vendor/rayon/src/iter/chain.rs - toolchain/rustc - Git at Google

 use super::plumbing::*;
 use super::*;
 use std::cmp;
 use std::iter;
 use rayon_core::join;

 /// `Chain` is an iterator that joins `b` after `a` in one continuous iterator.
 /// This struct is created by the [`chain()`] method on [`ParallelIterator`]
 ///
 /// [`chain()`]: trait.ParallelIterator.html#method.chain
 /// [`ParallelIterator`]: trait.ParallelIterator.html
 #[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
 #[derive(Debug, Clone)]
 pub struct Chain<A, B>
     where A: ParallelIterator,
           B: ParallelIterator<Item = A::Item>
 {
     a: A,
     b: B,
 }

 /// Create a new `Chain` iterator.
 ///
 /// NB: a free fn because it is NOT part of the end-user API.
 pub fn new<A, B>(a: A, b: B) -> Chain<A, B>
     where A: ParallelIterator,
           B: ParallelIterator<Item = A::Item>
 {
     Chain { a: a, b: b }
 }

 impl<A, B> ParallelIterator for Chain<A, B>
     where A: ParallelIterator,
           B: ParallelIterator<Item = A::Item>
 {
     type Item = A::Item;

     fn drive_unindexed<C>(self, consumer: C) -> C::Result
         where C: UnindexedConsumer<Self::Item>
     {
         let Chain { a, b } = self;

         // If we returned a value from our own `opt_len`, then the collect consumer in particular
         // will balk at being treated like an actual `UnindexedConsumer`.  But when we do know the
         // length, we can use `Consumer::split_at` instead, and this is still harmless for other
         // truly-unindexed consumers too.
         let (left, right, reducer) = if let Some(len) = a.opt_len() {
             consumer.split_at(len)
         } else {
             let reducer = consumer.to_reducer();
             (consumer.split_off_left(), consumer, reducer)
         };

         let (a, b) = join(|| a.drive_unindexed(left), || b.drive_unindexed(right));
         reducer.reduce(a, b)
     }

     fn opt_len(&self) -> Option<usize> {
         match (self.a.opt_len(), self.b.opt_len()) {
             (Some(a_len), Some(b_len)) => a_len.checked_add(b_len),
             _ => None,
         }
     }
 }

 impl<A, B> IndexedParallelIterator for Chain<A, B>
     where A: IndexedParallelIterator,
           B: IndexedParallelIterator<Item = A::Item>
 {
     fn drive<C>(self, consumer: C) -> C::Result
         where C: Consumer<Self::Item>
     {
         let Chain { a, b } = self;
         let (left, right, reducer) = consumer.split_at(a.len());
         let (a, b) = join(|| a.drive(left), || b.drive(right));
         reducer.reduce(a, b)
     }

     fn len(&self) -> usize {
         self.a
             .len()
             .checked_add(self.b.len())
             .expect("overflow")
     }

     fn with_producer<CB>(self, callback: CB) -> CB::Output
         where CB: ProducerCallback<Self::Item>
     {
         let a_len = self.a.len();
         return self.a.with_producer(CallbackA {
                                         callback: callback,
                                         a_len: a_len,
                                         b: self.b,
                                     });

         struct CallbackA<CB, B> {
             callback: CB,
             a_len: usize,
             b: B,
         }

         impl<CB, B> ProducerCallback<B::Item> for CallbackA<CB, B>
             where B: IndexedParallelIterator,
                   CB: ProducerCallback<B::Item>
         {
             type Output = CB::Output;

             fn callback<A>(self, a_producer: A) -> Self::Output
                 where A: Producer<Item = B::Item>
             {
                 return self.b.with_producer(CallbackB {
                                                 callback: self.callback,
                                                 a_len: self.a_len,
                                                 a_producer: a_producer,
                                             });
             }
         }

         struct CallbackB<CB, A> {
             callback: CB,
             a_len: usize,
             a_producer: A,
         }

         impl<CB, A> ProducerCallback<A::Item> for CallbackB<CB, A>
             where A: Producer,
                   CB: ProducerCallback<A::Item>
         {
             type Output = CB::Output;

             fn callback<B>(self, b_producer: B) -> Self::Output
                 where B: Producer<Item = A::Item>
             {
                 let producer = ChainProducer::new(self.a_len, self.a_producer, b_producer);
                 self.callback.callback(producer)
             }
         }

