use crate::loom::sync::Arc; use crate::sync::batch_semaphore::{self as semaphore, TryAcquireError}; use crate::sync::mpsc::chan; use crate::sync::mpsc::error::{SendError, TryRecvError, TrySendError}; cfg_time! { use crate::sync::mpsc::error::SendTimeoutError; use crate::time::Duration; } use std::fmt; use std::task::{Context, Poll}; /// Sends values to the associated `Receiver`. /// /// Instances are created by the [`channel`] function. /// /// To convert the `Sender` into a `Sink` or use it in a poll function, you can /// use the [`PollSender`] utility. /// /// [`PollSender`]: https://docs.rs/tokio-util/latest/tokio_util/sync/struct.PollSender.html pub struct Sender { chan: chan::Tx, } /// A sender that does not prevent the channel from being closed. /// /// If all [`Sender`] instances of a channel were dropped and only `WeakSender` /// instances remain, the channel is closed. /// /// In order to send messages, the `WeakSender` needs to be upgraded using /// [`WeakSender::upgrade`], which returns `Option`. It returns `None` /// if all `Sender`s have been dropped, and otherwise it returns a `Sender`. /// /// [`Sender`]: Sender /// [`WeakSender::upgrade`]: WeakSender::upgrade /// /// # Examples /// /// ``` /// use tokio::sync::mpsc::channel; /// /// #[tokio::main] /// async fn main() { /// let (tx, _rx) = channel::(15); /// let tx_weak = tx.downgrade(); /// /// // Upgrading will succeed because `tx` still exists. /// assert!(tx_weak.upgrade().is_some()); /// /// // If we drop `tx`, then it will fail. /// drop(tx); /// assert!(tx_weak.clone().upgrade().is_none()); /// } /// ``` pub struct WeakSender { chan: Arc>, } /// Permits to send one value into the channel. /// /// `Permit` values are returned by [`Sender::reserve()`] and [`Sender::try_reserve()`] /// and are used to guarantee channel capacity before generating a message to send. /// /// [`Sender::reserve()`]: Sender::reserve /// [`Sender::try_reserve()`]: Sender::try_reserve pub struct Permit<'a, T> { chan: &'a chan::Tx, } /// An [`Iterator`] of [`Permit`] that can be used to hold `n` slots in the channel. /// /// `PermitIterator` values are returned by [`Sender::reserve_many()`] and [`Sender::try_reserve_many()`] /// and are used to guarantee channel capacity before generating `n` messages to send. /// /// [`Sender::reserve_many()`]: Sender::reserve_many /// [`Sender::try_reserve_many()`]: Sender::try_reserve_many pub struct PermitIterator<'a, T> { chan: &'a chan::Tx, n: usize, } /// Owned permit to send one value into the channel. /// /// This is identical to the [`Permit`] type, except that it moves the sender /// rather than borrowing it. /// /// `OwnedPermit` values are returned by [`Sender::reserve_owned()`] and /// [`Sender::try_reserve_owned()`] and are used to guarantee channel capacity /// before generating a message to send. /// /// [`Permit`]: Permit /// [`Sender::reserve_owned()`]: Sender::reserve_owned /// [`Sender::try_reserve_owned()`]: Sender::try_reserve_owned pub struct OwnedPermit { chan: Option>, } /// Receives values from the associated `Sender`. /// /// Instances are created by the [`channel`] function. /// /// This receiver can be turned into a `Stream` using [`ReceiverStream`]. /// /// [`ReceiverStream`]: https://docs.rs/tokio-stream/0.1/tokio_stream/wrappers/struct.ReceiverStream.html pub struct Receiver { /// The channel receiver. chan: chan::Rx, } /// Creates a bounded mpsc channel for communicating between asynchronous tasks /// with backpressure. /// /// The channel will buffer up to the provided number of messages. Once the /// buffer is full, attempts to send new messages will wait until a message is /// received from the channel. The provided buffer capacity must be at least 1. /// /// All data sent on `Sender` will become available on `Receiver` in the same /// order as it was sent. /// /// The `Sender` can be cloned to `send` to the same channel from multiple code /// locations. Only one `Receiver` is supported. /// /// If the `Receiver` is disconnected while trying to `send`, the `send` method /// will return a `SendError`. Similarly, if `Sender` is disconnected while /// trying to `recv`, the `recv` method will return `None`. /// /// # Panics /// /// Panics if the buffer capacity is 0. /// /// # Examples /// /// ```rust /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(100); /// /// tokio::spawn(async move { /// for i in 0..10 { /// if let Err(_) = tx.send(i).await { /// println!("receiver dropped"); /// return; /// } /// } /// }); /// /// while let Some(i) = rx.recv().await { /// println!("got = {}", i); /// } /// } /// ``` #[track_caller] pub fn channel(buffer: usize) -> (Sender, Receiver) { assert!(buffer > 0, "mpsc bounded channel requires buffer > 0"); let semaphore = Semaphore { semaphore: semaphore::Semaphore::new(buffer), bound: buffer, }; let (tx, rx) = chan::channel(semaphore); let tx = Sender::new(tx); let rx = Receiver::new(rx); (tx, rx) } /// Channel semaphore is a tuple of the semaphore implementation and a `usize` /// representing the channel bound. #[derive(Debug)] pub(crate) struct Semaphore { pub(crate) semaphore: semaphore::Semaphore, pub(crate) bound: usize, } impl Receiver { pub(crate) fn new(chan: chan::Rx) -> Receiver { Receiver { chan } } /// Receives the next value for this receiver. /// /// This method returns `None` if the channel has been closed and there are /// no remaining messages in the channel's buffer. This indicates that no /// further values can ever be received from this `Receiver`. The channel is /// closed when all senders have been dropped, or when [`close`] is called. /// /// If there are no messages in the channel's buffer, but the channel has /// not yet been closed, this method will sleep until a message is sent or /// the channel is closed. Note that if [`close`] is called, but there are /// still outstanding [`Permits`] from before it was closed, the channel is /// not considered closed by `recv` until the permits are released. /// /// # 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. /// /// [`close`]: Self::close /// [`Permits`]: struct@crate::sync::mpsc::Permit /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(100); /// /// tokio::spawn(async move { /// tx.send("hello").await.unwrap(); /// }); /// /// assert_eq!(Some("hello"), rx.recv().await); /// assert_eq!(None, rx.recv().await); /// } /// ``` /// /// Values are buffered: /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(100); /// /// tx.send("hello").await.unwrap(); /// tx.send("world").await.unwrap(); /// /// assert_eq!