nalgebra/nalgebra-sparse/tests/unit_tests/csr.rs

762 lines
28 KiB
Rust

use nalgebra::DMatrix;
use nalgebra_sparse::csr::CsrMatrix;
use nalgebra_sparse::{SparseEntry, SparseEntryMut, SparseFormatErrorKind};
use proptest::prelude::*;
use proptest::sample::subsequence;
use super::test_data_examples::{InvalidCsDataExamples, ValidCsDataExamples};
use crate::assert_panics;
use crate::common::csr_strategy;
use std::collections::HashSet;
#[test]
fn csr_matrix_default() {
let matrix: CsrMatrix<f32> = CsrMatrix::default();
assert_eq!(matrix.nrows(), 0);
assert_eq!(matrix.ncols(), 0);
assert_eq!(matrix.nnz(), 0);
assert_eq!(matrix.values(), &[]);
assert!(matrix.get_entry(0, 0).is_none());
}
#[test]
fn csr_matrix_valid_data() {
// Construct matrix from valid data and check that selected methods return results
// that agree with expectations.
{
// A CSR matrix with zero explicitly stored entries
let offsets = vec![0, 0, 0, 0];
let indices = vec![];
let values = Vec::<i32>::new();
let mut matrix = CsrMatrix::try_from_csr_data(3, 2, offsets, indices, values).unwrap();
assert_eq!(matrix, CsrMatrix::zeros(3, 2));
assert_eq!(matrix.nrows(), 3);
assert_eq!(matrix.ncols(), 2);
assert_eq!(matrix.nnz(), 0);
assert_eq!(matrix.row_offsets(), &[0, 0, 0, 0]);
assert_eq!(matrix.col_indices(), &[]);
assert_eq!(matrix.values(), &[]);
assert!(matrix.triplet_iter().next().is_none());
assert!(matrix.triplet_iter_mut().next().is_none());
assert_eq!(matrix.row(0).ncols(), 2);
assert_eq!(matrix.row(0).nnz(), 0);
assert_eq!(matrix.row(0).col_indices(), &[]);
assert_eq!(matrix.row(0).values(), &[]);
assert_eq!(matrix.row_mut(0).ncols(), 2);
assert_eq!(matrix.row_mut(0).nnz(), 0);
assert_eq!(matrix.row_mut(0).col_indices(), &[]);
assert_eq!(matrix.row_mut(0).values(), &[]);
assert_eq!(matrix.row_mut(0).values_mut(), &[]);
assert_eq!(
matrix.row_mut(0).cols_and_values_mut(),
([].as_ref(), [].as_mut())
);
assert_eq!(matrix.row(1).ncols(), 2);
assert_eq!(matrix.row(1).nnz(), 0);
assert_eq!(matrix.row(1).col_indices(), &[]);
assert_eq!(matrix.row(1).values(), &[]);
assert_eq!(matrix.row_mut(1).ncols(), 2);
assert_eq!(matrix.row_mut(1).nnz(), 0);
assert_eq!(matrix.row_mut(1).col_indices(), &[]);
assert_eq!(matrix.row_mut(1).values(), &[]);
assert_eq!(matrix.row_mut(1).values_mut(), &[]);
assert_eq!(
matrix.row_mut(1).cols_and_values_mut(),
([].as_ref(), [].as_mut())
);
assert_eq!(matrix.row(2).ncols(), 2);
assert_eq!(matrix.row(2).nnz(), 0);
assert_eq!(matrix.row(2).col_indices(), &[]);
assert_eq!(matrix.row(2).values(), &[]);
assert_eq!(matrix.row_mut(2).ncols(), 2);
assert_eq!(matrix.row_mut(2).nnz(), 0);
assert_eq!(matrix.row_mut(2).col_indices(), &[]);
assert_eq!(matrix.row_mut(2).values(), &[]);
assert_eq!(matrix.row_mut(2).values_mut(), &[]);
assert_eq!(
matrix.row_mut(2).cols_and_values_mut(),
([].as_ref(), [].as_mut())
);
assert!(matrix.get_row(3).is_none());
assert!(matrix.get_row_mut(3).is_none());
let (offsets, indices, values) = matrix.disassemble();
assert_eq!(offsets, vec![0, 0, 0, 0]);
assert_eq!(indices, vec![]);
assert_eq!(values, vec![]);
}
{
// An arbitrary CSR matrix
let offsets = vec![0, 2, 2, 5];
let indices = vec![0, 5, 1, 2, 3];
let values = vec![0, 1, 2, 3, 4];
let mut matrix =
CsrMatrix::try_from_csr_data(3, 6, offsets.clone(), indices.clone(), values.clone())
.unwrap();
assert_eq!(matrix.nrows(), 3);
assert_eq!(matrix.ncols(), 6);
