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//! A multi-producer, multi-consumer broadcast queue. Each sent value is seen by
//! all consumers.
//!
//! A [`Sender`] is used to broadcast values to **all** connected [`Receiver`]
//! values. [`Sender`] handles are clone-able, allowing concurrent send and
//! receive actions. [`Sender`] and [`Receiver`] are both `Send` and `Sync` as
//! long as `T` is `Send`.
//!
//! When a value is sent, **all** [`Receiver`] handles are notified and will
//! receive the value. The value is stored once inside the channel and cloned on
//! demand for each receiver. Once all receivers have received a clone of the
//! value, the value is released from the channel.
//!
//! A channel is created by calling [`channel`], specifying the maximum number
//! of messages the channel can retain at any given time.
//!
//! New [`Receiver`] handles are created by calling [`Sender::subscribe`]. The
//! returned [`Receiver`] will receive values sent **after** the call to
//! `subscribe`.
//!
//! This channel is also suitable for the single-producer multi-consumer
//! use-case, where a single sender broadcasts values to many receivers.
//!
//! ## Lagging
//!
//! As sent messages must be retained until **all** [`Receiver`] handles receive
//! a clone, broadcast channels are susceptible to the "slow receiver" problem.
//! In this case, all but one receiver are able to receive values at the rate
//! they are sent. Because one receiver is stalled, the channel starts to fill
//! up.
//!
//! This broadcast channel implementation handles this case by setting a hard
//! upper bound on the number of values the channel may retain at any given
//! time. This upper bound is passed to the [`channel`] function as an argument.
//!
//! If a value is sent when the channel is at capacity, the oldest value
//! currently held by the channel is released. This frees up space for the new
//! value. Any receiver that has not yet seen the released value will return
//! [`RecvError::Lagged`] the next time [`recv`] is called.
//!
//! Once [`RecvError::Lagged`] is returned, the lagging receiver's position is
//! updated to the oldest value contained by the channel. The next call to
//! [`recv`] will return this value.
//!
//! This behavior enables a receiver to detect when it has lagged so far behind
//! that data has been dropped. The caller may decide how to respond to this:
//! either by aborting its task or by tolerating lost messages and resuming
//! consumption of the channel.
//!
//! ## Closing
//!
//! When **all** [`Sender`] handles have been dropped, no new values may be
//! sent. At this point, the channel is "closed". Once a receiver has received
//! all values retained by the channel, the next call to [`recv`] will return
//! with [`RecvError::Closed`].
//!
//! When a [`Receiver`] handle is dropped, any messages not read by the receiver
//! will be marked as read. If this receiver was the only one not to have read
//! that message, the message will be dropped at this point.
//!
//! [`Sender`]: crate::sync::broadcast::Sender
//! [`Sender::subscribe`]: crate::sync::broadcast::Sender::subscribe
//! [`Receiver`]: crate::sync::broadcast::Receiver
//! [`channel`]: crate::sync::broadcast::channel
//! [`RecvError::Lagged`]: crate::sync::broadcast::error::RecvError::Lagged
//! [`RecvError::Closed`]: crate::sync::broadcast::error::RecvError::Closed
//! [`recv`]: crate::sync::broadcast::Receiver::recv
//!
//! # Examples
//!
//! Basic usage
//!
//! ```
//! use tokio::sync::broadcast;
//!
//! #[tokio::main]
//! async fn main() {
//! let (tx, mut rx1) = broadcast::channel(16);
//! let mut rx2 = tx.subscribe();
//!
//! tokio::spawn(async move {
//! assert_eq!(rx1.recv().await.unwrap(), 10);
//! assert_eq!(rx1.recv().await.unwrap(), 20);
//! });
//!
//! tokio::spawn(async move {
//! assert_eq!(rx2.recv().await.unwrap(), 10);
//! assert_eq!(rx2.recv().await.unwrap(), 20);
//! });
//!
//! tx.send(10).unwrap();
//! tx.send(20).unwrap();
//! }
//! ```
//!
//! Handling lag
//!
//! ```
//! use tokio::sync::broadcast;
//!
//! #[tokio::main]
//! async fn main() {
//! let (tx, mut rx) = broadcast::channel(2);
//!
//! tx.send(10).unwrap();
//! tx.send(20).unwrap();
//! tx.send(30).unwrap();
//!
//! // The receiver lagged behind
//! assert!(rx.recv().await.is_err());
//!
//! // At this point, we can abort or continue with lost messages
//!
//! assert_eq!(20, rx.recv().await.unwrap());
//! assert_eq!(30, rx.recv().await.unwrap());
//! }
//! ```
use crate::loom::cell::UnsafeCell;
use crate::loom::sync::atomic::AtomicUsize;
use crate::loom::sync::{Arc, Mutex, MutexGuard, RwLock, RwLockReadGuard};
use crate::util::linked_list::{self, GuardedLinkedList, LinkedList};
use crate::util::WakeList;
use std::fmt;
use std::future::Future;
use std::marker::PhantomPinned;
use std::pin::Pin;
use std::ptr::NonNull;
use std::sync::atomic::Ordering::SeqCst;
use std::task::{Context, Poll, Waker};
use std::usize;
/// Sending-half of the [`broadcast`] channel.
///
/// May be used from many threads. Messages can be sent with
/// [`send`][Sender::send].
