Implement spadd_build_pattern
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7c68950614
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@ -3,7 +3,7 @@ use crate::ops::{Transpose};
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use nalgebra::{Scalar, DMatrixSlice, ClosedAdd, ClosedMul, DMatrixSliceMut};
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use num_traits::{Zero, One};
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/// Sparse-dense matrix-matrix multiplication `C = beta * C + alpha * trans(A) * trans(B)`.
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/// Sparse-dense matrix-matrix multiplication `C <- beta * C + alpha * trans(A) * trans(B)`.
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pub fn spmm_csr_dense<'a, T>(c: impl Into<DMatrixSliceMut<'a, T>>,
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beta: T,
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alpha: T,
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@ -32,6 +32,8 @@ macro_rules! assert_compatible_spmm_dims {
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mod coo;
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mod csr;
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mod pattern;
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pub use coo::*;
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pub use csr::*;
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pub use pattern::*;
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@ -0,0 +1,77 @@
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use crate::pattern::SparsityPattern;
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use std::mem::swap;
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use std::iter;
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/// Sparse matrix addition pattern construction, `C <- A + B`.
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///
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/// Builds the pattern for `C`, which is able to hold the result of the sum `A + B`.
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/// The patterns are assumed to have the same major and minor dimensions. In other words,
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/// both patterns `A` and `B` must both stem from the same kind of compressed matrix:
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/// CSR or CSC.
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/// TODO: Explain that output pattern is only used to avoid allocations
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pub fn spadd_build_pattern(pattern: &mut SparsityPattern,
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a: &SparsityPattern,
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b: &SparsityPattern)
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{
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// TODO: Proper error messages
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assert_eq!(a.major_dim(), b.major_dim());
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assert_eq!(a.minor_dim(), b.minor_dim());
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let input_pattern = pattern;
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let mut temp_pattern = SparsityPattern::new(a.major_dim(), b.minor_dim());
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swap(input_pattern, &mut temp_pattern);
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let (mut offsets, mut indices) = temp_pattern.disassemble();
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offsets.clear();
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offsets.reserve(a.major_dim() + 1);
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indices.clear();
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offsets.push(0);
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for lane_idx in 0 .. a.major_dim() {
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let lane_a = a.lane(lane_idx);
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let lane_b = b.lane(lane_idx);
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indices.extend(iterate_intersection(lane_a, lane_b));
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offsets.push(indices.len());
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}
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// TODO: Consider circumventing format checks? (requires unsafe, should benchmark first)
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let mut new_pattern = SparsityPattern::try_from_offsets_and_indices(
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a.major_dim(), a.minor_dim(), offsets, indices)
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.expect("Pattern must be valid by definition");
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swap(input_pattern, &mut new_pattern);
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}
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/// Iterate over the intersection of the two sets represented by sorted slices
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/// (with unique elements)
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fn iterate_intersection<'a>(mut sorted_a: &'a [usize],
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mut sorted_b: &'a [usize]) -> impl Iterator<Item=usize> + 'a {
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// TODO: Can use a kind of simultaneous exponential search to speed things up here
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iter::from_fn(move || {
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if let (Some(a_item), Some(b_item)) = (sorted_a.first(), sorted_b.first()) {
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let item = if a_item < b_item {
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sorted_a = &sorted_a[1 ..];
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a_item
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} else if b_item < a_item {
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sorted_b = &sorted_b[1 ..];
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b_item
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} else {
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// Both lists contain the same element, advance both slices to avoid
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// duplicate entries in the result
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sorted_a = &sorted_a[1 ..];
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sorted_b = &sorted_b[1 ..];
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a_item
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};
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Some(*item)
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} else if let Some(a_item) = sorted_a.first() {
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sorted_a = &sorted_a[1..];
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Some(*a_item)
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} else if let Some(b_item) = sorted_b.first() {
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sorted_b = &sorted_b[1..];
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Some(*b_item)
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} else {
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None
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}
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})
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}
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@ -1,8 +1,9 @@
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use nalgebra_sparse::coo::CooMatrix;
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use nalgebra_sparse::ops::serial::{spmv_coo, spmm_csr_dense};
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use nalgebra_sparse::ops::serial::{spmv_coo, spmm_csr_dense, spadd_build_pattern};
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use nalgebra_sparse::ops::{Transpose};
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use nalgebra_sparse::csr::CsrMatrix;
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use nalgebra_sparse::proptest::csr;
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use nalgebra_sparse::proptest::{csr, sparsity_pattern};
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use nalgebra_sparse::pattern::SparsityPattern;
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use nalgebra::{DVector, DMatrix, Scalar, DMatrixSliceMut, DMatrixSlice};
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use nalgebra::proptest::matrix;
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@ -10,6 +11,7 @@ use nalgebra::proptest::matrix;
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use proptest::prelude::*;
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use std::panic::catch_unwind;
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use std::sync::Arc;
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#[test]
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fn spmv_coo_agrees_with_dense_gemv() {
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@ -99,6 +101,19 @@ fn trans_strategy() -> impl Strategy<Value=Transpose> + Clone {
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proptest::bool::ANY.prop_map(Transpose)
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}
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fn pattern_strategy() -> impl Strategy<Value=SparsityPattern> {
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sparsity_pattern(0 ..= 6usize, 0..= 6usize, 40)
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}
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/// Constructs pairs (a, b) where a and b have the same dimensions
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fn spadd_build_pattern_strategy() -> impl Strategy<Value=(SparsityPattern, SparsityPattern)> {
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pattern_strategy()
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.prop_flat_map(|a| {
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let b = sparsity_pattern(Just(a.major_dim()), Just(a.minor_dim()), 40);
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(Just(a), b)
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})
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}
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/// Helper function to help us call dense GEMM with our transposition parameters
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fn dense_gemm<'a>(c: impl Into<DMatrixSliceMut<'a, i32>>,
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beta: i32,
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@ -167,4 +182,26 @@ proptest! {
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"The SPMM kernel executed successfully despite mismatch dimensions");
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}
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#[test]
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fn spadd_build_pattern_test((c, (a, b)) in (pattern_strategy(), spadd_build_pattern_strategy()))
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{
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// (a, b) are dimensionally compatible patterns, whereas c is an *arbitrary* pattern
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let mut pattern_result = c.clone();
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spadd_build_pattern(&mut pattern_result, &a, &b);
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// To verify the pattern, we construct CSR matrices with positive integer entries
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// corresponding to a and b, and convert them to dense matrices.
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// The sum of these dense matrices will then have non-zeros in exactly the same locations
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// as the result of "adding" the sparsity patterns
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let a_csr = CsrMatrix::try_from_pattern_and_values(Arc::new(a.clone()), vec![1; a.nnz()])
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.unwrap();
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let a_dense = DMatrix::from(&a_csr);
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let b_csr = CsrMatrix::try_from_pattern_and_values(Arc::new(b.clone()), vec![1; b.nnz()])
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.unwrap();
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let b_dense = DMatrix::from(&b_csr);
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let c_dense = a_dense + b_dense;
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let c_csr = CsrMatrix::from(&c_dense);
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prop_assert_eq!(&pattern_result, &*c_csr.pattern());
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}
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}
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