//! examples/async_task2 #![no_main] #![no_std] #![feature(const_fn)] #![feature(type_alias_impl_trait)] // use core::cell::Cell; // use core::cell::UnsafeCell; use core::future::Future; use core::mem; // use core::mem::MaybeUninit; use core::pin::Pin; // use core::ptr; // use core::ptr::NonNull; // use core::sync::atomic::{AtomicPtr, AtomicU32, Ordering}; use core::task::{Context, Poll, RawWaker, RawWakerVTable, Waker}; use cortex_m_semihosting::{debug, hprintln}; use panic_semihosting as _; #[rtic::app(device = lm3s6965, dispatchers = [SSI0], peripherals = true)] mod app { use crate::Timer; use crate::*; #[resources] struct Resources { syst: cortex_m::peripheral::SYST, } #[init] fn init(cx: init::Context) -> init::LateResources { hprintln!("init").unwrap(); foo::spawn().unwrap(); init::LateResources { syst: cx.core.SYST } } #[idle] fn idle(_: idle::Context) -> ! { // debug::exit(debug::EXIT_SUCCESS); loop { hprintln!("idle"); cortex_m::asm::wfi(); // put the MCU in sleep mode until interrupt occurs } } #[task(resources = [syst])] fn foo(mut cx: foo::Context) { // BEGIN BOILERPLATE type F = impl Future + 'static; fn create(cx: foo::Context<'static>) -> F { task(cx) } static mut TASK: Task = Task::new(); hprintln!("foo trampoline").ok(); unsafe { match TASK { Task::Idle | Task::Done(_) => { hprintln!("foo spawn task").ok(); TASK.spawn(|| create(mem::transmute(cx))); } _ => {} }; hprintln!("foo trampoline poll").ok(); TASK.poll(|| {}); match TASK { Task::Done(ref r) => { hprintln!("foo trampoline done").ok(); // hprintln!("r = {:?}", mem::transmute::<_, &u32>(r)).ok(); } _ => { hprintln!("foo trampoline running").ok(); } } } // END BOILERPLATE async fn task(mut cx: foo::Context<'static>) { hprintln!("foo task").ok(); hprintln!("delay long time").ok(); let fut = cx.resources.syst.lock(|syst| timer_delay(syst, 5000000)); hprintln!("we have just created the future"); fut.await; // this calls poll on the timer future hprintln!("foo task resumed").ok(); hprintln!("delay short time").ok(); cx.resources .syst .lock(|syst| timer_delay(syst, 1000000)) .await; hprintln!("foo task resumed").ok(); } } // #[task(resources = [syst])] // fn timer(cx: timer::Context<'static>) { // // BEGIN BOILERPLATE // type F = impl Future + 'static; // fn create(cx: timer::Context<'static>) -> F { // task(cx) // } // static mut TASK: Task = Task::new(); // hprintln!("timer trampoline").ok(); // unsafe { // match TASK { // Task::Idle | Task::Done(_) => { // hprintln!("create task").ok(); // TASK.spawn(|| create(mem::transmute(cx))); // } // _ => {} // }; // hprintln!("timer poll").ok(); // TASK.poll(|| {}); // match TASK { // Task::Done(_) => { // hprintln!("timer done").ok(); // } // _ => { // hprintln!("running").ok(); // } // } // } // // END BOILERPLATE // // for now assume this async task is done directly // async fn task(mut cx: timer::Context<'static>) { // hprintln!("SysTick").ok(); // Timer::delay(100000).await; // // cx.resources.waker.lock(|w| *w = Some()) // } // } // This the actual RTIC task, binds to systic. #[task(binds = SysTick, resources = [syst], priority = 2)] fn systic(mut cx: systic::Context) { hprintln!("systic interrupt").ok(); cx.resources.syst.lock(|syst| syst.disable_interrupt()); crate::app::foo::spawn(); // this should be from a Queue later } } //============= // Waker static WAKER_VTABLE: RawWakerVTable = RawWakerVTable::new(waker_clone, waker_wake, waker_wake, waker_drop); unsafe fn waker_clone(p: *const ()) -> RawWaker { RawWaker::new(p, &WAKER_VTABLE) } unsafe fn waker_wake(p: *const ()) { let f: fn() = mem::transmute(p); f(); } unsafe fn waker_drop(_: *const ()) { // nop } //============ // Task enum Task { Idle, Running(F), Done(F::Output), } impl Task { const fn new() -> Self { Self::Idle } fn spawn(&mut self, future: impl FnOnce() -> F) { *self = Task::Running(future()); } unsafe fn poll(&mut self, wake: fn()) { match self { Task::Idle => {} Task::Running(future) => { let future = Pin::new_unchecked(future); let waker_data: *const () = mem::transmute(wake); let waker = Waker::from_raw(RawWaker::new(waker_data, &WAKER_VTABLE)); let mut cx = Context::from_waker(&waker); match future.poll(&mut cx) { Poll::Ready(r) => *self = Task::Done(r), Poll::Pending => {} }; } Task::Done(_) => {} } } } //============= // Timer // Later we want a proper queue use heapless; pub struct Timer { pub done: bool, // pub waker_task: Option Result<(), ()>>, } impl Future for Timer { type Output = (); fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { if self.done { Poll::Ready(()) } else { hprintln!("timer polled"); cx.waker().wake_by_ref(); hprintln!("after wake_by_ref"); self.done = true; Poll::Pending } } } fn timer_delay(syst: &mut cortex_m::peripheral::SYST, t: u32) -> Timer { hprintln!("timer_delay {}", t); syst.set_reload(t); syst.enable_counter(); syst.enable_interrupt(); Timer { done: false, // waker_task: Some(app::foo::spawn), // we should add waker field to async task context i RTIC } }