Documentation for CsrMatrix

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Andreas Longva 2021-01-25 12:09:16 +01:00
parent 0bee9be6c7
commit afcad0ccc8
2 changed files with 100 additions and 2 deletions

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@ -14,8 +14,106 @@ use std::slice::{IterMut, Iter};
/// The Compressed Sparse Row (CSR) format is well-suited as a general-purpose storage format
/// for many sparse matrix applications.
///
/// TODO: Storage explanation and examples
/// # Usage
///
/// ```rust
/// use nalgebra_sparse::csr::CsrMatrix;
/// use nalgebra::{DMatrix, Matrix3x4};
/// use matrixcompare::assert_matrix_eq;
///
/// // The sparsity patterns of CSR matrices are immutable. This means that you cannot dynamically
/// // change the sparsity pattern of the matrix after it has been constructed. The easiest
/// // way to construct a CSR matrix is to first incrementally construct a COO matrix,
/// // and then convert it to CSR.
/// # use nalgebra_sparse::coo::CooMatrix;
/// # let coo = CooMatrix::<f64>::new(3, 3);
/// let csr = CsrMatrix::from(&coo);
///
/// // Alternatively, a CSR matrix can be constructed directly from raw CSR data.
/// // Here, we construct a 3x4 matrix
/// let row_offsets = vec![0, 3, 3, 5];
/// let col_indices = vec![0, 1, 3, 1, 2];
/// let values = vec![1.0, 2.0, 3.0, 4.0, 5.0];
///
/// // The dense representation of the CSR data, for comparison
/// let dense = Matrix3x4::new(1.0, 2.0, 0.0, 3.0,
/// 0.0, 0.0, 0.0, 0.0,
/// 0.0, 4.0, 5.0, 0.0);
///
/// // The constructor validates the raw CSR data and returns an error if it is invalid.
/// let csr = CsrMatrix::try_from_csr_data(3, 4, row_offsets, col_indices, values)
/// .expect("CSR data must conform to format specifications");
/// assert_matrix_eq!(csr, dense);
///
/// // A third approach is to construct a CSR matrix from a pattern and values. Sometimes this is
/// // useful if the sparsity pattern is constructed separately from the values of the matrix.
/// let (pattern, values) = csr.into_pattern_and_values();
/// let csr = CsrMatrix::try_from_pattern_and_values(pattern, values)
/// .expect("The pattern and values must be compatible");
///
/// // Once we have constructed our matrix, we can use it for arithmetic operations together with
/// // other CSR matrices and dense matrices/vectors.
/// let x = csr;
/// # #[allow(non_snake_case)]
/// let xTx = x.transpose() * &x;
///
/// let z = DMatrix::from_fn(4, 8, |i, j| (i as f64) * (j as f64));
/// let w = 3.0 * xTx * z;
///
/// // Although the sparsity pattern of a CSR matrix cannot be changed, its values can.
/// // Here are two different ways to scale all values by a constant:
/// let mut x = x;
/// x *= 5.0;
/// x.values_mut().iter_mut().for_each(|x_i| *x_i *= 5.0);
/// ```
///
/// # Format
///
/// An `m x n` sparse matrix with `nnz` non-zeros consists of the following three arrays:
///
/// - `row_offsets`, an array of integers with length `m + 1`.
/// - `col_indices`, an array of integers with length `nnz`.
/// - `values`, an array of values with length `nnz`.
///
/// The relationship between the arrays is described below.
///
/// - Each consecutive pair of entries `row_offsets[i] .. row_offsets[i + 1]` corresponds to an
/// offset range in `col_indices` that holds the column indices in row `i`.
/// - For an entry represented by the index `idx`, `col_indices[idx]` stores its column index and
/// `values[idx]` stores its value.
///
/// The following invariants must be upheld and are enforced by the data structure:
///
/// - `row_offsets[0] == 0`
/// - `row_offsets[m] == nnz`
/// - `row_offsets` is monotonically increasing.
/// - The column indices associated with each row are monotonically increasing (see below).
///
/// The CSR format is a standard sparse matrix format (see [Wikipedia article]). The format
/// represents the matrix in a row-by-row fashion. The entries associated with row `i` are
/// determined as follows:
///
/// ```rust
/// # let row_offsets: Vec<usize> = vec![0, 0];
/// # let col_indices: Vec<usize> = vec![];
/// # let values: Vec<i32> = vec![];
/// # let i = 0;
/// let range = row_offsets[i] .. row_offsets[i + 1];
/// let row_i_cols = &col_indices[range.clone()];
/// let row_i_vals = &values[range];
///
/// // For each pair (j, v) in (row_i_cols, row_i_vals), we obtain a corresponding entry
/// // (i, j, v) in the matrix.
/// assert_eq!(row_i_cols.len(), row_i_vals.len());
/// ```
///
/// In the above example, for each row `i`, the column indices `row_i_cols` must appear in
/// monotonically increasing order. In other words, they must be *sorted*. This criterion is not
/// standard among all sparse matrix libraries, but we enforce this property as it is a crucial
/// assumption for both correctness and performance for many algorithms.
///
///
/// [Wikipedia article]: https://en.wikipedia.org/wiki/Sparse_matrix#Compressed_sparse_row_(CSR,_CRS_or_Yale_format)
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct CsrMatrix<T> {
// Rows are major, cols are minor in the sparsity pattern

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@ -123,7 +123,7 @@
//! use nalgebra_sparse::ops::{Op, serial::spmm_csr_dense};
//! let mut y = y;
//! // Compute y <- 0.0 * y + 1.0 * csr * dense. We store the result directly in `y`, without
//! // any immediate allocations
//! // any intermediate allocations
//! spmm_csr_dense(0.0, &mut y, 1.0, Op::NoOp(&csr), Op::NoOp(&x));
//! assert_matrix_eq!(y, y_expected, comp = abs, tol = 1e-9);
//! }