Source code
Revision control
Copy as Markdown
Other Tools
use futures::channel::{mpsc, oneshot};
use futures::executor::{block_on, block_on_stream};
use futures::future::{poll_fn, FutureExt};
use futures::pin_mut;
use futures::sink::{Sink, SinkExt};
use futures::stream::{Stream, StreamExt};
use futures::task::{Context, Poll};
use futures_test::task::{new_count_waker, noop_context};
use std::sync::atomic::{AtomicUsize, Ordering};
use std::sync::{Arc, Mutex};
use std::thread;
trait AssertSend: Send {}
impl AssertSend for mpsc::Sender<i32> {}
impl AssertSend for mpsc::Receiver<i32> {}
#[test]
fn send_recv() {
let (mut tx, rx) = mpsc::channel::<i32>(16);
block_on(tx.send(1)).unwrap();
drop(tx);
let v: Vec<_> = block_on(rx.collect());
assert_eq!(v, vec![1]);
}
#[test]
fn send_recv_no_buffer() {
// Run on a task context
block_on(poll_fn(move |cx| {
let (tx, rx) = mpsc::channel::<i32>(0);
pin_mut!(tx, rx);
assert!(tx.as_mut().poll_flush(cx).is_ready());
assert!(tx.as_mut().poll_ready(cx).is_ready());
// Send first message
assert!(tx.as_mut().start_send(1).is_ok());
assert!(tx.as_mut().poll_ready(cx).is_pending());
// poll_ready said Pending, so no room in buffer, therefore new sends
// should get rejected with is_full.
assert!(tx.as_mut().start_send(0).unwrap_err().is_full());
assert!(tx.as_mut().poll_ready(cx).is_pending());
// Take the value
assert_eq!(rx.as_mut().poll_next(cx), Poll::Ready(Some(1)));
assert!(tx.as_mut().poll_ready(cx).is_ready());
// Send second message
assert!(tx.as_mut().poll_ready(cx).is_ready());
assert!(tx.as_mut().start_send(2).is_ok());
assert!(tx.as_mut().poll_ready(cx).is_pending());
// Take the value
assert_eq!(rx.as_mut().poll_next(cx), Poll::Ready(Some(2)));
assert!(tx.as_mut().poll_ready(cx).is_ready());
Poll::Ready(())
}));
}
#[test]
fn send_shared_recv() {
let (mut tx1, rx) = mpsc::channel::<i32>(16);
let mut rx = block_on_stream(rx);
let mut tx2 = tx1.clone();
block_on(tx1.send(1)).unwrap();
assert_eq!(rx.next(), Some(1));
block_on(tx2.send(2)).unwrap();
assert_eq!(rx.next(), Some(2));
}
#[test]
fn send_recv_threads() {
let (mut tx, rx) = mpsc::channel::<i32>(16);
let t = thread::spawn(move || {
block_on(tx.send(1)).unwrap();
});
let v: Vec<_> = block_on(rx.take(1).collect());
assert_eq!(v, vec![1]);
t.join().unwrap();
}
#[test]
fn send_recv_threads_no_capacity() {
let (mut tx, rx) = mpsc::channel::<i32>(0);
let t = thread::spawn(move || {
block_on(tx.send(1)).unwrap();
block_on(tx.send(2)).unwrap();
});
let v: Vec<_> = block_on(rx.collect());
assert_eq!(v, vec![1, 2]);
t.join().unwrap();
}
#[test]
fn recv_close_gets_none() {
let (mut tx, mut rx) = mpsc::channel::<i32>(10);
// Run on a task context
block_on(poll_fn(move |cx| {
rx.close();
assert_eq!(rx.poll_next_unpin(cx), Poll::Ready(None));
match tx.poll_ready(cx) {
Poll::Pending | Poll::Ready(Ok(_)) => panic!(),
Poll::Ready(Err(e)) => assert!(e.is_disconnected()),
};
Poll::Ready(())
}));
}
#[test]
fn tx_close_gets_none() {
let (_, mut rx) = mpsc::channel::<i32>(10);
// Run on a task context
block_on(poll_fn(move |cx| {
assert_eq!(rx.poll_next_unpin(cx), Poll::Ready(None));
Poll::Ready(())
}));
}
// #[test]
// fn spawn_sends_items() {
// let core = local_executor::Core::new();
// let stream = unfold(0, |i| Some(ok::<_,u8>((i, i + 1))));
// let rx = mpsc::spawn(stream, &core, 1);
// assert_eq!(core.run(rx.take(4).collect()).unwrap(),
// [0, 1, 2, 3]);
// }
// #[test]
// fn spawn_kill_dead_stream() {
// use std::thread;
// use std::time::Duration;
// use futures::future::Either;
// use futures::sync::oneshot;
//
// // a stream which never returns anything (maybe a remote end isn't
// // responding), but dropping it leads to observable side effects
// // (like closing connections, releasing limited resources, ...)