(Some("hello"), rx.recv().await); /// assert_eq!(Some("world"), rx.recv().await); /// } /// ``` pub async fn recv(&mut self) -> Option { use std::future::poll_fn; poll_fn(|cx| self.chan.recv(cx)).await } /// Receives the next values for this receiver and extends `buffer`. /// /// This method extends `buffer` by no more than a fixed number of values /// as specified by `limit`. If `limit` is zero, the function immediately /// returns `0`. The return value is the number of values added to `buffer`. /// /// For `limit > 0`, if there are no messages in the channel's queue, but /// the channel has not yet been closed, this method will sleep until a /// message is sent or the channel is closed. Note that if [`close`] is /// called, but there are still outstanding [`Permits`] from before it was /// closed, the channel is not considered closed by `recv_many` until the /// permits are released. /// /// For non-zero values of `limit`, this method will never return `0` unless /// the channel has been closed and there are no remaining messages in the /// channel's queue. This indicates that no further values can ever be /// received from this `Receiver`. The channel is closed when all senders /// have been dropped, or when [`close`] is called. /// /// The capacity of `buffer` is increased as needed. /// /// # Cancel safety /// /// This method is cancel safe. If `recv_many` 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. /// /// [`close`]: Self::close /// [`Permits`]: struct@crate::sync::mpsc::Permit /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let mut buffer: Vec<&str> = Vec::with_capacity(2); /// let limit = 2; /// let (tx, mut rx) = mpsc::channel(100); /// let tx2 = tx.clone(); /// tx2.send("first").await.unwrap(); /// tx2.send("second").await.unwrap(); /// tx2.send("third").await.unwrap(); /// /// // Call `recv_many` to receive up to `limit` (2) values. /// assert_eq!(2, rx.recv_many(&mut buffer, limit).await); /// assert_eq!(vec!["first", "second"], buffer); /// /// // If the buffer is full, the next call to `recv_many` /// // reserves additional capacity. /// assert_eq!(1, rx.recv_many(&mut buffer, 1).await); /// /// tokio::spawn(async move { /// tx.send("fourth").await.unwrap(); /// }); /// /// // 'tx' is dropped, but `recv_many` /// // is guaranteed not to return 0 as the channel /// // is not yet closed. /// assert_eq!(1, rx.recv_many(&mut buffer, 1).await); /// assert_eq!(vec!["first", "second", "third", "fourth"], buffer); /// /// // Once the last sender is dropped, the channel is /// // closed and `recv_many` returns 0, capacity unchanged. /// drop(tx2); /// assert_eq!(0, rx.recv_many(&mut buffer, limit).await); /// assert_eq!(vec!["first", "second", "third", "fourth"], buffer); /// } /// ``` pub async fn recv_many(&mut self, buffer: &mut Vec, limit: usize) -> usize { use std::future::poll_fn; poll_fn(|cx| self.chan.recv_many(cx, buffer, limit)).await } /// Tries to receive the next value for this receiver. /// /// This method returns the [`Empty`] error if the channel is currently /// empty, but there are still outstanding [senders] or [permits]. /// /// This method returns the [`Disconnected`] error if the channel is /// currently empty, and there are no outstanding [senders] or [permits]. /// /// Unlike the [`poll_recv`] method, this method will never return an /// [`Empty`] error spuriously. /// /// [`Empty`]: crate::sync::mpsc::error::TryRecvError::Empty /// [`Disconnected`]: crate::sync::mpsc::error::TryRecvError::Disconnected /// [`poll_recv`]: Self::poll_recv /// [senders]: crate::sync::mpsc::Sender /// [permits]: crate::sync::mpsc::Permit /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// use tokio::sync::mpsc::error::TryRecvError; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(100); /// /// tx.send("hello").await.unwrap(); /// /// assert_eq!(Ok("hello"), rx.try_recv()); /// assert_eq!(Err(TryRecvError::Empty), rx.try_recv()); /// /// tx.send("hello").await.unwrap(); /// // Drop the last sender, closing the channel. /// drop(tx); /// /// assert_eq!(Ok("hello"), rx.try_recv()); /// assert_eq!(Err(TryRecvError::Disconnected), rx.try_recv()); /// } /// ``` pub fn try_recv(&mut self) -> Result { self.chan.try_recv() } /// Blocking receive to call outside of asynchronous contexts. /// /// This method returns `None` if the channel has been closed and there are /// no remaining messages in the channel's buffer. This indicates that no /// further values can ever be received from this `Receiver`. The channel is /// closed when all senders have been dropped, or when [`close`] is called. /// /// If there are no messages in the channel's buffer, but the channel has /// not yet been closed, this method will block until a message is sent or /// the channel is closed. /// /// This method is intended for use cases where you are sending from /// asynchronous code to synchronous code, and will work even if the sender /// is not using [`blocking_send`] to send the message. /// /// Note that if [`close`] is called, but there are still outstanding /// [`Permits`] from before it was closed, the channel is not considered /// closed by `blocking_recv` until the permits are released. /// /// [`close`]: Self::close /// [`Permits`]: struct@crate::sync::mpsc::Permit /// [`blocking_send`]: fn@crate::sync::mpsc::Sender::blocking_send /// /// # Panics /// /// This function panics if called within an asynchronous execution /// context. /// /// # Examples /// /// ``` /// use std::thread; /// use tokio::runtime::Runtime; /// use tokio::sync::mpsc; /// /// fn main() { /// let (tx, mut rx) = mpsc::channel::(10); /// /// let sync_code = thread::spawn(move || { /// assert_eq!(Some(10), rx.blocking_recv()); /// }); /// /// Runtime::new() /// .unwrap() /// .block_on(async move { /// let _ = tx.send(10).await; /// }); /// sync_code.join().unwrap() /// } /// ``` #[track_caller] #[cfg(feature = "sync")] #[cfg_attr(docsrs, doc(alias = "recv_blocking"))] pub fn blocking_recv(&mut self) -> Option { crate::future::block_on(self.recv()) } /// Variant of [`Self::recv_many`] for blocking contexts. /// /// The same conditions as in [`Self::blocking_recv`] apply. #[track_caller] #[cfg(feature = "sync")] #[cfg_attr(docsrs, doc(alias = "recv_many_blocking"))] pub fn blocking_recv_many(&mut self, buffer: &mut Vec, limit: usize) -> usize { crate::future::block_on(self.recv_many(buffer, limit)) } /// Closes the receiving half of a channel without dropping it. /// /// This prevents any further messages from being sent on the channel while /// still enabling the receiver to drain messages that are buffered. Any /// outstanding [`Permit`] values will still be able to send messages. /// /// To guarantee that no messages are dropped, after calling `close()`, /// `recv()` must be called until `None` is returned. If there are /// outstanding [`Permit`] or [`OwnedPermit`] values, the `recv` method will /// not return `None` until those are released. /// /// [`Permit`]: Permit /// [`OwnedPermit`]: OwnedPermit /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(20); /// /// tokio::spawn(async move { /// let mut i = 0; /// while let Ok(permit) = tx.reserve().await { /// permit.send(i); /// i += 1; /// } /// }); /// /// rx.close(); /// /// while let Some(msg) = rx.recv().await { /// println!