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
/// let mut rx2 = tx.subscribe();
///
/// tokio::spawn(async move {
/// assert_eq!(rx1.recv().await.unwrap(), 10);
/// assert_eq!(rx1.recv().await.unwrap(), 20);
/// });
///
/// tokio::spawn(async move {
/// assert_eq!(rx2.recv().await.unwrap(), 10);
/// assert_eq!(rx2.recv().await.unwrap(), 20);
/// });
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
/// }
/// ```
///
/// [`broadcast`]: crate::sync::broadcast
pub struct Sender<T> {
shared: Arc<Shared<T>>,
}
/// Receiving-half of the [`broadcast`] channel.
///
/// Must not be used concurrently. Messages may be retrieved using
/// [`recv`][Receiver::recv].
///
/// To turn this receiver into a `Stream`, you can use the [`BroadcastStream`]
/// wrapper.
///
/// [`BroadcastStream`]: https://docs.rs/tokio-stream/0.1/tokio_stream/wrappers/struct.BroadcastStream.html
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
/// let mut rx2 = tx.subscribe();
///
/// tokio::spawn(async move {
/// assert_eq!(rx1.recv().await.unwrap(), 10);
/// assert_eq!(rx1.recv().await.unwrap(), 20);
/// });
///
/// tokio::spawn(async move {
/// assert_eq!(rx2.recv().await.unwrap(), 10);
/// assert_eq!(rx2.recv().await.unwrap(), 20);
/// });
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
/// }
/// ```
///
/// [`broadcast`]: crate::sync::broadcast
pub struct Receiver<T> {
/// State shared with all receivers and senders.
shared: Arc<Shared<T>>,
/// Next position to read from
next: u64,
}
pub mod error {
//! Broadcast error types
use std::fmt;
/// Error returned by from the [`send`] function on a [`Sender`].
///
/// A **send** operation can only fail if there are no active receivers,
/// implying that the message could never be received. The error contains the
/// message being sent as a payload so it can be recovered.
///
/// [`send`]: crate::sync::broadcast::Sender::send
/// [`Sender`]: crate::sync::broadcast::Sender
#[derive(Debug)]
pub struct SendError<T>(pub T);
impl<T> fmt::Display for SendError<T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "channel closed")
}
}
impl<T: fmt::Debug> std::error::Error for SendError<T> {}
/// An error returned from the [`recv`] function on a [`Receiver`].
///
/// [`recv`]: crate::sync::broadcast::Receiver::recv
/// [`Receiver`]: crate::sync::broadcast::Receiver
#[derive(Debug, PartialEq, Eq, Clone)]
pub enum RecvError {
/// There are no more active senders implying no further messages will ever
/// be sent.
Closed,
/// The receiver lagged too far behind. Attempting to receive again will
/// return the oldest message still retained by the channel.
///
/// Includes the number of skipped messages.
Lagged(u64),
}
impl fmt::Display for RecvError {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self {
RecvError::Closed => write!(f, "channel closed"),
RecvError::Lagged(amt) => write!(f, "channel lagged by {}", amt),
}
}
}
impl std::error::Error for RecvError {}
/// An error returned from the [`try_recv`] function on a [`Receiver`].
///
/// [`try_recv`]: crate::sync::broadcast::Receiver::try_recv
/// [`Receiver`]: crate::sync::broadcast::Receiver
#[derive(Debug, PartialEq, Eq, Clone)]
pub enum TryRecvError {
/// The channel is currently empty. There are still active
/// [`Sender`] handles, so data may yet become available.
///
/// [`Sender`]: crate::sync::broadcast::Sender
Empty,
/// There are no more active senders implying no further messages will ever
/// be sent.
Closed,
/// The receiver lagged too far behind and has been forcibly disconnected.
/// Attempting to receive again will return the oldest message still
/// retained by the channel.
///
/// Includes the number of skipped messages.
Lagged(u64),
}
impl fmt::Display for TryRecvError {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self {
TryRecvError::Empty => write!(f, "channel empty"),
TryRecvError::Closed => write!(f, "channel closed"),
TryRecvError::Lagged(amt) => write!(f, "channel lagged by {}", amt),
}
}
}
impl std::error::Error for TryRecvError {}
}
use self::error::*;
/// Data shared between senders and receivers.
struct Shared<T> {
/// slots in the channel.
buffer: Box<[RwLock<Slot<T>>]>,
/// Mask a position -> index.
mask: usize,
/// Tail of the queue. Includes the rx wait list.
tail: Mutex<Tail>,
/// Number of outstanding Sender handles.
num_tx: AtomicUsize,
}
/// Next position to write a value.
struct Tail {
/// Next position to write to.
pos: u64,
/// Number of active receivers.
rx_cnt: usize,
/// True if the channel is closed.
closed: bool,
/// Receivers waiting for a value.
waiters: LinkedList<Waiter, <Waiter as linked_list::Link>::Target>,
}
/// Slot in the buffer.
struct Slot<T> {
/// Remaining number of receivers that are expected to see this value.
///
/// When this goes to zero, the value is released.
///
/// An atomic is used as it is mutated concurrently with the slot read lock
/// acquired.
rem: AtomicUsize,
/// Uniquely identifies the `send` stored in the slot.
pos: u64,
/// The value being broadcast.
