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android / platform / external / rust / crates / lock_api / c1ea2362d0be5cf6e06fae9e6eb133ede887c2b6 / . / src / mutex.rs
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// Copyright 2018 Amanieu d'Antras
//
// Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
// http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
// http://opensource.org/licenses/MIT>, at your option. This file may not be
// copied, modified, or distributed except according to those terms.
use core::cell::UnsafeCell;
use core::fmt;
use core::marker::PhantomData;
use core::mem;
use core::ops::{Deref, DerefMut};
#[cfg(feature = "owning_ref")]
use owning_ref::StableAddress;
#[cfg(feature = "serde")]
use serde::{Deserialize, Deserializer, Serialize, Serializer};
/// Basic operations for a mutex.
///
/// Types implementing this trait can be used by `Mutex` to form a safe and
/// fully-functioning mutex type.
///
/// # Safety
///
/// Implementations of this trait must ensure that the mutex is actually
/// exclusive: a lock can't be acquired while the mutex is already locked.
pub unsafe trait RawMutex {
/// Initial value for an unlocked mutex.
// A “non-constant” const item is a legacy way to supply an initialized value to downstream
// static items. Can hopefully be replaced with `const fn new() -> Self` at some point.
#[allow(clippy::declare_interior_mutable_const)]
const INIT: Self;
/// Marker type which determines whether a lock guard should be `Send`. Use
/// one of the `GuardSend` or `GuardNoSend` helper types here.
type GuardMarker;
/// Acquires this mutex, blocking the current thread until it is able to do so.
fn lock(&self);
/// Attempts to acquire this mutex without blocking. Returns `true`
/// if the lock was successfully acquired and `false` otherwise.
fn try_lock(&self) -> bool;
/// Unlocks this mutex.
///
/// # Safety
///
/// This method may only be called if the mutex is held in the current context, i.e. it must
/// be paired with a successful call to [`lock`], [`try_lock`], [`try_lock_for`] or [`try_lock_until`].
///
/// [`lock`]: #tymethod.lock
/// [`try_lock`]: #tymethod.try_lock
/// [`try_lock_for`]: trait.RawMutexTimed.html#tymethod.try_lock_for
/// [`try_lock_until`]: trait.RawMutexTimed.html#tymethod.try_lock_until
unsafe fn unlock(&self);
/// Checks whether the mutex is currently locked.
#[inline]
fn is_locked(&self) -> bool {
let acquired_lock = self.try_lock();
if acquired_lock {
// Safety: The lock has been successfully acquired above.
unsafe {
self.unlock();
}
}
!acquired_lock
}
}
/// Additional methods for mutexes which support fair unlocking.
///
/// Fair unlocking means that a lock is handed directly over to the next waiting
/// thread if there is one, without giving other threads the opportunity to
/// "steal" the lock in the meantime. This is typically slower than unfair
/// unlocking, but may be necessary in certain circumstances.
pub unsafe trait RawMutexFair: RawMutex {
/// Unlocks this mutex using a fair unlock protocol.
///
/// # Safety
///
/// This method may only be called if the mutex is held in the current context, see
/// the documentation of [`unlock`].
///
/// [`unlock`]: trait.RawMutex.html#tymethod.unlock
unsafe fn unlock_fair(&self);
/// Temporarily yields the mutex to a waiting thread if there is one.
///
/// This method is functionally equivalent to calling `unlock_fair` followed
/// by `lock`, however it can be much more efficient in the case where there
/// are no waiting threads.
///
/// # Safety
///
/// This method may only be called if the mutex is held in the current context, see
/// the documentation of [`unlock`].
///
/// [`unlock`]: trait.RawMutex.html#tymethod.unlock
unsafe fn bump(&self) {
self.unlock_fair();
self.lock();
}
}
/// Additional methods for mutexes which support locking with timeouts.
///
/// The `Duration` and `Instant` types are specified as associated types so that
/// this trait is usable even in `no_std` environments.
pub unsafe trait RawMutexTimed: RawMutex {
/// Duration type used for `try_lock_for`.
type Duration;
/// Instant type used for `try_lock_until`.
type Instant;
/// Attempts to acquire this lock until a timeout is reached.
fn try_lock_for(&self, timeout: Self::Duration) -> bool;
/// Attempts to acquire this lock until a timeout is reached.
fn try_lock_until(&self, timeout: Self::Instant) -> bool;
}
/// A mutual exclusion primitive useful for protecting shared data
///
/// This mutex will block threads waiting for the lock to become available. The
/// mutex can also be statically initialized or created via a `new`
/// constructor. Each mutex has a type parameter which represents the data that
/// it is protecting. The data can only be accessed through the RAII guards
/// returned from `lock` and `try_lock`, which guarantees that the data is only
/// ever accessed when the mutex is locked.
pub struct Mutex<R, T: ?Sized> {
raw: R,
data: UnsafeCell<T>,
}
unsafe impl<R: RawMutex + Send, T: ?Sized + Send> Send for Mutex<R, T> {}
unsafe impl<R: RawMutex + Sync, T: ?Sized + Send> Sync for Mutex<R, T> {}
impl<R: RawMutex, T> Mutex<R, T> {
/// Creates a new mutex in an unlocked state ready for use.
