crates/rayon/src/iter/collect/consumer.rs - platform/external/rust/android-crates-io - Git at Google

 use super::super::plumbing::*;
 use crate::SendPtr;
 use std::marker::PhantomData;
 use std::ptr;
 use std::slice;

 pub(super) struct CollectConsumer<'c, T: Send> {
     /// See `CollectResult` for explanation of why this is not a slice
     start: SendPtr<T>,
     len: usize,
     marker: PhantomData<&'c mut T>,
 }

 impl<T: Send> CollectConsumer<'_, T> {
     /// Create a collector for `len` items in the unused capacity of the vector.
     pub(super) fn appender(vec: &mut Vec<T>, len: usize) -> CollectConsumer<'_, T> {
         let start = vec.len();
         assert!(vec.capacity() - start >= len);

         // SAFETY: We already made sure to have the additional space allocated.
         // The pointer is derived from `Vec` directly, not through a `Deref`,
         // so it has provenance over the whole allocation.
         unsafe { CollectConsumer::new(vec.as_mut_ptr().add(start), len) }
     }
 }

 impl<'c, T: Send + 'c> CollectConsumer<'c, T> {
     /// The target memory is considered uninitialized, and will be
     /// overwritten without reading or dropping existing values.
     unsafe fn new(start: *mut T, len: usize) -> Self {
         CollectConsumer {
             start: SendPtr(start),
             len,
             marker: PhantomData,
         }
     }
 }

 /// CollectResult represents an initialized part of the target slice.
 ///
 /// This is a proxy owner of the elements in the slice; when it drops,
 /// the elements will be dropped, unless its ownership is released before then.
 #[must_use]
 pub(super) struct CollectResult<'c, T> {
     /// This pointer and length has the same representation as a slice,
     /// but retains the provenance of the entire array so that we can merge
     /// these regions together in `CollectReducer`.
     start: SendPtr<T>,
     total_len: usize,
     /// The current initialized length after `start`
     initialized_len: usize,
     /// Lifetime invariance guarantees that the data flows from consumer to result,
     /// especially for the `scope_fn` callback in `Collect::with_consumer`.
     invariant_lifetime: PhantomData<&'c mut &'c mut [T]>,
 }

 unsafe impl<'c, T> Send for CollectResult<'c, T> where T: Send {}

 impl<'c, T> CollectResult<'c, T> {
     /// The current length of the collect result
     pub(super) fn len(&self) -> usize {
         self.initialized_len
     }

     /// Release ownership of the slice of elements, and return the length
     pub(super) fn release_ownership(mut self) -> usize {
         let ret = self.initialized_len;
         self.initialized_len = 0;
         ret
     }
 }

 impl<'c, T> Drop for CollectResult<'c, T> {
     fn drop(&mut self) {
         // Drop the first `self.initialized_len` elements, which have been recorded
         // to be initialized by the folder.
         unsafe {
             ptr::drop_in_place(slice::from_raw_parts_mut(
                 self.start.0,
                 self.initialized_len,
             ));
         }
     }
 }

 impl<'c, T: Send + 'c> Consumer<T> for CollectConsumer<'c, T> {
     type Folder = CollectResult<'c, T>;
     type Reducer = CollectReducer;
     type Result = CollectResult<'c, T>;

     fn split_at(self, index: usize) -> (Self, Self, CollectReducer) {
         let CollectConsumer { start, len, .. } = self;

         // Produce new consumers.
         // SAFETY: This assert checks that `index` is a valid offset for `start`
         unsafe {
             assert!(index <= len);
             (
                 CollectConsumer::new(start.0, index),
                 CollectConsumer::new(start.0.add(index), len - index),
                 CollectReducer,
             )
         }
     }

     fn into_folder(self) -> Self::Folder {
         // Create a result/folder that consumes values and writes them
         // into the region after start. The initial result has length 0.
         CollectResult {
             start: self.start,
             total_len: self.len,
             initialized_len: 0,
             invariant_lifetime: PhantomData,
         }
     }

     fn full(&self) -> bool {
         false
     }
 }

 impl<'c, T: Send + 'c> Folder<T> for CollectResult<'c, T> {
     type Result = Self;

     fn consume(mut self, item: T) -> Self {
         assert!(
             self.initialized_len < self.total_len,
             "too many values pushed to consumer"
         );

