignatureKind.Call).length > 0;
        }

        function getTypeReferenceSerializationKind(
            typeNameIn: EntityName,
            location?: Node
        ): TypeReferenceSerializationKind {
            // ensure both `typeName` and `location` are parse tree nodes.
            const typeName = getParseTreeNode(typeNameIn, isEntityName);
            if (!typeName) return TypeReferenceSerializationKind.Unknown;

            if (location) {
                location = getParseTreeNode(location);
                if (!location) return TypeReferenceSerializationKind.Unknown;
            }

            // Resolve the symbol as a value to ensure the type can be reached at runtime during emit.
            const valueSymbol = resolveEntityName(
                typeName,
                SymbolFlags.Value, /*ignoreErrors*/
                true, /*dontResolveAlias*/
                false,
                location
            );

            // Resolve the symbol as a type so that we can provide a more useful hint for the type serializer.
            const typeSymbol = resolveEntityName(
                typeName,
                SymbolFlags.Type, /*ignoreErrors*/
                true, /*dontResolveAlias*/
                false,
                location
            );
            if (valueSymbol && valueSymbol === typeSymbol) {
                const globalPromiseSymbol = getGlobalPromiseConstructorSymbol(/*reportErrors*/ false);
                if (globalPromiseSymbol
                    && valueSymbol === globalPromiseSymbol)
                {
                    return TypeReferenceSerializationKind.Promise;
                }

                const constructorType = getTypeOfSymbol(valueSymbol);
                if (constructorType && isConstructorType(constructorType)) {
                    return TypeReferenceSerializationKind
                        .TypeWithConstructSignatureAndValue;
                }
            }

            // We might not be able to resolve type symbol so use unknown type in that case (eg error case)
            if (!typeSymbol) {
                return TypeReferenceSerializationKind.Unknown;
            }
            const type = getDeclaredTypeOfSymbol(typeSymbol);
            if (type === errorType) {
                return TypeReferenceSerializationKind.Unknown;
            } else if (type.flags & TypeFlags.AnyOrUnknown) {
                return TypeReferenceSerializationKind.ObjectType;
            } else if (isTypeAssignableToKind(
                type,
                TypeFlags.Void | TypeFlags.Nullable | TypeFlags.Never
            )) {
                return TypeReferenceSerializationKind.VoidNullableOrNeverType;
            } else if (isTypeAssignableToKind(type, TypeFlags.BooleanLike)) {
                return TypeReferenceSerializationKind.BooleanType;
            } else if (isTypeAssignableToKind(type, TypeFlags.NumberLike)) {
                return TypeReferenceSerializationKind.NumberLikeType;
            } else if (isTypeAssignableToKind(type, TypeFlags.BigIntLike)) {
                return TypeReferenceSerializationKind.BigIntLikeType;
            } else if (isTypeAssignableToKind(type, TypeFlags.StringLike)) {
                return TypeReferenceSerializationKind.StringLikeType;
            } else if (isTupleType(type)) {
                return TypeReferenceSerializationKind.ArrayLikeType;
            } else if (isTypeAssignableToKind(type, TypeFlags.ESSymbolLike)) {
                return TypeReferenceSerializationKind.ESSymbolType;
            } else if (isFunctionType(type)) {
                return TypeReferenceSerializationKind.TypeWithCallSignature;
            } else if (isArrayType(type)) {
                return TypeReferenceSerializationKind.ArrayLikeType;
            } else {
                return TypeReferenceSerializationKind.ObjectType;
            }
        }

        function createTypeOfDeclaration(
            declarationIn: AccessorDeclaration | VariableLikeDeclaration
                | PropertyAccessExpression,
            enclosingDeclaration: Node,
            flags: NodeBuilderFlags,
            tracker: SymbolTracker,
            addUndefined?: boolean
        ) {
            const declaration = getParseTreeNode(
                declarationIn,
                isVariableLikeOrAccessor
            );
            if (!declaration) {
                return createToken(SyntaxKind.AnyKeyword) as KeywordTypeNode;
            }
            // Get type of the symbol if this is the valid symbol otherwise get type at location
            const symbol = getSymbolOfNode(declaration);
            let type = symbol
                && !(symbol.flags
                    & (SymbolFlags.TypeLiteral | SymbolFlags.Signature))
                ? getWidenedLiteralType(getTypeOfSymbol(symbol))
                : errorType;
            if (type.flags & TypeFlags.UniqueESSymbol
                && type.symbol === symbol)
            {
                flags |= NodeBuilderFlags.AllowUniqueESSymbolType;
            }
            if (addUndefined) {
                type = getOptionalType(type);
            }
            return nodeBuilder.typeToTypeNode(
                type,
                enclosingDeclaration,
                flags | NodeBuilderFlags.MultilineObjectLiterals,
                tracker
            );
        }

        function createReturnTypeOfSignatureDeclaration(
            signatureDeclarationIn: SignatureDeclaration,
            enclosingDeclaration: Node,
            flags: NodeBuilderFlags,
            tracker: SymbolTracker
        ) {
            const signatureDeclaration = getParseTreeNode(
                signatureDeclarationIn,
                isFunctionLike
            );
            if (!signatureDeclaration) {
                return createToken(SyntaxKind.AnyKeyword) as KeywordTypeNode;
            }
            const signature = getSignatureFromDeclaration(signatureDeclaration);
            return nodeBuilder
                .typeToTypeNode(
                    getReturnTypeOfSignature(signature),
                    enclosingDeclaration,
                    flags | NodeBuilderFlags.MultilineObjectLiterals,
                    tracker
                );
        }

        function createTypeOfExpression(
            exprIn: Expression,
            enclosingDeclaration: Node,
            flags: NodeBuilderFlags,
            tracker: SymbolTracker
        ) {
            const expr = getParseTreeNode(exprIn, isExpression);
            if (!expr) {
                return createToken(SyntaxKind.AnyKeyword) as KeywordTypeNode;
            }
            const type = getWidenedType(getRegularTypeOfExpression(expr));
            return nodeBuilder.typeToTypeNode(
                type,
                enclosingDeclaration,
                flags | NodeBuilderFlags.MultilineObjectLiterals,
                tracker
            );
        }

        function hasGlobalName(name: string): boolean {
            return globals.has(escapeLeadingUnderscores(name));
        }

        function getReferencedValueSymbol(
            reference: Identifier,
            startInDeclarationContainer?: boolean
        ): Symbol | undefined {
            const resolvedSymbol = getNodeLinks(reference).resolvedSymbol;
            if (resolvedSymbol) {
                return resolvedSymbol;
            }

            let location: Node = reference;
            if (startInDeclarationContainer) {
                // When resolving the name of a declaration as a value, we need to start resolution
                // at a point outside of the declaration.
                const parent = reference.parent;
                if (isDeclaration(parent) && reference === parent.name) {
                    location = getDeclarationContainer(parent);
                }
            }

            return resolveName(
                location,
                reference.escapedText,
                SymbolFlags.Value | SymbolFlags.ExportValue
                    | SymbolFlags.Alias, /*nodeNotFoundMessage*/
                undefined, /*nameArg*/
                undefined, /*isUse*/
                true
            );
        }

        function getReferencedValueDeclaration(
            referenceIn: Identifier
        ): Declaration | undefined {
            if (!isGeneratedIdentifier(referenceIn)) {
                const reference = getParseTreeNode(referenceIn, isIdentifier);
                if (reference) {
                    const symbol = getReferencedValueSymbol(reference);
                    if (symbol) {
                        return getExportSymbolOfValueSymbolIfExported(symbol)
                            .valueDeclaration;
                    }
                }
            }

            return undefined;
        }

        function isLiteralConstDeclaration(
            node: VariableDeclaration | PropertyDeclaration | PropertySignature
                | ParameterDeclaration
        ): boolean {
            if (isDeclarationReadonly(node) || isVariableDeclaration(node)
                && isVarConst(node))
            {
                return isFreshLiteralType(getTypeOfSymbol(getSymbolOfNode(node)));
            }
            return false;
        }

        function literalTypeToNode(
            type: FreshableType,
            enclosing: Node,
            tracker: SymbolTracker
        ): Expression {
            const enumResult = type.flags & TypeFlags.EnumLiteral
                ? nodeBuilder.symbolToExpression(
                    type.symbol,
                    SymbolFlags.Value,
                    enclosing, /*flags*/
                    undefined,
                    tracker
                )
                : type === trueType
                    ? createTrue()
                    : type === falseType && createFalse();
            return enumResult || createLiteral((type as LiteralType).value);
        }

        function createLiteralConstValue(
            node: VariableDeclaration | PropertyDeclaration | PropertySignature
                | ParameterDeclaration,
            tracker: SymbolTracker
        ) {
            const type = getTypeOfSymbol(getSymbolOfNode(node));
            return literalTypeToNode(<FreshableType> type, node, tracker);
        }

        function createResolver(): EmitResolver {
            // this variable and functions that use it are deliberately moved here from the outer scope
            // to avoid scope pollution
            const resolvedTypeReferenceDirectives = host
                .getResolvedTypeReferenceDirectives();
            let fileToDirective: Map<string>;
            if (resolvedTypeReferenceDirectives) {
                // populate reverse mapping: file path -> type reference directive that was resolved to this file
                fileToDirective = createMap<string>();
                resolvedTypeReferenceDirectives
                    .forEach((resolvedDirective, key) => {
                        if (!resolvedDirective
                            || !resolvedDirective.resolvedFileName)
                        {
                            return;
                        }
                        const file = host
                            .getSourceFile(resolvedDirective
                                .resolvedFileName)!;
                        // Add the transitive closure of path references loaded by this file (as long as they are not)
                        // part of an existing type reference.
                        addReferencedFilesToTypeDirective(file, key);
                    });
            }

            return {
                getReferencedExportContainer,
                getReferencedImportDeclaration,
                getReferencedDeclarationWithCollidingName,
                isDeclarationWithCollidingName,
                isValueAliasDeclaration: node => {
                    node = getParseTreeNode(node);
                    // Synthesized nodes are always treated like values.
                    return node ? isValueAliasDeclaration(node) : true;
                },
                hasGlobalName,
                isReferencedAliasDeclaration: (node, checkChildren?) => {
                    node = getParseTreeNode(node);
                    // Synthesized nodes are always treated as referenced.
                    return node
                        ? isReferencedAliasDeclaration(node, checkChildren)
                        : true;
                },
                getNodeCheckFlags: node => {
                    node = getParseTreeNode(node);
                    return node ? getNodeCheckFlags(node) : 0;
                },
                isTopLevelValueImportEqualsWithEntityName,
                isDeclarationVisible,
                isImplementationOfOverload,
                isRequiredInitializedParameter,
                isOptionalUninitializedParameterProperty,
                isExpandoFunctionDeclaration,
                getPropertiesOfContainerFunction,
                createTypeOfDeclaration,
                createReturnTypeOfSignatureDeclaration,
                createTypeOfExpression,
                createLiteralConstValue,
                isSymbolAccessible,
                isEntityNameVisible,
                getConstantValue: nodeIn => {
                    const node = getParseTreeNode(nodeIn,
                        canHaveConstantValue);
                    return node ? getConstantValue(node) : undefined;
                },
                collectLinkedAliases,
                getReferencedValueDeclaration,
                getTypeReferenceSerializationKind,
                isOptionalParameter,
                moduleExportsSomeValue,
                isArgumentsLocalBinding,
                getExternalModuleFileFromDeclaration,
                getTypeReferenceDirectivesForEntityName,
                getTypeReferenceDirectivesForSymbol,
                isLiteralConstDeclaration,
                isLateBound:
                    (nodeIn: Declaration): nodeIn is LateBoundDeclaration => {
                        const node = getParseTreeNode(nodeIn, isDeclaration);
                        const symbol = node && getSymbolOfNode(node);
                        return !!(symbol
                            && getCheckFlags(symbol) & CheckFlags.Late);
                    },
                getJsxFactoryEntity: location => location
                    ? (getJsxNamespace(location), (getSourceFileOfNode(
                        location
                    ).localJsxFactory || _jsxFactoryEntity))
                    : _jsxFactoryEntity,
                getAllAccessorDeclarations(
                    accessor: AccessorDeclaration
                ): AllAccessorDeclarations {
                    accessor = getParseTreeNode(
                        accessor,
                        isGetOrSetAccessorDeclaration
                    )!; // TODO: GH#18217
                    const otherKind = accessor.kind === SyntaxKind.SetAccessor
                        ? SyntaxKind.GetAccessor
                        : SyntaxKind.SetAccessor;
                    const otherAccessor = getDeclarationOfKind<AccessorDeclaration>(
                        getSymbolOfNode(accessor),
                        otherKind
                    );
                    const firstAccessor = otherAccessor
                        && (otherAccessor.pos < accessor.pos)
                        ? otherAccessor
                        : accessor;
                    const secondAccessor = otherAccessor
                        && (otherAccessor.pos < accessor.pos)
                        ? accessor
                        : otherAccessor;
                    const setAccessor = accessor.kind
                        === SyntaxKind.SetAccessor
                        ? accessor
                        : otherAccessor as SetAccessorDeclaration;
                    const getAccessor = accessor.kind
                        === SyntaxKind.GetAccessor
                        ? accessor
                        : otherAccessor as GetAccessorDeclaration;
                    return {
                        firstAccessor,
                        secondAccessor,
                        setAccessor,
                        getAccessor
                    };
                },
                getSymbolOfExternalModuleSpecifier:
                    moduleName => resolveExternalModuleNameWorker(
                        moduleName,
                        moduleName, /*moduleNotFoundError*/
                        undefined
                    ),
                isBindingCapturedByNode: (node, decl) => {
                    const parseNode = getParseTreeNode(node);
                    const parseDecl = getParseTreeNode(decl);
                    return !!parseNode && !!parseDecl
                        && (isVariableDeclaration(parseDecl)
                            || isBindingElement(parseDecl))
                        && isBindingCapturedByNode(parseNode, parseDecl);
                },
                getDeclarationStatementsForSourceFile: (
                    node,
                    flags,
                    tracker,
                    bundled
                ) => {
                    const n = getParseTreeNode(node) as SourceFile;
                    Debug.assert(
                        n && n.kind === SyntaxKind.SourceFile,
                        'Non-sourcefile node passed into getDeclarationsForSourceFile'
                    );
                    const sym = getSymbolOfNode(node);
                    if (!sym) {
                        return !node.locals
                            ? []
                            : nodeBuilder.symbolTableToDeclarationStatements(
                                node.locals,
                                node,
                                flags,
                                tracker,
                                bundled
                            );
                    }
                    return !sym.exports
                        ? []
                        : nodeBuilder.symbolTableToDeclarationStatements(
                            sym.exports,
                            node,
                            flags,
                            tracker,
                            bundled
                        );
                }
            };

            function isInHeritageClause(
                node: PropertyAccessEntityNameExpression
            ) {
                return node.parent
                    && node.parent.kind
                    === SyntaxKind.ExpressionWithTypeArguments
                    && node.parent.parent
                    && node.parent.parent.kind === SyntaxKind.HeritageClause;
            }

