use crate::runtime::task::RawTask; use std::fmt; use std::future::Future; use std::marker::PhantomData; use std::pin::Pin; use std::task::{Context, Poll}; cfg_task! { /// An owned permission to join on a task (await its termination). /// /// This can be thought of as the equivalent of [`std::thread::JoinHandle`] for /// a task rather than a thread. /// /// A `JoinHandle` *detaches* the associated task when it is dropped, which /// means that there is no longer any handle to the task, and no way to `join` /// on it. /// /// This `struct` is created by the [`task::spawn`] and [`task::spawn_blocking`] /// functions. /// /// # Examples /// /// Creation from [`task::spawn`]: /// /// ``` /// use tokio::task; /// /// # async fn doc() { /// let join_handle: task::JoinHandle<_> = task::spawn(async { /// // some work here /// }); /// # } /// ``` /// /// Creation from [`task::spawn_blocking`]: /// /// ``` /// use tokio::task; /// /// # async fn doc() { /// let join_handle: task::JoinHandle<_> = task::spawn_blocking(|| { /// // some blocking work here /// }); /// # } /// ``` /// /// The generic parameter `T` in `JoinHandle` is the return type of the spawned task. /// If the return value is an i32, the join handle has type `JoinHandle`: /// /// ``` /// use tokio::task; /// /// # async fn doc() { /// let join_handle: task::JoinHandle = task::spawn(async { /// 5 + 3 /// }); /// # } /// /// ``` /// /// If the task does not have a return value, the join handle has type `JoinHandle<()>`: /// /// ``` /// use tokio::task; /// /// # async fn doc() { /// let join_handle: task::JoinHandle<()> = task::spawn(async { /// println!("I return nothing."); /// }); /// # } /// ``` /// /// Note that `handle.await` doesn't give you the return type directly. It is wrapped in a /// `Result` because panics in the spawned task are caught by Tokio. The `?` operator has /// to be double chained to extract the returned value: /// /// ``` /// use tokio::task; /// use std::io; /// /// #[tokio::main] /// async fn main() -> io::Result<()> { /// let join_handle: task::JoinHandle> = tokio::spawn(async { /// Ok(5 + 3) /// }); /// /// let result = join_handle.await??; /// assert_eq!(result, 8); /// Ok(()) /// } /// ``` /// /// If the task panics, the error is a [`JoinError`] that contains the panic: /// /// ``` /// use tokio::task; /// use std::io; /// use std::panic; /// /// #[tokio::main] /// async fn main() -> io::Result<()> { /// let join_handle: task::JoinHandle> = tokio::spawn(async { /// panic!("boom"); /// }); /// /// let err = join_handle.await.unwrap_err(); /// assert!(err.is_panic()); /// Ok(()) /// } /// /// ``` /// Child being detached and outliving its parent: /// /// ```no_run /// use tokio::task; /// use tokio::time; /// use std::time::Duration; /// /// # #[tokio::main] async fn main() { /// let original_task = task::spawn(async { /// let _detached_task = task::spawn(async { /// // Here we sleep to make sure that the first task returns before. /// time::sleep(Duration::from_millis(10)).await; /// // This will be called, even though the JoinHandle is dropped. /// println!("♫ Still alive ♫"); /// }); /// }); /// /// original_task.await.expect("The task being joined has panicked"); /// println!("Original task is joined."); /// /// // We make sure that the new task has time to run, before the main /// // task returns. /// /// time::sleep(Duration::from_millis(1000)).await; /// # } /// ``` /// /// [`task::spawn`]: crate::task::spawn() /// [`task::spawn_blocking`]: crate::task::spawn_blocking /// [`std::thread::JoinHandle`]: std::thread::JoinHandle /// [`JoinError`]: crate::task::JoinError pub struct JoinHandle { raw: Option, _p: PhantomData, } } unsafe impl Send for JoinHandle {} unsafe impl Sync for JoinHandle {} impl JoinHandle { pub(super) fn new(raw: RawTask) -> JoinHandle { JoinHandle { raw: Some(raw), _p: PhantomData, } } /// Abort the task associated with the handle. /// /// Awaiting a cancelled task might complete as usual if the task was /// already completed at the time it was cancelled, but most likely it /// will complete with a `Err(JoinError::Cancelled)`. /// /// ```rust /// use tokio::time; /// /// #[tokio::main] /// async fn main() { /// let mut handles = Vec::new(); /// /// handles.push(tokio::spawn(async { /// time::sleep(time::Duration::from_secs(10)).await; /// true /// })); /// /// handles.push(tokio::spawn(async { /// time::sleep(time::Duration::from_secs(10)).await; /// false /// })); /// /// for handle in &handles { /// handle.abort(); /// } /// /// for handle in handles { /// assert!(handle.await.unwrap_err().is_cancelled()); /// } /// } /// ``` pub fn abort(&self) { if let Some(raw) = self.raw { raw.shutdown(); } } } impl Unpin for JoinHandle {} impl Future for JoinHandle { type Output = super::Result; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { let mut ret = Poll::Pending; // Keep track of task budget let coop = ready!(crate::coop::poll_proceed(cx)); // Raw should always be set. If it is not, this is due to polling after // completion let raw = self .raw .as_ref() .expect("polling after `JoinHandle` already completed"); // Try to read the task output. If the task is not yet complete, the // waker is stored and is notified once the task does complete. // // The function must go via the vtable, which requires erasing generic // types. To do this, the function "return" is placed on the stack // **before** calling the function and is passed into the function using // `*mut ()`. // // Safety: // // The type of `T` must match the task's output type. unsafe { raw.try_read_output(&mut ret as *mut _ as *mut (), cx.waker()); } if ret.is_ready() { coop.made_progress(); } ret } } impl Drop for JoinHandle { fn drop(&mut self) { if let Some(raw) = self.raw.take() { if raw.header().state.drop_join_handle_fast().is_ok() { return; } raw.drop_join_handle_slow(); } } } impl fmt::Debug for JoinHandle where T: fmt::Debug, { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt.debug_struct("JoinHandle").finish() } }