#![cfg_attr(not(feature = "sync"), allow(dead_code, unreachable_pub))] //! A one-shot channel is used for sending a single message between //! asynchronous tasks. The [`channel`] function is used to create a //! [`Sender`] and [`Receiver`] handle pair that form the channel. //! //! The `Sender` handle is used by the producer to send the value. //! The `Receiver` handle is used by the consumer to receive the value. //! //! Each handle can be used on separate tasks. //! //! Since the `send` method is not async, it can be used anywhere. This includes //! sending between two runtimes, and using it from non-async code. //! //! # Examples //! //! ``` //! use tokio::sync::oneshot; //! //! #[tokio::main] //! async fn main() { //! let (tx, rx) = oneshot::channel(); //! //! tokio::spawn(async move { //! if let Err(_) = tx.send(3) { //! println!("the receiver dropped"); //! } //! }); //! //! match rx.await { //! Ok(v) => println!("got = {:?}", v), //! Err(_) => println!("the sender dropped"), //! } //! } //! ``` //! //! If the sender is dropped without sending, the receiver will fail with //! [`error::RecvError`]: //! //! ``` //! use tokio::sync::oneshot; //! //! #[tokio::main] //! async fn main() { //! let (tx, rx) = oneshot::channel::(); //! //! tokio::spawn(async move { //! drop(tx); //! }); //! //! match rx.await { //! Ok(_) => panic!("This doesn't happen"), //! Err(_) => println!("the sender dropped"), //! } //! } //! ``` //! //! To use a oneshot channel in a `tokio::select!` loop, add `&mut` in front of //! the channel. //! //! ``` //! use tokio::sync::oneshot; //! use tokio::time::{interval, sleep, Duration}; //! //! #[tokio::main] //! # async fn _doc() {} //! # #[tokio::main(flavor = "current_thread", start_paused = true)] //! async fn main() { //! let (send, mut recv) = oneshot::channel(); //! let mut interval = interval(Duration::from_millis(100)); //! //! # let handle = //! tokio::spawn(async move { //! sleep(Duration::from_secs(1)).await; //! send.send("shut down").unwrap(); //! }); //! //! loop { //! tokio::select! { //! _ = interval.tick() => println!("Another 100ms"), //! msg = &mut recv => { //! println!("Got message: {}", msg.unwrap()); //! break; //! } //! } //! } //! # handle.await.unwrap(); //! } //! ``` //! //! To use a `Sender` from a destructor, put it in an [`Option`] and call //! [`Option::take`]. //! //! ``` //! use tokio::sync::oneshot; //! //! struct SendOnDrop { //! sender: Option>, //! } //! impl Drop for SendOnDrop { //! fn drop(&mut self) { //! if let Some(sender) = self.sender.take() { //! // Using `let _ =` to ignore send errors. //! let _ = sender.send("I got dropped!"); //! } //! } //! } //! //! #[tokio::main] //! # async fn _doc() {} //! # #[tokio::main(flavor = "current_thread")] //! async fn main() { //! let (send, recv) = oneshot::channel(); //! //! let send_on_drop = SendOnDrop { sender: Some(send) }; //! drop(send_on_drop); //! //! assert_eq!(recv.await, Ok("I got dropped!")); //! } //! ``` use crate::loom::cell::UnsafeCell; use crate::loom::sync::atomic::AtomicUsize; use crate::loom::sync::Arc; #[cfg(all(tokio_unstable, feature = "tracing"))] use crate::util::trace; use std::fmt; use std::future::Future; use std::mem::MaybeUninit; use std::pin::Pin; use std::sync::atomic::Ordering::{self, AcqRel, Acquire}; use std::task::Poll::{Pending, Ready}; use std::task::{Context, Poll, Waker}; /// Sends a value to the associated [`Receiver`]. /// /// A pair of both a [`Sender`] and a [`Receiver`] are created by the /// [`channel`](fn@channel) function. /// /// # Examples /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = oneshot::channel(); /// /// tokio::spawn(async move { /// if let Err(_) = tx.send(3) { /// println!("the receiver dropped"); /// } /// }); /// /// match rx.await { /// Ok(v) => println!("got = {:?}", v), /// Err(_) => println!("the sender dropped"), /// } /// } /// ``` /// /// If the sender is dropped without sending, the receiver will fail with /// [`error::RecvError`]: /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = oneshot::channel::(); /// /// tokio::spawn(async move { /// drop(tx); /// }); /// /// match rx.await { /// Ok(_) => panic!