// #[derive(Debug)]
// struct Dead {
// // when dropped you should get Err(oneshot::Canceled) on the
// // receiving end
// done: oneshot::Sender<()>,
// }
// impl Stream for Dead {
// type Item = ();
// type Error = ();
//
// fn poll(&mut self) -> Poll<Option<Self::Item>, Self::Error> {
// Ok(Poll::Pending)
// }
// }
//
// // need to implement a timeout for the test, as it would hang
// // forever right now
// let (timeout_tx, timeout_rx) = oneshot::channel();
// thread::spawn(move || {
// thread::sleep(Duration::from_millis(1000));
// let _ = timeout_tx.send(());
// });
//
// let core = local_executor::Core::new();
// let (done_tx, done_rx) = oneshot::channel();
// let stream = Dead{done: done_tx};
// let rx = mpsc::spawn(stream, &core, 1);
// let res = core.run(
// Ok::<_, ()>(())
// .into_future()
// .then(move |_| {
// // now drop the spawned stream: maybe some timeout exceeded,
// // or some connection on this end was closed by the remote
// // end.
// drop(rx);
// // and wait for the spawned stream to release its resources
// done_rx
// })
// .select2(timeout_rx)
// );
// match res {
// Err(Either::A((oneshot::Canceled, _))) => (),
// _ => {
// panic!("dead stream wasn't canceled");
// },
// }
// }
#[test]
fn stress_shared_unbounded() {
const AMT: u32 = if cfg!(miri) { 100 } else { 10000 };
const NTHREADS: u32 = 8;
let (tx, rx) = mpsc::unbounded::<i32>();
let t = thread::spawn(move || {
let result: Vec<_> = block_on(rx.collect());
assert_eq!(result.len(), (AMT * NTHREADS) as usize);
for item in result {
assert_eq!(item, 1);
}
});
for _ in 0..NTHREADS {
let tx = tx.clone();
thread::spawn(move || {
for _ in 0..AMT {
tx.unbounded_send(1).unwrap();
}
});
}
drop(tx);
t.join().ok().unwrap();
}
#[test]
fn stress_shared_bounded_hard() {
const AMT: u32 = if cfg!(miri) { 100 } else { 10000 };
const NTHREADS: u32 = 8;
let (tx, rx) = mpsc::channel::<i32>(0);
let t = thread::spawn(move || {
let result: Vec<_> = block_on(rx.collect());
assert_eq!(result.len(), (AMT * NTHREADS) as usize);
for item in result {
assert_eq!(item, 1);
}
});
for _ in 0..NTHREADS {
let mut tx = tx.clone();
thread::spawn(move || {
for _ in 0..AMT {
block_on(tx.send(1)).unwrap();
}
});
}
drop(tx);
t.join().unwrap();
}
#[allow(clippy::same_item_push)]
#[test]
fn stress_receiver_multi_task_bounded_hard() {
const AMT: usize = if cfg!(miri) { 100 } else { 10_000 };
const NTHREADS: u32 = 2;
let (mut tx, rx) = mpsc::channel::<usize>(0);
let rx = Arc::new(Mutex::new(Some(rx)));
let n = Arc::new(AtomicUsize::new(0));
let mut th = vec![];
for _ in 0..NTHREADS {
let rx = rx.clone();
let n = n.clone();
let t = thread::spawn(move || {
let mut i = 0;
loop {
i += 1;
let mut rx_opt = rx.lock().unwrap();
if let Some(rx) = &mut *rx_opt {
if i % 5 == 0 {
let item = block_on(rx.next());
if item.is_none() {
*rx_opt = None;
break;
}
n.fetch_add(1, Ordering::Relaxed);
} else {
// Just poll
let n = n.clone();
match rx.poll_next_unpin(&mut noop_context()) {
Poll::Ready(Some(_)) => {
n.fetch_add(1, Ordering::Relaxed);
}
Poll::Ready(None) => {
*rx_opt = None;
break;
}
Poll::Pending => {}
}
}
} else {
break;
}
}
});
th.push(t);
}
for i in 0..AMT {
block_on(tx.send(i)).unwrap();
}
drop(tx);
for t in th {
t.join().unwrap();
}
assert_eq!(AMT, n.load(Ordering::Relaxed));
}
/// Stress test that receiver properly receives all the messages
/// after sender dropped.
