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//! Methods for custom fork-join scopes, created by the [`scope()`]
//! and [`in_place_scope()`] functions. These are a more flexible alternative to [`join()`].
//!
//! [`scope()`]: fn.scope.html
//! [`in_place_scope()`]: fn.in_place_scope.html
//! [`join()`]: ../join/join.fn.html
use crate::broadcast::BroadcastContext;
use crate::job::{ArcJob, HeapJob, JobFifo, JobRef};
use crate::latch::{CountLatch, CountLockLatch, Latch};
use crate::registry::{global_registry, in_worker, Registry, WorkerThread};
use crate::tlv::{self, Tlv};
use crate::unwind;
use std::any::Any;
use std::fmt;
use std::marker::PhantomData;
use std::mem::ManuallyDrop;
use std::ptr;
use std::sync::atomic::{AtomicPtr, Ordering};
use std::sync::Arc;
#[cfg(test)]
mod test;
/// Represents a fork-join scope which can be used to spawn any number of tasks.
/// See [`scope()`] for more information.
///
///[`scope()`]: fn.scope.html
pub struct Scope<'scope> {
base: ScopeBase<'scope>,
}
/// Represents a fork-join scope which can be used to spawn any number of tasks.
/// Those spawned from the same thread are prioritized in relative FIFO order.
/// See [`scope_fifo()`] for more information.
///
///[`scope_fifo()`]: fn.scope_fifo.html
pub struct ScopeFifo<'scope> {
base: ScopeBase<'scope>,
fifos: Vec<JobFifo>,
}
pub(super) enum ScopeLatch {
/// A latch for scopes created on a rayon thread which will participate in work-
/// stealing while it waits for completion. This thread is not necessarily part
/// of the same registry as the scope itself!
Stealing {
latch: CountLatch,
/// If a worker thread in registry A calls `in_place_scope` on a ThreadPool
/// with registry B, when a job completes in a thread of registry B, we may
/// need to call `latch.set_and_tickle_one()` to wake the thread in registry A.
/// That means we need a reference to registry A (since at that point we will
/// only have a reference to registry B), so we stash it here.
registry: Arc<Registry>,
/// The index of the worker to wake in `registry`
worker_index: usize,
},
/// A latch for scopes created on a non-rayon thread which will block to wait.
Blocking { latch: CountLockLatch },
}
struct ScopeBase<'scope> {
/// thread registry where `scope()` was executed or where `in_place_scope()`
/// should spawn jobs.
registry: Arc<Registry>,
/// if some job panicked, the error is stored here; it will be
/// propagated to the one who created the scope
panic: AtomicPtr<Box<dyn Any + Send + 'static>>,
/// latch to track job counts
job_completed_latch: ScopeLatch,
/// You can think of a scope as containing a list of closures to execute,
/// all of which outlive `'scope`. They're not actually required to be
/// `Sync`, but it's still safe to let the `Scope` implement `Sync` because
/// the closures are only *moved* across threads to be executed.
marker: PhantomData<Box<dyn FnOnce(&Scope<'scope>) + Send + Sync + 'scope>>,
/// The TLV at the scope's creation. Used to set the TLV for spawned jobs.
tlv: Tlv,
}
/// Creates a "fork-join" scope `s` and invokes the closure with a
/// reference to `s`. This closure can then spawn asynchronous tasks
/// into `s`. Those tasks may run asynchronously with respect to the
/// closure; they may themselves spawn additional tasks into `s`. When
/// the closure returns, it will block until all tasks that have been
/// spawned into `s` complete.
