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Spracherkennung für: .rs vermutete Sprache: Unknown {[0] [0] [0]} [Methode: Schwerpunktbildung, einfache Gewichte, sechs Dimensionen] //! Runs `!Send` futures on the current thread.
use crate::loom::cell::UnsafeCell; use crate::loom::sync::{Arc, Mutex}; #[cfg(tokio_unstable)] use crate::runtime; use crate::runtime::task::{self, JoinHandle, LocalOwnedTasks, Task}; use crate::runtime::{context, ThreadId, BOX_FUTURE_THRESHOLD}; use crate::sync::AtomicWaker; use crate::util::RcCell; use std::cell::Cell; use std::collections::VecDeque; use std::fmt; use std::future::Future; use std::marker::PhantomData; use std::pin::Pin; use std::rc::Rc; use std::task::Poll; use pin_project_lite::pin_project; cfg_rt! { /// A set of tasks which are executed on the same thread. /// /// In some cases, it is necessary to run one or more futures that do not /// implement [`Send`] and thus are unsafe to send between threads. In these /// cases, a [local task set] may be used to schedule one or more `!Send` /// futures to run together on the same thread. /// /// For example, the following code will not compile: /// /// ```rust,compile_fail /// use std::rc::Rc; /// /// #[tokio::main] /// async fn main() { /// // `Rc` does not implement `Send`, and thus may not be sent between /// // threads safely. /// let nonsend_data = Rc::new("my nonsend data..."); /// /// let nonsend_data = nonsend_data.clone(); /// // Because the `async` block here moves `nonsend_data`, the future is `!Send`. /// // Since `tokio::spawn` requires the spawned future to implement `Send`, this /// // will not compile. /// tokio::spawn(async move { /// println!("{}", nonsend_data); /// // ... /// }).await.unwrap(); /// } /// ``` /// /// # Use with `run_until` /// /// To spawn `!Send` futures, we can use a local task set to schedule them /// on the thread calling [`Runtime::block_on`]. When running inside of the /// local task set, we can use [`task::spawn_local`], which can spawn /// `!Send` futures. For example: /// /// ```rust /// use std::rc::Rc; /// use tokio::task; /// /// #[tokio::main] /// async fn main() { /// let nonsend_data = Rc::new("my nonsend data..."); /// /// // Construct a local task set that can run `!Send` futures. /// let local = task::LocalSet::new(); /// /// // Run the local task set. /// local.run_until(async move { /// let nonsend_data = nonsend_data.clone(); /// // `spawn_local` ensures that the future is spawned on the local /// // task set. /// task::spawn_local(async move { /// println!("{}", nonsend_data); /// // ... /// }).await.unwrap(); /// }).await; /// } /// ``` /// **Note:** The `run_until` method can only be used in `#[tokio::main]`, /// `#[tokio::test]` or directly inside a call to [`Runtime::block_on`]. It /// cannot be used inside a task spawned with `tokio::spawn`. /// /// ## Awaiting a `LocalSet` /// /// Additionally, a `LocalSet` itself implements `Future`, completing when /// *all* tasks spawned on the `LocalSet` complete. This can be used to run /// several futures on a `LocalSet` and drive the whole set until they /// complete. For example, /// /// ```rust /// use tokio::{task, time}; /// use std::rc::Rc; /// /// #[tokio::main] /// async fn main() { /// let nonsend_data = Rc::new("world"); /// let local = task::LocalSet::new(); /// /// let nonsend_data2 = nonsend_data.clone(); /// local.spawn_local(async move { /// // ... /// println!("hello {}", nonsend_data2) /// }); /// /// local.spawn_local(async move { /// time::sleep(time::Duration::from_millis(100)).await; /// println!("goodbye {}", nonsend_data) /// }); /// /// // ... /// /// local.await; /// } /// ``` /// **Note:** Awaiting a `LocalSet` can only be done inside /// `#[tokio::main]`, `#[tokio::test]` or directly inside a call to /// [`Runtime::block_on`]. It cannot be used inside a task spawned with /// `tokio::spawn`. /// /// ## Use inside `tokio::spawn` /// /// The two methods mentioned above cannot be used inside `tokio::spawn`, so /// to spawn `!Send` futures from inside `tokio::spawn`, we need to do /// something else. The solution is to create the `LocalSet` somewhere else, /// and communicate with it using an [`mpsc`] channel. /// /// The following example puts the `LocalSet` inside a new thread. /// ``` /// use tokio::runtime::Builder; /// use