#[cfg(feature = "nightly")]
#[inline]
pub const fn new(val: T) -> Mutex<R, T> {
Mutex {
raw: R::INIT,
data: UnsafeCell::new(val),
}
}
/// Creates a new mutex in an unlocked state ready for use.
#[cfg(not(feature = "nightly"))]
#[inline]
pub fn new(val: T) -> Mutex<R, T> {
Mutex {
raw: R::INIT,
data: UnsafeCell::new(val),
}
}
/// Consumes this mutex, returning the underlying data.
#[inline]
pub fn into_inner(self) -> T {
self.data.into_inner()
}
}
impl<R, T> Mutex<R, T> {
/// Creates a new mutex based on a pre-existing raw mutex.
///
/// This allows creating a mutex in a constant context on stable Rust.
#[inline]
pub const fn const_new(raw_mutex: R, val: T) -> Mutex<R, T> {
Mutex {
raw: raw_mutex,
data: UnsafeCell::new(val),
}
}
}
impl<R: RawMutex, T: ?Sized> Mutex<R, T> {
/// # Safety
///
/// The lock must be held when calling this method.
#[inline]
unsafe fn guard(&self) -> MutexGuard<'_, R, T> {
MutexGuard {
mutex: self,
marker: PhantomData,
}
}
/// Acquires a mutex, blocking the current thread until it is able to do so.
///
/// This function will block the local thread until it is available to acquire
/// the mutex. Upon returning, the thread is the only thread with the mutex
/// held. An RAII guard is returned to allow scoped unlock of the lock. When
/// the guard goes out of scope, the mutex will be unlocked.
///
/// Attempts to lock a mutex in the thread which already holds the lock will
/// result in a deadlock.
#[inline]
pub fn lock(&self) -> MutexGuard<'_, R, T> {
self.raw.lock();
// SAFETY: The lock is held, as required.
unsafe { self.guard() }
}
/// Attempts to acquire this lock.
///
/// If the lock could not be acquired at this time, then `None` is returned.
/// Otherwise, an RAII guard is returned. The lock will be unlocked when the
/// guard is dropped.
///
/// This function does not block.
#[inline]
pub fn try_lock(&self) -> Option<MutexGuard<'_, R, T>> {
if self.raw.try_lock() {
// SAFETY: The lock is held, as required.
Some(unsafe { self.guard() })
} else {
None
}
}
/// Returns a mutable reference to the underlying data.
///
/// Since this call borrows the `Mutex` mutably, no actual locking needs to
/// take place---the mutable borrow statically guarantees no locks exist.
#[inline]
pub fn get_mut(&mut self) -> &mut T {
unsafe { &mut *self.data.get() }
}
/// Checks whether the mutex is currently locked.
#[inline]
pub fn is_locked(&self) -> bool {
self.raw.is_locked()
}
/// Forcibly unlocks the mutex.
///
/// This is useful when combined with `mem::forget` to hold a lock without
/// the need to maintain a `MutexGuard` object alive, for example when
/// dealing with FFI.
///
/// # Safety
///
/// This method must only be called if the current thread logically owns a
/// `MutexGuard` but that guard has be discarded using `mem::forget`.
/// Behavior is undefined if a mutex is unlocked when not locked.
#[inline]
pub unsafe fn force_unlock(&self) {
self.raw.unlock();
}
/// Returns the underlying raw mutex object.
///
/// Note that you will most likely need to import the `RawMutex` trait from
/// `lock_api` to be able to call functions on the raw mutex.
///
/// # Safety
///
/// This method is unsafe because it allows unlocking a mutex while
/// still holding a reference to a `MutexGuard`.
#[inline]
pub unsafe fn raw(&self) -> &R {
&self.raw
}
/// Returns a raw pointer to the underlying data.
///
/// This is useful when combined with `mem::forget` to hold a lock without
/// the need to maintain a `MutexGuard` object alive, for example when
/// dealing with FFI.
///
/// # Safety
///
/// You must ensure that there are no data races when dereferencing the
/// returned pointer, for example if the current thread logically owns
/// a `MutexGuard` but that guard has been discarded using `mem::forget`.
