Struct async_executor::Executor
source · pub struct Executor<'a> { /* private fields */ }
Expand description
An async executor.
§Examples
A multi-threaded executor:
use async_channel::unbounded;
use async_executor::Executor;
use easy_parallel::Parallel;
use futures_lite::future;
let ex = Executor::new();
let (signal, shutdown) = unbounded::<()>();
Parallel::new()
// Run four executor threads.
.each(0..4, |_| future::block_on(ex.run(shutdown.recv())))
// Run the main future on the current thread.
.finish(|| future::block_on(async {
println!("Hello world!");
drop(signal);
}));
Implementations§
source§impl<'a> Executor<'a>
impl<'a> Executor<'a>
sourcepub fn is_empty(&self) -> bool
pub fn is_empty(&self) -> bool
Returns true
if there are no unfinished tasks.
§Examples
use async_executor::Executor;
let ex = Executor::new();
assert!(ex.is_empty());
let task = ex.spawn(async {
println!("Hello world");
});
assert!(!ex.is_empty());
assert!(ex.try_tick());
assert!(ex.is_empty());
sourcepub fn spawn<T: Send + 'a>(
&self,
future: impl Future<Output = T> + Send + 'a
) -> Task<T>
pub fn spawn<T: Send + 'a>( &self, future: impl Future<Output = T> + Send + 'a ) -> Task<T>
Spawns a task onto the executor.
§Examples
use async_executor::Executor;
let ex = Executor::new();
let task = ex.spawn(async {
println!("Hello world");
});
sourcepub fn spawn_many<T: Send + 'a, F: Future<Output = T> + Send + 'a>(
&self,
futures: impl IntoIterator<Item = F>,
handles: &mut impl Extend<Task<F::Output>>
)
pub fn spawn_many<T: Send + 'a, F: Future<Output = T> + Send + 'a>( &self, futures: impl IntoIterator<Item = F>, handles: &mut impl Extend<Task<F::Output>> )
Spawns many tasks onto the executor.
As opposed to the spawn
method, this locks the executor’s inner task lock once and
spawns all of the tasks in one go. With large amounts of tasks this can improve
contention.
For very large numbers of tasks the lock is occasionally dropped and re-acquired to prevent runner thread starvation. It is assumed that the iterator provided does not block; blocking iterators can lock up the internal mutex and therefore the entire executor.
§Example
use async_executor::Executor;
use futures_lite::{stream, prelude::*};
use std::future::ready;
let mut ex = Executor::new();
let futures = [
ready(1),
ready(2),
ready(3)
];
// Spawn all of the futures onto the executor at once.
let mut tasks = vec![];
ex.spawn_many(futures, &mut tasks);
// Await all of them.
let results = ex.run(async move {
stream::iter(tasks).then(|x| x).collect::<Vec<_>>().await
}).await;
assert_eq!(results, [1, 2, 3]);
sourcepub fn try_tick(&self) -> bool
pub fn try_tick(&self) -> bool
Attempts to run a task if at least one is scheduled.
Running a scheduled task means simply polling its future once.
§Examples
use async_executor::Executor;
let ex = Executor::new();
assert!(!ex.try_tick()); // no tasks to run
let task = ex.spawn(async {
println!("Hello world");
});
assert!(ex.try_tick()); // a task was found
sourcepub async fn tick(&self)
pub async fn tick(&self)
Runs a single task.
Running a task means simply polling its future once.
If no tasks are scheduled when this method is called, it will wait until one is scheduled.
§Examples
use async_executor::Executor;
use futures_lite::future;
let ex = Executor::new();
let task = ex.spawn(async {
println!("Hello world");
});
future::block_on(ex.tick()); // runs the task
sourcepub async fn run<T>(&self, future: impl Future<Output = T>) -> T
pub async fn run<T>(&self, future: impl Future<Output = T>) -> T
Runs the executor until the given future completes.
§Examples
use async_executor::Executor;
use futures_lite::future;
let ex = Executor::new();
let task = ex.spawn(async { 1 + 2 });
let res = future::block_on(ex.run(async { task.await * 2 }));
assert_eq!(res, 6);