            // defined here to avoid outer scope pollution
            function getTypeReferenceDirectivesForEntityName(
                node: EntityNameOrEntityNameExpression
            ): string[] | undefined {
                // program does not have any files with type reference directives - bail out
                if (!fileToDirective) {
                    return undefined;
                }
                // property access can only be used as values, or types when within an expression with type arguments inside a heritage clause
                // qualified names can only be used as types\namespaces
                // identifiers are treated as values only if they appear in type queries
                let meaning = SymbolFlags.Type | SymbolFlags.Namespace;
                if ((node.kind === SyntaxKind.Identifier
                    && isInTypeQuery(node))
                    || (node.kind === SyntaxKind.PropertyAccessExpression
                        && !isInHeritageClause(node)))
                {
                    meaning = SymbolFlags.Value | SymbolFlags.ExportValue;
                }

                const symbol = resolveEntityName(
                    node,
                    meaning, /*ignoreErrors*/
                    true
                );
                return symbol && symbol !== unknownSymbol
                    ? getTypeReferenceDirectivesForSymbol(symbol, meaning)
                    : undefined;
            }

            // defined here to avoid outer scope pollution
            function getTypeReferenceDirectivesForSymbol(
                symbol: Symbol,
                meaning?: SymbolFlags
            ): string[] | undefined {
                // program does not have any files with type reference directives - bail out
                if (!fileToDirective) {
                    return undefined;
                }
                if (!isSymbolFromTypeDeclarationFile(symbol)) {
                    return undefined;
                }
                // check what declarations in the symbol can contribute to the target meaning
                let typeReferenceDirectives: string[] | undefined;
                for (const decl of symbol.declarations) {
                    // check meaning of the local symbol to see if declaration needs to be analyzed further
                    if (decl.symbol && decl.symbol.flags & meaning!) {
                        const file = getSourceFileOfNode(decl);
                        const typeReferenceDirective = fileToDirective
                            .get(file.path);
                        if (typeReferenceDirective) {
                            (typeReferenceDirectives
                                || (typeReferenceDirectives = []))
                                .push(typeReferenceDirective);
                        } else {
                            // found at least one entry that does not originate from type reference directive
                            return undefined;
                        }
                    }
                }
                return typeReferenceDirectives;
            }

            function isSymbolFromTypeDeclarationFile(symbol: Symbol): boolean {
                // bail out if symbol does not have associated declarations (i.e. this is transient symbol created for property in binding pattern)
                if (!symbol.declarations) {
                    return false;
                }

                // walk the parent chain for symbols to make sure that top level parent symbol is in the global scope
                // external modules cannot define or contribute to type declaration files
                let current = symbol;
                while (true) {
                    const parent = getParentOfSymbol(current);
                    if (parent) {
                        current = parent;
                    } else {
                        break;
                    }
                }

                if (current.valueDeclaration
                    && current.valueDeclaration.kind === SyntaxKind.SourceFile
                    && current.flags & SymbolFlags.ValueModule)
                {
                    return false;
                }

                // check that at least one declaration of top level symbol originates from type declaration file
                for (const decl of symbol.declarations) {
                    const file = getSourceFileOfNode(decl);
                    if (fileToDirective.has(file.path)) {
                        return true;
                    }
                }
                return false;
            }

            function addReferencedFilesToTypeDirective(
                file: SourceFile,
                key: string
            ) {
                if (fileToDirective.has(file.path)) return;
                fileToDirective.set(file.path, key);
                for (const { fileName } of file.referencedFiles) {
                    const resolvedFile = resolveTripleslashReference(
                        fileName,
                        file.originalFileName
                    );
                    const referencedFile = host.getSourceFile(resolvedFile);
                    if (referencedFile) {
                        addReferencedFilesToTypeDirective(referencedFile, key);
                    }
                }
            }
        }

        function getExternalModuleFileFromDeclaration(
            declaration: AnyImportOrReExport | ModuleDeclaration
                | ImportTypeNode
        ): SourceFile | undefined {
            const specifier = declaration.kind === SyntaxKind.ModuleDeclaration
                ? tryCast(declaration.name, isStringLiteral)
                : getExternalModuleName(declaration);
            const moduleSymbol = resolveExternalModuleNameWorker(
                specifier!,
                specifier!, /*moduleNotFoundError*/
                undefined
            ); // TODO: GH#18217
            if (!moduleSymbol) {
                return undefined;
            }
            return getDeclarationOfKind(moduleSymbol, SyntaxKind.SourceFile);
        }

        function initializeTypeChecker() {
            // Bind all source files and propagate errors
            for (const file of host.getSourceFiles()) {
                bindSourceFile(file, compilerOptions);
            }

            amalgamatedDuplicates = createMap();

            // Initialize global symbol table
            let augmentations: (readonly (StringLiteral | Identifier)[])[]
                | undefined;
            for (const file of host.getSourceFiles()) {
                if (file.redirectInfo) {
                    continue;
                }
                if (!isExternalOrCommonJsModule(file)) {
                    // It is an error for a non-external-module (i.e. script) to declare its own `globalThis`.
                    // We can't use `builtinGlobals` for this due to synthetic expando-namespace generation in JS files.
                    const fileGlobalThisSymbol = file.locals!
                        .get('globalThis' as __String);
                    if (fileGlobalThisSymbol) {
                        for (const declaration of fileGlobalThisSymbol
                            .declarations)
                        {
                            diagnostics
                                .add(
                                    createDiagnosticForNode(
                                        declaration,
                                        Diagnostics
                                            .Declaration_name_conflicts_with_built_in_global_identifier_0,
                                        'globalThis'
                                    )
                                );
                        }
                    }
                    mergeSymbolTable(globals, file.locals!);
                }
                if (file.jsGlobalAugmentations) {
                    mergeSymbolTable(globals, file.jsGlobalAugmentations);
                }
                if (file.patternAmbientModules
                    && file.patternAmbientModules.length)
                {
                    patternAmbientModules = concatenate(
                        patternAmbientModules,
                        file.patternAmbientModules
                    );
                }
                if (file.moduleAugmentations.length) {
                    (augmentations || (augmentations = []))
                        .push(file.moduleAugmentations);
                }
                if (file.symbol && file.symbol.globalExports) {
                    // Merge in UMD exports with first-in-wins semantics (see #9771)
                    const source = file.symbol.globalExports;
                    source.forEach((sourceSymbol, id) => {
                        if (!globals.has(id)) {
                            globals.set(id, sourceSymbol);
                        }
                    });
                }
            }

            // We do global augmentations separately from module augmentations (and before creating global types) because they
            //  1. Affect global types. We won't have the correct global types until global augmentations are merged. Also,
            //  2. Module augmentation instantiation requires creating the type of a module, which, in turn, can require
            //       checking for an export or property on the module (if export=) which, in turn, can fall back to the
            //       apparent type of the module - either globalObjectType or globalFunctionType - which wouldn't exist if we
            //       did module augmentations prior to finalizing the global types.
            if (augmentations) {
                // merge _global_ module augmentations.
                // this needs to be done after global symbol table is initialized to make sure that all ambient modules are indexed
                for (const list of augmentations) {
                    for (const augmentation of list) {
                        if (!isGlobalScopeAugmentation(
                            augmentation.parent as ModuleDeclaration
                        )) {
                            continue;
                        }
                        mergeModuleAugmentation(augmentation);
                    }
                }
            }

            // Setup global builtins
            addToSymbolTable(
                globals,
                builtinGlobals,
                Diagnostics
                    .Declaration_name_conflicts_with_built_in_global_identifier_0
            );

            getSymbolLinks(undefinedSymbol).type = undefinedWideningType;
            getSymbolLinks(argumentsSymbol)
                .type = getGlobalType(
                    'IArguments' as __String /*arity*/,
                    0, /*reportErrors*/
                    true
                );
            getSymbolLinks(unknownSymbol).type = errorType;
            getSymbolLinks(globalThisSymbol)
                .type = createObjectType(
                    ObjectFlags.Anonymous,
                    globalThisSymbol
                );

            // Initialize special types
            globalArrayType = getGlobalType(
                'Array' as __String /*arity*/,
                1, /*reportErrors*/
                true
            );
            globalObjectType = getGlobalType(
                'Object' as __String /*arity*/,
                0, /*reportErrors*/
                true
            );
            globalFunctionType = getGlobalType(
                'Function' as __String /*arity*/,
                0, /*reportErrors*/
                true
            );
            globalCallableFunctionType = strictBindCallApply
                && getGlobalType(
                    'CallableFunction' as __String /*arity*/,
                    0, /*reportErrors*/
                    true
                ) || globalFunctionType;
            globalNewableFunctionType = strictBindCallApply
                && getGlobalType(
                    'NewableFunction' as __String /*arity*/,
                    0, /*reportErrors*/
                    true
                ) || globalFunctionType;
            globalStringType = getGlobalType(
                'String' as __String /*arity*/,
                0, /*reportErrors*/
                true
            );
            globalNumberType = getGlobalType(
                'Number' as __String /*arity*/,
                0, /*reportErrors*/
                true
            );
            globalBooleanType = getGlobalType(
                'Boolean' as __String /*arity*/,
                0, /*reportErrors*/
                true
            );
            globalRegExpType = getGlobalType(
                'RegExp' as __String /*arity*/,
                0, /*reportErrors*/
                true
            );
            anyArrayType = createArrayType(anyType);

            autoArrayType = createArrayType(autoType);
            if (autoArrayType === emptyObjectType) {
                // autoArrayType is used as a marker, so even if global Array type is not defined, it needs to be a unique type
                autoArrayType = createAnonymousType(
                    undefined,
                    emptySymbols,
                    emptyArray,
                    emptyArray,
                    undefined,
                    undefined
                );
            }

            globalReadonlyArrayType = <GenericType> getGlobalTypeOrUndefined(
                'ReadonlyArray' as __String /*arity*/,
                1
            ) || globalArrayType;
            anyReadonlyArrayType = globalReadonlyArrayType
                ? createTypeFromGenericGlobalType(
                    globalReadonlyArrayType,
                    [anyType]
                )
                : anyArrayType;
            globalThisType = <GenericType> getGlobalTypeOrUndefined(
                'ThisType' as __String /*arity*/,
                1
            );

            if (augmentations) {
                // merge _nonglobal_ module augmentations.
                // this needs to be done after global symbol table is initialized to make sure that all ambient modules are indexed
                for (const list of augmentations) {
                    for (const augmentation of list) {
                        if (isGlobalScopeAugmentation(
                            augmentation.parent as ModuleDeclaration
                        )) {
                            continue;
                        }
                        mergeModuleAugmentation(augmentation);
                    }
                }
            }

            amalgamatedDuplicates
                .forEach(({ firstFile, secondFile, conflictingSymbols }) => {
                    // If not many things conflict, issue individual errors
                    if (conflictingSymbols.size < 8) {
                        conflictingSymbols
                            .forEach((
                                { isBlockScoped, firstFileLocations,
                                    secondFileLocations },
                                symbolName
                            ) => {
                                const message = isBlockScoped
                                    ? Diagnostics
                                        .Cannot_redeclare_block_scoped_variable_0
                                    : Diagnostics.Duplicate_identifier_0;
                                for (const node of firstFileLocations) {
                                    addDuplicateDeclarationError(
                                        node,
                                        message,
                                        symbolName,
                                        secondFileLocations
                                    );
                                }
                                for (const node of secondFileLocations) {
                                    addDuplicateDeclarationError(
                                        node,
                                        message,
                                        symbolName,
                                        firstFileLocations
                                    );
                                }
                            });
                    } else {
                        // Otherwise issue top-level error since the files appear very identical in terms of what they contain
                        const list = arrayFrom(conflictingSymbols.keys())
                            .join(', ');
                        diagnostics.add(
                            addRelatedInfo(
                                createDiagnosticForNode(
                                    firstFile,
                                    Diagnostics
                                        .Definitions_of_the_following_identifiers_conflict_with_those_in_another_file_Colon_0,
                                    list
                                ),
                                createDiagnosticForNode(
                                    secondFile,
                                    Diagnostics.Conflicts_are_in_this_file
                                )
                            )
                        );
                        diagnostics.add(
                            addRelatedInfo(
                                createDiagnosticForNode(
                                    secondFile,
                                    Diagnostics
                                        .Definitions_of_the_following_identifiers_conflict_with_those_in_another_file_Colon_0,
                                    list
                                ),
                                createDiagnosticForNode(
                                    firstFile,
                                    Diagnostics.Conflicts_are_in_this_file
                                )
                            )
                        );
                    }
                });
            amalgamatedDuplicates = undefined;
        }

        function checkExternalEmitHelpers(
            location: Node,
            helpers: ExternalEmitHelpers
        ) {
            if ((requestedExternalEmitHelpers & helpers) !== helpers
                && compilerOptions.importHelpers)
            {
                const sourceFile = getSourceFileOfNode(location);
                if (isEffectiveExternalModule(sourceFile, compilerOptions)
                    && !(location.flags & NodeFlags.Ambient))
                {
                    const helpersModule = resolveHelpersModule(
                        sourceFile,
                        location
                    );
                    if (helpersModule !== unknownSymbol) {
                        const uncheckedHelpers = helpers
                            & ~requestedExternalEmitHelpers;
                        for (let helper = ExternalEmitHelpers.FirstEmitHelper;
                            helper <= ExternalEmitHelpers.LastEmitHelper;
                            helper <<= 1)
                        {
                            if (uncheckedHelpers & helper) {
                                const name = getHelperName(helper);
                                const symbol = getSymbol(
                                    helpersModule.exports!,
                                    escapeLeadingUnderscores(name),
                                    SymbolFlags.Value
                                );
                                if (!symbol) {
                                    error(
                                        location,
                                        Diagnostics
                                            .This_syntax_requires_an_imported_helper_named_1_which_does_not_exist_in_0_Consider_upgrading_your_version_of_0,
                                        externalHelpersModuleNameText,
                                        name
                                    );
                                }
                            }
                        }
                    }
                    requestedExternalEmitHelpers |= helpers;
                }
            }
        }

        function getHelperName(helper: ExternalEmitHelpers) {
            switch (helper) {
                case ExternalEmitHelpers.Extends:
                    return '__extends';
                case ExternalEmitHelpers.Assign:
                    return '__assign';
                case ExternalEmitHelpers.Rest:
                    return '__rest';
                case ExternalEmitHelpers.Decorate:
                    return '__decorate';
                case ExternalEmitHelpers.Metadata:
                    return '__metadata';
                case ExternalEmitHelpers.Param:
                    return '__param';
                case ExternalEmitHelpers.Awaiter:
                    return '__awaiter';
                case ExternalEmitHelpers.Generator:
                    return '__generator';
                case ExternalEmitHelpers.Values:
                    return '__values';
                case ExternalEmitHelpers.Read:
                    return '__read';
                case ExternalEmitHelpers.Spread:
                    return '__spread';
                case ExternalEmitHelpers.SpreadArrays:
                    return '__spreadArrays';
                case ExternalEmitHelpers.Await:
                    return '__await';
                case ExternalEmitHelpers.AsyncGenerator:
                    return '__asyncGenerator';
                case ExternalEmitHelpers.AsyncDelegator:
                    return '__asyncDelegator';
                case ExternalEmitHelpers.AsyncValues:
                    return '__asyncValues';
                case ExternalEmitHelpers.ExportStar:
                    return '__exportStar';
                case ExternalEmitHelpers.MakeTemplateObject:
                    return '__makeTemplateObject';
                case ExternalEmitHelpers.ClassPrivateFieldGet:
                    return '__classPrivateFieldGet';
                case ExternalEmitHelpers.ClassPrivateFieldSet:
                    return '__classPrivateFieldSet';
                default:
                    return Debug.fail('Unrecognized helper');
            }
        }

        function resolveHelpersModule(node: SourceFile, errorNode: Node) {
            if (!externalHelpersModule) {
                externalHelpersModule = resolveExternalModule(
                    node,
                    externalHelpersModuleNameText,
                    Diagnostics
                        .This_syntax_requires_an_imported_helper_but_module_0_cannot_be_found,
                    errorNode
                ) || unknownSymbol;
            }
            return externalHelpersModule;
        }

