bevy/crates/bevy_tasks/src/task_pool.rs

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use std::{
future::Future,
mem,
pin::Pin,
sync::Arc,
thread::{self, JoinHandle},
};
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use futures_lite::{future, pin};
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use crate::Task;
/// Used to create a TaskPool
#[derive(Debug, Default, Clone)]
pub struct TaskPoolBuilder {
/// If set, we'll set up the thread pool to use at most n threads. Otherwise use
/// the logical core count of the system
num_threads: Option<usize>,
/// If set, we'll use the given stack size rather than the system default
stack_size: Option<usize>,
/// Allows customizing the name of the threads - helpful for debugging. If set, threads will
/// be named <thread_name> (<thread_index>), i.e. "MyThreadPool (2)"
thread_name: Option<String>,
}
impl TaskPoolBuilder {
/// Creates a new TaskPoolBuilder instance
pub fn new() -> Self {
Self::default()
}
/// Override the number of threads created for the pool. If unset, we default to the number
/// of logical cores of the system
pub fn num_threads(mut self, num_threads: usize) -> Self {
self.num_threads = Some(num_threads);
self
}
/// Override the stack size of the threads created for the pool
pub fn stack_size(mut self, stack_size: usize) -> Self {
self.stack_size = Some(stack_size);
self
}
/// Override the name of the threads created for the pool. If set, threads will
/// be named <thread_name> (<thread_index>), i.e. "MyThreadPool (2)"
pub fn thread_name(mut self, thread_name: String) -> Self {
self.thread_name = Some(thread_name);
self
}
/// Creates a new ThreadPoolBuilder based on the current options.
pub fn build(self) -> TaskPool {
TaskPool::new_internal(
self.num_threads,
self.stack_size,
self.thread_name.as_deref(),
)
}
}
#[derive(Debug)]
struct TaskPoolInner {
threads: Vec<JoinHandle<()>>,
shutdown_tx: async_channel::Sender<()>,
}
impl Drop for TaskPoolInner {
fn drop(&mut self) {
self.shutdown_tx.close();
for join_handle in self.threads.drain(..) {
join_handle
.join()
.expect("task thread panicked while executing");
}
}
}
/// A thread pool for executing tasks. Tasks are futures that are being automatically driven by
/// the pool on threads owned by the pool.
#[derive(Debug, Clone)]
pub struct TaskPool {
/// The executor for the pool
///
/// This has to be separate from TaskPoolInner because we have to create an Arc<Executor> to
/// pass into the worker threads, and we must create the worker threads before we can create the
/// Vec<Task<T>> contained within TaskPoolInner
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executor: Arc<async_executor::Executor<'static>>,
/// Inner state of the pool
inner: Arc<TaskPoolInner>,
}
impl TaskPool {
/// Create a `TaskPool` with the default configuration.
pub fn new() -> Self {
TaskPoolBuilder::new().build()
}
fn new_internal(
num_threads: Option<usize>,
stack_size: Option<usize>,
thread_name: Option<&str>,
) -> Self {
let (shutdown_tx, shutdown_rx) = async_channel::unbounded::<()>();
let executor = Arc::new(async_executor::Executor::new());
let num_threads = num_threads.unwrap_or_else(num_cpus::get);
let threads = (0..num_threads)
.map(|i| {
let ex = Arc::clone(&executor);
let shutdown_rx = shutdown_rx.clone();
let thread_name = if let Some(thread_name) = thread_name {
format!("{} ({})", thread_name, i)
} else {
format!("TaskPool ({})", i)
};
let mut thread_builder = thread::Builder::new().name(thread_name);
if let Some(stack_size) = stack_size {
thread_builder = thread_builder.stack_size(stack_size);
}
thread_builder
.spawn(move || {
let shutdown_future = ex.run(shutdown_rx.recv());
// Use unwrap_err because we expect a Closed error
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future::block_on(shutdown_future).unwrap_err();
})
.expect("failed to spawn thread")
})
.collect();
Self {
executor,
inner: Arc::new(TaskPoolInner {
threads,
shutdown_tx,
}),
}
}
/// Return the number of threads owned by the task pool
pub fn thread_num(&self) -> usize {
self.inner.threads.len()
}
/// 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 `rayon::scope` and `crossbeam::scope`
pub fn scope<'scope, F, T>(&self, f: F) -> Vec<T>
where
F: FnOnce(&mut Scope<'scope, T>) + 'scope + Send,
T: Send + 'static,
{
// SAFETY: This function blocks until all futures complete, so this future must return
// before this function returns. However, rust has no way of knowing
// this so we must convert to 'static here to appease the compiler as it is unable to
// validate safety.
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let executor: &async_executor::Executor = &*self.executor;
let executor: &'scope async_executor::Executor = unsafe { mem::transmute(executor) };
let fut = async move {
let mut scope = Scope {
executor,
spawned: Vec::new(),
};
f(&mut scope);
let mut results = Vec::with_capacity(scope.spawned.len());
for task in scope.spawned {
results.push(task.await);
}
results
};
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// Pin the future on the stack.
pin!(fut);
// SAFETY: This function blocks until all futures complete, so we do not read/write the
// data from futures outside of the 'scope lifetime. However, rust has no way of knowing
// this so we must convert to 'static here to appease the compiler as it is unable to
// validate safety.
let fut: Pin<&mut (dyn Future<Output = Vec<T>> + Send)> = fut;
let fut: Pin<&'static mut (dyn Future<Output = Vec<T>> + Send + 'static)> =
unsafe { mem::transmute(fut) };
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future::block_on(self.executor.spawn(fut))
}
/// Spawns a static future onto the thread pool. The returned Task is a future. It can also be
/// cancelled and "detached" allowing it to continue running without having to be polled by the
/// end-user.
pub fn spawn<T>(&self, future: impl Future<Output = T> + Send + 'static) -> Task<T>
where
T: Send + 'static,
{
Task::new(self.executor.spawn(future))
}
}
impl Default for TaskPool {
fn default() -> Self {
Self::new()
}
}
#[derive(Debug)]
pub struct Scope<'scope, T> {
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executor: &'scope async_executor::Executor<'scope>,
spawned: Vec<async_executor::Task<T>>,
}
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impl<'scope, T: Send + 'scope> Scope<'scope, T> {
pub fn spawn<Fut: Future<Output = T> + 'scope + Send>(&mut self, f: Fut) {
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let task = self.executor.spawn(f);
self.spawned.push(task);
}
}
#[cfg(test)]
mod tests {
use super::*;
use std::sync::atomic::{AtomicI32, Ordering};
#[test]
pub fn test_spawn() {
let pool = TaskPool::new();
let foo = Box::new(42);
let foo = &*foo;
let count = Arc::new(AtomicI32::new(0));
let outputs = pool.scope(|scope| {
for _ in 0..100 {
let count_clone = count.clone();
scope.spawn(async move {
if *foo != 42 {
panic!("not 42!?!?")
} else {
count_clone.fetch_add(1, Ordering::Relaxed);
*foo
}
});
}
});
for output in &outputs {
assert_eq!(*output, 42);
}
assert_eq!(outputs.len(), 100);
assert_eq!(count.load(Ordering::Relaxed), 100);
}
}