2021-01-22 21:32:13 +08:00
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//! Functionality for integrating `nalgebra-sparse` with `proptest`.
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2020-11-12 18:49:19 +08:00
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//!
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2021-01-22 21:32:13 +08:00
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//! **This module is only available if the `proptest-support` feature is enabled**.
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//!
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//! The strategies provided here are generally expected to be able to generate the entire range
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//! of possible outputs given the constraints on dimensions and values. However, there are no
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//! particular guarantees on the distribution of possible values.
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2020-11-12 18:49:19 +08:00
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use crate::coo::CooMatrix;
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2021-01-26 00:26:27 +08:00
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use crate::csc::CscMatrix;
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2020-11-25 00:34:19 +08:00
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use crate::csr::CsrMatrix;
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use crate::pattern::SparsityPattern;
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2021-01-21 00:43:01 +08:00
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use nalgebra::proptest::DimRange;
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2021-01-26 00:26:27 +08:00
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use nalgebra::{Dim, Scalar};
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use proptest::collection::{btree_set, hash_map, vec};
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use proptest::prelude::*;
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use proptest::sample::Index;
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use std::cmp::min;
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use std::iter::repeat;
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2020-11-25 00:34:19 +08:00
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2021-01-26 00:26:27 +08:00
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fn dense_row_major_coord_strategy(
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nrows: usize,
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ncols: usize,
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nnz: usize,
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) -> impl Strategy<Value = Vec<(usize, usize)>> {
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2021-01-20 23:07:43 +08:00
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assert!(nnz <= nrows * ncols);
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2020-11-25 00:34:19 +08:00
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let mut booleans = vec![true; nnz];
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booleans.append(&mut vec![false; (nrows * ncols) - nnz]);
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// Make sure that exactly `nnz` of the booleans are true
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2021-12-01 19:44:07 +08:00
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Just(booleans)
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// Need to shuffle to make sure they are randomly distributed
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.prop_shuffle()
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.prop_map(move |booleans| {
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2021-01-26 00:26:27 +08:00
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booleans
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.into_iter()
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.enumerate()
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.filter_map(|(index, is_entry)| {
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if is_entry {
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// Convert linear index to row/col pair
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let i = index / ncols;
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let j = index % ncols;
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Some((i, j))
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} else {
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None
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}
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})
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.collect::<Vec<_>>()
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})
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2020-11-25 00:34:19 +08:00
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}
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2020-11-18 20:54:14 +08:00
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/// A strategy for generating `nnz` triplets.
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///
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/// This strategy should generally only be used when `nnz` is close to `nrows * ncols`.
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2021-01-26 00:26:27 +08:00
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fn dense_triplet_strategy<T>(
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value_strategy: T,
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nrows: usize,
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ncols: usize,
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nnz: usize,
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) -> impl Strategy<Value = Vec<(usize, usize, T::Value)>>
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2020-11-18 20:54:14 +08:00
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where
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T: Strategy + Clone + 'static,
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T::Value: Scalar,
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{
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assert!(nnz <= nrows * ncols);
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// Construct a number of booleans of which exactly `nnz` are true.
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let booleans: Vec<_> = repeat(true)
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.take(nnz)
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.chain(repeat(false))
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.take(nrows * ncols)
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.collect();
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Just(booleans)
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// Shuffle the booleans so that they are randomly distributed
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.prop_shuffle()
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// Convert the booleans into a list of coordinate pairs
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.prop_map(move |booleans| {
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booleans
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.into_iter()
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.enumerate()
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.filter_map(|(index, is_entry)| {
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if is_entry {
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// Convert linear index to row/col pair
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let i = index / ncols;
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let j = index % ncols;
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Some((i, j))
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} else {
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None
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}
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})
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.collect::<Vec<_>>()
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})
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// Assign values to each coordinate pair in order to generate a list of triplets
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.prop_flat_map(move |coords| {
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2021-01-26 00:26:27 +08:00
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vec![value_strategy.clone(); coords.len()].prop_map(move |values| {
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coords
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.clone()
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.into_iter()
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.zip(values)
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.map(|((i, j), v)| (i, j, v))
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.collect::<Vec<_>>()
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})
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2020-11-18 20:54:14 +08:00
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})
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}
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/// A strategy for generating `nnz` triplets.
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///
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/// This strategy should generally only be used when `nnz << nrows * ncols`. If `nnz` is too
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/// close to `nrows * ncols` it may fail due to excessive rejected samples.
