Adding upstream version 1.64.0+dfsg1.upstream/1.64.0+dfsg1

Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>

1 files changed, 336 insertions, 0 deletions

diff --git a/vendor/rustc-rayon/src/iter/interleave.rs b/vendor/rustc-rayon/src/iter/interleave.rs
new file mode 100644
index 000000000..b5d43d53d
--- /dev/null
+++ b/vendor/rustc-rayon/src/iter/interleave.rs
@@ -0,0 +1,336 @@
+use super::plumbing::*;
+use super::*;
+use std::cmp;
+use std::iter::Fuse;
+
+/// `Interleave` is an iterator that interleaves elements of iterators
+/// `i` and `j` in one continuous iterator. This struct is created by
+/// the [`interleave()`] method on [`IndexedParallelIterator`]
+///
+/// [`interleave()`]: trait.IndexedParallelIterator.html#method.interleave
+/// [`IndexedParallelIterator`]: trait.IndexedParallelIterator.html
+#[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
+#[derive(Debug, Clone)]
+pub struct Interleave<I, J>
+where
+    I: IndexedParallelIterator,
+    J: IndexedParallelIterator<Item = I::Item>,
+{
+    i: I,
+    j: J,
+}
+
+impl<I, J> Interleave<I, J>
+where
+    I: IndexedParallelIterator,
+    J: IndexedParallelIterator<Item = I::Item>,
+{
+    /// Creates a new `Interleave` iterator
+    pub(super) fn new(i: I, j: J) -> Self {
+        Interleave { i, j }
+    }
+}
+
+impl<I, J> ParallelIterator for Interleave<I, J>
+where
+    I: IndexedParallelIterator,
+    J: IndexedParallelIterator<Item = I::Item>,
+{
+    type Item = I::Item;
+
+    fn drive_unindexed<C>(self, consumer: C) -> C::Result
+    where
+        C: Consumer<I::Item>,
+    {
+        bridge(self, consumer)
+    }
+
+    fn opt_len(&self) -> Option<usize> {
+        Some(self.len())
+    }
+}
+
+impl<I, J> IndexedParallelIterator for Interleave<I, J>
+where
+    I: IndexedParallelIterator,
+    J: IndexedParallelIterator<Item = I::Item>,
+{
+    fn drive<C>(self, consumer: C) -> C::Result
+    where
+        C: Consumer<Self::Item>,
+    {
+        bridge(self, consumer)
+    }
+
+    fn len(&self) -> usize {
+        self.i.len().checked_add(self.j.len()).expect("overflow")
+    }
+
+    fn with_producer<CB>(self, callback: CB) -> CB::Output
+    where
+        CB: ProducerCallback<Self::Item>,
+    {
+        let (i_len, j_len) = (self.i.len(), self.j.len());
+        return self.i.with_producer(CallbackI {
+            callback,
+            i_len,
+            j_len,
+            i_next: false,
+            j: self.j,
+        });
+
+        struct CallbackI<CB, J> {
+            callback: CB,
+            i_len: usize,
+            j_len: usize,
+            i_next: bool,
+            j: J,
+        }
+
+        impl<CB, J> ProducerCallback<J::Item> for CallbackI<CB, J>
+        where
+            J: IndexedParallelIterator,
+            CB: ProducerCallback<J::Item>,
+        {
+            type Output = CB::Output;
+
+            fn callback<I>(self, i_producer: I) -> Self::Output
+            where
+                I: Producer<Item = J::Item>,
+            {
+                self.j.with_producer(CallbackJ {
+                    i_producer,
+                    i_len: self.i_len,
+                    j_len: self.j_len,
+                    i_next: self.i_next,
+                    callback: self.callback,
+                })
+            }
+        }
+
+        struct CallbackJ<CB, I> {
+            callback: CB,
+            i_len: usize,
+            j_len: usize,
+            i_next: bool,
+            i_producer: I,
+        }
+
+        impl<CB, I> ProducerCallback<I::Item> for CallbackJ<CB, I>
+        where
+            I: Producer,
+            CB: ProducerCallback<I::Item>,
+        {
+            type Output = CB::Output;
+
+            fn callback<J>(self, j_producer: J) -> Self::Output
+            where
+                J: Producer<Item = I::Item>,
+            {
+                let producer = InterleaveProducer::new(
+                    self.i_producer,
+                    j_producer,
+                    self.i_len,
+                    self.j_len,
+                    self.i_next,
+                );
+                self.callback.callback(producer)
+            }
+        }
+    }
+}
+
+struct InterleaveProducer<I, J>
+where
+    I: Producer,
+    J: Producer<Item = I::Item>,
+{
+    i: I,
+    j: J,
+    i_len: usize,
+    j_len: usize,
+    i_next: bool,
+}
+
+impl<I, J> InterleaveProducer<I, J>
+where
+    I: Producer,
+    J: Producer<Item = I::Item>,
+{
+    fn new(i: I, j: J, i_len: usize, j_len: usize, i_next: bool) -> InterleaveProducer<I, J> {
+        InterleaveProducer {
+            i,
+            j,
+            i_len,
+            j_len,
+            i_next,
+        }
+    }
+}
+
+impl<I, J> Producer for InterleaveProducer<I, J>
+where
+    I: Producer,
+    J: Producer<Item = I::Item>,
+{
+    type Item = I::Item;