         // SAFETY: The assert above is a bounds check for this write, and we
         // avoid assignment here so we do not drop an uninitialized T.
         unsafe {
             // Write item and increase the initialized length
             self.start.0.add(self.initialized_len).write(item);
             self.initialized_len += 1;
         }

         self
     }

     fn complete(self) -> Self::Result {
         // NB: We don't explicitly check that the local writes were complete,
         // but Collect will assert the total result length in the end.
         self
     }

     fn full(&self) -> bool {
         false
     }
 }

 /// Pretend to be unindexed for `special_collect_into_vec`,
 /// but we should never actually get used that way...
 impl<'c, T: Send + 'c> UnindexedConsumer<T> for CollectConsumer<'c, T> {
     fn split_off_left(&self) -> Self {
         unreachable!("CollectConsumer must be indexed!")
     }
     fn to_reducer(&self) -> Self::Reducer {
         CollectReducer
     }
 }

 /// CollectReducer combines adjacent chunks; the result must always
 /// be contiguous so that it is one combined slice.
 pub(super) struct CollectReducer;

 impl<'c, T> Reducer<CollectResult<'c, T>> for CollectReducer {
     fn reduce(
         self,
         mut left: CollectResult<'c, T>,
         right: CollectResult<'c, T>,
     ) -> CollectResult<'c, T> {
         // Merge if the CollectResults are adjacent and in left to right order
         // else: drop the right piece now and total length will end up short in the end,
         // when the correctness of the collected result is asserted.
         unsafe {
             let left_end = left.start.0.add(left.initialized_len);
             if left_end == right.start.0 {
                 left.total_len += right.total_len;
                 left.initialized_len += right.release_ownership();
             }
             left
         }
     }
 }
	use super::super::plumbing::*;
	use crate::SendPtr;
	use std::marker::PhantomData;
	use std::ptr;
	use std::slice;

	pub(super) struct CollectConsumer<'c, T: Send> {
	/// See `CollectResult` for explanation of why this is not a slice
	start: SendPtr<T>,
	len: usize,
	marker: PhantomData<&'c mut T>,
	}

	impl<T: Send> CollectConsumer<'_, T> {
	/// Create a collector for `len` items in the unused capacity of the vector.
	pub(super) fn appender(vec: &mut Vec<T>, len: usize) -> CollectConsumer<'_, T> {
	let start = vec.len();
	assert!(vec.capacity() - start >= len);

	// SAFETY: We already made sure to have the additional space allocated.
	// The pointer is derived from `Vec` directly, not through a `Deref`,
	// so it has provenance over the whole allocation.
	unsafe { CollectConsumer::new(vec.as_mut_ptr().add(start), len) }
	}
	}

	impl<'c, T: Send + 'c> CollectConsumer<'c, T> {
	/// The target memory is considered uninitialized, and will be
	/// overwritten without reading or dropping existing values.
	unsafe fn new(start: *mut T, len: usize) -> Self {
	CollectConsumer {
	start: SendPtr(start),
	len,
	marker: PhantomData,
	}
	}
	}

	/// CollectResult represents an initialized part of the target slice.
	///
	/// This is a proxy owner of the elements in the slice; when it drops,
	/// the elements will be dropped, unless its ownership is released before then.
	#[must_use]
	pub(super) struct CollectResult<'c, T> {
	/// This pointer and length has the same representation as a slice,
	/// but retains the provenance of the entire array so that we can merge
	/// these regions together in `CollectReducer`.
	start: SendPtr<T>,
	total_len: usize,
	/// The current initialized length after `start`
	initialized_len: usize,
	/// Lifetime invariance guarantees that the data flows from consumer to result,
	/// especially for the `scope_fn` callback in `Collect::with_consumer`.
	invariant_lifetime: PhantomData<&'c mut &'c mut [T]>,
	}

	unsafe impl<'c, T> Send for CollectResult<'c, T> where T: Send {}

	impl<'c, T> CollectResult<'c, T> {
	/// The current length of the collect result
	pub(super) fn len(&self) -> usize {
	self.initialized_len
	}