        // GRAMMAR CHECKING
        function checkGrammarDecoratorsAndModifiers(node: Node): boolean {
            return checkGrammarDecorators(node) || checkGrammarModifiers(node);
        }

        function checkGrammarDecorators(node: Node): boolean {
            if (!node.decorators) {
                return false;
            }
            if (!nodeCanBeDecorated(node, node.parent, node.parent.parent)) {
                if (node.kind === SyntaxKind.MethodDeclaration
                    && !nodeIsPresent((<MethodDeclaration> node).body))
                {
                    return grammarErrorOnFirstToken(
                        node,
                        Diagnostics
                            .A_decorator_can_only_decorate_a_method_implementation_not_an_overload
                    );
                } else {
                    return grammarErrorOnFirstToken(
                        node,
                        Diagnostics.Decorators_are_not_valid_here
                    );
                }
            } else if (node.kind === SyntaxKind.GetAccessor
                || node.kind === SyntaxKind.SetAccessor)
            {
                const accessors = getAllAccessorDeclarations(
                    (<ClassDeclaration> node.parent).members,
                    <AccessorDeclaration> node
                );
                if (accessors.firstAccessor.decorators
                    && node === accessors.secondAccessor)
                {
                    return grammarErrorOnFirstToken(
                        node,
                        Diagnostics
                            .Decorators_cannot_be_applied_to_multiple_get_Slashset_accessors_of_the_same_name
                    );
                }
            }
            return false;
        }

        function checkGrammarModifiers(node: Node): boolean {
            const quickResult = reportObviousModifierErrors(node);
            if (quickResult !== undefined) {
                return quickResult;
            }

            let lastStatic: Node | undefined, lastDeclare: Node | undefined,
                lastAsync: Node | undefined, lastReadonly: Node | undefined;
            let flags = ModifierFlags.None;
            for (const modifier of node.modifiers!) {
                if (modifier.kind !== SyntaxKind.ReadonlyKeyword) {
                    if (node.kind === SyntaxKind.PropertySignature
                        || node.kind === SyntaxKind.MethodSignature)
                    {
                        return grammarErrorOnNode(
                            modifier,
                            Diagnostics
                                ._0_modifier_cannot_appear_on_a_type_member,
                            tokenToString(modifier.kind)
                        );
                    }
                    if (node.kind === SyntaxKind.IndexSignature) {
                        return grammarErrorOnNode(
                            modifier,
                            Diagnostics
                                ._0_modifier_cannot_appear_on_an_index_signature,
                            tokenToString(modifier.kind)
                        );
                    }
                }
                switch (modifier.kind) {
                    case SyntaxKind.ConstKeyword:
                        if (node.kind !== SyntaxKind.EnumDeclaration) {
                            return grammarErrorOnNode(
                                node,
                                Diagnostics
                                    .A_class_member_cannot_have_the_0_keyword,
                                tokenToString(SyntaxKind.ConstKeyword)
                            );
                        }
                        break;
                    case SyntaxKind.PublicKeyword:
                    case SyntaxKind.ProtectedKeyword:
                    case SyntaxKind.PrivateKeyword:
                        const text = visibilityToString(
                            modifierToFlag(
                                modifier.kind
                            )
                        );

                        if (flags & ModifierFlags.AccessibilityModifier) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics.Accessibility_modifier_already_seen
                            );
                        } else if (flags & ModifierFlags.Static) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_must_precede_1_modifier,
                                text,
                                'static'
                            );
                        } else if (flags & ModifierFlags.Readonly) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_must_precede_1_modifier,
                                text,
                                'readonly'
                            );
                        } else if (flags & ModifierFlags.Async) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_must_precede_1_modifier,
                                text,
                                'async'
                            );
                        } else if (node.parent.kind === SyntaxKind.ModuleBlock
                            || node.parent.kind === SyntaxKind.SourceFile)
                        {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_appear_on_a_module_or_namespace_element,
                                text
                            );
                        } else if (flags & ModifierFlags.Abstract) {
                            if (modifier.kind === SyntaxKind.PrivateKeyword) {
                                return grammarErrorOnNode(
                                    modifier,
                                    Diagnostics
                                        ._0_modifier_cannot_be_used_with_1_modifier,
                                    text,
                                    'abstract'
                                );
                            } else {
                                return grammarErrorOnNode(
                                    modifier,
                                    Diagnostics
                                        ._0_modifier_must_precede_1_modifier,
                                    text,
                                    'abstract'
                                );
                            }
                        }
                        flags |= modifierToFlag(modifier.kind);
                        break;
                    case SyntaxKind.StaticKeyword:
                        if (flags & ModifierFlags.Static) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics._0_modifier_already_seen,
                                'static'
                            );
                        } else if (flags & ModifierFlags.Readonly) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_must_precede_1_modifier,
                                'static',
                                'readonly'
                            );
                        } else if (flags & ModifierFlags.Async) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_must_precede_1_modifier,
                                'static',
                                'async'
                            );
                        } else if (node.parent.kind === SyntaxKind.ModuleBlock
                            || node.parent.kind === SyntaxKind.SourceFile)
                        {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_appear_on_a_module_or_namespace_element,
                                'static'
                            );
                        } else if (node.kind === SyntaxKind.Parameter) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_appear_on_a_parameter,
                                'static'
                            );
                        } else if (flags & ModifierFlags.Abstract) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_be_used_with_1_modifier,
                                'static',
                                'abstract'
                            );
                        } else if (isPrivateIdentifierPropertyDeclaration(node)) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_be_used_with_a_private_identifier,
                                'static'
                            );
                        }
                        flags |= ModifierFlags.Static;
                        lastStatic = modifier;
                        break;
                    case SyntaxKind.ReadonlyKeyword:
                        if (flags & ModifierFlags.Readonly) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics._0_modifier_already_seen,
                                'readonly'
                            );
                        } else if (node.kind !== SyntaxKind.PropertyDeclaration
                            && node.kind !== SyntaxKind.PropertySignature
                            && node.kind !== SyntaxKind.IndexSignature
                            && node.kind !== SyntaxKind.Parameter)
                        {
                            // If node.kind === SyntaxKind.Parameter, checkParameter report an error if it's not a parameter property.
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    .readonly_modifier_can_only_appear_on_a_property_declaration_or_index_signature
                            );
                        }
                        flags |= ModifierFlags.Readonly;
                        lastReadonly = modifier;
                        break;
                    case SyntaxKind.ExportKeyword:
                        if (flags & ModifierFlags.Export) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics._0_modifier_already_seen,
                                'export'
                            );
                        } else if (flags & ModifierFlags.Ambient) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_must_precede_1_modifier,
                                'export',
                                'declare'
                            );
                        } else if (flags & ModifierFlags.Abstract) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_must_precede_1_modifier,
                                'export',
                                'abstract'
                            );
                        } else if (flags & ModifierFlags.Async) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_must_precede_1_modifier,
                                'export',
                                'async'
                            );
                        } else if (isClassLike(node.parent)) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_appear_on_a_class_element,
                                'export'
                            );
                        } else if (node.kind === SyntaxKind.Parameter) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_appear_on_a_parameter,
                                'export'
                            );
                        }
                        flags |= ModifierFlags.Export;
                        break;
                    case SyntaxKind.DefaultKeyword:
                        const container = node.parent.kind
                            === SyntaxKind.SourceFile
                            ? node.parent
                            : node.parent.parent;
                        if (container.kind === SyntaxKind.ModuleDeclaration
                            && !isAmbientModule(container))
                        {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    .A_default_export_can_only_be_used_in_an_ECMAScript_style_module
                            );
                        }

                        flags |= ModifierFlags.Default;
                        break;
                    case SyntaxKind.DeclareKeyword:
                        if (flags & ModifierFlags.Ambient) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics._0_modifier_already_seen,
                                'declare'
                            );
                        } else if (flags & ModifierFlags.Async) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_be_used_in_an_ambient_context,
                                'async'
                            );
                        } else if (isClassLike(node.parent)
                            && !isPropertyDeclaration(node))
                        {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_appear_on_a_class_element,
                                'declare'
                            );
                        } else if (node.kind === SyntaxKind.Parameter) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_appear_on_a_parameter,
                                'declare'
                            );
                        } else if ((node.parent.flags & NodeFlags.Ambient)
                            && node.parent.kind === SyntaxKind.ModuleBlock)
                        {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    .A_declare_modifier_cannot_be_used_in_an_already_ambient_context
                            );
                        }
                        flags |= ModifierFlags.Ambient;
                        lastDeclare = modifier;
                        break;
                    case SyntaxKind.AbstractKeyword:
                        if (flags & ModifierFlags.Abstract) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics._0_modifier_already_seen,
                                'abstract'
                            );
                        }
                        if (node.kind !== SyntaxKind.ClassDeclaration) {
                            if (node.kind !== SyntaxKind.MethodDeclaration
                                && node.kind !== SyntaxKind.PropertyDeclaration
                                && node.kind !== SyntaxKind.GetAccessor
                                && node.kind !== SyntaxKind.SetAccessor)
                            {
                                return grammarErrorOnNode(
                                    modifier,
                                    Diagnostics
                                        .abstract_modifier_can_only_appear_on_a_class_method_or_property_declaration
                                );
                            }
                            if (!(node.parent.kind
                                === SyntaxKind.ClassDeclaration
                                && hasModifier(
                                    node.parent,
                                    ModifierFlags.Abstract
                                )))
                            {
                                return grammarErrorOnNode(
                                    modifier,
                                    Diagnostics
                                        .Abstract_methods_can_only_appear_within_an_abstract_class
                                );
                            }
                            if (flags & ModifierFlags.Static) {
                                return grammarErrorOnNode(
                                    modifier,
                                    Diagnostics
                                        ._0_modifier_cannot_be_used_with_1_modifier,
                                    'static',
                                    'abstract'
                                );
                            }
                            if (flags & ModifierFlags.Private) {
                                return grammarErrorOnNode(
                                    modifier,
                                    Diagnostics
                                        ._0_modifier_cannot_be_used_with_1_modifier,
                                    'private',
                                    'abstract'
                                );
                            }
                        }
                        if (isNamedDeclaration(node)
                            && node.name.kind === SyntaxKind.PrivateIdentifier)
                        {
                            return grammarErrorOnNode(
                                node,
                                Diagnostics
                                    ._0_modifier_cannot_be_used_with_a_private_identifier,
                                'abstract'
                            );
                        }

                        flags |= ModifierFlags.Abstract;
                        break;
                    case SyntaxKind.AsyncKeyword:
                        if (flags & ModifierFlags.Async) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics._0_modifier_already_seen,
                                'async'
                            );
                        } else if (flags & ModifierFlags.Ambient
                            || node.parent.flags & NodeFlags.Ambient)
                        {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_be_used_in_an_ambient_context,
                                'async'
                            );
                        } else if (node.kind === SyntaxKind.Parameter) {
                            return grammarErrorOnNode(
                                modifier,
                                Diagnostics
                                    ._0_modifier_cannot_appear_on_a_parameter,
                                'async'
                            );
                        }
                        flags |= ModifierFlags.Async;
                        lastAsync = modifier;
                        break;
                }
            }

            if (node.kind === SyntaxKind.Constructor) {
                if (flags & ModifierFlags.Static) {
                    return grammarErrorOnNode(
                        lastStatic!,
                        Diagnostics
                            ._0_modifier_cannot_appear_on_a_constructor_declaration,
                        'static'
                    );
                }
                if (flags & ModifierFlags.Abstract) {
                    return grammarErrorOnNode(
                        lastStatic!,
                        Diagnostics
                            ._0_modifier_cannot_appear_on_a_constructor_declaration,
                        'abstract'
                    ); // TODO: GH#18217
                } else if (flags & ModifierFlags.Async) {
                    return grammarErrorOnNode(
                        lastAsync!,
                        Diagnostics
                            ._0_modifier_cannot_appear_on_a_constructor_declaration,
                        'async'
                    );
                } else if (flags & ModifierFlags.Readonly) {
                    return grammarErrorOnNode(
                        lastReadonly!,
                        Diagnostics
                            ._0_modifier_cannot_appear_on_a_constructor_declaration,
                        'readonly'
                    );
                }
                return false;
            } else if ((node.kind === SyntaxKind.ImportDeclaration
                || node.kind === SyntaxKind.ImportEqualsDeclaration)
                && flags & ModifierFlags.Ambient)
            {
                return grammarErrorOnNode(
                    lastDeclare!,
                    Diagnostics
                        .A_0_modifier_cannot_be_used_with_an_import_declaration,
                    'declare'
                );
            } else if (node.kind === SyntaxKind.Parameter
                && (flags & ModifierFlags.ParameterPropertyModifier)
                && isBindingPattern((<ParameterDeclaration> node).name))
            {
                return grammarErrorOnNode(
                    node,
                    Diagnostics
                        .A_parameter_property_may_not_be_declared_using_a_binding_pattern
                );
            } else if (node.kind === SyntaxKind.Parameter
                && (flags & ModifierFlags.ParameterPropertyModifier)
                && (<ParameterDeclaration> node).dotDotDotToken)
            {
                return grammarErrorOnNode(
                    node,
                    Diagnostics
                        .A_parameter_property_cannot_be_declared_using_a_rest_parameter
                );
            } else if (isNamedDeclaration(node)
                && (flags & ModifierFlags.AccessibilityModifier)
                && node.name.kind === SyntaxKind.PrivateIdentifier)
            {
                return grammarErrorOnNode(
                    node,
                    Diagnostics
                        .An_accessibility_modifier_cannot_be_used_with_a_private_identifier
                );
            }
            if (flags & ModifierFlags.Async) {
                return checkGrammarAsyncModifier(node, lastAsync!);
            }
            return false;
        }

