src/task.rs - platform/external/rust/crates/async-task - Gitiles

 use std::fmt;
 use std::future::Future;
 use std::marker::PhantomData;
 use std::mem;
 use std::ptr::NonNull;

 use crate::header::Header;
 use crate::raw::RawTask;
 use crate::JoinHandle;

 /// Creates a new task.
 ///
 /// This constructor returns a [`Task`] reference that runs the future and a [`JoinHandle`] that
 /// awaits its result.
 ///
 /// When run, the task polls `future`. When woken, it gets scheduled for running by the `schedule`
 /// function. Argument `tag` is an arbitrary piece of data stored inside the task.
 ///
 /// [`Task`]: struct.Task.html
 /// [`JoinHandle`]: struct.JoinHandle.html
 ///
 /// # Examples
 ///
 /// ```
 /// use crossbeam::channel;
 ///
 /// // The future inside the task.
 /// let future = async {
 ///     println!("Hello, world!");
 /// };
 ///
 /// // If the task gets woken, it will be sent into this channel.
 /// let (s, r) = channel::unbounded();
 /// let schedule = move |task| s.send(task).unwrap();
 ///
 /// // Create a task with the future and the schedule function.
 /// let (task, handle) = async_task::spawn(future, schedule, ());
 /// ```
 pub fn spawn<F, R, S, T>(future: F, schedule: S, tag: T) -> (Task<T>, JoinHandle<R, T>)
 where
     F: Future<Output = R> + Send + 'static,
     R: Send + 'static,
     S: Fn(Task<T>) + Send + Sync + 'static,
     T: Send + Sync + 'static,
 {
     let raw_task = RawTask::<F, R, S, T>::allocate(tag, future, schedule);
     let task = Task {
         raw_task,
         _marker: PhantomData,
     };
     let handle = JoinHandle {
         raw_task,
         _marker: PhantomData,
     };
     (task, handle)
 }

 /// A task reference that runs its future.
 ///
 /// The [`Task`] reference "owns" the task itself and is able to run it. Running consumes the
 /// [`Task`] reference and polls its internal future. If the future is still pending after getting
 /// polled, the [`Task`] reference simply won't exist until a [`Waker`] notifies the task. If the
 /// future completes, its result becomes available to the [`JoinHandle`].
 ///
 /// When the task is woken, the [`Task`] reference is recreated and passed to the schedule
 /// function. In most executors, scheduling simply pushes the [`Task`] reference into a queue of
 /// runnable tasks.
 ///
 /// If the [`Task`] reference is dropped without being run, the task is cancelled. When cancelled,
 /// the task won't be scheduled again even if a [`Waker`] wakes it. It is possible for the
 /// [`JoinHandle`] to cancel while the [`Task`] reference exists, in which case an attempt to run
 /// the task won't do anything.
 ///
 /// [`run()`]: struct.Task.html#method.run
 /// [`JoinHandle`]: struct.JoinHandle.html
 /// [`Task`]: struct.Task.html
 /// [`Waker`]: https://doc.rust-lang.org/std/task/struct.Waker.html
 pub struct Task<T> {
     /// A pointer to the heap-allocated task.
     pub(crate) raw_task: NonNull<()>,

     /// A marker capturing the generic type `T`.
     pub(crate) _marker: PhantomData<T>,
 }

 unsafe impl<T> Send for Task<T> {}
 unsafe impl<T> Sync for Task<T> {}

 impl<T> Task<T> {
     /// Schedules the task.
     ///
     /// This is a convenience method that simply reschedules the task by passing it to its schedule
     /// function.
     ///
     /// If the task is cancelled, this method won't do anything.
     pub fn schedule(self) {
         let ptr = self.raw_task.as_ptr();
         let header = ptr as *const Header;
         mem::forget(self);

