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PoC Monotonic impl based on stm32-metapac
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@ -7,6 +7,10 @@ For each category, *Added*, *Changed*, *Fixed* add new entries at the top!
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## Unreleased
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### Added
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- STM32 support.
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## v1.1.0 - 2023-08-29
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### Added
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@ -9,6 +9,7 @@ authors = [
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"Henrik Tjäder <henrik@tjaders.com>",
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"Jorge Aparicio <jorge@japaric.io>",
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"Per Lindgren <per.lindgren@ltu.se>",
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"Andres Vahter <andres@vahter.me>",
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]
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categories = ["concurrency", "embedded", "no-std", "asynchronous"]
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description = "A library that provides implementations of the Monotonic trait from rtic-time"
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@ -40,6 +41,9 @@ nrf5340-app-pac = { version = "0.12.2", optional = true }
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nrf5340-net-pac = { version = "0.12.2", optional = true }
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nrf9160-pac = { version = "0.12.2", optional = true }
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# STM32
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stm32-metapac = { version = "13.0.0", features = ["metadata"], optional = true }
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[features]
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default = []
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defmt = ["fugit/defmt"]
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@ -63,3 +67,6 @@ nrf52840 = ["dep:cortex-m", "dep:nrf52840-pac", "dep:critical-section"]
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nrf5340-app = ["dep:cortex-m", "dep:nrf5340-app-pac", "dep:critical-section"]
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nrf5340-net = ["dep:cortex-m", "dep:nrf5340-net-pac", "dep:critical-section"]
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nrf9160 = ["dep:cortex-m", "dep:nrf9160-pac", "dep:critical-section"]
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# STM32 timers
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stm32g081kb = ["dep:cortex-m", "stm32-metapac/stm32g081kb"]
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@ -46,6 +46,9 @@ pub mod rp2040;
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))]
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pub mod nrf;
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#[cfg(any(feature = "stm32g081kb",))]
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pub mod stm32;
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#[allow(dead_code)]
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pub(crate) const fn cortex_logical2hw(logical: u8, nvic_prio_bits: u8) -> u8 {
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((1 << nvic_prio_bits) - logical) << (8 - nvic_prio_bits)
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@ -61,6 +64,7 @@ pub(crate) const fn cortex_logical2hw(logical: u8, nvic_prio_bits: u8) -> u8 {
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feature = "nrf5340-app",
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feature = "nrf5340-net",
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feature = "nrf9160",
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feature = "stm32g081kb",
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))]
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pub(crate) unsafe fn set_monotonic_prio(
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prio_bits: u8,
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249
rtic-monotonics/src/stm32.rs
Normal file
249
rtic-monotonics/src/stm32.rs
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@ -0,0 +1,249 @@
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//! [`Monotonic`] impl for the STM32.
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//!
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//! Not all timers are available on all parts. Ensure that only available
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//! timers are exposed by having the correct `stm32*` feature enabled for `rtic-monotonic`.
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//!
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//! # Example
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//!
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//! ```
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//! use rtic_monotonics::stm32::*;
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//! use rtic_monotonics::stm32::Tim2 as Mono;
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//! use rtic_monotonics::Monotonic;
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//! use embassy_stm32::peripherals::TIM2;
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//! use embassy_stm32::rcc::low_level::RccPeripheral;
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//!
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//! fn init() {
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//! // Generate timer token to ensure correct timer interrupt handler is used.
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//! let token = rtic_monotonics::create_stm32_tim2_monotonic_token!();
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//!
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//! // If using `embassy-stm32` HAL, timer clock can be read out like this:
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//! let timer_clock_hz = TIM2::frequency();
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//! // Or define it manually if you are using other HAL or know correct frequency:
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//! let timer_clock_hz = 64_000_000;
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//!
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//! // Start the monotonic
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//! Mono::start(timer_clock_hz, token);
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//! }
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//!
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//! async fn usage() {
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//! loop {
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//! // Use the monotonic
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//! let timestamp = Mono::now().ticks();
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//! Mono::delay(100.millis()).await;
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//! }
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//! }
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//! ```
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use crate::{Monotonic, TimeoutError, TimerQueue};
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use atomic_polyfill::{AtomicU64, Ordering};
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pub use fugit::{self, ExtU64};
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use pac::metadata::METADATA;
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use stm32_metapac as pac;
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const TIMER_HZ: u32 = 1_000_000;
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#[doc(hidden)]
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#[macro_export]
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macro_rules! __internal_create_stm32_timer_interrupt {
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($mono_timer:ident, $timer:ident, $timer_token:ident) => {{
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#[no_mangle]
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#[allow(non_snake_case)]
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unsafe extern "C" fn $timer() {
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$crate::stm32::$mono_timer::__tq().on_monotonic_interrupt();
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}
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pub struct $timer_token;
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unsafe impl $crate::InterruptToken<$crate::stm32::$mono_timer> for $timer_token {}
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$timer_token
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}};
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}
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/// Register TIM2 interrupt for the monotonic.
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#[macro_export]
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macro_rules! create_stm32_tim2_monotonic_token {
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() => {{
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$crate::__internal_create_stm32_timer_interrupt!(Tim2, TIM2, Tim2Token)
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}};
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}
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/// Register TIM3 interrupt for the monotonic.