tokio::sync::{mpsc, oneshot}; /// use tokio::task::LocalSet; /// /// // This struct describes the task you want to spawn. Here we include /// // some simple examples. The oneshot channel allows sending a response /// // to the spawner. /// #[derive(Debug)] /// enum Task { /// PrintNumber(u32), /// AddOne(u32, oneshot::Sender<u32>), /// } /// /// #[derive(Clone)] /// struct LocalSpawner { /// send: mpsc::UnboundedSender<Task>, /// } /// /// impl LocalSpawner { /// pub fn new() -> Self { /// let (send, mut recv) = mpsc::unbounded_channel(); /// /// let rt = Builder::new_current_thread() /// .enable_all() /// .build() /// .unwrap(); /// /// std::thread::spawn(move || { /// let local = LocalSet::new(); /// /// local.spawn_local(async move { /// while let Some(new_task) = recv.recv().await { /// tokio::task::spawn_local(run_task(new_task)); /// } /// // If the while loop returns, then all the LocalSpawner /// // objects have been dropped. /// }); /// /// // This will return once all senders are dropped and all /// // spawned tasks have returned. /// rt.block_on(local); /// }); /// /// Self { /// send, /// } /// } /// /// pub fn spawn(&self, task: Task) { /// self.send.send(task).expect("Thread with LocalSet has shut down."); /// } /// } /// /// // This task may do !Send stuff. We use printing a number as an example, /// // but it could be anything. /// // /// // The Task struct is an enum to support spawning many different kinds /// // of operations. /// async fn run_task(task: Task) { /// match task { /// Task::PrintNumber(n) => { /// println!("{}", n); /// }, /// Task::AddOne(n, response) => { /// // We ignore failures to send the response. /// let _ = response.send(n + 1); /// }, /// } /// } /// /// #[tokio::main] /// async fn main() { /// let spawner = LocalSpawner::new(); /// /// let (send, response) = oneshot::channel(); /// spawner.spawn(Task::AddOne(10, send)); /// let eleven = response.await.unwrap(); /// assert_eq!(eleven, 11); /// } /// ``` /// /// [`Send`]: trait@std::marker::Send /// [local task set]: struct@LocalSet /// [`Runtime::block_on`]: method@crate::runtime::Runtime::block_on /// [`task::spawn_local`]: fn@spawn_local /// [`mpsc`]: mod@crate::sync::mpsc pub struct LocalSet { /// Current scheduler tick. tick: Cell<u8>, /// State available from thread-local. context: Rc<Context>, /// This type should not be Send. _not_send: PhantomData<*const ()>, } } /// State available from the thread-local. struct Context { /// State shared between threads. shared: Arc<Shared>, /// True if a task panicked without being handled and the local set is /// configured to shutdown on unhandled panic. unhandled_panic: Cell<bool>, } /// `LocalSet` state shared between threads. struct Shared { /// # Safety /// /// This field must *only* be accessed from the thread that owns the /// `LocalSet` (i.e., `Thread::current().id() == owner`). local_state: LocalState, /// Remote run queue sender. queue: Mutex<Option<VecDeque<task::Notified<Arc<Shared>>>>>, /// Wake the `LocalSet` task. waker: AtomicWaker, /// How to respond to unhandled task panics. #[cfg(tokio_unstable)] pub(crate) unhandled_panic: crate::runtime::UnhandledPanic, } /// Tracks the `LocalSet` state that must only be accessed from the thread that /// created the `LocalSet`. struct LocalState { /// The `ThreadId` of the thread that owns the `LocalSet`. owner: ThreadId, /// Local run queue sender and receiver. local_queue: UnsafeCell<VecDeque<task::Notified<Arc<Shared>>>>, /// Collection of all active tasks spawned onto this executor. owned: LocalOwnedTasks<Arc<Shared>>, } pin_project! { #[derive(Debug)] struct RunUntil<'a, F> { local_set: &'a LocalSet, #[pin] future: F, } } tokio_thread_local!