///
/// `scope()` is a more flexible building block compared to `join()`,
/// since a loop can be used to spawn any number of tasks without
/// recursing. However, that flexibility comes at a performance price:
/// tasks spawned using `scope()` must be allocated onto the heap,
/// whereas `join()` can make exclusive use of the stack. **Prefer
/// `join()` (or, even better, parallel iterators) where possible.**
///
/// # Example
///
/// The Rayon `join()` function launches two closures and waits for them
/// to stop. One could implement `join()` using a scope like so, although
/// it would be less efficient than the real implementation:
///
/// ```rust
/// # use rayon_core as rayon;
/// pub fn join<A,B,RA,RB>(oper_a: A, oper_b: B) -> (RA, RB)
/// where A: FnOnce() -> RA + Send,
/// B: FnOnce() -> RB + Send,
/// RA: Send,
/// RB: Send,
/// {
/// let mut result_a: Option<RA> = None;
/// let mut result_b: Option<RB> = None;
/// rayon::scope(|s| {
/// s.spawn(|_| result_a = Some(oper_a()));
/// s.spawn(|_| result_b = Some(oper_b()));
/// });
/// (result_a.unwrap(), result_b.unwrap())
/// }
/// ```
///
/// # A note on threading
///
/// The closure given to `scope()` executes in the Rayon thread-pool,
/// as do those given to `spawn()`. This means that you can't access
/// thread-local variables (well, you can, but they may have
/// unexpected values).
///
/// # Task execution
///
/// Task execution potentially starts as soon as `spawn()` is called.
/// The task will end sometime before `scope()` returns. Note that the
/// *closure* given to scope may return much earlier. In general
/// the lifetime of a scope created like `scope(body)` goes something like this:
///
/// - Scope begins when `scope(body)` is called
/// - Scope body `body()` is invoked
/// - Scope tasks may be spawned
/// - Scope body returns
/// - Scope tasks execute, possibly spawning more tasks
/// - Once all tasks are done, scope ends and `scope()` returns
///
/// To see how and when tasks are joined, consider this example:
///
/// ```rust
/// # use rayon_core as rayon;
/// // point start
/// rayon::scope(|s| {
/// s.spawn(|s| { // task s.1
/// s.spawn(|s| { // task s.1.1
/// rayon::scope(|t| {
/// t.spawn(|_| ()); // task t.1
/// t.spawn(|_| ()); // task t.2
/// });
/// });
/// });
/// s.spawn(|s| { // task s.2
/// });
/// // point mid
/// });
/// // point end
/// ```
///
/// The various tasks that are run will execute roughly like so:
///
/// ```notrust
/// | (start)
/// |
/// | (scope `s` created)
/// +-----------------------------------------------+ (task s.2)
/// +-------+ (task s.1) |
/// | | |
/// | +---+ (task s.1.1) |
/// | | | |
/// | | | (scope `t` created) |
/// | | +----------------+ (task t.2) |
/// | | +---+ (task t.1) | |
/// | (mid) | | | | |
/// : | + <-+------------+ (scope `t` ends) |
/// : | | |
/// |<------+---+-----------------------------------+ (scope `s` ends)
/// |
/// | (end)
/// ```
///
/// The point here is that everything spawned into scope `s` will
/// terminate (at latest) at the same point -- right before the
/// original call to `rayon::scope` returns. This includes new
/// subtasks created by other subtasks (e.g., task `s.1.1`). If a new
/// scope is created (such as `t`), the things spawned into that scope
/// will be joined before that scope returns, which in turn occurs
/// before the creating task (task `s.1.1` in this case) finishes.
///
/// There is no guaranteed order of execution for spawns in a scope,
/// given that other threads may steal tasks at any time. However, they
/// are generally prioritized in a LIFO order on the thread from which
/// they were spawned. So in this example, absent any stealing, we can
/// expect `s.2` to execute before `s.1`, and `t.2` before `t.1`. Other
/// threads always steal from the other end of the deque, like FIFO
/// order. The idea is that "recent" tasks are most likely to be fresh
/// in the local CPU's cache, while other threads can steal older
/// "stale" tasks. For an alternate approach, consider
/// [`scope_fifo()`] instead.
///
/// [`scope_fifo()`]: fn.scope_fifo.html
///
/// # Accessing stack data
///
/// In general, spawned tasks may access stack data in place that
/// outlives the scope itself. Other data must be fully owned by the
/// spawned task.
