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//! Traits and functions used to implement parallel iteration. These are
//! low-level details -- users of parallel iterators should not need to
//! interact with them directly. See [the `plumbing` README][r] for a general overview.
//!
use crate::join_context;
use super::IndexedParallelIterator;
use std::cmp;
use std::usize;
/// The `ProducerCallback` trait is a kind of generic closure,
/// [analogous to `FnOnce`][FnOnce]. See [the corresponding section in
/// the plumbing README][r] for more details.
///
/// [r]: https://github.com/rayon-rs/rayon/blob/master/src/iter/plumbing/README.md#producer-callback
pub trait ProducerCallback<T> {
/// The type of value returned by this callback. Analogous to
/// [`Output` from the `FnOnce` trait][Output].
///
type Output;
/// Invokes the callback with the given producer as argument. The
/// key point of this trait is that this method is generic over
/// `P`, and hence implementors must be defined for any producer.
fn callback<P>(self, producer: P) -> Self::Output
where
P: Producer<Item = T>;
}
/// A `Producer` is effectively a "splittable `IntoIterator`". That
/// is, a producer is a value which can be converted into an iterator
/// at any time: at that point, it simply produces items on demand,
/// like any iterator. But what makes a `Producer` special is that,
/// *before* we convert to an iterator, we can also **split** it at a
/// particular point using the `split_at` method. This will yield up
/// two producers, one producing the items before that point, and one
/// producing the items after that point (these two producers can then
/// independently be split further, or be converted into iterators).
/// In Rayon, this splitting is used to divide between threads.
/// See [the `plumbing` README][r] for further details.
///
/// Note that each producer will always produce a fixed number of
/// items N. However, this number N is not queryable through the API;
/// the consumer is expected to track it.
///
/// NB. You might expect `Producer` to extend the `IntoIterator`
/// trait. However, [rust-lang/rust#20671][20671] prevents us from
/// declaring the DoubleEndedIterator and ExactSizeIterator
/// constraints on a required IntoIterator trait, so we inline
/// IntoIterator here until that issue is fixed.
///
pub trait Producer: Send + Sized {
/// The type of item that will be produced by this producer once
/// it is converted into an iterator.
type Item;
/// The type of iterator we will become.
type IntoIter: Iterator<Item = Self::Item> + DoubleEndedIterator + ExactSizeIterator;
/// Convert `self` into an iterator; at this point, no more parallel splits
/// are possible.
fn into_iter(self) -> Self::IntoIter;
/// The minimum number of items that we will process
/// sequentially. Defaults to 1, which means that we will split
/// all the way down to a single item. This can be raised higher
/// using the [`with_min_len`] method, which will force us to
/// create sequential tasks at a larger granularity. Note that
/// Rayon automatically normally attempts to adjust the size of
/// parallel splits to reduce overhead, so this should not be
/// needed.
///
/// [`with_min_len`]: ../trait.IndexedParallelIterator.html#method.with_min_len
fn min_len(&self) -> usize {
1
}
/// The maximum number of items that we will process
/// sequentially. Defaults to MAX, which means that we can choose
/// not to split at all. This can be lowered using the
/// [`with_max_len`] method, which will force us to create more
/// parallel tasks. Note that Rayon automatically normally
/// attempts to adjust the size of parallel splits to reduce
/// overhead, so this should not be needed.
///
/// [`with_max_len`]: ../trait.IndexedParallelIterator.html#method.with_max_len
fn max_len(&self) -> usize {
usize::MAX
}
/// Split into two producers; one produces items `0..index`, the
/// other `index..N`. Index must be less than or equal to `N`.
fn split_at(self, index: usize) -> (Self, Self);
/// Iterate the producer, feeding each element to `folder`, and
/// stop when the folder is full (or all elements have been consumed).