        /**
         * true | false: Early return this value from checkGrammarModifiers.
         * undefined: Need to do full checking on the modifiers.
         */
        function reportObviousModifierErrors(node: Node): boolean | undefined {
            return !node.modifiers
                ? false
                : shouldReportBadModifier(node)
                    ? grammarErrorOnFirstToken(
                        node,
                        Diagnostics.Modifiers_cannot_appear_here
                    )
                    : undefined;
        }
        function shouldReportBadModifier(node: Node): boolean {
            switch (node.kind) {
                case SyntaxKind.GetAccessor:
                case SyntaxKind.SetAccessor:
                case SyntaxKind.Constructor:
                case SyntaxKind.PropertyDeclaration:
                case SyntaxKind.PropertySignature:
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.MethodSignature:
                case SyntaxKind.IndexSignature:
                case SyntaxKind.ModuleDeclaration:
                case SyntaxKind.ImportDeclaration:
                case SyntaxKind.ImportEqualsDeclaration:
                case SyntaxKind.ExportDeclaration:
                case SyntaxKind.ExportAssignment:
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.ArrowFunction:
                case SyntaxKind.Parameter:
                    return false;
                default:
                    if (node.parent.kind === SyntaxKind.ModuleBlock
                        || node.parent.kind === SyntaxKind.SourceFile)
                    {
                        return false;
                    }
                    switch (node.kind) {
                        case SyntaxKind.FunctionDeclaration:
                            return nodeHasAnyModifiersExcept(
                                node,
                                SyntaxKind.AsyncKeyword
                            );
                        case SyntaxKind.ClassDeclaration:
                            return nodeHasAnyModifiersExcept(
                                node,
                                SyntaxKind.AbstractKeyword
                            );
                        case SyntaxKind.InterfaceDeclaration:
                        case SyntaxKind.VariableStatement:
                        case SyntaxKind.TypeAliasDeclaration:
                            return true;
                        case SyntaxKind.EnumDeclaration:
                            return nodeHasAnyModifiersExcept(
                                node,
                                SyntaxKind.ConstKeyword
                            );
                        default:
                            Debug.fail();
                            return false;
                    }
            }
        }
        function nodeHasAnyModifiersExcept(
            node: Node,
            allowedModifier: SyntaxKind
        ): boolean {
            return node.modifiers!.length > 1
                || node.modifiers![0].kind !== allowedModifier;
        }

        function checkGrammarAsyncModifier(
            node: Node,
            asyncModifier: Node
        ): boolean {
            switch (node.kind) {
                case SyntaxKind.MethodDeclaration:
                case SyntaxKind.FunctionDeclaration:
                case SyntaxKind.FunctionExpression:
                case SyntaxKind.ArrowFunction:
                    return false;
            }

            return grammarErrorOnNode(
                asyncModifier,
                Diagnostics._0_modifier_cannot_be_used_here,
                'async'
            );
        }

        function checkGrammarForDisallowedTrailingComma(
            list: NodeArray<Node> | undefined,
            diag = Diagnostics.Trailing_comma_not_allowed
        ): boolean {
            if (list && list.hasTrailingComma) {
                return grammarErrorAtPos(
                    list[0],
                    list.end - ','.length,
                    ','.length,
                    diag
                );
            }
            return false;
        }

        function checkGrammarTypeParameterList(
            typeParameters: NodeArray<TypeParameterDeclaration> | undefined,
            file: SourceFile
        ): boolean {
            if (typeParameters && typeParameters.length === 0) {
                const start = typeParameters.pos - '<'.length;
                const end = skipTrivia(file.text, typeParameters.end)
                    + '>'.length;
                return grammarErrorAtPos(
                    file,
                    start,
                    end - start,
                    Diagnostics.Type_parameter_list_cannot_be_empty
                );
            }
            return false;
        }

        function checkGrammarParameterList(
            parameters: NodeArray<ParameterDeclaration>
        ) {
            let seenOptionalParameter = false;
            const parameterCount = parameters.length;

            for (let i = 0; i < parameterCount; i++) {
                const parameter = parameters[i];
                if (parameter.dotDotDotToken) {
                    if (i !== (parameterCount - 1)) {
                        return grammarErrorOnNode(
                            parameter.dotDotDotToken,
                            Diagnostics
                                .A_rest_parameter_must_be_last_in_a_parameter_list
                        );
                    }
                    if (!(parameter.flags
                        & NodeFlags
                            .Ambient))
                    { // Allow `...foo,` in ambient declarations; see GH#23070
                        checkGrammarForDisallowedTrailingComma(
                            parameters,
                            Diagnostics
                                .A_rest_parameter_or_binding_pattern_may_not_have_a_trailing_comma
                        );
                    }

                    if (parameter.questionToken) {
                        return grammarErrorOnNode(
                            parameter.questionToken,
                            Diagnostics.A_rest_parameter_cannot_be_optional
                        );
                    }

                    if (parameter.initializer) {
                        return grammarErrorOnNode(
                            parameter.name,
                            Diagnostics
                                .A_rest_parameter_cannot_have_an_initializer
                        );
                    }
                } else if (parameter.questionToken) {
                    seenOptionalParameter = true;

                    if (parameter.initializer) {
                        return grammarErrorOnNode(
                            parameter.name,
                            Diagnostics
                                .Parameter_cannot_have_question_mark_and_initializer
                        );
                    }
                } else if (seenOptionalParameter && !parameter.initializer) {
                    return grammarErrorOnNode(
                        parameter.name,
                        Diagnostics
                            .A_required_parameter_cannot_follow_an_optional_parameter
                    );
                }
            }
        }

        function getNonSimpleParameters(
            parameters: readonly ParameterDeclaration[]
        ): readonly ParameterDeclaration[] {
            return filter(
                parameters,
                parameter => !!parameter.initializer
                    || isBindingPattern(parameter.name)
                    || isRestParameter(parameter)
            );
        }

        function checkGrammarForUseStrictSimpleParameterList(
            node: FunctionLikeDeclaration
        ): boolean {
            if (languageVersion >= ScriptTarget.ES2016) {
                const useStrictDirective = node.body && isBlock(node.body)
                    && findUseStrictPrologue(node.body.statements);
                if (useStrictDirective) {
                    const nonSimpleParameters = getNonSimpleParameters(
                        node.parameters
                    );
                    if (length(nonSimpleParameters)) {
                        forEach(
                            nonSimpleParameters,
                            parameter => {
                                addRelatedInfo(
                                    error(
                                        parameter,
                                        Diagnostics
                                            .This_parameter_is_not_allowed_with_use_strict_directive
                                    ),
                                    createDiagnosticForNode(
                                        useStrictDirective,
                                        Diagnostics
                                            .use_strict_directive_used_here
                                    )
                                );
                            }
                        );

                        const diagnostics = nonSimpleParameters
                            .map((parameter, index) => (
                                index === 0
                                    ? createDiagnosticForNode(
                                        parameter,
                                        Diagnostics
                                            .Non_simple_parameter_declared_here
                                    )
                                    : createDiagnosticForNode(
                                        parameter,
                                        Diagnostics.and_here
                                    )
                            )) as [DiagnosticWithLocation,
                                ...DiagnosticWithLocation[]];
                        addRelatedInfo(
                            error(
                                useStrictDirective,
                                Diagnostics
                                    .use_strict_directive_cannot_be_used_with_non_simple_parameter_list
                            ),
                            ...diagnostics
                        );
                        return true;
                    }
                }
            }
            return false;
        }

        function checkGrammarFunctionLikeDeclaration(
            node: FunctionLikeDeclaration | MethodSignature
        ): boolean {
            // Prevent cascading error by short-circuit
            const file = getSourceFileOfNode(node);
            return checkGrammarDecoratorsAndModifiers(node)
                || checkGrammarTypeParameterList(node.typeParameters, file)
                || checkGrammarParameterList(node.parameters)
                || checkGrammarArrowFunction(node, file)
                || (isFunctionLikeDeclaration(node)
                    && checkGrammarForUseStrictSimpleParameterList(node));
        }

        function checkGrammarClassLikeDeclaration(
            node: ClassLikeDeclaration
        ): boolean {
            const file = getSourceFileOfNode(node);
            return checkGrammarClassDeclarationHeritageClauses(node)
                || checkGrammarTypeParameterList(node.typeParameters, file);
        }

        function checkGrammarArrowFunction(
            node: Node,
            file: SourceFile
        ): boolean {
            if (!isArrowFunction(node)) {
                return false;
            }

            const { equalsGreaterThanToken } = node;
            const startLine = getLineAndCharacterOfPosition(
                file,
                equalsGreaterThanToken.pos
            ).line;
            const endLine = getLineAndCharacterOfPosition(
                file,
                equalsGreaterThanToken.end
            ).line;
            return startLine !== endLine
                && grammarErrorOnNode(
                    equalsGreaterThanToken,
                    Diagnostics.Line_terminator_not_permitted_before_arrow
                );
        }

        function checkGrammarIndexSignatureParameters(
            node: SignatureDeclaration
        ): boolean {
            const parameter = node.parameters[0];
            if (node.parameters.length !== 1) {
                if (parameter) {
                    return grammarErrorOnNode(
                        parameter.name,
                        Diagnostics
                            .An_index_signature_must_have_exactly_one_parameter
                    );
                } else {
                    return grammarErrorOnNode(
                        node,
                        Diagnostics
                            .An_index_signature_must_have_exactly_one_parameter
                    );
                }
            }
            if (parameter.dotDotDotToken) {
                return grammarErrorOnNode(
                    parameter.dotDotDotToken,
                    Diagnostics.An_index_signature_cannot_have_a_rest_parameter
                );
            }
            if (hasModifiers(parameter)) {
                return grammarErrorOnNode(
                    parameter.name,
                    Diagnostics
                        .An_index_signature_parameter_cannot_have_an_accessibility_modifier
                );
            }
            if (parameter.questionToken) {
                return grammarErrorOnNode(
                    parameter.questionToken,
                    Diagnostics
                        .An_index_signature_parameter_cannot_have_a_question_mark
                );
            }
            if (parameter.initializer) {
                return grammarErrorOnNode(
                    parameter.name,
                    Diagnostics
                        .An_index_signature_parameter_cannot_have_an_initializer
                );
            }
            if (!parameter.type) {
                return grammarErrorOnNode(
                    parameter.name,
                    Diagnostics
                        .An_index_signature_parameter_must_have_a_type_annotation
                );
            }
            if (parameter.type.kind !== SyntaxKind.StringKeyword
                && parameter.type.kind !== SyntaxKind.NumberKeyword)
            {
                const type = getTypeFromTypeNode(parameter.type);

                if (type.flags & TypeFlags.String
                    || type.flags & TypeFlags.Number)
                {
                    return grammarErrorOnNode(
                        parameter.name,
                        Diagnostics
                            .An_index_signature_parameter_type_cannot_be_a_type_alias_Consider_writing_0_Colon_1_Colon_2_instead,
                        getTextOfNode(parameter.name),
                        typeToString(type),
                        typeToString(
                            node.type
                                ? getTypeFromTypeNode(node.type)
                                : anyType
                        )
                    );
                }

                if (type.flags & TypeFlags.Union
                    && allTypesAssignableToKind(
                        type,
                        TypeFlags.StringOrNumberLiteral, /*strict*/
                        true
                    ))
                {
                    return grammarErrorOnNode(
                        parameter.name,
                        Diagnostics
                            .An_index_signature_parameter_type_cannot_be_a_union_type_Consider_using_a_mapped_object_type_instead
                    );
                }

                return grammarErrorOnNode(
                    parameter.name,
                    Diagnostics
                        .An_index_signature_parameter_type_must_be_either_string_or_number
                );
            }
            if (!node.type) {
                return grammarErrorOnNode(
                    node,
                    Diagnostics.An_index_signature_must_have_a_type_annotation
                );
            }
            return false;
        }

        function checkGrammarIndexSignature(node: SignatureDeclaration) {
            // Prevent cascading error by short-circuit
            return checkGrammarDecoratorsAndModifiers(node)
                || checkGrammarIndexSignatureParameters(node);
        }

        function checkGrammarForAtLeastOneTypeArgument(
            node: Node,
            typeArguments: NodeArray<TypeNode> | undefined
        ): boolean {
            if (typeArguments && typeArguments.length === 0) {
                const sourceFile = getSourceFileOfNode(node);
                const start = typeArguments.pos - '<'.length;
                const end = skipTrivia(sourceFile.text, typeArguments.end)
                    + '>'.length;
                return grammarErrorAtPos(
                    sourceFile,
                    start,
                    end - start,
                    Diagnostics.Type_argument_list_cannot_be_empty
                );
            }
            return false;
        }

        function checkGrammarTypeArguments(
            node: Node,
            typeArguments: NodeArray<TypeNode> | undefined
        ): boolean {
            return checkGrammarForDisallowedTrailingComma(typeArguments)
                || checkGrammarForAtLeastOneTypeArgument(node, typeArguments);
        }

        function checkGrammarTaggedTemplateChain(
            node: TaggedTemplateExpression
        ): boolean {
            if (node.questionDotToken
                || node.flags & NodeFlags.OptionalChain)
            {
                return grammarErrorOnNode(
                    node.template,
                    Diagnostics
                        .Tagged_template_expressions_are_not_permitted_in_an_optional_chain
                );
            }
            return false;
        }

        function checkGrammarForOmittedArgument(
            args: NodeArray<Expression> | undefined
        ): boolean {
            if (args) {
                for (const arg of args) {
                    if (arg.kind === SyntaxKind.OmittedExpression) {
                        return grammarErrorAtPos(
                            arg,
                            arg.pos,
                            0,
                            Diagnostics.Argument_expression_expected
                        );
                    }
                }
            }
            return false;
        }

        function checkGrammarArguments(
            args: NodeArray<Expression> | undefined
        ): boolean {
            return checkGrammarForOmittedArgument(args);
        }

        function checkGrammarHeritageClause(node: HeritageClause): boolean {
            const types = node.types;
            if (checkGrammarForDisallowedTrailingComma(types)) {
                return true;
            }
            if (types && types.length === 0) {
                const listType = tokenToString(node.token);
                return grammarErrorAtPos(
                    node,
                    types.pos,
                    0,
                    Diagnostics._0_list_cannot_be_empty,
                    listType
                );
            }
            return some(types, checkGrammarExpressionWithTypeArguments);
        }

        function checkGrammarExpressionWithTypeArguments(
            node: ExpressionWithTypeArguments
        ) {
            return checkGrammarTypeArguments(node, node.typeArguments);
        }

        function checkGrammarClassDeclarationHeritageClauses(
            node: ClassLikeDeclaration
        ) {
            let seenExtendsClause = false;
            let seenImplementsClause = false;

            if (!checkGrammarDecoratorsAndModifiers(node)
                && node.heritageClauses)
            {
                for (const heritageClause of node.heritageClauses) {
                    if (heritageClause.token === SyntaxKind.ExtendsKeyword) {
                        if (seenExtendsClause) {
                            return grammarErrorOnFirstToken(
                                heritageClause,
                                Diagnostics.extends_clause_already_seen
                            );
                        }

