use futures::channel::oneshot; use futures::executor::{block_on, block_on_stream}; use futures::future::{self, join, Future, FutureExt}; use futures::stream::{FusedStream, FuturesUnordered, StreamExt}; use futures::task::{Context, Poll}; use futures_test::future::FutureTestExt; use futures_test::task::noop_context; use futures_test::{assert_stream_done, assert_stream_next, assert_stream_pending}; use std::iter::FromIterator; use std::pin::Pin; use std::sync::atomic::{AtomicBool, Ordering}; #[test] fn is_terminated() { let mut cx = noop_context(); let mut tasks = FuturesUnordered::new(); assert_eq!(tasks.is_terminated(), false); assert_eq!(tasks.poll_next_unpin(&mut cx), Poll::Ready(None)); assert_eq!(tasks.is_terminated(), true); // Test that the sentinel value doesn't leak assert_eq!(tasks.is_empty(), true); assert_eq!(tasks.len(), 0); assert_eq!(tasks.iter_mut().len(), 0); tasks.push(future::ready(1)); assert_eq!(tasks.is_empty(), false); assert_eq!(tasks.len(), 1); assert_eq!(tasks.iter_mut().len(), 1); assert_eq!(tasks.is_terminated(), false); assert_eq!(tasks.poll_next_unpin(&mut cx), Poll::Ready(Some(1))); assert_eq!(tasks.is_terminated(), false); assert_eq!(tasks.poll_next_unpin(&mut cx), Poll::Ready(None)); assert_eq!(tasks.is_terminated(), true); } #[test] fn works_1() { let (a_tx, a_rx) = oneshot::channel::(); let (b_tx, b_rx) = oneshot::channel::(); let (c_tx, c_rx) = oneshot::channel::(); let mut iter = block_on_stream(vec![a_rx, b_rx, c_rx].into_iter().collect::>()); b_tx.send(99).unwrap(); assert_eq!(Some(Ok(99)), iter.next()); a_tx.send(33).unwrap(); c_tx.send(33).unwrap(); assert_eq!(Some(Ok(33)), iter.next()); assert_eq!(Some(Ok(33)), iter.next()); assert_eq!(None, iter.next()); } #[test] fn works_2() { let (a_tx, a_rx) = oneshot::channel::(); let (b_tx, b_rx) = oneshot::channel::(); let (c_tx, c_rx) = oneshot::channel::(); let mut stream = vec![a_rx.boxed(), join(b_rx, c_rx).map(|(a, b)| Ok(a? + b?)).boxed()] .into_iter() .collect::>(); a_tx.send(9).unwrap(); b_tx.send(10).unwrap(); let mut cx = noop_context(); assert_eq!(stream.poll_next_unpin(&mut cx), Poll::Ready(Some(Ok(9)))); c_tx.send(20).unwrap(); assert_eq!(stream.poll_next_unpin(&mut cx), Poll::Ready(Some(Ok(30)))); assert_eq!(stream.poll_next_unpin(&mut cx), Poll::Ready(None)); } #[test] fn from_iterator() { let stream = vec![future::ready::(1), future::ready::(2), future::ready::(3)] .into_iter() .collect::>(); assert_eq!(stream.len(), 3); assert_eq!(block_on(stream.collect::>()), vec![1, 2, 3]); } #[test] fn finished_future() { let (_a_tx, a_rx) = oneshot::channel::(); let (b_tx, b_rx) = oneshot::channel::(); let (c_tx, c_rx) = oneshot::channel::(); let mut stream = vec![ Box::new(a_rx) as Box> + Unpin>, Box::new(future::select(b_rx, c_rx).map(|e| e.factor_first().0)) as _, ] .into_iter() .collect::>(); let cx = &mut noop_context(); for _ in 0..10 { assert!(stream.poll_next_unpin(cx).is_pending()); } b_tx.send(12).unwrap(); c_tx.send(3).unwrap(); assert!(stream.poll_next_unpin(cx).is_ready()); assert!(stream.poll_next_unpin(cx).is_pending()); assert!(stream.poll_next_unpin(cx).is_pending()); } #[test] fn iter_mut_cancel() { let (a_tx, a_rx) = oneshot::channel::(); let (b_tx, b_rx) = oneshot::channel::(); let (c_tx, c_rx) = oneshot::channel::(); let mut stream = vec![a_rx, b_rx, c_rx].into_iter().collect::>(); for rx in stream.iter_mut() { rx.close(); } let mut iter = block_on_stream(stream); assert!(a_tx.is_canceled()); assert!(b_tx.is_canceled()); assert!(c_tx.is_canceled()); assert_eq!(iter.next(), Some(Err(futures::channel::oneshot::Canceled))); assert_eq!(iter.next(), Some(Err(futures::channel::oneshot::Canceled))); assert_eq!(iter.next(), Some(Err(futures::channel::oneshot::Canceled))); assert_eq!(iter.next(), None); } #[test] fn iter_mut_len() { let mut stream = vec![future::pending::<()>(), future::pending::<()>(), future::pending::<()>()] .into_iter() .collect::>(); let mut iter_mut = stream.iter_mut(); assert_eq!(iter_mut.len(), 3); assert!(iter_mut.next().is_some()); assert_eq!(iter_mut.len(), 2); assert!(iter_mut.next().is_some()); assert_eq!(iter_mut.len(), 1); assert!(iter_mut.next().is_some()); assert_eq!(iter_mut.len(), 0); assert!(iter_mut.next().is_none()); } #[test] fn iter_cancel() { struct AtomicCancel { future: F, cancel: AtomicBool, } impl Future for AtomicCancel { type Output = Option<::Output>; fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { if self.cancel.load(Ordering::Relaxed) { Poll::Ready(None) } else { self.future.poll_unpin(cx).map(Some) } } } impl AtomicCancel { fn new(future: F) -> Self { Self { future, cancel: AtomicBool::new(false) } } } let stream = vec![ AtomicCancel::new(future::pending::<()>()), AtomicCancel::new(future::pending::<()>()), AtomicCancel::new(future::pending::<()>()), ] .into_iter() .collect::>(); for f in stream.iter() { f.cancel.store(true, Ordering::Relaxed); } let mut iter = block_on_stream(stream); assert_eq!(iter.next(), Some(None)); assert_eq!(iter.next(), Some(None)); assert_eq!(iter.next(), Some(None)); assert_eq!(iter.next(), None); } #[test] fn iter_len() { let stream = vec![future::pending::<()>(), future::pending::<()>(), future::pending::<()>()] .into_iter() .collect::>(); let mut iter = stream.iter(); assert_eq!(iter.len(), 3); assert!(iter.next().is_some()); assert_eq!(iter.len(), 2); assert!(iter.next().is_some()); assert_eq!(iter.len(), 1); assert!(iter.next().is_some()); assert_eq!(iter.len(), 0); assert!(iter.next().is_none()); } #[test] fn into_iter_cancel() { let (a_tx, a_rx) = oneshot::channel::(); let (b_tx, b_rx) = oneshot::channel::(); let (c_tx, c_rx) = oneshot::channel::(); let stream = vec![a_rx, b_rx, c_rx].into_iter().collect::>(); let stream = stream .into_iter() .map(|mut rx| { rx.close(); rx }) .collect::>(); let mut iter = block_on_stream(stream); assert!(a_tx.is_canceled()); assert!(b_tx.is_canceled()); assert!(c_tx.is_canceled()); assert_eq!(iter.next(), Some(Err(futures::channel::oneshot::Canceled))); assert_eq!(iter.next(), Some(Err(futures::channel::oneshot::Canceled))); assert_eq!(iter.next(), Some(Err(futures::channel::oneshot::Canceled))); assert_eq!(iter.next(), None); } #[test] fn into_iter_len() { let stream = vec![future::pending::<()>(), future::pending::<()>(), future::pending::<()>()] .into_iter() .collect::>(); let mut into_iter = stream.into_iter(); assert_eq!(into_iter.len(), 3); assert!(into_iter.next().is_some()); assert_eq!(into_iter.len(), 2); assert!(into_iter.next().is_some()); assert_eq!(into_iter.len(), 1); assert!(into_iter.next().is_some()); assert_eq!(into_iter.len(), 0); assert!(into_iter.next().is_none()); } #[test] fn into_iter_partial() { let stream = vec![future::ready(1), future::ready(2), future::ready(3), future::ready(4)] .into_iter() .collect::>(); let mut into_iter = stream.into_iter(); assert!(into_iter.next().is_some()); assert!(into_iter.next().is_some()); assert!(into_iter.next().is_some()); assert_eq!(into_iter.len(), 1); // don't panic when iterator is dropped before completing } #[test] fn futures_not_moved_after_poll() { // Future that will be ready after being polled twice, // asserting that it does not move. let fut = future::ready(()).pending_once().assert_unmoved(); let mut stream = vec![fut; 3].into_iter().collect::>(); assert_stream_pending!(stream); assert_stream_next!(stream, ()); assert_stream_next!(stream, ()); assert_stream_next!(stream, ()); assert_stream_done!(stream); } #[test] fn len_valid_during_out_of_order_completion() { // Complete futures out-of-order and add new futures afterwards to ensure // length values remain correct. let (a_tx, a_rx) = oneshot::channel::(); let (b_tx, b_rx) = oneshot::channel::(); let (c_tx, c_rx) = oneshot::channel::(); let (d_tx, d_rx) = oneshot::channel::(); let mut cx = noop_context(); let mut stream = FuturesUnordered::new(); assert_eq!(stream.len(), 0); stream.push(a_rx); assert_eq!(stream.len(), 1); stream.push(b_rx); assert_eq!(stream.len(), 2); stream.push(c_rx); assert_eq!(stream.len(), 3); b_tx.send(4).unwrap(); assert_eq!(stream.poll_next_unpin(&mut cx), Poll::Ready(Some(Ok(4)))); assert_eq!(stream.len(), 2); stream.push(d_rx); assert_eq!(stream.len(), 3); c_tx.send(5).unwrap(); assert_eq!(stream.poll_next_unpin(&mut cx), Poll::Ready(Some(Ok(5)))); assert_eq!(stream.len(), 2); d_tx.send(6).unwrap(); assert_eq!(stream.poll_next_unpin(&mut cx), Poll::Ready(Some(Ok(6)))); assert_eq!(stream.len(), 1); a_tx.send(7).unwrap(); assert_eq!(stream.poll_next_unpin(&mut cx), Poll::Ready(Some(Ok(7)))); assert_eq!(stream.len(), 0); } #[test] fn polled_only_once_at_most_per_iteration() { #[derive(Debug, Clone, Copy, Default)] struct F { polled: bool, } impl Future for F { type Output = (); fn poll(mut self: Pin<&mut Self>, _: &mut Context) -> Poll { if self.polled { panic!("polled twice") } else { self.polled = true; Poll::Pending } } } let cx = &mut noop_context(); let mut tasks = FuturesUnordered::from_iter(vec![F::default(); 10]); assert!(tasks.poll_next_unpin(cx).is_pending()); assert_eq!(10, tasks.iter().filter(|f| f.polled).count()); let mut tasks = FuturesUnordered::from_iter(vec![F::default(); 33]); assert!(tasks.poll_next_unpin(cx).is_pending()); assert_eq!(33, tasks.iter().filter(|f| f.polled).count()); let mut tasks = FuturesUnordered::::new(); assert_eq!(Poll::Ready(None), tasks.poll_next_unpin(cx)); } #[test] fn clear() { let mut tasks = FuturesUnordered::from_iter(vec![future::ready(1), future::ready(2)]); assert_eq!(block_on(tasks.next()), Some(1)); assert!(!tasks.is_empty()); tasks.clear(); assert!(tasks.is_empty()); tasks.push(future::ready(3)); assert!(!tasks.is_empty()); tasks.clear(); assert!(tasks.is_empty()); assert_eq!(block_on(tasks.next()), None); assert!(tasks.is_terminated()); tasks.clear(); assert!(!tasks.is_terminated()); }