(static CURRENT: LocalData = const { LocalData { ctx: RcCell::new(), wake_on_schedule: Cell::new(false), } }); struct LocalData { ctx: RcCell<Context>, wake_on_schedule: Cell<bool>, } impl LocalData { /// Should be called except when we call `LocalSet::enter`. /// Especially when we poll a `LocalSet`. #[must_use = "dropping this guard will reset the entered state"] fn enter(&self, ctx: Rc<Context>) -> LocalDataEnterGuard<'_> { let ctx = self.ctx.replace(Some(ctx)); let wake_on_schedule = self.wake_on_schedule.replace(false); LocalDataEnterGuard { local_data_ref: self, ctx, wake_on_schedule, } } } /// A guard for `LocalData::enter()` struct LocalDataEnterGuard<'a> { local_data_ref: &'a LocalData, ctx: Option<Rc<Context>>, wake_on_schedule: bool, } impl<'a> Drop for LocalDataEnterGuard<'a> { fn drop(&mut self) { self.local_data_ref.ctx.set(self.ctx.take()); self.local_data_ref .wake_on_schedule .set(self.wake_on_schedule) } } cfg_rt! { /// Spawns a `!Send` future on the current [`LocalSet`]. /// /// The spawned future will run on the same thread that called `spawn_local`. /// /// The provided future will start running in the background immediately /// when `spawn_local` is called, even if you don't await the returned /// `JoinHandle`. /// /// # Panics /// /// This function panics if called outside of a [`LocalSet`]. /// /// Note that if [`tokio::spawn`] is used from within a `LocalSet`, the /// resulting new task will _not_ be inside the `LocalSet`, so you must use /// `spawn_local` if you want to stay within the `LocalSet`. /// /// # Examples /// /// ```rust /// use std::rc::Rc; /// use tokio::task; /// /// #[tokio::main] /// async fn main() { /// let nonsend_data = Rc::new("my nonsend data..."); /// /// let local = task::LocalSet::new(); /// /// // Run the local task set. /// local.run_until(async move { /// let nonsend_data = nonsend_data.clone(); /// task::spawn_local(async move { /// println!("{}", nonsend_data); /// // ... /// }).await.unwrap(); /// }).await; /// } /// ``` /// /// [`LocalSet`]: struct@crate::task::LocalSet /// [`tokio::spawn`]: fn@crate::task::spawn #[track_caller] pub fn spawn_local<F>(future: F) -> JoinHandle<F::Output> where F: Future + 'static, F::Output: 'static, { if cfg!(debug_assertions) && std::mem::size_of::<F>() > BOX_FUTURE_THRESHOLD { spawn_local_inner(Box::pin(future), None) } else { spawn_local_inner(future, None) } } #[track_caller] pub(super) fn spawn_local_inner<F>(future: F, name: Option<&str>) -> JoinHandle<F::Output> where F: Future + 'static, F::Output: 'static { match CURRENT.with(|LocalData { ctx, .. }| ctx.get()) { None => panic!("`spawn_local` called from outside of a `task::LocalSet`"), Some(cx) => cx.spawn(future, name) } } } /// Initial queue capacity. const INITIAL_CAPACITY: usize = 64; /// Max number of tasks to poll per tick. const MAX_TASKS_PER_TICK: usize = 61; /// How often it check the remote queue first. const REMOTE_FIRST_INTERVAL: u8 = 31; /// Context guard for `LocalSet` pub struct LocalEnterGuard { ctx: Option<Rc<Context>>, /// Distinguishes whether the context was entered or being polled. /// When we enter it, the value `wake_on_schedule` is set. In this case /// `spawn_local` refers the context, whereas it is not being polled now. wake_on_schedule: bool, } impl Drop for LocalEnterGuard { fn drop(&mut self) { CURRENT.with( |LocalData { ctx, wake_on_schedule, }| { ctx.set(self.ctx.take()); wake_on_schedule.set(self.wake_on_schedule); }, ); } } impl fmt::Debug for LocalEnterGuard { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("LocalEnterGuard").finish() } } impl LocalSet { /// Returns a new local task set. pub fn new() -> LocalSet { let owner = context::thread_id().expect("cannot create LocalSet during thread shutdown") LocalSet { tick: Cell::new(0), context: Rc::new(Context { shared: Arc::new(Shared { local_state: LocalState { owner, owned: LocalOwnedTasks::new(), local_queue: UnsafeCell::new(VecDeque::with_capacity(INITIAL_CAPACITY)), }, queue: Mutex::new(Some(VecDeque::with_capacity(INITIAL_CAPACITY))), waker: AtomicWaker::new(), #[cfg(tokio_unstable)] unhandled_panic: crate::runtime::UnhandledPanic::Ignore, }), unhandled_panic: Cell::new(false), }), _not_send: PhantomData, } } /// Enters the context of this `LocalSet`. /// /// The [`spawn_local`] method will spawn tasks on the `LocalSet` whose /// context you are inside. /// /// [`spawn_local`]: fn@crate::task::spawn_local pub fn enter(&self) -> LocalEnterGuard { CURRENT.with( |LocalData { ctx, wake_on_schedule, .. }| { let ctx = ctx.replace(Some(self.context.clone())); let wake_on_schedule = wake_on_schedule.replace(true); LocalEnterGuard { ctx, wake_on_schedule, } }, ) } /// Spawns a `!Send` task onto the local task set. /// /// This task is guaranteed to be run on the current thread. /// /// Unlike the free function [`spawn_local`], this method may be used to /// spawn local tasks when the `LocalSet` is _not_ running. The provided /// future will