faer 0.24.0

linear algebra library
Documentation 
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use crate::assert;
use crate::internal_prelude::*;
use linalg::matmul::triangular::BlockStructure;
pub fn inverse_scratch<I: Index, T: ComplexField>(
	dim: usize,
	par: Par,
) -> StackReq {
	_ = par;
	temp_mat_scratch::<T>(dim, dim)
}
#[track_caller]
pub fn inverse<I: Index, T: ComplexField>(
	out: MatMut<'_, T>,
	L: MatRef<'_, T>,
	perm: PermRef<'_, I>,
	par: Par,
	stack: &mut MemStack,
) {
	let mut out = out;
	let n = out.nrows();
	assert!(all(
		out.nrows() == n,
		out.ncols() == n,
		L.nrows() == n,
		L.ncols() == n,
	));
	let (mut tmp, _) = unsafe { temp_mat_uninit::<T, _, _>(n, n, stack) };
	let mut tmp = tmp.as_mat_mut();
	linalg::triangular_inverse::invert_lower_triangular(out.rb_mut(), L, par);
	let L_inv = out.rb();
	linalg::matmul::triangular::matmul(
		tmp.rb_mut(),
		BlockStructure::TriangularLower,
		Accum::Replace,
		L_inv.adjoint(),
		BlockStructure::TriangularUpper,
		L_inv,
		BlockStructure::TriangularLower,
		one(),
		par,
	);
	let p = perm.arrays().1;
	for j in 0..n {
		let jj = p[j].zx();
		for i in j..n {
			let ii = p[i].zx();
			if ii >= jj {
				out[(i, j)] = tmp[(ii, jj)].copy();
			} else {
				out[(i, j)] = tmp[(jj, ii)].conj();
			}
		}
	}
}
#[cfg(test)]
mod tests {
	use super::*;
	use crate::assert;
	use crate::stats::prelude::*;
	use crate::utils::approx::*;
	use dyn_stack::MemBuffer;
	use linalg::cholesky::llt_pivoting::*;
	#[test]
	fn test_inverse() {
		let rng = &mut StdRng::seed_from_u64(0);
		let n = 50;
		let A = CwiseMatDistribution {
			nrows: n,
			ncols: n,
			dist: ComplexDistribution::new(StandardNormal, StandardNormal),
		}
		.rand::<Mat<c64>>(rng);
		let A = &A * A.adjoint();
		let mut L = A.to_owned();
		let perm_fwd = &mut *vec![0usize; n];
		let perm_bwd = &mut *vec![0usize; n];
		let (_, perm) = factor::cholesky_in_place(
			L.as_mut(),
			perm_fwd,
			perm_bwd,
			Par::Seq,
			MemStack::new(&mut {
				MemBuffer::new(factor::cholesky_in_place_scratch::<usize, c64>(
					n,
					Par::Seq,
					default(),
				))
			}),
			default(),
		)
		.unwrap();
		let approx_eq = CwiseMat(ApproxEq::eps() * (n as f64));
		let mut A_inv = Mat::zeros(n, n);
		inverse::inverse(
			A_inv.as_mut(),
			L.as_ref(),
			perm,
			Par::Seq,
			MemStack::new(&mut MemBuffer::new(inverse::inverse_scratch::<
				usize,
				c64,
			>(n, Par::Seq))),
		);
		for j in 0..n {
			for i in 0..j {
				A_inv[(i, j)] = A_inv[(j, i)].conj();
			}
		}
		assert!(A_inv * A ~ Mat::identity(n, n));
	}
}