                        if (seenImplementsClause) {
                            return grammarErrorOnFirstToken(
                                heritageClause,
                                Diagnostics
                                    .extends_clause_must_precede_implements_clause
                            );
                        }

                        if (heritageClause.types.length > 1) {
                            return grammarErrorOnFirstToken(
                                heritageClause.types[1],
                                Diagnostics
                                    .Classes_can_only_extend_a_single_class
                            );
                        }

                        seenExtendsClause = true;
                    } else {
                        Debug
                            .assert(
                                heritageClause.token
                                    === SyntaxKind.ImplementsKeyword
                            );
                        if (seenImplementsClause) {
                            return grammarErrorOnFirstToken(
                                heritageClause,
                                Diagnostics.implements_clause_already_seen
                            );
                        }

                        seenImplementsClause = true;
                    }

                    // Grammar checking heritageClause inside class declaration
                    checkGrammarHeritageClause(heritageClause);
                }
            }
        }

        function checkGrammarInterfaceDeclaration(node: InterfaceDeclaration) {
            let seenExtendsClause = false;

            if (node.heritageClauses) {
                for (const heritageClause of node.heritageClauses) {
                    if (heritageClause.token === SyntaxKind.ExtendsKeyword) {
                        if (seenExtendsClause) {
                            return grammarErrorOnFirstToken(
                                heritageClause,
                                Diagnostics.extends_clause_already_seen
                            );
                        }

                        seenExtendsClause = true;
                    } else {
                        Debug
                            .assert(
                                heritageClause.token
                                    === SyntaxKind.ImplementsKeyword
                            );
                        return grammarErrorOnFirstToken(
                            heritageClause,
                            Diagnostics
                                .Interface_declaration_cannot_have_implements_clause
                        );
                    }

                    // Grammar checking heritageClause inside class declaration
                    checkGrammarHeritageClause(heritageClause);
                }
            }
            return false;
        }

        function checkGrammarComputedPropertyName(node: Node): boolean {
            // If node is not a computedPropertyName, just skip the grammar checking
            if (node.kind !== SyntaxKind.ComputedPropertyName) {
                return false;
            }

            const computedPropertyName = <ComputedPropertyName> node;
            if (computedPropertyName.expression.kind
                === SyntaxKind.BinaryExpression
                && (<BinaryExpression> computedPropertyName.expression)
                    .operatorToken.kind === SyntaxKind.CommaToken)
            {
                return grammarErrorOnNode(
                    computedPropertyName.expression,
                    Diagnostics
                        .A_comma_expression_is_not_allowed_in_a_computed_property_name
                );
            }
            return false;
        }

        function checkGrammarForGenerator(node: FunctionLikeDeclaration) {
            if (node.asteriskToken) {
                Debug.assert(
                    node.kind === SyntaxKind.FunctionDeclaration
                        || node.kind === SyntaxKind.FunctionExpression
                        || node.kind === SyntaxKind.MethodDeclaration
                );
                if (node.flags & NodeFlags.Ambient) {
                    return grammarErrorOnNode(
                        node.asteriskToken!,
                        Diagnostics
                            .Generators_are_not_allowed_in_an_ambient_context
                    );
                }
                if (!node.body) {
                    return grammarErrorOnNode(
                        node.asteriskToken!,
                        Diagnostics
                            .An_overload_signature_cannot_be_declared_as_a_generator
                    );
                }
            }
        }

        function checkGrammarForInvalidQuestionMark(
            questionToken: QuestionToken | undefined,
            message: DiagnosticMessage
        ): boolean {
            return !!questionToken
                && grammarErrorOnNode(questionToken, message);
        }

        function checkGrammarForInvalidExclamationToken(
            exclamationToken: ExclamationToken | undefined,
            message: DiagnosticMessage
        ): boolean {
            return !!exclamationToken
                && grammarErrorOnNode(exclamationToken, message);
        }

        function checkGrammarObjectLiteralExpression(
            node: ObjectLiteralExpression,
            inDestructuring: boolean
        ) {
            const seen = createUnderscoreEscapedMap<DeclarationMeaning>();

            for (const prop of node.properties) {
                if (prop.kind === SyntaxKind.SpreadAssignment) {
                    if (inDestructuring) {
                        // a rest property cannot be destructured any further
                        const expression = skipParentheses(prop.expression);
                        if (isArrayLiteralExpression(expression)
                            || isObjectLiteralExpression(expression))
                        {
                            return grammarErrorOnNode(
                                prop.expression,
                                Diagnostics
                                    .A_rest_element_cannot_contain_a_binding_pattern
                            );
                        }
                    }
                    continue;
                }
                const name = prop.name;
                if (name.kind === SyntaxKind.ComputedPropertyName) {
                    // If the name is not a ComputedPropertyName, the grammar checking will skip it
                    checkGrammarComputedPropertyName(name);
                }

                if (prop.kind === SyntaxKind.ShorthandPropertyAssignment
                    && !inDestructuring && prop.objectAssignmentInitializer)
                {
                    // having objectAssignmentInitializer is only valid in ObjectAssignmentPattern
                    // outside of destructuring it is a syntax error
                    return grammarErrorOnNode(
                        prop.equalsToken!,
                        Diagnostics
                            .can_only_be_used_in_an_object_literal_property_inside_a_destructuring_assignment
                    );
                }

                if (name.kind === SyntaxKind.PrivateIdentifier) {
                    return grammarErrorOnNode(
                        name,
                        Diagnostics
                            .Private_identifiers_are_not_allowed_outside_class_bodies
                    );
                }

                // Modifiers are never allowed on properties except for 'async' on a method declaration
                if (prop.modifiers) {
                    // eslint-disable-next-line @typescript-eslint/no-unnecessary-type-assertion
                    for (const mod of prop.modifiers!) { // TODO: GH#19955
                        if (mod.kind !== SyntaxKind.AsyncKeyword
                            || prop.kind !== SyntaxKind.MethodDeclaration)
                        {
                            grammarErrorOnNode(
                                mod,
                                Diagnostics._0_modifier_cannot_be_used_here,
                                getTextOfNode(mod)
                            );
                        }
                    }
                }

                // ECMA-262 11.1.5 Object Initializer
                // If previous is not undefined then throw a SyntaxError exception if any of the following conditions are true
                // a.This production is contained in strict code and IsDataDescriptor(previous) is true and
                // IsDataDescriptor(propId.descriptor) is true.
                //    b.IsDataDescriptor(previous) is true and IsAccessorDescriptor(propId.descriptor) is true.
                //    c.IsAccessorDescriptor(previous) is true and IsDataDescriptor(propId.descriptor) is true.
                //    d.IsAccessorDescriptor(previous) is true and IsAccessorDescriptor(propId.descriptor) is true
                // and either both previous and propId.descriptor have[[Get]] fields or both previous and propId.descriptor have[[Set]] fields
                let currentKind: DeclarationMeaning;
                switch (prop.kind) {
                    case SyntaxKind.ShorthandPropertyAssignment:
                        checkGrammarForInvalidExclamationToken(
                            prop.exclamationToken,
                            Diagnostics
                                .A_definite_assignment_assertion_is_not_permitted_in_this_context
                        );
                        // falls through
                    case SyntaxKind.PropertyAssignment:
                        // Grammar checking for computedPropertyName and shorthandPropertyAssignment
                        checkGrammarForInvalidQuestionMark(
                            prop.questionToken,
                            Diagnostics
                                .An_object_member_cannot_be_declared_optional
                        );
                        if (name.kind === SyntaxKind.NumericLiteral) {
                            checkGrammarNumericLiteral(name);
                        }
                        currentKind = DeclarationMeaning.PropertyAssignment;
                        break;
                    case SyntaxKind.MethodDeclaration:
                        currentKind = DeclarationMeaning.Method;
                        break;
                    case SyntaxKind.GetAccessor:
                        currentKind = DeclarationMeaning.GetAccessor;
                        break;
                    case SyntaxKind.SetAccessor:
                        currentKind = DeclarationMeaning.SetAccessor;
                        break;
                    default:
                        throw Debug.assertNever(
                            prop,
                            'Unexpected syntax kind:' + (<Node> prop).kind
                        );
                }

                const effectiveName = getPropertyNameForPropertyNameNode(name);
                if (effectiveName === undefined) {
                    continue;
                }

                const existingKind = seen.get(effectiveName);
                if (!existingKind) {
                    seen.set(effectiveName, currentKind);
                } else {
                    if ((currentKind
                        & DeclarationMeaning.PropertyAssignmentOrMethod)
                        && (existingKind
                            & DeclarationMeaning.PropertyAssignmentOrMethod))
                    {
                        grammarErrorOnNode(
                            name,
                            Diagnostics.Duplicate_identifier_0,
                            getTextOfNode(name)
                        );
                    } else if ((currentKind
                        & DeclarationMeaning.GetOrSetAccessor)
                        && (existingKind
                            & DeclarationMeaning.GetOrSetAccessor))
                    {
                        if (existingKind
                            !== DeclarationMeaning.GetOrSetAccessor
                            && currentKind !== existingKind)
                        {
                            seen.set(effectiveName,
                                currentKind | existingKind);
                        } else {
                            return grammarErrorOnNode(
                                name,
                                Diagnostics
                                    .An_object_literal_cannot_have_multiple_get_Slashset_accessors_with_the_same_name
                            );
                        }
                    } else {
                        return grammarErrorOnNode(
                            name,
                            Diagnostics
                                .An_object_literal_cannot_have_property_and_accessor_with_the_same_name
                        );
                    }
                }
            }
        }

        function checkGrammarJsxElement(node: JsxOpeningLikeElement) {
            checkGrammarTypeArguments(node, node.typeArguments);
            const seen = createUnderscoreEscapedMap<boolean>();

            for (const attr of node.attributes.properties) {
                if (attr.kind === SyntaxKind.JsxSpreadAttribute) {
                    continue;
                }

                const { name, initializer } = attr;
                if (!seen.get(name.escapedText)) {
                    seen.set(name.escapedText, true);
                } else {
                    return grammarErrorOnNode(
                        name,
                        Diagnostics
                            .JSX_elements_cannot_have_multiple_attributes_with_the_same_name
                    );
                }

                if (initializer
                    && initializer.kind === SyntaxKind.JsxExpression
                    && !initializer.expression)
                {
                    return grammarErrorOnNode(
                        initializer,
                        Diagnostics
                            .JSX_attributes_must_only_be_assigned_a_non_empty_expression
                    );
                }
            }
        }

        function checkGrammarJsxExpression(node: JsxExpression) {
            if (node.expression && isCommaSequence(node.expression)) {
                return grammarErrorOnNode(
                    node.expression,
                    Diagnostics
                        .JSX_expressions_may_not_use_the_comma_operator_Did_you_mean_to_write_an_array
                );
            }
        }

        function checkGrammarForInOrForOfStatement(
            forInOrOfStatement: ForInOrOfStatement
        ): boolean {
            if (checkGrammarStatementInAmbientContext(forInOrOfStatement)) {
                return true;
            }

            if (forInOrOfStatement.kind === SyntaxKind.ForOfStatement
                && forInOrOfStatement.awaitModifier)
            {
                if ((forInOrOfStatement.flags & NodeFlags.AwaitContext)
                    === NodeFlags.None)
                {
                    // use of 'for-await-of' in non-async function
                    const sourceFile = getSourceFileOfNode(forInOrOfStatement);
                    if (!hasParseDiagnostics(sourceFile)) {
                        const diagnostic = createDiagnosticForNode(
                            forInOrOfStatement.awaitModifier,
                            Diagnostics
                                .A_for_await_of_statement_is_only_allowed_within_an_async_function_or_async_generator
                        );
                        const func = getContainingFunction(forInOrOfStatement);
                        if (func && func.kind !== SyntaxKind.Constructor) {
                            Debug
                                .assert(
                                    (getFunctionFlags(func)
                                        & FunctionFlags.Async) === 0,
                                    'Enclosing function should never be an async function.'
                                );
                            const relatedInfo = createDiagnosticForNode(
                                func,
                                Diagnostics
                                    .Did_you_mean_to_mark_this_function_as_async
                            );
                            addRelatedInfo(diagnostic, relatedInfo);
                        }
                        diagnostics.add(diagnostic);
                        return true;
                    }
                    return false;
                }
            }

            if (forInOrOfStatement.initializer.kind
                === SyntaxKind.VariableDeclarationList)
            {
                const variableList = <VariableDeclarationList> forInOrOfStatement
                    .initializer;
                if (!checkGrammarVariableDeclarationList(variableList)) {
                    const declarations = variableList.declarations;