start running once the `LocalSet` is next started, even if /// you don't await the returned `JoinHandle`. /// /// # Examples /// /// ```rust /// use tokio::task; /// /// #[tokio::main] /// async fn main() { /// let local = task::LocalSet::new(); /// /// // Spawn a future on the local set. This future will be run when /// // we call `run_until` to drive the task set. /// local.spawn_local(async { /// // ... /// }); /// /// // Run the local task set. /// local.run_until(async move { /// // ... /// }).await; /// /// // When `run` finishes, we can spawn _more_ futures, which will /// // run in subsequent calls to `run_until`. /// local.spawn_local(async { /// // ... /// }); /// /// local.run_until(async move { /// // ... /// }).await; /// } /// ``` /// [`spawn_local`]: fn@spawn_local #[track_caller] pub fn spawn_local<F>(&self, future: F) -> JoinHandle<F::Output> where F: Future + 'static, F::Output: 'static, { self.spawn_named(future, None) } /// Runs a future to completion on the provided runtime, driving any local /// futures spawned on this task set on the current thread. /// /// This runs the given future on the runtime, blocking until it is /// complete, and yielding its resolved result. Any tasks or timers which /// the future spawns internally will be executed on the runtime. The future /// may also call [`spawn_local`] to `spawn_local` additional local futures on the /// current thread. /// /// This method should not be called from an asynchronous context. /// /// # Panics /// /// This function panics if the executor is at capacity, if the provided /// future panics, or if called within an asynchronous execution context. /// /// # Notes /// /// Since this function internally calls [`Runtime::block_on`], and drives /// futures in the local task set inside that call to `block_on`, the local /// futures may not use [in-place blocking]. If a blocking call needs to be /// issued from a local task, the [`spawn_blocking`] API may be used instead. /// /// For example, this will panic: /// ```should_panic /// use tokio::runtime::Runtime; /// use tokio::task; /// /// let rt = Runtime::new().unwrap(); /// let local = task::LocalSet::new(); /// local.block_on(&rt, async { /// let join = task::spawn_local(async { /// let blocking_result = task::block_in_place(|| { /// // ... /// }); /// // ... /// }); /// join.await.unwrap(); /// }) /// ``` /// This, however, will not panic: /// ``` /// use tokio::runtime::Runtime; /// use tokio::task; /// /// let rt = Runtime::new().unwrap(); /// let local = task::LocalSet::new(); /// local.block_on(&rt, async { /// let join = task::spawn_local(async { /// let blocking_result = task::spawn_blocking(|| { /// // ... /// }).await; /// // ... /// }); /// join.await.unwrap(); /// }) /// ``` /// /// [`spawn_local`]: fn@spawn_local /// [`Runtime::block_on`]: method@crate::runtime::Runtime::block_on /// [in-place blocking]: fn@crate::task::block_in_place /// [`spawn_blocking`]: fn@crate::task::spawn_blocking #[track_caller] #[cfg(feature = "rt")] #[cfg_attr(docsrs, doc(cfg(feature = "rt")))] pub fn block_on<F>(&self, rt: &crate::runtime::Runtime, future: F) -> F::Output where F: Future, { rt.block_on(self.run_until(future)) } /// Runs a future to completion on the local set, returning its output. /// /// This returns a future that runs the given future with a local set, /// allowing it to call [`spawn_local`] to spawn additional `!Send` futures. /// Any local futures spawned on the local set will be driven in the /// background until the future passed to `run_until` completes. When the future /// passed to `run_until` finishes, any local futures which have not completed /// will remain on the local set, and will be driven on subsequent calls to /// `run_until` or when [awaiting the local set] itself. /// /// # Cancel safety /// /// This method is cancel safe when `future` is cancel safe. /// /// # Examples /// /// ```rust /// use tokio::task; /// /// #[tokio::main] /// async fn main() { /// task::LocalSet::new().run_until(async { /// task::spawn_local(async move { /// // ... /// }).await.unwrap(); /// // ... /// }).await; /// } /// ``` /// /// [`spawn_local`]: fn@spawn_local /// [awaiting the local set]: #awaiting-a-localset pub async fn run_until<F>(&self, future: F) -> F::Output where F: Future, { let run_until = RunUntil { future, local_set: self, }; run_until.await } #[track_caller] pub(in crate::task) fn spawn_named<F>( &self, future: F, name: Option<&str>, ) -> JoinHandle<F::Output> where F: Future + 'static, F::Output: 'static, { if cfg!