mirror of
https://github.com/rtic-rs/rtic.git
synced 2024-11-27 22:15:07 +01:00
314 lines
9.4 KiB
Rust
314 lines
9.4 KiB
Rust
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//! A test that verifies the sub-tick correctness of the [`TimerQueue`]'s `delay` functionality.
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//!
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//! To run this test, you need to activate the `critical-section/std` feature.
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use std::{
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fmt::Debug,
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future::Future,
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pin::Pin,
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sync::{
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atomic::{AtomicBool, AtomicU64, AtomicUsize, Ordering},
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Arc,
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},
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task::Context,
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thread::sleep,
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time::Duration,
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};
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use ::fugit::ExtU64Ceil;
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use cooked_waker::{IntoWaker, WakeRef};
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use parking_lot::Mutex;
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use rtic_time::{Monotonic, TimeoutError, TimerQueue};
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const SUBTICKS_PER_TICK: u32 = 10;
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struct SubtickTestTimer;
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static TIMER_QUEUE: TimerQueue<SubtickTestTimer> = TimerQueue::new();
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static NOW_SUBTICKS: AtomicU64 = AtomicU64::new(0);
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static COMPARE_TICKS: Mutex<Option<u64>> = Mutex::new(None);
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impl Monotonic for SubtickTestTimer {
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const ZERO: Self::Instant = Self::Instant::from_ticks(0);
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const TICK_PERIOD: Self::Duration = Self::Duration::from_ticks(1);
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type Instant = fugit::Instant<u64, SUBTICKS_PER_TICK, 1000>;
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type Duration = fugit::Duration<u64, SUBTICKS_PER_TICK, 1000>;
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fn now() -> Self::Instant {
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Self::Instant::from_ticks(
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NOW_SUBTICKS.load(Ordering::Relaxed) / u64::from(SUBTICKS_PER_TICK),
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)
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}
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fn set_compare(instant: Self::Instant) {
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*COMPARE_TICKS.lock() = Some(instant.ticks());
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}
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fn clear_compare_flag() {}
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fn pend_interrupt() {
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unsafe {
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Self::__tq().on_monotonic_interrupt();
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}
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}
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}
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impl SubtickTestTimer {
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pub fn init() {
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Self::__tq().initialize(Self)
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}
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pub fn tick() -> u64 {
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let now = NOW_SUBTICKS.fetch_add(1, Ordering::Relaxed) + 1;
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let ticks = now / u64::from(SUBTICKS_PER_TICK);
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let subticks = now % u64::from(SUBTICKS_PER_TICK);
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let compare = COMPARE_TICKS.lock();
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// println!(
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// "ticks: {ticks}, subticks: {subticks}, compare: {:?}",
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// *compare
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// );
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if subticks == 0 && Some(ticks) == *compare {
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unsafe {
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Self::__tq().on_monotonic_interrupt();
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}
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}
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subticks
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}
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pub fn forward_to_subtick(subtick: u64) {
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assert!(subtick < u64::from(SUBTICKS_PER_TICK));
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while Self::tick() != subtick {}
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}
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pub fn now_subticks() -> u64 {
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NOW_SUBTICKS.load(Ordering::Relaxed)
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}
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fn __tq() -> &'static TimerQueue<Self> {
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&TIMER_QUEUE
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}
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/// Delay for some duration of time.
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#[inline]
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pub async fn delay(duration: <Self as Monotonic>::Duration) {
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Self::__tq().delay(duration).await;
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}
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/// Timeout after a specific duration.
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#[inline]
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pub async fn timeout_after<F: core::future::Future>(
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duration: <Self as Monotonic>::Duration,
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future: F,
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) -> Result<F::Output, TimeoutError> {
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Self::__tq().timeout_after(duration, future).await
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}
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}
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rtic_time::embedded_hal_delay_impl_fugit64!(SubtickTestTimer);
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rtic_time::embedded_hal_async_delay_impl_fugit64!(SubtickTestTimer);
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// A simple struct that counts the number of times it is awoken. Can't
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// be awoken by value (because that would discard the counter), so we
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// must instead wrap it in an Arc.
