Struct futures_locks::RwLock[][src]

pub struct RwLock<T: ?Sized> { /* fields omitted */ }
Expand description

A Futures-aware RwLock.

std::sync::RwLock cannot be used in an asynchronous environment like Tokio, because an acquisition can block an entire reactor. This class can be used instead. It functions much like std::sync::RwLock. Unlike that class, it also has a builtin Arc, making it accessible from multiple threads. It’s also safe to clone. Also unlike std::sync::RwLock, this class does not detect lock poisoning.

Implementations

Create a new RwLock in the unlocked state.

Consumes the RwLock and returns the wrapped data. If the RwLock still has multiple references (not necessarily locked), returns a copy of self instead.

Returns a reference to the underlying data, if there are no other clones of the RwLock.

Since this call borrows the RwLock mutably, no actual locking takes place – the mutable borrow statically guarantees no locks exist. However, if the RwLock has already been cloned, then None will be returned instead.

Examples
let mut lock = RwLock::<u32>::new(0);
*lock.get_mut().unwrap() += 5;
assert_eq!(lock.try_unwrap().unwrap(), 5);

Acquire the RwLock nonexclusively, read-only, blocking the task in the meantime.

When the returned Future is ready, then this task will have read-only access to the protected data.

Examples
let rwlock = RwLock::<u32>::new(42);
let fut = rwlock.read().map(|mut guard| { *guard });
assert_eq!(block_on(fut), 42);

Acquire the RwLock exclusively, read-write, blocking the task in the meantime.

When the returned Future is ready, then this task will have read-write access to the protected data.

Examples
let rwlock = RwLock::<u32>::new(42);
let fut = rwlock.write().map(|mut guard| { *guard = 5;});
block_on(fut);
assert_eq!(rwlock.try_unwrap().unwrap(), 5);

Attempts to acquire the RwLock nonexclusively.

If the operation would block, returns Err instead. Otherwise, returns a guard (not a Future).

Examples
let mut lock = RwLock::<u32>::new(5);
let r = match lock.try_read() {
    Ok(guard) => *guard,
    Err(_) => panic!("Better luck next time!")
};
assert_eq!(5, r);

Attempts to acquire the RwLock exclusively.

If the operation would block, returns Err instead. Otherwise, returns a guard (not a Future).

Examples
let mut lock = RwLock::<u32>::new(5);
match lock.try_write() {
    Ok(mut guard) => *guard += 5,
    Err(_) => panic!("Better luck next time!")
}
assert_eq!(10, lock.try_unwrap().unwrap());
This is supported on crate feature tokio only.

Acquires a RwLock nonexclusively and performs a computation on its guarded value in a separate task. Returns a Future containing the result of the computation.

When using Tokio, this method will often hold the RwLock for less time than chaining a computation to read. The reason is that Tokio polls all tasks promptly upon notification. However, Tokio does not guarantee that it will poll all futures promptly when their owning task gets notified. So it’s best to hold RwLocks within their own tasks, lest their continuations get blocked by slow stacked combinators.

Examples
let rwlock = RwLock::<u32>::new(5);
let mut rt = Runtime::new().unwrap();
let r = rt.block_on(async {
    rwlock.with_read(|mut guard| {
        ready(*guard)
    }).await
});
assert_eq!(r, 5);
This is supported on crate feature tokio only.

Like with_read but for Futures that aren’t Send. Spawns a new task on a single-threaded Runtime to complete the Future.

Examples
// Note: Rc is not `Send`
let rwlock = RwLock::<Rc<u32>>::new(Rc::new(5));
let mut rt = Runtime::new().unwrap();
let r = rt.block_on(async {
    rwlock.with_read_local(|mut guard| {
        ready(**guard)
    }).await
});
assert_eq!(r, 5);
This is supported on crate feature tokio only.

Acquires a RwLock exclusively and performs a computation on its guarded value in a separate task. Returns a Future containing the result of the computation.

When using Tokio, this method will often hold the RwLock for less time than chaining a computation to write. The reason is that Tokio polls all tasks promptly upon notification. However, Tokio does not guarantee that it will poll all futures promptly when their owning task gets notified. So it’s best to hold RwLocks within their own tasks, lest their continuations get blocked by slow stacked combinators.

Examples
let rwlock = RwLock::<u32>::new(0);
let mut rt = Runtime::new().unwrap();
let r = rt.block_on(async {
    rwlock.with_write(|mut guard| {
        *guard += 5;
        ready(())
    }).await
});
assert_eq!(rwlock.try_unwrap().unwrap(), 5);
This is supported on crate feature tokio only.

Like with_write but for Futures that aren’t Send. Spawns a new task on a single-threaded Runtime to complete the Future.

Examples
// Note: Rc is not `Send`
let rwlock = RwLock::<Rc<u32>>::new(Rc::new(0));
let mut rt = Runtime::new().unwrap();
let r = rt.block_on(async {
    rwlock.with_write_local(|mut guard| {
        *Rc::get_mut(&mut *guard).unwrap() += 5;
        ready(())
    }).await
});
assert_eq!(*rwlock.try_unwrap().unwrap(), 5);

Trait Implementations

Returns a copy of the value. Read more

Performs copy-assignment from source. Read more

Formats the value using the given formatter. Read more

Returns the “default value” for a type. Read more

Auto Trait Implementations

Blanket Implementations

Gets the TypeId of self. Read more

Immutably borrows from an owned value. Read more

Mutably borrows from an owned value. Read more

Performs the conversion.

Performs the conversion.

The resulting type after obtaining ownership.

Creates owned data from borrowed data, usually by cloning. Read more

🔬 This is a nightly-only experimental API. (toowned_clone_into)

recently added

Uses borrowed data to replace owned data, usually by cloning. Read more

The type returned in the event of a conversion error.

Performs the conversion.

The type returned in the event of a conversion error.

Performs the conversion.