2020-12-22 18:01:50 +08:00
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use std::mem::replace;
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2021-01-19 21:15:19 +08:00
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use std::ops::Range;
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use std::sync::Arc;
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2021-01-11 22:03:58 +08:00
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use num_traits::One;
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2021-01-19 21:15:19 +08:00
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2021-01-11 22:03:58 +08:00
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use nalgebra::Scalar;
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2020-12-22 17:19:17 +08:00
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2021-01-19 21:15:19 +08:00
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use crate::{SparseEntry, SparseEntryMut};
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use crate::pattern::SparsityPattern;
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2020-12-22 17:19:17 +08:00
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/// An abstract compressed matrix.
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///
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/// For the time being, this is only used internally to share implementation between
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/// CSR and CSC matrices.
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///
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/// A CSR matrix is obtained by associating rows with the major dimension, while a CSC matrix
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/// is obtained by associating columns with the major dimension.
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#[derive(Debug, Clone, PartialEq, Eq)]
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pub struct CsMatrix<T> {
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sparsity_pattern: Arc<SparsityPattern>,
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values: Vec<T>
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}
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impl<T> CsMatrix<T> {
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/// Create a zero matrix with no explicitly stored entries.
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#[inline]
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pub fn new(major_dim: usize, minor_dim: usize) -> Self {
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Self {
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sparsity_pattern: Arc::new(SparsityPattern::new(major_dim, minor_dim)),
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values: vec![],
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}
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}
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#[inline]
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pub fn pattern(&self) -> &Arc<SparsityPattern> {
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&self.sparsity_pattern
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}
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#[inline]
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pub fn values(&self) -> &[T] {
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&self.values
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}
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#[inline]
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pub fn values_mut(&mut self) -> &mut [T] {
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&mut self.values
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}
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/// Returns the raw data represented as a tuple `(major_offsets, minor_indices, values)`.
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#[inline]
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pub fn cs_data(&self) -> (&[usize], &[usize], &[T]) {
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let pattern = self.pattern().as_ref();
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(pattern.major_offsets(), pattern.minor_indices(), &self.values)
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}
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/// Returns the raw data represented as a tuple `(major_offsets, minor_indices, values)`.
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#[inline]
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pub fn cs_data_mut(&mut self) -> (&[usize], &[usize], &mut [T]) {
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let pattern = self.sparsity_pattern.as_ref();
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(pattern.major_offsets(), pattern.minor_indices(), &mut self.values)
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}
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#[inline]
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pub fn pattern_and_values_mut(&mut self) -> (&Arc<SparsityPattern>, &mut [T]) {
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(&self.sparsity_pattern, &mut self.values)
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}
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#[inline]
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pub fn from_pattern_and_values(pattern: Arc<SparsityPattern>, values: Vec<T>)
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-> Self {
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assert_eq!(pattern.nnz(), values.len(), "Internal error: consumers should verify shape compatibility.");
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Self {
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sparsity_pattern: pattern,
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values,
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}
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}
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/// Internal method for simplifying access to a lane's data
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#[inline]
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pub fn get_index_range(&self, row_index: usize) -> Option<Range<usize>> {
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let row_begin = *self.sparsity_pattern.major_offsets().get(row_index)?;
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let row_end = *self.sparsity_pattern.major_offsets().get(row_index + 1)?;
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Some(row_begin .. row_end)
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}
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pub fn take_pattern_and_values(self) -> (Arc<SparsityPattern>, Vec<T>) {
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(self.sparsity_pattern, self.values)
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}
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#[inline]
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pub fn disassemble(self) -> (Vec<usize>, Vec<usize>, Vec<T>) {
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// Take an Arc to the pattern, which might be the sole reference to the data after
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// taking the values. This is important, because it might let us avoid cloning the data
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// further below.
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let pattern = self.sparsity_pattern;
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let values = self.values;
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// Try to take the pattern out of the `Arc` if possible,
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// otherwise clone the pattern.
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let owned_pattern = Arc::try_unwrap(pattern)
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.unwrap_or_else(|arc| SparsityPattern::clone(&*arc));
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let (offsets, indices) = owned_pattern.disassemble();
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(offsets, indices, values)
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}
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/// Returns an entry for the given major/minor indices, or `None` if the indices are out
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/// of bounds.
