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//! An unbounded set of futures.
//!
//! This module is only available when the `std` or `alloc` feature of this
//! library is activated, and it is activated by default.
use crate::task::AtomicWaker;
use alloc::sync::{Arc, Weak};
use core::cell::UnsafeCell;
use core::cmp;
use core::fmt::{self, Debug};
use core::iter::FromIterator;
use core::marker::PhantomData;
use core::mem;
use core::pin::Pin;
use core::ptr;
use core::sync::atomic::Ordering::{AcqRel, Acquire, Relaxed, Release, SeqCst};
use core::sync::atomic::{AtomicBool, AtomicPtr};
use futures_core::future::Future;
use futures_core::stream::{FusedStream, Stream};
use futures_core::task::{Context, Poll};
use futures_task::{FutureObj, LocalFutureObj, LocalSpawn, Spawn, SpawnError};
mod abort;
mod iter;
pub use self::iter::{IntoIter, Iter, IterMut, IterPinMut, IterPinRef};
mod task;
use self::task::Task;
mod ready_to_run_queue;
use self::ready_to_run_queue::{Dequeue, ReadyToRunQueue};
/// Constant used for a `FuturesUnordered` to determine how many times it is
/// allowed to poll underlying futures without yielding.
///
/// A single call to `poll_next` may potentially do a lot of work before
/// yielding. This happens in particular if the underlying futures are awoken
/// frequently but continue to return `Pending`. This is problematic if other
/// tasks are waiting on the executor, since they do not get to run. This value
/// caps the number of calls to `poll` on underlying futures a single call to
/// `poll_next` is allowed to make.
///
/// The value itself is chosen somewhat arbitrarily. It needs to be high enough
/// that amortize wakeup and scheduling costs, but low enough that we do not
/// starve other tasks for long.
///
/// See also https://github.com/rust-lang/futures-rs/issues/2047.
///
/// Note that using the length of the `FuturesUnordered` instead of this value
/// may cause problems if the number of futures is large.
/// See also https://github.com/rust-lang/futures-rs/pull/2527.
///
/// Additionally, polling the same future twice per iteration may cause another
/// problem. So, when using this value, it is necessary to limit the max value
/// based on the length of the `FuturesUnordered`.
/// (e.g., `cmp::min(self.len(), YIELD_EVERY)`)
/// See also https://github.com/rust-lang/futures-rs/pull/2333.
const YIELD_EVERY: usize = 32;
/// A set of futures which may complete in any order.
///
/// This structure is optimized to manage a large number of futures.
/// Futures managed by [`FuturesUnordered`] will only be polled when they
/// generate wake-up notifications. This reduces the required amount of work
/// needed to poll large numbers of futures.
///
/// [`FuturesUnordered`] can be filled by [`collect`](Iterator::collect)ing an
/// iterator of futures into a [`FuturesUnordered`], or by
/// [`push`](FuturesUnordered::push)ing futures onto an existing
/// [`FuturesUnordered`]. When new futures are added,
/// [`poll_next`](Stream::poll_next) must be called in order to begin receiving
/// wake-ups for new futures.
///
/// Note that you can create a ready-made [`FuturesUnordered`] via the
/// [`collect`](Iterator::collect) method, or you can start with an empty set
/// with the [`FuturesUnordered::new`] constructor.
///
/// This type is only available when the `std` or `alloc` feature of this
/// library is activated, and it is activated by default.
