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

use nalgebra_sparse::csc::CscMatrix;
use nalgebra_sparse::SparseFormatErrorKind;
use nalgebra::DMatrix;

use proptest::prelude::*;
use proptest::sample::subsequence;

use crate::common::csc_strategy;

use std::collections::HashSet;

#[test]
fn csc_matrix_valid_data() {
    // Construct matrix from valid data and check that selected methods return results
    // that agree with expectations.

    {
        // A CSC matrix with zero explicitly stored entries
        let offsets = vec![0, 0, 0, 0];
        let indices = vec![];
        let values = Vec::<i32>::new();
        let mut matrix = CscMatrix::try_from_csc_data(2, 3, offsets, indices, values).unwrap();

        assert_eq!(matrix, CscMatrix::zeros(2, 3));

        assert_eq!(matrix.nrows(), 2);
        assert_eq!(matrix.ncols(), 3);
        assert_eq!(matrix.nnz(), 0);
        assert_eq!(matrix.col_offsets(), &[0, 0, 0, 0]);
        assert_eq!(matrix.row_indices(), &[]);
        assert_eq!(matrix.values(), &[]);

        assert!(matrix.triplet_iter().next().is_none());
        assert!(matrix.triplet_iter_mut().next().is_none());

        assert_eq!(matrix.col(0).nrows(), 2);
        assert_eq!(matrix.col(0).nnz(), 0);
        assert_eq!(matrix.col(0).row_indices(), &[]);
        assert_eq!(matrix.col(0).values(), &[]);
        assert_eq!(matrix.col_mut(0).nrows(), 2);
        assert_eq!(matrix.col_mut(0).nnz(), 0);
        assert_eq!(matrix.col_mut(0).row_indices(), &[]);
        assert_eq!(matrix.col_mut(0).values(), &[]);
        assert_eq!(matrix.col_mut(0).values_mut(), &[]);
        assert_eq!(matrix.col_mut(0).rows_and_values_mut(), ([].as_ref(), [].as_mut()));

        assert_eq!(matrix.col(1).nrows(), 2);
        assert_eq!(matrix.col(1).nnz(), 0);
        assert_eq!(matrix.col(1).row_indices(), &[]);
        assert_eq!(matrix.col(1).values(), &[]);
        assert_eq!(matrix.col_mut(1).nrows(), 2);
        assert_eq!(matrix.col_mut(1).nnz(), 0);
        assert_eq!(matrix.col_mut(1).row_indices(), &[]);
        assert_eq!(matrix.col_mut(1).values(), &[]);
        assert_eq!(matrix.col_mut(1).values_mut(), &[]);
        assert_eq!(matrix.col_mut(1).rows_and_values_mut(), ([].as_ref(), [].as_mut()));

        assert_eq!(matrix.col(2).nrows(), 2);
        assert_eq!(matrix.col(2).nnz(), 0);
        assert_eq!(matrix.col(2).row_indices(), &[]);
        assert_eq!(matrix.col(2).values(), &[]);
        assert_eq!(matrix.col_mut(2).nrows(), 2);
        assert_eq!(matrix.col_mut(2).nnz(), 0);
        assert_eq!(matrix.col_mut(2).row_indices(), &[]);
        assert_eq!(matrix.col_mut(2).values(), &[]);
        assert_eq!(matrix.col_mut(2).values_mut(), &[]);
        assert_eq!(matrix.col_mut(2).rows_and_values_mut(), ([].as_ref(), [].as_mut()));

        assert!(matrix.get_col(3).is_none());
        assert!(matrix.get_col_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 CSC 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 = CscMatrix::try_from_csc_data(6,
                                                      3,
                                                      offsets.clone(),
                                                      indices.clone(),
                                                      values.clone()).unwrap();

        assert_eq!(matrix.nrows(), 6);
        assert_eq!(matrix.ncols(), 3);
        assert_eq!(matrix.nnz(), 5);
        assert_eq!(matrix.col_offsets(), &[0, 2, 2, 5]);
        assert_eq!(matrix.row_indices(), &[0, 5, 1, 2, 3]);
        assert_eq!(matrix.values(), &[0, 1, 2, 3, 4]);