///
/// The value is set by `send` when the write lock is held. When a reader
/// drops, `rem` is decremented. When it hits zero, the value is dropped.
val: UnsafeCell<Option<T>>,
}
/// An entry in the wait queue.
struct Waiter {
/// True if queued.
queued: bool,
/// Task waiting on the broadcast channel.
waker: Option<Waker>,
/// Intrusive linked-list pointers.
pointers: linked_list::Pointers<Waiter>,
/// Should not be `Unpin`.
_p: PhantomPinned,
}
impl Waiter {
fn new() -> Self {
Self {
queued: false,
waker: None,
pointers: linked_list::Pointers::new(),
_p: PhantomPinned,
}
}
}
generate_addr_of_methods! {
impl<> Waiter {
unsafe fn addr_of_pointers(self: NonNull<Self>) -> NonNull<linked_list::Pointers<Waiter>> {
&self.pointers
}
}
}
struct RecvGuard<'a, T> {
slot: RwLockReadGuard<'a, Slot<T>>,
}
/// Receive a value future.
struct Recv<'a, T> {
/// Receiver being waited on.
receiver: &'a mut Receiver<T>,
/// Entry in the waiter `LinkedList`.
waiter: UnsafeCell<Waiter>,
}
unsafe impl<'a, T: Send> Send for Recv<'a, T> {}
unsafe impl<'a, T: Send> Sync for Recv<'a, T> {}
/// Max number of receivers. Reserve space to lock.
const MAX_RECEIVERS: usize = usize::MAX >> 2;
/// Create a bounded, multi-producer, multi-consumer channel where each sent
/// value is broadcasted to all active receivers.
///
/// **Note:** The actual capacity may be greater than the provided `capacity`.
///
/// All data sent on [`Sender`] will become available on every active
/// [`Receiver`] in the same order as it was sent.
///
/// The `Sender` can be cloned to `send` to the same channel from multiple
/// points in the process or it can be used concurrently from an `Arc`. New
/// `Receiver` handles are created by calling [`Sender::subscribe`].
///
/// If all [`Receiver`] handles are dropped, the `send` method will return a
/// [`SendError`]. Similarly, if all [`Sender`] handles are dropped, the [`recv`]
/// method will return a [`RecvError`].
///
/// [`Sender`]: crate::sync::broadcast::Sender
/// [`Sender::subscribe`]: crate::sync::broadcast::Sender::subscribe
/// [`Receiver`]: crate::sync::broadcast::Receiver
/// [`recv`]: crate::sync::broadcast::Receiver::recv
/// [`SendError`]: crate::sync::broadcast::error::SendError
/// [`RecvError`]: crate::sync::broadcast::error::RecvError
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
/// let mut rx2 = tx.subscribe();
///
/// tokio::spawn(async move {
/// assert_eq!(rx1.recv().await.unwrap(), 10);
/// assert_eq!(rx1.recv().await.unwrap(), 20);
/// });
///
/// tokio::spawn(async move {
/// assert_eq!(rx2.recv().await.unwrap(), 10);
/// assert_eq!(rx2.recv().await.unwrap(), 20);
/// });
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
/// }
/// ```
///
/// # Panics
///
/// This will panic if `capacity` is equal to `0` or larger
/// than `usize::MAX / 2`.
#[track_caller]
pub fn channel<T: Clone>(capacity: usize) -> (Sender<T>, Receiver<T>) {
// SAFETY: In the line below we are creating one extra receiver, so there will be 1 in total.
let tx = unsafe { Sender::new_with_receiver_count(1, capacity) };
let rx = Receiver {
shared: tx.shared.clone(),
next: 0,
};
(tx, rx)
}
unsafe impl<T: Send> Send for Sender<T> {}
unsafe impl<T: Send> Sync for Sender<T> {}
unsafe impl<T: Send> Send for Receiver<T> {}
unsafe impl<T: Send> Sync for Receiver<T> {}
impl<T> Sender<T> {
/// Creates the sending-half of the [`broadcast`] channel.
///
/// See the documentation of [`broadcast::channel`] for more information on this method.
///
/// [`broadcast`]: crate::sync::broadcast
/// [`broadcast::channel`]: crate::sync::broadcast
#[track_caller]
pub fn new(capacity: usize) -> Self {
// SAFETY: We don't create extra receivers, so there are 0.
unsafe { Self::new_with_receiver_count(0, capacity) }
}
/// Creates the sending-half of the [`broadcast`](self) channel, and provide the receiver
/// count.
///
/// See the documentation of [`broadcast::channel`](self::channel) for more errors when
/// calling this function.
///
/// # Safety:
///
/// The caller must ensure that the amount of receivers for this Sender is correct before
/// the channel functionalities are used, the count is zero by default, as this function
/// does not create any receivers by itself.
#[track_caller]
unsafe fn new_with_receiver_count(receiver_count: usize, mut capacity: usize) -> Self {
assert!(capacity > 0, "broadcast channel capacity cannot be zero");
assert!(
capacity <= usize::MAX >> 1,
"broadcast channel capacity exceeded `usize::MAX / 2`"
);
// Round to a power of two
capacity = capacity.next_power_of_two();
let mut buffer = Vec::with_capacity(capacity);
for i in 0..capacity {
buffer.push(RwLock::new(Slot {
rem: AtomicUsize::new(0),
pos: (i as u64).wrapping_sub(capacity as u64),
val: UnsafeCell::new(None),
}));
}
let shared = Arc::new(Shared {
buffer: buffer.into_boxed_slice(),
mask: capacity - 1,
tail: Mutex::new(Tail {
pos: 0,
rx_cnt: receiver_count,
closed: false,
waiters: LinkedList::new(),
}),
num_tx: AtomicUsize::new(1),
});
Sender { shared }
}
/// Attempts to send a value to all active [`Receiver`] handles, returning
/// it back if it could not be sent.