("This doesn't happen"), /// Err(_) => println!("the sender dropped"), /// } /// } /// ``` /// /// To use a `Sender` from a destructor, put it in an [`Option`] and call /// [`Option::take`]. /// /// ``` /// use tokio::sync::oneshot; /// /// struct SendOnDrop { /// sender: Option>, /// } /// impl Drop for SendOnDrop { /// fn drop(&mut self) { /// if let Some(sender) = self.sender.take() { /// // Using `let _ =` to ignore send errors. /// let _ = sender.send("I got dropped!"); /// } /// } /// } /// /// #[tokio::main] /// # async fn _doc() {} /// # #[tokio::main(flavor = "current_thread")] /// async fn main() { /// let (send, recv) = oneshot::channel(); /// /// let send_on_drop = SendOnDrop { sender: Some(send) }; /// drop(send_on_drop); /// /// assert_eq!(recv.await, Ok("I got dropped!")); /// } /// ``` /// /// [`Option`]: std::option::Option /// [`Option::take`]: std::option::Option::take #[derive(Debug)] pub struct Sender { inner: Option>>, #[cfg(all(tokio_unstable, feature = "tracing"))] resource_span: tracing::Span, } /// Receives a value from the associated [`Sender`]. /// /// A pair of both a [`Sender`] and a [`Receiver`] are created by the /// [`channel`](fn@channel) function. /// /// This channel has no `recv` method because the receiver itself implements the /// [`Future`] trait. To receive a `Result`, `.await` the `Receiver` object directly. /// /// The `poll` method on the `Future` trait is allowed to spuriously return /// `Poll::Pending` even if the message has been sent. If such a spurious /// failure happens, then the caller will be woken when the spurious failure has /// been resolved so that the caller can attempt to receive the message again. /// Note that receiving such a wakeup does not guarantee that the next call will /// succeed — it could fail with another spurious failure. (A spurious failure /// does not mean that the message is lost. It is just delayed.) /// /// [`Future`]: trait@std::future::Future /// /// # Examples /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = oneshot::channel(); /// /// tokio::spawn(async move { /// if let Err(_) = tx.send(3) { /// println!("the receiver dropped"); /// } /// }); /// /// match rx.await { /// Ok(v) => println!("got = {:?}", v), /// Err(_) => println!("the sender dropped"), /// } /// } /// ``` /// /// If the sender is dropped without sending, the receiver will fail with /// [`error::RecvError`]: /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = oneshot::channel::(); /// /// tokio::spawn(async move { /// drop(tx); /// }); /// /// match rx.await { /// Ok(_) => panic!("This doesn't happen"), /// Err(_) => println!("the sender dropped"), /// } /// } /// ``` /// /// To use a `Receiver` in a `tokio::select!` loop, add `&mut` in front of the /// channel. /// /// ``` /// use tokio::sync::oneshot; /// use tokio::time::{interval, sleep, Duration}; /// /// #[tokio::main] /// # async fn _doc() {} /// # #[tokio::main(flavor = "current_thread", start_paused = true)] /// async fn main() { /// let (send, mut recv) = oneshot::channel(); /// let mut interval = interval(Duration::from_millis(100)); /// /// # let handle = /// tokio::spawn(async move { /// sleep(Duration::from_secs(1)).await; /// send.send("shut down").unwrap(); /// }); /// /// loop { /// tokio::select! { /// _ = interval.tick() => println!("Another 100ms"), /// msg = &mut recv => { /// println!("Got message: {}", msg.unwrap()); /// break; /// } /// } /// } /// # handle.await.unwrap(); /// } /// ``` #[derive(Debug)] pub struct Receiver { inner: Option>>, #[cfg(all(tokio_unstable, feature = "tracing"))] resource_span: tracing::Span, #[cfg(all(tokio_unstable, feature = "tracing"))] async_op_span: tracing::Span, #[cfg(all(tokio_unstable, feature = "tracing"))] async_op_poll_span: tracing::Span, } pub mod error { //! Oneshot error types. use std::fmt; /// Error returned by the `Future` implementation for `Receiver`. /// /// This error is returned by the receiver when the sender is dropped without sending. #[derive(Debug, Eq, PartialEq, Clone)] pub struct RecvError(pub(super) ()); /// Error returned by the `try_recv` function on `Receiver`. #[derive(Debug, Eq, PartialEq, Clone)] pub enum TryRecvError { /// The send half of the channel has not yet sent a value. Empty, /// The send half of the channel was dropped without sending a value. Closed, } // ===== impl RecvError ===== impl fmt::Display for RecvError { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { write!