tests/time_interval.rs - platform/external/rust/crates/tokio - Git at Google

 #![warn(rust_2018_idioms)]
 #![cfg(feature = "full")]

 use tokio::time::{self, Duration, Instant, MissedTickBehavior};
 use tokio_test::{assert_pending, assert_ready_eq, task};

 use std::task::Poll;

 // Takes the `Interval` task, `start` variable, and optional time deltas
 // For each time delta, it polls the `Interval` and asserts that the result is
 // equal to `start` + the specific time delta. Then it asserts that the
 // `Interval` is pending.
 macro_rules! check_interval_poll {
     ($i:ident, $start:ident, $($delta:expr),*$(,)?) => {
         $(
             assert_ready_eq!(poll_next(&mut $i), $start + ms($delta));
         )*
         assert_pending!(poll_next(&mut $i));
     };
     ($i:ident, $start:ident) => {
         check_interval_poll!($i, $start,);
     };
 }

 #[tokio::test]
 #[should_panic]
 async fn interval_zero_duration() {
     let _ = time::interval_at(Instant::now(), ms(0));
 }

 // Expected ticks: |     1     |     2     |     3     |     4     |     5     |     6     |
 // Actual ticks:   | work -----|          delay          | work | work | work -| work -----|
 // Poll behavior:  |   |       |                         |      |      |       |           |
 //                 |   |       |                         |      |      |       |           |
 //          Ready(s)   |       |             Ready(s + 2p)      |      |       |           |
 //               Pending       |                    Ready(s + 3p)      |       |           |
 //                  Ready(s + p)                           Ready(s + 4p)       |           |
 //                                                                 Ready(s + 5p)           |
 //                                                                             Ready(s + 6p)
 #[tokio::test(start_paused = true)]
 async fn burst() {
     let start = Instant::now();

     // This is necessary because the timer is only so granular, and in order for
     // all our ticks to resolve, the time needs to be 1ms ahead of what we
     // expect, so that the runtime will see that it is time to resolve the timer
     time::advance(ms(1)).await;

     let mut i = task::spawn(time::interval_at(start, ms(300)));

     check_interval_poll!(i, start, 0);

     time::advance(ms(100)).await;
     check_interval_poll!(i, start);

     time::advance(ms(200)).await;
     check_interval_poll!(i, start, 300);

     time::advance(ms(650)).await;
     check_interval_poll!(i, start, 600, 900);

     time::advance(ms(200)).await;
     check_interval_poll!(i, start);

     time::advance(ms(100)).await;
     check_interval_poll!(i, start, 1200);

     time::advance(ms(250)).await;
     check_interval_poll!(i, start, 1500);

     time::advance(ms(300)).await;
     check_interval_poll!(i, start, 1800);
 }

 // Expected ticks: |     1     |     2     |     3     |     4     |     5     |     6     |
 // Actual ticks:   | work -----|          delay          | work -----| work -----| work -----|
 // Poll behavior:  |   |       |                         |   |       |           |           |
 //                 |   |       |                         |   |       |           |           |
 //          Ready(s)   |       |             Ready(s + 2p)   |       |           |           |
 //               Pending       |                       Pending       |           |           |
 //                  Ready(s + p)                     Ready(s + 2p + d)           |           |
 //                                                               Ready(s + 3p + d)           |
 //                                                                           Ready(s + 4p + d)
 #[tokio::test(start_paused = true)]
 async fn delay() {
     let start = Instant::now();

     // This is necessary because the timer is only so granular, and in order for
     // all our ticks to resolve, the time needs to be 1ms ahead of what we
     // expect, so that the runtime will see that it is time to resolve the timer
     time::advance(ms(1)).await;

     let mut i = task::spawn(time::interval_at(start, ms(300)));
     i.set_missed_tick_behavior(MissedTickBehavior::Delay);

     check_interval_poll!(i, start, 0);

     time::advance(ms(100)).await;
     check_interval_poll!(i, start);

     time::advance(ms(200)).await;
     check_interval_poll!(i, start, 300);

     time::advance(ms(650)).await;
     check_interval_poll!(i, start, 600);

     time::advance(ms(100)).await;
     check_interval_poll!(i, start);