assert_eq!(matrix.nnz(), 5);
assert_eq!(matrix.row_offsets(), &[0, 2, 2, 5]);
assert_eq!(matrix.col_indices(), &[0, 5, 1, 2, 3]);
assert_eq!(matrix.values(), &[0, 1, 2, 3, 4]);
let expected_triplets = vec![(0, 0, 0), (0, 5, 1), (2, 1, 2), (2, 2, 3), (2, 3, 4)];
assert_eq!(
matrix
.triplet_iter()
.map(|(i, j, v)| (i, j, *v))
.collect::<Vec<_>>(),
expected_triplets
);
assert_eq!(
matrix
.triplet_iter_mut()
.map(|(i, j, v)| (i, j, *v))
.collect::<Vec<_>>(),
expected_triplets
);
assert_eq!(matrix.row(0).ncols(), 6);
assert_eq!(matrix.row(0).nnz(), 2);
assert_eq!(matrix.row(0).col_indices(), &[0, 5]);
assert_eq!(matrix.row(0).values(), &[0, 1]);
assert_eq!(matrix.row_mut(0).ncols(), 6);
assert_eq!(matrix.row_mut(0).nnz(), 2);
assert_eq!(matrix.row_mut(0).col_indices(), &[0, 5]);
assert_eq!(matrix.row_mut(0).values(), &[0, 1]);
assert_eq!(matrix.row_mut(0).values_mut(), &[0, 1]);
assert_eq!(
matrix.row_mut(0).cols_and_values_mut(),
([0, 5].as_ref(), [0, 1].as_mut())
);
assert_eq!(matrix.row(1).ncols(), 6);
assert_eq!(matrix.row(1).nnz(), 0);
assert_eq!(matrix.row(1).col_indices(), &[]);
assert_eq!(matrix.row(1).values(), &[]);
assert_eq!(matrix.row_mut(1).ncols(), 6);
assert_eq!(matrix.row_mut(1).nnz(), 0);
assert_eq!(matrix.row_mut(1).col_indices(), &[]);
assert_eq!(matrix.row_mut(1).values(), &[]);
assert_eq!(matrix.row_mut(1).values_mut(), &[]);
assert_eq!(
matrix.row_mut(1).cols_and_values_mut(),
([].as_ref(), [].as_mut())
);
assert_eq!(matrix.row(2).ncols(), 6);
assert_eq!(matrix.row(2).nnz(), 3);
assert_eq!(matrix.row(2).col_indices(), &[1, 2, 3]);
assert_eq!(matrix.row(2).values(), &[2, 3, 4]);
assert_eq!(matrix.row_mut(2).ncols(), 6);
assert_eq!(matrix.row_mut(2).nnz(), 3);
assert_eq!(matrix.row_mut(2).col_indices(), &[1, 2, 3]);
assert_eq!(matrix.row_mut(2).values(), &[2, 3, 4]);
assert_eq!(matrix.row_mut(2).values_mut(), &[2, 3, 4]);
assert_eq!(
matrix.row_mut(2).cols_and_values_mut(),
([1, 2, 3].as_ref(), [2, 3, 4].as_mut())
);
assert!(matrix.get_row(3).is_none());
assert!(matrix.get_row_mut(3).is_none());
let (offsets2, indices2, values2) = matrix.disassemble();
assert_eq!(offsets2, offsets);
assert_eq!(indices2, indices);
assert_eq!(values2, values);
}
}
#[test]
fn csr_matrix_valid_data_unsorted_column_indices() {
let valid_data: ValidCsDataExamples = ValidCsDataExamples::new();
let (offsets, indices, values) = valid_data.valid_unsorted_cs_data;
let csr = CsrMatrix::try_from_unsorted_csr_data(4, 5, offsets, indices, values).unwrap();
let (offsets2, indices2, values2) = valid_data.valid_cs_data;
let expected_csr = CsrMatrix::try_from_csr_data(4, 5, offsets2, indices2, values2).unwrap();
assert_eq!(csr, expected_csr);
}
#[test]
fn csr_matrix_try_from_invalid_csr_data() {
let invalid_data: InvalidCsDataExamples = InvalidCsDataExamples::new();
{
// Empty offset array (invalid length)
let (offsets, indices, values) = invalid_data.empty_offset_array;
let matrix = CsrMatrix::try_from_csr_data(0, 0, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Offset array invalid length for arbitrary data
let (offsets, indices, values) =
invalid_data.offset_array_invalid_length_for_arbitrary_data;
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Invalid first entry in offsets array
let (offsets, indices, values) = invalid_data.invalid_first_entry_in_offsets_array;
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Invalid last entry in offsets array