///
/// A successful send occurs when there is at least one active [`Receiver`]
/// handle. An unsuccessful send would be one where all associated
/// [`Receiver`] handles have already been dropped.
///
/// # Return
///
/// On success, the number of subscribed [`Receiver`] handles is returned.
/// This does not mean that this number of receivers will see the message as
/// a receiver may drop or lag ([see lagging](self#lagging)) before receiving
/// the message.
///
/// # Note
///
/// A return value of `Ok` **does not** mean that the sent value will be
/// observed by all or any of the active [`Receiver`] handles. [`Receiver`]
/// handles may be dropped before receiving the sent message.
///
/// A return value of `Err` **does not** mean that future calls to `send`
/// will fail. New [`Receiver`] handles may be created by calling
/// [`subscribe`].
///
/// [`Receiver`]: crate::sync::broadcast::Receiver
/// [`subscribe`]: crate::sync::broadcast::Sender::subscribe
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
/// let mut rx2 = tx.subscribe();
///
/// tokio::spawn(async move {
/// assert_eq!(rx1.recv().await.unwrap(), 10);
/// assert_eq!(rx1.recv().await.unwrap(), 20);
/// });
///
/// tokio::spawn(async move {
/// assert_eq!(rx2.recv().await.unwrap(), 10);
/// assert_eq!(rx2.recv().await.unwrap(), 20);
/// });
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
/// }
/// ```
pub fn send(&self, value: T) -> Result<usize, SendError<T>> {
let mut tail = self.shared.tail.lock();
if tail.rx_cnt == 0 {
return Err(SendError(value));
}
// Position to write into
let pos = tail.pos;
let rem = tail.rx_cnt;
let idx = (pos & self.shared.mask as u64) as usize;
// Update the tail position
tail.pos = tail.pos.wrapping_add(1);
// Get the slot
let mut slot = self.shared.buffer[idx].write().unwrap();
// Track the position
slot.pos = pos;
// Set remaining receivers
slot.rem.with_mut(|v| *v = rem);
// Write the value
slot.val = UnsafeCell::new(Some(value));
// Release the slot lock before notifying the receivers.
drop(slot);
// Notify and release the mutex. This must happen after the slot lock is
// released, otherwise the writer lock bit could be cleared while another
// thread is in the critical section.
self.shared.notify_rx(tail);
Ok(rem)
}
/// Creates a new [`Receiver`] handle that will receive values sent **after**
/// this call to `subscribe`.
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, _rx) = broadcast::channel(16);
///
/// // Will not be seen
/// tx.send(10).unwrap();
///
/// let mut rx = tx.subscribe();
///
/// tx.send(20).unwrap();
///
/// let value = rx.recv().await.unwrap();
/// assert_eq!(20, value);
/// }
/// ```
pub fn subscribe(&self) -> Receiver<T> {
let shared = self.shared.clone();
new_receiver(shared)
}
/// Returns the number of queued values.
///
/// A value is queued until it has either been seen by all receivers that were alive at the time
/// it was sent, or has been evicted from the queue by subsequent sends that exceeded the
/// queue's capacity.
///
/// # Note
///
/// In contrast to [`Receiver::len`], this method only reports queued values and not values that
/// have been evicted from the queue before being seen by all receivers.
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
/// let mut rx2 = tx.subscribe();
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
/// tx.send(30).unwrap();
///
/// assert_eq!(tx.len(), 3);
///
/// rx1.recv().await.unwrap();
///
/// // The len is still 3 since rx2 hasn't seen the first value yet.
/// assert_eq!(tx.len(), 3);
///
/// rx2.recv().await.unwrap();
///
/// assert_eq!(tx.len(), 2);
/// }
/// ```
pub fn len(&self) -> usize {
let tail = self.shared.tail.lock();
let base_idx = (tail.pos & self.shared.mask as u64) as usize;
let mut low = 0;
let mut high = self.shared.buffer.len();
while low < high {
let mid = low + (high - low) / 2;
let idx = base_idx.wrapping_add(mid) & self.shared.mask;
if self.shared.buffer[idx].read().unwrap().rem.load(SeqCst) == 0 {
low = mid + 1;
} else {
high = mid;
}
}
self.shared.buffer.len() - low
}
/// Returns true if there are no queued values.
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
/// let mut rx2 = tx.subscribe();
///
/// assert!(tx.is_empty());
///
/// tx.send(10).unwrap();
///
/// assert!(!tx.is_empty());
///
/// rx1.recv().await.unwrap();
///
/// // The queue is still not empty since rx2 hasn't seen the value.