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pub fn get_entry(&self, major_index: usize, minor_index: usize) -> Option<SparseEntry<T>> {
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let row_range = self.get_index_range(major_index)?;
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let (_, minor_indices, values) = self.cs_data();
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let minor_indices = &minor_indices[row_range.clone()];
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let values = &values[row_range];
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get_entry_from_slices(self.pattern().minor_dim(), minor_indices, values, minor_index)
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}
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/// Returns a mutable entry for the given major/minor indices, or `None` if the indices are out
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/// of bounds.
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pub fn get_entry_mut(&mut self, major_index: usize, minor_index: usize)
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-> Option<SparseEntryMut<T>> {
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let row_range = self.get_index_range(major_index)?;
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let minor_dim = self.pattern().minor_dim();
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let (_, minor_indices, values) = self.cs_data_mut();
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let minor_indices = &minor_indices[row_range.clone()];
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let values = &mut values[row_range];
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get_mut_entry_from_slices(minor_dim, minor_indices, values, minor_index)
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}
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pub fn get_lane(&self, index: usize) -> Option<CsLane<T>> {
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let range = self.get_index_range(index)?;
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let (_, minor_indices, values) = self.cs_data();
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Some(CsLane {
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minor_indices: &minor_indices[range.clone()],
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values: &values[range],
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minor_dim: self.pattern().minor_dim()
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})
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}
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#[inline]
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pub fn get_lane_mut(&mut self, index: usize) -> Option<CsLaneMut<T>> {
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let range = self.get_index_range(index)?;
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let minor_dim = self.pattern().minor_dim();
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let (_, minor_indices, values) = self.cs_data_mut();
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Some(CsLaneMut {
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minor_dim,
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minor_indices: &minor_indices[range.clone()],
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values: &mut values[range]
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})
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}
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2020-12-30 23:09:46 +08:00
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#[inline]
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pub fn lane_iter(&self) -> CsLaneIter<T> {
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CsLaneIter::new(self.pattern().as_ref(), self.values())
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}
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#[inline]
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pub fn lane_iter_mut(&mut self) -> CsLaneIterMut<T> {
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CsLaneIterMut::new(self.sparsity_pattern.as_ref(), &mut self.values)
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}
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2021-01-15 00:12:08 +08:00
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#[inline]
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pub fn filter<P>(&self, predicate: P) -> Self
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where
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T: Clone,
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P: Fn(usize, usize, &T) -> bool
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{
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let (major_dim, minor_dim) = (self.pattern().major_dim(), self.pattern().minor_dim());
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let mut new_offsets = Vec::with_capacity(self.pattern().major_dim() + 1);
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let mut new_indices = Vec::new();
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let mut new_values = Vec::new();
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new_offsets.push(0);
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for (i, lane) in self.lane_iter().enumerate() {
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for (&j, value) in lane.minor_indices().iter().zip(lane.values) {
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if predicate(i, j, value) {
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new_indices.push(j);
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new_values.push(value.clone());
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}
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}
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new_offsets.push(new_indices.len());
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}
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// TODO: Avoid checks here
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let new_pattern = SparsityPattern::try_from_offsets_and_indices(
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major_dim,
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minor_dim,
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new_offsets,
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new_indices)
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.expect("Internal error: Sparsity pattern must always be valid.");
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Self::from_pattern_and_values(Arc::new(new_pattern), new_values)
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}
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2020-12-22 17:19:17 +08:00
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}
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2021-01-11 22:03:58 +08:00
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impl<T: Scalar + One> CsMatrix<T> {
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/// TODO
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#[inline]
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pub fn identity(n: usize) -> Self {
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let offsets: Vec<_> = (0 ..= n).collect();
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let indices: Vec<_> = (0 .. n).collect();
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let values = vec![T::one(); n];
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// TODO: We should skip checks here
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let pattern = SparsityPattern::try_from_offsets_and_indices(n, n, offsets, indices)
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.unwrap();
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Self::from_pattern_and_values(Arc::new(pattern), values)
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}
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}
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2020-12-30 23:09:46 +08:00
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fn get_entry_from_slices<'a, T>(
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2020-12-22 17:19:17 +08:00
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minor_dim: usize,
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minor_indices: &'a [usize],
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values: &'a [T],
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global_minor_index: usize) -> Option<SparseEntry<'a, T>> {
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let local_index = minor_indices.binary_search(&global_minor_index);
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if let Ok(local_index) = local_index {
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Some(SparseEntry::NonZero(&values[local_index]))
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} else if global_minor_index < minor_dim {
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Some(SparseEntry::Zero)