///
/// ```rust
/// # use rayon_core as rayon;
/// let ok: Vec<i32> = vec![1, 2, 3];
/// rayon::scope(|s| {
/// let bad: Vec<i32> = vec![4, 5, 6];
/// s.spawn(|_| {
/// // We can access `ok` because outlives the scope `s`.
/// println!("ok: {:?}", ok);
///
/// // If we just try to use `bad` here, the closure will borrow `bad`
/// // (because we are just printing it out, and that only requires a
/// // borrow), which will result in a compilation error. Read on
/// // for options.
/// // println!("bad: {:?}", bad);
/// });
/// });
/// ```
///
/// As the comments example above suggest, to reference `bad` we must
/// take ownership of it. One way to do this is to detach the closure
/// from the surrounding stack frame, using the `move` keyword. This
/// will cause it to take ownership of *all* the variables it touches,
/// in this case including both `ok` *and* `bad`:
///
/// ```rust
/// # use rayon_core as rayon;
/// let ok: Vec<i32> = vec![1, 2, 3];
/// rayon::scope(|s| {
/// let bad: Vec<i32> = vec![4, 5, 6];
/// s.spawn(move |_| {
/// println!("ok: {:?}", ok);
/// println!("bad: {:?}", bad);
/// });
///
/// // That closure is fine, but now we can't use `ok` anywhere else,
/// // since it is owned by the previous task:
/// // s.spawn(|_| println!("ok: {:?}", ok));
/// });
/// ```
///
/// While this works, it could be a problem if we want to use `ok` elsewhere.
/// There are two choices. We can keep the closure as a `move` closure, but
/// instead of referencing the variable `ok`, we create a shadowed variable that
/// is a borrow of `ok` and capture *that*:
///
/// ```rust
/// # use rayon_core as rayon;
/// let ok: Vec<i32> = vec![1, 2, 3];
/// rayon::scope(|s| {
/// let bad: Vec<i32> = vec![4, 5, 6];
/// let ok: &Vec<i32> = &ok; // shadow the original `ok`
/// s.spawn(move |_| {
/// println!("ok: {:?}", ok); // captures the shadowed version
/// println!("bad: {:?}", bad);
/// });
///
/// // Now we too can use the shadowed `ok`, since `&Vec<i32>` references
/// // can be shared freely. Note that we need a `move` closure here though,
/// // because otherwise we'd be trying to borrow the shadowed `ok`,
/// // and that doesn't outlive `scope`.
/// s.spawn(move |_| println!("ok: {:?}", ok));
/// });
/// ```
///
/// Another option is not to use the `move` keyword but instead to take ownership
/// of individual variables:
///
/// ```rust
/// # use rayon_core as rayon;
/// let ok: Vec<i32> = vec![1, 2, 3];
/// rayon::scope(|s| {
/// let bad: Vec<i32> = vec![4, 5, 6];
/// s.spawn(|_| {
/// // Transfer ownership of `bad` into a local variable (also named `bad`).
/// // This will force the closure to take ownership of `bad` from the environment.
/// let bad = bad;
/// println!("ok: {:?}", ok); // `ok` is only borrowed.
/// println!("bad: {:?}", bad); // refers to our local variable, above.
/// });
///
/// s.spawn(|_| println!("ok: {:?}", ok)); // we too can borrow `ok`
/// });
/// ```
///
/// # Panics
///
/// If a panic occurs, either in the closure given to `scope()` or in
/// any of the spawned jobs, that panic will be propagated and the
/// call to `scope()` will panic. If multiple panics occurs, it is
/// non-deterministic which of their panic values will propagate.