/// assert!(!tx.is_empty());
///
/// rx2.recv().await.unwrap();
///
/// assert!(tx.is_empty());
/// }
/// ```
pub fn is_empty(&self) -> bool {
let tail = self.shared.tail.lock();
let idx = (tail.pos.wrapping_sub(1) & self.shared.mask as u64) as usize;
self.shared.buffer[idx].read().unwrap().rem.load(SeqCst) == 0
}
/// Returns the number of active receivers
///
/// An active receiver is a [`Receiver`] handle returned from [`channel`] or
/// [`subscribe`]. These are the handles that will receive values sent on
/// this [`Sender`].
///
/// # Note
///
/// It is not guaranteed that a sent message will reach this number of
/// receivers. Active receivers may never call [`recv`] again before
/// dropping.
///
/// [`recv`]: crate::sync::broadcast::Receiver::recv
/// [`Receiver`]: crate::sync::broadcast::Receiver
/// [`Sender`]: crate::sync::broadcast::Sender
/// [`subscribe`]: crate::sync::broadcast::Sender::subscribe
/// [`channel`]: crate::sync::broadcast::channel
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, _rx1) = broadcast::channel(16);
///
/// assert_eq!(1, tx.receiver_count());
///
/// let mut _rx2 = tx.subscribe();
///
/// assert_eq!(2, tx.receiver_count());
///
/// tx.send(10).unwrap();
/// }
/// ```
pub fn receiver_count(&self) -> usize {
let tail = self.shared.tail.lock();
tail.rx_cnt
}
/// Returns `true` if senders belong to the same channel.
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, _rx) = broadcast::channel::<()>(16);
/// let tx2 = tx.clone();
///
/// assert!(tx.same_channel(&tx2));
///
/// let (tx3, _rx3) = broadcast::channel::<()>(16);
///
/// assert!(!tx3.same_channel(&tx2));
/// }
/// ```
pub fn same_channel(&self, other: &Self) -> bool {
Arc::ptr_eq(&self.shared, &other.shared)
}
fn close_channel(&self) {
let mut tail = self.shared.tail.lock();
tail.closed = true;
self.shared.notify_rx(tail);
}
}
/// Create a new `Receiver` which reads starting from the tail.
fn new_receiver<T>(shared: Arc<Shared<T>>) -> Receiver<T> {
let mut tail = shared.tail.lock();
if tail.rx_cnt == MAX_RECEIVERS {
panic!("max receivers");
}
tail.rx_cnt = tail.rx_cnt.checked_add(1).expect("overflow");
let next = tail.pos;
drop(tail);
Receiver { shared, next }
}
/// List used in `Shared::notify_rx`. It wraps a guarded linked list
/// and gates the access to it on the `Shared.tail` mutex. It also empties
/// the list on drop.
struct WaitersList<'a, T> {
list: GuardedLinkedList<Waiter, <Waiter as linked_list::Link>::Target>,
is_empty: bool,
shared: &'a Shared<T>,
}
impl<'a, T> Drop for WaitersList<'a, T> {
fn drop(&mut self) {
// If the list is not empty, we unlink all waiters from it.
// We do not wake the waiters to avoid double panics.
if !self.is_empty {
let _lock_guard = self.shared.tail.lock();
while self.list.pop_back().is_some() {}
}
}
}
impl<'a, T> WaitersList<'a, T> {
fn new(
unguarded_list: LinkedList<Waiter, <Waiter as linked_list::Link>::Target>,
guard: Pin<&'a Waiter>,
shared: &'a Shared<T>,
) -> Self {
let guard_ptr = NonNull::from(guard.get_ref());
let list = unguarded_list.into_guarded(guard_ptr);
WaitersList {
list,
is_empty: false,
shared,
}
}
/// Removes the last element from the guarded list. Modifying this list
/// requires an exclusive access to the main list in `Notify`.
fn pop_back_locked(&mut self, _tail: &mut Tail) -> Option<NonNull<Waiter>> {
let result = self.list.pop_back();
if result.is_none() {
// Save information about emptiness to avoid waiting for lock
// in the destructor.
self.is_empty = true;
}
result
}
}
impl<T> Shared<T> {
fn notify_rx<'a, 'b: 'a>(&'b self, mut tail: MutexGuard<'a, Tail>) {
// It is critical for `GuardedLinkedList` safety that the guard node is
// pinned in memory and is not dropped until the guarded list is dropped.
let guard = Waiter::new();
pin!(guard);
// We move all waiters to a secondary list. It uses a `GuardedLinkedList`
// underneath to allow every waiter to safely remove itself from it.
//
// * This list will be still guarded by the `waiters` lock.
// `NotifyWaitersList` wrapper makes sure we hold the lock to modify it.
// * This wrapper will empty the list on drop. It is critical for safety
// that we will not leave any list entry with a pointer to the local
// guard node after this function returns / panics.
let mut list = WaitersList::new(std::mem::take(&mut tail.waiters), guard.as_ref(), self);
let mut wakers = WakeList::new();
'outer: loop {
while wakers.can_push() {
match list.pop_back_locked(&mut tail) {
Some(mut waiter) => {
// Safety: `tail` lock is still held.
let waiter = unsafe { waiter.as_mut() };
assert!(waiter.queued);
waiter.queued = false;
if let Some(waker) = waiter.waker.take() {
wakers.push(waker);
}
}
None => {
break 'outer;
}
}
}
// Release the lock before waking.
drop(tail);
// Before we acquire the lock again all sorts of things can happen:
// some waiters may remove themselves from the list and new waiters
// may be added. This is fine since at worst we will unnecessarily
// wake up waiters which will then queue themselves again.
wakers.wake_all();
// Acquire the lock again.
tail = self.tail.lock();
}
// Release the lock before waking.
drop(tail);
wakers.wake_all();
}
}
impl<T> Clone for Sender<T> {
fn clone(&self) -> Sender<T> {
let shared = self.shared.clone();
shared.num_tx.fetch_add(1, SeqCst);
Sender { shared }
}
}
impl<T> Drop for Sender<T> {
fn drop(&mut self) {
if 1 == self.shared.num_tx.fetch_sub(1, SeqCst) {
self.close_channel();
}
}
}
impl<T> Receiver<T> {
/// Returns the number of messages that were sent into the channel and that
/// this [`Receiver`] has yet to receive.
