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Fixes in MPSC linked list and dropper handling

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Emil Fresk 2023-01-26 21:29:52 +01:00 committed by Henrik Tjäder
parent 2e96229c91
commit 51d4eccc72
4 changed files with 673 additions and 1 deletions
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15
rtic-channel/Cargo.toml Normal file
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[package]
name = "rtic-channel"
version = "1.0.0"
edition = "2021"
# See more keys and their definitions at https://doc.rust-lang.org/cargo/reference/manifest.html
[dependencies]
heapless = "0.7"
critical-section = "1"
[features]
default = []
testing = ["critical-section/std"]

380
rtic-channel/src/lib.rs Normal file
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//! Crate
#![no_std]
#![deny(missing_docs)]
use core::{
cell::UnsafeCell,
future::poll_fn,
mem::MaybeUninit,
ptr,
task::{Poll, Waker},
};
use heapless::Deque;
use wait_queue::WaitQueue;
use waker_registration::CriticalSectionWakerRegistration as WakerRegistration;
mod wait_queue;
mod waker_registration;
/// An MPSC channel for use in no-alloc systems. `N` sets the size of the queue.
///
/// This channel uses critical sections, however there are extremely small and all `memcpy`
/// operations of `T` are done without critical sections.
pub struct Channel<T, const N: usize> {
// Here are all indexes that are not used in `slots` and ready to be allocated.
freeq: UnsafeCell<Deque<u8, N>>,
// Here are wakers and indexes to slots that are ready to be dequeued by the receiver.
readyq: UnsafeCell<Deque<u8, N>>,
// Waker for the receiver.
receiver_waker: WakerRegistration,
// Storage for N `T`s, so we don't memcpy around a lot of `T`s.
slots: [UnsafeCell<MaybeUninit<T>>; N],
// If there is no room in the queue a `Sender`s can wait for there to be place in the queue.
wait_queue: WaitQueue,
// Keep track of the receiver.
receiver_dropped: UnsafeCell<bool>,
// Keep track of the number of senders.
num_senders: UnsafeCell<usize>,
}
struct UnsafeAccess<'a, const N: usize> {
freeq: &'a mut Deque<u8, N>,
readyq: &'a mut Deque<u8, N>,
receiver_dropped: &'a mut bool,
num_senders: &'a mut usize,
}
impl<T, const N: usize> Channel<T, N> {
const _CHECK: () = assert!(N < 256, "This queue support a maximum of 255 entries");
const INIT_SLOTS: UnsafeCell<MaybeUninit<T>> = UnsafeCell::new(MaybeUninit::uninit());
/// Create a new channel.
pub const fn new() -> Self {
Self {
freeq: UnsafeCell::new(Deque::new()),
readyq: UnsafeCell::new(Deque::new()),
receiver_waker: WakerRegistration::new(),
slots: [Self::INIT_SLOTS; N],
wait_queue: WaitQueue::new(),
receiver_dropped: UnsafeCell::new(false),
num_senders: UnsafeCell::new(0),
}
}
/// Split the queue into a `Sender`/`Receiver` pair.
pub fn split<'a>(&'a mut self) -> (Sender<'a, T, N>, Receiver<'a, T, N>) {
// Fill free queue
for idx in 0..(N - 1) as u8 {
debug_assert!(!self.freeq.get_mut().is_full());
// SAFETY: This safe as the loop goes from 0 to the capacity of the underlying queue.
unsafe {
self.freeq.get_mut().push_back_unchecked(idx);
}
}
debug_assert!(self.freeq.get_mut().is_full());
// There is now 1 sender
*self.num_senders.get_mut() = 1;
(Sender(self), Receiver(self))
}
fn access<'a>(&'a self, _cs: critical_section::CriticalSection) -> UnsafeAccess<'a, N> {
// SAFETY: This is safe as are in a critical section.
unsafe {
UnsafeAccess {
freeq: &mut *self.freeq.get(),
readyq: &mut *self.readyq.get(),
receiver_dropped: &mut *self.receiver_dropped.get(),
num_senders: &mut *self.num_senders.get(),
}
}
}
}
/// Creates a split channel with `'static` lifetime.