     // We have to add one here for the same reason as is above.
     // Because `Interval` has reset its timer according to `Instant::now()`,
     // we have to go forward 1 more millisecond than is expected so that the
     // runtime realizes that it's time to resolve the timer.
     time::advance(ms(201)).await;
     // We add one because when using the `Delay` behavior, `Interval`
     // adds the `period` from `Instant::now()`, which will always be off by one
     // because we have to advance time by 1 (see above).
     check_interval_poll!(i, start, 1251);

     time::advance(ms(300)).await;
     // Again, we add one.
     check_interval_poll!(i, start, 1551);

     time::advance(ms(300)).await;
     check_interval_poll!(i, start, 1851);
 }

 // Expected ticks: |     1     |     2     |     3     |     4     |     5     |     6     |
 // Actual ticks:   | work -----|          delay          | work ---| work -----| work -----|
 // Poll behavior:  |   |       |                         |         |           |           |
 //                 |   |       |                         |         |           |           |
 //          Ready(s)   |       |             Ready(s + 2p)         |           |           |
 //               Pending       |                       Ready(s + 4p)           |           |
 //                  Ready(s + p)                                   Ready(s + 5p)           |
 //                                                                             Ready(s + 6p)
 #[tokio::test(start_paused = true)]
 async fn skip() {
     let start = Instant::now();

     // This is necessary because the timer is only so granular, and in order for
     // all our ticks to resolve, the time needs to be 1ms ahead of what we
     // expect, so that the runtime will see that it is time to resolve the timer
     time::advance(ms(1)).await;

     let mut i = task::spawn(time::interval_at(start, ms(300)));
     i.set_missed_tick_behavior(MissedTickBehavior::Skip);

     check_interval_poll!(i, start, 0);

     time::advance(ms(100)).await;
     check_interval_poll!(i, start);

     time::advance(ms(200)).await;
     check_interval_poll!(i, start, 300);

     time::advance(ms(650)).await;
     check_interval_poll!(i, start, 600);

     time::advance(ms(250)).await;
     check_interval_poll!(i, start, 1200);

     time::advance(ms(300)).await;
     check_interval_poll!(i, start, 1500);

     time::advance(ms(300)).await;
     check_interval_poll!(i, start, 1800);
 }

 fn poll_next(interval: &mut task::Spawn<time::Interval>) -> Poll<Instant> {
     interval.enter(|cx, mut interval| interval.poll_tick(cx))
 }

 fn ms(n: u64) -> Duration {
     Duration::from_millis(n)
 }
	#![warn(rust_2018_idioms)]
	#![cfg(feature = "full")]

	use tokio::time::{self, Duration, Instant, MissedTickBehavior};
	use tokio_test::{assert_pending, assert_ready_eq, task};

	use std::task::Poll;

	// Takes the `Interval` task, `start` variable, and optional time deltas
	// For each time delta, it polls the `Interval` and asserts that the result is
	// equal to `start` + the specific time delta. Then it asserts that the
	// `Interval` is pending.
	macro_rules! check_interval_poll {
	($i:ident, $start:ident, $($delta:expr),*$(,)?) => {
	$(
	assert_ready_eq!(poll_next(&mut $i), $start + ms($delta));
	)*
	assert_pending!(poll_next(&mut $i));
	};
	($i:ident, $start:ident) => {
	check_interval_poll!($i, $start,);
	};
	}

	#[tokio::test]
	#[should_panic]
	async fn interval_zero_duration() {
	let _ = time::interval_at(Instant::now(), ms(0));
	}

	// Expected ticks: \| 1 \| 2 \| 3 \| 4 \| 5 \| 6 \|
	// Actual ticks: \| work -----\| delay \| work \| work \| work -\| work -----\|
	// Poll behavior: \| \| \| \| \| \| \| \|
	// \| \| \| \| \| \| \| \|
	// Ready(s) \| \| Ready(s + 2p) \| \| \| \|
	// Pending \| Ready(s + 3p) \| \| \|
	// Ready(s + p) Ready(s + 4p) \| \|
	// Ready(s + 5p) \|
	// Ready(s + 6p)
	#[tokio::test(start_paused = true)]
	async fn burst() {
	let start = Instant::now();