///
/// If the returned value from `len` is larger than the next largest power of 2
/// of the capacity of the channel any call to [`recv`] will return an
/// `Err(RecvError::Lagged)` and any call to [`try_recv`] will return an
/// `Err(TryRecvError::Lagged)`, e.g. if the capacity of the channel is 10,
/// [`recv`] will start to return `Err(RecvError::Lagged)` once `len` returns
/// values larger than 16.
///
/// [`Receiver`]: crate::sync::broadcast::Receiver
/// [`recv`]: crate::sync::broadcast::Receiver::recv
/// [`try_recv`]: crate::sync::broadcast::Receiver::try_recv
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
///
/// assert_eq!(rx1.len(), 2);
/// assert_eq!(rx1.recv().await.unwrap(), 10);
/// assert_eq!(rx1.len(), 1);
/// assert_eq!(rx1.recv().await.unwrap(), 20);
/// assert_eq!(rx1.len(), 0);
/// }
/// ```
pub fn len(&self) -> usize {
let next_send_pos = self.shared.tail.lock().pos;
(next_send_pos - self.next) as usize
}
/// Returns true if there aren't any messages in the channel that the [`Receiver`]
/// has yet to receive.
///
/// [`Receiver]: create::sync::broadcast::Receiver
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
///
/// assert!(rx1.is_empty());
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
///
/// assert!(!rx1.is_empty());
/// assert_eq!(rx1.recv().await.unwrap(), 10);
/// assert_eq!(rx1.recv().await.unwrap(), 20);
/// assert!(rx1.is_empty());
/// }
/// ```
pub fn is_empty(&self) -> bool {
self.len() == 0
}
/// Returns `true` if receivers belong to the same channel.
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, rx) = broadcast::channel::<()>(16);
/// let rx2 = tx.subscribe();
///
/// assert!(rx.same_channel(&rx2));
///
/// let (_tx3, rx3) = broadcast::channel::<()>(16);
///
/// assert!(!rx3.same_channel(&rx2));
/// }
/// ```
pub fn same_channel(&self, other: &Self) -> bool {
Arc::ptr_eq(&self.shared, &other.shared)
}
/// Locks the next value if there is one.
fn recv_ref(
&mut self,
waiter: Option<(&UnsafeCell<Waiter>, &Waker)>,
) -> Result<RecvGuard<'_, T>, TryRecvError> {
let idx = (self.next & self.shared.mask as u64) as usize;
// The slot holding the next value to read
let mut slot = self.shared.buffer[idx].read().unwrap();
if slot.pos != self.next {
// Release the `slot` lock before attempting to acquire the `tail`
// lock. This is required because `send2` acquires the tail lock
// first followed by the slot lock. Acquiring the locks in reverse
// order here would result in a potential deadlock: `recv_ref`
// acquires the `slot` lock and attempts to acquire the `tail` lock
// while `send2` acquired the `tail` lock and attempts to acquire
// the slot lock.
drop(slot);
let mut old_waker = None;
let mut tail = self.shared.tail.lock();
// Acquire slot lock again
slot = self.shared.buffer[idx].read().unwrap();
// Make sure the position did not change. This could happen in the
// unlikely event that the buffer is wrapped between dropping the
// read lock and acquiring the tail lock.
if slot.pos != self.next {
let next_pos = slot.pos.wrapping_add(self.shared.buffer.len() as u64);
if next_pos == self.next {
// At this point the channel is empty for *this* receiver. If
// it's been closed, then that's what we return, otherwise we
// set a waker and return empty.
if tail.closed {
return Err(TryRecvError::Closed);
}
// Store the waker
if let Some((waiter, waker)) = waiter {
// Safety: called while locked.
unsafe {
// Only queue if not already queued
waiter.with_mut(|ptr| {
// If there is no waker **or** if the currently
// stored waker references a **different** task,
// track the tasks' waker to be notified on
// receipt of a new value.
match (*ptr).waker {
Some(ref w) if w.will_wake(waker) => {}
_ => {
old_waker = std::mem::replace(
&mut (*ptr).waker,
Some(waker.clone()),
);
}
}
if !(*ptr).queued {
(*ptr).queued = true;
tail.waiters.push_front(NonNull::new_unchecked(&mut *ptr));
}
});
}
}
// Drop the old waker after releasing the locks.
drop(slot);
drop(tail);
drop(old_waker);
return Err(TryRecvError::Empty);
}
// At this point, the receiver has lagged behind the sender by
// more than the channel capacity. The receiver will attempt to
// catch up by skipping dropped messages and setting the
// internal cursor to the **oldest** message stored by the
// channel.
let next = tail.pos.wrapping_sub(self.shared.buffer.len() as u64);
let missed = next.wrapping_sub(self.next);
drop(tail);
// The receiver is slow but no values have been missed
if missed == 0 {
self.next = self.next.wrapping_add(1);
return Ok(RecvGuard { slot });
}
self.next = next;
return Err(TryRecvError::Lagged(missed));
}
}
self.next = self.next.wrapping_add(1);
Ok(RecvGuard { slot })
}
}
impl<T: Clone> Receiver<T> {
/// Re-subscribes to the channel starting from the current tail element.