(fmt, "channel closed") } } impl std::error::Error for RecvError {} // ===== impl TryRecvError ===== impl fmt::Display for TryRecvError { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { match self { TryRecvError::Empty => write!(fmt, "channel empty"), TryRecvError::Closed => write!(fmt, "channel closed"), } } } impl std::error::Error for TryRecvError {} } use self::error::*; struct Inner { /// Manages the state of the inner cell. state: AtomicUsize, /// The value. This is set by `Sender` and read by `Receiver`. The state of /// the cell is tracked by `state`. value: UnsafeCell>, /// The task to notify when the receiver drops without consuming the value. /// /// ## Safety /// /// The `TX_TASK_SET` bit in the `state` field is set if this field is /// initialized. If that bit is unset, this field may be uninitialized. tx_task: Task, /// The task to notify when the value is sent. /// /// ## Safety /// /// The `RX_TASK_SET` bit in the `state` field is set if this field is /// initialized. If that bit is unset, this field may be uninitialized. rx_task: Task, } struct Task(UnsafeCell>); impl Task { unsafe fn will_wake(&self, cx: &mut Context<'_>) -> bool { self.with_task(|w| w.will_wake(cx.waker())) } unsafe fn with_task(&self, f: F) -> R where F: FnOnce(&Waker) -> R, { self.0.with(|ptr| { let waker: *const Waker = (*ptr).as_ptr(); f(&*waker) }) } unsafe fn drop_task(&self) { self.0.with_mut(|ptr| { let ptr: *mut Waker = (*ptr).as_mut_ptr(); ptr.drop_in_place(); }); } unsafe fn set_task(&self, cx: &mut Context<'_>) { self.0.with_mut(|ptr| { let ptr: *mut Waker = (*ptr).as_mut_ptr(); ptr.write(cx.waker().clone()); }); } } #[derive(Clone, Copy)] struct State(usize); /// Creates a new one-shot channel for sending single values across asynchronous /// tasks. /// /// The function returns separate "send" and "receive" handles. The `Sender` /// handle is used by the producer to send the value. The `Receiver` handle is /// used by the consumer to receive the value. /// /// Each handle can be used on separate tasks. /// /// # Examples /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = oneshot::channel(); /// /// tokio::spawn(async move { /// if let Err(_) = tx.send(3) { /// println!("the receiver dropped"); /// } /// }); /// /// match rx.await { /// Ok(v) => println!("got = {:?}", v), /// Err(_) => println!("the sender dropped"), /// } /// } /// ``` #[track_caller] pub fn channel() -> (Sender, Receiver) { #[cfg(all(tokio_unstable, feature = "tracing"))] let resource_span = { let location = std::panic::Location::caller(); let resource_span = tracing::trace_span!( "runtime.resource", concrete_type = "Sender|Receiver", kind = "Sync", loc.file = location.file(), loc.line = location.line(), loc.col = location.column(), ); resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", tx_dropped = false, tx_dropped.op = "override", ) }); resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", rx_dropped = false, rx_dropped.op = "override", ) }); resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", value_sent = false, value_sent.op = "override", ) }); resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", value_received = false, value_received.op = "override", ) }); resource_span }; let inner = Arc::new(Inner { state: AtomicUsize::new(State::new().as_usize()), value: UnsafeCell::new(None), tx_task: Task(UnsafeCell::new(MaybeUninit::uninit())), rx_task: Task(UnsafeCell::new(MaybeUninit::uninit())), }); let tx = Sender { inner: Some(inner.clone()), #[cfg(all(tokio_unstable, feature = "tracing"))] resource_span: resource_span.clone(), }; #[cfg(all(tokio_unstable, feature = "tracing"))] let async_op_span = resource_span .in_scope(|| tracing::trace_span!