("got {}", msg); /// } /// /// // Channel closed and no messages are lost. /// } /// ``` pub fn close(&mut self) { self.chan.close(); } /// Checks if a channel is closed. /// /// This method returns `true` if the channel has been closed. The channel is closed /// when all [`Sender`] have been dropped, or when [`Receiver::close`] is called. /// /// [`Sender`]: crate::sync::mpsc::Sender /// [`Receiver::close`]: crate::sync::mpsc::Receiver::close /// /// # Examples /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (_tx, mut rx) = mpsc::channel::<()>(10); /// assert!(!rx.is_closed()); /// /// rx.close(); /// /// assert!(rx.is_closed()); /// } /// ``` pub fn is_closed(&self) -> bool { self.chan.is_closed() } /// Checks if a channel is empty. /// /// This method returns `true` if the channel has no messages. /// /// # Examples /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = mpsc::channel(10); /// assert!(rx.is_empty()); /// /// tx.send(0).await.unwrap(); /// assert!(!rx.is_empty()); /// } /// /// ``` pub fn is_empty(&self) -> bool { self.chan.is_empty() } /// Returns the number of messages in the channel. /// /// # Examples /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = mpsc::channel(10); /// assert_eq!(0, rx.len()); /// /// tx.send(0).await.unwrap(); /// assert_eq!(1, rx.len()); /// } /// ``` pub fn len(&self) -> usize { self.chan.len() } /// Returns the current capacity of the channel. /// /// The capacity goes down when the sender sends a value by calling [`Sender::send`] or by reserving /// capacity with [`Sender::reserve`]. The capacity goes up when values are received. /// This is distinct from [`max_capacity`], which always returns buffer capacity initially /// specified when calling [`channel`]. /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel::<()>(5); /// /// assert_eq!(rx.capacity(), 5); /// /// // Making a reservation drops the capacity by one. /// let permit = tx.reserve().await.unwrap(); /// assert_eq!(rx.capacity(), 4); /// assert_eq!(rx.len(), 0); /// /// // Sending and receiving a value increases the capacity by one. /// permit.send(()); /// assert_eq!(rx.len(), 1); /// rx.recv().await.unwrap(); /// assert_eq!(rx.capacity(), 5); /// /// // Directly sending a message drops the capacity by one. /// tx.send(()).await.unwrap(); /// assert_eq!(rx.capacity(), 4); /// assert_eq!(rx.len(), 1); /// /// // Receiving the message increases the capacity by one. /// rx.recv().await.unwrap(); /// assert_eq!(rx.capacity(), 5); /// assert_eq!(rx.len(), 0); /// } /// ``` /// [`capacity`]: Receiver::capacity /// [`max_capacity`]: Receiver::max_capacity pub fn capacity(&self) -> usize { self.chan.semaphore().semaphore.available_permits() } /// Returns the maximum buffer capacity of the channel. /// /// The maximum capacity is the buffer capacity initially specified when calling /// [`channel`]. This is distinct from [`capacity`], which returns the *current* /// available buffer capacity: as messages are sent and received, the value /// returned by [`capacity`] will go up or down, whereas the value /// returned by [`max_capacity`] will remain constant. /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = mpsc::channel::<()>(5); /// /// // both max capacity and capacity are the same at first /// assert_eq!(rx.max_capacity(), 5); /// assert_eq!(rx.capacity(), 5); /// /// // Making a reservation doesn't change the max capacity. /// let permit = tx.reserve().await.unwrap(); /// assert_eq!(rx.max_capacity(), 5); /// // but drops the capacity by one /// assert_eq!(rx.capacity(), 4); /// } /// ``` /// [`capacity`]: Receiver::capacity /// [`max_capacity`]: Receiver::max_capacity pub fn max_capacity(&self) -> usize { self.chan.semaphore().bound } /// Polls to receive the next message on this channel. /// /// This method returns: /// /// * `Poll::Pending` if no messages are available but the channel is not /// closed, or if a spurious failure happens. /// * `Poll::Ready(Some(message))` if a message is available. /// * `Poll::Ready(None)` if the channel has been closed and all messages /// sent before it was closed have been received. /// /// When the method returns `Poll::Pending`, the `Waker` in the provided /// `Context` is scheduled to receive a wakeup when a message is sent on any /// receiver, or when the channel is closed. Note that on multiple calls to /// `poll_recv` or `poll_recv_many`, only the `Waker` from the `Context` /// passed to the most recent call is scheduled to receive a wakeup. /// /// If this method returns `Poll::Pending` due to a spurious failure, then /// the `Waker` will be notified when the situation causing the spurious /// failure has been resolved. Note that receiving such a wakeup does not /// guarantee that the next call will succeed — it could fail with another /// spurious failure. pub fn poll_recv(&mut self, cx: &mut Context<'_>) -> Poll> { self.chan.recv(cx) } /// Polls to receive multiple messages on this channel, extending the provided buffer. /// /// This method returns: /// * `Poll::Pending` if no messages are available but the channel is not closed, or if a /// spurious failure happens. /// * `Poll::Ready(count)` where `count` is the number of messages successfully received and /// stored in `buffer`. This can be less than, or equal to, `limit`. /// * `Poll::Ready(0)` if `limit` is set to zero or when the channel is closed. /// /// When the method returns `Poll::Pending`, the `Waker` in the provided /// `Context` is scheduled to receive a wakeup when a message is sent on any /// receiver, or when the channel is closed. Note that on multiple calls to /// `poll_recv` or `poll_recv_many`, only the `Waker` from the `Context` /// passed to the most recent call is scheduled to receive a wakeup. /// /// Note that this method does not guarantee that exactly `limit` messages /// are received. Rather, if at least one message is