(debug_assertions) && std::mem::size_of::<F>() > BOX_FUTURE_THRESHOLD { self.spawn_named_inner(Box::pin(future), name) } else { self.spawn_named_inner(future, name) } } #[track_caller] fn spawn_named_inner<F>(&self, future: F, name: Option<&str>) -> JoinHandle<F::Output> where F: Future + 'static, F::Output: 'static, { let handle = self.context.spawn(future, name); // Because a task was spawned from *outside* the `LocalSet`, wake the // `LocalSet` future to execute the new task, if it hasn't been woken. // // Spawning via the free fn `spawn` does not require this, as it can // only be called from *within* a future executing on the `LocalSet` — // in that case, the `LocalSet` must already be awake. self.context.shared.waker.wake(); handle } /// Ticks the scheduler, returning whether the local future needs to be /// notified again. fn tick(&self) -> bool { for _ in 0..MAX_TASKS_PER_TICK { // Make sure we didn't hit an unhandled panic assert!(!self.context.unhandled_panic.get(), "a spawned task panicked and the LocalSet i match self.next_task() { // Run the task // // Safety: As spawned tasks are `!Send`, `run_unchecked` must be // used. We are responsible for maintaining the invariant that // `run_unchecked` is only called on threads that spawned the // task initially. Because `LocalSet` itself is `!Send`, and // `spawn_local` spawns into the `LocalSet` on the current // thread, the invariant is maintained. Some(task) => crate::runtime::coop::budget(|| task.run()), // We have fully drained the queue of notified tasks, so the // local future doesn't need to be notified again — it can wait // until something else wakes a task in the local set. None => return false, } } true } fn next_task(&self) -> Option<task::LocalNotified<Arc<Shared>>> { let tick = self.tick.get(); self.tick.set(tick.wrapping_add(1)); let task = if tick % REMOTE_FIRST_INTERVAL == 0 { self.context .shared .queue .lock() .as_mut() .and_then(|queue| queue.pop_front()) .or_else(|| self.pop_local()) } else { self.pop_local().or_else(|| { self.context .shared .queue .lock() .as_mut() .and_then(VecDeque::pop_front) }) }; task.map(|task| unsafe { // Safety: because the `LocalSet` itself is `!Send`, we know we are // on the same thread if we have access to the `LocalSet`, and can // therefore access the local run queue. self.context.shared.local_state.assert_owner(task) }) } fn pop_local(&self) -> Option<task::Notified<Arc<Shared>>> { unsafe { // Safety: because the `LocalSet` itself is `!Send`, we know we are // on the same thread if we have access to the `LocalSet`, and can // therefore access the local run queue. self.context.shared.local_state.task_pop_front() } } fn with<T>(&self, f: impl FnOnce() -> T) -> T { CURRENT.with(|local_data| { let _guard = local_data.enter(self.context.clone()); f() }) } /// This method is like `with`, but it just calls `f` without setting the thread-local if that /// fails. fn with_if_possible<T>(&self, f: impl FnOnce() -> T) -> T { let mut f = Some(f); let res = CURRENT.try_with(|local_data| { let _guard = local_data.enter(self.context.clone()); (f.take().unwrap())() }); match res { Ok(res) => res, Err(_access_error) => (f.take().unwrap())(), } } } cfg_unstable! { impl LocalSet { /// Configure how the `LocalSet` responds to an unhandled panic on a /// spawned task. /// /// By default, an unhandled panic (i.e. a panic not caught by /// [`std::panic::catch_unwind`]) has no impact on the `LocalSet`'s /// execution. The panic is error value is forwarded to the task's /// [`JoinHandle`] and all other spawned tasks continue running. /// /// The `unhandled_panic` option enables configuring this behavior. /// /// * `UnhandledPanic::Ignore` is the default behavior. Panics on /// spawned tasks have no impact on the `LocalSet`'s execution. /// * `UnhandledPanic::ShutdownRuntime` will force the `LocalSet` to /// shutdown immediately when a spawned task panics even if that /// task's `JoinHandle` has not been dropped. All other spawned tasks /// will immediately terminate and further calls to /// [`LocalSet::block_on`] and [`LocalSet::run_until`] will