     }
 }

 /// ////////////////////////////////////////////////////////////////////////

 struct ChainProducer<A, B>
     where A: Producer,
           B: Producer<Item = A::Item>
 {
     a_len: usize,
     a: A,
     b: B,
 }

 impl<A, B> ChainProducer<A, B>
     where A: Producer,
           B: Producer<Item = A::Item>
 {
     fn new(a_len: usize, a: A, b: B) -> Self {
         ChainProducer {
             a_len: a_len,
             a: a,
             b: b,
         }
     }
 }

 impl<A, B> Producer for ChainProducer<A, B>
     where A: Producer,
           B: Producer<Item = A::Item>
 {
     type Item = A::Item;
     type IntoIter = ChainSeq<A::IntoIter, B::IntoIter>;

     fn into_iter(self) -> Self::IntoIter {
         ChainSeq::new(self.a.into_iter(), self.b.into_iter())
     }

     fn min_len(&self) -> usize {
         cmp::max(self.a.min_len(), self.b.min_len())
     }

     fn max_len(&self) -> usize {
         cmp::min(self.a.max_len(), self.b.max_len())
     }

     fn split_at(self, index: usize) -> (Self, Self) {
         if index <= self.a_len {
             let a_rem = self.a_len - index;
             let (a_left, a_right) = self.a.split_at(index);
             let (b_left, b_right) = self.b.split_at(0);
             (ChainProducer::new(index, a_left, b_left), ChainProducer::new(a_rem, a_right, b_right))
         } else {
             let (a_left, a_right) = self.a.split_at(self.a_len);
             let (b_left, b_right) = self.b.split_at(index - self.a_len);
             (ChainProducer::new(self.a_len, a_left, b_left),
              ChainProducer::new(0, a_right, b_right))
         }
     }

     fn fold_with<F>(self, mut folder: F) -> F
         where F: Folder<A::Item>
     {
         folder = self.a.fold_with(folder);
         if folder.full() {
             folder
         } else {
             self.b.fold_with(folder)
         }
     }
 }

 /// ////////////////////////////////////////////////////////////////////////
 /// Wrapper for Chain to implement ExactSizeIterator

 struct ChainSeq<A, B> {
     chain: iter::Chain<A, B>,
 }

 impl<A, B> ChainSeq<A, B> {
     fn new(a: A, b: B) -> ChainSeq<A, B>
         where A: ExactSizeIterator,
               B: ExactSizeIterator<Item = A::Item>
     {
         ChainSeq { chain: a.chain(b) }
     }
 }

 impl<A, B> Iterator for ChainSeq<A, B>
     where A: Iterator,
           B: Iterator<Item = A::Item>
 {
     type Item = A::Item;

     fn next(&mut self) -> Option<Self::Item> {
         self.chain.next()
     }

     fn size_hint(&self) -> (usize, Option<usize>) {
         self.chain.size_hint()
     }
 }

 impl<A, B> ExactSizeIterator for ChainSeq<A, B>
     where A: ExactSizeIterator,
           B: ExactSizeIterator<Item = A::Item>
 {
 }

 impl<A, B> DoubleEndedIterator for ChainSeq<A, B>
     where A: DoubleEndedIterator,
           B: DoubleEndedIterator<Item = A::Item>
 {
     fn next_back(&mut self) -> Option<Self::Item> {
         self.chain.next_back()
     }
 }
	use super::plumbing::*;
	use super::*;
	use std::cmp;
	use std::iter;
	use rayon_core::join;

	/// `Chain` is an iterator that joins `b` after `a` in one continuous iterator.
	/// This struct is created by the [`chain()`] method on [`ParallelIterator`]
	///
	/// [`chain()`]: trait.ParallelIterator.html#method.chain
	/// [`ParallelIterator`]: trait.ParallelIterator.html
	#[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
	#[derive(Debug, Clone)]
	pub struct Chain<A, B>
	where A: ParallelIterator,
	B: ParallelIterator<Item = A::Item>
	{
	a: A,
	b: B,
	}

	/// Create a new `Chain` iterator.
	///
	/// NB: a free fn because it is NOT part of the end-user API.
	pub fn new<A, B>(a: A, b: B) -> Chain<A, B>
	where A: ParallelIterator,
	B: ParallelIterator<Item = A::Item>
	{
	Chain { a: a, b: b }
	}

	impl<A, B> ParallelIterator for Chain<A, B>
	where A: ParallelIterator,
	B: ParallelIterator<Item = A::Item>
	{
	type Item = A::Item;

	fn drive_unindexed<C>(self, consumer: C) -> C::Result
	where C: UnindexedConsumer<Self::Item>
	{
	let Chain { a, b } = self;

	// If we returned a value from our own `opt_len`, then the collect consumer in particular
	// will balk at being treated like an actual `UnindexedConsumer`. But when we do know the
	// length, we can use `Consumer::split_at` instead, and this is still harmless for other
	// truly-unindexed consumers too.
	let (left, right, reducer) = if let Some(len) = a.opt_len() {
	consumer.split_at(len)
	} else {
	let reducer = consumer.to_reducer();
	(consumer.split_off_left(), consumer, reducer)
	};

	let (a, b) = join(\|\| a.drive_unindexed(left), \|\| b.drive_unindexed(right));
	reducer.reduce(a, b)
	}

	fn opt_len(&self) -> Option<usize> {
	match (self.a.opt_len(), self.b.opt_len()) {
	(Some(a_len), Some(b_len)) => a_len.checked_add(b_len),
	_ => None,
	}
	}
	}

	impl<A, B> IndexedParallelIterator for Chain<A, B>
	where A: IndexedParallelIterator,
	B: IndexedParallelIterator<Item = A::Item>
	{
	fn drive<C>(self, consumer: C) -> C::Result
	where C: Consumer<Self::Item>
	{
	let Chain { a, b } = self;
	let (left, right, reducer) = consumer.split_at(a.len());
	let (a, b) = join(\|\| a.drive(left), \|\| b.drive(right));
	reducer.reduce(a, b)
	}