        let expected_triplets = vec![(0, 0, 0), (5, 0, 1), (1, 2, 2), (2, 2, 3), (3, 2, 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.col(0).nrows(), 6);
        assert_eq!(matrix.col(0).nnz(), 2);
        assert_eq!(matrix.col(0).row_indices(), &[0, 5]);
        assert_eq!(matrix.col(0).values(), &[0, 1]);
        assert_eq!(matrix.col_mut(0).nrows(), 6);
        assert_eq!(matrix.col_mut(0).nnz(), 2);
        assert_eq!(matrix.col_mut(0).row_indices(), &[0, 5]);
        assert_eq!(matrix.col_mut(0).values(), &[0, 1]);
        assert_eq!(matrix.col_mut(0).values_mut(), &[0, 1]);
        assert_eq!(matrix.col_mut(0).rows_and_values_mut(), ([0, 5].as_ref(), [0, 1].as_mut()));

        assert_eq!(matrix.col(1).nrows(), 6);
        assert_eq!(matrix.col(1).nnz(), 0);
        assert_eq!(matrix.col(1).row_indices(), &[]);
        assert_eq!(matrix.col(1).values(), &[]);
        assert_eq!(matrix.col_mut(1).nrows(), 6);
        assert_eq!(matrix.col_mut(1).nnz(), 0);
        assert_eq!(matrix.col_mut(1).row_indices(), &[]);
        assert_eq!(matrix.col_mut(1).values(), &[]);
        assert_eq!(matrix.col_mut(1).values_mut(), &[]);
        assert_eq!(matrix.col_mut(1).rows_and_values_mut(), ([].as_ref(), [].as_mut()));

        assert_eq!(matrix.col(2).nrows(), 6);
        assert_eq!(matrix.col(2).nnz(), 3);
        assert_eq!(matrix.col(2).row_indices(), &[1, 2, 3]);
        assert_eq!(matrix.col(2).values(), &[2, 3, 4]);
        assert_eq!(matrix.col_mut(2).nrows(), 6);
        assert_eq!(matrix.col_mut(2).nnz(), 3);
        assert_eq!(matrix.col_mut(2).row_indices(), &[1, 2, 3]);
        assert_eq!(matrix.col_mut(2).values(), &[2, 3, 4]);
        assert_eq!(matrix.col_mut(2).values_mut(), &[2, 3, 4]);
        assert_eq!(matrix.col_mut(2).rows_and_values_mut(), ([1, 2, 3].as_ref(), [2, 3, 4].as_mut()));

        assert!(matrix.get_col(3).is_none());
        assert!(matrix.get_col_mut(3).is_none());

        let (offsets2, indices2, values2) = matrix.disassemble();

        assert_eq!(offsets2, offsets);
        assert_eq!(indices2, indices);
        assert_eq!(values2, values);
    }
}

#[test]
fn csc_matrix_try_from_invalid_csc_data() {

    {
        // Empty offset array (invalid length)
        let matrix = CscMatrix::try_from_csc_data(0, 0, Vec::new(), Vec::new(), Vec::<u32>::new());
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);
    }

    {
        // Offset array invalid length for arbitrary data
        let offsets = vec![0, 3, 5];
        let indices = vec![0, 1, 2, 3, 5];
        let values = vec![0, 1, 2, 3, 4];

        let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);
    }

    {
        // Invalid first entry in offsets array
        let offsets = vec![1, 2, 2, 5];
        let indices = vec![0, 5, 1, 2, 3];
        let values = vec![0, 1, 2, 3, 4];
        let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);
    }

    {
        // Invalid last entry in offsets array
        let offsets = vec![0, 2, 2, 4];
        let indices = vec![0, 5, 1, 2, 3];
        let values = vec![0, 1, 2, 3, 4];
        let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);
    }

    {
        // Invalid length of offsets array
        let offsets = vec![0, 2, 2];
        let indices = vec![0, 5, 1, 2, 3];
        let values = vec![0, 1, 2, 3, 4];
        let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);
    }

    {
        // Nonmonotonic offsets
        let offsets = vec![0, 3, 2, 5];
        let indices = vec![0, 1, 2, 3, 4];
        let values = vec![0, 1, 2, 3, 4];
        let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);
    }

    {
        // Nonmonotonic minor indices
        let offsets = vec![0, 2, 2, 5];
        let indices = vec![0, 2, 3, 1, 4];
        let values = vec![0, 1, 2, 3, 4];
        let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);
    }

    {
        // Minor index out of bounds
        let offsets = vec![0, 2, 2, 5];
        let indices = vec![0, 6, 1, 2, 3];
        let values = vec![0, 1, 2, 3, 4];
        let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::IndexOutOfBounds);
    }