let (offsets, indices, values) = invalid_data.invalid_last_entry_in_offsets_array;
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Invalid length of offsets array
let (offsets, indices, values) = invalid_data.invalid_length_of_offsets_array;
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Nonmonotonic offsets
let (offsets, indices, values) = invalid_data.nonmonotonic_offsets;
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Nonmonotonic minor indices
let (offsets, indices, values) = invalid_data.nonmonotonic_minor_indices;
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Minor index out of bounds
let (offsets, indices, values) = invalid_data.minor_index_out_of_bounds;
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::IndexOutOfBounds
);
}
{
// Duplicate entry
let (offsets, indices, values) = invalid_data.duplicate_entry;
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::DuplicateEntry
);
}
}
#[test]
fn csr_matrix_try_from_unsorted_invalid_csr_data() {
let invalid_data: InvalidCsDataExamples = InvalidCsDataExamples::new();
{
// Empty offset array (invalid length)
let (offsets, indices, values) = invalid_data.empty_offset_array;
let matrix = CsrMatrix::try_from_unsorted_csr_data(0, 0, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Offset array invalid length for arbitrary data
let (offsets, indices, values) =
invalid_data.offset_array_invalid_length_for_arbitrary_data;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Invalid first entry in offsets array
let (offsets, indices, values) = invalid_data.invalid_first_entry_in_offsets_array;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Invalid last entry in offsets array
let (offsets, indices, values) = invalid_data.invalid_last_entry_in_offsets_array;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Invalid length of offsets array
let (offsets, indices, values) = invalid_data.invalid_length_of_offsets_array;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Nonmonotonic offsets
let (offsets, indices, values) = invalid_data.nonmonotonic_offsets;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
{
// Major offset out of bounds
let (offsets, indices, values) = invalid_data.major_offset_out_of_bounds;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::IndexOutOfBounds
);
}
{
// Minor index out of bounds
let (offsets, indices, values) = invalid_data.minor_index_out_of_bounds;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::IndexOutOfBounds
);
}
{
// Duplicate entry
let (offsets, indices, values) = invalid_data.duplicate_entry;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::DuplicateEntry
);
}
{
// Duplicate entry in unsorted lane
let (offsets, indices, values) = invalid_data.duplicate_entry_unsorted;
let matrix = CsrMatrix::try_from_unsorted_csr_data(3, 6, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::DuplicateEntry
);
}
{
// Wrong values length
let (offsets, indices, values) = invalid_data.wrong_values_length;
let matrix = CsrMatrix::try_from_unsorted_csr_data(6, 3, offsets, indices, values);
assert_eq!(
matrix.unwrap_err().kind(),
&SparseFormatErrorKind::InvalidStructure
);
}
}
#[test]
fn csr_disassemble_avoids_clone_when_owned() {
// Test that disassemble avoids cloning the sparsity pattern when it holds the sole reference
// to the pattern. We do so by checking that the pointer to the data is unchanged.