/// Regardless, once a task is spawned using `scope.spawn()`, it will
/// execute, even if the spawning task should later panic. `scope()`
/// returns once all spawned jobs have completed, and any panics are
/// propagated at that point.
pub fn scope<'scope, OP, R>(op: OP) -> R
where
OP: FnOnce(&Scope<'scope>) -> R + Send,
R: Send,
{
in_worker(|owner_thread, _| {
let scope = Scope::<'scope>::new(Some(owner_thread), None);
scope.base.complete(Some(owner_thread), || op(&scope))
})
}
/// Creates a "fork-join" scope `s` with FIFO order, and invokes the
/// closure with a reference to `s`. This closure can then spawn
/// asynchronous tasks into `s`. Those tasks may run asynchronously with
/// respect to the closure; they may themselves spawn additional tasks
/// into `s`. When the closure returns, it will block until all tasks
/// that have been spawned into `s` complete.
///
/// # Task execution
///
/// Tasks in a `scope_fifo()` run similarly to [`scope()`], but there's a
/// difference in the order of execution. Consider a similar example:
///
/// [`scope()`]: fn.scope.html
///
/// ```rust
/// # use rayon_core as rayon;
/// // point start
/// rayon::scope_fifo(|s| {
/// s.spawn_fifo(|s| { // task s.1
/// s.spawn_fifo(|s| { // task s.1.1
/// rayon::scope_fifo(|t| {
/// t.spawn_fifo(|_| ()); // task t.1
/// t.spawn_fifo(|_| ()); // task t.2
/// });
/// });
/// });
/// s.spawn_fifo(|s| { // task s.2
/// });
/// // point mid
/// });
/// // point end
/// ```
///
/// The various tasks that are run will execute roughly like so:
///
/// ```notrust
/// | (start)
/// |
/// | (FIFO scope `s` created)
/// +--------------------+ (task s.1)
/// +-------+ (task s.2) |
/// | | +---+ (task s.1.1)
/// | | | |
/// | | | | (FIFO scope `t` created)
/// | | | +----------------+ (task t.1)
/// | | | +---+ (task t.2) |
/// | (mid) | | | | |
/// : | | + <-+------------+ (scope `t` ends)
/// : | | |
/// |<------+------------+---+ (scope `s` ends)
/// |
/// | (end)
/// ```
///
/// Under `scope_fifo()`, the spawns are prioritized in a FIFO order on
/// the thread from which they were spawned, as opposed to `scope()`'s
/// LIFO. So in this example, we can expect `s.1` to execute before
/// `s.2`, and `t.1` before `t.2`. Other threads also steal tasks in
/// FIFO order, as usual. Overall, this has roughly the same order as
/// the now-deprecated [`breadth_first`] option, except the effect is
/// isolated to a particular scope. If spawns are intermingled from any
/// combination of `scope()` and `scope_fifo()`, or from different
/// threads, their order is only specified with respect to spawns in the
/// same scope and thread.
///
/// For more details on this design, see Rayon [RFC #1].
///
/// [`breadth_first`]: struct.ThreadPoolBuilder.html#method.breadth_first
/// [RFC #1]: https://github.com/rayon-rs/rfcs/blob/master/accepted/rfc0001-scope-scheduling.md
///
/// # Panics
///
/// If a panic occurs, either in the closure given to `scope_fifo()` or
/// in any of the spawned jobs, that panic will be propagated and the
/// call to `scope_fifo()` will panic. If multiple panics occurs, it is
/// non-deterministic which of their panic values will propagate.
/// Regardless, once a task is spawned using `scope.spawn_fifo()`, it
/// will execute, even if the spawning task should later panic.
/// `scope_fifo()` returns once all spawned jobs have completed, and any
/// panics are propagated at that point.
pub fn scope_fifo<'scope, OP, R>(op: OP) -> R
where
OP: FnOnce(&ScopeFifo<'scope>) -> R + Send,
R: Send,
{
in_worker(|owner_thread, _| {
let scope = ScopeFifo::<'scope>::new(Some(owner_thread), None);
scope.base.complete(Some(owner_thread), || op(&scope))
})
}
/// Creates a "fork-join" scope `s` and invokes the closure with a
/// reference to `s`. This closure can then spawn asynchronous tasks
/// into `s`. Those tasks may run asynchronously with respect to the
/// closure; they may themselves spawn additional tasks into `s`. When
/// the closure returns, it will block until all tasks that have been
/// spawned into `s` complete.