#[must_use = "streams do nothing unless polled"]
pub struct FuturesUnordered<Fut> {
ready_to_run_queue: Arc<ReadyToRunQueue<Fut>>,
head_all: AtomicPtr<Task<Fut>>,
is_terminated: AtomicBool,
}
unsafe impl<Fut: Send> Send for FuturesUnordered<Fut> {}
unsafe impl<Fut: Sync> Sync for FuturesUnordered<Fut> {}
impl<Fut> Unpin for FuturesUnordered<Fut> {}
impl Spawn for FuturesUnordered<FutureObj<'_, ()>> {
fn spawn_obj(&self, future_obj: FutureObj<'static, ()>) -> Result<(), SpawnError> {
self.push(future_obj);
Ok(())
}
}
impl LocalSpawn for FuturesUnordered<LocalFutureObj<'_, ()>> {
fn spawn_local_obj(&self, future_obj: LocalFutureObj<'static, ()>) -> Result<(), SpawnError> {
self.push(future_obj);
Ok(())
}
}
// FuturesUnordered is implemented using two linked lists. One which links all
// futures managed by a `FuturesUnordered` and one that tracks futures that have
// been scheduled for polling. The first linked list allows for thread safe
// insertion of nodes at the head as well as forward iteration, but is otherwise
// not thread safe and is only accessed by the thread that owns the
// `FuturesUnordered` value for any other operations. The second linked list is
// an implementation of the intrusive MPSC queue algorithm described by
// 1024cores.net.
//
// When a future is submitted to the set, a task is allocated and inserted in
// both linked lists. The next call to `poll_next` will (eventually) see this
// task and call `poll` on the future.
//
// Before a managed future is polled, the current context's waker is replaced
// with one that is aware of the specific future being run. This ensures that
// wake-up notifications generated by that specific future are visible to
// `FuturesUnordered`. When a wake-up notification is received, the task is
// inserted into the ready to run queue, so that its future can be polled later.
//
// Each task is wrapped in an `Arc` and thereby atomically reference counted.
// Also, each task contains an `AtomicBool` which acts as a flag that indicates
// whether the task is currently inserted in the atomic queue. When a wake-up
// notification is received, the task will only be inserted into the ready to
// run queue if it isn't inserted already.
impl<Fut> Default for FuturesUnordered<Fut> {
fn default() -> Self {
Self::new()
}
}
impl<Fut> FuturesUnordered<Fut> {
/// Constructs a new, empty [`FuturesUnordered`].
///
/// The returned [`FuturesUnordered`] does not contain any futures.
/// In this state, [`FuturesUnordered::poll_next`](Stream::poll_next) will
/// return [`Poll::Ready(None)`](Poll::Ready).
pub fn new() -> Self {
let stub = Arc::new(Task {
future: UnsafeCell::new(None),
next_all: AtomicPtr::new(ptr::null_mut()),
prev_all: UnsafeCell::new(ptr::null()),
len_all: UnsafeCell::new(0),
next_ready_to_run: AtomicPtr::new(ptr::null_mut()),
queued: AtomicBool::new(true),
ready_to_run_queue: Weak::new(),
});
let stub_ptr = &*stub as *const Task<Fut>;
let ready_to_run_queue = Arc::new(ReadyToRunQueue {
waker: AtomicWaker::new(),
head: AtomicPtr::new(stub_ptr as *mut _),
tail: UnsafeCell::new(stub_ptr),
stub,
});
Self {
head_all: AtomicPtr::new(ptr::null_mut()),
ready_to_run_queue,
is_terminated: AtomicBool::new(false),
}
}
/// Returns the number of futures contained in the set.
///
/// This represents the total number of in-flight futures.
pub fn len(&self) -> usize {
let (_, len) = self.atomic_load_head_and_len_all();
len
}
/// Returns `true` if the set contains no futures.
pub fn is_empty(&self) -> bool {
// Relaxed ordering can be used here since we don't need to read from
// the head pointer, only check whether it is null.
self.head_all.load(Relaxed).is_null()
}
/// Push a future into the set.