let offsets = vec![0, 2, 2, 5];
let indices = vec![0, 5, 1, 2, 3];
let values = vec![0, 1, 2, 3, 4];
let offsets_ptr = offsets.as_ptr();
let indices_ptr = indices.as_ptr();
let values_ptr = values.as_ptr();
let matrix = CsrMatrix::try_from_csr_data(3, 6, offsets, indices, values).unwrap();
let (offsets, indices, values) = matrix.disassemble();
assert_eq!(offsets.as_ptr(), offsets_ptr);
assert_eq!(indices.as_ptr(), indices_ptr);
assert_eq!(values.as_ptr(), values_ptr);
}
// Rustfmt makes this test much harder to read by expanding some of the one-liners to 4-liners,
// so for now we skip rustfmt...
#[rustfmt::skip]
#[test]
fn csr_matrix_get_index_entry() {
// Test .get_entry(_mut) and .index_entry(_mut) methods
#[rustfmt::skip]
let dense = DMatrix::from_row_slice(2, 3, &[
1, 0, 3,
0, 5, 6
]);
let csr = CsrMatrix::from(&dense);
assert_eq!(csr.get_entry(0, 0), Some(SparseEntry::NonZero(&1)));
assert_eq!(csr.index_entry(0, 0), SparseEntry::NonZero(&1));
assert_eq!(csr.get_entry(0, 1), Some(SparseEntry::Zero));
assert_eq!(csr.index_entry(0, 1), SparseEntry::Zero);
assert_eq!(csr.get_entry(0, 2), Some(SparseEntry::NonZero(&3)));
assert_eq!(csr.index_entry(0, 2), SparseEntry::NonZero(&3));
assert_eq!(csr.get_entry(1, 0), Some(SparseEntry::Zero));
assert_eq!(csr.index_entry(1, 0), SparseEntry::Zero);
assert_eq!(csr.get_entry(1, 1), Some(SparseEntry::NonZero(&5)));
assert_eq!(csr.index_entry(1, 1), SparseEntry::NonZero(&5));
assert_eq!(csr.get_entry(1, 2), Some(SparseEntry::NonZero(&6)));
assert_eq!(csr.index_entry(1, 2), SparseEntry::NonZero(&6));
// Check some out of bounds with .get_entry
assert_eq!(csr.get_entry(0, 3), None);
assert_eq!(csr.get_entry(0, 4), None);
assert_eq!(csr.get_entry(1, 3), None);
assert_eq!(csr.get_entry(1, 4), None);
assert_eq!(csr.get_entry(2, 0), None);
assert_eq!(csr.get_entry(2, 1), None);
assert_eq!(csr.get_entry(2, 2), None);
assert_eq!(csr.get_entry(2, 3), None);
assert_eq!(csr.get_entry(2, 4), None);
// Check that out of bounds with .index_entry panics
assert_panics!(csr.index_entry(0, 3));
assert_panics!(csr.index_entry(0, 4));
assert_panics!(csr.index_entry(1, 3));
assert_panics!(csr.index_entry(1, 4));
assert_panics!(csr.index_entry(2, 0));
assert_panics!(csr.index_entry(2, 1));
assert_panics!(csr.index_entry(2, 2));
assert_panics!(csr.index_entry(2, 3));
assert_panics!(csr.index_entry(2, 4));
{
// Check mutable versions of the above functions
let mut csr = csr;
assert_eq!(csr.get_entry_mut(0, 0), Some(SparseEntryMut::NonZero(&mut 1)));
assert_eq!(csr.index_entry_mut(0, 0), SparseEntryMut::NonZero(&mut 1));
assert_eq!(csr.get_entry_mut(0, 1), Some(SparseEntryMut::Zero));
assert_eq!(csr.index_entry_mut(0, 1), SparseEntryMut::Zero);
assert_eq!(csr.get_entry_mut(0, 2), Some(SparseEntryMut::NonZero(&mut 3)));
assert_eq!(csr.index_entry_mut(0, 2), SparseEntryMut::NonZero(&mut 3));
assert_eq!(csr.get_entry_mut(1, 0), Some(SparseEntryMut::Zero));
assert_eq!(csr.index_entry_mut(1, 0), SparseEntryMut::Zero);