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2021-01-26 00:26:27 +08:00
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fn sparse_triplet_strategy<T>(
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value_strategy: T,
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nrows: usize,
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ncols: usize,
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nnz: usize,
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) -> impl Strategy<Value = Vec<(usize, usize, T::Value)>>
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where
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T: Strategy + Clone + 'static,
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T::Value: Scalar,
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2020-11-18 20:54:14 +08:00
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{
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// Have to handle the zero case: proptest doesn't like empty ranges (i.e. 0 .. 0)
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2021-01-26 00:26:27 +08:00
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let row_index_strategy = if nrows > 0 { 0..nrows } else { 0..1 };
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let col_index_strategy = if ncols > 0 { 0..ncols } else { 0..1 };
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2020-11-18 20:54:14 +08:00
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let coord_strategy = (row_index_strategy, col_index_strategy);
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hash_map(coord_strategy, value_strategy.clone(), nnz)
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.prop_map(|hash_map| {
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2021-01-26 00:26:27 +08:00
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let triplets: Vec<_> = hash_map.into_iter().map(|((i, j), v)| (i, j, v)).collect();
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2020-11-18 20:54:14 +08:00
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triplets
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})
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// Although order in the hash map is unspecified, it's not necessarily *random*
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// - or, in particular, it does not necessarily sample the whole space of possible outcomes -
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// so we additionally shuffle the triplets
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.prop_shuffle()
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}
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2021-01-22 21:32:13 +08:00
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/// A strategy for producing COO matrices without duplicate entries.
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///
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/// The values of the matrix are picked from the provided `value_strategy`, while the size of the
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/// generated matrices is determined by the ranges `rows` and `cols`. The number of explicitly
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/// stored entries is bounded from above by `max_nonzeros`. Note that the matrix might still
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/// contain explicitly stored zeroes if the value strategy is capable of generating zero values.
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2020-11-18 20:54:14 +08:00
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pub fn coo_no_duplicates<T>(
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value_strategy: T,
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2021-01-21 00:43:01 +08:00
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rows: impl Into<DimRange>,
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cols: impl Into<DimRange>,
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2021-01-26 00:26:27 +08:00
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max_nonzeros: usize,
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) -> impl Strategy<Value = CooMatrix<T::Value>>
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2020-11-18 20:54:14 +08:00
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where
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T: Strategy + Clone + 'static,
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T::Value: Scalar,
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{
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2021-01-26 00:26:27 +08:00
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(
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rows.into().to_range_inclusive(),
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cols.into().to_range_inclusive(),
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)
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2020-11-18 20:54:14 +08:00
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.prop_flat_map(move |(nrows, ncols)| {
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let max_nonzeros = min(max_nonzeros, nrows * ncols);
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2021-01-26 00:26:27 +08:00
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let size_range = 0..=max_nonzeros;
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2020-11-18 20:54:14 +08:00
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let value_strategy = value_strategy.clone();
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2021-01-26 00:26:27 +08:00
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size_range
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.prop_flat_map(move |nnz| {
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let value_strategy = value_strategy.clone();
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if nnz as f64 > 0.10 * (nrows as f64) * (ncols as f64) {
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// If the number of nnz is sufficiently dense, then use the dense
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// sample strategy
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dense_triplet_strategy(value_strategy, nrows, ncols, nnz).boxed()
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} else {
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// Otherwise, use a hash map strategy so that we can get a sparse sampling
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// (so that complexity is rather on the order of max_nnz than nrows * ncols)
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sparse_triplet_strategy(value_strategy, nrows, ncols, nnz).boxed()
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}
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})
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.prop_map(move |triplets| {
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let mut coo = CooMatrix::new(nrows, ncols);
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for (i, j, v) in triplets {
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coo.push(i, j, v);
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}
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coo
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})
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2020-11-18 20:54:14 +08:00
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})
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}
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2020-11-12 18:49:19 +08:00
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2021-01-22 21:32:13 +08:00
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/// A strategy for producing COO matrices with duplicate entries.
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///
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/// The values of the matrix are picked from the provided `value_strategy`, while the size of the
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/// generated matrices is determined by the ranges `rows` and `cols`. Note that the values
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/// only apply to individual entries, and since this strategy can generate duplicate entries,
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/// the matrix will generally have values outside the range determined by `value_strategy` when
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/// converted to other formats, since the duplicate entries are summed together in this case.
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2020-11-18 20:54:14 +08:00
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///
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2021-01-22 21:32:13 +08:00
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/// The number of explicitly stored entries is bounded from above by `max_nonzeros`. The maximum
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/// number of duplicate entries is determined by `max_duplicates`. Note that the matrix might still
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/// contain explicitly stored zeroes if the value strategy is capable of generating zero values.
