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Async examples working, manual codegen

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This commit is contained in:
Emil Fresk 2022-03-21 14:56:56 +01:00
parent b87fca3d21
commit e2e7948411
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287
examples/async.rs Normal file
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#![no_main]
#![no_std]
#![feature(type_alias_impl_trait)]
use core::future::Future;
use core::mem;
use core::pin::Pin;
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::*;
#[shared]
struct Shared {
syst: cortex_m::peripheral::SYST,
}
#[local]
struct Local {}
#[init]
fn init(cx: init::Context) -> (Shared, Local, init::Monotonics) {
hprintln!("init").unwrap();
foo::spawn().unwrap();
foo2::spawn().unwrap();
(Shared { syst: cx.core.SYST }, Local {}, init::Monotonics())
}
#[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
}
}
type F = impl Future + 'static;
static mut TASK: Task<F> = Task::new();
#[task(shared = [syst])]
fn foo(mut cx: foo::Context) {
// BEGIN BOILERPLATE
fn create(cx: foo::Context<'static>) -> F {
task(cx)
}
hprintln!("foo trampoline").ok();
unsafe {
match TASK {
Task::Idle | Task::Done(_) => {
hprintln!("foo spawn task").ok();
TASK.spawn(|| create(mem::transmute(cx)));
// Per:
// I think transmute could be removed as in:
// TASK.spawn(|| create(cx));
//
// This could be done if spawn for async tasks would be passed
// a 'static reference by the generated code.
//
// Soundness:
// Check if lifetime for async context is correct.
}
_ => {}
};
foo_poll::spawn();
}
// END BOILERPLATE
async fn task(mut cx: foo::Context<'static>) {
hprintln!("foo task").ok();
hprintln!("delay long time").ok();
let fut = cx.shared.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.shared.syst.lock(|syst| timer_delay(syst, 1000000)).await;
hprintln!("foo task resumed").ok();
debug::exit(debug::EXIT_SUCCESS);
}
}
#[task(shared = [syst])]
fn foo_poll(mut cx: foo_poll::Context) {
// BEGIN BOILERPLATE
hprintln!("foo poll trampoline").ok();
unsafe {
hprintln!("foo trampoline poll").ok();
TASK.poll(|| {
hprintln!("foo poll closure").ok();
});
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
}
type F2 = impl Future + 'static;
static mut TASK2: Task<F2> = Task::new();
#[task(shared = [syst])]
fn foo2(mut cx: foo2::Context) {
// BEGIN BOILERPLATE
fn create(cx: foo2::Context<'static>) -> F2 {
task(cx)
}
hprintln!("foo2 trampoline").ok();
unsafe {
match TASK2 {
Task::Idle | Task::Done(_) => {
hprintln!("foo2 spawn task").ok();
TASK2.spawn(|| create(mem::transmute(cx)));
// Per:
// I think transmute could be removed as in:
// TASK.spawn(|| create(cx));
//
// This could be done if spawn for async tasks would be passed
// a 'static reference by the generated code.
//
// Soundness:
// Check if lifetime for async context is correct.
}
_ => {}
};
foo2_poll::spawn();
}
// END BOILERPLATE
async fn task(mut cx: foo2::Context<'static>) {
hprintln!("foo2 task").ok();
hprintln!("foo2 delay long time").ok();
let fut = cx.shared.syst.lock(|syst| timer_delay(syst, 10_000_000));
hprintln!("we have just created the future");
fut.await; // this calls poll on the timer future
hprintln!("foo task resumed").ok();
}
}
#[task(shared = [syst])]
fn foo2_poll(mut cx: foo2_poll::Context) {
// BEGIN BOILERPLATE
hprintln!("foo2 poll trampoline").ok();
unsafe {
hprintln!("foo2 trampoline poll").ok();
TASK2.poll(|| {
hprintln!("foo2 poll closure").ok();
});
match TASK2 {
Task::Done(ref r) => {
hprintln!("foo2 trampoline done").ok();
// hprintln!("r = {:?}", mem::transmute::<_, &u32>(r)).ok();
}
_ => {
hprintln!("foo2 trampoline running").ok();
}
}
}
// END BOILERPLATE
}
// This the actual RTIC task, binds to systic.