assert_eq!(csr.get_entry_mut(1, 1), Some(SparseEntryMut::NonZero(&mut 5)));
assert_eq!(csr.index_entry_mut(1, 1), SparseEntryMut::NonZero(&mut 5));
assert_eq!(csr.get_entry_mut(1, 2), Some(SparseEntryMut::NonZero(&mut 6)));
assert_eq!(csr.index_entry_mut(1, 2), SparseEntryMut::NonZero(&mut 6));
// Check some out of bounds with .get_entry_mut
assert_eq!(csr.get_entry_mut(0, 3), None);
assert_eq!(csr.get_entry_mut(0, 4), None);
assert_eq!(csr.get_entry_mut(1, 3), None);
assert_eq!(csr.get_entry_mut(1, 4), None);
assert_eq!(csr.get_entry_mut(2, 0), None);
assert_eq!(csr.get_entry_mut(2, 1), None);
assert_eq!(csr.get_entry_mut(2, 2), None);
assert_eq!(csr.get_entry_mut(2, 3), None);
assert_eq!(csr.get_entry_mut(2, 4), None);
// Check that out of bounds with .index_entry_mut panics
// Note: the cloning is necessary because a mutable reference is not UnwindSafe
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(0, 3); });
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(0, 4); });
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(1, 3); });
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(1, 4); });
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(2, 0); });
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(2, 1); });
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(2, 2); });
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(2, 3); });
assert_panics!({ let mut csr = csr.clone(); csr.index_entry_mut(2, 4); });
}
}
#[test]
fn csr_upper_triangle_solve_ok() {
const N: usize = 10;
let eye = CsrMatrix::<f32>::identity(N);
let b = DMatrix::from_row_slice(N, 1, &[0.5; N]);
assert_eq!(eye.solve_upper_triangular(&b), Some(b));
let mut eye = CsrMatrix::<f32>::identity(N);
let v = if let SparseEntryMut::NonZero(v) = eye.index_entry_mut(0, 0) {
v
} else {
unreachable!();
};
*v = 2.0;
let b = DMatrix::from_row_slice(N, 1, &[1.0; N]);
let mut x = b.clone();
x[0] = 0.5;
assert_eq!(eye.solve_upper_triangular(&b), Some(x));
#[rustfmt::skip]
let dense = DMatrix::from_row_slice(3, 3, &[
1., 1., 1.,
0., 1., 1.,
0., 0., 1.,
]);
let csr = CsrMatrix::from(&dense);
let b = DMatrix::from_row_slice(3, 1, &[1.0; 3]);
let x = DMatrix::from_row_slice(3, 1, &[-1., 0., 1.]);
assert_eq!(csr.solve_upper_triangular(&b), Some(x));
}
#[test]
fn csr_matrix_row_iter() {
#[rustfmt::skip]
let dense = DMatrix::from_row_slice(3, 4, &[
0, 1, 2, 0,
3, 0, 0, 0,
0, 4, 0, 5
]);
let csr = CsrMatrix::from(&dense);
// Immutable iterator
{
let mut row_iter = csr.row_iter();
{
let row = row_iter.next().unwrap();
assert_eq!(row.ncols(), 4);
assert_eq!(row.nnz(), 2);
assert_eq!(row.col_indices(), &[1, 2]);
assert_eq!(row.values(), &[1, 2]);
assert_eq!(row.get_entry(0), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(1), Some(SparseEntry::NonZero(&1)));
assert_eq!(row.get_entry(2), Some(SparseEntry::NonZero(&2)));
assert_eq!(row.get_entry(3), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(4), None);