available, it returns /// as many messages as it can up to the given limit. This method returns /// zero only if the channel is closed (or if `limit` is zero). /// /// # Examples /// /// ``` /// use std::task::{Context, Poll}; /// use std::pin::Pin; /// use tokio::sync::mpsc; /// use futures::Future; /// /// struct MyReceiverFuture<'a> { /// receiver: mpsc::Receiver, /// buffer: &'a mut Vec, /// limit: usize, /// } /// /// impl<'a> Future for MyReceiverFuture<'a> { /// type Output = usize; // Number of messages received /// /// fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { /// let MyReceiverFuture { receiver, buffer, limit } = &mut *self; /// /// // Now `receiver` and `buffer` are mutable references, and `limit` is copied /// match receiver.poll_recv_many(cx, *buffer, *limit) { /// Poll::Pending => Poll::Pending, /// Poll::Ready(count) => Poll::Ready(count), /// } /// } /// } /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = mpsc::channel(32); /// let mut buffer = Vec::new(); /// /// let my_receiver_future = MyReceiverFuture { /// receiver: rx, /// buffer: &mut buffer, /// limit: 3, /// }; /// /// for i in 0..10 { /// tx.send(i).await.unwrap(); /// } /// /// let count = my_receiver_future.await; /// assert_eq!(count, 3); /// assert_eq!(buffer, vec![0,1,2]) /// } /// ``` pub fn poll_recv_many( &mut self, cx: &mut Context<'_>, buffer: &mut Vec, limit: usize, ) -> Poll { self.chan.recv_many(cx, buffer, limit) } /// Returns the number of [`Sender`] handles. pub fn sender_strong_count(&self) -> usize { self.chan.sender_strong_count() } /// Returns the number of [`WeakSender`] handles. pub fn sender_weak_count(&self) -> usize { self.chan.sender_weak_count() } } impl fmt::Debug for Receiver { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("Receiver") .field("chan", &self.chan) .finish() } } impl Unpin for Receiver {} impl Sender { pub(crate) fn new(chan: chan::Tx) -> Sender { Sender { chan } } /// Sends a value, waiting until there is capacity. /// /// A successful send occurs when it is determined that the other end of the /// channel has not hung up already. An unsuccessful send would be one where /// the corresponding receiver has already been closed. Note that a return /// value of `Err` means that the data will never be received, but a return /// value of `Ok` does not mean that the data will be received. It is /// possible for the corresponding receiver to hang up immediately after /// this function returns `Ok`. /// /// # Errors /// /// If the receive half of the channel is closed, either due to [`close`] /// being called or the [`Receiver`] handle dropping, the function returns /// an error. The error includes the value passed to `send`. /// /// [`close`]: Receiver::close /// [`Receiver`]: Receiver /// /// # Cancel safety /// /// If `send` is used as the event in a [`tokio::select!`](crate::select) /// statement and some other branch completes first, then it is guaranteed /// that the message was not sent. **However, in that case, the message /// is dropped and will be lost.** /// /// To avoid losing messages, use [`reserve`](Self::reserve) to reserve /// capacity, then use the returned [`Permit`] to send the message. /// /// This channel uses a queue to ensure that calls to `send` and `reserve` /// complete in the order they were requested. Cancelling a call to /// `send` makes you lose your place in the queue. /// /// # Examples /// /// In the following example, each call to `send` will block until the /// previously sent value was received. /// /// ```rust /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// tokio::spawn(async move { /// for i in 0..10 { /// if let Err(_) = tx.send(i).await { /// println!("receiver dropped"); /// return; /// } /// } /// }); /// /// while let Some(i) = rx.recv().await { /// println!("got = {}", i); /// } /// } /// ``` pub async fn send(&self, value: T) -> Result<(), SendError> { match self.reserve().await { Ok(permit) => { permit.send(value); Ok(()) } Err(_) => Err(SendError(value)), } } /// Completes when the receiver has dropped. /// /// This allows the producers to get notified when interest in the produced /// values is canceled and immediately stop doing work. /// /// # Cancel safety /// /// This method is cancel safe. Once the channel is closed, it stays closed /// forever and all future calls to `closed` will return immediately. /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx1, rx) = mpsc::channel::<()>(1); /// let tx2 = tx1.clone(); /// let tx3 = tx1.clone(); /// let tx4 = tx1.clone(); /// let tx5 = tx1.clone(); /// tokio::spawn(async move { /// drop(rx); /// }); /// /// futures::join!( /// tx1.closed(), /// tx2.closed(), /// tx3.closed(), /// tx4.closed(), /// tx5.closed() /// ); /// println!("Receiver dropped"); /// } /// ``` pub async fn closed(&self) { self.chan.closed().await; } /// Attempts to immediately send a message on this `Sender` /// /// This method differs from [`send`] by returning immediately if the channel's /// buffer is full or no receiver is waiting to acquire some data. Compared /// with [`send`], this function has two failure cases instead of one (one for /// disconnection, one for a full buffer). /// /// # Errors /// /// If the channel capacity has been reached, i.e., the channel has `n` /// buffered values where `n` is the argument passed to [`channel`], then an /// error is returned. /// /// If the receive half of the channel is closed, either due to [`close`] /// being called or the [`Receiver`] handle dropping, the function returns /// an error. The error includes the value passed to `send`. /// /// [`send`]: Sender::send /// [`channel`]: channel /// [`close`]: Receiver::close /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// // Create a channel with buffer size 1 /// let (tx1, mut rx) = mpsc::channel(1); /// let tx2 = tx1.clone(); /// /// tokio::spawn(async move { /// tx1.send(1).await.unwrap(); /// tx1.send(2).await.unwrap(); /// // task waits until the receiver receives a value. /// }); /// /// tokio::spawn(async move { /// // This will return an error and send /// // no message if the buffer is full /// let _ = tx2.try_send(3); /// }); /// /// let mut msg; /// msg = rx.recv().await.unwrap(); /// println!("message {} received", msg); /// /// msg = rx.recv().await.unwrap(); /// println!("message {} received", msg); /// /// // Third message may have never been sent /// match rx.recv().await { /// Some(msg) => println!("message {} received", msg), /// None => println!