///
/// This method adds the given future to the set. This method will not
/// call [`poll`](core::future::Future::poll) on the submitted future. The caller must
/// ensure that [`FuturesUnordered::poll_next`](Stream::poll_next) is called
/// in order to receive wake-up notifications for the given future.
pub fn push(&self, future: Fut) {
let task = Arc::new(Task {
future: UnsafeCell::new(Some(future)),
next_all: AtomicPtr::new(self.pending_next_all()),
prev_all: UnsafeCell::new(ptr::null_mut()),
len_all: UnsafeCell::new(0),
next_ready_to_run: AtomicPtr::new(ptr::null_mut()),
queued: AtomicBool::new(true),
ready_to_run_queue: Arc::downgrade(&self.ready_to_run_queue),
});
// Reset the `is_terminated` flag if we've previously marked ourselves
// as terminated.
self.is_terminated.store(false, Relaxed);
// Right now our task has a strong reference count of 1. We transfer
// ownership of this reference count to our internal linked list
// and we'll reclaim ownership through the `unlink` method below.
let ptr = self.link(task);
// We'll need to get the future "into the system" to start tracking it,
// e.g. getting its wake-up notifications going to us tracking which
// futures are ready. To do that we unconditionally enqueue it for
// polling here.
self.ready_to_run_queue.enqueue(ptr);
}
/// Returns an iterator that allows inspecting each future in the set.
pub fn iter(&self) -> Iter<'_, Fut>
where
Fut: Unpin,
{
Iter(Pin::new(self).iter_pin_ref())
}
/// Returns an iterator that allows inspecting each future in the set.
pub fn iter_pin_ref(self: Pin<&Self>) -> IterPinRef<'_, Fut> {
let (task, len) = self.atomic_load_head_and_len_all();
let pending_next_all = self.pending_next_all();
IterPinRef { task, len, pending_next_all, _marker: PhantomData }
}
/// Returns an iterator that allows modifying each future in the set.
pub fn iter_mut(&mut self) -> IterMut<'_, Fut>
where
Fut: Unpin,
{
IterMut(Pin::new(self).iter_pin_mut())
}
/// Returns an iterator that allows modifying each future in the set.
pub fn iter_pin_mut(mut self: Pin<&mut Self>) -> IterPinMut<'_, Fut> {
// `head_all` can be accessed directly and we don't need to spin on
// `Task::next_all` since we have exclusive access to the set.
let task = *self.head_all.get_mut();
let len = if task.is_null() { 0 } else { unsafe { *(*task).len_all.get() } };
IterPinMut { task, len, _marker: PhantomData }
}
/// Returns the current head node and number of futures in the list of all
/// futures within a context where access is shared with other threads
/// (mostly for use with the `len` and `iter_pin_ref` methods).
fn atomic_load_head_and_len_all(&self) -> (*const Task<Fut>, usize) {
let task = self.head_all.load(Acquire);
let len = if task.is_null() {
0
} else {
unsafe {
(*task).spin_next_all(self.pending_next_all(), Acquire);
*(*task).len_all.get()
}
};
(task, len)
}
/// Releases the task. It destroys the future inside and either drops
/// the `Arc<Task>` or transfers ownership to the ready to run queue.
/// The task this method is called on must have been unlinked before.
fn release_task(&mut self, task: Arc<Task<Fut>>) {
// `release_task` must only be called on unlinked tasks
debug_assert_eq!(task.next_all.load(Relaxed), self.pending_next_all());
unsafe {
debug_assert!((*task.prev_all.get()).is_null());
}
// The future is done, try to reset the queued flag. This will prevent
// `wake` from doing any work in the future
let prev = task.queued.swap(true, SeqCst);
// Drop the future, even if it hasn't finished yet. This is safe
// because we're dropping the future on the thread that owns
// `FuturesUnordered`, which correctly tracks `Fut`'s lifetimes and
// such.
unsafe {
// Set to `None` rather than `take()`ing to prevent moving the
// future.
*task.future.get() = None;
}
// If the queued flag was previously set, then it means that this task
// is still in our internal ready to run queue. We then transfer
// ownership of our reference count to the ready to run queue, and it'll
// come along and free it later, noticing that the future is `None`.