         unsafe {
             ((*header).vtable.schedule)(ptr);
         }
     }

     /// Runs the task.
     ///
     /// This method polls the task's future. If the future completes, its result will become
     /// available to the [`JoinHandle`]. And if the future is still pending, the task will have to
     /// be woken in order to be rescheduled and then run again.
     ///
     /// If the task was cancelled by a [`JoinHandle`] before it gets run, then this method won't do
     /// anything.
     ///
     /// It is possible that polling the future panics, in which case the panic will be propagated
     /// into the caller. It is advised that invocations of this method are wrapped inside
     /// [`catch_unwind`].
     ///
     /// If a panic occurs, the task is automatically cancelled.
     ///
     /// [`JoinHandle`]: struct.JoinHandle.html
     /// [`catch_unwind`]: https://doc.rust-lang.org/std/panic/fn.catch_unwind.html
     pub fn run(self) {
         let ptr = self.raw_task.as_ptr();
         let header = ptr as *const Header;
         mem::forget(self);

         unsafe {
             ((*header).vtable.run)(ptr);
         }
     }

     /// Cancels the task.
     ///
     /// When cancelled, the task won't be scheduled again even if a [`Waker`] wakes it. An attempt
     /// to run it won't do anything.
     ///
     /// [`Waker`]: https://doc.rust-lang.org/std/task/struct.Waker.html
     pub fn cancel(&self) {
         let ptr = self.raw_task.as_ptr();
         let header = ptr as *const Header;

         unsafe {
             (*header).cancel();
         }
     }

     /// Returns a reference to the tag stored inside the task.
     pub fn tag(&self) -> &T {
         let offset = Header::offset_tag::<T>();
         let ptr = self.raw_task.as_ptr();

         unsafe {
             let raw = (ptr as *mut u8).add(offset) as *const T;
             &*raw
         }
     }
 }

 impl<T> Drop for Task<T> {
     fn drop(&mut self) {
         let ptr = self.raw_task.as_ptr();
         let header = ptr as *const Header;

         unsafe {
             // Cancel the task.
             (*header).cancel();

             // Drop the future.
             ((*header).vtable.drop_future)(ptr);

             // Drop the task reference.
             ((*header).vtable.decrement)(ptr);
         }
     }
 }

 impl<T: fmt::Debug> fmt::Debug for Task<T> {
     fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
         let ptr = self.raw_task.as_ptr();
         let header = ptr as *const Header;

         f.debug_struct("Task")
             .field("header", unsafe { &(*header) })
             .field("tag", self.tag())
             .finish()
     }
 }
	use std::fmt;
	use std::future::Future;
	use std::marker::PhantomData;
	use std::mem;
	use std::ptr::NonNull;

	use crate::header::Header;
	use crate::raw::RawTask;
	use crate::JoinHandle;

	/// Creates a new task.
	///
	/// This constructor returns a [`Task`] reference that runs the future and a [`JoinHandle`] that
	/// awaits its result.
	///
	/// When run, the task polls `future`. When woken, it gets scheduled for running by the `schedule`
	/// function. Argument `tag` is an arbitrary piece of data stored inside the task.
	///
	/// [`Task`]: struct.Task.html
	/// [`JoinHandle`]: struct.JoinHandle.html
	///
	/// # Examples
	///
	/// ```
	/// use crossbeam::channel;
	///
	/// // The future inside the task.
	/// let future = async {
	/// println!("Hello, world!");
	/// };
	///
	/// // If the task gets woken, it will be sent into this channel.
	/// let (s, r) = channel::unbounded();
	/// let schedule = move \|task\| s.send(task).unwrap();
	///
	/// // Create a task with the future and the schedule function.
	/// let (task, handle) = async_task::spawn(future, schedule, ());
	/// ```
	pub fn spawn<F, R, S, T>(future: F, schedule: S, tag: T) -> (Task<T>, JoinHandle<R, T>)
	where
	F: Future<Output = R> + Send + 'static,
	R: Send + 'static,
	S: Fn(Task<T>) + Send + Sync + 'static,
	T: Send + Sync + 'static,
	{
	let raw_task = RawTask::<F, R, S, T>::allocate(tag, future, schedule);
	let task = Task {
	raw_task,
	_marker: PhantomData,
	};
	let handle = JoinHandle {
	raw_task,
	_marker: PhantomData,
	};
	(task, handle)
	}

