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use ndarray::prelude::*;
use num_traits::float::Float;
use matrix::Matrix;
use scalar::LapackScalar;
use error::{LinalgError, NotSquareError};
pub trait SquareMatrix: Matrix {
fn eigh(self) -> Result<(Self::Vector, Self), LinalgError>;
fn inv(self) -> Result<Self, LinalgError>;
fn trace(&self) -> Result<Self::Scalar, LinalgError>;
fn ssqrt(self) -> Result<Self, LinalgError>;
fn check_square(&self) -> Result<(), NotSquareError> {
let (rows, cols) = self.size();
if rows == cols {
Ok(())
} else {
Err(NotSquareError {
rows: rows,
cols: cols,
})
}
}
}
impl<A: LapackScalar + Float> SquareMatrix for Array<A, (Ix, Ix)> {
fn eigh(self) -> Result<(Self::Vector, Self), LinalgError> {
try!(self.check_square());
let (rows, cols) = self.size();
let (w, a) = try!(LapackScalar::eigh(rows, self.into_raw_vec()));
let ea = Array::from_vec(w);
let va = Array::from_vec(a).into_shape((rows, cols)).unwrap().reversed_axes();
Ok((ea, va))
}
fn inv(self) -> Result<Self, LinalgError> {
try!(self.check_square());
let (n, _) = self.size();
let is_fortran_align = self.strides()[0] > self.strides()[1];
let a = try!(LapackScalar::inv(n, self.into_raw_vec()));
let m = Array::from_vec(a).into_shape((n, n)).unwrap();
if is_fortran_align {
Ok(m)
} else {
Ok(m.reversed_axes())
}
}
fn ssqrt(self) -> Result<Self, LinalgError> {
let (n, _) = self.size();
let (e, v) = try!(self.eigh());
let mut res = Array::zeros((n, n));
for i in 0..n {
for j in 0..n {
res[(i, j)] = e[i].sqrt() * v[(j, i)];
}
}
Ok(v.dot(&res))
}
fn trace(&self) -> Result<Self::Scalar, LinalgError> {
try!(self.check_square());
let (n, _) = self.size();
Ok((0..n).fold(A::zero(), |sum, i| sum + self[(i, i)]))
}
}