("the third message was never sent"), /// } /// } /// ``` pub fn try_send(&self, message: T) -> Result<(), TrySendError> { match self.chan.semaphore().semaphore.try_acquire(1) { Ok(()) => {} Err(TryAcquireError::Closed) => return Err(TrySendError::Closed(message)), Err(TryAcquireError::NoPermits) => return Err(TrySendError::Full(message)), } // Send the message self.chan.send(message); Ok(()) } /// Sends a value, waiting until there is capacity, but only for a limited time. /// /// Shares the same success and error conditions as [`send`], adding one more /// condition for an unsuccessful send, which is when the provided timeout has /// elapsed, and there is no capacity available. /// /// [`send`]: Sender::send /// /// # Errors /// /// If the receive half of the channel is closed, either due to [`close`] /// being called or the [`Receiver`] having been dropped, /// the function returns an error. The error includes the value passed to `send`. /// /// [`close`]: Receiver::close /// [`Receiver`]: Receiver /// /// # Panics /// /// This function panics if it is called outside the context of a Tokio /// runtime [with time enabled](crate::runtime::Builder::enable_time). /// /// # Examples /// /// In the following example, each call to `send_timeout` will block until the /// previously sent value was received, unless the timeout has elapsed. /// /// ```rust /// use tokio::sync::mpsc; /// use tokio::time::{sleep, Duration}; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// tokio::spawn(async move { /// for i in 0..10 { /// if let Err(e) = tx.send_timeout(i, Duration::from_millis(100)).await { /// println!("send error: #{:?}", e); /// return; /// } /// } /// }); /// /// while let Some(i) = rx.recv().await { /// println!("got = {}", i); /// sleep(Duration::from_millis(200)).await; /// } /// } /// ``` #[cfg(feature = "time")] #[cfg_attr(docsrs, doc(cfg(feature = "time")))] pub async fn send_timeout( &self, value: T, timeout: Duration, ) -> Result<(), SendTimeoutError> { let permit = match crate::time::timeout(timeout, self.reserve()).await { Err(_) => { return Err(SendTimeoutError::Timeout(value)); } Ok(Err(_)) => { return Err(SendTimeoutError::Closed(value)); } Ok(Ok(permit)) => permit, }; permit.send(value); Ok(()) } /// Blocking send to call outside of asynchronous contexts. /// /// This method is intended for use cases where you are sending from /// synchronous code to asynchronous code, and will work even if the /// receiver is not using [`blocking_recv`] to receive the message. /// /// [`blocking_recv`]: fn@crate::sync::mpsc::Receiver::blocking_recv /// /// # Panics /// /// This function panics if called within an asynchronous execution /// context. /// /// # Examples /// /// ``` /// use std::thread; /// use tokio::runtime::Runtime; /// use tokio::sync::mpsc; /// /// fn main() { /// let (tx, mut rx) = mpsc::channel::(1); /// /// let sync_code = thread::spawn(move || { /// tx.blocking_send(10).unwrap(); /// }); /// /// Runtime::new().unwrap().block_on(async move { /// assert_eq!(Some(10), rx.recv().await); /// }); /// sync_code.join().unwrap() /// } /// ``` #[track_caller] #[cfg(feature = "sync")] #[cfg_attr(docsrs, doc(alias = "send_blocking"))] pub fn blocking_send(&self, value: T) -> Result<(), SendError> { crate::future::block_on(self.send(value)) } /// Checks if the channel has been closed. This happens when the /// [`Receiver`] is dropped, or when the [`Receiver::close`] method is /// called. /// /// [`Receiver`]: crate::sync::mpsc::Receiver /// [`Receiver::close`]: crate::sync::mpsc::Receiver::close /// /// ``` /// let (tx, rx) = tokio::sync::mpsc::channel::<()>(42); /// assert!(!tx.is_closed()); /// /// let tx2 = tx.clone(); /// assert!(!tx2.is_closed()); /// /// drop(rx); /// assert!(tx.is_closed()); /// assert!(tx2.is_closed()); /// ``` pub fn is_closed(&self) -> bool { self.chan.is_closed() } /// Waits for channel capacity. Once capacity to send one message is /// available, it is reserved for the caller. /// /// If the channel is full, the function waits for the number of unreceived /// messages to become less than the channel capacity. Capacity to send one /// message is reserved for the caller. A [`Permit`] is returned to track /// the reserved capacity. The [`send`] function on [`Permit`] consumes the /// reserved capacity. /// /// Dropping [`Permit`] without sending a message releases the capacity back /// to the channel. /// /// [`Permit`]: Permit /// [`send`]: Permit::send /// /// # Cancel safety /// /// This channel uses a queue to ensure that calls to `send` and `reserve` /// complete in the order they were requested. Cancelling a call to /// `reserve` makes you lose your place in the queue. /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// // Reserve capacity /// let permit = tx.reserve().await.unwrap(); /// /// // Trying to send directly on the `tx` will fail due to no /// // available capacity. /// assert!(tx.try_send(123).is_err()); /// /// // Sending on the permit succeeds /// permit.send(456); /// /// // The value sent on the permit is received /// assert_eq!(rx.recv().await.unwrap(), 456); /// } /// ``` pub async fn reserve(&self) -> Result, SendError<()>> { self.reserve_inner(1).await?; Ok(Permit { chan: &self.chan }) } /// Waits for channel capacity. Once capacity to send `n` messages is /// available, it is reserved for the caller. /// /// If the channel is full or if there are fewer than `n` permits available, the function waits /// for the number of unreceived messages to become `n` less than the channel capacity. /// Capacity to send `n` message is then reserved for the caller. /// /// A [`PermitIterator`] is returned to track the reserved capacity. /// You can call this [`Iterator`] until it is exhausted to /// get a [`Permit`] and then call [`Permit::send`]. This function is similar to /// [`try_reserve_many`] except it awaits for the slots to become available. /// /// If the channel is closed, the function returns a [`SendError`]. /// /// Dropping [`PermitIterator`] without consuming it entirely releases the remaining /// permits back to the channel. /// /// [`PermitIterator`]: PermitIterator /// [`Permit`]: Permit /// [`send`]: Permit::send /// [`try_reserve_many`]: Sender::try_reserve_many /// /// # Cancel safety /// /// This channel uses a queue to ensure that calls to `send` and `reserve_many` /// complete in the order they were requested. Cancelling a call to /// `reserve_many` makes you lose your place in the queue. /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(2); /// /// // Reserve capacity /// let mut permit = tx.reserve_many(2).await.unwrap(); /// /// // Trying to send directly on the `tx` will fail due to no /// // available capacity. /// assert!