("runtime.resource.async_op", source = "Receiver::await")); #[cfg(all(tokio_unstable, feature = "tracing"))] let async_op_poll_span = async_op_span.in_scope(|| tracing::trace_span!("runtime.resource.async_op.poll")); let rx = Receiver { inner: Some(inner), #[cfg(all(tokio_unstable, feature = "tracing"))] resource_span, #[cfg(all(tokio_unstable, feature = "tracing"))] async_op_span, #[cfg(all(tokio_unstable, feature = "tracing"))] async_op_poll_span, }; (tx, rx) } impl Sender { /// Attempts to send a value on this channel, returning it back if it could /// not be sent. /// /// This method consumes `self` as only one value may ever be sent on a oneshot /// channel. It is not marked async because sending a message to an oneshot /// channel never requires any form of waiting. Because of this, the `send` /// method can be used in both synchronous and asynchronous code without /// problems. /// /// 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 deallocated. 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`. /// /// # Examples /// /// Send a value to another task /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = oneshot::channel(); /// /// tokio::spawn(async move { /// if let Err(_) = tx.send(3) { /// println!("the receiver dropped"); /// } /// }); /// /// match rx.await { /// Ok(v) => println!("got = {:?}", v), /// Err(_) => println!("the sender dropped"), /// } /// } /// ``` pub fn send(mut self, t: T) -> Result<(), T> { let inner = self.inner.take().unwrap(); inner.value.with_mut(|ptr| unsafe { // SAFETY: The receiver will not access the `UnsafeCell` unless the // channel has been marked as "complete" (the `VALUE_SENT` state bit // is set). // That bit is only set by the sender later on in this method, and // calling this method consumes `self`. Therefore, if it was possible to // call this method, we know that the `VALUE_SENT` bit is unset, and // the receiver is not currently accessing the `UnsafeCell`. *ptr = Some(t); }); if !inner.complete() { unsafe { // SAFETY: The receiver will not access the `UnsafeCell` unless // the channel has been marked as "complete". Calling // `complete()` will return true if this bit is set, and false // if it is not set. Thus, if `complete()` returned false, it is // safe for us to access the value, because we know that the // receiver will not. return Err(inner.consume_value().unwrap()); } } #[cfg(all(tokio_unstable, feature = "tracing"))] self.resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", value_sent = true, value_sent.op = "override", ) }); Ok(()) } /// Waits for the associated [`Receiver`] handle to close. /// /// A [`Receiver`] is closed by either calling [`close`] explicitly or the /// [`Receiver`] value is dropped. /// /// This function is useful when paired with `select!` to abort a /// computation when the receiver is no longer interested in the result. /// /// # Return /// /// Returns a `Future` which must be awaited on. /// /// [`Receiver`]: Receiver /// [`close`]: Receiver::close /// /// # Examples /// /// Basic usage /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (mut tx, rx) = oneshot::channel::<()>(); /// /// tokio::spawn(async move { /// drop(rx); /// }); /// /// tx.closed().await; /// println!