	// This is necessary because the timer is only so granular, and in order for
	// all our ticks to resolve, the time needs to be 1ms ahead of what we
	// expect, so that the runtime will see that it is time to resolve the timer
	time::advance(ms(1)).await;

	let mut i = task::spawn(time::interval_at(start, ms(300)));

	check_interval_poll!(i, start, 0);

	time::advance(ms(100)).await;
	check_interval_poll!(i, start);

	time::advance(ms(200)).await;
	check_interval_poll!(i, start, 300);

	time::advance(ms(650)).await;
	check_interval_poll!(i, start, 600, 900);

	time::advance(ms(200)).await;
	check_interval_poll!(i, start);

	time::advance(ms(100)).await;
	check_interval_poll!(i, start, 1200);

	time::advance(ms(250)).await;
	check_interval_poll!(i, start, 1500);

	time::advance(ms(300)).await;
	check_interval_poll!(i, start, 1800);
	}

	// Expected ticks: \| 1 \| 2 \| 3 \| 4 \| 5 \| 6 \|
	// Actual ticks: \| work -----\| delay \| work -----\| work -----\| work -----\|
	// Poll behavior: \| \| \| \| \| \| \| \|
	// \| \| \| \| \| \| \| \|
	// Ready(s) \| \| Ready(s + 2p) \| \| \| \|
	// Pending \| Pending \| \| \|
	// Ready(s + p) Ready(s + 2p + d) \| \|
	// Ready(s + 3p + d) \|
	// Ready(s + 4p + d)
	#[tokio::test(start_paused = true)]
	async fn delay() {
	let start = Instant::now();

	// This is necessary because the timer is only so granular, and in order for
	// all our ticks to resolve, the time needs to be 1ms ahead of what we
	// expect, so that the runtime will see that it is time to resolve the timer
	time::advance(ms(1)).await;

	let mut i = task::spawn(time::interval_at(start, ms(300)));
	i.set_missed_tick_behavior(MissedTickBehavior::Delay);

	check_interval_poll!(i, start, 0);

	time::advance(ms(100)).await;
	check_interval_poll!(i, start);

	time::advance(ms(200)).await;
	check_interval_poll!(i, start, 300);

	time::advance(ms(650)).await;
	check_interval_poll!(i, start, 600);

	time::advance(ms(100)).await;
	check_interval_poll!(i, start);

	// We have to add one here for the same reason as is above.
	// Because `Interval` has reset its timer according to `Instant::now()`,
	// we have to go forward 1 more millisecond than is expected so that the
	// runtime realizes that it's time to resolve the timer.
	time::advance(ms(201)).await;
	// We add one because when using the `Delay` behavior, `Interval`
	// adds the `period` from `Instant::now()`, which will always be off by one
	// because we have to advance time by 1 (see above).
	check_interval_poll!(i, start, 1251);

	time::advance(ms(300)).await;
	// Again, we add one.
	check_interval_poll!(i, start, 1551);

	time::advance(ms(300)).await;
	check_interval_poll!(i, start, 1851);
	}

	// Expected ticks: \| 1 \| 2 \| 3 \| 4 \| 5 \| 6 \|
	// Actual ticks: \| work -----\| delay \| work ---\| work -----\| work -----\|
	// Poll behavior: \| \| \| \| \| \| \|
	// \| \| \| \| \| \| \|
	// Ready(s) \| \| Ready(s + 2p) \| \| \|
	// Pending \| Ready(s + 4p) \| \|
	// Ready(s + p) Ready(s + 5p) \|
	// Ready(s + 6p)
	#[tokio::test(start_paused = true)]
	async fn skip() {
	let start = Instant::now();

	// This is necessary because the timer is only so granular, and in order for
	// all our ticks to resolve, the time needs to be 1ms ahead of what we
	// expect, so that the runtime will see that it is time to resolve the timer
	time::advance(ms(1)).await;

	let mut i = task::spawn(time::interval_at(start, ms(300)));
	i.set_missed_tick_behavior(MissedTickBehavior::Skip);

	check_interval_poll!(i, start, 0);

	time::advance(ms(100)).await;
	check_interval_poll!(i, start);

	time::advance(ms(200)).await;
	check_interval_poll!(i, start, 300);

	time::advance(ms(650)).await;
	check_interval_poll!(i, start, 600);

	time::advance(ms(250)).await;
	check_interval_poll!(i, start, 1200);

	time::advance(ms(300)).await;
	check_interval_poll!(i, start, 1500);

	time::advance(ms(300)).await;
	check_interval_poll!(i, start, 1800);
	}

	fn poll_next(interval: &mut task::Spawn<time::Interval>) -> Poll<Instant> {
	interval.enter(\|cx, mut interval\| interval.poll_tick(cx))
	}

	fn ms(n: u64) -> Duration {
	Duration::from_millis(n)
	}