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Quelle bilock.rs
Sprache: unbekannt
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Spracherkennung für: .rs vermutete Sprache: Unknown {[0] [0] [0]} [Methode: Schwerpunktbildung, einfache Gewichte, sechs Dimensionen]
//! Futures-powered synchronization primitives.
use alloc::boxed::Box;
use alloc::sync::Arc;
use core::cell::UnsafeCell;
use core::ops::{Deref, DerefMut};
use core::pin::Pin;
use core::sync::atomic::AtomicPtr;
use core::sync::atomic::Ordering::SeqCst;
use core::{fmt, ptr};
#[cfg(feature = "bilock")]
use futures_core::future::Future;
use futures_core::task::{Context, Poll, Waker};
/// A type of futures-powered synchronization primitive which is a mutex between
/// two possible owners.
///
/// This primitive is not as generic as a full-blown mutex but is sufficient for
/// many use cases where there are only two possible owners of a resource. The
/// implementation of `BiLock` can be more optimized for just the two possible
/// owners.
///
/// Note that it's possible to use this lock through a poll-style interface with
/// the `poll_lock` method but you can also use it as a future with the `lock`
/// method that consumes a `BiLock` and returns a future that will resolve when
/// it's locked.
///
/// A `BiLock` is typically used for "split" operations where data which serves
/// two purposes wants to be split into two to be worked with separately. For
/// example a TCP stream could be both a reader and a writer or a framing layer
/// could be both a stream and a sink for messages. A `BiLock` enables splitting
/// these two and then using each independently in a futures-powered fashion.
///
/// This type is only available when the `bilock` feature of this
/// library is activated.
#[derive(Debug)]
#[cfg_attr(docsrs, doc(cfg(feature = "bilock")))]
pub struct BiLock<T> {
arc: Arc<Inner<T>>,
}
#[derive(Debug)]
struct Inner<T> {
state: AtomicPtr<Waker>,
value: Option<UnsafeCell<T>>,
}
unsafe impl<T: Send> Send for Inner<T> {}
unsafe impl<T: Send> Sync for Inner<T> {}
impl<T> BiLock<T> {
/// Creates a new `BiLock` protecting the provided data.
///
/// Two handles to the lock are returned, and these are the only two handles
/// that will ever be available to the lock. These can then be sent to separate
/// tasks to be managed there.
///
/// The data behind the bilock is considered to be pinned, which allows `Pin`
/// references to locked data. However, this means that the locked value
/// will only be available through `Pin<&mut T>` (not `&mut T`) unless `T` is `Unpin`.
/// Similarly, reuniting the lock and extracting the inner value is only
/// possible when `T` is `Unpin`.
pub fn new(t: T) -> (Self, Self) {
let arc = Arc::new(Inner {
state: AtomicPtr::new(ptr::null_mut()),
value: Some(UnsafeCell::new(t)),
});
(Self { arc: arc.clone() }, Self { arc })
}
/// Attempt to acquire this lock, returning `Pending` if it can't be
/// acquired.
///
/// This function will acquire the lock in a nonblocking fashion, returning
/// immediately if the lock is already held. If the lock is successfully
/// acquired then `Poll::Ready` is returned with a value that represents
/// the locked value (and can be used to access the protected data). The
/// lock is unlocked when the returned `BiLockGuard` is dropped.
///
/// If the lock is already held then this function will return
/// `Poll::Pending`. In this case the current task will also be scheduled
/// to receive a notification when the lock would otherwise become
/// available.
///
/// # Panics
///
/// This function will panic if called outside the context of a future's
/// task.
pub fn poll_lock(&self, cx: &mut Context<'_>) -> Poll<BiLockGuard<'_, T>> {
let mut waker = None;
loop {
let n = self.arc.state.swap(invalid_ptr(1), SeqCst);
match n as usize {
// Woohoo, we grabbed the lock!
0 => return Poll::Ready(BiLockGuard { bilock: self }),
// Oops, someone else has locked the lock
1 => {}
// A task was previously blocked on this lock, likely our task,
// so we need to update that task.
_ => unsafe {
let mut prev = Box::from_raw(n);
*prev = cx.waker().clone();
waker = Some(prev);
},
}
// type ascription for safety's sake!
let me: Box<Waker> = waker.take().unwrap_or_else(|| Box::new(cx.waker().clone()));
let me = Box::into_raw(me);
match self.arc.state.compare_exchange(invalid_ptr(1), me, SeqCst, SeqCst) {
// The lock is still locked, but we've now parked ourselves, so
// just report that we're scheduled to receive a notification.
Ok(_) => return Poll::Pending,
// Oops, looks like the lock was unlocked after our swap above
// and before the compare_exchange. Deallocate what we just
// allocated and go through the loop again.
Err(n) if n.is_null() => unsafe {
waker = Some(Box::from_raw(me));
},
// The top of this loop set the previous state to 1, so if we
// failed the CAS above then it's because the previous value was
// *not* zero or one. This indicates that a task was blocked,
// but we're trying to acquire the lock and there's only one
// other reference of the lock, so it should be impossible for
// that task to ever block itself.
Err(n) => panic!("invalid state: {}", n as usize),
}
}
}
/// Perform a "blocking lock" of this lock, consuming this lock handle and
/// returning a future to the acquired lock.