("the receiver dropped"); /// } /// ``` /// /// Paired with select /// /// ``` /// use tokio::sync::oneshot; /// use tokio::time::{self, Duration}; /// /// async fn compute() -> String { /// // Complex computation returning a `String` /// # "hello".to_string() /// } /// /// #[tokio::main] /// async fn main() { /// let (mut tx, rx) = oneshot::channel(); /// /// tokio::spawn(async move { /// tokio::select! { /// _ = tx.closed() => { /// // The receiver dropped, no need to do any further work /// } /// value = compute() => { /// // The send can fail if the channel was closed at the exact same /// // time as when compute() finished, so just ignore the failure. /// let _ = tx.send(value); /// } /// } /// }); /// /// // Wait for up to 10 seconds /// let _ = time::timeout(Duration::from_secs(10), rx).await; /// } /// ``` pub async fn closed(&mut self) { use crate::future::poll_fn; #[cfg(all(tokio_unstable, feature = "tracing"))] let resource_span = self.resource_span.clone(); #[cfg(all(tokio_unstable, feature = "tracing"))] let closed = trace::async_op( || poll_fn(|cx| self.poll_closed(cx)), resource_span, "Sender::closed", "poll_closed", false, ); #[cfg(not(all(tokio_unstable, feature = "tracing")))] let closed = poll_fn(|cx| self.poll_closed(cx)); closed.await } /// Returns `true` if the associated [`Receiver`] handle has been dropped. /// /// A [`Receiver`] is closed by either calling [`close`] explicitly or the /// [`Receiver`] value is dropped. /// /// If `true` is returned, a call to `send` will always result in an error. /// /// [`Receiver`]: Receiver /// [`close`]: Receiver::close /// /// # Examples /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = oneshot::channel(); /// /// assert!(!tx.is_closed()); /// /// drop(rx); /// /// assert!(tx.is_closed()); /// assert!(tx.send("never received").is_err()); /// } /// ``` pub fn is_closed(&self) -> bool { let inner = self.inner.as_ref().unwrap(); let state = State::load(&inner.state, Acquire); state.is_closed() } /// Checks whether the oneshot channel has been closed, and if not, schedules the /// `Waker` in the provided `Context` to receive a notification when the channel is /// closed. /// /// A [`Receiver`] is closed by either calling [`close`] explicitly, or when the /// [`Receiver`] value is dropped. /// /// Note that on multiple calls to poll, only the `Waker` from the `Context` passed /// to the most recent call will be scheduled to receive a wakeup. /// /// [`Receiver`]: struct@crate::sync::oneshot::Receiver /// [`close`]: fn@crate::sync::oneshot::Receiver::close /// /// # Return value /// /// This function returns: /// /// * `Poll::Pending` if the channel is still open. /// * `Poll::Ready(())` if the channel is closed. /// /// # Examples /// /// ``` /// use tokio::sync::oneshot; /// /// use futures::future::poll_fn; /// /// #[tokio::main] /// async fn main() { /// let (mut tx, mut rx) = oneshot::channel::<()>(); /// /// tokio::spawn(async move { /// rx.close(); /// }); /// /// poll_fn(|cx| tx.poll_closed(cx)).await; /// /// println!("the receiver dropped"); /// } /// ``` pub fn poll_closed(&mut self, cx: &mut Context<'_>) -> Poll<()> { // Keep track of task budget let coop = ready!(crate::runtime::coop::poll_proceed(cx)); let inner = self.inner.as_ref().unwrap(); let mut state = State::load(&inner.state, Acquire); if state.is_closed() { coop.made_progress(); return Poll::Ready(()); } if state.is_tx_task_set() { let will_notify = unsafe { inner.tx_task.will_wake(cx) }; if !will_notify { state = State::unset_tx_task(&inner.state); if state.is_closed() { // Set the flag again so that the waker is released in drop State::set_tx_task(&inner.state); coop.made_progress(); return Ready(()); } else { unsafe { inner.tx_task.drop_task() }; } } } if !state.is_tx_task_set() { // Attempt to set the task unsafe { inner.tx_task.set_task(cx); } // Update the state state = State::set_tx_task(&inner.state); if state.is_closed() { coop.made_progress(); return Ready(()); } } Pending } } impl Drop for Sender { fn drop(&mut self) { if let Some(inner) = self.inner.as_ref() { inner.complete(); #[cfg(all(tokio_unstable, feature = "tracing"))] self.resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", tx_dropped = true, tx_dropped.op = "override", ) }); } } } impl Receiver { /// Prevents the associated [`Sender`] handle from sending a value. /// /// Any `send` operation which happens after calling `close` is guaranteed /// to fail. After calling `close`, [`try_recv`] should be called to /// receive a value if one was sent **before** the call to `close` /// completed. /// /// This function is useful to perform a graceful shutdown and ensure that a /// value will not be sent into the channel and never received. /// /// `close` is no-op if a message is already received or the channel /// is already closed. /// /// [`Sender`]: Sender /// [`try_recv`]: Receiver::try_recv /// /// # Examples /// /// Prevent a value from being sent /// /// ``` /// use tokio::sync::oneshot; /// use tokio::sync::oneshot::error::TryRecvError; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = oneshot::channel(); /// /// assert!