#[task(binds = SysTick, shared = [syst], priority = 2)]
fn systic(mut cx: systic::Context) {
hprintln!("systic interrupt").ok();
cx.shared.syst.lock(|syst| syst.disable_interrupt());
crate::app::foo_poll::spawn(); // this should be from a Queue later
crate::app::foo2_poll::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<F: Future + 'static> {
Idle,
Running(F),
Done(F::Output),
}
impl<F: Future + 'static> Task<F> {
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<fn() -> Result<(), ()>>,
}
impl Future for Timer {
type Output = ();
fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
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
}
}

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#![no_main]
#![no_std]
#![feature(type_alias_impl_trait)]
use core::future::Future;
use core::mem;
use core::pin::Pin;
use core::task::{Context, Poll, RawWaker, RawWakerVTable, Waker};
use cortex_m_semihosting::{debug, hprintln};
use panic_semihosting as _;
use systick_monotonic::*;
// NOTES:
//
// - Async tasks cannot have `#[lock_free]` resources, as they can interleve and each async
// task can have a mutable reference stored.
// - Spawning an async task equates to it being polled at least once.
// - ...
#[rtic::app(device = lm3s6965, dispatchers = [SSI0], peripherals = true)]
mod app {
use crate::*;
pub type AppInstant = <Systick<100> as rtic::Monotonic>::Instant;
pub type AppDuration = <Systick<100> as rtic::Monotonic>::Duration;
#[shared]
struct Shared {
s: u32,
}
#[local]
struct Local {}
#[monotonic(binds = SysTick, default = true)]
type MyMono = Systick<100>;
#[init]
fn init(cx: init::Context) -> (Shared, Local, init::Monotonics) {
hprintln!("init").unwrap();
task_executor::spawn().unwrap();
(
Shared { s: 0 },
Local {},
init::Monotonics(Systick::new(cx.core.SYST, 12_000_000)),
)
}
#[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
}
}
// TODO: This should be the task, that is understood by the `syntax` proc-macro
// #[task(priority = 2)]
async fn task(cx: task_executor::Context<'_>) {
#[allow(unused_imports)]
use rtic::mutex_prelude::*;
hprintln!("delay long time").ok();
let fut = Delay::spawn(2500.millis());
hprintln!("we have just created the future").ok();
fut.await;
hprintln!("long delay done").ok();
hprintln!("delay short time").ok();
sleep(500.millis()).await;
hprintln!("short delay done").ok();
hprintln!("test timeout").ok();
let res = timeout(NeverEndingFuture {}, 1.secs()).await;
hprintln!("timeout done: {:?}", res).ok();
hprintln!("test timeout 2").ok();
let res = timeout(Delay::spawn(500.millis()), 1.secs()).await;
hprintln!("timeout done 2: {:?}", res).ok();
debug::exit(debug::EXIT_SUCCESS);
}
//////////////////////////////////////////////
// BEGIN BOILERPLATE
//////////////////////////////////////////////
type F = impl Future + 'static;
static mut TASK: AsyncTaskExecutor<F> = AsyncTaskExecutor::new();
// TODO: This should be a special case codegen for the `dispatcher`, which runs
// in the dispatcher. Not as its own task, this is just to make it work
// in this example.
#[task(shared = [s])]
fn task_executor(cx: task_executor::Context) {
let task_storage = unsafe { &mut TASK };
match task_storage {
AsyncTaskExecutor::Idle => {
// TODO: The context generated for async tasks need 'static lifetime,
// use `mem::transmute` for now until codegen is fixed
//
// TODO: Check if there is some way to not need 'static lifetime
hprintln!(" task_executor spawn").ok();
task_storage.spawn(|| task(unsafe { mem::transmute(cx) }));
task_executor::spawn().ok();
}
_ => {
hprintln!(" task_executor run").ok();
task_storage.poll(|| {
task_executor::spawn().ok();
});
}
};
}
//////////////////////////////////////////////
// END BOILERPLATE
//////////////////////////////////////////////
// TODO: This is generated by the `delay` impl, it needs a capacity equal or grater
// than the number of async tasks in the system. Should more likely be a part
// of the monotonic codegen, not its own task.