                    // declarations.length can be zero if there is an error in variable declaration in for-of or for-in
                    // See http://www.ecma-international.org/ecma-262/6.0/#sec-for-in-and-for-of-statements for details
                    // For example:
                    //      var let = 10;
                    //      for (let of [1,2,3]) {} // this is invalid ES6 syntax
                    //      for (let in [1,2,3]) {} // this is invalid ES6 syntax
                    // We will then want to skip on grammar checking on variableList declaration
                    if (!declarations.length) {
                        return false;
                    }

                    if (declarations.length > 1) {
                        const diagnostic = forInOrOfStatement.kind
                            === SyntaxKind.ForInStatement
                            ? Diagnostics
                                .Only_a_single_variable_declaration_is_allowed_in_a_for_in_statement
                            : Diagnostics
                                .Only_a_single_variable_declaration_is_allowed_in_a_for_of_statement;
                        return grammarErrorOnFirstToken(
                            variableList.declarations[1],
                            diagnostic
                        );
                    }
                    const firstDeclaration = declarations[0];

                    if (firstDeclaration.initializer) {
                        const diagnostic = forInOrOfStatement.kind
                            === SyntaxKind.ForInStatement
                            ? Diagnostics
                                .The_variable_declaration_of_a_for_in_statement_cannot_have_an_initializer
                            : Diagnostics
                                .The_variable_declaration_of_a_for_of_statement_cannot_have_an_initializer;
                        return grammarErrorOnNode(
                            firstDeclaration.name,
                            diagnostic
                        );
                    }
                    if (firstDeclaration.type) {
                        const diagnostic = forInOrOfStatement.kind
                            === SyntaxKind.ForInStatement
                            ? Diagnostics
                                .The_left_hand_side_of_a_for_in_statement_cannot_use_a_type_annotation
                            : Diagnostics
                                .The_left_hand_side_of_a_for_of_statement_cannot_use_a_type_annotation;
                        return grammarErrorOnNode(firstDeclaration,
                            diagnostic);
                    }
                }
            }

            return false;
        }

        function checkGrammarAccessor(accessor: AccessorDeclaration): boolean {
            if (!(accessor.flags & NodeFlags.Ambient)) {
                if (languageVersion < ScriptTarget.ES5) {
                    return grammarErrorOnNode(
                        accessor.name,
                        Diagnostics
                            .Accessors_are_only_available_when_targeting_ECMAScript_5_and_higher
                    );
                }
                if (accessor.body === undefined
                    && !hasModifier(accessor, ModifierFlags.Abstract))
                {
                    return grammarErrorAtPos(
                        accessor,
                        accessor.end - 1,
                        ';'.length,
                        Diagnostics._0_expected,
                        '{'
                    );
                }
            }
            if (accessor.body
                && hasModifier(accessor, ModifierFlags.Abstract))
            {
                return grammarErrorOnNode(
                    accessor,
                    Diagnostics
                        .An_abstract_accessor_cannot_have_an_implementation
                );
            }
            if (accessor.typeParameters) {
                return grammarErrorOnNode(
                    accessor.name,
                    Diagnostics.An_accessor_cannot_have_type_parameters
                );
            }
            if (!doesAccessorHaveCorrectParameterCount(accessor)) {
                return grammarErrorOnNode(
                    accessor.name,
                    accessor.kind === SyntaxKind.GetAccessor
                        ? Diagnostics.A_get_accessor_cannot_have_parameters
                        : Diagnostics
                            .A_set_accessor_must_have_exactly_one_parameter
                );
            }
            if (accessor.kind === SyntaxKind.SetAccessor) {
                if (accessor.type) {
                    return grammarErrorOnNode(
                        accessor.name,
                        Diagnostics
                            .A_set_accessor_cannot_have_a_return_type_annotation
                    );
                }
                const parameter = Debug
                    .assertDefined(
                        getSetAccessorValueParameter(accessor),
                        'Return value does not match parameter count assertion.'
                    );
                if (parameter.dotDotDotToken) {
                    return grammarErrorOnNode(
                        parameter.dotDotDotToken,
                        Diagnostics.A_set_accessor_cannot_have_rest_parameter
                    );
                }
                if (parameter.questionToken) {
                    return grammarErrorOnNode(
                        parameter.questionToken,
                        Diagnostics
                            .A_set_accessor_cannot_have_an_optional_parameter
                    );
                }
                if (parameter.initializer) {
                    return grammarErrorOnNode(
                        accessor.name,
                        Diagnostics
                            .A_set_accessor_parameter_cannot_have_an_initializer
                    );
                }
            }
            return false;
        }

        /** Does the accessor have the right number of parameters?
         * A get accessor has no parameters or a single `this` parameter.
         * A set accessor has one parameter or a `this` parameter and one more parameter.
         */
        function doesAccessorHaveCorrectParameterCount(
            accessor: AccessorDeclaration
        ) {
            return getAccessorThisParameter(accessor)
                || accessor.parameters.length
                === (accessor.kind === SyntaxKind.GetAccessor ? 0 : 1);
        }

        function getAccessorThisParameter(
            accessor: AccessorDeclaration
        ): ParameterDeclaration | undefined {
            if (accessor.parameters.length
                === (accessor.kind === SyntaxKind.GetAccessor ? 1 : 2))
            {
                return getThisParameter(accessor);
            }
        }

        function checkGrammarTypeOperatorNode(node: TypeOperatorNode) {
            if (node.operator === SyntaxKind.UniqueKeyword) {
                if (node.type.kind !== SyntaxKind.SymbolKeyword) {
                    return grammarErrorOnNode(
                        node.type,
                        Diagnostics._0_expected,
                        tokenToString(SyntaxKind.SymbolKeyword)
                    );
                }

                const parent = walkUpParenthesizedTypes(node.parent);
                switch (parent.kind) {
                    case SyntaxKind.VariableDeclaration:
                        const decl = parent as VariableDeclaration;
                        if (decl.name.kind !== SyntaxKind.Identifier) {
                            return grammarErrorOnNode(
                                node,
                                Diagnostics
                                    .unique_symbol_types_may_not_be_used_on_a_variable_declaration_with_a_binding_name
                            );
                        }
                        if (!isVariableDeclarationInVariableStatement(decl)) {
                            return grammarErrorOnNode(
                                node,
                                Diagnostics
                                    .unique_symbol_types_are_only_allowed_on_variables_in_a_variable_statement
                            );
                        }
                        if (!(decl.parent.flags & NodeFlags.Const)) {
                            return grammarErrorOnNode(
                                (<VariableDeclaration> parent).name,
                                Diagnostics
                                    .A_variable_whose_type_is_a_unique_symbol_type_must_be_const
                            );
                        }
                        break;
                    case SyntaxKind.PropertyDeclaration:
                        if (!hasModifier(parent, ModifierFlags.Static)
                            || !hasModifier(parent, ModifierFlags.Readonly))
                        {
                            return grammarErrorOnNode(
                                (<PropertyDeclaration> parent).name,
                                Diagnostics
                                    .A_property_of_a_class_whose_type_is_a_unique_symbol_type_must_be_both_static_and_readonly
                            );
                        }
                        break;
                    case SyntaxKind.PropertySignature:
                        if (!hasModifier(parent, ModifierFlags.Readonly)) {
                            return grammarErrorOnNode(
                                (<PropertySignature> parent).name,
                                Diagnostics
                                    .A_property_of_an_interface_or_type_literal_whose_type_is_a_unique_symbol_type_must_be_readonly
                            );
                        }
                        break;
                    default:
                        return grammarErrorOnNode(
                            node,
                            Diagnostics
                                .unique_symbol_types_are_not_allowed_here
                        );
                }
            } else if (node.operator === SyntaxKind.ReadonlyKeyword) {
                if (node.type.kind !== SyntaxKind.ArrayType
                    && node.type.kind !== SyntaxKind.TupleType)
                {
                    return grammarErrorOnFirstToken(
                        node,
                        Diagnostics
                            .readonly_type_modifier_is_only_permitted_on_array_and_tuple_literal_types,
                        tokenToString(SyntaxKind.SymbolKeyword)
                    );
                }
            }
        }

        function checkGrammarForInvalidDynamicName(
            node: DeclarationName,
            message: DiagnosticMessage
        ) {
            if (isNonBindableDynamicName(node)) {
                return grammarErrorOnNode(node, message);
            }
        }

        function checkGrammarMethod(node: MethodDeclaration
            | MethodSignature)
        {
            if (checkGrammarFunctionLikeDeclaration(node)) {
                return true;
            }

            if (node.kind === SyntaxKind.MethodDeclaration) {
                if (node.parent.kind === SyntaxKind.ObjectLiteralExpression) {
                    // We only disallow modifier on a method declaration if it is a property of object-literal-expression
                    if (node.modifiers
                        && !(node.modifiers.length === 1
                            && first(node.modifiers).kind
                            === SyntaxKind.AsyncKeyword))
                    {
                        return grammarErrorOnFirstToken(
                            node,
                            Diagnostics.Modifiers_cannot_appear_here
                        );
                    } else if (checkGrammarForInvalidQuestionMark(
                        node.questionToken,
                        Diagnostics
                            .An_object_member_cannot_be_declared_optional
                    )) {
                        return true;
                    } else if (checkGrammarForInvalidExclamationToken(
                        node.exclamationToken,
                        Diagnostics
                            .A_definite_assignment_assertion_is_not_permitted_in_this_context
                    )) {
                        return true;
                    } else if (node.body === undefined) {
                        return grammarErrorAtPos(
                            node,
                            node.end - 1,
                            ';'.length,
                            Diagnostics._0_expected,
                            '{'
                        );
                    }
                }
                if (checkGrammarForGenerator(node)) {
                    return true;
                }
            }

            if (isClassLike(node.parent)) {
                // Technically, computed properties in ambient contexts is disallowed
                // for property declarations and accessors too, not just methods.
                // However, property declarations disallow computed names in general,
                // and accessors are not allowed in ambient contexts in general,
                // so this error only really matters for methods.
                if (node.flags & NodeFlags.Ambient) {
                    return checkGrammarForInvalidDynamicName(
                        node.name,
                        Diagnostics
                            .A_computed_property_name_in_an_ambient_context_must_refer_to_an_expression_whose_type_is_a_literal_type_or_a_unique_symbol_type
                    );
                } else if (node.kind === SyntaxKind.MethodDeclaration
                    && !node.body)
                {
                    return checkGrammarForInvalidDynamicName(
                        node.name,
                        Diagnostics
                            .A_computed_property_name_in_a_method_overload_must_refer_to_an_expression_whose_type_is_a_literal_type_or_a_unique_symbol_type
                    );
                }
            } else if (node.parent.kind === SyntaxKind.InterfaceDeclaration) {
                return checkGrammarForInvalidDynamicName(
                    node.name,
                    Diagnostics
                        .A_computed_property_name_in_an_interface_must_refer_to_an_expression_whose_type_is_a_literal_type_or_a_unique_symbol_type
                );
            } else if (node.parent.kind === SyntaxKind.TypeLiteral) {
                return checkGrammarForInvalidDynamicName(
                    node.name,
                    Diagnostics
                        .A_computed_property_name_in_a_type_literal_must_refer_to_an_expression_whose_type_is_a_literal_type_or_a_unique_symbol_type
                );
            }
        }

        function checkGrammarBreakOrContinueStatement(
            node: BreakOrContinueStatement
        ): boolean {
            let current: Node = node;
            while (current) {
                if (isFunctionLike(current)) {
                    return grammarErrorOnNode(
                        node,
                        Diagnostics.Jump_target_cannot_cross_function_boundary
                    );
                }

                switch (current.kind) {
                    case SyntaxKind.LabeledStatement:
                        if (node.label
                            && (<LabeledStatement> current).label.escapedText
                            === node.label.escapedText)
                        {
                            // found matching label - verify that label usage is correct
                            // continue can only target labels that are on iteration statements
                            const isMisplacedContinueLabel = node.kind
                                === SyntaxKind.ContinueStatement
                                && !isIterationStatement(
                                    (<LabeledStatement> current)
                                        .statement, /*lookInLabeledStatement*/
                                    true
                                );

                            if (isMisplacedContinueLabel) {
                                return grammarErrorOnNode(
                                    node,
                                    Diagnostics
                                        .A_continue_statement_can_only_jump_to_a_label_of_an_enclosing_iteration_statement
                                );
                            }

                            return false;
                        }
                        break;
                    case SyntaxKind.SwitchStatement:
                        if (node.kind === SyntaxKind.BreakStatement
                            && !node.label)
                        {
                            // unlabeled break within switch statement - ok
                            return false;
                        }
                        break;
                    default:
                        if (isIterationStatement(
                            current, /*lookInLabeledStatement*/
                            false
                        ) && !node.label) {
                            // unlabeled break or continue within iteration statement - ok
                            return false;
                        }
                        break;
                }

                current = current.parent;
            }

            if (node.label) {
                const message = node.kind === SyntaxKind.BreakStatement
                    ? Diagnostics
                        .A_break_statement_can_only_jump_to_a_label_of_an_enclosing_statement
                    : Diagnostics
                        .A_continue_statement_can_only_jump_to_a_label_of_an_enclosing_iteration_statement;

                return grammarErrorOnNode(node, message);
            } else {
                const message = node.kind === SyntaxKind.BreakStatement
                    ? Diagnostics
                        .A_break_statement_can_only_be_used_within_an_enclosing_iteration_or_switch_statement
                    : Diagnostics
                        .A_continue_statement_can_only_be_used_within_an_enclosing_iteration_statement;
                return grammarErrorOnNode(node, message);
            }
        }

        function checkGrammarBindingElement(node: BindingElement) {
            if (node.dotDotDotToken) {
                const elements = node.parent.elements;
                if (node !== last(elements)) {
                    return grammarErrorOnNode(
                        node,
                        Diagnostics
                            .A_rest_element_must_be_last_in_a_destructuring_pattern
                    );
                }
                checkGrammarForDisallowedTrailingComma(
                    elements,
                    Diagnostics
                        .A_rest_parameter_or_binding_pattern_may_not_have_a_trailing_comma
                );

                if (node.propertyName) {
                    return grammarErrorOnNode(
                        node.name,
                        Diagnostics.A_rest_element_cannot_have_a_property_name
                    );
                }

                if (node.initializer) {
                    // Error on equals token which immediately precedes the initializer
                    return grammarErrorAtPos(
                        node,
                        node.initializer.pos - 1,
                        1,
                        Diagnostics.A_rest_element_cannot_have_an_initializer
                    );
                }
            }
        }

        function isStringOrNumberLiteralExpression(expr: Expression) {
            return isStringOrNumericLiteralLike(expr)
                || expr.kind === SyntaxKind.PrefixUnaryExpression
                && (<PrefixUnaryExpression> expr).operator
                === SyntaxKind.MinusToken
                && (<PrefixUnaryExpression> expr).operand.kind
                === SyntaxKind.NumericLiteral;
        }

        function isBigIntLiteralExpression(expr: Expression) {
            return expr.kind === SyntaxKind.BigIntLiteral
                || expr.kind === SyntaxKind.PrefixUnaryExpression
                && (<PrefixUnaryExpression> expr).operator
                === SyntaxKind.MinusToken
                && (<PrefixUnaryExpression> expr).operand.kind
                === SyntaxKind.BigIntLiteral;
        }

