Struct bevy_internal::tasks::prelude::AsyncComputeTaskPool
source · pub struct AsyncComputeTaskPool(/* private fields */);
Expand description
A newtype for a task pool for CPU-intensive work that may span across multiple frames
See TaskPool
documentation for details on Bevy tasks.
Use ComputeTaskPool
if the work must be complete before advancing to the next frame.
Implementations§
source§impl AsyncComputeTaskPool
impl AsyncComputeTaskPool
sourcepub fn get_or_init(
f: impl FnOnce() -> TaskPool
) -> &'static AsyncComputeTaskPool
pub fn get_or_init( f: impl FnOnce() -> TaskPool ) -> &'static AsyncComputeTaskPool
Gets the global AsyncComputeTaskPool
instance, or initializes it with f
.
sourcepub fn try_get() -> Option<&'static AsyncComputeTaskPool>
pub fn try_get() -> Option<&'static AsyncComputeTaskPool>
Attempts to get the global AsyncComputeTaskPool
instance, or returns None
if it is not initialized.
sourcepub fn get() -> &'static AsyncComputeTaskPool
pub fn get() -> &'static AsyncComputeTaskPool
Gets the global AsyncComputeTaskPool
instance.
Panics
Panics if the global instance has not been initialized yet.
Methods from Deref<Target = TaskPool>§
sourcepub fn thread_num(&self) -> usize
pub fn thread_num(&self) -> usize
Return the number of threads owned by the task pool
sourcepub fn scope<'env, F, T>(&self, f: F) -> Vec<T>
pub fn scope<'env, F, T>(&self, f: F) -> Vec<T>
Allows spawning non-'static
futures on the thread pool. The function takes a callback,
passing a scope object into it. The scope object provided to the callback can be used
to spawn tasks. This function will await the completion of all tasks before returning.
This is similar to thread::scope
and rayon::scope
.
Example
use bevy_tasks::TaskPool;
let pool = TaskPool::new();
let mut x = 0;
let results = pool.scope(|s| {
s.spawn(async {
// you can borrow the spawner inside a task and spawn tasks from within the task
s.spawn(async {
// borrow x and mutate it.
x = 2;
// return a value from the task
1
});
// return some other value from the first task
0
});
});
// The ordering of results is non-deterministic if you spawn from within tasks as above.
// If you're doing this, you'll have to write your code to not depend on the ordering.
assert!(results.contains(&0));
assert!(results.contains(&1));
// The ordering is deterministic if you only spawn directly from the closure function.
let results = pool.scope(|s| {
s.spawn(async { 0 });
s.spawn(async { 1 });
});
assert_eq!(&results[..], &[0, 1]);
// You can access x after scope runs, since it was only temporarily borrowed in the scope.
assert_eq!(x, 2);
Lifetimes
The Scope
object takes two lifetimes: 'scope
and 'env
.
The 'scope
lifetime represents the lifetime of the scope. That is the time during
which the provided closure and tasks that are spawned into the scope are run.
The 'env
lifetime represents the lifetime of whatever is borrowed by the scope.
Thus this lifetime must outlive 'scope
.
use bevy_tasks::TaskPool;
fn scope_escapes_closure() {
let pool = TaskPool::new();
let foo = Box::new(42);
pool.scope(|scope| {
std::thread::spawn(move || {
// UB. This could spawn on the scope after `.scope` returns and the internal Scope is dropped.
scope.spawn(async move {
assert_eq!(*foo, 42);
});
});
});
}
use bevy_tasks::TaskPool;
fn cannot_borrow_from_closure() {
let pool = TaskPool::new();
pool.scope(|scope| {
let x = 1;
let y = &x;
scope.spawn(async move {
assert_eq!(*y, 1);
});
});
}
sourcepub fn scope_with_executor<'env, F, T>(
&self,
tick_task_pool_executor: bool,
external_executor: Option<&ThreadExecutor<'_>>,
f: F
) -> Vec<T>
pub fn scope_with_executor<'env, F, T>( &self, tick_task_pool_executor: bool, external_executor: Option<&ThreadExecutor<'_>>, f: F ) -> Vec<T>
This allows passing an external executor to spawn tasks on. When you pass an external executor
Scope::spawn_on_scope
spawns is then run on the thread that ThreadExecutor
is being ticked on.
If None
is passed the scope will use a ThreadExecutor
that is ticked on the current thread.
When tick_task_pool_executor
is set to true
, the multithreaded task stealing executor is ticked on the scope
thread. Disabling this can be useful when finishing the scope is latency sensitive. Pulling tasks from
global executor can run tasks unrelated to the scope and delay when the scope returns.
See Self::scope
for more details in general about how scopes work.
sourcepub fn spawn<T>(
&self,
future: impl Future<Output = T> + Send + 'static
) -> Task<T> ⓘwhere
T: Send + 'static,
pub fn spawn<T>(
&self,
future: impl Future<Output = T> + Send + 'static
) -> Task<T> ⓘwhere
T: Send + 'static,
Spawns a static future onto the thread pool. The returned Task
is a
future that can be polled for the result. It can also be canceled and
“detached”, allowing the task to continue running even if dropped. In
any case, the pool will execute the task even without polling by the
end-user.
If the provided future is non-Send
, TaskPool::spawn_local
should
be used instead.
sourcepub fn spawn_local<T>(
&self,
future: impl Future<Output = T> + 'static
) -> Task<T> ⓘwhere
T: 'static,
pub fn spawn_local<T>(
&self,
future: impl Future<Output = T> + 'static
) -> Task<T> ⓘwhere
T: 'static,
Spawns a static future on the thread-local async executor for the current thread. The task will run entirely on the thread the task was spawned on.
The returned Task
is a future that can be polled for the
result. It can also be canceled and “detached”, allowing the task to
continue running even if dropped. In any case, the pool will execute the
task even without polling by the end-user.
Users should generally prefer to use TaskPool::spawn
instead,
unless the provided future is not Send
.
sourcepub fn with_local_executor<F, R>(&self, f: F) -> Rwhere
F: FnOnce(&LocalExecutor<'_>) -> R,
pub fn with_local_executor<F, R>(&self, f: F) -> Rwhere
F: FnOnce(&LocalExecutor<'_>) -> R,
Runs a function with the local executor. Typically used to tick the local executor on the main thread as it needs to share time with other things.
use bevy_tasks::TaskPool;
TaskPool::new().with_local_executor(|local_executor| {
local_executor.try_tick();
});
Trait Implementations§
source§impl Debug for AsyncComputeTaskPool
impl Debug for AsyncComputeTaskPool
Auto Trait Implementations§
impl !RefUnwindSafe for AsyncComputeTaskPool
impl Send for AsyncComputeTaskPool
impl Sync for AsyncComputeTaskPool
impl Unpin for AsyncComputeTaskPool
impl !UnwindSafe for AsyncComputeTaskPool
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