//
// If, however, the queued flag was *not* set then we're safe to
// release our reference count on the task. The queued flag was set
// above so all future `enqueue` operations will not actually
// enqueue the task, so our task will never see the ready to run queue
// again. The task itself will be deallocated once all reference counts
// have been dropped elsewhere by the various wakers that contain it.
if prev {
mem::forget(task);
}
}
/// Insert a new task into the internal linked list.
fn link(&self, task: Arc<Task<Fut>>) -> *const Task<Fut> {
// `next_all` should already be reset to the pending state before this
// function is called.
debug_assert_eq!(task.next_all.load(Relaxed), self.pending_next_all());
let ptr = Arc::into_raw(task);
// Atomically swap out the old head node to get the node that should be
// assigned to `next_all`.
let next = self.head_all.swap(ptr as *mut _, AcqRel);
unsafe {
// Store the new list length in the new node.
let new_len = if next.is_null() {
1
} else {
// Make sure `next_all` has been written to signal that it is
// safe to read `len_all`.
(*next).spin_next_all(self.pending_next_all(), Acquire);
*(*next).len_all.get() + 1
};
*(*ptr).len_all.get() = new_len;
// Write the old head as the next node pointer, signaling to other
// threads that `len_all` and `next_all` are ready to read.
(*ptr).next_all.store(next, Release);
// `prev_all` updates don't need to be synchronized, as the field is
// only ever used after exclusive access has been acquired.
if !next.is_null() {
*(*next).prev_all.get() = ptr;
}
}
ptr
}
/// Remove the task from the linked list tracking all tasks currently
/// managed by `FuturesUnordered`.
/// This method is unsafe because it has be guaranteed that `task` is a
/// valid pointer.
unsafe fn unlink(&mut self, task: *const Task<Fut>) -> Arc<Task<Fut>> {
// Compute the new list length now in case we're removing the head node
// and won't be able to retrieve the correct length later.
let head = *self.head_all.get_mut();
debug_assert!(!head.is_null());
let new_len = *(*head).len_all.get() - 1;
let task = Arc::from_raw(task);
let next = task.next_all.load(Relaxed);
let prev = *task.prev_all.get();
task.next_all.store(self.pending_next_all(), Relaxed);
*task.prev_all.get() = ptr::null_mut();
if !next.is_null() {
*(*next).prev_all.get() = prev;
}
if !prev.is_null() {
(*prev).next_all.store(next, Relaxed);
} else {
*self.head_all.get_mut() = next;
}
// Store the new list length in the head node.
let head = *self.head_all.get_mut();
if !head.is_null() {
*(*head).len_all.get() = new_len;
}
task
}
/// Returns the reserved value for `Task::next_all` to indicate a pending
/// assignment from the thread that inserted the task.
///
/// `FuturesUnordered::link` needs to update `Task` pointers in an order
/// that ensures any iterators created on other threads can correctly
/// traverse the entire `Task` list using the chain of `next_all` pointers.
/// This could be solved with a compare-exchange loop that stores the
/// current `head_all` in `next_all` and swaps out `head_all` with the new
/// `Task` pointer if the head hasn't already changed. Under heavy thread
/// contention, this compare-exchange loop could become costly.
///
/// An alternative is to initialize `next_all` to a reserved pending state
/// first, perform an atomic swap on `head_all`, and finally update
/// `next_all` with the old head node. Iterators will then either see the
/// pending state value or the correct next node pointer, and can reload
/// `next_all` as needed until the correct value is loaded. The number of
/// retries needed (if any) would be small and will always be finite, so
/// this should generally perform better than the compare-exchange loop.
///
/// A valid `Task` pointer in the `head_all` list is guaranteed to never be
/// this value, so it is safe to use as a reserved value until the correct
/// value can be written.
fn pending_next_all(&self) -> *mut Task<Fut> {
// The `ReadyToRunQueue` stub is never inserted into the `head_all`
// list, and its pointer value will remain valid for the lifetime of
// this `FuturesUnordered`, so we can make use of its value here.
