nalgebra/nalgebra-sparse/src/factorization/cholesky.rs

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// TODO: Remove this allowance
#![allow(missing_docs)]
use crate::pattern::SparsityPattern;
use crate::csc::CscMatrix;
use core::{mem, iter};
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use nalgebra::{Scalar, RealField};
use std::sync::Arc;
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use std::fmt::{Display, Formatter};
pub struct CscSymbolicCholesky {
// Pattern of the original matrix that was decomposed
m_pattern: Arc<SparsityPattern>,
l_pattern: SparsityPattern,
// u in this context is L^T, so that M = L L^T
u_pattern: SparsityPattern
}
impl CscSymbolicCholesky {
pub fn factor(pattern: &Arc<SparsityPattern>) -> Self {
assert_eq!(pattern.major_dim(), pattern.minor_dim(),
"Major and minor dimensions must be the same (square matrix).");
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let (l_pattern, u_pattern) = nonzero_pattern(&*pattern);
Self {
m_pattern: Arc::clone(pattern),
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l_pattern,
u_pattern,
}
}
pub fn l_pattern(&self) -> &SparsityPattern {
&self.l_pattern
}
}
pub struct CscCholesky<T> {
// Pattern of the original matrix
m_pattern: Arc<SparsityPattern>,
l_factor: CscMatrix<T>,
u_pattern: SparsityPattern,
work_x: Vec<T>,
work_c: Vec<usize>
}
#[derive(Debug, PartialEq, Eq, Clone)]
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#[non_exhaustive]
pub enum CholeskyError {
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/// The matrix is not positive definite.
NotPositiveDefinite,
}
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impl Display for CholeskyError {
fn fmt(&self, f: &mut Formatter<'_>) -> std::fmt::Result {
write!(f, "Matrix is not positive definite")
}
}
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impl std::error::Error for CholeskyError {}
impl<T: RealField> CscCholesky<T> {
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pub fn factor_numerical(symbolic: CscSymbolicCholesky, values: &[T]) -> Result<Self, CholeskyError> {
assert_eq!(symbolic.l_pattern.nnz(), symbolic.u_pattern.nnz(),
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"u is just the transpose of l, so should have the same nnz");
let l_nnz = symbolic.l_pattern.nnz();
let l_values = vec![T::zero(); l_nnz];
let l_factor = CscMatrix::try_from_pattern_and_values(Arc::new(symbolic.l_pattern), l_values)
.unwrap();
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let (nrows, ncols) = (l_factor.nrows(), l_factor.ncols());
let mut factorization = CscCholesky {
m_pattern: symbolic.m_pattern,
l_factor,
u_pattern: symbolic.u_pattern,
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work_x: vec![T::zero(); nrows],
// Fill with MAX so that things hopefully totally fail if values are not
// overwritten. Might be easier to debug this way
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work_c: vec![usize::MAX, ncols],
};
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factorization.refactor(values)?;
Ok(factorization)
}
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pub fn factor(matrix: &CscMatrix<T>) -> Result<Self, CholeskyError> {
let symbolic = CscSymbolicCholesky::factor(&*matrix.pattern());
Self::factor_numerical(symbolic, matrix.values())
}
pub fn refactor(&mut self, values: &[T]) -> Result<(), CholeskyError> {
self.decompose_left_looking(values)
}
pub fn l(&self) -> &CscMatrix<T> {
&self.l_factor
}
pub fn take_l(self) -> CscMatrix<T> {
self.l_factor
}
/// Perform a numerical left-looking cholesky decomposition of a matrix with the same structure as the
/// one used to initialize `self`, but with different non-zero values provided by `values`.
fn decompose_left_looking(&mut self, values: &[T]) -> Result<(), CholeskyError> {
assert!(
values.len() >= self.m_pattern.nnz(),
// TODO: Improve error message
"The set of values is too small."