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} else {
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None
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}
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}
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2020-12-30 23:09:46 +08:00
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fn get_mut_entry_from_slices<'a, T>(
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2020-12-22 17:19:17 +08:00
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minor_dim: usize,
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minor_indices: &'a [usize],
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values: &'a mut [T],
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global_minor_indices: usize) -> Option<SparseEntryMut<'a, T>> {
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let local_index = minor_indices.binary_search(&global_minor_indices);
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if let Ok(local_index) = local_index {
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Some(SparseEntryMut::NonZero(&mut values[local_index]))
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} else if global_minor_indices < minor_dim {
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Some(SparseEntryMut::Zero)
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} else {
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None
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}
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}
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#[derive(Debug, Clone, PartialEq, Eq)]
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pub struct CsLane<'a, T> {
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2020-12-30 23:09:46 +08:00
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minor_dim: usize,
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minor_indices: &'a [usize],
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values: &'a [T]
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2020-12-22 17:19:17 +08:00
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}
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#[derive(Debug, PartialEq, Eq)]
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pub struct CsLaneMut<'a, T> {
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minor_dim: usize,
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minor_indices: &'a [usize],
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values: &'a mut [T]
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2020-12-22 17:19:17 +08:00
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}
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pub struct CsLaneIter<'a, T> {
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// The index of the lane that will be returned on the next iteration
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current_lane_idx: usize,
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pattern: &'a SparsityPattern,
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remaining_values: &'a [T],
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}
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impl<'a, T> CsLaneIter<'a, T> {
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pub fn new(pattern: &'a SparsityPattern, values: &'a [T]) -> Self {
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Self {
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current_lane_idx: 0,
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pattern,
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remaining_values: values
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}
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}
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}
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impl<'a, T> Iterator for CsLaneIter<'a, T>
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where
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T: 'a
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{
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type Item = CsLane<'a, T>;
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fn next(&mut self) -> Option<Self::Item> {
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let lane = self.pattern.get_lane(self.current_lane_idx);
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let minor_dim = self.pattern.minor_dim();
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if let Some(minor_indices) = lane {
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let count = minor_indices.len();
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let values_in_lane = &self.remaining_values[..count];
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self.remaining_values = &self.remaining_values[count ..];
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self.current_lane_idx += 1;
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Some(CsLane {
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minor_dim,
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minor_indices,
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values: values_in_lane
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})
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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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pub struct CsLaneIterMut<'a, T> {
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// The index of the lane that will be returned on the next iteration
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current_lane_idx: usize,
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pattern: &'a SparsityPattern,
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2020-12-22 18:01:50 +08:00
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remaining_values: &'a mut [T],
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2020-12-22 17:19:17 +08:00
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}
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impl<'a, T> CsLaneIterMut<'a, T> {
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pub fn new(pattern: &'a SparsityPattern, values: &'a mut [T]) -> Self {
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Self {
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current_lane_idx: 0,
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pattern,
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2020-12-22 18:01:50 +08:00
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remaining_values: values
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2020-12-22 17:19:17 +08:00
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}
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}
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}
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impl<'a, T> Iterator for CsLaneIterMut<'a, T>
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where
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T: 'a
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{
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type Item = CsLaneMut<'a, T>;
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fn next(&mut self) -> Option<Self::Item> {
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let lane = self.pattern.get_lane(self.current_lane_idx);
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let minor_dim = self.pattern.minor_dim();
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if let Some(minor_indices) = lane {
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let count = minor_indices.len();
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2020-12-22 18:01:50 +08:00
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let remaining = replace(&mut self.remaining_values, &mut []);
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let (values_in_lane, remaining) = remaining.split_at_mut(count);
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self.remaining_values = remaining;
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2020-12-22 17:19:17 +08:00
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self.current_lane_idx += 1;
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Some(CsLaneMut {
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minor_dim,
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minor_indices,
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values: values_in_lane
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})
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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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2020-12-30 23:09:46 +08:00
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/// Implement the methods common to both CsLane and CsLaneMut. See the documentation for the
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/// methods delegated here by CsrMatrix and CscMatrix members for more information.