///
/// The provided implementation is sufficient for most iterables.
fn fold_with<F>(self, folder: F) -> F
where
F: Folder<Self::Item>,
{
folder.consume_iter(self.into_iter())
}
}
/// A consumer is effectively a [generalized "fold" operation][fold],
/// and in fact each consumer will eventually be converted into a
/// [`Folder`]. What makes a consumer special is that, like a
/// [`Producer`], it can be **split** into multiple consumers using
/// the `split_at` method. When a consumer is split, it produces two
/// consumers, as well as a **reducer**. The two consumers can be fed
/// items independently, and when they are done the reducer is used to
/// combine their two results into one. See [the `plumbing`
/// README][r] for further details.
///
/// [`Folder`]: trait.Folder.html
/// [`Producer`]: trait.Producer.html
pub trait Consumer<Item>: Send + Sized {
/// The type of folder that this consumer can be converted into.
type Folder: Folder<Item, Result = Self::Result>;
/// The type of reducer that is produced if this consumer is split.
type Reducer: Reducer<Self::Result>;
/// The type of result that this consumer will ultimately produce.
type Result: Send;
/// Divide the consumer into two consumers, one processing items
/// `0..index` and one processing items from `index..`. Also
/// produces a reducer that can be used to reduce the results at
/// the end.
fn split_at(self, index: usize) -> (Self, Self, Self::Reducer);
/// Convert the consumer into a folder that can consume items
/// sequentially, eventually producing a final result.
fn into_folder(self) -> Self::Folder;
/// Hint whether this `Consumer` would like to stop processing
/// further items, e.g. if a search has been completed.
fn full(&self) -> bool;
}
/// The `Folder` trait encapsulates [the standard fold
/// operation][fold]. It can be fed many items using the `consume`
/// method. At the end, once all items have been consumed, it can then
/// be converted (using `complete`) into a final value.
///
pub trait Folder<Item>: Sized {
/// The type of result that will ultimately be produced by the folder.
type Result;
/// Consume next item and return new sequential state.
fn consume(self, item: Item) -> Self;
/// Consume items from the iterator until full, and return new sequential state.
///
/// This method is **optional**. The default simply iterates over
/// `iter`, invoking `consume` and checking after each iteration
/// whether `full` returns false.
///
/// The main reason to override it is if you can provide a more
/// specialized, efficient implementation.
fn consume_iter<I>(mut self, iter: I) -> Self
where
I: IntoIterator<Item = Item>,
{
for item in iter {
self = self.consume(item);
if self.full() {
break;
}
}
self
}
/// Finish consuming items, produce final result.
fn complete(self) -> Self::Result;
/// Hint whether this `Folder` would like to stop processing
/// further items, e.g. if a search has been completed.
fn full(&self) -> bool;
}
/// The reducer is the final step of a `Consumer` -- after a consumer
/// has been split into two parts, and each of those parts has been
/// fully processed, we are left with two results. The reducer is then
/// used to combine those two results into one. See [the `plumbing`
/// README][r] for further details.
///
pub trait Reducer<Result> {
/// Reduce two final results into one; this is executed after a
/// split.
fn reduce(self, left: Result, right: Result) -> Result;
}
/// A stateless consumer can be freely copied. These consumers can be
/// used like regular consumers, but they also support a
/// `split_off_left` method that does not take an index to split, but
/// simply splits at some arbitrary point (`for_each`, for example,
/// produces an unindexed consumer).
pub trait UnindexedConsumer<I>: Consumer<I> {
/// Splits off a "left" consumer and returns it. The `self`
/// consumer should then be used to consume the "right" portion of
/// the data. (The ordering matters for methods like find_first --
/// values produced by the returned value are given precedence
/// over values produced by `self`.) Once the left and right
/// halves have been fully consumed, you should reduce the results
/// with the result of `to_reducer`.
fn split_off_left(&self) -> Self;
/// Creates a reducer that can be used to combine the results from
/// a split consumer.
fn to_reducer(&self) -> Self::Reducer;
}
/// A variant on `Producer` which does not know its exact length or
/// cannot represent it in a `usize`. These producers act like
/// ordinary producers except that they cannot be told to split at a
/// particular point. Instead, you just ask them to split 'somewhere'.