#[inline]
pub fn data_ptr(&self) -> *mut T {
self.data.get()
}
}
impl<R: RawMutexFair, T: ?Sized> Mutex<R, T> {
/// Forcibly unlocks the mutex using a fair unlock procotol.
///
/// This is useful when combined with `mem::forget` to hold a lock without
/// the need to maintain a `MutexGuard` object alive, for example when
/// dealing with FFI.
///
/// # Safety
///
/// This method must only be called if the current thread logically owns a
/// `MutexGuard` but that guard has be discarded using `mem::forget`.
/// Behavior is undefined if a mutex is unlocked when not locked.
#[inline]
pub unsafe fn force_unlock_fair(&self) {
self.raw.unlock_fair();
}
}
impl<R: RawMutexTimed, T: ?Sized> Mutex<R, T> {
/// Attempts to acquire this lock until a timeout is reached.
///
/// If the lock could not be acquired before the timeout expired, then
/// `None` is returned. Otherwise, an RAII guard is returned. The lock will
/// be unlocked when the guard is dropped.
#[inline]
pub fn try_lock_for(&self, timeout: R::Duration) -> Option<MutexGuard<'_, R, T>> {
if self.raw.try_lock_for(timeout) {
// SAFETY: The lock is held, as required.
Some(unsafe { self.guard() })
} else {
None
}
}
/// Attempts to acquire this lock until a timeout is reached.
///
/// If the lock could not be acquired before the timeout expired, then
/// `None` is returned. Otherwise, an RAII guard is returned. The lock will
/// be unlocked when the guard is dropped.
#[inline]
pub fn try_lock_until(&self, timeout: R::Instant) -> Option<MutexGuard<'_, R, T>> {
if self.raw.try_lock_until(timeout) {
// SAFETY: The lock is held, as required.
Some(unsafe { self.guard() })
} else {
None
}
}
}
impl<R: RawMutex, T: ?Sized + Default> Default for Mutex<R, T> {
#[inline]
fn default() -> Mutex<R, T> {
Mutex::new(Default::default())
}
}
impl<R: RawMutex, T> From<T> for Mutex<R, T> {
#[inline]
fn from(t: T) -> Mutex<R, T> {
Mutex::new(t)
}
}
impl<R: RawMutex, T: ?Sized + fmt::Debug> fmt::Debug for Mutex<R, T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self.try_lock() {
Some(guard) => f.debug_struct("Mutex").field("data", &&*guard).finish(),
None => {
struct LockedPlaceholder;
impl fmt::Debug for LockedPlaceholder {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.write_str("<locked>")
}
}
f.debug_struct("Mutex")
.field("data", &LockedPlaceholder)
.finish()
}
}
}
}
// Copied and modified from serde
#[cfg(feature = "serde")]
impl<R, T> Serialize for Mutex<R, T>
where
R: RawMutex,
T: Serialize + ?Sized,
{
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: Serializer,
{
self.lock().serialize(serializer)
}
}
#[cfg(feature = "serde")]
impl<'de, R, T> Deserialize<'de> for Mutex<R, T>
where
R: RawMutex,
T: Deserialize<'de> + ?Sized,
{
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: Deserializer<'de>,
{
Deserialize::deserialize(deserializer).map(Mutex::new)
}
}
/// An RAII implementation of a "scoped lock" of a mutex. When this structure is
/// dropped (falls out of scope), the lock will be unlocked.
///
/// The data protected by the mutex can be accessed through this guard via its
/// `Deref` and `DerefMut` implementations.
#[must_use = "if unused the Mutex will immediately unlock"]
pub struct MutexGuard<'a, R: RawMutex, T: ?Sized> {
mutex: &'a Mutex<R, T>,
marker: PhantomData<(&'a mut T, R::GuardMarker)>,
}
unsafe impl<'a, R: RawMutex + Sync + 'a, T: ?Sized + Sync + 'a> Sync for MutexGuard<'a, R, T> {}
impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> MutexGuard<'a, R, T> {
/// Returns a reference to the original `Mutex` object.
pub fn mutex(s: &Self) -> &'a Mutex<R, T> {
s.mutex
}
/// Makes a new `MappedMutexGuard` for a component of the locked data.
///
/// This operation cannot fail as the `MutexGuard` passed
/// in already locked the mutex.
///
/// This is an associated function that needs to be
/// used as `MutexGuard::map(...)`. A method would interfere with methods of
/// the same name on the contents of the locked data.