#[macro_export]
macro_rules! make_channel {
($type:path, $size:expr) => {{
static mut CHANNEL: Channel<$type, $size> = Channel::new();
// SAFETY: This is safe as we hide the static mut from others to access it.
// Only this point is where the mutable access happens.
unsafe { CHANNEL.split() }
}};
}
// -------- Sender
/// Error state for when the receiver has been dropped.
pub struct NoReceiver<T>(pub T);
/// A `Sender` can send to the channel and can be cloned.
pub struct Sender<'a, T, const N: usize>(&'a Channel<T, N>);
unsafe impl<'a, T, const N: usize> Send for Sender<'a, T, N> {}
impl<'a, T, const N: usize> Sender<'a, T, N> {
#[inline(always)]
fn send_footer(&mut self, idx: u8, val: T) {
// Write the value to the slots, note; this memcpy is not under a critical section.
unsafe {
ptr::write(
self.0.slots.get_unchecked(idx as usize).get() as *mut T,
val,
)
}
// Write the value into the ready queue.
critical_section::with(|cs| unsafe { self.0.access(cs).readyq.push_back_unchecked(idx) });
// If there is a receiver waker, wake it.
self.0.receiver_waker.wake();
}
/// Try to send a value, non-blocking. If the channel is full this will return an error.
/// Note; this does not check if the channel is closed.
pub fn try_send(&mut self, val: T) -> Result<(), T> {
// If the wait queue is not empty, we can't try to push into the queue.
if !self.0.wait_queue.is_empty() {
return Err(val);
}
let idx =
if let Some(idx) = critical_section::with(|cs| self.0.access(cs).freeq.pop_front()) {
idx
} else {
return Err(val);
};
self.send_footer(idx, val);
Ok(())
}
/// Send a value. If there is no place left in the queue this will wait until there is.
/// If the receiver does not exist this will return an error.
pub async fn send(&mut self, val: T) -> Result<(), NoReceiver<T>> {
if self.is_closed() {}
let mut __hidden_link: Option<wait_queue::Link<Waker>> = None;
// Make this future `Drop`-safe
let link_ptr = &mut __hidden_link as *mut Option<wait_queue::Link<Waker>>;
let dropper = OnDrop::new(|| {
// SAFETY: We only run this closure and dereference the pointer if we have
// exited the `poll_fn` below in the `drop(dropper)` call. The other dereference
// of this pointer is in the `poll_fn`.
if let Some(link) = unsafe { &mut *link_ptr } {
link.remove_from_list(&self.0.wait_queue);
}
});
let idx = poll_fn(|cx| {
if self.is_closed() {
return Poll::Ready(Err(()));
}
// Do all this in one critical section, else there can be race conditions
let queue_idx = critical_section::with(|cs| {
if !self.0.wait_queue.is_empty() || self.0.access(cs).freeq.is_empty() {
// SAFETY: This pointer is only dereferenced here and on drop of the future.
let link = unsafe { &mut *link_ptr };
if link.is_none() {
// Place the link in the wait queue on first run.
let link_ref = link.insert(wait_queue::Link::new(cx.waker().clone()));
self.0.wait_queue.push(link_ref);
}
return None;
}
// Get index as the queue is guaranteed not empty and the wait queue is empty
let idx = unsafe { self.0.access(cs).freeq.pop_front_unchecked() };
Some(idx)
});
if let Some(idx) = queue_idx {
// Return the index
Poll::Ready(Ok(idx))
} else {
return Poll::Pending;
}
})
.await;
// Make sure the link is removed from the queue.
drop(dropper);
if let Ok(idx) = idx {
self.send_footer(idx, val);
Ok(())
} else {
Err(NoReceiver(val))
}
}
/// Returns true if there is no `Receiver`s.