///
/// (In principle, `Producer` could extend this trait; however, it
/// does not because to do so would require producers to carry their
/// own length with them.)
pub trait UnindexedProducer: Send + Sized {
/// The type of item returned by this producer.
type Item;
/// Split midway into a new producer if possible, otherwise return `None`.
fn split(self) -> (Self, Option<Self>);
/// Iterate the producer, feeding each element to `folder`, and
/// stop when the folder is full (or all elements have been consumed).
fn fold_with<F>(self, folder: F) -> F
where
F: Folder<Self::Item>;
}
/// A splitter controls the policy for splitting into smaller work items.
///
/// Thief-splitting is an adaptive policy that starts by splitting into
/// enough jobs for every worker thread, and then resets itself whenever a
/// job is actually stolen into a different thread.
#[derive(Clone, Copy)]
struct Splitter {
/// The `splits` tell us approximately how many remaining times we'd
/// like to split this job. We always just divide it by two though, so
/// the effective number of pieces will be `next_power_of_two()`.
splits: usize,
}
impl Splitter {
#[inline]
fn new() -> Splitter {
Splitter {
splits: crate::current_num_threads(),
}
}
#[inline]
fn try_split(&mut self, stolen: bool) -> bool {
let Splitter { splits } = *self;
if stolen {
// This job was stolen! Reset the number of desired splits to the
// thread count, if that's more than we had remaining anyway.
self.splits = cmp::max(crate::current_num_threads(), self.splits / 2);
true
} else if splits > 0 {
// We have splits remaining, make it so.
self.splits /= 2;
true
} else {
// Not stolen, and no more splits -- we're done!
false
}
}
}
/// The length splitter is built on thief-splitting, but additionally takes
/// into account the remaining length of the iterator.
#[derive(Clone, Copy)]
struct LengthSplitter {
inner: Splitter,
/// The smallest we're willing to divide into. Usually this is just 1,
/// but you can choose a larger working size with `with_min_len()`.
min: usize,
}
impl LengthSplitter {
/// Creates a new splitter based on lengths.
///
/// The `min` is a hard lower bound. We'll never split below that, but
/// of course an iterator might start out smaller already.
///
/// The `max` is an upper bound on the working size, used to determine
/// the minimum number of times we need to split to get under that limit.
/// The adaptive algorithm may very well split even further, but never
/// smaller than the `min`.
#[inline]
fn new(min: usize, max: usize, len: usize) -> LengthSplitter {
let mut splitter = LengthSplitter {
inner: Splitter::new(),
min: cmp::max(min, 1),
};
// Divide the given length by the max working length to get the minimum
// number of splits we need to get under that max. This rounds down,
// but the splitter actually gives `next_power_of_two()` pieces anyway.
// e.g. len 12345 / max 100 = 123 min_splits -> 128 pieces.
let min_splits = len / cmp::max(max, 1);
// Only update the value if it's not splitting enough already.
if min_splits > splitter.inner.splits {
splitter.inner.splits = min_splits;
}
splitter
}
#[inline]
fn try_split(&mut self, len: usize, stolen: bool) -> bool {
// If splitting wouldn't make us too small, try the inner splitter.
len / 2 >= self.min && self.inner.try_split(stolen)
}
}
/// This helper function is used to "connect" a parallel iterator to a
/// consumer. It will convert the `par_iter` into a producer P and
/// then pull items from P and feed them to `consumer`, splitting and
/// creating parallel threads as needed.
///
/// This is useful when you are implementing your own parallel
/// iterators: it is often used as the definition of the
/// [`drive_unindexed`] or [`drive`] methods.