#[test]
fn stress_drop_sender() {
const ITER: usize = if cfg!(miri) { 100 } else { 10000 };
fn list() -> impl Stream<Item = i32> {
let (tx, rx) = mpsc::channel(1);
thread::spawn(move || {
block_on(send_one_two_three(tx));
});
rx
}
for _ in 0..ITER {
let v: Vec<_> = block_on(list().collect());
assert_eq!(v, vec![1, 2, 3]);
}
}
async fn send_one_two_three(mut tx: mpsc::Sender<i32>) {
for i in 1..=3 {
tx.send(i).await.unwrap();
}
}
/// Stress test that after receiver dropped,
/// no messages are lost.
fn stress_close_receiver_iter() {
let (tx, rx) = mpsc::unbounded();
let mut rx = block_on_stream(rx);
let (unwritten_tx, unwritten_rx) = std::sync::mpsc::channel();
let th = thread::spawn(move || {
for i in 1.. {
if tx.unbounded_send(i).is_err() {
unwritten_tx.send(i).expect("unwritten_tx");
return;
}
}
});
// Read one message to make sure thread effectively started
assert_eq!(Some(1), rx.next());
rx.close();
for i in 2.. {
match rx.next() {
Some(r) => assert!(i == r),
None => {
let unwritten = unwritten_rx.recv().expect("unwritten_rx");
assert_eq!(unwritten, i);
th.join().unwrap();
return;
}
}
}
}
#[test]
fn stress_close_receiver() {
const ITER: usize = if cfg!(miri) { 50 } else { 10000 };
for _ in 0..ITER {
stress_close_receiver_iter();
}
}
async fn stress_poll_ready_sender(mut sender: mpsc::Sender<u32>, count: u32) {
for i in (1..=count).rev() {
sender.send(i).await.unwrap();
}
}
/// Tests that after `poll_ready` indicates capacity a channel can always send without waiting.
#[allow(clippy::same_item_push)]
#[test]
fn stress_poll_ready() {
const AMT: u32 = if cfg!(miri) { 100 } else { 1000 };
const NTHREADS: u32 = 8;
/// Run a stress test using the specified channel capacity.
fn stress(capacity: usize) {
let (tx, rx) = mpsc::channel(capacity);
let mut threads = Vec::new();
for _ in 0..NTHREADS {
let sender = tx.clone();
threads.push(thread::spawn(move || block_on(stress_poll_ready_sender(sender, AMT))));
}
drop(tx);
let result: Vec<_> = block_on(rx.collect());
assert_eq!(result.len() as u32, AMT * NTHREADS);
for thread in threads {
thread.join().unwrap();
}
}
stress(0);
stress(1);
stress(8);
stress(16);
}
#[test]
fn try_send_1() {
const N: usize = if cfg!(miri) { 100 } else { 3000 };
let (mut tx, rx) = mpsc::channel(0);
let t = thread::spawn(move || {
for i in 0..N {
loop {
if tx.try_send(i).is_ok() {
break;
}
}
}
});
let result: Vec<_> = block_on(rx.collect());
for (i, j) in result.into_iter().enumerate() {
assert_eq!(i, j);
}
t.join().unwrap();
}
#[test]
fn try_send_2() {
let (mut tx, rx) = mpsc::channel(0);
let mut rx = block_on_stream(rx);
tx.try_send("hello").unwrap();
let (readytx, readyrx) = oneshot::channel::<()>();
let th = thread::spawn(move || {
block_on(poll_fn(|cx| {
assert!(tx.poll_ready(cx).is_pending());
Poll::Ready(())
}));
drop(readytx);
block_on(tx.send("goodbye")).unwrap();
});
let _ = block_on(readyrx);
assert_eq!(rx.next(), Some("hello"));
assert_eq!(rx.next(), Some("goodbye"));
assert_eq!(rx.next(), None);
th.join().unwrap();
}
#[test]
fn try_send_fail() {
let (mut tx, rx) = mpsc::channel(0);
let mut rx = block_on_stream(rx);
tx.try_send("hello").unwrap();
// This should fail
assert!(tx.try_send("fail").is_err());
assert_eq!(rx.next(), Some("hello"));
tx.try_send("goodbye").unwrap();
drop(tx);
assert_eq!(rx.next(), Some("goodbye"));
assert_eq!(rx.next(), None);
}
#[test]
fn try_send_recv() {