#[task(capacity = 12)]
fn delay_handler(_: delay_handler::Context, waker: Waker) {
waker.wake();
}
}
//=============
// 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 ()) {
// The only thing we need from a waker is the function to call to pend the async
// dispatcher.
let f: fn() = mem::transmute(p);
f();
}
unsafe fn waker_drop(_: *const ()) {
// nop
}
//============
// AsyncTaskExecutor
enum AsyncTaskExecutor<F: Future + 'static> {
Idle,
Running(F),
}
impl<F: Future + 'static> AsyncTaskExecutor<F> {
const fn new() -> Self {
Self::Idle
}
fn spawn(&mut self, future: impl FnOnce() -> F) {
*self = AsyncTaskExecutor::Running(future());
}
fn poll(&mut self, wake: fn()) {
match self {
AsyncTaskExecutor::Idle => {}
AsyncTaskExecutor::Running(future) => unsafe {
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);
let future = Pin::new_unchecked(future);
match future.poll(&mut cx) {
Poll::Ready(_) => {
*self = AsyncTaskExecutor::Idle;
hprintln!(" task_executor idle").ok();
}
Poll::Pending => {}
};
},
}
}
}
//=============
// Delay
pub struct Delay {
until: crate::app::AppInstant,
}
impl Delay {
pub fn spawn(duration: crate::app::AppDuration) -> Self {
let until = crate::app::monotonics::now() + duration;
Delay { until }
}
}
#[inline(always)]
pub fn sleep(duration: crate::app::AppDuration) -> Delay {
Delay::spawn(duration)
}
impl Future for Delay {
type Output = ();
fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
let s = self.as_mut();
let now = crate::app::monotonics::now();
hprintln!(" poll Delay").ok();
if now >= s.until {
Poll::Ready(())
} else {
let waker = cx.waker().clone();
crate::app::delay_handler::spawn_after(s.until - now, waker).ok();
Poll::Pending
}
}
}
//=============
// Timeout future
#[derive(Copy, Clone, Debug)]
pub struct TimeoutError;
pub struct Timeout<F: Future> {
future: F,
until: crate::app::AppInstant,
cancel_handle: Option<crate::app::delay_handler::SpawnHandle>,
}
impl<F> Timeout<F>
where
F: Future,
{
pub fn timeout(future: F, duration: crate::app::AppDuration) -> Self {
let until = crate::app::monotonics::now() + duration;
Self {
future,
until,
cancel_handle: None,
}
}
}
#[inline(always)]
pub fn timeout<F: Future>(future: F, duration: crate::app::AppDuration) -> Timeout<F> {
Timeout::timeout(future, duration)
}
impl<F> Future for Timeout<F>
where
F: Future,
{
type Output = Result<F::Output, TimeoutError>;
fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
let now = crate::app::monotonics::now();
// SAFETY: We don't move the underlying pinned value.
let mut s = unsafe { self.get_unchecked_mut() };
let future = unsafe { Pin::new_unchecked(&mut s.future) };
hprintln!(" poll Timeout").ok();
match future.poll(cx) {
Poll::Ready(r) => {
if let Some(ch) = s.cancel_handle.take() {
ch.cancel().ok();
}
Poll::Ready(Ok(r))
}
Poll::Pending => {
if now >= s.until {
Poll::Ready(Err(TimeoutError))
} else if s.cancel_handle.is_none() {
let waker = cx.waker().clone();
let sh = crate::app::delay_handler::spawn_after(s.until - now, waker)
.expect("Internal RTIC bug, this should never fail");
s.cancel_handle = Some(sh);
Poll::Pending
} else {
Poll::Pending
}
}
}
}
}
pub struct NeverEndingFuture {}
impl Future for NeverEndingFuture {
type Output = ();
fn poll(self: Pin<&mut Self>, _: &mut Context<'_>) -> Poll<Self::Output> {
// Never finish
hprintln!(" polling NeverEndingFuture").ok();
Poll::Pending
}
}
//=============
// Async SPI driver
// #[task]
async fn test_spi(async_spi_driver: &mut AsyncSpi) {
let transfer = Transaction {
buf: [0; 16],
n_write: 1,
n_read: 5,
};
let ret = async_spi_driver.transfer(transfer).await;
// do_something(ret);
}
/// A DMA transaction.
///
/// NOTE: Don't leak this `Future`, if you do there is immediate UB!
struct Transaction {
pub buf: [u8; 16],
pub n_write: usize,
pub n_read: usize,
}
struct AsyncSpi {
transaction: Option<Transaction>,
queue: heapless::spsc::Queue<Waker, 8>,
}
impl AsyncSpi {
pub fn transfer(&mut self, transfer: Transaction) -> AsyncSpiTransaction {
todo!()
}
}
struct AsyncSpiTransaction {
// ...
}
impl Future for AsyncSpiTransaction {
type Output = ();
fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
todo!()
}
}