///
/// [`drive_unindexed`]: ../trait.ParallelIterator.html#tymethod.drive_unindexed
/// [`drive`]: ../trait.IndexedParallelIterator.html#tymethod.drive
pub fn bridge<I, C>(par_iter: I, consumer: C) -> C::Result
where
I: IndexedParallelIterator,
C: Consumer<I::Item>,
{
let len = par_iter.len();
return par_iter.with_producer(Callback { len, consumer });
struct Callback<C> {
len: usize,
consumer: C,
}
impl<C, I> ProducerCallback<I> for Callback<C>
where
C: Consumer<I>,
{
type Output = C::Result;
fn callback<P>(self, producer: P) -> C::Result
where
P: Producer<Item = I>,
{
bridge_producer_consumer(self.len, producer, self.consumer)
}
}
}
/// This helper function is used to "connect" a producer and a
/// consumer. You may prefer to call [`bridge`], which wraps this
/// function. This function will draw items from `producer` and feed
/// them to `consumer`, splitting and creating parallel tasks when
/// needed.
///
/// This is useful when you are implementing your own parallel
/// iterators: it is often used as the definition of the
/// [`drive_unindexed`] or [`drive`] methods.
///
/// [`bridge`]: fn.bridge.html
/// [`drive_unindexed`]: ../trait.ParallelIterator.html#tymethod.drive_unindexed
/// [`drive`]: ../trait.IndexedParallelIterator.html#tymethod.drive
pub fn bridge_producer_consumer<P, C>(len: usize, producer: P, consumer: C) -> C::Result
where
P: Producer,
C: Consumer<P::Item>,
{
let splitter = LengthSplitter::new(producer.min_len(), producer.max_len(), len);
return helper(len, false, splitter, producer, consumer);
fn helper<P, C>(
len: usize,
migrated: bool,
mut splitter: LengthSplitter,
producer: P,
consumer: C,
) -> C::Result
where
P: Producer,
C: Consumer<P::Item>,
{
if consumer.full() {
consumer.into_folder().complete()
} else if splitter.try_split(len, migrated) {
let mid = len / 2;
let (left_producer, right_producer) = producer.split_at(mid);
let (left_consumer, right_consumer, reducer) = consumer.split_at(mid);
let (left_result, right_result) = join_context(
|context| {
helper(
mid,
context.migrated(),
splitter,
left_producer,
left_consumer,
)
},
|context| {
helper(
len - mid,
context.migrated(),
splitter,
right_producer,
right_consumer,
)
},
);
reducer.reduce(left_result, right_result)
} else {
producer.fold_with(consumer.into_folder()).complete()
}
}
}
/// A variant of [`bridge_producer_consumer`] where the producer is an unindexed producer.
///
/// [`bridge_producer_consumer`]: fn.bridge_producer_consumer.html
pub fn bridge_unindexed<P, C>(producer: P, consumer: C) -> C::Result
where
P: UnindexedProducer,
C: UnindexedConsumer<P::Item>,
{
let splitter = Splitter::new();
bridge_unindexed_producer_consumer(false, splitter, producer, consumer)
}
fn bridge_unindexed_producer_consumer<P, C>(
migrated: bool,
mut splitter: Splitter,
producer: P,
consumer: C,
) -> C::Result
where
P: UnindexedProducer,
C: UnindexedConsumer<P::Item>,
{
if consumer.full() {
consumer.into_folder().complete()
} else if splitter.try_split(migrated) {
match producer.split() {
(left_producer, Some(right_producer)) => {
let (reducer, left_consumer, right_consumer) =
(consumer.to_reducer(), consumer.split_off_left(), consumer);
let bridge = bridge_unindexed_producer_consumer;
let (left_result, right_result) = join_context(
|context| bridge(context.migrated(), splitter, left_producer, left_consumer),
|context| bridge(context.migrated(), splitter, right_producer, right_consumer),
);
reducer.reduce(left_result, right_result)
}
(producer, None) => producer.fold_with(consumer.into_folder()).complete(),
}
} else {
producer.fold_with(consumer.into_folder()).complete()
}
}