panic. /// /// # Panics /// /// This method panics if called after the `LocalSet` has started /// running. /// /// # Unstable /// /// This option is currently unstable and its implementation is /// incomplete. The API may change or be removed in the future. See /// tokio-rs/tokio#4516 for more details. /// /// # Examples /// /// The following demonstrates a `LocalSet` configured to shutdown on /// panic. The first spawned task panics and results in the `LocalSet` /// shutting down. The second spawned task never has a chance to /// execute. The call to `run_until` will panic due to the runtime being /// forcibly shutdown. /// /// ```should_panic /// use tokio::runtime::UnhandledPanic; /// /// # #[tokio::main] /// # async fn main() { /// tokio::task::LocalSet::new() /// .unhandled_panic(UnhandledPanic::ShutdownRuntime) /// .run_until(async { /// tokio::task::spawn_local(async { panic!("boom"); }); /// tokio::task::spawn_local(async { /// // This task never completes /// }); /// /// // Do some work, but `run_until` will panic before it completes /// # loop { tokio::task::yield_now().await; } /// }) /// .await; /// # } /// ``` /// /// [`JoinHandle`]: struct@crate::task::JoinHandle pub fn unhandled_panic(&mut self, behavior: crate::runtime::UnhandledPanic) -> &mut Sel // TODO: This should be set as a builder Rc::get_mut(&mut self.context) .and_then(|ctx| Arc::get_mut(&mut ctx.shared)) .expect("Unhandled Panic behavior modified after starting LocalSet") .unhandled_panic = behavior; self } /// Returns the [`Id`] of the current `LocalSet` runtime. /// /// # Examples /// /// ```rust /// use tokio::task; /// /// #[tokio::main] /// async fn main() { /// let local_set = task::LocalSet::new(); /// println!("Local set id: {}", local_set.id()); /// } /// ``` /// /// **Note**: This is an [unstable API][unstable]. The public API of this type /// may break in 1.x releases. See [the documentation on unstable /// features][unstable] for details. /// /// [unstable]: crate#unstable-features /// [`Id`]: struct@crate::runtime::Id pub fn id(&self) -> runtime::Id { self.context.shared.local_state.owned.id.into() } } } impl fmt::Debug for LocalSet { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("LocalSet").finish() } } impl Future for LocalSet { type Output = (); fn poll(self: Pin<&mut Self>, cx: &mut std::task::Context<'_>) -> Poll<Self::Output> { // Register the waker before starting to work self.context.shared.waker.register_by_ref(cx.waker()); if self.with(|| self.tick()) { // If `tick` returns true, we need to notify the local future again: // there are still tasks remaining in the run queue. cx.waker().wake_by_ref(); Poll::Pending // Safety: called from the thread that owns `LocalSet`. Because // `LocalSet` is `!Send`, this is safe. } else if unsafe { self.context.shared.local_state.owned_is_empty() } { // If the scheduler has no remaining futures, we're done! Poll::Ready(()) } else { // There are still futures in the local set, but we've polled all the // futures in the run queue. Therefore, we can just return Pending // since the remaining futures will be woken from somewhere else. Poll::Pending } } } impl Default for LocalSet { fn default() -> LocalSet { LocalSet::new() } } impl Drop for LocalSet { fn drop(&mut self) { self.with_if_possible(|| { // Shut down all tasks in the LocalOwnedTasks and close it to // prevent new tasks from ever being added. unsafe { // Safety: called from the thread that owns `LocalSet` self.context.shared.local_state.close_and_shutdown_all(); } // We already called shutdown on all tasks above, so there is no // need to call shutdown. // Safety: note that this *intentionally* bypasses the unsafe // `Shared::local_queue()` method. This is in order to avoid the // debug assertion that we are on the thread that owns the // `LocalSet`, because on some systems (e.g. at least some macOS // versions), attempting to get the current thread ID can panic due // to the thread's local data that stores the thread ID being // dropped *before* the `LocalSet`. // // Despite avoiding the assertion here, it is safe for us to access // the local queue in `Drop`, because the `LocalSet` itself is // `!Send`, so we can reasonably guarantee that it will not be // `Drop`ped from another thread. let local_queue = unsafe { // Safety: called from the thread that owns `LocalSet` self.context.shared.local_state.take_local_queue() }; for task in local_queue { drop(task); } // Take the queue from the Shared object to prevent pushing // notifications to it in the future. let queue = self.context.shared.queue.lock().take().unwrap(); for task in queue { drop(task); } // Safety: called from the thread that owns `LocalSet` assert!