    {
        // Duplicate entry
        let offsets = vec![0, 2, 2, 5];
        let indices = vec![0, 5, 2, 2, 3];
        let values = vec![0, 1, 2, 3, 4];
        let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);
        assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::DuplicateEntry);
    }

}

#[test]
fn csc_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 = CscMatrix::try_from_csc_data(6,
                                              3,
                                              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);
}

#[test]
fn csc_matrix_get_index() {
    // TODO: Implement tests for ::get() and index()
}

#[test]
fn csc_matrix_col_iter() {
    // TODO
}

proptest! {
    #[test]
    fn csc_double_transpose_is_identity(csc in csc_strategy()) {
        prop_assert_eq!(csc.transpose().transpose(), csc);
    }

    #[test]
    fn csc_transpose_agrees_with_dense(csc in csc_strategy()) {
        let dense_transpose = DMatrix::from(&csc).transpose();
        let csc_transpose = csc.transpose();
        prop_assert_eq!(dense_transpose, DMatrix::from(&csc_transpose));
        prop_assert_eq!(csc.nnz(), csc_transpose.nnz());
    }

    #[test]
    fn csc_filter(
        (csc, triplet_subset)
        in csc_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 CscMatrix 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 = csc.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 csc_lower_triangle_agrees_with_dense(csc in csc_strategy()) {
        let csc_lower_triangle = csc.lower_triangle();
        prop_assert_eq!(DMatrix::from(&csc_lower_triangle), DMatrix::from(&csc).lower_triangle());
        prop_assert!(csc_lower_triangle.nnz() <= csc.nnz());
    }

    #[test]
    fn csc_upper_triangle_agrees_with_dense(csc in csc_strategy()) {
        let csc_upper_triangle = csc.upper_triangle();
        prop_assert_eq!(DMatrix::from(&csc_upper_triangle), DMatrix::from(&csc).upper_triangle());
        prop_assert!(csc_upper_triangle.nnz() <= csc.nnz());
    }

    #[test]
    fn csc_diagonal_as_csc(csc in csc_strategy()) {
        let d = csc.diagonal_as_csc();
        let d_entries: HashSet<_> = d.triplet_iter().cloned_values().collect();
        let csc_diagonal_entries: HashSet<_> = csc
            .triplet_iter()
            .cloned_values()
            .filter(|&(i, j, _)| i == j)
            .collect();

        prop_assert_eq!(d_entries, csc_diagonal_entries);
    }
}
Implement CSC matrix basic API The CSC matrix API mirrors the CSR matrix API. However, there are subtle differences throughout (both in the available methods and the implementation) that I believe makes any attempt to avoid the duplicate effort futile. 2020-09-28 17:36:00 +08:00			`use nalgebra_sparse::csc::CscMatrix;`
			`use nalgebra_sparse::SparseFormatErrorKind;`
Implement Csr/CscMatrix::transpose() 2020-12-09 21:42:31 +08:00			`use nalgebra::DMatrix;`

			`use proptest::prelude::*;`
Implement CsrMatrix/CscMatrix::filter and associated helpers Includes ::lower_triangle(), ::upper_triangle() and ::diagonal_matrix(). 2021-01-15 00:12:08 +08:00			`use proptest::sample::subsequence;`
Implement Csr/CscMatrix::transpose() 2020-12-09 21:42:31 +08:00
			`use crate::common::csc_strategy;`
Implement CSC matrix basic API The CSC matrix API mirrors the CSR matrix API. However, there are subtle differences throughout (both in the available methods and the implementation) that I believe makes any attempt to avoid the duplicate effort futile. 2020-09-28 17:36:00 +08:00
Implement CsrMatrix/CscMatrix::filter and associated helpers Includes ::lower_triangle(), ::upper_triangle() and ::diagonal_matrix(). 2021-01-15 00:12:08 +08:00			`use std::collections::HashSet;`

Implement CSC matrix basic API The CSC matrix API mirrors the CSR matrix API. However, there are subtle differences throughout (both in the available methods and the implementation) that I believe makes any attempt to avoid the duplicate effort futile. 2020-09-28 17:36:00 +08:00			`#[test]`
			`fn csc_matrix_valid_data() {`
			`// Construct matrix from valid data and check that selected methods return results`
			`// that agree with expectations.`