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2020-11-18 20:54:14 +08:00
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pub fn coo_with_duplicates<T>(
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2021-01-26 00:26:27 +08:00
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value_strategy: T,
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rows: impl Into<DimRange>,
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cols: impl Into<DimRange>,
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max_nonzeros: usize,
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max_duplicates: usize,
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) -> impl Strategy<Value = CooMatrix<T::Value>>
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2020-11-12 18:49:19 +08:00
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where
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T: Strategy + Clone + 'static,
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T::Value: Scalar,
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{
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2020-11-18 20:54:14 +08:00
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let coo_strategy = coo_no_duplicates(value_strategy.clone(), rows, cols, max_nonzeros);
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2021-01-26 00:26:27 +08:00
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let duplicate_strategy = vec((any::<Index>(), value_strategy.clone()), 0..=max_duplicates);
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2020-11-18 20:54:14 +08:00
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(coo_strategy, duplicate_strategy)
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.prop_flat_map(|(coo, duplicates)| {
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2021-01-26 00:26:27 +08:00
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let mut triplets: Vec<(usize, usize, T::Value)> = coo
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.triplet_iter()
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2020-11-18 20:54:14 +08:00
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.map(|(i, j, v)| (i, j, v.clone()))
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.collect();
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if !triplets.is_empty() {
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let duplicates_iter: Vec<_> = duplicates
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.into_iter()
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.map(|(idx, val)| {
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let (i, j, _) = idx.get(&triplets);
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(*i, *j, val)
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})
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.collect();
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triplets.extend(duplicates_iter);
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}
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// Make sure to shuffle so that the duplicates get mixed in with the non-duplicates
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let shuffled = Just(triplets).prop_shuffle();
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(Just(coo.nrows()), Just(coo.ncols()), shuffled)
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})
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.prop_map(move |(nrows, ncols, triplets)| {
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let mut coo = CooMatrix::new(nrows, ncols);
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for (i, j, v) in triplets {
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coo.push(i, j, v);
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}
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coo
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})
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2020-11-25 00:34:19 +08:00
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}
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2021-01-26 00:26:27 +08:00
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fn sparsity_pattern_from_row_major_coords<I>(
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nmajor: usize,
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nminor: usize,
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coords: I,
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) -> SparsityPattern
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2020-11-25 00:34:19 +08:00
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where
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2021-01-26 00:26:27 +08:00
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I: Iterator<Item = (usize, usize)> + ExactSizeIterator,
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2020-11-25 00:34:19 +08:00
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{
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let mut minors = Vec::with_capacity(coords.len());
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let mut offsets = Vec::with_capacity(nmajor + 1);
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let mut current_major = 0;
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offsets.push(0);
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for (idx, (i, j)) in coords.enumerate() {
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assert!(i >= current_major);
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2021-01-26 00:26:27 +08:00
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assert!(
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i < nmajor && j < nminor,
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"Generated coords are out of bounds"
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);
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while current_major < i {
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2020-11-25 00:34:19 +08:00
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offsets.push(idx);
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current_major += 1;
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}
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minors.push(j);
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}
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while current_major < nmajor {
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offsets.push(minors.len());
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current_major += 1;
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}
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assert_eq!(offsets.first().unwrap(), &0);
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assert_eq!(offsets.len(), nmajor + 1);
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2021-01-26 00:26:27 +08:00
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SparsityPattern::try_from_offsets_and_indices(nmajor, nminor, offsets, minors)
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2020-11-25 00:34:19 +08:00
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.expect("Internal error: Generated sparsity pattern is invalid")
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}
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2021-01-22 21:32:13 +08:00
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/// A strategy for generating sparsity patterns.
