pub struct Mutex<T>where
T: ?Sized,{ /* private fields */ }
Expand description
An async mutex.
The locking mechanism uses eventual fairness to ensure locking will be fair on average without sacrificing performance. This is done by forcing a fair lock whenever a lock operation is starved for longer than 0.5 milliseconds.
§Examples
use async_lock::Mutex;
let m = Mutex::new(1);
let mut guard = m.lock().await;
*guard = 2;
assert!(m.try_lock().is_none());
drop(guard);
assert_eq!(*m.try_lock().unwrap(), 2);
Implementations§
source§impl<T> Mutex<T>
impl<T> Mutex<T>
source§impl<T> Mutex<T>where
T: ?Sized,
impl<T> Mutex<T>where
T: ?Sized,
sourcepub fn lock(&self) -> Lock<'_, T> ⓘ
pub fn lock(&self) -> Lock<'_, T> ⓘ
Acquires the mutex.
Returns a guard that releases the mutex when dropped.
§Examples
use async_lock::Mutex;
let mutex = Mutex::new(10);
let guard = mutex.lock().await;
assert_eq!(*guard, 10);
sourcepub fn lock_blocking(&self) -> MutexGuard<'_, T>
pub fn lock_blocking(&self) -> MutexGuard<'_, T>
Acquires the mutex using the blocking strategy.
Returns a guard that releases the mutex when dropped.
§Blocking
Rather than using asynchronous waiting, like the lock
method,
this method will block the current thread until the lock is acquired.
This method should not be used in an asynchronous context. It is intended to be used in a way that a mutex can be used in both asynchronous and synchronous contexts. Calling this method in an asynchronous context may result in a deadlock.
§Examples
use async_lock::Mutex;
let mutex = Mutex::new(10);
let guard = mutex.lock_blocking();
assert_eq!(*guard, 10);
sourcepub fn try_lock(&self) -> Option<MutexGuard<'_, T>>
pub fn try_lock(&self) -> Option<MutexGuard<'_, T>>
sourcepub fn get_mut(&mut self) -> &mut T
pub fn get_mut(&mut self) -> &mut T
Returns a mutable reference to the underlying data.
Since this call borrows the mutex mutably, no actual locking takes place – the mutable borrow statically guarantees the mutex is not already acquired.
§Examples
use async_lock::Mutex;
let mut mutex = Mutex::new(0);
*mutex.get_mut() = 10;
assert_eq!(*mutex.lock().await, 10);
source§impl<T> Mutex<T>where
T: ?Sized,
impl<T> Mutex<T>where
T: ?Sized,
sourcepub fn lock_arc(self: &Arc<Mutex<T>>) -> LockArc<T> ⓘ
pub fn lock_arc(self: &Arc<Mutex<T>>) -> LockArc<T> ⓘ
Acquires the mutex and clones a reference to it.
Returns an owned guard that releases the mutex when dropped.
§Examples
use async_lock::Mutex;
use std::sync::Arc;
let mutex = Arc::new(Mutex::new(10));
let guard = mutex.lock_arc().await;
assert_eq!(*guard, 10);
sourcepub fn lock_arc_blocking(self: &Arc<Mutex<T>>) -> MutexGuardArc<T>
pub fn lock_arc_blocking(self: &Arc<Mutex<T>>) -> MutexGuardArc<T>
Acquires the mutex and clones a reference to it using the blocking strategy.
Returns an owned guard that releases the mutex when dropped.
§Blocking
Rather than using asynchronous waiting, like the lock_arc
method,
this method will block the current thread until the lock is acquired.
This method should not be used in an asynchronous context. It is intended to be used in a way that a mutex can be used in both asynchronous and synchronous contexts. Calling this method in an asynchronous context may result in a deadlock.
§Examples
use async_lock::Mutex;
use std::sync::Arc;
let mutex = Arc::new(Mutex::new(10));
let guard = mutex.lock_arc_blocking();
assert_eq!(*guard, 10);
sourcepub fn try_lock_arc(self: &Arc<Mutex<T>>) -> Option<MutexGuardArc<T>>
pub fn try_lock_arc(self: &Arc<Mutex<T>>) -> Option<MutexGuardArc<T>>
Attempts to acquire the mutex and clone a reference to it.
If the mutex could not be acquired at this time, then None
is returned. Otherwise, an
owned guard is returned that releases the mutex when dropped.
§Examples
use async_lock::Mutex;
use std::sync::Arc;
let mutex = Arc::new(Mutex::new(10));
if let Some(guard) = mutex.try_lock() {
assert_eq!(*guard, 10);
}