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#[derive(Debug, Default)]
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struct WakeCounter {
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count: AtomicUsize,
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}
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impl WakeCounter {
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fn get(&self) -> usize {
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self.count.load(Ordering::SeqCst)
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}
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}
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impl WakeRef for WakeCounter {
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fn wake_by_ref(&self) {
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let _prev = self.count.fetch_add(1, Ordering::SeqCst);
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}
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}
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struct OnDrop<F: FnOnce()>(Option<F>);
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impl<F: FnOnce()> OnDrop<F> {
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pub fn new(f: F) -> Self {
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Self(Some(f))
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}
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}
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impl<F: FnOnce()> Drop for OnDrop<F> {
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fn drop(&mut self) {
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(self.0.take().unwrap())();
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}
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}
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macro_rules! subtick_test {
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(@run $start:expr, $actual_duration:expr, $delay_fn:expr) => {{
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// forward clock to $start
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SubtickTestTimer::forward_to_subtick($start);
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// call wait function
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let delay_fn = $delay_fn;
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let mut future = std::pin::pin!(delay_fn);
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let wakecounter = Arc::new(WakeCounter::default());
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let waker = Arc::clone(&wakecounter).into_waker();
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let mut context = Context::from_waker(&waker);
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let mut finished_after: Option<u64> = None;
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for i in 0..10 * u64::from(SUBTICKS_PER_TICK) {
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if Future::poll(Pin::new(&mut future), &mut context).is_ready() {
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if finished_after.is_none() {
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finished_after = Some(i);
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}
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break;
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};
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assert_eq!(wakecounter.get(), 0);
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SubtickTestTimer::tick();
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}
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let expected_wakeups = {
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if $actual_duration == 0 {
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0
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} else {
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1
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}
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};
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assert_eq!(wakecounter.get(), expected_wakeups);
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// Tick again to test that we don't get a second wake
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SubtickTestTimer::tick();
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assert_eq!(wakecounter.get(), expected_wakeups);
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assert_eq!(
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Some($actual_duration),
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finished_after,
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"Expected to wait {} ticks, but waited {:?} ticks.",
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$actual_duration,
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finished_after,
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);
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}};
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(@run_blocking $start:expr, $actual_duration:expr, $delay_fn:expr) => {{
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// forward clock to $start
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SubtickTestTimer::forward_to_subtick($start);
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let t_start = SubtickTestTimer::now_subticks();
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let finished = AtomicBool::new(false);
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std::thread::scope(|s|{
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s.spawn(||{
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let _finished_guard = OnDrop::new(|| finished.store(true, Ordering::Relaxed));
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($delay_fn)();
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});
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s.spawn(||{
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sleep(Duration::from_millis(10));
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while !finished.load(Ordering::Relaxed) {
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SubtickTestTimer::tick();
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sleep(Duration::from_millis(10));
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}
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});
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});
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let t_end = SubtickTestTimer::now_subticks();
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let measured_duration = t_end - t_start;
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assert_eq!(
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$actual_duration,
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measured_duration,
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"Expected to wait {} ticks, but waited {:?} ticks.",
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$actual_duration,
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measured_duration,
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);
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}};
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($start:expr, $min_duration:expr, $actual_duration:expr) => {{
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subtick_test!(@run $start, $actual_duration, async {
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let mut timer = SubtickTestTimer;
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embedded_hal_async::delay::DelayNs::delay_ms(&mut timer, $min_duration).await;
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});
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subtick_test!(@run $start, $actual_duration, async {
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let mut timer = SubtickTestTimer;
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embedded_hal_async::delay::DelayNs::delay_us(&mut timer, 1_000 * $min_duration).await;
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});
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subtick_test!(@run $start, $actual_duration, async {
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let mut timer = SubtickTestTimer;
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embedded_hal_async::delay::DelayNs::delay_ns(&mut timer, 1_000_000 * $min_duration).await;
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});
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subtick_test!(@run $start, $actual_duration, async {
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SubtickTestTimer::delay($min_duration.millis_at_least()).await;
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});
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subtick_test!(@run $start, $actual_duration, async {
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let _ = SubtickTestTimer::timeout_after($min_duration.millis_at_least(), std::future::pending::<()>()).await;
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});
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// Those are slow and unreliable; enable them when needed.
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const ENABLE_BLOCKING_TESTS: bool = false;
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if ENABLE_BLOCKING_TESTS {
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subtick_test!(@run_blocking $start, $actual_duration, || {
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let mut timer = SubtickTestTimer;
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embedded_hal::delay::DelayNs::delay_ms(&mut timer, $min_duration);
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});
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subtick_test!(@run_blocking $start, $actual_duration, || {
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let mut timer = SubtickTestTimer;
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embedded_hal::delay::DelayNs::delay_us(&mut timer, 1_000 * $min_duration);
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});
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subtick_test!(@run_blocking $start, $actual_duration, || {
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let mut timer = SubtickTestTimer;
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embedded_hal::delay::DelayNs::delay_ns(&mut timer, 1_000_000 * $min_duration);
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});
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}
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}};
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}
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#[test]
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fn timer_queue_subtick_precision() {
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SubtickTestTimer::init();
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// subtick_test!(a, b, c) tests the following thing:
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//
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// If we start at subtick a and we need to wait b subticks,
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// then we will actually wait c subticks.
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// The important part is that c is never smaller than b,
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// in all cases, as that would violate the contract of
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// embedded-hal's DelayUs.
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subtick_test!(0, 0, 0);
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subtick_test!(0, 1, 20);
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subtick_test!(0, 10, 20);
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subtick_test!(0, 11, 30);
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subtick_test!(0, 12, 30);
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subtick_test!(1, 0, 0);
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subtick_test!(1, 1, 19);
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subtick_test!(1, 10, 19);
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subtick_test!(1, 11, 29);
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subtick_test!(1, 12, 29);
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subtick_test!(2, 0, 0);
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subtick_test!(2, 1, 18);
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subtick_test!(2, 10, 18);
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subtick_test!(2, 11, 28);
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subtick_test!(2, 12, 28);
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subtick_test!(3, 0, 0);
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subtick_test!(3, 1, 17);
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subtick_test!(3, 10, 17);
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subtick_test!(3, 11, 27);
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subtick_test!(3, 12, 27);
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subtick_test!(8, 0, 0);
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subtick_test!(8, 1, 12);
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subtick_test!(8, 10, 12);
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subtick_test!(8, 11, 22);
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subtick_test!(8, 12, 22);
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subtick_test!(9, 0, 0);
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subtick_test!(9, 1, 11);
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subtick_test!(9, 10, 11);
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subtick_test!(9, 11, 21);
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subtick_test!(9, 12, 21);
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}
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