///
/// This [`Receiver`] handle will receive a clone of all values sent
/// **after** it has resubscribed. This will not include elements that are
/// in the queue of the current receiver. Consider the following example.
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx) = broadcast::channel(2);
///
/// tx.send(1).unwrap();
/// let mut rx2 = rx.resubscribe();
/// tx.send(2).unwrap();
///
/// assert_eq!(rx2.recv().await.unwrap(), 2);
/// assert_eq!(rx.recv().await.unwrap(), 1);
/// }
/// ```
pub fn resubscribe(&self) -> Self {
let shared = self.shared.clone();
new_receiver(shared)
}
/// Receives the next value for this receiver.
///
/// Each [`Receiver`] handle will receive a clone of all values sent
/// **after** it has subscribed.
///
/// `Err(RecvError::Closed)` is returned when all `Sender` halves have
/// dropped, indicating that no further values can be sent on the channel.
///
/// If the [`Receiver`] handle falls behind, once the channel is full, newly
/// sent values will overwrite old values. At this point, a call to [`recv`]
/// will return with `Err(RecvError::Lagged)` and the [`Receiver`]'s
/// internal cursor is updated to point to the oldest value still held by
/// the channel. A subsequent call to [`recv`] will return this value
/// **unless** it has been since overwritten.
///
/// # Cancel safety
///
/// This method is cancel safe. If `recv` is used as the event in a
/// [`tokio::select!`](crate::select) statement and some other branch
/// completes first, it is guaranteed that no messages were received on this
/// channel.
///
/// [`Receiver`]: crate::sync::broadcast::Receiver
/// [`recv`]: crate::sync::broadcast::Receiver::recv
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx1) = broadcast::channel(16);
/// let mut rx2 = tx.subscribe();
///
/// tokio::spawn(async move {
/// assert_eq!(rx1.recv().await.unwrap(), 10);
/// assert_eq!(rx1.recv().await.unwrap(), 20);
/// });
///
/// tokio::spawn(async move {
/// assert_eq!(rx2.recv().await.unwrap(), 10);
/// assert_eq!(rx2.recv().await.unwrap(), 20);
/// });
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
/// }
/// ```
///
/// Handling lag
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx) = broadcast::channel(2);
///
/// tx.send(10).unwrap();
/// tx.send(20).unwrap();
/// tx.send(30).unwrap();
///
/// // The receiver lagged behind
/// assert!(rx.recv().await.is_err());
///
/// // At this point, we can abort or continue with lost messages
///
/// assert_eq!(20, rx.recv().await.unwrap());
/// assert_eq!(30, rx.recv().await.unwrap());
/// }
/// ```
pub async fn recv(&mut self) -> Result<T, RecvError> {
let fut = Recv::new(self);
fut.await
}
/// Attempts to return a pending value on this receiver without awaiting.
///
/// This is useful for a flavor of "optimistic check" before deciding to
/// await on a receiver.
///
/// Compared with [`recv`], this function has three failure cases instead of two
/// (one for closed, one for an empty buffer, one for a lagging receiver).
///
/// `Err(TryRecvError::Closed)` is returned when all `Sender` halves have
/// dropped, indicating that no further values can be sent on the channel.
///
/// If the [`Receiver`] handle falls behind, once the channel is full, newly
/// sent values will overwrite old values. At this point, a call to [`recv`]
/// will return with `Err(TryRecvError::Lagged)` and the [`Receiver`]'s
/// internal cursor is updated to point to the oldest value still held by
/// the channel. A subsequent call to [`try_recv`] will return this value
/// **unless** it has been since overwritten. If there are no values to
/// receive, `Err(TryRecvError::Empty)` is returned.
///
/// [`recv`]: crate::sync::broadcast::Receiver::recv
/// [`try_recv`]: crate::sync::broadcast::Receiver::try_recv
/// [`Receiver`]: crate::sync::broadcast::Receiver
///
/// # Examples
///
/// ```
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx) = broadcast::channel(16);
///
/// assert!(rx.try_recv().is_err());
///
/// tx.send(10).unwrap();
///
/// let value = rx.try_recv().unwrap();
/// assert_eq!(10, value);
/// }
/// ```
pub fn try_recv(&mut self) -> Result<T, TryRecvError> {
let guard = self.recv_ref(None)?;
guard.clone_value().ok_or(TryRecvError::Closed)
}
/// Blocking receive to call outside of asynchronous contexts.
///
/// # Panics
///
/// This function panics if called within an asynchronous execution
/// context.