(tx.try_send(123).is_err()); /// /// // Sending with the permit iterator succeeds /// permit.next().unwrap().send(456); /// permit.next().unwrap().send(457); /// /// // The iterator should now be exhausted /// assert!(permit.next().is_none()); /// /// // The value sent on the permit is received /// assert_eq!(rx.recv().await.unwrap(), 456); /// assert_eq!(rx.recv().await.unwrap(), 457); /// } /// ``` pub async fn reserve_many(&self, n: usize) -> Result, SendError<()>> { self.reserve_inner(n).await?; Ok(PermitIterator { chan: &self.chan, n, }) } /// Waits for channel capacity, moving the `Sender` and returning an owned /// permit. Once capacity to send one message is available, it is reserved /// for the caller. /// /// This moves the sender _by value_, and returns an owned permit that can /// be used to send a message into the channel. Unlike [`Sender::reserve`], /// this method may be used in cases where the permit must be valid for the /// `'static` lifetime. `Sender`s may be cloned cheaply (`Sender::clone` is /// essentially a reference count increment, comparable to [`Arc::clone`]), /// so when multiple [`OwnedPermit`]s are needed or the `Sender` cannot be /// moved, it can be cloned prior to calling `reserve_owned`. /// /// If the channel is full, the function waits for the number of unreceived /// messages to become less than the channel capacity. Capacity to send one /// message is reserved for the caller. An [`OwnedPermit`] is returned to /// track the reserved capacity. The [`send`] function on [`OwnedPermit`] /// consumes the reserved capacity. /// /// Dropping the [`OwnedPermit`] without sending a message releases the /// capacity back to the channel. /// /// # Cancel safety /// /// This channel uses a queue to ensure that calls to `send` and `reserve` /// complete in the order they were requested. Cancelling a call to /// `reserve_owned` makes you lose your place in the queue. /// /// # Examples /// Sending a message using an [`OwnedPermit`]: /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// // Reserve capacity, moving the sender. /// let permit = tx.reserve_owned().await.unwrap(); /// /// // Send a message, consuming the permit and returning /// // the moved sender. /// let tx = permit.send(123); /// /// // The value sent on the permit is received. /// assert_eq!(rx.recv().await.unwrap(), 123); /// /// // The sender can now be used again. /// tx.send(456).await.unwrap(); /// } /// ``` /// /// When multiple [`OwnedPermit`]s are needed, or the sender cannot be moved /// by value, it can be inexpensively cloned before calling `reserve_owned`: /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// // Clone the sender and reserve capacity. /// let permit = tx.clone().reserve_owned().await.unwrap(); /// /// // Trying to send directly on the `tx` will fail due to no /// // available capacity. /// assert!(tx.try_send(123).is_err()); /// /// // Sending on the permit succeeds. /// permit.send(456); /// /// // The value sent on the permit is received /// assert_eq!(rx.recv().await.unwrap(), 456); /// } /// ``` /// /// [`Sender::reserve`]: Sender::reserve /// [`OwnedPermit`]: OwnedPermit /// [`send`]: OwnedPermit::send /// [`Arc::clone`]: std::sync::Arc::clone pub async fn reserve_owned(self) -> Result, SendError<()>> { self.reserve_inner(1).await?; Ok(OwnedPermit { chan: Some(self.chan), }) } async fn reserve_inner(&self, n: usize) -> Result<(), SendError<()>> { crate::trace::async_trace_leaf().await; if n > self.max_capacity() { return Err(SendError(())); } match self.chan.semaphore().semaphore.acquire(n).await { Ok(()) => Ok(()), Err(_) => Err(SendError(())), } } /// Tries to acquire a slot in the channel without waiting for the slot to become /// available. /// /// If the channel is full this function will return [`TrySendError`], otherwise /// if there is a slot available it will return a [`Permit`] that will then allow you /// to [`send`] on the channel with a guaranteed slot. This function is similar to /// [`reserve`] except it does not await for the slot to become available. /// /// Dropping [`Permit`] without sending a message releases the capacity back /// to the channel. /// /// [`Permit`]: Permit /// [`send`]: Permit::send /// [`reserve`]: Sender::reserve /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// // Reserve capacity /// let permit = tx.try_reserve().unwrap(); /// /// // Trying to send directly on the `tx` will fail due to no /// // available capacity. /// assert!(tx.try_send(123).is_err()); /// /// // Trying to reserve an additional slot on the `tx` will /// // fail because there is no capacity. /// assert!(tx.try_reserve().is_err()); /// /// // Sending on the permit succeeds /// permit.send(456); /// /// // The value sent on the permit is received /// assert_eq!(rx.recv().await.unwrap(), 456); /// /// } /// ``` pub fn try_reserve(&self) -> Result, TrySendError<()>> { match self.chan.semaphore().semaphore.try_acquire(1) { Ok(()) => {} Err(TryAcquireError::Closed) => return Err(TrySendError::Closed(())), Err(TryAcquireError::NoPermits) => return Err(TrySendError::Full(())), } Ok(Permit { chan: &self.chan }) } /// Tries to acquire `n` slots in the channel without waiting for the slot to become /// available. /// /// A [`PermitIterator`] is returned to track the reserved capacity. /// You can call this [`Iterator`] until it is exhausted to /// get a [`Permit`] and then call [`Permit::send`]. This function is similar to /// [`reserve_many`] except it does not await for the slots to become available. /// /// If there are fewer than `n` permits available on the channel, then /// this function will return a [`TrySendError::Full`]. If the channel is closed /// this function will return a [`TrySendError::Closed`]. /// /// Dropping [`PermitIterator`] without consuming it entirely releases the remaining /// permits back to the channel. /// /// [`PermitIterator`]: PermitIterator /// [`send`]: Permit::send /// [`reserve_many`]: Sender::reserve_many /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(2); /// /// // Reserve capacity /// let mut permit = tx.try_reserve_many(2).unwrap(); /// /// // Trying to send directly on the `tx` will fail due to no /// // available capacity. /// assert!(tx.try_send(123).is_err()); /// /// // Trying to reserve an additional slot on the `tx` will /// // fail because there is no capacity. /// assert!(tx.try_reserve().is_err()); /// /// // Sending with the permit iterator succeeds /// permit.next().unwrap().send(456); /// permit.next().unwrap().send(457); /// /// // The iterator should now be exhausted /// assert!