			`{`
			`// A CSC matrix with zero explicitly stored entries`
			`let offsets = vec![0, 0, 0, 0];`
			`let indices = vec![];`
			`let values = Vec::<i32>::new();`
			`let mut matrix = CscMatrix::try_from_csc_data(2, 3, offsets, indices, values).unwrap();`

Rename some Csr/Csc/SparsityPattern methods 2021-01-25 23:04:29 +08:00			`assert_eq!(matrix, CscMatrix::zeros(2, 3));`
Implement CSC matrix basic API The CSC matrix API mirrors the CSR matrix API. However, there are subtle differences throughout (both in the available methods and the implementation) that I believe makes any attempt to avoid the duplicate effort futile. 2020-09-28 17:36:00 +08:00
			`assert_eq!(matrix.nrows(), 2);`
			`assert_eq!(matrix.ncols(), 3);`
			`assert_eq!(matrix.nnz(), 0);`
			`assert_eq!(matrix.col_offsets(), &[0, 0, 0, 0]);`
			`assert_eq!(matrix.row_indices(), &[]);`
			`assert_eq!(matrix.values(), &[]);`

			`assert!(matrix.triplet_iter().next().is_none());`
			`assert!(matrix.triplet_iter_mut().next().is_none());`

			`assert_eq!(matrix.col(0).nrows(), 2);`
			`assert_eq!(matrix.col(0).nnz(), 0);`
			`assert_eq!(matrix.col(0).row_indices(), &[]);`
			`assert_eq!(matrix.col(0).values(), &[]);`
			`assert_eq!(matrix.col_mut(0).nrows(), 2);`
			`assert_eq!(matrix.col_mut(0).nnz(), 0);`
			`assert_eq!(matrix.col_mut(0).row_indices(), &[]);`
			`assert_eq!(matrix.col_mut(0).values(), &[]);`
			`assert_eq!(matrix.col_mut(0).values_mut(), &[]);`
			`assert_eq!(matrix.col_mut(0).rows_and_values_mut(), ([].as_ref(), [].as_mut()));`

			`assert_eq!(matrix.col(1).nrows(), 2);`
			`assert_eq!(matrix.col(1).nnz(), 0);`
			`assert_eq!(matrix.col(1).row_indices(), &[]);`
			`assert_eq!(matrix.col(1).values(), &[]);`
			`assert_eq!(matrix.col_mut(1).nrows(), 2);`
			`assert_eq!(matrix.col_mut(1).nnz(), 0);`
			`assert_eq!(matrix.col_mut(1).row_indices(), &[]);`
			`assert_eq!(matrix.col_mut(1).values(), &[]);`
			`assert_eq!(matrix.col_mut(1).values_mut(), &[]);`
			`assert_eq!(matrix.col_mut(1).rows_and_values_mut(), ([].as_ref(), [].as_mut()));`

			`assert_eq!(matrix.col(2).nrows(), 2);`
			`assert_eq!(matrix.col(2).nnz(), 0);`
			`assert_eq!(matrix.col(2).row_indices(), &[]);`
			`assert_eq!(matrix.col(2).values(), &[]);`
			`assert_eq!(matrix.col_mut(2).nrows(), 2);`
			`assert_eq!(matrix.col_mut(2).nnz(), 0);`
			`assert_eq!(matrix.col_mut(2).row_indices(), &[]);`
			`assert_eq!(matrix.col_mut(2).values(), &[]);`
			`assert_eq!(matrix.col_mut(2).values_mut(), &[]);`
			`assert_eq!(matrix.col_mut(2).rows_and_values_mut(), ([].as_ref(), [].as_mut()));`

			`assert!(matrix.get_col(3).is_none());`
			`assert!(matrix.get_col_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 CSC 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 = CscMatrix::try_from_csc_data(6,`
			`3,`
			`offsets.clone(),`
			`indices.clone(),`
			`values.clone()).unwrap();`

			`assert_eq!(matrix.nrows(), 6);`
			`assert_eq!(matrix.ncols(), 3);`
			`assert_eq!(matrix.nnz(), 5);`
			`assert_eq!(matrix.col_offsets(), &[0, 2, 2, 5]);`
			`assert_eq!(matrix.row_indices(), &[0, 5, 1, 2, 3]);`
			`assert_eq!(matrix.values(), &[0, 1, 2, 3, 4]);`