///
/// This is just like `scope()` except the closure runs on the same thread
/// that calls `in_place_scope()`. Only work that it spawns runs in the
/// thread pool.
///
/// # Panics
///
/// If a panic occurs, either in the closure given to `in_place_scope()` or in
/// any of the spawned jobs, that panic will be propagated and the
/// call to `in_place_scope()` will panic. If multiple panics occurs, it is
/// non-deterministic which of their panic values will propagate.
/// Regardless, once a task is spawned using `scope.spawn()`, it will
/// execute, even if the spawning task should later panic. `in_place_scope()`
/// returns once all spawned jobs have completed, and any panics are
/// propagated at that point.
pub fn in_place_scope<'scope, OP, R>(op: OP) -> R
where
OP: FnOnce(&Scope<'scope>) -> R,
{
do_in_place_scope(None, op)
}
pub(crate) fn do_in_place_scope<'scope, OP, R>(registry: Option<&Arc<Registry>>, op: OP) -> R
where
OP: FnOnce(&Scope<'scope>) -> R,
{
let thread = unsafe { WorkerThread::current().as_ref() };
let scope = Scope::<'scope>::new(thread, registry);
scope.base.complete(thread, || op(&scope))
}
/// Creates a "fork-join" scope `s` with FIFO order, and invokes the
/// closure with a reference to `s`. This closure can then spawn
/// asynchronous tasks into `s`. Those tasks may run asynchronously with
/// respect to the closure; they may themselves spawn additional tasks
/// into `s`. When the closure returns, it will block until all tasks
/// that have been spawned into `s` complete.
///
/// This is just like `scope_fifo()` except the closure runs on the same thread
/// that calls `in_place_scope_fifo()`. Only work that it spawns runs in the
/// thread pool.
///
/// # Panics
///
/// If a panic occurs, either in the closure given to `in_place_scope_fifo()` or in
/// any of the spawned jobs, that panic will be propagated and the
/// call to `in_place_scope_fifo()` will panic. If multiple panics occurs, it is
/// non-deterministic which of their panic values will propagate.
/// Regardless, once a task is spawned using `scope.spawn_fifo()`, it will
/// execute, even if the spawning task should later panic. `in_place_scope_fifo()`
/// returns once all spawned jobs have completed, and any panics are
/// propagated at that point.
pub fn in_place_scope_fifo<'scope, OP, R>(op: OP) -> R
where
OP: FnOnce(&ScopeFifo<'scope>) -> R,
{
do_in_place_scope_fifo(None, op)
}
pub(crate) fn do_in_place_scope_fifo<'scope, OP, R>(registry: Option<&Arc<Registry>>, op: OP) -> R
where
OP: FnOnce(&ScopeFifo<'scope>) -> R,
{
let thread = unsafe { WorkerThread::current().as_ref() };
let scope = ScopeFifo::<'scope>::new(thread, registry);
scope.base.complete(thread, || op(&scope))
}
impl<'scope> Scope<'scope> {
fn new(owner: Option<&WorkerThread>, registry: Option<&Arc<Registry>>) -> Self {
let base = ScopeBase::new(owner, registry);
Scope { base }
}
/// Spawns a job into the fork-join scope `self`. This job will
/// execute sometime before the fork-join scope completes. The
/// job is specified as a closure, and this closure receives its
/// own reference to the scope `self` as argument. This can be
/// used to inject new jobs into `self`.
///
/// # Returns
///
/// Nothing. The spawned closures cannot pass back values to the
/// caller directly, though they can write to local variables on
/// the stack (if those variables outlive the scope) or
/// communicate through shared channels.
///
/// (The intention is to eventually integrate with Rust futures to
/// support spawns of functions that compute a value.)