(unsafe { self.context.shared.local_state.owned_is_empty() }); }); } } // === impl Context === impl Context { #[track_caller] fn spawn<F>(&self, future: F, name: Option<&str>) -> JoinHandle<F::Output> where F: Future + 'static, F::Output: 'static, { let id = crate::runtime::task::Id::next(); let future = crate::util::trace::task(future, "local", name, id.as_u64()); // Safety: called from the thread that owns the `LocalSet` let (handle, notified) = { self.shared.local_state.assert_called_from_owner_thread(); self.shared .local_state .owned .bind(future, self.shared.clone(), id) }; if let Some(notified) = notified { self.shared.schedule(notified); } handle } } // === impl LocalFuture === impl<T: Future> Future for RunUntil<'_, T> { type Output = T::Output; fn poll(self: Pin<&mut Self>, cx: &mut std::task::Context<'_>) -> Poll<Self::Output> { let me = self.project(); me.local_set.with(|| { me.local_set .context .shared .waker .register_by_ref(cx.waker()); let _no_blocking = crate::runtime::context::disallow_block_in_place(); let f = me.future; if let Poll::Ready(output) = f.poll(cx) { return Poll::Ready(output); } if me.local_set.tick() { // If `tick` returns `true`, we need to notify the local future again: // there are still tasks remaining in the run queue. cx.waker().wake_by_ref(); } Poll::Pending }) } } impl Shared { /// Schedule the provided task on the scheduler. fn schedule(&self, task: task::Notified<Arc<Self>>) { CURRENT.with(|localdata| { match localdata.ctx.get() { // If the current `LocalSet` is being polled, we don't need to wake it. // When we `enter` it, then the value `wake_on_schedule` is set to be true. // In this case it is not being polled, so we need to wake it. Some(cx) if cx.shared.ptr_eq(self) && !localdata.wake_on_schedule.get() => unsafe { // Safety: if the current `LocalSet` context points to this // `LocalSet`, then we are on the thread that owns it. cx.shared.local_state.task_push_back(task); }, // We are on the thread that owns the `LocalSet`, so we can // wake to the local queue. _ if context::thread_id().ok() == Some(self.local_state.owner) => { unsafe { // Safety: we just checked that the thread ID matches // the localset's owner, so this is safe. self.local_state.task_push_back(task); } // We still have to wake the `LocalSet`, because it isn't // currently being polled. self.waker.wake(); } // We are *not* on the thread that owns the `LocalSet`, so we // have to wake to the remote queue. _ => { // First, check whether the queue is still there (if not, the // LocalSet is dropped). Then push to it if so, and if not, // do nothing. let mut lock = self.queue.lock(); if let Some(queue) = lock.as_mut() { queue.push_back(task); drop(lock); self.waker.wake(); } } } }); } fn ptr_eq(&self, other: &Shared) -> bool { std::ptr::eq(self, other) } } // This is safe because (and only because) we *pinky pwomise* to never touch the // local run queue except from the thread that owns the `LocalSet`. unsafe impl Sync for Shared {} impl task::Schedule for Arc<Shared> { fn release(&self, task: &Task<Self>) -> Option<Task<Self>> { // Safety, this is always called from the thread that owns `LocalSet` unsafe { self.local_state.task_remove(task) } } fn schedule(&self, task: task::Notified<Self>) { Shared::schedule(self, task); } cfg_unstable! { fn unhandled_panic(&self) { use crate::runtime::UnhandledPanic; match self.unhandled_panic { UnhandledPanic::Ignore => { // Do nothing } UnhandledPanic::ShutdownRuntime => { // This hook is only called from within the runtime, so // `CURRENT` should match with `&self`, i.e. there is no // opportunity for a nested scheduler to be called. CURRENT.with(|LocalData { ctx, .. }| match ctx.get() { Some(cx) if Arc::ptr_eq(self, &cx.shared) => { cx.unhandled_panic.set(true); // Safety: this is always called from the thread that owns `LocalSet` unsafe { cx.shared.local_state.close_and_shutdown_all(); } } _ => unreachable!