pub fn is_closed(&self) -> bool {
critical_section::with(|cs| *self.0.access(cs).receiver_dropped)
}
/// Is the queue full.
pub fn is_full(&self) -> bool {
critical_section::with(|cs| self.0.access(cs).freeq.is_empty())
}
/// Is the queue empty.
pub fn is_empty(&self) -> bool {
critical_section::with(|cs| self.0.access(cs).freeq.is_full())
}
}
impl<'a, T, const N: usize> Drop for Sender<'a, T, N> {
fn drop(&mut self) {
// Count down the reference counter
let num_senders = critical_section::with(|cs| {
*self.0.access(cs).num_senders -= 1;
*self.0.access(cs).num_senders
});
// If there are no senders, wake the receiver to do error handling.
if num_senders == 0 {
self.0.receiver_waker.wake();
}
}
}
impl<'a, T, const N: usize> Clone for Sender<'a, T, N> {
fn clone(&self) -> Self {
// Count up the reference counter
critical_section::with(|cs| *self.0.access(cs).num_senders += 1);
Self(self.0)
}
}
// -------- Receiver
/// A receiver of the channel. There can only be one receiver at any time.
pub struct Receiver<'a, T, const N: usize>(&'a Channel<T, N>);
/// Error state for when all senders has been dropped.
pub struct NoSender;
impl<'a, T, const N: usize> Receiver<'a, T, N> {
/// Receives a value if there is one in the channel, non-blocking.
/// Note; this does not check if the channel is closed.
pub fn try_recv(&mut self) -> Option<T> {
// Try to get a ready slot.
let ready_slot =
critical_section::with(|cs| self.0.access(cs).readyq.pop_front().map(|rs| rs));
if let Some(rs) = ready_slot {
// Read the value from the slots, note; this memcpy is not under a critical section.
let r = unsafe { ptr::read(self.0.slots.get_unchecked(rs as usize).get() as *const T) };
// Return the index to the free queue after we've read the value.
critical_section::with(|cs| unsafe { self.0.access(cs).freeq.push_back_unchecked(rs) });
// If someone is waiting in the WaiterQueue, wake the first one up.
if let Some(wait_head) = self.0.wait_queue.pop() {
wait_head.wake();
}
Some(r)
} else {
None
}
}
/// Receives a value, waiting if the queue is empty.
/// If all senders are dropped this will error with `NoSender`.
pub async fn recv(&mut self) -> Result<T, NoSender> {
// There was nothing in the queue, setup the waiting.
poll_fn(|cx| {
// Register waker.
// TODO: Should it happen here or after the if? This might cause a spurious wake.
self.0.receiver_waker.register(cx.waker());
// Try to dequeue.
if let Some(val) = self.try_recv() {
return Poll::Ready(Ok(val));
}
// If the queue is empty and there is no sender, return the error.
if self.is_closed() {
return Poll::Ready(Err(NoSender));
}
Poll::Pending
})
.await
}
/// Returns true if there are no `Sender`s.
pub fn is_closed(&self) -> bool {
critical_section::with(|cs| *self.0.access(cs).num_senders == 0)
}
/// Is the queue full.
pub fn is_full(&self) -> bool {
critical_section::with(|cs| self.0.access(cs).readyq.is_empty())
}
/// Is the queue empty.
pub fn is_empty(&self) -> bool {
critical_section::with(|cs| self.0.access(cs).readyq.is_empty())
}
}
impl<'a, T, const N: usize> Drop for Receiver<'a, T, N> {
fn drop(&mut self) {
// Mark the receiver as dropped and wake all waiters
critical_section::with(|cs| *self.0.access(cs).receiver_dropped = true);
while let Some(waker) = self.0.wait_queue.pop() {
waker.wake();
}
}
}
struct OnDrop<F: FnOnce()> {
f: core::mem::MaybeUninit<F>,
}
impl<F: FnOnce()> OnDrop<F> {
pub fn new(f: F) -> Self {
Self {
f: core::mem::MaybeUninit::new(f),
}
}
#[allow(unused)]
pub fn defuse(self) {
core::mem::forget(self)
}
}
impl<F: FnOnce()> Drop for OnDrop<F> {
fn drop(&mut self) {
unsafe { self.f.as_ptr().read()() }
}
}
#[cfg(test)]
#[macro_use]
extern crate std;
#[cfg(test)]
mod tests {
#[test]
fn channel() {}
}

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rtic-channel/src/wait_queue.rs Normal file
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//! ...