        function isSimpleLiteralEnumReference(expr: Expression) {
            if ((isPropertyAccessExpression(expr)
                || (isElementAccessExpression(expr)
                    && isStringOrNumberLiteralExpression(
                        expr.argumentExpression
                    )))
                && isEntityNameExpression(expr.expression))
            {
                return !!(checkExpressionCached(expr).flags
                    & TypeFlags.EnumLiteral);
            }
        }

        function checkAmbientInitializer(
            node: VariableDeclaration | PropertyDeclaration | PropertySignature
        ) {
            const { initializer } = node;
            if (initializer) {
                const isInvalidInitializer = !(
                    isStringOrNumberLiteralExpression(initializer)
                    || isSimpleLiteralEnumReference(initializer)
                    || initializer.kind === SyntaxKind.TrueKeyword
                    || initializer.kind === SyntaxKind.FalseKeyword
                    || isBigIntLiteralExpression(initializer)
                );
                const isConstOrReadonly = isDeclarationReadonly(node)
                    || isVariableDeclaration(node) && isVarConst(node);
                if (isConstOrReadonly && !node.type) {
                    if (isInvalidInitializer) {
                        return grammarErrorOnNode(
                            initializer,
                            Diagnostics
                                .A_const_initializer_in_an_ambient_context_must_be_a_string_or_numeric_literal_or_literal_enum_reference
                        );
                    }
                } else {
                    return grammarErrorOnNode(
                        initializer,
                        Diagnostics
                            .Initializers_are_not_allowed_in_ambient_contexts
                    );
                }
                if (!isConstOrReadonly || isInvalidInitializer) {
                    return grammarErrorOnNode(
                        initializer,
                        Diagnostics
                            .Initializers_are_not_allowed_in_ambient_contexts
                    );
                }
            }
        }

        function checkGrammarVariableDeclaration(node: VariableDeclaration) {
            if (node.parent.parent.kind !== SyntaxKind.ForInStatement
                && node.parent.parent.kind !== SyntaxKind.ForOfStatement)
            {
                if (node.flags & NodeFlags.Ambient) {
                    checkAmbientInitializer(node);
                } else if (!node.initializer) {
                    if (isBindingPattern(node.name)
                        && !isBindingPattern(node.parent))
                    {
                        return grammarErrorOnNode(
                            node,
                            Diagnostics
                                .A_destructuring_declaration_must_have_an_initializer
                        );
                    }
                    if (isVarConst(node)) {
                        return grammarErrorOnNode(
                            node,
                            Diagnostics.const_declarations_must_be_initialized
                        );
                    }
                }
            }

            if (node.exclamationToken
                && (node.parent.parent.kind !== SyntaxKind.VariableStatement
                    || !node.type || node.initializer
                    || node.flags & NodeFlags.Ambient))
            {
                return grammarErrorOnNode(
                    node.exclamationToken,
                    Diagnostics
                        .Definite_assignment_assertions_can_only_be_used_along_with_a_type_annotation
                );
            }

            const moduleKind = getEmitModuleKind(compilerOptions);

            if (moduleKind < ModuleKind.ES2015
                && moduleKind !== ModuleKind.System && !compilerOptions.noEmit
                && !(node.parent.parent.flags & NodeFlags.Ambient)
                && hasModifier(node.parent.parent, ModifierFlags.Export))
            {
                checkESModuleMarker(node.name);
            }

            const checkLetConstNames = (isLet(node) || isVarConst(node));

            // 1. LexicalDeclaration : LetOrConst BindingList ;
            // It is a Syntax Error if the BoundNames of BindingList contains "let".
            // 2. ForDeclaration: ForDeclaration : LetOrConst ForBinding
            // It is a Syntax Error if the BoundNames of ForDeclaration contains "let".

            // It is a SyntaxError if a VariableDeclaration or VariableDeclarationNoIn occurs within strict code
            // and its Identifier is eval or arguments
            return checkLetConstNames
                && checkGrammarNameInLetOrConstDeclarations(node.name);
        }

        function checkESModuleMarker(
            name: Identifier | BindingPattern
        ): boolean {
            if (name.kind === SyntaxKind.Identifier) {
                if (idText(name) === '__esModule') {
                    return grammarErrorOnNode(
                        name,
                        Diagnostics
                            .Identifier_expected_esModule_is_reserved_as_an_exported_marker_when_transforming_ECMAScript_modules
                    );
                }
            } else {
                const elements = name.elements;
                for (const element of elements) {
                    if (!isOmittedExpression(element)) {
                        return checkESModuleMarker(element.name);
                    }
                }
            }
            return false;
        }

        function checkGrammarNameInLetOrConstDeclarations(
            name: Identifier | BindingPattern
        ): boolean {
            if (name.kind === SyntaxKind.Identifier) {
                if (name.originalKeywordKind === SyntaxKind.LetKeyword) {
                    return grammarErrorOnNode(
                        name,
                        Diagnostics
                            .let_is_not_allowed_to_be_used_as_a_name_in_let_or_const_declarations
                    );
                }
            } else {
                const elements = name.elements;
                for (const element of elements) {
                    if (!isOmittedExpression(element)) {
                        checkGrammarNameInLetOrConstDeclarations(element.name);
                    }
                }
            }
            return false;
        }

        function checkGrammarVariableDeclarationList(
            declarationList: VariableDeclarationList
        ): boolean {
            const declarations = declarationList.declarations;
            if (checkGrammarForDisallowedTrailingComma(
                declarationList.declarations
            )) {
                return true;
            }

            if (!declarationList.declarations.length) {
                return grammarErrorAtPos(
                    declarationList,
                    declarations.pos,
                    declarations.end - declarations.pos,
                    Diagnostics.Variable_declaration_list_cannot_be_empty
                );
            }
            return false;
        }

        function allowLetAndConstDeclarations(parent: Node): boolean {
            switch (parent.kind) {
                case SyntaxKind.IfStatement:
                case SyntaxKind.DoStatement:
                case SyntaxKind.WhileStatement:
                case SyntaxKind.WithStatement:
                case SyntaxKind.ForStatement:
                case SyntaxKind.ForInStatement:
                case SyntaxKind.ForOfStatement:
                    return false;
                case SyntaxKind.LabeledStatement:
                    return allowLetAndConstDeclarations(parent.parent);
            }

            return true;
        }

        function checkGrammarForDisallowedLetOrConstStatement(
            node: VariableStatement
        ) {
            if (!allowLetAndConstDeclarations(node.parent)) {
                if (isLet(node.declarationList)) {
                    return grammarErrorOnNode(
                        node,
                        Diagnostics
                            .let_declarations_can_only_be_declared_inside_a_block
                    );
                } else if (isVarConst(node.declarationList)) {
                    return grammarErrorOnNode(
                        node,
                        Diagnostics
                            .const_declarations_can_only_be_declared_inside_a_block
                    );
                }
            }
        }

        function checkGrammarMetaProperty(node: MetaProperty) {
            const escapedText = node.name.escapedText;
            switch (node.keywordToken) {
                case SyntaxKind.NewKeyword:
                    if (escapedText !== 'target') {
                        return grammarErrorOnNode(
                            node.name,
                            Diagnostics
                                ._0_is_not_a_valid_meta_property_for_keyword_1_Did_you_mean_2,
                            node.name.escapedText,
                            tokenToString(node.keywordToken),
                            'target'
                        );
                    }
                    break;
                case SyntaxKind.ImportKeyword:
                    if (escapedText !== 'meta') {
                        return grammarErrorOnNode(
                            node.name,
                            Diagnostics
                                ._0_is_not_a_valid_meta_property_for_keyword_1_Did_you_mean_2,
                            node.name.escapedText,
                            tokenToString(node.keywordToken),
                            'meta'
                        );
                    }
                    break;
            }
        }

        function hasParseDiagnostics(sourceFile: SourceFile): boolean {
            return sourceFile.parseDiagnostics.length > 0;
        }

        function grammarErrorOnFirstToken(
            node: Node,
            message: DiagnosticMessage,
            arg0?: any,
            arg1?: any,
            arg2?: any
        ): boolean {
            const sourceFile = getSourceFileOfNode(node);
            if (!hasParseDiagnostics(sourceFile)) {
                const span = getSpanOfTokenAtPosition(sourceFile, node.pos);
                diagnostics
                    .add(
                        createFileDiagnostic(
                            sourceFile,
                            span.start,
                            span.length,
                            message,
                            arg0,
                            arg1,
                            arg2
                        )
                    );
                return true;
            }
            return false;
        }

        function grammarErrorAtPos(
            nodeForSourceFile: Node,
            start: number,
            length: number,
            message: DiagnosticMessage,
            arg0?: any,
            arg1?: any,
            arg2?: any
        ): boolean {
            const sourceFile = getSourceFileOfNode(nodeForSourceFile);
            if (!hasParseDiagnostics(sourceFile)) {
                diagnostics
                    .add(
                        createFileDiagnostic(
                            sourceFile,
                            start,
                            length,
                            message,
                            arg0,
                            arg1,
                            arg2
                        )
                    );
                return true;
            }
            return false;
        }

        function grammarErrorOnNode(
            node: Node,
            message: DiagnosticMessage,
            arg0?: any,
            arg1?: any,
            arg2?: any
        ): boolean {
            const sourceFile = getSourceFileOfNode(node);
            if (!hasParseDiagnostics(sourceFile)) {
                diagnostics
                    .add(
                        createDiagnosticForNode(
                            node,
                            message,
                            arg0,
                            arg1,
                            arg2
                        )
                    );
                return true;
            }
            return false;
        }

        function checkGrammarConstructorTypeParameters(
            node: ConstructorDeclaration
        ) {
            const jsdocTypeParameters = isInJSFile(node)
                ? getJSDocTypeParameterDeclarations(node)
                : undefined;
            const range = node.typeParameters || jsdocTypeParameters
                && firstOrUndefined(jsdocTypeParameters);
            if (range) {
                const pos = range.pos === range.end
                    ? range.pos
                    : skipTrivia(getSourceFileOfNode(node).text, range.pos);
                return grammarErrorAtPos(
                    node,
                    pos,
                    range.end - pos,
                    Diagnostics
                        .Type_parameters_cannot_appear_on_a_constructor_declaration
                );
            }
        }

        function checkGrammarConstructorTypeAnnotation(
            node: ConstructorDeclaration
        ) {
            const type = getEffectiveReturnTypeNode(node);
            if (type) {
                return grammarErrorOnNode(
                    type,
                    Diagnostics
                        .Type_annotation_cannot_appear_on_a_constructor_declaration
                );
            }
        }

        function checkGrammarProperty(
            node: PropertyDeclaration | PropertySignature
        ) {
            if (isClassLike(node.parent)) {
                if (isStringLiteral(node.name)
                    && node.name.text === 'constructor')
                {
                    return grammarErrorOnNode(
                        node.name,
                        Diagnostics
                            .Classes_may_not_have_a_field_named_constructor
                    );
                }
                if (checkGrammarForInvalidDynamicName(
                    node.name,
                    Diagnostics
                        .A_computed_property_name_in_a_class_property_declaration_must_refer_to_an_expression_whose_type_is_a_literal_type_or_a_unique_symbol_type
                )) {
                    return true;
                }
                if (languageVersion < ScriptTarget.ES2015
                    && isPrivateIdentifier(node.name))
                {
                    return grammarErrorOnNode(
                        node.name,
                        Diagnostics
                            .Private_identifiers_are_only_available_when_targeting_ECMAScript_2015_and_higher
                    );
                }
            } else if (node.parent.kind === SyntaxKind.InterfaceDeclaration) {
                if (checkGrammarForInvalidDynamicName(
                    node.name,
                    Diagnostics
                        .A_computed_property_name_in_an_interface_must_refer_to_an_expression_whose_type_is_a_literal_type_or_a_unique_symbol_type
                )) {
                    return true;
                }
                if (node.initializer) {
                    return grammarErrorOnNode(
                        node.initializer,
                        Diagnostics
                            .An_interface_property_cannot_have_an_initializer
                    );
                }
            } else if (node.parent.kind === SyntaxKind.TypeLiteral) {
                if (checkGrammarForInvalidDynamicName(
                    node.name,
                    Diagnostics
                        .A_computed_property_name_in_a_type_literal_must_refer_to_an_expression_whose_type_is_a_literal_type_or_a_unique_symbol_type
                )) {
                    return true;
                }
                if (node.initializer) {
                    return grammarErrorOnNode(
                        node.initializer,
                        Diagnostics
                            .A_type_literal_property_cannot_have_an_initializer
                    );
                }
            }

            if (node.flags & NodeFlags.Ambient) {
                checkAmbientInitializer(node);
            }

            if (isPropertyDeclaration(node) && node.exclamationToken
                && (!isClassLike(node.parent) || !node.type || node.initializer
                    || node.flags & NodeFlags.Ambient
                    || hasModifier(
                        node,
                        ModifierFlags.Static | ModifierFlags.Abstract
                    )))
            {
                return grammarErrorOnNode(
                    node.exclamationToken,
                    Diagnostics
                        .A_definite_assignment_assertion_is_not_permitted_in_this_context
                );
            }
        }

        function checkGrammarTopLevelElementForRequiredDeclareModifier(
            node: Node
        ): boolean {
            // A declare modifier is required for any top level .d.ts declaration except export=, export default, export as namespace
            // interfaces and imports categories:
            //
            //  DeclarationElement:
            //     ExportAssignment
            //     export_opt   InterfaceDeclaration
            //     export_opt   TypeAliasDeclaration
            //     export_opt   ImportDeclaration
            //     export_opt   ExternalImportDeclaration
            //     export_opt   AmbientDeclaration
            //
            // TODO: The spec needs to be amended to reflect this grammar.
            if (node.kind === SyntaxKind.InterfaceDeclaration
                || node.kind === SyntaxKind.TypeAliasDeclaration
                || node.kind === SyntaxKind.ImportDeclaration
                || node.kind === SyntaxKind.ImportEqualsDeclaration
                || node.kind === SyntaxKind.ExportDeclaration
                || node.kind === SyntaxKind.ExportAssignment
                || node.kind === SyntaxKind.NamespaceExportDeclaration
                || hasModifier(
                    node,
                    ModifierFlags.Ambient | ModifierFlags.Export
                        | ModifierFlags.Default
                ))
            {
                return false;
            }

            return grammarErrorOnFirstToken(
                node,
                Diagnostics
                    .Top_level_declarations_in_d_ts_files_must_start_with_either_a_declare_or_export_modifier
            );
        }

        function checkGrammarTopLevelElementsForRequiredDeclareModifier(
            file: SourceFile
        ): boolean {
            for (const decl of file.statements) {
                if (isDeclaration(decl)
                    || decl.kind === SyntaxKind.VariableStatement)
                {
                    if (checkGrammarTopLevelElementForRequiredDeclareModifier(decl)) {
                        return true;
                    }
                }
            }
            return false;
        }

        function checkGrammarSourceFile(node: SourceFile): boolean {
            return !!(node.flags & NodeFlags.Ambient)
                && checkGrammarTopLevelElementsForRequiredDeclareModifier(node);
        }

        function checkGrammarStatementInAmbientContext(node: Node): boolean {
            if (node.flags & NodeFlags.Ambient) {
                // Find containing block which is either Block, ModuleBlock, SourceFile
                const links = getNodeLinks(node);
                if (!links.hasReportedStatementInAmbientContext
                    && (isFunctionLike(node.parent)
                        || isAccessor(node.parent)))
                {
                    return getNodeLinks(node)
                        .hasReportedStatementInAmbientContext = grammarErrorOnFirstToken(
                            node,
                            Diagnostics
                                .An_implementation_cannot_be_declared_in_ambient_contexts
                        );
                }