(!tx.is_closed()); /// /// rx.close(); /// /// assert!(tx.is_closed()); /// assert!(tx.send("never received").is_err()); /// /// match rx.try_recv() { /// Err(TryRecvError::Closed) => {} /// _ => unreachable!(), /// } /// } /// ``` /// /// Receive a value sent **before** calling `close` /// /// ``` /// use tokio::sync::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = oneshot::channel(); /// /// assert!(tx.send("will receive").is_ok()); /// /// rx.close(); /// /// let msg = rx.try_recv().unwrap(); /// assert_eq!(msg, "will receive"); /// } /// ``` pub fn close(&mut self) { if let Some(inner) = self.inner.as_ref() { inner.close(); #[cfg(all(tokio_unstable, feature = "tracing"))] self.resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", rx_dropped = true, rx_dropped.op = "override", ) }); } } /// Attempts to receive a value. /// /// If a pending value exists in the channel, it is returned. If no value /// has been sent, the current task **will not** be registered for /// future notification. /// /// This function is useful to call from outside the context of an /// asynchronous task. /// /// Note that unlike the `poll` method, the `try_recv` method cannot fail /// spuriously. Any send or close event that happens before this call to /// `try_recv` will be correctly returned to the caller. /// /// # Return /// /// - `Ok(T)` if a value is pending in the channel. /// - `Err(TryRecvError::Empty)` if no value has been sent yet. /// - `Err(TryRecvError::Closed)` if the sender has dropped without sending /// a value, or if the message has already been received. /// /// # Examples /// /// `try_recv` before a value is sent, then after. /// /// ``` /// use tokio::sync::oneshot; /// use tokio::sync::oneshot::error::TryRecvError; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = oneshot::channel(); /// /// match rx.try_recv() { /// // The channel is currently empty /// Err(TryRecvError::Empty) => {} /// _ => unreachable!(), /// } /// /// // Send a value /// tx.send("hello").unwrap(); /// /// match rx.try_recv() { /// Ok(value) => assert_eq!(value, "hello"), /// _ => unreachable!(), /// } /// } /// ``` /// /// `try_recv` when the sender dropped before sending a value /// /// ``` /// use tokio::sync::oneshot; /// use tokio::sync::oneshot::error::TryRecvError; /// /// #[tokio::main] /// async fn main() { /// let (tx, mut rx) = oneshot::channel::<()>(); /// /// drop(tx); /// /// match rx.try_recv() { /// // The channel will never receive a value. /// Err(TryRecvError::Closed) => {} /// _ => unreachable!(), /// } /// } /// ``` pub fn try_recv(&mut self) -> Result { let result = if let Some(inner) = self.inner.as_ref() { let state = State::load(&inner.state, Acquire); if state.is_complete() { // SAFETY: If `state.is_complete()` returns true, then the // `VALUE_SENT` bit has been set and the sender side of the // channel will no longer attempt to access the inner // `UnsafeCell`. Therefore, it is now safe for us to access the // cell. match unsafe { inner.consume_value() } { Some(value) => { #[cfg(all(tokio_unstable, feature = "tracing"))] self.resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", value_received = true, value_received.op = "override", ) }); Ok(value) } None => Err(TryRecvError::Closed), } } else if state.is_closed() { Err(TryRecvError::Closed) } else { // Not ready, this does not clear `inner` return Err(TryRecvError::Empty); } } else { Err(TryRecvError::Closed) }; self.inner = None; result } /// 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::oneshot; /// /// #[tokio::main] /// async fn main() { /// let (tx, rx) = oneshot::channel::(); /// /// let sync_code = thread::spawn(move || { /// assert_eq!