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2020-11-25 00:34:19 +08:00
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pub fn sparsity_pattern(
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2021-01-21 00:43:01 +08:00
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major_lanes: impl Into<DimRange>,
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minor_lanes: impl Into<DimRange>,
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2021-01-26 00:26:27 +08:00
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max_nonzeros: usize,
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) -> impl Strategy<Value = SparsityPattern> {
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(
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major_lanes.into().to_range_inclusive(),
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minor_lanes.into().to_range_inclusive(),
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)
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2020-11-25 00:34:19 +08:00
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.prop_flat_map(move |(nmajor, nminor)| {
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let max_nonzeros = min(nmajor * nminor, max_nonzeros);
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2021-01-26 00:26:27 +08:00
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(Just(nmajor), Just(nminor), 0..=max_nonzeros)
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})
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.prop_flat_map(move |(nmajor, nminor, nnz)| {
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2020-11-25 00:34:19 +08:00
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if 10 * nnz < nmajor * nminor {
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// If nnz is small compared to a dense matrix, then use a sparse sampling strategy
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btree_set((0..nmajor, 0..nminor), nnz)
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.prop_map(move |coords| {
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sparsity_pattern_from_row_major_coords(nmajor, nminor, coords.into_iter())
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})
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.boxed()
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} else {
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// If the required number of nonzeros is sufficiently dense,
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// we instead use a dense sampling
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dense_row_major_coord_strategy(nmajor, nminor, nnz)
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2021-01-20 23:07:43 +08:00
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.prop_map(move |coords| {
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let coords = coords.into_iter();
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2020-11-25 00:34:19 +08:00
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sparsity_pattern_from_row_major_coords(nmajor, nminor, coords)
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2021-01-26 00:26:27 +08:00
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})
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.boxed()
|
2020-11-25 00:34:19 +08:00
|
|
|
}
|
|
|
|
})
|
|
|
|
}
|
|
|
|
|
2021-01-22 21:32:13 +08:00
|
|
|
/// A strategy for generating CSR matrices.
|
2021-01-26 00:26:27 +08:00
|
|
|
pub fn csr<T>(
|
|
|
|
value_strategy: T,
|
|
|
|
rows: impl Into<DimRange>,
|
|
|
|
cols: impl Into<DimRange>,
|
|
|
|
max_nonzeros: usize,
|
|
|
|
) -> impl Strategy<Value = CsrMatrix<T::Value>>
|
2020-11-25 00:34:19 +08:00
|
|
|
where
|
|
|
|
T: Strategy + Clone + 'static,
|
|
|
|
T::Value: Scalar,
|
|
|
|
{
|
2021-01-21 00:43:01 +08:00
|
|
|
let rows = rows.into();
|
|
|
|
let cols = cols.into();
|
2021-01-26 00:26:27 +08:00
|
|
|
sparsity_pattern(
|
|
|
|
rows.lower_bound().value()..=rows.upper_bound().value(),
|
|
|
|
cols.lower_bound().value()..=cols.upper_bound().value(),
|
|
|
|
max_nonzeros,
|
|
|
|
)
|
|
|
|
.prop_flat_map(move |pattern| {
|
|
|
|
let nnz = pattern.nnz();
|
|
|
|
let values = vec![value_strategy.clone(); nnz];
|
|
|
|
(Just(pattern), values)
|
|
|
|
})
|
|
|
|
.prop_map(|(pattern, values)| {
|
|
|
|
CsrMatrix::try_from_pattern_and_values(pattern, values)
|
|
|
|
.expect("Internal error: Generated CsrMatrix is invalid")
|
|
|
|
})
|
2020-11-25 00:34:19 +08:00
|
|
|
}
|
|
|
|
|
2021-01-22 21:32:13 +08:00
|
|
|
/// A strategy for generating CSC matrices.
|
2021-01-26 00:26:27 +08:00
|
|
|
pub fn csc<T>(
|
|
|
|
value_strategy: T,
|
|
|
|
rows: impl Into<DimRange>,
|
|
|
|
cols: impl Into<DimRange>,
|
|
|
|
max_nonzeros: usize,
|
|
|
|
) -> impl Strategy<Value = CscMatrix<T::Value>>
|
|
|
|
where
|
|
|
|
T: Strategy + Clone + 'static,
|
|
|
|
T::Value: Scalar,
|
2020-11-25 00:34:19 +08:00
|
|
|
{
|
2021-01-21 00:43:01 +08:00
|
|
|
let rows = rows.into();
|
|
|
|
let cols = cols.into();
|
2021-01-26 00:26:27 +08:00
|
|
|
sparsity_pattern(
|
|
|
|
cols.lower_bound().value()..=cols.upper_bound().value(),
|
|
|
|
rows.lower_bound().value()..=rows.upper_bound().value(),
|
|
|
|
max_nonzeros,
|
|
|
|
)
|
|
|
|
.prop_flat_map(move |pattern| {
|
|
|
|
let nnz = pattern.nnz();
|
|
|
|
let values = vec![value_strategy.clone(); nnz];
|
|
|
|
(Just(pattern), values)
|
|
|
|
})
|
|
|
|
.prop_map(|(pattern, values)| {
|
|
|
|
CscMatrix::try_from_pattern_and_values(pattern, values)
|
|
|
|
.expect("Internal error: Generated CscMatrix is invalid")
|
|
|
|
})
|
|
|
|
}
|