///
/// # Examples
///
/// ```rust
/// # use rayon_core as rayon;
/// let mut value_a = None;
/// let mut value_b = None;
/// let mut value_c = None;
/// rayon::scope(|s| {
/// s.spawn(|s1| {
/// // ^ this is the same scope as `s`; this handle `s1`
/// // is intended for use by the spawned task,
/// // since scope handles cannot cross thread boundaries.
///
/// value_a = Some(22);
///
/// // the scope `s` will not end until all these tasks are done
/// s1.spawn(|_| {
/// value_b = Some(44);
/// });
/// });
///
/// s.spawn(|_| {
/// value_c = Some(66);
/// });
/// });
/// assert_eq!(value_a, Some(22));
/// assert_eq!(value_b, Some(44));
/// assert_eq!(value_c, Some(66));
/// ```
///
/// # See also
///
/// The [`scope` function] has more extensive documentation about
/// task spawning.
///
/// [`scope` function]: fn.scope.html
pub fn spawn<BODY>(&self, body: BODY)
where
BODY: FnOnce(&Scope<'scope>) + Send + 'scope,
{
let scope_ptr = ScopePtr(self);
let job = HeapJob::new(self.base.tlv, move || unsafe {
// SAFETY: this job will execute before the scope ends.
let scope = scope_ptr.as_ref();
ScopeBase::execute_job(&scope.base, move || body(scope))
});
let job_ref = self.base.heap_job_ref(job);
// Since `Scope` implements `Sync`, we can't be sure that we're still in a
// thread of this pool, so we can't just push to the local worker thread.
// Also, this might be an in-place scope.
self.base.registry.inject_or_push(job_ref);
}
/// Spawns a job into every thread of the fork-join scope `self`. This job will
/// execute on each thread sometime before the fork-join scope completes. The
/// job is specified as a closure, and this closure receives its own reference
/// to the scope `self` as argument, as well as a `BroadcastContext`.
pub fn spawn_broadcast<BODY>(&self, body: BODY)
where
BODY: Fn(&Scope<'scope>, BroadcastContext<'_>) + Send + Sync + 'scope,
{
let scope_ptr = ScopePtr(self);
let job = ArcJob::new(move || unsafe {
// SAFETY: this job will execute before the scope ends.
let scope = scope_ptr.as_ref();
let body = &body;
let func = move || BroadcastContext::with(move |ctx| body(scope, ctx));
ScopeBase::execute_job(&scope.base, func)
});
self.base.inject_broadcast(job)
}
}
impl<'scope> ScopeFifo<'scope> {
fn new(owner: Option<&WorkerThread>, registry: Option<&Arc<Registry>>) -> Self {
let base = ScopeBase::new(owner, registry);
let num_threads = base.registry.num_threads();
let fifos = (0..num_threads).map(|_| JobFifo::new()).collect();
ScopeFifo { base, fifos }
}
/// Spawns a job into the fork-join scope `self`. This job will
/// execute sometime before the fork-join scope completes. The
/// job is specified as a closure, and this closure receives its
/// own reference to the scope `self` as argument. This can be
/// used to inject new jobs into `self`.
///
/// # See also
///
/// This method is akin to [`Scope::spawn()`], but with a FIFO
/// priority. The [`scope_fifo` function] has more details about
/// this distinction.
///
/// [`Scope::spawn()`]: struct.Scope.html#method.spawn
/// [`scope_fifo` function]: fn.scope_fifo.html
pub fn spawn_fifo<BODY>(&self, body: BODY)
where
BODY: FnOnce(&ScopeFifo<'scope>) + Send + 'scope,
{
let scope_ptr = ScopePtr(self);
let job = HeapJob::new(self.base.tlv, move || unsafe {
// SAFETY: this job will execute before the scope ends.
let scope = scope_ptr.as_ref();
ScopeBase::execute_job(&scope.base, move || body(scope))
});
let job_ref = self.base.heap_job_ref(job);
// If we're in the pool, use our scope's private fifo for this thread to execute
// in a locally-FIFO order. Otherwise, just use the pool's global injector.
match self.base.registry.current_thread() {
Some(worker) => {
let fifo = &self.fifos[worker.index()];
// SAFETY: this job will execute before the scope ends.