let (mut tx, mut rx) = mpsc::channel(1);
tx.try_send("hello").unwrap();
tx.try_send("hello").unwrap();
tx.try_send("hello").unwrap_err(); // should be full
rx.try_next().unwrap();
rx.try_next().unwrap();
rx.try_next().unwrap_err(); // should be empty
tx.try_send("hello").unwrap();
rx.try_next().unwrap();
rx.try_next().unwrap_err(); // should be empty
}
#[test]
fn same_receiver() {
let (mut txa1, _) = mpsc::channel::<i32>(1);
let txa2 = txa1.clone();
let (mut txb1, _) = mpsc::channel::<i32>(1);
let txb2 = txb1.clone();
assert!(txa1.same_receiver(&txa2));
assert!(txb1.same_receiver(&txb2));
assert!(!txa1.same_receiver(&txb1));
txa1.disconnect();
txb1.close_channel();
assert!(!txa1.same_receiver(&txa2));
assert!(txb1.same_receiver(&txb2));
}
#[test]
fn is_connected_to() {
let (txa, rxa) = mpsc::channel::<i32>(1);
let (txb, rxb) = mpsc::channel::<i32>(1);
assert!(txa.is_connected_to(&rxa));
assert!(txb.is_connected_to(&rxb));
assert!(!txa.is_connected_to(&rxb));
assert!(!txb.is_connected_to(&rxa));
}
#[test]
fn hash_receiver() {
use std::collections::hash_map::DefaultHasher;
use std::hash::Hasher;
let mut hasher_a1 = DefaultHasher::new();
let mut hasher_a2 = DefaultHasher::new();
let mut hasher_b1 = DefaultHasher::new();
let mut hasher_b2 = DefaultHasher::new();
let (mut txa1, _) = mpsc::channel::<i32>(1);
let txa2 = txa1.clone();
let (mut txb1, _) = mpsc::channel::<i32>(1);
let txb2 = txb1.clone();
txa1.hash_receiver(&mut hasher_a1);
let hash_a1 = hasher_a1.finish();
txa2.hash_receiver(&mut hasher_a2);
let hash_a2 = hasher_a2.finish();
txb1.hash_receiver(&mut hasher_b1);
let hash_b1 = hasher_b1.finish();
txb2.hash_receiver(&mut hasher_b2);
let hash_b2 = hasher_b2.finish();
assert_eq!(hash_a1, hash_a2);
assert_eq!(hash_b1, hash_b2);
assert!(hash_a1 != hash_b1);
txa1.disconnect();
txb1.close_channel();
let mut hasher_a1 = DefaultHasher::new();
let mut hasher_a2 = DefaultHasher::new();
let mut hasher_b1 = DefaultHasher::new();
let mut hasher_b2 = DefaultHasher::new();
txa1.hash_receiver(&mut hasher_a1);
let hash_a1 = hasher_a1.finish();
txa2.hash_receiver(&mut hasher_a2);
let hash_a2 = hasher_a2.finish();
txb1.hash_receiver(&mut hasher_b1);
let hash_b1 = hasher_b1.finish();
txb2.hash_receiver(&mut hasher_b2);
let hash_b2 = hasher_b2.finish();
assert!(hash_a1 != hash_a2);
assert_eq!(hash_b1, hash_b2);
}
#[test]
fn send_backpressure() {
let (waker, counter) = new_count_waker();
let mut cx = Context::from_waker(&waker);
let (mut tx, mut rx) = mpsc::channel(1);
block_on(tx.send(1)).unwrap();
let mut task = tx.send(2);
assert_eq!(task.poll_unpin(&mut cx), Poll::Pending);
assert_eq!(counter, 0);
let item = block_on(rx.next()).unwrap();
assert_eq!(item, 1);
assert_eq!(counter, 1);
assert_eq!(task.poll_unpin(&mut cx), Poll::Ready(Ok(())));
let item = block_on(rx.next()).unwrap();
assert_eq!(item, 2);
}
#[test]
fn send_backpressure_multi_senders() {
let (waker, counter) = new_count_waker();
let mut cx = Context::from_waker(&waker);
let (mut tx1, mut rx) = mpsc::channel(1);
let mut tx2 = tx1.clone();
block_on(tx1.send(1)).unwrap();
let mut task = tx2.send(2);
assert_eq!(task.poll_unpin(&mut cx), Poll::Pending);
assert_eq!(counter, 0);
let item = block_on(rx.next()).unwrap();
assert_eq!(item, 1);
assert_eq!(counter, 1);
assert_eq!(task.poll_unpin(&mut cx), Poll::Ready(Ok(())));
let item = block_on(rx.next()).unwrap();
assert_eq!(item, 2);
}