			`let expected_triplets = vec![(0, 0, 0), (5, 0, 1), (1, 2, 2), (2, 2, 3), (3, 2, 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.col(0).nrows(), 6);`
			`assert_eq!(matrix.col(0).nnz(), 2);`
			`assert_eq!(matrix.col(0).row_indices(), &[0, 5]);`
			`assert_eq!(matrix.col(0).values(), &[0, 1]);`
			`assert_eq!(matrix.col_mut(0).nrows(), 6);`
			`assert_eq!(matrix.col_mut(0).nnz(), 2);`
			`assert_eq!(matrix.col_mut(0).row_indices(), &[0, 5]);`
			`assert_eq!(matrix.col_mut(0).values(), &[0, 1]);`
			`assert_eq!(matrix.col_mut(0).values_mut(), &[0, 1]);`
			`assert_eq!(matrix.col_mut(0).rows_and_values_mut(), ([0, 5].as_ref(), [0, 1].as_mut()));`

			`assert_eq!(matrix.col(1).nrows(), 6);`
			`assert_eq!(matrix.col(1).nnz(), 0);`
			`assert_eq!(matrix.col(1).row_indices(), &[]);`
			`assert_eq!(matrix.col(1).values(), &[]);`
			`assert_eq!(matrix.col_mut(1).nrows(), 6);`
			`assert_eq!(matrix.col_mut(1).nnz(), 0);`
			`assert_eq!(matrix.col_mut(1).row_indices(), &[]);`
			`assert_eq!(matrix.col_mut(1).values(), &[]);`
			`assert_eq!(matrix.col_mut(1).values_mut(), &[]);`
			`assert_eq!(matrix.col_mut(1).rows_and_values_mut(), ([].as_ref(), [].as_mut()));`

			`assert_eq!(matrix.col(2).nrows(), 6);`
			`assert_eq!(matrix.col(2).nnz(), 3);`
			`assert_eq!(matrix.col(2).row_indices(), &[1, 2, 3]);`
			`assert_eq!(matrix.col(2).values(), &[2, 3, 4]);`
			`assert_eq!(matrix.col_mut(2).nrows(), 6);`
			`assert_eq!(matrix.col_mut(2).nnz(), 3);`
			`assert_eq!(matrix.col_mut(2).row_indices(), &[1, 2, 3]);`
			`assert_eq!(matrix.col_mut(2).values(), &[2, 3, 4]);`
			`assert_eq!(matrix.col_mut(2).values_mut(), &[2, 3, 4]);`
			`assert_eq!(matrix.col_mut(2).rows_and_values_mut(), ([1, 2, 3].as_ref(), [2, 3, 4].as_mut()));`

			`assert!(matrix.get_col(3).is_none());`
			`assert!(matrix.get_col_mut(3).is_none());`

			`let (offsets2, indices2, values2) = matrix.disassemble();`

			`assert_eq!(offsets2, offsets);`
			`assert_eq!(indices2, indices);`
			`assert_eq!(values2, values);`
			`}`
			`}`

			`#[test]`
			`fn csc_matrix_try_from_invalid_csc_data() {`

			`{`
			`// Empty offset array (invalid length)`
			`let matrix = CscMatrix::try_from_csc_data(0, 0, Vec::new(), Vec::new(), Vec::<u32>::new());`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);`
			`}`

			`{`
			`// Offset array invalid length for arbitrary data`
			`let offsets = vec![0, 3, 5];`
			`let indices = vec![0, 1, 2, 3, 5];`
			`let values = vec![0, 1, 2, 3, 4];`

			`let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);`
			`}`

			`{`
			`// Invalid first entry in offsets array`
			`let offsets = vec![1, 2, 2, 5];`
			`let indices = vec![0, 5, 1, 2, 3];`
			`let values = vec![0, 1, 2, 3, 4];`
			`let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);`
			`}`

			`{`
			`// Invalid last entry in offsets array`
			`let offsets = vec![0, 2, 2, 4];`
			`let indices = vec![0, 5, 1, 2, 3];`
			`let values = vec![0, 1, 2, 3, 4];`
			`let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);`
			`}`

			`{`
			`// Invalid length of offsets array`
			`let offsets = vec![0, 2, 2];`
			`let indices = vec![0, 5, 1, 2, 3];`
			`let values = vec![0, 1, 2, 3, 4];`
			`let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);`
			`}`

			`{`
			`// Nonmonotonic offsets`
			`let offsets = vec![0, 3, 2, 5];`
			`let indices = vec![0, 1, 2, 3, 4];`
			`let values = vec![0, 1, 2, 3, 4];`
			`let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);`
			`}`