}
{
let row = row_iter.next().unwrap();
assert_eq!(row.ncols(), 4);
assert_eq!(row.nnz(), 1);
assert_eq!(row.col_indices(), &[0]);
assert_eq!(row.values(), &[3]);
assert_eq!(row.get_entry(0), Some(SparseEntry::NonZero(&3)));
assert_eq!(row.get_entry(1), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(2), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(3), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(4), None);
}
{
let row = row_iter.next().unwrap();
assert_eq!(row.ncols(), 4);
assert_eq!(row.nnz(), 2);
assert_eq!(row.col_indices(), &[1, 3]);
assert_eq!(row.values(), &[4, 5]);
assert_eq!(row.get_entry(0), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(1), Some(SparseEntry::NonZero(&4)));
assert_eq!(row.get_entry(2), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(3), Some(SparseEntry::NonZero(&5)));
assert_eq!(row.get_entry(4), None);
}
assert!(row_iter.next().is_none());
}
// Mutable iterator
{
let mut csr = csr;
let mut row_iter = csr.row_iter_mut();
{
let mut row = row_iter.next().unwrap();
assert_eq!(row.ncols(), 4);
assert_eq!(row.nnz(), 2);
assert_eq!(row.col_indices(), &[1, 2]);
assert_eq!(row.values(), &[1, 2]);
assert_eq!(row.get_entry(0), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(1), Some(SparseEntry::NonZero(&1)));
assert_eq!(row.get_entry(2), Some(SparseEntry::NonZero(&2)));
assert_eq!(row.get_entry(3), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(4), None);
assert_eq!(row.values_mut(), &mut [1, 2]);
assert_eq!(
row.cols_and_values_mut(),
([1, 2].as_ref(), [1, 2].as_mut())
);
assert_eq!(row.get_entry_mut(0), Some(SparseEntryMut::Zero));
assert_eq!(row.get_entry_mut(1), Some(SparseEntryMut::NonZero(&mut 1)));
assert_eq!(row.get_entry_mut(2), Some(SparseEntryMut::NonZero(&mut 2)));
assert_eq!(row.get_entry_mut(3), Some(SparseEntryMut::Zero));
assert_eq!(row.get_entry_mut(4), None);
}
{
let mut row = row_iter.next().unwrap();
assert_eq!(row.ncols(), 4);
assert_eq!(row.nnz(), 1);
assert_eq!(row.col_indices(), &[0]);
assert_eq!(row.values(), &[3]);
assert_eq!(row.get_entry(0), Some(SparseEntry::NonZero(&3)));
assert_eq!(row.get_entry(1), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(2), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(3), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(4), None);
assert_eq!(row.values_mut(), &mut [3]);
assert_eq!(row.cols_and_values_mut(), ([0].as_ref(), [3].as_mut()));
assert_eq!(row.get_entry_mut(0), Some(SparseEntryMut::NonZero(&mut 3)));
assert_eq!(row.get_entry_mut(1), Some(SparseEntryMut::Zero));
assert_eq!(row.get_entry_mut(2), Some(SparseEntryMut::Zero));
assert_eq!(row.get_entry_mut(3), Some(SparseEntryMut::Zero));
assert_eq!(row.get_entry_mut(4), None);
}
{
let mut row = row_iter.next().unwrap();
assert_eq!(row.ncols(), 4);
assert_eq!(row.nnz(), 2);
assert_eq!(row.col_indices(), &[1, 3]);
assert_eq!(row.values(), &[4, 5]);