	fn len(&self) -> usize {
	self.a
	.len()
	.checked_add(self.b.len())
	.expect("overflow")
	}

	fn with_producer<CB>(self, callback: CB) -> CB::Output
	where CB: ProducerCallback<Self::Item>
	{
	let a_len = self.a.len();
	return self.a.with_producer(CallbackA {
	callback: callback,
	a_len: a_len,
	b: self.b,
	});

	struct CallbackA<CB, B> {
	callback: CB,
	a_len: usize,
	b: B,
	}

	impl<CB, B> ProducerCallback<B::Item> for CallbackA<CB, B>
	where B: IndexedParallelIterator,
	CB: ProducerCallback<B::Item>
	{
	type Output = CB::Output;

	fn callback<A>(self, a_producer: A) -> Self::Output
	where A: Producer<Item = B::Item>
	{
	return self.b.with_producer(CallbackB {
	callback: self.callback,
	a_len: self.a_len,
	a_producer: a_producer,
	});
	}
	}

	struct CallbackB<CB, A> {
	callback: CB,
	a_len: usize,
	a_producer: A,
	}

	impl<CB, A> ProducerCallback<A::Item> for CallbackB<CB, A>
	where A: Producer,
	CB: ProducerCallback<A::Item>
	{
	type Output = CB::Output;

	fn callback<B>(self, b_producer: B) -> Self::Output
	where B: Producer<Item = A::Item>
	{
	let producer = ChainProducer::new(self.a_len, self.a_producer, b_producer);
	self.callback.callback(producer)
	}
	}

	}
	}

	/// ////////////////////////////////////////////////////////////////////////

	struct ChainProducer<A, B>
	where A: Producer,
	B: Producer<Item = A::Item>
	{
	a_len: usize,
	a: A,
	b: B,
	}

	impl<A, B> ChainProducer<A, B>
	where A: Producer,
	B: Producer<Item = A::Item>
	{
	fn new(a_len: usize, a: A, b: B) -> Self {
	ChainProducer {
	a_len: a_len,
	a: a,
	b: b,
	}
	}
	}

	impl<A, B> Producer for ChainProducer<A, B>
	where A: Producer,
	B: Producer<Item = A::Item>
	{
	type Item = A::Item;
	type IntoIter = ChainSeq<A::IntoIter, B::IntoIter>;

	fn into_iter(self) -> Self::IntoIter {
	ChainSeq::new(self.a.into_iter(), self.b.into_iter())
	}

	fn min_len(&self) -> usize {
	cmp::max(self.a.min_len(), self.b.min_len())
	}

	fn max_len(&self) -> usize {
	cmp::min(self.a.max_len(), self.b.max_len())
	}

	fn split_at(self, index: usize) -> (Self, Self) {
	if index <= self.a_len {
	let a_rem = self.a_len - index;
	let (a_left, a_right) = self.a.split_at(index);
	let (b_left, b_right) = self.b.split_at(0);
	(ChainProducer::new(index, a_left, b_left), ChainProducer::new(a_rem, a_right, b_right))
	} else {
	let (a_left, a_right) = self.a.split_at(self.a_len);
	let (b_left, b_right) = self.b.split_at(index - self.a_len);
	(ChainProducer::new(self.a_len, a_left, b_left),
	ChainProducer::new(0, a_right, b_right))
	}
	}

	fn fold_with<F>(self, mut folder: F) -> F
	where F: Folder<A::Item>
	{
	folder = self.a.fold_with(folder);
	if folder.full() {
	folder
	} else {
	self.b.fold_with(folder)
	}
	}
	}

	/// ////////////////////////////////////////////////////////////////////////
	/// Wrapper for Chain to implement ExactSizeIterator

	struct ChainSeq<A, B> {
	chain: iter::Chain<A, B>,
	}

	impl<A, B> ChainSeq<A, B> {
	fn new(a: A, b: B) -> ChainSeq<A, B>
	where A: ExactSizeIterator,
	B: ExactSizeIterator<Item = A::Item>
	{
	ChainSeq { chain: a.chain(b) }
	}
	}

	impl<A, B> Iterator for ChainSeq<A, B>
	where A: Iterator,
	B: Iterator<Item = A::Item>
	{
	type Item = A::Item;

	fn next(&mut self) -> Option<Self::Item> {
	self.chain.next()
	}

	fn size_hint(&self) -> (usize, Option<usize>) {
	self.chain.size_hint()
	}
	}

	impl<A, B> ExactSizeIterator for ChainSeq<A, B>
	where A: ExactSizeIterator,
	B: ExactSizeIterator<Item = A::Item>
	{
	}

	impl<A, B> DoubleEndedIterator for ChainSeq<A, B>
	where A: DoubleEndedIterator,
	B: DoubleEndedIterator<Item = A::Item>
	{
	fn next_back(&mut self) -> Option<Self::Item> {
	self.chain.next_back()
	}
	}