#[inline]
pub fn map<U: ?Sized, F>(s: Self, f: F) -> MappedMutexGuard<'a, R, U>
where
F: FnOnce(&mut T) -> &mut U,
{
let raw = &s.mutex.raw;
let data = f(unsafe { &mut *s.mutex.data.get() });
mem::forget(s);
MappedMutexGuard {
raw,
data,
marker: PhantomData,
}
}
/// Attempts to make a new `MappedMutexGuard` for a component of the
/// locked data. The original guard is returned if the closure returns `None`.
///
/// This operation cannot fail as the `MutexGuard` passed
/// in already locked the mutex.
///
/// This is an associated function that needs to be
/// used as `MutexGuard::try_map(...)`. A method would interfere with methods of
/// the same name on the contents of the locked data.
#[inline]
pub fn try_map<U: ?Sized, F>(s: Self, f: F) -> Result<MappedMutexGuard<'a, R, U>, Self>
where
F: FnOnce(&mut T) -> Option<&mut U>,
{
let raw = &s.mutex.raw;
let data = match f(unsafe { &mut *s.mutex.data.get() }) {
Some(data) => data,
None => return Err(s),
};
mem::forget(s);
Ok(MappedMutexGuard {
raw,
data,
marker: PhantomData,
})
}
/// Temporarily unlocks the mutex to execute the given function.
///
/// This is safe because `&mut` guarantees that there exist no other
/// references to the data protected by the mutex.
#[inline]
pub fn unlocked<F, U>(s: &mut Self, f: F) -> U
where
F: FnOnce() -> U,
{
// Safety: A MutexGuard always holds the lock.
unsafe {
s.mutex.raw.unlock();
}
defer!(s.mutex.raw.lock());
f()
}
}
impl<'a, R: RawMutexFair + 'a, T: ?Sized + 'a> MutexGuard<'a, R, T> {
/// Unlocks the mutex using a fair unlock protocol.
///
/// By default, mutexes are unfair and allow the current thread to re-lock
/// the mutex before another has the chance to acquire the lock, even if
/// that thread has been blocked on the mutex for a long time. This is the
/// default because it allows much higher throughput as it avoids forcing a
/// context switch on every mutex unlock. This can result in one thread
/// acquiring a mutex many more times than other threads.
///
/// However in some cases it can be beneficial to ensure fairness by forcing
/// the lock to pass on to a waiting thread if there is one. This is done by
/// using this method instead of dropping the `MutexGuard` normally.
#[inline]
pub fn unlock_fair(s: Self) {
// Safety: A MutexGuard always holds the lock.
unsafe {
s.mutex.raw.unlock_fair();
}
mem::forget(s);
}
/// Temporarily unlocks the mutex to execute the given function.
///
/// The mutex is unlocked using a fair unlock protocol.
///
/// This is safe because `&mut` guarantees that there exist no other
/// references to the data protected by the mutex.
#[inline]
pub fn unlocked_fair<F, U>(s: &mut Self, f: F) -> U
where
F: FnOnce() -> U,
{
// Safety: A MutexGuard always holds the lock.
unsafe {
s.mutex.raw.unlock_fair();
}
defer!(s.mutex.raw.lock());
f()
}
/// Temporarily yields the mutex to a waiting thread if there is one.
///
/// This method is functionally equivalent to calling `unlock_fair` followed
/// by `lock`, however it can be much more efficient in the case where there
/// are no waiting threads.
#[inline]
pub fn bump(s: &mut Self) {
// Safety: A MutexGuard always holds the lock.
unsafe {
s.mutex.raw.bump();
}
}
}
impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> Deref for MutexGuard<'a, R, T> {
type Target = T;
#[inline]
fn deref(&self) -> &T {
unsafe { &*self.mutex.data.get() }
}
}
impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> DerefMut for MutexGuard<'a, R, T> {
#[inline]
fn deref_mut(&mut self) -> &mut T {
unsafe { &mut *self.mutex.data.get() }
}
}
impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> Drop for MutexGuard<'a, R, T> {
#[inline]
fn drop(&mut self) {
// Safety: A MutexGuard always holds the lock.
unsafe {
self.mutex.raw.unlock();
}
}
}
impl<'a, R: RawMutex + 'a, T: fmt::Debug + ?Sized + 'a> fmt::Debug for MutexGuard<'a, R, T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt::Debug::fmt(&**self, f)
}
}
impl<'a, R: RawMutex + 'a, T: fmt::Display + ?Sized + 'a> fmt::Display for MutexGuard<'a, R, T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
(**self).fmt(f)
}
}
#[cfg(feature = "owning_ref")]
unsafe impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> StableAddress for MutexGuard<'a, R, T> {}
/// An RAII mutex guard returned by `MutexGuard::map`, which can point to a
/// subfield of the protected data.