);
let n = self.l_factor.nrows();
// Reset `work_c` to the column pointers of `l`.
self.work_c.clear();
self.work_c.extend_from_slice(self.l_factor.col_offsets());
unsafe {
for k in 0..n {
// Scatter the k-th column of the original matrix with the values provided.
let range_begin = *self.m_pattern.major_offsets().get_unchecked(k);
let range_end = *self.m_pattern.major_offsets().get_unchecked(k + 1);
let range_k = range_begin..range_end;
*self.work_x.get_unchecked_mut(k) = T::zero();
for p in range_k.clone() {
let irow = *self.m_pattern.minor_indices().get_unchecked(p);
if irow >= k {
*self.work_x.get_unchecked_mut(irow) = *values.get_unchecked(p);
}
}
for &j in self.u_pattern.lane(k) {
let factor = -*self
.l_factor
.values()
.get_unchecked(*self.work_c.get_unchecked(j));
*self.work_c.get_unchecked_mut(j) += 1;
if j < k {
let col_j = self.l_factor.col(j);
let col_j_entries = col_j.row_indices().iter().zip(col_j.values());
for (&z, val) in col_j_entries {
if z >= k {
*self.work_x.get_unchecked_mut(z) += val.inlined_clone() * factor;
}
}
}
}
let diag = *self.work_x.get_unchecked(k);
if diag > T::zero() {
let denom = diag.sqrt();
{
let (offsets, _, values) = self.l_factor.csc_data_mut();
*values
.get_unchecked_mut(*offsets.get_unchecked(k)) = denom;
}
let mut col_k = self.l_factor.col_mut(k);
let (col_k_rows, col_k_values) = col_k.rows_and_values_mut();
let col_k_entries = col_k_rows.iter().zip(col_k_values);
for (&p, val) in col_k_entries {
*val = *self.work_x.get_unchecked(p) / denom;
*self.work_x.get_unchecked_mut(p) = T::zero();
}
} else {
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return Err(CholeskyError::NotPositiveDefinite);
}
}
}
Ok(())
}
}
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fn reach(
pattern: &SparsityPattern,
j: usize,
max_j: usize,
tree: &[usize],
marks: &mut Vec<bool>,
out: &mut Vec<usize>,
) {
marks.clear();
marks.resize(tree.len(), false);
// TODO: avoid all those allocations.
let mut tmp = Vec::new();
let mut res = Vec::new();
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for &irow in pattern.lane(j) {
let mut curr = irow;
while curr != usize::max_value() && curr <= max_j && !marks[curr] {
marks[curr] = true;
tmp.push(curr);
curr = tree[curr];
}
tmp.append(&mut res);
mem::swap(&mut tmp, &mut res);
}
res.sort_unstable();
out.append(&mut res);
}
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fn nonzero_pattern(m: &SparsityPattern) -> (SparsityPattern, SparsityPattern) {
let etree = elimination_tree(m);
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// Note: We assume CSC, therefore rows == minor and cols == major
let (nrows, ncols) = (m.minor_dim(), m.major_dim());
let mut rows = Vec::with_capacity(m.nnz());
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let mut col_offsets = Vec::with_capacity(ncols + 1);
let mut marks = Vec::new();
// NOTE: the following will actually compute the non-zero pattern of
// the transpose of l.
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col_offsets.push(0);
for i in 0..nrows {
reach(m, i, i, &etree, &mut marks, &mut rows);
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col_offsets.push(rows.len());
}
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let u_pattern = SparsityPattern::try_from_offsets_and_indices(nrows, ncols, col_offsets, rows)
.unwrap();
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// TODO: Avoid this transpose?
let l_pattern = u_pattern.transpose();
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(l_pattern, u_pattern)
}
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fn elimination_tree(pattern: &SparsityPattern) -> Vec<usize> {
// Note: The pattern is assumed to of a CSC matrix, so the number of rows is
// given by the minor dimension
let nrows = pattern.minor_dim();
let mut forest: Vec<_> = iter::repeat(usize::max_value()).take(nrows).collect();
let mut ancestor: Vec<_> = iter::repeat(usize::max_value()).take(nrows).collect();
for k in 0..nrows {
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for &irow in pattern.lane(k) {
let mut i = irow;
while i < k {
let i_ancestor = ancestor[i];
ancestor[i] = k;
if i_ancestor == usize::max_value() {
forest[i] = k;
break;
}
i = i_ancestor;
}
}
}
forest
}