(permit.next().is_none()); /// /// // The value sent on the permit is received /// assert_eq!(rx.recv().await.unwrap(), 456); /// assert_eq!(rx.recv().await.unwrap(), 457); /// /// // Trying to call try_reserve_many with 0 will return an empty iterator /// let mut permit = tx.try_reserve_many(0).unwrap(); /// assert!(permit.next().is_none()); /// /// // Trying to call try_reserve_many with a number greater than the channel /// // capacity will return an error /// let permit = tx.try_reserve_many(3); /// assert!(permit.is_err()); /// /// // Trying to call try_reserve_many on a closed channel will return an error /// drop(rx); /// let permit = tx.try_reserve_many(1); /// assert!(permit.is_err()); /// /// let permit = tx.try_reserve_many(0); /// assert!(permit.is_err()); /// } /// ``` pub fn try_reserve_many(&self, n: usize) -> Result, TrySendError<()>> { if n > self.max_capacity() { return Err(TrySendError::Full(())); } match self.chan.semaphore().semaphore.try_acquire(n) { Ok(()) => {} Err(TryAcquireError::Closed) => return Err(TrySendError::Closed(())), Err(TryAcquireError::NoPermits) => return Err(TrySendError::Full(())), } Ok(PermitIterator { chan: &self.chan, n, }) } /// Tries to acquire a slot in the channel without waiting for the slot to become /// available, returning an owned permit. /// /// This moves the sender _by value_, and returns an owned permit that can /// be used to send a message into the channel. Unlike [`Sender::try_reserve`], /// this method may be used in cases where the permit must be valid for the /// `'static` lifetime. `Sender`s may be cloned cheaply (`Sender::clone` is /// essentially a reference count increment, comparable to [`Arc::clone`]), /// so when multiple [`OwnedPermit`]s are needed or the `Sender` cannot be /// moved, it can be cloned prior to calling `try_reserve_owned`. /// /// If the channel is full this function will return a [`TrySendError`]. /// Since the sender is taken by value, the `TrySendError` returned in this /// case contains the sender, so that it may be used again. Otherwise, if /// there is a slot available, this method will return an [`OwnedPermit`] /// that can then be used to [`send`] on the channel with a guaranteed slot. /// This function is similar to [`reserve_owned`] except it does not await /// for the slot to become available. /// /// Dropping the [`OwnedPermit`] without sending a message releases the capacity back /// to the channel. /// /// [`OwnedPermit`]: OwnedPermit /// [`send`]: OwnedPermit::send /// [`reserve_owned`]: Sender::reserve_owned /// [`Arc::clone`]: std::sync::Arc::clone /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// // Reserve capacity /// let permit = tx.clone().try_reserve_owned().unwrap(); /// /// // Trying to send directly on the `tx` will fail due to no /// // available capacity. /// assert!(tx.try_send(123).is_err()); /// /// // Trying to reserve an additional slot on the `tx` will /// // fail because there is no capacity. /// assert!(tx.try_reserve().is_err()); /// /// // Sending on the permit succeeds /// permit.send(456); /// /// // The value sent on the permit is received /// assert_eq!(rx.recv().await.unwrap(), 456); /// /// } /// ``` pub fn try_reserve_owned(self) -> Result, TrySendError> { match self.chan.semaphore().semaphore.try_acquire(1) { Ok(()) => {} Err(TryAcquireError::Closed) => return Err(TrySendError::Closed(self)), Err(TryAcquireError::NoPermits) => return Err(TrySendError::Full(self)), } Ok(OwnedPermit { chan: Some(self.chan), }) } /// Returns `true` if senders belong to the same channel. /// /// # Examples /// /// ``` /// let (tx, rx) = tokio::sync::mpsc::channel::<()>(1); /// let tx2 = tx.clone(); /// assert!(tx.same_channel(&tx2)); /// /// let (tx3, rx3) = tokio::sync::mpsc::channel::<()>(1); /// assert!(!tx3.same_channel(&tx2)); /// ``` pub fn same_channel(&self, other: &Self) -> bool { self.chan.same_channel(&other.chan) } /// Returns the current capacity of the channel. /// /// The capacity goes down when sending a value by calling [`send`] or by reserving capacity /// with [`reserve`]. The capacity goes up when values are received by the [`Receiver`]. /// This is distinct from [`max_capacity`], which always returns buffer capacity initially /// specified when calling [`channel`] /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel::<()>(5); /// /// assert_eq!(tx.capacity(), 5); /// /// // Making a reservation drops the capacity by one. /// let permit = tx.reserve().await.unwrap(); /// assert_eq!(tx.capacity(), 4); /// /// // Sending and receiving a value increases the capacity by one. /// permit.send(()); /// rx.recv().await.unwrap(); /// assert_eq!(tx.capacity(), 5); /// } /// ``` /// /// [`send`]: Sender::send /// [`reserve`]: Sender::reserve /// [`channel`]: channel /// [`max_capacity`]: Sender::max_capacity pub fn capacity(&self) -> usize { self.chan.semaphore().semaphore.available_permits() } /// Converts the `Sender` to a [`WeakSender`] that does not count /// towards RAII semantics, i.e. if all `Sender` instances of the /// channel were dropped and only `WeakSender` instances remain, /// the channel is closed. #[must_use = "Downgrade creates a WeakSender without destroying the original non-weak sender."] pub fn downgrade(&self) -> WeakSender { WeakSender { chan: self.chan.downgrade(), } } /// Returns the maximum buffer capacity of the channel. /// /// The maximum capacity is the buffer capacity initially specified when calling /// [`channel`]. This is distinct from [`capacity`], which returns the *current* /// available buffer capacity: as messages are sent and received, the /// value returned by [`capacity`] will go up or down, whereas the value /// returned by [`max_capacity`] will remain constant. /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, _rx) = mpsc::channel::<()>(5); /// /// // both max capacity and capacity are the same at first /// assert_eq!(tx.max_capacity(), 5); /// assert_eq!(tx.capacity(), 5); /// /// // Making a reservation doesn't change the max capacity. /// let permit = tx.reserve().await.unwrap(); /// assert_eq!(tx.max_capacity(), 5); /// // but drops the capacity by one /// assert_eq!