                // We are either parented by another statement, or some sort of block.
                // If we're in a block, we only want to really report an error once
                // to prevent noisiness.  So use a bit on the block to indicate if
                // this has already been reported, and don't report if it has.
                //
                if (node.parent.kind === SyntaxKind.Block
                    || node.parent.kind === SyntaxKind.ModuleBlock
                    || node.parent.kind === SyntaxKind.SourceFile)
                {
                    const links = getNodeLinks(node.parent);
                    // Check if the containing block ever report this error
                    if (!links.hasReportedStatementInAmbientContext) {
                        return links
                            .hasReportedStatementInAmbientContext = grammarErrorOnFirstToken(
                                node,
                                Diagnostics
                                    .Statements_are_not_allowed_in_ambient_contexts
                            );
                    }
                } else {
                    // We must be parented by a statement.  If so, there's no need
                    // to report the error as our parent will have already done it.
                    // Debug.assert(isStatement(node.parent));
                }
            }
            return false;
        }

        function checkGrammarNumericLiteral(node: NumericLiteral): boolean {
            // Grammar checking
            if (node.numericLiteralFlags & TokenFlags.Octal) {
                let diagnosticMessage: DiagnosticMessage | undefined;
                if (languageVersion >= ScriptTarget.ES5) {
                    diagnosticMessage = Diagnostics
                        .Octal_literals_are_not_available_when_targeting_ECMAScript_5_and_higher_Use_the_syntax_0;
                } else if (isChildOfNodeWithKind(node,
                    SyntaxKind.LiteralType))
                {
                    diagnosticMessage = Diagnostics
                        .Octal_literal_types_must_use_ES2015_syntax_Use_the_syntax_0;
                } else if (isChildOfNodeWithKind(node,
                    SyntaxKind.EnumMember))
                {
                    diagnosticMessage = Diagnostics
                        .Octal_literals_are_not_allowed_in_enums_members_initializer_Use_the_syntax_0;
                }
                if (diagnosticMessage) {
                    const withMinus = isPrefixUnaryExpression(node.parent)
                        && node.parent.operator === SyntaxKind.MinusToken;
                    const literal = (withMinus ? '-' : '') + '0o' + node.text;
                    return grammarErrorOnNode(
                        withMinus ? node.parent : node,
                        diagnosticMessage,
                        literal
                    );
                }
            }

            // Realism (size) checking
            checkNumericLiteralValueSize(node);

            return false;
        }

        function checkNumericLiteralValueSize(node: NumericLiteral) {
            // Scientific notation (e.g. 2e54 and 1e00000000010) can't be converted to bigint
            // Literals with 15 or fewer characters aren't long enough to reach past 2^53 - 1
            // Fractional numbers (e.g. 9000000000000000.001) are inherently imprecise anyway
            if (node.numericLiteralFlags & TokenFlags.Scientific
                || node.text.length <= 15 || node.text.indexOf('.') !== -1)
            {
                return;
            }

            // We can't rely on the runtime to accurately store and compare extremely large numeric values
            // Even for internal use, we use getTextOfNode: https://github.com/microsoft/TypeScript/issues/33298
            // Thus, if the runtime claims a too-large number is lower than Number.MAX_SAFE_INTEGER,
            // it's likely addition operations on it will fail too
            const apparentValue = +getTextOfNode(node);
            if (apparentValue <= 2 ** 53 - 1
                && apparentValue + 1 > apparentValue)
            {
                return;
            }

            addErrorOrSuggestion(
                /*isError*/ false,
                createDiagnosticForNode(
                    node,
                    Diagnostics
                        .Numeric_literals_with_absolute_values_equal_to_2_53_or_greater_are_too_large_to_be_represented_accurately_as_integers
                )
            );
        }

        function checkGrammarBigIntLiteral(node: BigIntLiteral): boolean {
            const literalType = isLiteralTypeNode(node.parent)
                || isPrefixUnaryExpression(node.parent)
                && isLiteralTypeNode(node.parent.parent);
            if (!literalType) {
                if (languageVersion < ScriptTarget.ES2020) {
                    if (grammarErrorOnNode(
                        node,
                        Diagnostics
                            .BigInt_literals_are_not_available_when_targeting_lower_than_ES2020
                    )) {
                        return true;
                    }
                }
            }
            return false;
        }

        function grammarErrorAfterFirstToken(
            node: Node,
            message: DiagnosticMessage,
            arg0?: any,
            arg1?: any,
            arg2?: any
        ): boolean {
            const sourceFile = getSourceFileOfNode(node);
            if (!hasParseDiagnostics(sourceFile)) {
                const span = getSpanOfTokenAtPosition(sourceFile, node.pos);
                diagnostics
                    .add(
                        createFileDiagnostic(
                            sourceFile,
                            textSpanEnd(span), /*length*/
                            0,
                            message,
                            arg0,
                            arg1,
                            arg2
                        )
                    );
                return true;
            }
            return false;
        }

        function getAmbientModules(): Symbol[] {
            if (!ambientModulesCache) {
                ambientModulesCache = [];
                globals.forEach((global, sym) => {
                    // No need to `unescapeLeadingUnderscores`, an escaped symbol is never an ambient module.
                    if (ambientModuleSymbolRegex.test(sym as string)) {
                        ambientModulesCache!.push(global);
                    }
                });
            }
            return ambientModulesCache;
        }

        function checkGrammarImportClause(node: ImportClause): boolean {
            if (node.isTypeOnly && node.name && node.namedBindings) {
                return grammarErrorOnNode(
                    node,
                    Diagnostics
                        .A_type_only_import_can_specify_a_default_import_or_named_bindings_but_not_both
                );
            }
            return false;
        }

        function checkGrammarImportCallExpression(node: ImportCall): boolean {
            if (moduleKind === ModuleKind.ES2015) {
                return grammarErrorOnNode(
                    node,
                    Diagnostics
                        .Dynamic_imports_are_only_supported_when_the_module_flag_is_set_to_es2020_esnext_commonjs_amd_system_or_umd
                );
            }

            if (node.typeArguments) {
                return grammarErrorOnNode(
                    node,
                    Diagnostics.Dynamic_import_cannot_have_type_arguments
                );
            }

            const nodeArguments = node.arguments;
            if (nodeArguments.length !== 1) {
                return grammarErrorOnNode(
                    node,
                    Diagnostics
                        .Dynamic_import_must_have_one_specifier_as_an_argument
                );
            }
            checkGrammarForDisallowedTrailingComma(nodeArguments);
            // see: parseArgumentOrArrayLiteralElement...we use this function which parse arguments of callExpression to parse specifier for dynamic import.
            // parseArgumentOrArrayLiteralElement allows spread element to be in an argument list which is not allowed as specifier in dynamic import.
            if (isSpreadElement(nodeArguments[0])) {
                return grammarErrorOnNode(
                    nodeArguments[0],
                    Diagnostics
                        .Specifier_of_dynamic_import_cannot_be_spread_element
                );
            }
            return false;
        }

        function findMatchingTypeReferenceOrTypeAliasReference(
            source: Type,
            unionTarget: UnionOrIntersectionType
        ) {
            const sourceObjectFlags = getObjectFlags(source);
            if (sourceObjectFlags
                & (ObjectFlags.Reference | ObjectFlags.Anonymous)
                && unionTarget.flags & TypeFlags.Union)
            {
                return find(
                    unionTarget.types,
                    target => {
                        if (target.flags & TypeFlags.Object) {
                            const overlapObjFlags = sourceObjectFlags
                                & getObjectFlags(target);
                            if (overlapObjFlags & ObjectFlags.Reference) {
                                return (source as TypeReference).target
                                    === (target as TypeReference).target;
                            }
                            if (overlapObjFlags & ObjectFlags.Anonymous) {
                                return !!(source as AnonymousType).aliasSymbol
                                    && (source as AnonymousType).aliasSymbol
                                    === (target as AnonymousType).aliasSymbol;
                            }
                        }
                        return false;
                    }
                );
            }
        }

        function findBestTypeForObjectLiteral(
            source: Type,
            unionTarget: UnionOrIntersectionType
        ) {
            if (getObjectFlags(source) & ObjectFlags.ObjectLiteral
                && forEachType(unionTarget, isArrayLikeType))
            {
                return find(unionTarget.types, t => !isArrayLikeType(t));
            }
        }

        function findBestTypeForInvokable(
            source: Type,
            unionTarget: UnionOrIntersectionType
        ) {
            let signatureKind = SignatureKind.Call;
            const hasSignatures = getSignaturesOfType(source, signatureKind)
                .length > 0
                || (signatureKind = SignatureKind.Construct,
                    getSignaturesOfType(source, signatureKind).length > 0);
            if (hasSignatures) {
                return find(
                    unionTarget.types,
                    t => getSignaturesOfType(t, signatureKind).length > 0
                );
            }
        }

        function findMostOverlappyType(
            source: Type,
            unionTarget: UnionOrIntersectionType
        ) {
            let bestMatch: Type | undefined;
            let matchingCount = 0;
            for (const target of unionTarget.types) {
                const overlap = getIntersectionType(
                    [getIndexType(source), getIndexType(target)]
                );
                if (overlap.flags & TypeFlags.Index) {
                    // perfect overlap of keys
                    bestMatch = target;
                    matchingCount = Infinity;
                } else if (overlap.flags & TypeFlags.Union) {
                    // We only want to account for literal types otherwise.
                    // If we have a union of index types, it seems likely that we
                    // needed to elaborate between two generic mapped types anyway.
                    const len = length(
                        filter(
                            (overlap as UnionType).types,
                            isUnitType
                        )
                    );
                    if (len >= matchingCount) {
                        bestMatch = target;
                        matchingCount = len;
                    }
                } else if (isUnitType(overlap) && 1 >= matchingCount) {
                    bestMatch = target;
                    matchingCount = 1;
                }
            }
            return bestMatch;
        }

        function filterPrimitivesIfContainsNonPrimitive(type: UnionType) {
            if (maybeTypeOfKind(type, TypeFlags.NonPrimitive)) {
                const result = filterType(
                    type,
                    t => !(t.flags & TypeFlags.Primitive)
                );
                if (!(result.flags & TypeFlags.Never)) {
                    return result;
                }
            }
            return type;
        }

        // Keep this up-to-date with the same logic within `getApparentTypeOfContextualType`, since they should behave similarly
        function findMatchingDiscriminantType(
            source: Type,
            target: Type,
            isRelatedTo: (source: Type, target: Type) => Ternary
        ) {
            if (target.flags & TypeFlags.Union
                && source.flags & (TypeFlags.Intersection | TypeFlags.Object))
            {
                const sourceProperties = getPropertiesOfType(source);
                if (sourceProperties) {
                    const sourcePropertiesFiltered = findDiscriminantProperties(
                        sourceProperties,
                        target
                    );
                    if (sourcePropertiesFiltered) {
                        return discriminateTypeByDiscriminableItems(
                            <UnionType> target,
                            map(
                                sourcePropertiesFiltered,
                                p => ([() => getTypeOfSymbol(p),
                                    p.escapedName] as [() => Type, __String])
                            ),
                            isRelatedTo
                        );
                    }
                }
            }
            return undefined;
        }
    }

    function isNotAccessor(declaration: Declaration): boolean {
        // Accessors check for their own matching duplicates, and in contexts where they are valid, there are already duplicate identifier checks
        return !isAccessor(declaration);
    }

    function isNotOverload(declaration: Declaration): boolean {
        return (declaration.kind !== SyntaxKind.FunctionDeclaration
            && declaration.kind !== SyntaxKind.MethodDeclaration)
            || !!(declaration as FunctionDeclaration).body;
    }

    /** Like 'isDeclarationName', but returns true for LHS of `import { x as y }` or `export { x as y }`. */
    function isDeclarationNameOrImportPropertyName(name: Node): boolean {
        switch (name.parent.kind) {
            case SyntaxKind.ImportSpecifier:
            case SyntaxKind.ExportSpecifier:
                return isIdentifier(name);
            default:
                return isDeclarationName(name);
        }
    }

    function isSomeImportDeclaration(decl: Node): boolean {
        switch (decl.kind) {
            case SyntaxKind.ImportClause: // For default import
            case SyntaxKind.ImportEqualsDeclaration:
            case SyntaxKind.NamespaceImport:
            case SyntaxKind.ImportSpecifier: // For rename import `x as y`
                return true;
            case SyntaxKind.Identifier:
                // For regular import, `decl` is an Identifier under the ImportSpecifier.
                return decl.parent.kind === SyntaxKind.ImportSpecifier;
            default:
                return false;
        }
    }

    namespace JsxNames {
        export const JSX = 'JSX' as __String;
        export const IntrinsicElements = 'IntrinsicElements' as __String;
        export const ElementClass = 'ElementClass' as __String;
        export const ElementAttributesPropertyNameContainer = 'ElementAttributesProperty' as __String; // TODO: Deprecate and remove support
        export const ElementChildrenAttributeNameContainer = 'ElementChildrenAttribute' as __String;
        export const Element = 'Element' as __String;
        export const IntrinsicAttributes = 'IntrinsicAttributes' as __String;
        export const IntrinsicClassAttributes = 'IntrinsicClassAttributes' as __String;
        export const LibraryManagedAttributes = 'LibraryManagedAttributes' as __String;
    }

    function getIterationTypesKeyFromIterationTypeKind(
        typeKind: IterationTypeKind
    ) {
        switch (typeKind) {
            case IterationTypeKind.Yield:
                return 'yieldType';
            case IterationTypeKind.Return:
                return 'returnType';
            case IterationTypeKind.Next:
                return 'nextType';
        }
    }

    export function signatureHasRestParameter(s: Signature) {
        return !!(s.flags & SignatureFlags.HasRestParameter);
    }

    export function signatureHasLiteralTypes(s: Signature) {
        return !!(s.flags & SignatureFlags.HasLiteralTypes);
    }
}