use core::cell::UnsafeCell;
use core::marker::PhantomPinned;
use core::ptr::null_mut;
use core::sync::atomic::{AtomicPtr, Ordering};
use core::task::Waker;
use critical_section as cs;
pub type WaitQueue = LinkedList<Waker>;
struct MyLinkPtr<T>(UnsafeCell<*mut Link<T>>);
impl<T> MyLinkPtr<T> {
#[inline(always)]
fn new(val: *mut Link<T>) -> Self {
Self(UnsafeCell::new(val))
}
/// SAFETY: Only use this in a critical section, and don't forget them barriers.
#[inline(always)]
unsafe fn load_relaxed(&self) -> *mut Link<T> {
unsafe { *self.0.get() }
}
/// SAFETY: Only use this in a critical section, and don't forget them barriers.
#[inline(always)]
unsafe fn store_relaxed(&self, val: *mut Link<T>) {
unsafe { self.0.get().write(val) }
}
}
/// A FIFO linked list for a wait queue.
pub struct LinkedList<T> {
head: AtomicPtr<Link<T>>, // UnsafeCell<*mut Link<T>>
tail: AtomicPtr<Link<T>>,
}
impl<T> LinkedList<T> {
/// Create a new linked list.
pub const fn new() -> Self {
Self {
head: AtomicPtr::new(null_mut()),
tail: AtomicPtr::new(null_mut()),
}
}
}
impl<T: Clone> LinkedList<T> {
const R: Ordering = Ordering::Relaxed;
/// Pop the first element in the queue.
pub fn pop(&self) -> Option<T> {
cs::with(|_| {
// Make sure all previous writes are visible
core::sync::atomic::fence(Ordering::SeqCst);
let head = self.head.load(Self::R);
// SAFETY: `as_ref` is safe as `insert` requires a valid reference to a link
if let Some(head_ref) = unsafe { head.as_ref() } {
// Move head to the next element
self.head.store(head_ref.next.load(Self::R), Self::R);
// We read the value at head
let head_val = head_ref.val.clone();
let tail = self.tail.load(Self::R);
if head == tail {
// The queue is empty
self.tail.store(null_mut(), Self::R);
}
if let Some(next_ref) = unsafe { head_ref.next.load(Self::R).as_ref() } {
next_ref.prev.store(null_mut(), Self::R);
}
// Clear the pointers in the node.
head_ref.next.store(null_mut(), Self::R);
head_ref.prev.store(null_mut(), Self::R);
return Some(head_val);
}
None
})
}
/// Put an element at the back of the queue.
pub fn push(&self, link: &mut Link<T>) {
cs::with(|_| {
// Make sure all previous writes are visible
core::sync::atomic::fence(Ordering::SeqCst);
let tail = self.tail.load(Self::R);
if let Some(tail_ref) = unsafe { tail.as_ref() } {
// Queue is not empty
link.prev.store(tail, Self::R);
self.tail.store(link, Self::R);
tail_ref.next.store(link, Self::R);
} else {
// Queue is empty
self.tail.store(link, Self::R);
self.head.store(link, Self::R);
}
});
}
/// Check if the queue is empty.
pub fn is_empty(&self) -> bool {
self.head.load(Self::R).is_null()
}
}
/// A link in the linked list.
pub struct Link<T> {
pub(crate) val: T,
next: AtomicPtr<Link<T>>,
prev: AtomicPtr<Link<T>>,
_up: PhantomPinned,
}
impl<T: Clone> Link<T> {
const R: Ordering = Ordering::Relaxed;
/// Create a new link.