(Ok(10), rx.blocking_recv()); /// }); /// /// let _ = tx.send(10); /// sync_code.join().unwrap(); /// } /// ``` #[track_caller] #[cfg(feature = "sync")] pub fn blocking_recv(self) -> Result { crate::future::block_on(self) } } impl Drop for Receiver { fn drop(&mut self) { if let Some(inner) = self.inner.as_ref() { inner.close(); #[cfg(all(tokio_unstable, feature = "tracing"))] self.resource_span.in_scope(|| { tracing::trace!( target: "runtime::resource::state_update", rx_dropped = true, rx_dropped.op = "override", ) }); } } } impl Future for Receiver { type Output = Result; fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { // If `inner` is `None`, then `poll()` has already completed. #[cfg(all(tokio_unstable, feature = "tracing"))] let _res_span = self.resource_span.clone().entered(); #[cfg(all(tokio_unstable, feature = "tracing"))] let _ao_span = self.async_op_span.clone().entered(); #[cfg(all(tokio_unstable, feature = "tracing"))] let _ao_poll_span = self.async_op_poll_span.clone().entered(); let ret = if let Some(inner) = self.as_ref().get_ref().inner.as_ref() { #[cfg(all(tokio_unstable, feature = "tracing"))] let res = ready!(trace_poll_op!("poll_recv", inner.poll_recv(cx)))?; #[cfg(any(not(tokio_unstable), not(feature = "tracing")))] let res = ready!(inner.poll_recv(cx))?; res } else { panic!("called after complete"); }; self.inner = None; Ready(Ok(ret)) } } impl Inner { fn complete(&self) -> bool { let prev = State::set_complete(&self.state); if prev.is_closed() { return false; } if prev.is_rx_task_set() { // TODO: Consume waker? unsafe { self.rx_task.with_task(Waker::wake_by_ref); } } true } fn poll_recv(&self, cx: &mut Context<'_>) -> Poll> { // Keep track of task budget let coop = ready!(crate::runtime::coop::poll_proceed(cx)); // Load the state let mut state = State::load(&self.state, Acquire); if state.is_complete() { coop.made_progress(); match unsafe { self.consume_value() } { Some(value) => Ready(Ok(value)), None => Ready(Err(RecvError(()))), } } else if state.is_closed() { coop.made_progress(); Ready(Err(RecvError(()))) } else { if state.is_rx_task_set() { let will_notify = unsafe { self.rx_task.will_wake(cx) }; // Check if the task is still the same if !will_notify { // Unset the task state = State::unset_rx_task(&self.state); if state.is_complete() { // Set the flag again so that the waker is released in drop State::set_rx_task(&self.state); coop.made_progress(); // SAFETY: If `state.is_complete()` returns true, then the // `VALUE_SENT` bit has been set and the sender side of the // channel will no longer attempt to access the inner // `UnsafeCell`. Therefore, it is now safe for us to access the // cell. return match unsafe { self.consume_value() } { Some(value) => Ready(Ok(value)), None => Ready(Err(RecvError(()))), }; } else { unsafe { self.rx_task.drop_task() }; } } } if !state.is_rx_task_set() { // Attempt to set the task unsafe { self.rx_task.set_task(cx); } // Update the state state = State::set_rx_task(&self.state); if state.is_complete() { coop.made_progress(); match unsafe { self.consume_value() } { Some(value) => Ready(Ok(value)), None => Ready(Err(RecvError(()))), } } else { Pending } } else { Pending } } } /// Called by `Receiver` to indicate that the value will never be received. fn close(&self) { let prev = State::set_closed(&self.state); if prev.is_tx_task_set() && !prev.is_complete() { unsafe { self.tx_task.with_task(Waker::wake_by_ref); } } } /// Consumes the value. This function does not check `state`. /// /// # Safety /// /// Calling this method concurrently on multiple threads will result in a /// data race. The `VALUE_SENT` state bit is used to ensure that only the /// sender *or* the receiver will call this method at a given point in time. /// If `VALUE_SENT` is not set, then only the sender may call this method; /// if it is set, then only the receiver may call this method. unsafe fn