	/// Release ownership of the slice of elements, and return the length
	pub(super) fn release_ownership(mut self) -> usize {
	let ret = self.initialized_len;
	self.initialized_len = 0;
	ret
	}
	}

	impl<'c, T> Drop for CollectResult<'c, T> {
	fn drop(&mut self) {
	// Drop the first `self.initialized_len` elements, which have been recorded
	// to be initialized by the folder.
	unsafe {
	ptr::drop_in_place(slice::from_raw_parts_mut(
	self.start.0,
	self.initialized_len,
	));
	}
	}
	}

	impl<'c, T: Send + 'c> Consumer<T> for CollectConsumer<'c, T> {
	type Folder = CollectResult<'c, T>;
	type Reducer = CollectReducer;
	type Result = CollectResult<'c, T>;

	fn split_at(self, index: usize) -> (Self, Self, CollectReducer) {
	let CollectConsumer { start, len, .. } = self;

	// Produce new consumers.
	// SAFETY: This assert checks that `index` is a valid offset for `start`
	unsafe {
	assert!(index <= len);
	(
	CollectConsumer::new(start.0, index),
	CollectConsumer::new(start.0.add(index), len - index),
	CollectReducer,
	)
	}
	}

	fn into_folder(self) -> Self::Folder {
	// Create a result/folder that consumes values and writes them
	// into the region after start. The initial result has length 0.
	CollectResult {
	start: self.start,
	total_len: self.len,
	initialized_len: 0,
	invariant_lifetime: PhantomData,
	}
	}

	fn full(&self) -> bool {
	false
	}
	}

	impl<'c, T: Send + 'c> Folder<T> for CollectResult<'c, T> {
	type Result = Self;

	fn consume(mut self, item: T) -> Self {
	assert!(
	self.initialized_len < self.total_len,
	"too many values pushed to consumer"
	);

	// SAFETY: The assert above is a bounds check for this write, and we
	// avoid assignment here so we do not drop an uninitialized T.
	unsafe {
	// Write item and increase the initialized length
	self.start.0.add(self.initialized_len).write(item);
	self.initialized_len += 1;
	}

	self
	}

	fn complete(self) -> Self::Result {
	// NB: We don't explicitly check that the local writes were complete,
	// but Collect will assert the total result length in the end.
	self
	}

	fn full(&self) -> bool {
	false
	}
	}

	/// Pretend to be unindexed for `special_collect_into_vec`,
	/// but we should never actually get used that way...
	impl<'c, T: Send + 'c> UnindexedConsumer<T> for CollectConsumer<'c, T> {
	fn split_off_left(&self) -> Self {
	unreachable!("CollectConsumer must be indexed!")
	}
	fn to_reducer(&self) -> Self::Reducer {
	CollectReducer
	}
	}

	/// CollectReducer combines adjacent chunks; the result must always
	/// be contiguous so that it is one combined slice.
	pub(super) struct CollectReducer;

	impl<'c, T> Reducer<CollectResult<'c, T>> for CollectReducer {
	fn reduce(
	self,
	mut left: CollectResult<'c, T>,
	right: CollectResult<'c, T>,
	) -> CollectResult<'c, T> {
	// Merge if the CollectResults are adjacent and in left to right order
	// else: drop the right piece now and total length will end up short in the end,
	// when the correctness of the collected result is asserted.
	unsafe {
	let left_end = left.start.0.add(left.initialized_len);
	if left_end == right.start.0 {
	left.total_len += right.total_len;
	left.initialized_len += right.release_ownership();
	}
	left
	}
	}
	}