&*self.ready_to_run_queue.stub as *const _ as *mut _
}
}
impl<Fut: Future> Stream for FuturesUnordered<Fut> {
type Item = Fut::Output;
fn poll_next(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
// See YIELD_EVERY docs for more.
let yield_every = cmp::min(self.len(), YIELD_EVERY);
// Keep track of how many child futures we have polled,
// in case we want to forcibly yield.
let mut polled = 0;
// Ensure `parent` is correctly set.
self.ready_to_run_queue.waker.register(cx.waker());
loop {
// Safety: &mut self guarantees the mutual exclusion `dequeue`
// expects
let task = match unsafe { self.ready_to_run_queue.dequeue() } {
Dequeue::Empty => {
if self.is_empty() {
// We can only consider ourselves terminated once we
// have yielded a `None`
*self.is_terminated.get_mut() = true;
return Poll::Ready(None);
} else {
return Poll::Pending;
}
}
Dequeue::Inconsistent => {
// At this point, it may be worth yielding the thread &
// spinning a few times... but for now, just yield using the
// task system.
cx.waker().wake_by_ref();
return Poll::Pending;
}
Dequeue::Data(task) => task,
};
debug_assert!(task != self.ready_to_run_queue.stub());
// Safety:
// - `task` is a valid pointer.
// - We are the only thread that accesses the `UnsafeCell` that
// contains the future
let future = match unsafe { &mut *(*task).future.get() } {
Some(future) => future,
// If the future has already gone away then we're just
// cleaning out this task. See the comment in
// `release_task` for more information, but we're basically
// just taking ownership of our reference count here.
None => {
// This case only happens when `release_task` was called
// for this task before and couldn't drop the task
// because it was already enqueued in the ready to run
// queue.
// Safety: `task` is a valid pointer
let task = unsafe { Arc::from_raw(task) };
// Double check that the call to `release_task` really
// happened. Calling it required the task to be unlinked.
debug_assert_eq!(task.next_all.load(Relaxed), self.pending_next_all());
unsafe {
debug_assert!((*task.prev_all.get()).is_null());
}
continue;
}
};
// Safety: `task` is a valid pointer
let task = unsafe { self.unlink(task) };
// Unset queued flag: This must be done before polling to ensure
// that the future's task gets rescheduled if it sends a wake-up
// notification **during** the call to `poll`.
let prev = task.queued.swap(false, SeqCst);
assert!(prev);
// We're going to need to be very careful if the `poll`
// method below panics. We need to (a) not leak memory and
// (b) ensure that we still don't have any use-after-frees. To
// manage this we do a few things:
//
// * A "bomb" is created which if dropped abnormally will call
// `release_task`. That way we'll be sure the memory management
// of the `task` is managed correctly. In particular
// `release_task` will drop the future. This ensures that it is
// dropped on this thread and not accidentally on a different
// thread (bad).
// * We unlink the task from our internal queue to preemptively
// assume it'll panic, in which case we'll want to discard it
// regardless.
struct Bomb<'a, Fut> {
queue: &'a mut FuturesUnordered<Fut>,
task: Option<Arc<Task<Fut>>>,
}
impl<Fut> Drop for Bomb<'_, Fut> {
fn drop(&mut self) {
if let Some(task) = self.task.take() {
self.queue.release_task(task);
}
}
}
let mut bomb = Bomb { task: Some(task), queue: &mut *self };
// Poll the underlying future with the appropriate waker
// implementation. This is where a large bit of the unsafety
// starts to stem from internally. The waker is basically just
// our `Arc<Task<Fut>>` and can schedule the future for polling by
// enqueuing itself in the ready to run queue.
//
// Critically though `Task<Fut>` won't actually access `Fut`, the
// future, while it's floating around inside of wakers.
// These structs will basically just use `Fut` to size
// the internal allocation, appropriately accessing fields and
// deallocating the task if need be.
let res = {
let waker = Task::waker_ref(bomb.task.as_ref().unwrap());
let mut cx = Context::from_waker(&waker);
// Safety: We won't move the future ever again
let future = unsafe { Pin::new_unchecked(future) };
future.poll(&mut cx)
};
polled += 1;
match res {
Poll::Pending => {
let task = bomb.task.take().unwrap();
bomb.queue.link(task);
if polled == yield_every {
// We have polled a large number of futures in a row without yielding.