consume_value(&self) -> Option { self.value.with_mut(|ptr| (*ptr).take()) } } unsafe impl Send for Inner {} unsafe impl Sync for Inner {} fn mut_load(this: &mut AtomicUsize) -> usize { this.with_mut(|v| *v) } impl Drop for Inner { fn drop(&mut self) { let state = State(mut_load(&mut self.state)); if state.is_rx_task_set() { unsafe { self.rx_task.drop_task(); } } if state.is_tx_task_set() { unsafe { self.tx_task.drop_task(); } } } } impl fmt::Debug for Inner { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { use std::sync::atomic::Ordering::Relaxed; fmt.debug_struct("Inner") .field("state", &State::load(&self.state, Relaxed)) .finish() } } /// Indicates that a waker for the receiving task has been set. /// /// # Safety /// /// If this bit is not set, the `rx_task` field may be uninitialized. const RX_TASK_SET: usize = 0b00001; /// Indicates that a value has been stored in the channel's inner `UnsafeCell`. /// /// # Safety /// /// This bit controls which side of the channel is permitted to access the /// `UnsafeCell`. If it is set, the `UnsafeCell` may ONLY be accessed by the /// receiver. If this bit is NOT set, the `UnsafeCell` may ONLY be accessed by /// the sender. const VALUE_SENT: usize = 0b00010; const CLOSED: usize = 0b00100; /// Indicates that a waker for the sending task has been set. /// /// # Safety /// /// If this bit is not set, the `tx_task` field may be uninitialized. const TX_TASK_SET: usize = 0b01000; impl State { fn new() -> State { State(0) } fn is_complete(self) -> bool { self.0 & VALUE_SENT == VALUE_SENT } fn set_complete(cell: &AtomicUsize) -> State { // This method is a compare-and-swap loop rather than a fetch-or like // other `set_$WHATEVER` methods on `State`. This is because we must // check if the state has been closed before setting the `VALUE_SENT` // bit. // // We don't want to set both the `VALUE_SENT` bit if the `CLOSED` // bit is already set, because `VALUE_SENT` will tell the receiver that // it's okay to access the inner `UnsafeCell`. Immediately after calling // `set_complete`, if the channel was closed, the sender will _also_ // access the `UnsafeCell` to take the value back out, so if a // `poll_recv` or `try_recv` call is occurring concurrently, both // threads may try to access the `UnsafeCell` if we were to set the // `VALUE_SENT` bit on a closed channel. let mut state = cell.load(Ordering::Relaxed); loop { if State(state).is_closed() { break; } // TODO: This could be `Release`, followed by an `Acquire` fence *if* // the `RX_TASK_SET` flag is set. However, `loom` does not support // fences yet. match cell.compare_exchange_weak( state, state | VALUE_SENT, Ordering::AcqRel, Ordering::Acquire, ) { Ok(_) => break, Err(actual) => state = actual, } } State(state) } fn is_rx_task_set(self) -> bool { self.0 & RX_TASK_SET == RX_TASK_SET } fn set_rx_task(cell: &AtomicUsize) -> State { let val = cell.fetch_or(RX_TASK_SET, AcqRel); State(val | RX_TASK_SET) } fn unset_rx_task(cell: &AtomicUsize) -> State { let val = cell.fetch_and(!RX_TASK_SET, AcqRel); State(val & !RX_TASK_SET) } fn is_closed(self) -> bool { self.0 & CLOSED == CLOSED } fn set_closed(cell: &AtomicUsize) -> State { // Acquire because we want all later writes (attempting to poll) to be // ordered after this. let val = cell.fetch_or(CLOSED, Acquire); State(val) } fn set_tx_task(cell: &AtomicUsize) -> State { let val = cell.fetch_or(TX_TASK_SET, AcqRel); State(val | TX_TASK_SET) } fn unset_tx_task(cell: &AtomicUsize) -> State { let val = cell.fetch_and(!TX_TASK_SET, AcqRel); State(val & !TX_TASK_SET) } fn is_tx_task_set(self) -> bool { self.0 & TX_TASK_SET == TX_TASK_SET } fn as_usize(self) -> usize { self.0 } fn load(cell: &AtomicUsize, order: Ordering) -> State { let val = cell.load(order); State(val) } } impl fmt::Debug for State { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("State") .field("is_complete", &self.is_complete()) .field("is_closed", &self.is_closed()) .field("is_rx_task_set", &self.is_rx_task_set()) .field("is_tx_task_set", &self.is_tx_task_set()) .finish() } }