			`{`
			`// Nonmonotonic minor indices`
			`let offsets = vec![0, 2, 2, 5];`
			`let indices = vec![0, 2, 3, 1, 4];`
			`let values = vec![0, 1, 2, 3, 4];`
			`let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::InvalidStructure);`
			`}`

			`{`
			`// Minor index out of bounds`
			`let offsets = vec![0, 2, 2, 5];`
			`let indices = vec![0, 6, 1, 2, 3];`
			`let values = vec![0, 1, 2, 3, 4];`
			`let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::IndexOutOfBounds);`
			`}`

			`{`
			`// Duplicate entry`
			`let offsets = vec![0, 2, 2, 5];`
			`let indices = vec![0, 5, 2, 2, 3];`
			`let values = vec![0, 1, 2, 3, 4];`
			`let matrix = CscMatrix::try_from_csc_data(6, 3, offsets, indices, values);`
			`assert_eq!(matrix.unwrap_err().kind(), &SparseFormatErrorKind::DuplicateEntry);`
			`}`

			`}`

			`#[test]`
			`fn csc_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 = CscMatrix::try_from_csc_data(6,`
			`3,`
			`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);`
			`}`

			`#[test]`
			`fn csc_matrix_get_index() {`
			`// TODO: Implement tests for ::get() and index()`
			`}`

			`#[test]`
			`fn csc_matrix_col_iter() {`
			`// TODO`
Implement Csr/CscMatrix::transpose() 2020-12-09 21:42:31 +08:00			`}`

			`proptest! {`
			`#[test]`
			`fn csc_double_transpose_is_identity(csc in csc_strategy()) {`
			`prop_assert_eq!(csc.transpose().transpose(), csc);`
			`}`

			`#[test]`
			`fn csc_transpose_agrees_with_dense(csc in csc_strategy()) {`
			`let dense_transpose = DMatrix::from(&csc).transpose();`
			`let csc_transpose = csc.transpose();`
			`prop_assert_eq!(dense_transpose, DMatrix::from(&csc_transpose));`
			`prop_assert_eq!(csc.nnz(), csc_transpose.nnz());`
			`}`
Implement CsrMatrix/CscMatrix::filter and associated helpers Includes ::lower_triangle(), ::upper_triangle() and ::diagonal_matrix(). 2021-01-15 00:12:08 +08:00
			`#[test]`
			`fn csc_filter(`
			`(csc, triplet_subset)`
			`in csc_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 CscMatrix 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 = csc.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 csc_lower_triangle_agrees_with_dense(csc in csc_strategy()) {`
			`let csc_lower_triangle = csc.lower_triangle();`
			`prop_assert_eq!(DMatrix::from(&csc_lower_triangle), DMatrix::from(&csc).lower_triangle());`
			`prop_assert!(csc_lower_triangle.nnz() <= csc.nnz());`
			`}`

			`#[test]`
			`fn csc_upper_triangle_agrees_with_dense(csc in csc_strategy()) {`
			`let csc_upper_triangle = csc.upper_triangle();`
			`prop_assert_eq!(DMatrix::from(&csc_upper_triangle), DMatrix::from(&csc).upper_triangle());`
			`prop_assert!(csc_upper_triangle.nnz() <= csc.nnz());`
			`}`

			`#[test]`
Rename some Csr/Csc/SparsityPattern methods 2021-01-25 23:04:29 +08:00			`fn csc_diagonal_as_csc(csc in csc_strategy()) {`
			`let d = csc.diagonal_as_csc();`
Implement CsrMatrix/CscMatrix::filter and associated helpers Includes ::lower_triangle(), ::upper_triangle() and ::diagonal_matrix(). 2021-01-15 00:12:08 +08:00			`let d_entries: HashSet<_> = d.triplet_iter().cloned_values().collect();`
			`let csc_diagonal_entries: HashSet<_> = csc`
			`.triplet_iter()`
			`.cloned_values()`
			`.filter(\|&(i, j, _)\| i == j)`
			`.collect();`

			`prop_assert_eq!(d_entries, csc_diagonal_entries);`
			`}`
Implement CSC matrix basic API The CSC matrix API mirrors the CSR matrix API. However, there are subtle differences throughout (both in the available methods and the implementation) that I believe makes any attempt to avoid the duplicate effort futile. 2020-09-28 17:36:00 +08:00			`}`