///
/// # Examples
/// ```
/// use std::thread;
/// use tokio::sync::broadcast;
///
/// #[tokio::main]
/// async fn main() {
/// let (tx, mut rx) = broadcast::channel(16);
///
/// let sync_code = thread::spawn(move || {
/// assert_eq!(rx.blocking_recv(), Ok(10));
/// });
///
/// let _ = tx.send(10);
/// sync_code.join().unwrap();
/// }
/// ```
pub fn blocking_recv(&mut self) -> Result<T, RecvError> {
crate::future::block_on(self.recv())
}
}
impl<T> Drop for Receiver<T> {
fn drop(&mut self) {
let mut tail = self.shared.tail.lock();
tail.rx_cnt -= 1;
let until = tail.pos;
drop(tail);
while self.next < until {
match self.recv_ref(None) {
Ok(_) => {}
// The channel is closed
Err(TryRecvError::Closed) => break,
// Ignore lagging, we will catch up
Err(TryRecvError::Lagged(..)) => {}
// Can't be empty
Err(TryRecvError::Empty) => panic!("unexpected empty broadcast channel"),
}
}
}
}
impl<'a, T> Recv<'a, T> {
fn new(receiver: &'a mut Receiver<T>) -> Recv<'a, T> {
Recv {
receiver,
waiter: UnsafeCell::new(Waiter {
queued: false,
waker: None,
pointers: linked_list::Pointers::new(),
_p: PhantomPinned,
}),
}
}
/// A custom `project` implementation is used in place of `pin-project-lite`
/// as a custom drop implementation is needed.
fn project(self: Pin<&mut Self>) -> (&mut Receiver<T>, &UnsafeCell<Waiter>) {
unsafe {
// Safety: Receiver is Unpin
is_unpin::<&mut Receiver<T>>();
let me = self.get_unchecked_mut();
(me.receiver, &me.waiter)
}
}
}
impl<'a, T> Future for Recv<'a, T>
where
T: Clone,
{
type Output = Result<T, RecvError>;
fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Result<T, RecvError>> {
ready!(crate::trace::trace_leaf(cx));
let (receiver, waiter) = self.project();
let guard = match receiver.recv_ref(Some((waiter, cx.waker()))) {
Ok(value) => value,
Err(TryRecvError::Empty) => return Poll::Pending,
Err(TryRecvError::Lagged(n)) => return Poll::Ready(Err(RecvError::Lagged(n))),
Err(TryRecvError::Closed) => return Poll::Ready(Err(RecvError::Closed)),
};
Poll::Ready(guard.clone_value().ok_or(RecvError::Closed))
}
}
impl<'a, T> Drop for Recv<'a, T> {
fn drop(&mut self) {
// Acquire the tail lock. This is required for safety before accessing
// the waiter node.
let mut tail = self.receiver.shared.tail.lock();
// safety: tail lock is held
let queued = self.waiter.with(|ptr| unsafe { (*ptr).queued });
if queued {
// Remove the node
//
// safety: tail lock is held and the wait node is verified to be in
// the list.
unsafe {
self.waiter.with_mut(|ptr| {
tail.waiters.remove((&mut *ptr).into());
});
}
}
}
}
/// # Safety
///
/// `Waiter` is forced to be !Unpin.
unsafe impl linked_list::Link for Waiter {
type Handle = NonNull<Waiter>;
type Target = Waiter;
fn as_raw(handle: &NonNull<Waiter>) -> NonNull<Waiter> {
*handle
}
unsafe fn from_raw(ptr: NonNull<Waiter>) -> NonNull<Waiter> {
ptr
}
unsafe fn pointers(target: NonNull<Waiter>) -> NonNull<linked_list::Pointers<Waiter>> {
Waiter::addr_of_pointers(target)
}
}
impl<T> fmt::Debug for Sender<T> {
fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(fmt, "broadcast::Sender")
}
}
impl<T> fmt::Debug for Receiver<T> {
fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(fmt, "broadcast::Receiver")
}
}
impl<'a, T> RecvGuard<'a, T> {
fn clone_value(&self) -> Option<T>
where
T: Clone,
{
self.slot.val.with(|ptr| unsafe { (*ptr).clone() })
}
}
impl<'a, T> Drop for RecvGuard<'a, T> {
fn drop(&mut self) {
// Decrement the remaining counter
if 1 == self.slot.rem.fetch_sub(1, SeqCst) {
// Safety: Last receiver, drop the value
self.slot.val.with_mut(|ptr| unsafe { *ptr = None });
}
}
}
fn is_unpin<T: Unpin>() {}
#[cfg(not(loom))]
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn receiver_count_on_sender_constructor() {
let sender = Sender::<i32>::new(16);
assert_eq!(sender.receiver_count(), 0);
let rx_1 = sender.subscribe();
assert_eq!(sender.receiver_count(), 1);
let rx_2 = rx_1.resubscribe();
assert_eq!(sender.receiver_count(), 2);
let rx_3 = sender.subscribe();
assert_eq!(sender.receiver_count(), 3);
drop(rx_3);
drop(rx_1);
assert_eq!(sender.receiver_count(), 1);
drop(rx_2);
assert_eq!(sender.receiver_count(), 0);
}
#[cfg(not(loom))]
#[test]
fn receiver_count_on_channel_constructor() {
let (sender, rx) = channel::<i32>(16);
assert_eq!(sender.receiver_count(), 1);
let _rx_2 = rx.resubscribe();
assert_eq!(sender.receiver_count(), 2);
}
}