	/// A task reference that runs its future.
	///
	/// The [`Task`] reference "owns" the task itself and is able to run it. Running consumes the
	/// [`Task`] reference and polls its internal future. If the future is still pending after getting
	/// polled, the [`Task`] reference simply won't exist until a [`Waker`] notifies the task. If the
	/// future completes, its result becomes available to the [`JoinHandle`].
	///
	/// When the task is woken, the [`Task`] reference is recreated and passed to the schedule
	/// function. In most executors, scheduling simply pushes the [`Task`] reference into a queue of
	/// runnable tasks.
	///
	/// If the [`Task`] reference is dropped without being run, the task is cancelled. When cancelled,
	/// the task won't be scheduled again even if a [`Waker`] wakes it. It is possible for the
	/// [`JoinHandle`] to cancel while the [`Task`] reference exists, in which case an attempt to run
	/// the task won't do anything.
	///
	/// [`run()`]: struct.Task.html#method.run
	/// [`JoinHandle`]: struct.JoinHandle.html
	/// [`Task`]: struct.Task.html
	/// [`Waker`]: https://doc.rust-lang.org/std/task/struct.Waker.html
	pub struct Task<T> {
	/// A pointer to the heap-allocated task.
	pub(crate) raw_task: NonNull<()>,

	/// A marker capturing the generic type `T`.
	pub(crate) _marker: PhantomData<T>,
	}

	unsafe impl<T> Send for Task<T> {}
	unsafe impl<T> Sync for Task<T> {}

	impl<T> Task<T> {
	/// Schedules the task.
	///
	/// This is a convenience method that simply reschedules the task by passing it to its schedule
	/// function.
	///
	/// If the task is cancelled, this method won't do anything.
	pub fn schedule(self) {
	let ptr = self.raw_task.as_ptr();
	let header = ptr as *const Header;
	mem::forget(self);

	unsafe {
	((*header).vtable.schedule)(ptr);
	}
	}

	/// Runs the task.
	///
	/// This method polls the task's future. If the future completes, its result will become
	/// available to the [`JoinHandle`]. And if the future is still pending, the task will have to
	/// be woken in order to be rescheduled and then run again.
	///
	/// If the task was cancelled by a [`JoinHandle`] before it gets run, then this method won't do
	/// anything.
	///
	/// It is possible that polling the future panics, in which case the panic will be propagated
	/// into the caller. It is advised that invocations of this method are wrapped inside
	/// [`catch_unwind`].
	///
	/// If a panic occurs, the task is automatically cancelled.
	///
	/// [`JoinHandle`]: struct.JoinHandle.html
	/// [`catch_unwind`]: https://doc.rust-lang.org/std/panic/fn.catch_unwind.html
	pub fn run(self) {
	let ptr = self.raw_task.as_ptr();
	let header = ptr as *const Header;
	mem::forget(self);

	unsafe {
	((*header).vtable.run)(ptr);
	}
	}

	/// Cancels the task.
	///
	/// When cancelled, the task won't be scheduled again even if a [`Waker`] wakes it. An attempt
	/// to run it won't do anything.
	///
	/// [`Waker`]: https://doc.rust-lang.org/std/task/struct.Waker.html
	pub fn cancel(&self) {
	let ptr = self.raw_task.as_ptr();
	let header = ptr as *const Header;

	unsafe {
	(*header).cancel();
	}
	}

	/// Returns a reference to the tag stored inside the task.
	pub fn tag(&self) -> &T {
	let offset = Header::offset_tag::<T>();
	let ptr = self.raw_task.as_ptr();

	unsafe {
	let raw = (ptr as mut u8).add(offset) as const T;
	&*raw
	}
	}
	}

	impl<T> Drop for Task<T> {
	fn drop(&mut self) {
	let ptr = self.raw_task.as_ptr();
	let header = ptr as *const Header;

	unsafe {
	// Cancel the task.
	(*header).cancel();

	// Drop the future.
	((*header).vtable.drop_future)(ptr);

	// Drop the task reference.
	((*header).vtable.decrement)(ptr);
	}
	}
	}

	impl<T: fmt::Debug> fmt::Debug for Task<T> {
	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
	let ptr = self.raw_task.as_ptr();
	let header = ptr as *const Header;

	f.debug_struct("Task")
	.field("header", unsafe { &(*header) })
	.field("tag", self.tag())
	.finish()
	}
	}