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macro_rules! impl_cs_lane_common_methods {
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($name:ty) => {
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impl<'a, T> $name {
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#[inline]
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pub fn minor_dim(&self) -> usize {
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self.minor_dim
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}
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#[inline]
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pub fn nnz(&self) -> usize {
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self.minor_indices.len()
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}
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#[inline]
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pub fn minor_indices(&self) -> &[usize] {
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self.minor_indices
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}
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#[inline]
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pub fn values(&self) -> &[T] {
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self.values
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}
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#[inline]
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pub fn get_entry(&self, global_col_index: usize) -> Option<SparseEntry<T>> {
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get_entry_from_slices(
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self.minor_dim,
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self.minor_indices,
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self.values,
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global_col_index)
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}
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}
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}
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}
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impl_cs_lane_common_methods!(CsLane<'a, T>);
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impl_cs_lane_common_methods!(CsLaneMut<'a, T>);
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impl<'a, T> CsLaneMut<'a, T> {
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pub fn values_mut(&mut self) -> &mut [T] {
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self.values
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}
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2020-12-22 17:19:17 +08:00
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2020-12-30 23:09:46 +08:00
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pub fn indices_and_values_mut(&mut self) -> (&[usize], &mut [T]) {
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(self.minor_indices, self.values)
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}
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pub fn get_entry_mut(&mut self, global_minor_index: usize) -> Option<SparseEntryMut<T>> {
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get_mut_entry_from_slices(self.minor_dim,
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self.minor_indices,
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self.values,
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global_minor_index)
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}
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2021-01-19 21:15:19 +08:00
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}
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/// Helper struct for working with uninitialized data in vectors.
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/// TODO: This doesn't belong here.
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struct UninitVec<T> {
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vec: Vec<T>
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}
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impl<T> UninitVec<T> {
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pub fn from_len(len: usize) -> Self {
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Self {
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vec: Vec::with_capacity(len)
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}
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}
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/// Sets the element associated with the given index to the provided value.
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///
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/// Must be called exactly once per index, otherwise results in undefined behavior.
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pub unsafe fn set(&mut self, index: usize, value: T) {
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self.vec.as_mut_ptr().add(index).write(value)
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}
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/// Marks the vector data as initialized by returning a full vector.
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///
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/// It is undefined behavior to call this function unless *all* elements have been written to
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/// exactly once.
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pub unsafe fn assume_init(mut self) -> Vec<T> {
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self.vec.set_len(self.vec.capacity());
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self.vec
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}
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}
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/// Transposes the compressed format.
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///
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/// This means that major and minor roles are switched. This is used for converting between CSR
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/// and CSC formats.
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pub fn transpose_cs<T>(
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major_dim: usize,
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minor_dim: usize,
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source_major_offsets: &[usize],
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source_minor_indices: &[usize],
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values: &[T])
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-> (Vec<usize>, Vec<usize>, Vec<T>)
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where
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T: Scalar
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{
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assert_eq!(source_major_offsets.len(), major_dim + 1);
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assert_eq!(source_minor_indices.len(), values.len());
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let nnz = values.len();
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// Count the number of occurences of each minor index
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let mut minor_counts = vec![0; minor_dim];
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for minor_idx in source_minor_indices {
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minor_counts[*minor_idx] += 1;
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}
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convert_counts_to_offsets(&mut minor_counts);
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let mut target_offsets = minor_counts;
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target_offsets.push(nnz);
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let mut target_indices = vec![usize::MAX; nnz];
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// We have to use uninitialized storage, because we don't have any kind of "default" value
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// available for `T`. Unfortunately this necessitates some small amount of unsafe code
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let mut target_values = UninitVec::from_len(nnz);
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// Keep track of how many entries we have placed in each target major lane
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let mut current_target_major_counts = vec![0; minor_dim];
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for source_major_idx in 0 .. major_dim {
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let source_lane_begin = source_major_offsets[source_major_idx];
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let source_lane_end = source_major_offsets[source_major_idx + 1];
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let source_lane_indices = &source_minor_indices[source_lane_begin .. source_lane_end];
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let source_lane_values = &values[source_lane_begin .. source_lane_end];
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for (&source_minor_idx, val) in source_lane_indices.iter().zip(source_lane_values) {
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// Compute the offset in the target data for this particular source entry
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let target_lane_count = &mut current_target_major_counts[source_minor_idx];
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let entry_offset = target_offsets[source_minor_idx] + *target_lane_count;
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target_indices[entry_offset] = source_major_idx;
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unsafe { target_values.set(entry_offset, val.inlined_clone()); }
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*target_lane_count += 1;
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}
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}
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// At this point, we should have written to each element in target_values exactly once,
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// so initialization should be sound
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let target_values = unsafe { target_values.assume_init() };
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(target_offsets, target_indices, target_values)
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}
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pub fn convert_counts_to_offsets(counts: &mut [usize]) {
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// Convert the counts to an offset
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let mut offset = 0;
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for i_offset in counts.iter_mut() {
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let count = *i_offset;
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*i_offset = offset;
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offset += count;
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}
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}
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