pub const fn new(val: T) -> Self {
Self {
val,
next: AtomicPtr::new(null_mut()),
prev: AtomicPtr::new(null_mut()),
_up: PhantomPinned,
}
}
pub fn remove_from_list(&mut self, list: &LinkedList<T>) {
cs::with(|_| {
// Make sure all previous writes are visible
core::sync::atomic::fence(Ordering::SeqCst);
let prev = self.prev.load(Self::R);
let next = self.next.load(Self::R);
match unsafe { (prev.as_ref(), next.as_ref()) } {
(None, None) => {
// Not in the list or alone in the list, check if list head == node address
let sp = self as *const _;
if sp == list.head.load(Ordering::Relaxed) {
list.head.store(null_mut(), Self::R);
list.tail.store(null_mut(), Self::R);
}
}
(None, Some(next_ref)) => {
// First in the list
next_ref.prev.store(null_mut(), Self::R);
list.head.store(next, Self::R);
}
(Some(prev_ref), None) => {
// Last in the list
prev_ref.next.store(null_mut(), Self::R);
list.tail.store(prev, Self::R);
}
(Some(prev_ref), Some(next_ref)) => {
// Somewhere in the list
// Connect the `prev.next` and `next.prev` with each other to remove the node
prev_ref.next.store(next, Self::R);
next_ref.prev.store(prev, Self::R);
}
}
})
}
}
#[cfg(test)]
impl<T: core::fmt::Debug + Clone> LinkedList<T> {
fn print(&self) {
cs::with(|_| {
// Make sure all previous writes are visible
core::sync::atomic::fence(Ordering::SeqCst);
let mut head = self.head.load(Self::R);
let tail = self.tail.load(Self::R);
println!(
"List - h = 0x{:x}, t = 0x{:x}",
head as usize, tail as usize
);
let mut i = 0;
// SAFETY: `as_ref` is safe as `insert` requires a valid reference to a link
while let Some(head_ref) = unsafe { head.as_ref() } {
println!(
" {}: {:?}, s = 0x{:x}, n = 0x{:x}, p = 0x{:x}",
i,
head_ref.val,
head as usize,
head_ref.next.load(Ordering::Relaxed) as usize,
head_ref.prev.load(Ordering::Relaxed) as usize
);
head = head_ref.next.load(Self::R);
i += 1;
}
});
}
}
#[cfg(test)]
impl<T: core::fmt::Debug + Clone> Link<T> {
fn print(&self) {
cs::with(|_| {
// Make sure all previous writes are visible
core::sync::atomic::fence(Ordering::SeqCst);
println!("Link:");
println!(
" val = {:?}, n = 0x{:x}, p = 0x{:x}",
self.val,
self.next.load(Ordering::Relaxed) as usize,
self.prev.load(Ordering::Relaxed) as usize
);
});
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn linked_list() {
let mut wq = LinkedList::<u32>::new();
let mut i1 = Link::new(10);
let mut i2 = Link::new(11);
let mut i3 = Link::new(12);
let mut i4 = Link::new(13);
let mut i5 = Link::new(14);
wq.push(&mut i1);
wq.push(&mut i2);
wq.push(&mut i3);
wq.push(&mut i4);
wq.push(&mut i5);
wq.print();
wq.pop();
i1.print();
wq.print();
i4.remove_from_list(&wq);
wq.print();
// i1.remove_from_list(&wq);
// wq.print();
println!("i2");
i2.remove_from_list(&wq);
wq.print();
println!("i3");
i3.remove_from_list(&wq);
wq.print();
println!("i5");
i5.remove_from_list(&wq);
wq.print();
}
}

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rtic-time/src/lib.rs
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//! Crate
#![no_std]
#![no_main]
#![deny(missing_docs)]
#![allow(incomplete_features)]
#![feature(async_fn_in_trait)]