//! A queue for sending values between asynchronous tasks. //! //! It can be used concurrently by multiple producers (senders) and multiple //! consumers (receivers), i.e. it is an "MPMC channel". //! //! Receivers are competing for messages. So a message that is received by //! one receiver is not received by any other. //! //! This queue takes a Mutex type so that various //! targets can be attained. For example, a ThreadModeMutex can be used //! for single-core Cortex-M targets where messages are only passed //! between tasks running in thread mode. Similarly, a CriticalSectionMutex //! can also be used for single-core targets where messages are to be //! passed from exception mode e.g. out of an interrupt handler. //! //! This module provides a bounded channel that has a limit on the number of //! messages that it can store, and if this limit is reached, trying to send //! another message will result in an error being returned. //! use core::cell::RefCell; use core::future::Future; use core::pin::Pin; use core::task::{Context, Poll}; use heapless::Deque; use crate::blocking_mutex::raw::RawMutex; use crate::blocking_mutex::Mutex; use crate::waitqueue::WakerRegistration; /// Send-only access to a [`Channel`]. #[derive(Copy)] pub struct Sender<'ch, M, T, const N: usize> where M: RawMutex, { channel: &'ch Channel, } impl<'ch, M, T, const N: usize> Clone for Sender<'ch, M, T, N> where M: RawMutex, { fn clone(&self) -> Self { Sender { channel: self.channel } } } impl<'ch, M, T, const N: usize> Sender<'ch, M, T, N> where M: RawMutex, { /// Sends a value. /// /// See [`Channel::send()`] pub fn send(&self, message: T) -> SendFuture<'ch, M, T, N> { self.channel.send(message) } /// Attempt to immediately send a message. /// /// See [`Channel::send()`] pub fn try_send(&self, message: T) -> Result<(), TrySendError> { self.channel.try_send(message) } } /// Send-only access to a [`Channel`] without knowing channel size. #[derive(Copy)] pub struct DynamicSender<'ch, T> { channel: &'ch dyn DynamicChannel, } impl<'ch, T> Clone for DynamicSender<'ch, T> { fn clone(&self) -> Self { DynamicSender { channel: self.channel } } } impl<'ch, M, T, const N: usize> From> for DynamicSender<'ch, T> where M: RawMutex, { fn from(s: Sender<'ch, M, T, N>) -> Self { Self { channel: s.channel } } } impl<'ch, T> DynamicSender<'ch, T> { /// Sends a value. /// /// See [`Channel::send()`] pub fn send(&self, message: T) -> DynamicSendFuture<'ch, T> { DynamicSendFuture { channel: self.channel, message: Some(message), } } /// Attempt to immediately send a message. /// /// See [`Channel::send()`] pub fn try_send(&self, message: T) -> Result<(), TrySendError> { self.channel.try_send_with_context(message, None) } } /// Receive-only access to a [`Channel`]. #[derive(Copy)] pub struct Receiver<'ch, M, T, const N: usize> where M: RawMutex, { channel: &'ch Channel, } impl<'ch, M, T, const N: usize> Clone for Receiver<'ch, M, T, N> where M: RawMutex, { fn clone(&self) -> Self { Receiver { channel: self.channel } } } impl<'ch, M, T, const N: usize> Receiver<'ch, M, T, N> where M: RawMutex, { /// Receive the next value. /// /// See [`Channel::recv()`]. pub fn recv(&self) -> RecvFuture<'_, M, T, N> { self.channel.recv() } /// Attempt to immediately receive the next value. /// /// See [`Channel::try_recv()`] pub fn try_recv(&self) -> Result { self.channel.try_recv() } } /// Receive-only access to a [`Channel`] without knowing channel size. #[derive(Copy)] pub struct DynamicReceiver<'ch, T> { channel: &'ch dyn DynamicChannel, } impl<'ch, T> Clone for DynamicReceiver<'ch, T> { fn clone(&self) -> Self { DynamicReceiver { channel: self.channel } } } impl<'ch, T> DynamicReceiver<'ch, T> { /// Receive the next value. /// /// See [`Channel::recv()`]. pub fn recv(&self) -> DynamicRecvFuture<'_, T> { DynamicRecvFuture { channel: self.channel } } /// Attempt to immediately receive the next value. /// /// See [`Channel::try_recv()`] pub fn try_recv(&self) -> Result { self.channel.try_recv_with_context(None) } } impl<'ch, M, T, const N: usize> From> for DynamicReceiver<'ch, T> where M: RawMutex, { fn from(s: Receiver<'ch, M, T, N>) -> Self { Self { channel: s.channel } } } /// Future returned by [`Channel::recv`] and [`Receiver::recv`]. pub struct RecvFuture<'ch, M, T, const N: usize> where M: RawMutex, { channel: &'ch Channel, } impl<'ch, M, T, const N: usize> Future for RecvFuture<'ch, M, T, N> where M: RawMutex, { type Output = T; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { match self.channel.try_recv_with_context(Some(cx)) { Ok(v) => Poll::Ready(v), Err(TryRecvError::Empty) => Poll::Pending, } } } /// Future