unsafe { worker.push(fifo.push(job_ref)) };
}
None => self.base.registry.inject(job_ref),
}
}
/// Spawns a job into every thread of the fork-join scope `self`. This job will
/// execute on each thread sometime before the fork-join scope completes. The
/// job is specified as a closure, and this closure receives its own reference
/// to the scope `self` as argument, as well as a `BroadcastContext`.
pub fn spawn_broadcast<BODY>(&self, body: BODY)
where
BODY: Fn(&ScopeFifo<'scope>, BroadcastContext<'_>) + Send + Sync + 'scope,
{
let scope_ptr = ScopePtr(self);
let job = ArcJob::new(move || unsafe {
// SAFETY: this job will execute before the scope ends.
let scope = scope_ptr.as_ref();
let body = &body;
let func = move || BroadcastContext::with(move |ctx| body(scope, ctx));
ScopeBase::execute_job(&scope.base, func)
});
self.base.inject_broadcast(job)
}
}
impl<'scope> ScopeBase<'scope> {
/// Creates the base of a new scope for the given registry
fn new(owner: Option<&WorkerThread>, registry: Option<&Arc<Registry>>) -> Self {
let registry = registry.unwrap_or_else(|| match owner {
Some(owner) => owner.registry(),
None => global_registry(),
});
ScopeBase {
registry: Arc::clone(registry),
panic: AtomicPtr::new(ptr::null_mut()),
job_completed_latch: ScopeLatch::new(owner),
marker: PhantomData,
tlv: tlv::get(),
}
}
fn increment(&self) {
self.job_completed_latch.increment();
}
fn heap_job_ref<FUNC>(&self, job: Box<HeapJob<FUNC>>) -> JobRef
where
FUNC: FnOnce() + Send + 'scope,
{
unsafe {
self.increment();
job.into_job_ref()
}
}
fn inject_broadcast<FUNC>(&self, job: Arc<ArcJob<FUNC>>)
where
FUNC: Fn() + Send + Sync + 'scope,
{
let n_threads = self.registry.num_threads();
let job_refs = (0..n_threads).map(|_| unsafe {
self.increment();
ArcJob::as_job_ref(&job)
});
self.registry.inject_broadcast(job_refs);
}
/// Executes `func` as a job, either aborting or executing as
/// appropriate.
fn complete<FUNC, R>(&self, owner: Option<&WorkerThread>, func: FUNC) -> R
where
FUNC: FnOnce() -> R,
{
let result = unsafe { Self::execute_job_closure(self, func) };
self.job_completed_latch.wait(owner);
// Restore the TLV if we ran some jobs while waiting
tlv::set(self.tlv);
self.maybe_propagate_panic();
result.unwrap() // only None if `op` panicked, and that would have been propagated
}
/// Executes `func` as a job, either aborting or executing as
/// appropriate.
unsafe fn execute_job<FUNC>(this: *const Self, func: FUNC)
where
FUNC: FnOnce(),
{
let _: Option<()> = Self::execute_job_closure(this, func);
}
/// Executes `func` as a job in scope. Adjusts the "job completed"
/// counters and also catches any panic and stores it into
/// `scope`.