+    type IntoIter = InterleaveSeq<I::IntoIter, J::IntoIter>;
+
+    fn into_iter(self) -> Self::IntoIter {
+        InterleaveSeq {
+            i: self.i.into_iter().fuse(),
+            j: self.j.into_iter().fuse(),
+            i_next: self.i_next,
+        }
+    }
+
+    fn min_len(&self) -> usize {
+        cmp::max(self.i.min_len(), self.j.min_len())
+    }
+
+    fn max_len(&self) -> usize {
+        cmp::min(self.i.max_len(), self.j.max_len())
+    }
+
+    /// We know 0 < index <= self.i_len + self.j_len
+    ///
+    /// Find a, b satisfying:
+    ///
+    ///  (1) 0 < a <= self.i_len
+    ///  (2) 0 < b <= self.j_len
+    ///  (3) a + b == index
+    ///
+    /// For even splits, set a = b = index/2.
+    /// For odd splits, set a = (index/2)+1, b = index/2, if `i`
+    /// should yield the next element, otherwise, if `j` should yield
+    /// the next element, set a = index/2 and b = (index/2)+1
+    fn split_at(self, index: usize) -> (Self, Self) {
+        #[inline]
+        fn odd_offset(flag: bool) -> usize {
+            (!flag) as usize
+        }
+
+        let even = index % 2 == 0;
+        let idx = index >> 1;
+
+        // desired split
+        let (i_idx, j_idx) = (
+            idx + odd_offset(even || self.i_next),
+            idx + odd_offset(even || !self.i_next),
+        );
+
+        let (i_split, j_split) = if self.i_len >= i_idx && self.j_len >= j_idx {
+            (i_idx, j_idx)
+        } else if self.i_len >= i_idx {
+            // j too short
+            (index - self.j_len, self.j_len)
+        } else {
+            // i too short
+            (self.i_len, index - self.i_len)
+        };
+
+        let trailing_i_next = even == self.i_next;
+        let (i_left, i_right) = self.i.split_at(i_split);
+        let (j_left, j_right) = self.j.split_at(j_split);
+
+        (
+            InterleaveProducer::new(i_left, j_left, i_split, j_split, self.i_next),
+            InterleaveProducer::new(
+                i_right,
+                j_right,
+                self.i_len - i_split,
+                self.j_len - j_split,
+                trailing_i_next,
+            ),
+        )
+    }
+}
+
+/// Wrapper for Interleave to implement DoubleEndedIterator and
+/// ExactSizeIterator.
+///
+/// This iterator is fused.
+struct InterleaveSeq<I, J> {
+    i: Fuse<I>,
+    j: Fuse<J>,
+
+    /// Flag to control which iterator should provide the next element. When
+    /// `false` then `i` produces the next element, otherwise `j` produces the
+    /// next element.
+    i_next: bool,
+}
+
+/// Iterator implementation for InterleaveSeq. This implementation is
+/// taken more or less verbatim from itertools. It is replicated here
+/// (instead of calling itertools directly), because we also need to
+/// implement `DoubledEndedIterator` and `ExactSizeIterator`.
+impl<I, J> Iterator for InterleaveSeq<I, J>
+where
+    I: Iterator,
+    J: Iterator<Item = I::Item>,
+{
+    type Item = I::Item;
+
+    #[inline]
+    fn next(&mut self) -> Option<Self::Item> {
+        self.i_next = !self.i_next;
+        if self.i_next {
+            match self.i.next() {
+                None => self.j.next(),
+                r => r,
+            }
+        } else {
+            match self.j.next() {
+                None => self.i.next(),
+                r => r,
+            }
+        }
+    }
+
+    fn size_hint(&self) -> (usize, Option<usize>) {
+        let (ih, jh) = (self.i.size_hint(), self.j.size_hint());
+        let min = ih.0.saturating_add(jh.0);
+        let max = match (ih.1, jh.1) {
+            (Some(x), Some(y)) => x.checked_add(y),
+            _ => None,
+        };
+        (min, max)
+    }
+}
+
+// The implementation for DoubleEndedIterator requires
+// ExactSizeIterator to provide `next_back()`. The last element will
+// come from the iterator that runs out last (ie has the most elements
+// in it). If the iterators have the same number of elements, then the
+// last iterator will provide the last element.
+impl<I, J> DoubleEndedIterator for InterleaveSeq<I, J>
+where
+    I: DoubleEndedIterator + ExactSizeIterator,
+    J: DoubleEndedIterator<Item = I::Item> + ExactSizeIterator<Item = I::Item>,
+{
+    #[inline]
+    fn next_back(&mut self) -> Option<I::Item> {
+        if self.i.len() == self.j.len() {
+            if self.i_next {
+                self.i.next_back()
+            } else {
+                self.j.next_back()
+            }
+        } else if self.i.len() < self.j.len() {
+            self.j.next_back()
+        } else {
+            self.i.next_back()
+        }
+    }
+}
+
+impl<I, J> ExactSizeIterator for InterleaveSeq<I, J>
+where
+    I: ExactSizeIterator,
+    J: ExactSizeIterator<Item = I::Item>,
+{
+    #[inline]
+    fn len(&self) -> usize {
+        self.i.len() + self.j.len()
+    }
+}