assert_eq!(row.get_entry(0), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(1), Some(SparseEntry::NonZero(&4)));
assert_eq!(row.get_entry(2), Some(SparseEntry::Zero));
assert_eq!(row.get_entry(3), Some(SparseEntry::NonZero(&5)));
assert_eq!(row.get_entry(4), None);
assert_eq!(row.values_mut(), &mut [4, 5]);
assert_eq!(
row.cols_and_values_mut(),
([1, 3].as_ref(), [4, 5].as_mut())
);
assert_eq!(row.get_entry_mut(0), Some(SparseEntryMut::Zero));
assert_eq!(row.get_entry_mut(1), Some(SparseEntryMut::NonZero(&mut 4)));
assert_eq!(row.get_entry_mut(2), Some(SparseEntryMut::Zero));
assert_eq!(row.get_entry_mut(3), Some(SparseEntryMut::NonZero(&mut 5)));
assert_eq!(row.get_entry_mut(4), None);
}
assert!(row_iter.next().is_none());
}
}
proptest! {
#[test]
fn csr_double_transpose_is_identity(csr in csr_strategy()) {
prop_assert_eq!(csr.transpose().transpose(), csr);
}
#[test]
fn csr_transpose_agrees_with_dense(csr in csr_strategy()) {
let dense_transpose = DMatrix::from(&csr).transpose();
let csr_transpose = csr.transpose();
prop_assert_eq!(dense_transpose, DMatrix::from(&csr_transpose));
prop_assert_eq!(csr.nnz(), csr_transpose.nnz());
}
#[test]
fn csr_filter(
(csr, triplet_subset)
in csr_strategy()
.prop_flat_map(|matrix| {
let triplets: Vec<_> = matrix.triplet_iter().cloned_values().collect();
let subset = subsequence(triplets, 0 ..= matrix.nnz())
.prop_map(|triplet_subset| {
let set: HashSet<_> = triplet_subset.into_iter().collect();
set
});
(Just(matrix), subset)
}))
{
// We generate a CsrMatrix and a HashSet corresponding to a subset of the (i, j, v)
// values in the matrix, which we use for filtering the matrix entries.
// The resulting triplets in the filtered matrix must then be exactly equal to
// the subset.
let filtered = csr.filter(|i, j, v| triplet_subset.contains(&(i, j, *v)));
let filtered_triplets: HashSet<_> = filtered
.triplet_iter()
.cloned_values()
.collect();
prop_assert_eq!(filtered_triplets, triplet_subset);
}
#[test]
fn csr_lower_triangle_agrees_with_dense(csr in csr_strategy()) {
let csr_lower_triangle = csr.lower_triangle();
prop_assert_eq!(DMatrix::from(&csr_lower_triangle), DMatrix::from(&csr).lower_triangle());
prop_assert!(csr_lower_triangle.nnz() <= csr.nnz());
}
#[test]
fn csr_upper_triangle_agrees_with_dense(csr in csr_strategy()) {
let csr_upper_triangle = csr.upper_triangle();
prop_assert_eq!(DMatrix::from(&csr_upper_triangle), DMatrix::from(&csr).upper_triangle());
prop_assert!(csr_upper_triangle.nnz() <= csr.nnz());
}
#[test]
fn csr_diagonal_as_csr(csr in csr_strategy()) {
let d = csr.diagonal_as_csr();
let d_entries: HashSet<_> = d.triplet_iter().cloned_values().collect();
let csr_diagonal_entries: HashSet<_> = csr
.triplet_iter()
.cloned_values()
.filter(|&(i, j, _)| i == j)
.collect();
prop_assert_eq!(d_entries, csr_diagonal_entries);
}
#[test]
fn csr_identity(n in 0 ..= 6usize) {
let csr = CsrMatrix::<i32>::identity(n);
prop_assert_eq!(csr.nnz(), n);
prop_assert_eq!(DMatrix::from(&csr), DMatrix::identity(n, n));
}
}