unsafe fn execute_job_closure<FUNC, R>(this: *const Self, func: FUNC) -> Option<R>
where
FUNC: FnOnce() -> R,
{
match unwind::halt_unwinding(func) {
Ok(r) => {
Latch::set(&(*this).job_completed_latch);
Some(r)
}
Err(err) => {
(*this).job_panicked(err);
Latch::set(&(*this).job_completed_latch);
None
}
}
}
fn job_panicked(&self, err: Box<dyn Any + Send + 'static>) {
// capture the first error we see, free the rest
if self.panic.load(Ordering::Relaxed).is_null() {
let nil = ptr::null_mut();
let mut err = ManuallyDrop::new(Box::new(err)); // box up the fat ptr
let err_ptr: *mut Box<dyn Any + Send + 'static> = &mut **err;
if self
.panic
.compare_exchange(nil, err_ptr, Ordering::Release, Ordering::Relaxed)
.is_ok()
{
// ownership now transferred into self.panic
} else {
// another panic raced in ahead of us, so drop ours
let _: Box<Box<_>> = ManuallyDrop::into_inner(err);
}
}
}
fn maybe_propagate_panic(&self) {
// propagate panic, if any occurred; at this point, all
// outstanding jobs have completed, so we can use a relaxed
// ordering:
let panic = self.panic.swap(ptr::null_mut(), Ordering::Relaxed);
if !panic.is_null() {
let value = unsafe { Box::from_raw(panic) };
// Restore the TLV if we ran some jobs while waiting
tlv::set(self.tlv);
unwind::resume_unwinding(*value);
}
}
}
impl ScopeLatch {
fn new(owner: Option<&WorkerThread>) -> Self {
Self::with_count(1, owner)
}
pub(super) fn with_count(count: usize, owner: Option<&WorkerThread>) -> Self {
match owner {
Some(owner) => ScopeLatch::Stealing {
latch: CountLatch::with_count(count),
registry: Arc::clone(owner.registry()),
worker_index: owner.index(),
},
None => ScopeLatch::Blocking {
latch: CountLockLatch::with_count(count),
},
}
}
fn increment(&self) {
match self {
ScopeLatch::Stealing { latch, .. } => latch.increment(),
ScopeLatch::Blocking { latch } => latch.increment(),
}
}
pub(super) fn wait(&self, owner: Option<&WorkerThread>) {
match self {
ScopeLatch::Stealing {
latch,
registry,
worker_index,
} => unsafe {
let owner = owner.expect("owner thread");
debug_assert_eq!(registry.id(), owner.registry().id());
debug_assert_eq!(*worker_index, owner.index());
owner.wait_until(latch);
},
ScopeLatch::Blocking { latch } => latch.wait(),
}
}
}
impl Latch for ScopeLatch {
unsafe fn set(this: *const Self) {
match &*this {
ScopeLatch::Stealing {
latch,
registry,
worker_index,
} => CountLatch::set_and_tickle_one(latch, registry, *worker_index),
ScopeLatch::Blocking { latch } => Latch::set(latch),
}
}
}
impl<'scope> fmt::Debug for Scope<'scope> {
fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt.debug_struct("Scope")
.field("pool_id", &self.base.registry.id())
.field("panic", &self.base.panic)
.field("job_completed_latch", &self.base.job_completed_latch)
.finish()
}
}
impl<'scope> fmt::Debug for ScopeFifo<'scope> {
fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt.debug_struct("ScopeFifo")
.field("num_fifos", &self.fifos.len())
.field("pool_id", &self.base.registry.id())
.field("panic", &self.base.panic)
.field("job_completed_latch", &self.base.job_completed_latch)
.finish()
}
}
impl fmt::Debug for ScopeLatch {
fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result {
match self {
ScopeLatch::Stealing { latch, .. } => fmt
.debug_tuple("ScopeLatch::Stealing")
.field(latch)
.finish(),
ScopeLatch::Blocking { latch } => fmt
.debug_tuple("ScopeLatch::Blocking")
.field(latch)
.finish(),
}
}
}
/// Used to capture a scope `&Self` pointer in jobs, without faking a lifetime.
///
/// Unsafe code is still required to dereference the pointer, but that's fine in
/// scope jobs that are guaranteed to execute before the scope ends.
struct ScopePtr<T>(*const T);
// SAFETY: !Send for raw pointers is not for safety, just as a lint
unsafe impl<T: Sync> Send for ScopePtr<T> {}
// SAFETY: !Sync for raw pointers is not for safety, just as a lint
unsafe impl<T: Sync> Sync for ScopePtr<T> {}
impl<T> ScopePtr<T> {
// Helper to avoid disjoint captures of `scope_ptr.0`
unsafe fn as_ref(&self) -> &T {
&*self.0
}
}