///
/// This function consumes the `BiLock<T>` and returns a sentinel future,
/// `BiLockAcquire<T>`. The returned future will resolve to
/// `BiLockAcquired<T>` which represents a locked lock similarly to
/// `BiLockGuard<T>`.
///
/// Note that the returned future will never resolve to an error.
#[cfg(feature = "bilock")]
#[cfg_attr(docsrs, doc(cfg(feature = "bilock")))]
pub fn lock(&self) -> BiLockAcquire<'_, T> {
BiLockAcquire { bilock: self }
}
/// Attempts to put the two "halves" of a `BiLock<T>` back together and
/// recover the original value. Succeeds only if the two `BiLock<T>`s
/// originated from the same call to `BiLock::new`.
pub fn reunite(self, other: Self) -> Result<T, ReuniteError<T>>
where
T: Unpin,
{
if Arc::ptr_eq(&self.arc, &other.arc) {
drop(other);
let inner = Arc::try_unwrap(self.arc)
.ok()
.expect("futures: try_unwrap failed in BiLock<T>::reunite");
Ok(unsafe { inner.into_value() })
} else {
Err(ReuniteError(self, other))
}
}
fn unlock(&self) {
let n = self.arc.state.swap(ptr::null_mut(), SeqCst);
match n as usize {
// we've locked the lock, shouldn't be possible for us to see an
// unlocked lock.
0 => panic!("invalid unlocked state"),
// Ok, no one else tried to get the lock, we're done.
1 => {}
// Another task has parked themselves on this lock, let's wake them
// up as its now their turn.
_ => unsafe {
Box::from_raw(n).wake();
},
}
}
}
impl<T: Unpin> Inner<T> {
unsafe fn into_value(mut self) -> T {
self.value.take().unwrap().into_inner()
}
}
impl<T> Drop for Inner<T> {
fn drop(&mut self) {
assert!(self.state.load(SeqCst).is_null());
}
}
/// Error indicating two `BiLock<T>`s were not two halves of a whole, and
/// thus could not be `reunite`d.
#[cfg_attr(docsrs, doc(cfg(feature = "bilock")))]
pub struct ReuniteError<T>(pub BiLock<T>, pub BiLock<T>);
impl<T> fmt::Debug for ReuniteError<T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_tuple("ReuniteError").field(&"...").finish()
}
}
impl<T> fmt::Display for ReuniteError<T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "tried to reunite two BiLocks that don't form a pair")
}
}
#[cfg(feature = "std")]
impl<T: core::any::Any> std::error::Error for ReuniteError<T> {}
/// Returned RAII guard from the `poll_lock` method.
///
/// This structure acts as a sentinel to the data in the `BiLock<T>` itself,
/// implementing `Deref` and `DerefMut` to `T`. When dropped, the lock will be
/// unlocked.
#[derive(Debug)]
#[cfg_attr(docsrs, doc(cfg(feature = "bilock")))]
pub struct BiLockGuard<'a, T> {
bilock: &'a BiLock<T>,
}
// We allow parallel access to T via Deref, so Sync bound is also needed here.
unsafe impl<T: Send + Sync> Sync for BiLockGuard<'_, T> {}
impl<T> Deref for BiLockGuard<'_, T> {
type Target = T;
fn deref(&self) -> &T {
unsafe { &*self.bilock.arc.value.as_ref().unwrap().get() }
}
}
impl<T: Unpin> DerefMut for BiLockGuard<'_, T> {
fn deref_mut(&mut self) -> &mut T {
unsafe { &mut *self.bilock.arc.value.as_ref().unwrap().get() }
}
}
impl<T> BiLockGuard<'_, T> {
/// Get a mutable pinned reference to the locked value.
pub fn as_pin_mut(&mut self) -> Pin<&mut T> {
// Safety: we never allow moving a !Unpin value out of a bilock, nor
// allow mutable access to it
unsafe { Pin::new_unchecked(&mut *self.bilock.arc.value.as_ref().unwrap().get()) }
}
}
impl<T> Drop for BiLockGuard<'_, T> {
fn drop(&mut self) {
self.bilock.unlock();
}
}
/// Future returned by `BiLock::lock` which will resolve when the lock is
/// acquired.
#[cfg(feature = "bilock")]
#[cfg_attr(docsrs, doc(cfg(feature = "bilock")))]
#[must_use = "futures do nothing unless you `.await` or poll them"]
#[derive(Debug)]
pub struct BiLockAcquire<'a, T> {
bilock: &'a BiLock<T>,
}
// Pinning is never projected to fields
#[cfg(feature = "bilock")]
impl<T> Unpin for BiLockAcquire<'_, T> {}
#[cfg(feature = "bilock")]
impl<'a, T> Future for BiLockAcquire<'a, T> {
type Output = BiLockGuard<'a, T>;
fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
self.bilock.poll_lock(cx)
}
}
// Based on core::ptr::invalid_mut. Equivalent to `addr as *mut T`, but is strict-provenance compatible.
#[allow(clippy::useless_transmute)]
#[inline]
fn invalid_ptr<T>(addr: usize) -> *mut T {
// SAFETY: every valid integer is also a valid pointer (as long as you don't dereference that
// pointer).
unsafe { core::mem::transmute(addr) }
}
[ Dauer der Verarbeitung: 0.35 Sekunden
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2026-04-02
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