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#[macro_export]
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macro_rules! create_stm32_tim3_monotonic_token {
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() => {{
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$crate::__internal_create_stm32_timer_interrupt!(Tim3, TIM3, Tim3Token)
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}};
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}
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macro_rules! make_timer {
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($mono_name:ident, $timer:ident, $bits:ident, $set_tim_en:ident, $set_tim_rst:ident, $overflow:ident, $tq:ident$(, doc: ($($doc:tt)*))?) => {
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/// Monotonic timer queue implementation.
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$(
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#[cfg_attr(docsrs, doc(cfg($($doc)*)))]
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)?
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pub struct $mono_name;
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use pac::$timer;
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static $overflow: AtomicU64 = AtomicU64::new(0);
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static $tq: TimerQueue<$mono_name> = TimerQueue::new();
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impl $mono_name {
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/// Start monotonic timer. Must be called only once.
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/// `tim_clock_hz` shows to which frequency `TIMx` clock source is configured.
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pub fn start(tim_clock_hz: u32, _interrupt_token: impl crate::InterruptToken<Self>) {
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pac::RCC.apbenr1().modify(|r| r.$set_tim_en(true));
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pac::RCC.apbrstr1().modify(|r| r.$set_tim_rst(true));
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pac::RCC.apbrstr1().modify(|r| r.$set_tim_rst(false));
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$timer.cr1().modify(|r| r.set_cen(false));
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let psc = tim_clock_hz / TIMER_HZ - 1;
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$timer.psc().write(|r| r.set_psc(psc as u16));
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// Enable update event interrupt.
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$timer.dier().modify(|r| r.set_uie(true));
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// Trigger an update event to load the prescaler value to the clock.
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$timer.egr().write(|r| r.set_ug(true));
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// The above line raises an update event which will indicate that the timer is already finished.
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// Since this is not the case, it should be cleared.
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$timer.sr().modify(|r| r.set_uif(false));
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// Start the counter.
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$timer.cr1().modify(|r| {
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r.set_cen(true);
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});
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$tq.initialize(Self {});
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// SAFETY: We take full ownership of the peripheral and interrupt vector,
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// plus we are not using any external shared resources so we won't impact
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// basepri/source masking based critical sections.
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unsafe {
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crate::set_monotonic_prio(METADATA.nvic_priority_bits.unwrap(), pac::Interrupt::$timer);
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cortex_m::peripheral::NVIC::unmask(pac::Interrupt::$timer);
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}
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}
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/// Used to access the underlying timer queue
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#[doc(hidden)]
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pub fn __tq() -> &'static TimerQueue<$mono_name> {
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&$tq
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}
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fn is_overflow() -> bool {
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$timer.sr().read().uif()
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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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$tq.delay(duration).await;
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}
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/// Timeout at a specific time.
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pub async fn timeout_at<F: core::future::Future>(
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instant: <Self as rtic_time::Monotonic>::Instant,
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future: F,
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) -> Result<F::Output, TimeoutError> {
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$tq.timeout_at(instant, future).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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$tq.timeout_after(duration, future).await
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}
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/// Delay to some specific time instant.
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#[inline]
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pub async fn delay_until(instant: <Self as Monotonic>::Instant) {
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$tq.delay_until(instant).await;
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}
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}
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impl Monotonic for $mono_name {
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type Instant = fugit::TimerInstantU64<TIMER_HZ>;
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type Duration = fugit::TimerDurationU64<TIMER_HZ>;
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const ZERO: Self::Instant = Self::Instant::from_ticks(0);
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fn now() -> Self::Instant {
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let cnt = $timer.cnt().read().cnt();
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// If the overflow bit is set, we add this to the timer value. It means the `on_interrupt`
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// has not yet happened, and we need to compensate here.
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let ovf: u64 = if Self::is_overflow() {
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$bits::MAX as u64 + 1
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} else {
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0
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};
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Self::Instant::from_ticks(cnt as u64 + ovf + $overflow.load(Ordering::SeqCst))
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}
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fn set_compare(instant: Self::Instant) {
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let now = Self::now();
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let max_ticks = $bits::MAX as u64;
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// Since the timer may or may not overflow based on the requested compare val, we check how many ticks are left.
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let val = match instant.checked_duration_since(now) {
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None => 0, // In the past
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Some(x) if x.ticks() <= max_ticks => instant.duration_since_epoch().ticks() as $bits, // Will not overflow
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Some(_x) => $timer.cnt().read().cnt().wrapping_add($bits::MAX - 1), // Will overflow
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};
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$timer.ccr(1).write(|r| r.set_ccr(val));
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}
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fn clear_compare_flag() {
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$timer.sr().modify(|r| r.set_ccif(1, false));
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}
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fn pend_interrupt() {
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cortex_m::peripheral::NVIC::pend(pac::Interrupt::$timer);
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}
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fn enable_timer() {
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$timer.dier().modify(|r| r.set_ccie(1, true));
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}
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fn disable_timer() {
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$timer.dier().modify(|r| r.set_ccie(1, false));
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}
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fn on_interrupt() {
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if Self::is_overflow() {
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$timer.sr().modify(|r| r.set_uif(false));
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$overflow.fetch_add($bits::MAX as u64 + 1, Ordering::SeqCst);
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}
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}
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}
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};
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}
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make_timer!(
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Tim2,
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TIM2,
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u32,
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set_tim2en,
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set_tim2rst,
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TIMER2_OVERFLOWS,
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TIMER2_TQ
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);
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make_timer!(
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Tim3,
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TIM3,
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u16,
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set_tim3en,
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set_tim3rst,
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TIMER3_OVERFLOWS,
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TIMER3_TQ
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);
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