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//! Combinators for the [`Future`] trait. //! //! # Examples //! //! ``` //! use futures_lite::future; //! //! # spin_on::spin_on(async { //! for step in 0..3 { //! println!("step {}", step); //! //! // Give other tasks a chance to run. //! future::yield_now().await; //! } //! # }); //! ``` #[cfg(feature = "alloc")] extern crate alloc; #[doc(no_inline)] pub use core::future::Future; use core::fmt; use core::marker::PhantomData; use core::pin::Pin; use pin_project_lite::pin_project; #[cfg(feature = "std")] use std::{ any::Any, panic::{catch_unwind, AssertUnwindSafe, UnwindSafe}, }; #[cfg(feature = "alloc")] use alloc::boxed::Box; use core::task::{Context, Poll}; /// Blocks the current thread on a future. /// /// # Examples /// /// ``` /// use futures_lite::future; /// /// let val = future::block_on(async { /// 1 + 2 /// }); /// /// assert_eq!(val, 3); /// ``` #[cfg(feature = "std")] pub fn block_on<T>(future: impl Future<Output = T>) -> T { use std::cell::RefCell; use std::task::Waker; use parking::Parker; use waker_fn::waker_fn; // