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fuchsia / fuchsia / bdc0c4d1c7f8 / . / third_party / rust_crates / vendor / async-channel / tests / bounded.rs
blob: b9bf409dee3d489d4ad15340430645ae87c18083 [file] [log] [blame]
use std::sync::atomic::{AtomicUsize, Ordering};
use std::thread::sleep;
use std::time::Duration;
use async_channel::{bounded, RecvError, SendError, TryRecvError, TrySendError};
use easy_parallel::Parallel;
use futures_lite::{future, prelude::*};
fn ms(ms: u64) -> Duration {
Duration::from_millis(ms)
}
#[test]
fn smoke() {
let (s, r) = bounded(1);
future::block_on(s.send(7)).unwrap();
assert_eq!(r.try_recv(), Ok(7));
future::block_on(s.send(8)).unwrap();
assert_eq!(future::block_on(r.recv()), Ok(8));
assert_eq!(r.try_recv(), Err(TryRecvError::Empty));
}
#[test]
fn capacity() {
for i in 1..10 {
let (s, r) = bounded::<()>(i);
assert_eq!(s.capacity(), Some(i));
assert_eq!(r.capacity(), Some(i));
}
}
#[test]
fn len_empty_full() {
let (s, r) = bounded(2);
assert_eq!(s.len(), 0);
assert_eq!(s.is_empty(), true);
assert_eq!(s.is_full(), false);
assert_eq!(r.len(), 0);
assert_eq!(r.is_empty(), true);
assert_eq!(r.is_full(), false);
future::block_on(s.send(())).unwrap();
assert_eq!(s.len(), 1);
assert_eq!(s.is_empty(), false);
assert_eq!(s.is_full(), false);
assert_eq!(r.len(), 1);
assert_eq!(r.is_empty(), false);
assert_eq!(r.is_full(), false);
future::block_on(s.send(())).unwrap();
assert_eq!(s.len(), 2);
assert_eq!(s.is_empty(), false);
assert_eq!(s.is_full(), true);
assert_eq!(r.len(), 2);
assert_eq!(r.is_empty(), false);
assert_eq!(r.is_full(), true);
future::block_on(r.recv()).unwrap();
assert_eq!(s.len(), 1);
assert_eq!(s.is_empty(), false);
assert_eq!(s.is_full(), false);
assert_eq!(r.len(), 1);
assert_eq!(r.is_empty(), false);
assert_eq!(r.is_full(), false);
}
#[test]
fn try_recv() {
let (s, r) = bounded(100);
Parallel::new()
.add(move || {
assert_eq!(r.try_recv(), Err(TryRecvError::Empty));
sleep(ms(1500));
assert_eq!(r.try_recv(), Ok(7));
sleep(ms(500));
assert_eq!(r.try_recv(), Err(TryRecvError::Closed));
})
.add(move || {
sleep(ms(1000));
future::block_on(s.send(7)).unwrap();
})
.run();
}
#[test]
fn recv() {
let (s, r) = bounded(100);
Parallel::new()
.add(move || {
assert_eq!(future::block_on(r.recv()), Ok(7));
sleep(ms(1000));
assert_eq!(future::block_on(r.recv()), Ok(8));
sleep(ms(1000));
assert_eq!(future::block_on(r.recv()), Ok(9));
assert_eq!(future::block_on(r.recv()), Err(RecvError));
})
.add(move || {
sleep(ms(1500));
future::block_on(s.send(7)).unwrap();
future::block_on(s.send(8)).unwrap();
future::block_on(s.send(9)).unwrap();
})
.run();
}
#[test]
fn try_send() {
let (s, r) = bounded(1);
Parallel::new()
.add(move || {
assert_eq!(s.try_send(1), Ok(()));
assert_eq!(s.try_send(2), Err(TrySendError::Full(2)));
sleep(ms(1500));
assert_eq!(s.try_send(3), Ok(()));
sleep(ms(500));
assert_eq!(s.try_send(4), Err(TrySendError::Closed(4)));
})
.add(move || {
sleep(ms(1000));
assert_eq!(r.try_recv(), Ok(1));
assert_eq!(r.try_recv(), Err(TryRecvError::Empty));
assert_eq!(future::block_on(r.recv()), Ok(3));
})
.run();
}
#[test]
fn send() {
let (s, r) = bounded(1);
Parallel::new()
.add(|| {
future::block_on(s.send(7)).unwrap();
sleep(ms(1000));
future::block_on(s.send(8)).unwrap();
sleep(ms(1000));
future::block_on(s.send(9)).unwrap();
sleep(ms(1000));
future::block_on(s.send(10)).unwrap();
})
.add(|| {
sleep(ms(1500));
assert_eq!(future::block_on(r.recv()), Ok(7));
assert_eq!(future::block_on(r.recv()), Ok(8));
assert_eq!(future::block_on(r.recv()), Ok(9));
})
.run();
}
#[test]
fn send_after_close() {
let (s, r) = bounded(100);
future::block_on(s.send(1)).unwrap();
future::block_on(s.send(2)).unwrap();
future::block_on(s.send(3)).unwrap();
drop(r);
assert_eq!(future::block_on(s.send(4)), Err(SendError(4)));
assert_eq!(s.try_send(5), Err(TrySendError::Closed(5)));
assert_eq!(future::block_on(s.send(6)), Err(SendError(6)));
}
#[test]
fn recv_after_close() {
let (s, r) = bounded(100);
future::block_on(s.send(1)).unwrap();
future::block_on(s.send(2)).unwrap();
future::block_on(s.send(3)).unwrap();
drop(s);
assert_eq!(future::block_on(r.recv()), Ok(1));
assert_eq!(future::block_on(r.recv()), Ok(2));
assert_eq!(future::block_on(r.recv()), Ok(3));
assert_eq!(future::block_on(r.recv()), Err(RecvError));
}
#[test]
fn len() {
const COUNT: usize = 25_000;
const CAP: usize = 1000;
let (s, r) = bounded(CAP);
assert_eq!(s.len(), 0);
assert_eq!(r.len(), 0);
for _ in 0..CAP / 10 {
for i in 0..50 {
future::block_on(s.send(i)).unwrap();
assert_eq!(s.len(), i + 1);
}
for i in 0..50 {
future::block_on(r.recv()).unwrap();
assert_eq!(r.len(), 50 - i - 1);
}
}
assert_eq!(s.len(), 0);
assert_eq!(r.len(), 0);
for i in 0..CAP {
future::block_on(s.send(i)).unwrap();
assert_eq!(s.len(), i + 1);
}
for _ in 0..CAP {
future::block_on(r.recv()).unwrap();
}
assert_eq!(s.len(), 0);
assert_eq!(r.len(), 0);
Parallel::new()
.add(|| {
for i in 0..COUNT {
assert_eq!(future::block_on(r.recv()), Ok(i));
let len = r.len();
assert!(len <= CAP);
}
})
.add(|| {
for i in 0..COUNT {
future::block_on(s.send(i)).unwrap();
let len = s.len();
assert!(len <= CAP);
}
})
.run();
assert_eq!(s.len(), 0);
assert_eq!(r.len(), 0);
}
#[test]
fn receiver_count() {
let (s, r) = bounded::<()>(5);
let receiver_clones: Vec<_> = (0..20).map(|_| r.clone()).collect();
assert_eq!(s.receiver_count(), 21);
assert_eq!(r.receiver_count(), 21);
drop(receiver_clones);
assert_eq!(s.receiver_count(), 1);
assert_eq!(r.receiver_count(), 1);
}
#[test]
fn sender_count() {
let (s, r) = bounded::<()>(5);
let sender_clones: Vec<_> = (0..20).map(|_| s.clone()).collect();
assert_eq!(s.sender_count(), 21);
assert_eq!(r.sender_count(), 21);
drop(sender_clones);
assert_eq!(s.receiver_count(), 1);
assert_eq!(r.receiver_count(), 1);
}
#[test]
fn close_wakes_sender() {
let (s, r) = bounded(1);
Parallel::new()
.add(move || {
assert_eq!(future::block_on(s.send(())), Ok(()));
assert_eq!(future::block_on(s.send(())), Err(SendError(())));
})
.add(move || {
sleep(ms(1000));
drop(r);
})
.run();
}
#[test]
fn close_wakes_receiver() {
let (s, r) = bounded::<()>(1);
Parallel::new()
.add(move || {
assert_eq!(future::block_on(r.recv()), Err(RecvError));
})
.add(move || {
sleep(ms(1000));
drop(s);
})
.run();
}
#[test]
fn spsc() {
const COUNT: usize = 100_000;
let (s, r) = bounded(3);
Parallel::new()
.add(move || {
for i in 0..COUNT {
assert_eq!(future::block_on(r.recv()), Ok(i));
}
assert_eq!(future::block_on(r.recv()), Err(RecvError));
})
.add(move || {
for i in 0..COUNT {
future::block_on(s.send(i)).unwrap();
}
})
.run();
}
#[test]
fn mpmc() {
const COUNT: usize = 25_000;
const THREADS: usize = 4;
let (s, r) = bounded::<usize>(3);
let v = (0..COUNT).map(|_| AtomicUsize::new(0)).collect::<Vec<_>>();
Parallel::new()
.each(0..THREADS, |_| {
for _ in 0..COUNT {
let n = future::block_on(r.recv()).unwrap();
v[n].fetch_add(1, Ordering::SeqCst);
}
})
.each(0..THREADS, |_| {
for i in 0..COUNT {
future::block_on(s.send(i)).unwrap();
}
})
.run();
for c in v {
assert_eq!(c.load(Ordering::SeqCst), THREADS);
}
}
#[test]
fn mpmc_stream() {
const COUNT: usize = 25_000;
const THREADS: usize = 4;
let (s, r) = bounded::<usize>(3);
let v = (0..COUNT).map(|_| AtomicUsize::new(0)).collect::<Vec<_>>();
let v = &v;
Parallel::new()
.each(0..THREADS, {
let mut r = r;
move |_| {
for _ in 0..COUNT {
let n = future::block_on(r.next()).unwrap();
v[n].fetch_add(1, Ordering::SeqCst);
}
}
})
.each(0..THREADS, |_| {
for i in 0..COUNT {
future::block_on(s.send(i)).unwrap();
}
})
.run();
for c in v {
assert_eq!(c.load(Ordering::SeqCst), THREADS);
}
}