// To ensure we do not starve other tasks waiting on the executor,
// we yield here, but immediately wake ourselves up to continue.
cx.waker().wake_by_ref();
return Poll::Pending;
}
continue;
}
Poll::Ready(output) => return Poll::Ready(Some(output)),
}
}
}
fn size_hint(&self) -> (usize, Option<usize>) {
let len = self.len();
(len, Some(len))
}
}
impl<Fut> Debug for FuturesUnordered<Fut> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "FuturesUnordered {{ ... }}")
}
}
impl<Fut> FuturesUnordered<Fut> {
/// Clears the set, removing all futures.
pub fn clear(&mut self) {
self.clear_head_all();
// we just cleared all the tasks, and we have &mut self, so this is safe.
unsafe { self.ready_to_run_queue.clear() };
self.is_terminated.store(false, Relaxed);
}
fn clear_head_all(&mut self) {
while !self.head_all.get_mut().is_null() {
let head = *self.head_all.get_mut();
let task = unsafe { self.unlink(head) };
self.release_task(task);
}
}
}
impl<Fut> Drop for FuturesUnordered<Fut> {
fn drop(&mut self) {
// When a `FuturesUnordered` is dropped we want to drop all futures
// associated with it. At the same time though there may be tons of
// wakers flying around which contain `Task<Fut>` references
// inside them. We'll let those naturally get deallocated.
self.clear_head_all();
// Note that at this point we could still have a bunch of tasks in the
// ready to run queue. None of those tasks, however, have futures
// associated with them so they're safe to destroy on any thread. At
// this point the `FuturesUnordered` struct, the owner of the one strong
// reference to the ready to run queue will drop the strong reference.
// At that point whichever thread releases the strong refcount last (be
// it this thread or some other thread as part of an `upgrade`) will
// clear out the ready to run queue and free all remaining tasks.
//
// While that freeing operation isn't guaranteed to happen here, it's
// guaranteed to happen "promptly" as no more "blocking work" will
// happen while there's a strong refcount held.
}
}
impl<'a, Fut: Unpin> IntoIterator for &'a FuturesUnordered<Fut> {
type Item = &'a Fut;
type IntoIter = Iter<'a, Fut>;
fn into_iter(self) -> Self::IntoIter {
self.iter()
}
}
impl<'a, Fut: Unpin> IntoIterator for &'a mut FuturesUnordered<Fut> {
type Item = &'a mut Fut;
type IntoIter = IterMut<'a, Fut>;
fn into_iter(self) -> Self::IntoIter {
self.iter_mut()
}
}
impl<Fut: Unpin> IntoIterator for FuturesUnordered<Fut> {
type Item = Fut;
type IntoIter = IntoIter<Fut>;
fn into_iter(mut self) -> Self::IntoIter {
// `head_all` can be accessed directly and we don't need to spin on
// `Task::next_all` since we have exclusive access to the set.
let task = *self.head_all.get_mut();
let len = if task.is_null() { 0 } else { unsafe { *(*task).len_all.get() } };
IntoIter { len, inner: self }
}
}
impl<Fut> FromIterator<Fut> for FuturesUnordered<Fut> {
fn from_iter<I>(iter: I) -> Self
where
I: IntoIterator<Item = Fut>,
{
let acc = Self::new();
iter.into_iter().fold(acc, |acc, item| {
acc.push(item);
acc
})
}
}
impl<Fut: Future> FusedStream for FuturesUnordered<Fut> {
fn is_terminated(&self) -> bool {
self.is_terminated.load(Relaxed)
}
}
impl<Fut> Extend<Fut> for FuturesUnordered<Fut> {
fn extend<I>(&mut self, iter: I)
where
I: IntoIterator<Item = Fut>,
{
for item in iter {
self.push(item);
}
}
}