returned by [`DynamicReceiver::recv`]. pub struct DynamicRecvFuture<'ch, T> { channel: &'ch dyn DynamicChannel, } impl<'ch, T> Future for DynamicRecvFuture<'ch, T> { type Output = T; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { match self.channel.try_recv_with_context(Some(cx)) { Ok(v) => Poll::Ready(v), Err(TryRecvError::Empty) => Poll::Pending, } } } /// Future returned by [`Channel::send`] and [`Sender::send`]. pub struct SendFuture<'ch, M, T, const N: usize> where M: RawMutex, { channel: &'ch Channel, message: Option, } impl<'ch, M, T, const N: usize> Future for SendFuture<'ch, M, T, N> where M: RawMutex, { type Output = (); fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { match self.message.take() { Some(m) => match self.channel.try_send_with_context(m, Some(cx)) { Ok(..) => Poll::Ready(()), Err(TrySendError::Full(m)) => { self.message = Some(m); Poll::Pending } }, None => panic!("Message cannot be None"), } } } impl<'ch, M, T, const N: usize> Unpin for SendFuture<'ch, M, T, N> where M: RawMutex {} /// Future returned by [`DynamicSender::send`]. pub struct DynamicSendFuture<'ch, T> { channel: &'ch dyn DynamicChannel, message: Option, } impl<'ch, T> Future for DynamicSendFuture<'ch, T> { type Output = (); fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { match self.message.take() { Some(m) => match self.channel.try_send_with_context(m, Some(cx)) { Ok(..) => Poll::Ready(()), Err(TrySendError::Full(m)) => { self.message = Some(m); Poll::Pending } }, None => panic!("Message cannot be None"), } } } impl<'ch, T> Unpin for DynamicSendFuture<'ch, T> {} trait DynamicChannel { fn try_send_with_context(&self, message: T, cx: Option<&mut Context<'_>>) -> Result<(), TrySendError>; fn try_recv_with_context(&self, cx: Option<&mut Context<'_>>) -> Result; } /// Error returned by [`try_recv`](Channel::try_recv). #[derive(PartialEq, Eq, Clone, Copy, Debug)] #[cfg_attr(feature = "defmt", derive(defmt::Format))] pub enum TryRecvError { /// A message could not be received because the channel is empty. Empty, } /// Error returned by [`try_send`](Channel::try_send). #[derive(PartialEq, Eq, Clone, Copy, Debug)] #[cfg_attr(feature = "defmt", derive(defmt::Format))] pub enum TrySendError { /// The data could not be sent on the channel because the channel is /// currently full and sending would require blocking. Full(T), } struct ChannelState { queue: Deque, receiver_waker: WakerRegistration, senders_waker: WakerRegistration, } impl ChannelState { const fn new() -> Self { ChannelState { queue: Deque::new(), receiver_waker: WakerRegistration::new(), senders_waker: WakerRegistration::new(), } } fn try_recv(&mut self) -> Result { self.try_recv_with_context(None) } fn try_recv_with_context(&mut self, cx: Option<&mut Context<'_>>) -> Result { if self.queue.is_full() { self.senders_waker.wake(); } if let Some(message) = self.queue.pop_front() { Ok(message) } else { if let Some(cx) = cx { self.receiver_waker.register(cx.waker()); } Err(TryRecvError::Empty) } } fn try_send(&mut self, message: T) -> Result<(), TrySendError> { self.try_send_with_context(message, None) } fn try_send_with_context(&mut self, message: T, cx: Option<&mut Context<'_>>) -> Result<(), TrySendError> { match self.queue.push_back(message) { Ok(()) => { self.receiver_waker.wake(); Ok(()) } Err(message) => { if let Some(cx) = cx { self.senders_waker.register(cx.waker()); } Err(TrySendError::Full(message)) } } } } /// A bounded 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. /// /// All data sent will become available in the same order as it was sent. pub struct Channel where M: RawMutex, { inner: Mutex>>, } impl Channel where M: RawMutex, { /// Establish a new bounded channel. For example, to create one with a NoopMutex: /// /// ``` /// use embassy_sync::channel::Channel; /// use embassy_sync::blocking_mutex::raw::NoopRawMutex; /// /// // Declare a bounded channel of 3 u32s. /// let mut channel = Channel::::new(); /// ``` pub const fn new() -> Self { Self { inner: Mutex::new(RefCell::new(ChannelState::new())), } } fn lock(&self, f: impl FnOnce(&mut ChannelState) -> R) -> R { self.inner.lock(|rc| f(&mut *rc.borrow_mut())) } fn try_recv_with_context(&self, cx: Option<&mut Context<'_>>) -> Result { self.lock(|c| c.try_recv_with_context(cx)) } fn try_send_with_context(&self, m: T, cx: Option<&mut Context<'_>>) -> Result<(), TrySendError> { self.lock(|c| c.try_send_with_context(m, cx)) } /// Get a sender for this channel. pub fn sender(&self) -> Sender<'_, M, T, N> { Sender { channel: self } } /// Get a receiver for this channel. pub fn receiver(&self) -> Receiver<'_, M, T, N> { Receiver { channel: self } } /// Send a value, waiting until there is capacity. /// /// Sending completes when the value has been pushed to the channel's queue. /// This doesn't mean the value has been received yet. pub fn send(&self, message: T) -> SendFuture<'_, M, T, N> { SendFuture { channel: self, message: Some(message), } } /// Attempt to immediately send a message. /// /// This method differs from [`send`](Channel::send) by returning immediately if the channel's /// buffer is full, instead of waiting. /// /// # 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. pub fn try_send(&self, message: T) -> Result<(), TrySendError> { self.lock(|c| c.try_send(message)) } /// Receive the next value. /// /// If there are no messages in the channel's buffer, this method will /// wait until a message is sent. pub fn recv(&self) -> RecvFuture<'_, M, T, N> { RecvFuture { channel: self } } /// Attempt to immediately receive a message. /// /// This method will either receive a message from the channel immediately or return an error /// if the channel is empty. pub fn try_recv(&self) -> Result { self.lock(|c| c.try_recv()) } } /// Implements the DynamicChannel to allow creating types that are unaware of the queue size with the /// tradeoff cost of dynamic dispatch. impl DynamicChannel for Channel where M: RawMutex, { fn try_send_with_context(&self, m: T, cx: Option<&mut Context<'_>>) -> Result<(), TrySendError> { Channel::try_send_with_context(self, m, cx) } fn try_recv_with_context(&self, cx: Option<&mut Context<'_>>) -> Result { Channel::try_recv_with_context(self, cx) } } #[cfg(test)] mod tests { use core::time::Duration; use futures_executor::ThreadPool; use futures_timer::Delay; use futures_util::task::SpawnExt; use static_cell::StaticCell; use super::*; use crate::blocking_mutex::raw::{CriticalSectionRawMutex, NoopRawMutex}; fn capacity(c: &ChannelState) -> usize { c.queue.capacity() - c.queue.len() } #[test] fn sending_once() { let mut c = ChannelState::::new(); assert!(c.try_send(1).is_ok()); assert_eq!(capacity(&c), 2); } #[test] fn sending_when_full() { let mut c = ChannelState::::new(); let _ = c.try_send(1); let _ = c.try_send(1); let _ = c.try_send(1); match c.try_send(2) { Err(TrySendError::Full(2)) => assert!(true), _ => assert!(false), } assert_eq!(capacity(&c), 0); } #[test] fn receiving_once_with_one_send() { let mut c = ChannelState::::new(); assert!(c.try_send(1).is_ok()); assert_eq!(c.try_recv().unwrap(), 1); assert_eq!(capacity(&c), 3); } #[test] fn receiving_when_empty() { let mut c = ChannelState::::new(); match c.try_recv() { Err(TryRecvError::Empty) => assert!(true), _ => assert!(false), } assert_eq!(capacity(&c), 3); } #[test] fn simple_send_and_receive() { let c = Channel::::new(); assert!(c.try_send(1).is_ok()); assert_eq!(c.try_recv().unwrap(), 1); } #[test] fn cloning() { let c = Channel::::new(); let r1 = c.receiver(); let s1 = c.sender(); let _ = r1.clone(); let _ = s1.clone(); } #[test] fn dynamic_dispatch() { let c = Channel::::new(); let s: DynamicSender<'_, u32> = c.sender().into(); let r: DynamicReceiver<'_, u32> = c.receiver().into(); assert!(s.try_send(1).is_ok()); assert_eq!(r.try_recv().unwrap(), 1); } #[futures_test::test] async fn receiver_receives_given_try_send_async() { let executor = ThreadPool::new().unwrap(); static CHANNEL: StaticCell> = StaticCell::new(); let c = &*CHANNEL.init(Channel::new()); let c2 = c; assert!(executor .spawn(async move { assert!(c2.try_send(1).is_ok()); }) .is_ok()); assert_eq!(c.recv().await, 1); } #[futures_test::test] async fn sender_send_completes_if_capacity() { let c = Channel::::new(); c.send(1).await; assert_eq!(c.recv().await, 1); } #[futures_test::test] async fn senders_sends_wait_until_capacity() { let executor = ThreadPool::new().unwrap(); static CHANNEL: StaticCell> = StaticCell::new(); let c = &*CHANNEL.init(Channel::new()); assert!(c.try_send(1).is_ok()); let c2 = c; let send_task_1 = executor.spawn_with_handle(async move { c2.send(2).await }); let c2 = c; let send_task_2 = executor.spawn_with_handle(async move { c2.send(3).await }); // Wish I could think of a means of determining that the async send is waiting instead. // However, I've used the debugger to observe that the send does indeed wait. Delay::new(Duration::from_millis(500)).await; assert_eq!(c.recv().await, 1); assert!(executor .spawn(async move { loop { c.recv().await; } }) .is_ok()); send_task_1.unwrap().await; send_task_2.unwrap().await; } }