("runtime core not set in CURRENT thread-local"), }) } } } } } impl LocalState { unsafe fn task_pop_front(&self) -> Option<task::Notified<Arc<Shared>>> { // The caller ensures it is called from the same thread that owns // the LocalSet. self.assert_called_from_owner_thread(); self.local_queue.with_mut(|ptr| (*ptr).pop_front()) } unsafe fn task_push_back(&self, task: task::Notified<Arc<Shared>>) { // The caller ensures it is called from the same thread that owns // the LocalSet. self.assert_called_from_owner_thread(); self.local_queue.with_mut(|ptr| (*ptr).push_back(task)); } unsafe fn take_local_queue(&self) -> VecDeque<task::Notified<Arc<Shared>>> { // The caller ensures it is called from the same thread that owns // the LocalSet. self.assert_called_from_owner_thread(); self.local_queue.with_mut(|ptr| std::mem::take(&mut (*ptr))) } unsafe fn task_remove(&self, task: &Task<Arc<Shared>>) -> Option<Task<Arc<Shared>>> { // The caller ensures it is called from the same thread that owns // the LocalSet. self.assert_called_from_owner_thread(); self.owned.remove(task) } /// Returns true if the `LocalSet` does not have any spawned tasks unsafe fn owned_is_empty(&self) -> bool { // The caller ensures it is called from the same thread that owns // the LocalSet. self.assert_called_from_owner_thread(); self.owned.is_empty() } unsafe fn assert_owner( &self, task: task::Notified<Arc<Shared>>, ) -> task::LocalNotified<Arc<Shared>> { // The caller ensures it is called from the same thread that owns // the LocalSet. self.assert_called_from_owner_thread(); self.owned.assert_owner(task) } unsafe fn close_and_shutdown_all(&self) { // The caller ensures it is called from the same thread that owns // the LocalSet. self.assert_called_from_owner_thread(); self.owned.close_and_shutdown_all(); } #[track_caller] fn assert_called_from_owner_thread(&self) { // FreeBSD has some weirdness around thread-local destruction. // TODO: remove this hack when thread id is cleaned up #[cfg(not(any(target_os = "openbsd", target_os = "freebsd")))] debug_assert!( // if we couldn't get the thread ID because we're dropping the local // data, skip the assertion --- the `Drop` impl is not going to be // called from another thread, because `LocalSet` is `!Send` context::thread_id() .map(|id| id == self.owner) .unwrap_or(true), "`LocalSet`'s local run queue must not be accessed by another thread!" ); } } // This is `Send` because it is stored in `Shared`. It is up to the caller to // ensure they are on the same thread that owns the `LocalSet`. unsafe impl Send for LocalState {} #[cfg(all(test, not(loom)))] mod tests { use super::*; // Does a `LocalSet` running on a current-thread runtime...basically work? // // This duplicates a test in `tests/task_local_set.rs`, but because this is // a lib test, it will run under Miri, so this is necessary to catch stacked // borrows violations in the `LocalSet` implementation. #[test] fn local_current_thread_scheduler() { let f = async { LocalSet::new() .run_until(async { spawn_local(async {}).await.unwrap(); }) .await; }; crate::runtime::Builder::new_current_thread() .build() .expect("rt") .block_on(f) } // Tests that when a task on a `LocalSet` is woken by an io driver on the // same thread, the task is woken to the localset's local queue rather than // its remote queue. // // This test has to be defined in the `local.rs` file as a lib test, rather // than in `tests/`, because it makes assertions about the local set's // internal state. #[test] fn wakes_to_local_queue() { use super::*; use crate::sync::Notify; let rt = crate::runtime::Builder::new_current_thread() .build() .expect("rt"); rt.block_on(async { let local = LocalSet::new(); let notify = Arc::new(Notify::new()); let task = local.spawn_local({ let notify = notify.clone(); async move { notify.notified().await; } }); let mut run_until = Box::pin(local.run_until(async move { task.await.unwrap(); })); // poll the run until future once crate::future::poll_fn(|cx| { let _ = run_until.as_mut().poll(cx); Poll::Ready(()) }) .await; notify.notify_one(); let task = unsafe { local.context.shared.local_state.task_pop_front() }; // TODO(eliza): it would be nice to be able to assert that this is // the local task. assert!( task.is_some(), "task should have been notified to the LocalSet's local queue" ); }) } } [ Dauer der Verarbeitung: 0.44 Sekunden ] |
2026-04-04