(tx.capacity(), 4); /// } /// ``` /// /// [`channel`]: channel /// [`max_capacity`]: Sender::max_capacity /// [`capacity`]: Sender::capacity pub fn max_capacity(&self) -> usize { self.chan.semaphore().bound } /// Returns the number of [`Sender`] handles. pub fn strong_count(&self) -> usize { self.chan.strong_count() } /// Returns the number of [`WeakSender`] handles. pub fn weak_count(&self) -> usize { self.chan.weak_count() } } impl Clone for Sender { fn clone(&self) -> Self { Sender { chan: self.chan.clone(), } } } impl fmt::Debug for Sender { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("Sender") .field("chan", &self.chan) .finish() } } impl Clone for WeakSender { fn clone(&self) -> Self { self.chan.increment_weak_count(); WeakSender { chan: self.chan.clone(), } } } impl Drop for WeakSender { fn drop(&mut self) { self.chan.decrement_weak_count(); } } impl WeakSender { /// Tries to convert a `WeakSender` into a [`Sender`]. This will return `Some` /// if there are other `Sender` instances alive and the channel wasn't /// previously dropped, otherwise `None` is returned. pub fn upgrade(&self) -> Option> { chan::Tx::upgrade(self.chan.clone()).map(Sender::new) } /// Returns the number of [`Sender`] handles. pub fn strong_count(&self) -> usize { self.chan.strong_count() } /// Returns the number of [`WeakSender`] handles. pub fn weak_count(&self) -> usize { self.chan.weak_count() } } impl fmt::Debug for WeakSender { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("WeakSender").finish() } } // ===== impl Permit ===== impl Permit<'_, T> { /// Sends a value using the reserved capacity. /// /// Capacity for the message has already been reserved. The message is sent /// to the receiver and the permit is consumed. The operation will succeed /// even if the receiver half has been closed. See [`Receiver::close`] for /// more details on performing a clean shutdown. /// /// [`Receiver::close`]: Receiver::close /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// // Reserve capacity /// let permit = tx.reserve().await.unwrap(); /// /// // Trying to send directly on the `tx` will fail due to no /// // available capacity. /// assert!(tx.try_send(123).is_err()); /// /// // Send a message on the permit /// permit.send(456); /// /// // The value sent on the permit is received /// assert_eq!(rx.recv().await.unwrap(), 456); /// } /// ``` pub fn send(self, value: T) { use std::mem; self.chan.send(value); // Avoid the drop logic mem::forget(self); } } impl Drop for Permit<'_, T> { fn drop(&mut self) { use chan::Semaphore; let semaphore = self.chan.semaphore(); // Add the permit back to the semaphore semaphore.add_permit(); // If this is the last sender for this channel, wake the receiver so // that it can be notified that the channel is closed. if semaphore.is_closed() && semaphore.is_idle() { self.chan.wake_rx(); } } } impl fmt::Debug for Permit<'_, T> { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("Permit") .field("chan", &self.chan) .finish() } } // ===== impl PermitIterator ===== impl<'a, T> Iterator for PermitIterator<'a, T> { type Item = Permit<'a, T>; fn next(&mut self) -> Option { if self.n == 0 { return None; } self.n -= 1; Some(Permit { chan: self.chan }) } fn size_hint(&self) -> (usize, Option) { let n = self.n; (n, Some(n)) } } impl ExactSizeIterator for PermitIterator<'_, T> {} impl std::iter::FusedIterator for PermitIterator<'_, T> {} impl Drop for PermitIterator<'_, T> { fn drop(&mut self) { use chan::Semaphore; if self.n == 0 { return; } let semaphore = self.chan.semaphore(); // Add the remaining permits back to the semaphore semaphore.add_permits(self.n); // If this is the last sender for this channel, wake the receiver so // that it can be notified that the channel is closed. if semaphore.is_closed() && semaphore.is_idle() { self.chan.wake_rx(); } } } impl fmt::Debug for PermitIterator<'_, T> { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("PermitIterator") .field("chan", &self.chan) .field("capacity", &self.n) .finish() } } // ===== impl Permit ===== impl OwnedPermit { /// Sends a value using the reserved capacity. /// /// Capacity for the message has already been reserved. The message is sent /// to the receiver and the permit is consumed. The operation will succeed /// even if the receiver half has been closed. See [`Receiver::close`] for /// more details on performing a clean shutdown. /// /// Unlike [`Permit::send`], this method returns the [`Sender`] from which /// the `OwnedPermit` was reserved. /// /// [`Receiver::close`]: Receiver::close /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = mpsc::channel(1); /// /// // Reserve capacity /// let permit = tx.reserve_owned().await.unwrap(); /// /// // Send a message on the permit, returning the sender. /// let tx = permit.send(456); /// /// // The value sent on the permit is received /// assert_eq!(rx.recv().await.unwrap(), 456); /// /// // We may now reuse `tx` to send another message. /// tx.send(789).await.unwrap(); /// } /// ``` pub fn send(mut self, value: T) -> Sender { let chan = self.chan.take().unwrap_or_else(|| { unreachable!("OwnedPermit channel is only taken when the permit is moved") }); chan.send(value); Sender { chan } } /// Releases the reserved capacity *without* sending a message, returning the /// [`Sender`]. /// /// # Examples /// /// ``` /// use tokio::sync::mpsc; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = mpsc::channel(1); /// /// // Clone the sender and reserve capacity /// let permit = tx.clone().reserve_owned().await.unwrap(); /// /// // Trying to send on the original `tx` will fail, since the `permit` /// // has reserved all the available capacity. /// assert!(tx.try_send(123).is_err()); /// /// // Release the permit without sending a message, returning the clone /// // of the sender. /// let tx2 = permit.release(); /// /// // We may now reuse `tx` to send another message. /// tx.send(789).await.unwrap(); /// # drop(rx); drop(tx2); /// } /// ``` /// /// [`Sender`]: Sender pub fn release(mut self) -> Sender { use chan::Semaphore; let chan = self.chan.take().unwrap_or_else(|| { unreachable!("OwnedPermit channel is only taken when the permit is moved") }); // Add the permit back to the semaphore chan.semaphore().add_permit(); Sender { chan } } } impl Drop for OwnedPermit { fn drop(&mut self) { use chan::Semaphore; // Are we still holding onto the sender? if let Some(chan) = self.chan.take() { let semaphore = chan.semaphore(); // Add the permit back to the semaphore semaphore.add_permit(); // If this `OwnedPermit` is holding the last sender for this // channel, wake the receiver so that it can be notified that the // channel is closed. if semaphore.is_closed() && semaphore.is_idle() { chan.wake_rx(); } } // Otherwise, do nothing. } } impl fmt::Debug for OwnedPermit { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("OwnedPermit") .field("chan", &self.chan) .finish() } }