///
/// The main difference between `MappedMutexGuard` and `MutexGuard` is that the
/// former doesn't support temporarily unlocking and re-locking, since that
/// could introduce soundness issues if the locked object is modified by another
/// thread.
#[must_use = "if unused the Mutex will immediately unlock"]
pub struct MappedMutexGuard<'a, R: RawMutex, T: ?Sized> {
raw: &'a R,
data: *mut T,
marker: PhantomData<&'a mut T>,
}
unsafe impl<'a, R: RawMutex + Sync + 'a, T: ?Sized + Sync + 'a> Sync
for MappedMutexGuard<'a, R, T>
{
}
unsafe impl<'a, R: RawMutex + 'a, T: ?Sized + Send + 'a> Send for MappedMutexGuard<'a, R, T> where
R::GuardMarker: Send
{
}
impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> MappedMutexGuard<'a, R, T> {
/// Makes a new `MappedMutexGuard` for a component of the locked data.
///
/// This operation cannot fail as the `MappedMutexGuard` passed
/// in already locked the mutex.
///
/// This is an associated function that needs to be
/// used as `MappedMutexGuard::map(...)`. A method would interfere with methods of
/// the same name on the contents of the locked data.
#[inline]
pub fn map<U: ?Sized, F>(s: Self, f: F) -> MappedMutexGuard<'a, R, U>
where
F: FnOnce(&mut T) -> &mut U,
{
let raw = s.raw;
let data = f(unsafe { &mut *s.data });
mem::forget(s);
MappedMutexGuard {
raw,
data,
marker: PhantomData,
}
}
/// Attempts to make a new `MappedMutexGuard` for a component of the
/// locked data. The original guard is returned if the closure returns `None`.
///
/// This operation cannot fail as the `MappedMutexGuard` passed
/// in already locked the mutex.
///
/// This is an associated function that needs to be
/// used as `MappedMutexGuard::try_map(...)`. A method would interfere with methods of
/// the same name on the contents of the locked data.
#[inline]
pub fn try_map<U: ?Sized, F>(s: Self, f: F) -> Result<MappedMutexGuard<'a, R, U>, Self>
where
F: FnOnce(&mut T) -> Option<&mut U>,
{
let raw = s.raw;
let data = match f(unsafe { &mut *s.data }) {
Some(data) => data,
None => return Err(s),
};
mem::forget(s);
Ok(MappedMutexGuard {
raw,
data,
marker: PhantomData,
})
}
}
impl<'a, R: RawMutexFair + 'a, T: ?Sized + 'a> MappedMutexGuard<'a, R, T> {
/// Unlocks the mutex using a fair unlock protocol.
///
/// By default, mutexes are unfair and allow the current thread to re-lock
/// the mutex before another has the chance to acquire the lock, even if
/// that thread has been blocked on the mutex for a long time. This is the
/// default because it allows much higher throughput as it avoids forcing a
/// context switch on every mutex unlock. This can result in one thread
/// acquiring a mutex many more times than other threads.
///
/// However in some cases it can be beneficial to ensure fairness by forcing
/// the lock to pass on to a waiting thread if there is one. This is done by
/// using this method instead of dropping the `MutexGuard` normally.
#[inline]
pub fn unlock_fair(s: Self) {
// Safety: A MutexGuard always holds the lock.
unsafe {
s.raw.unlock_fair();
}
mem::forget(s);
}
}
impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> Deref for MappedMutexGuard<'a, R, T> {
type Target = T;
#[inline]
fn deref(&self) -> &T {
unsafe { &*self.data }
}
}
impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> DerefMut for MappedMutexGuard<'a, R, T> {
#[inline]
fn deref_mut(&mut self) -> &mut T {
unsafe { &mut *self.data }
}
}
impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> Drop for MappedMutexGuard<'a, R, T> {
#[inline]
fn drop(&mut self) {
// Safety: A MappedMutexGuard always holds the lock.
unsafe {
self.raw.unlock();
}
}
}
impl<'a, R: RawMutex + 'a, T: fmt::Debug + ?Sized + 'a> fmt::Debug for MappedMutexGuard<'a, R, T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt::Debug::fmt(&**self, f)
}
}
impl<'a, R: RawMutex + 'a, T: fmt::Display + ?Sized + 'a> fmt::Display
for MappedMutexGuard<'a, R, T>
{
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
(**self).fmt(f)
}
}
#[cfg(feature = "owning_ref")]
unsafe impl<'a, R: RawMutex + 'a, T: ?Sized + 'a> StableAddress for MappedMutexGuard<'a, R, T> {}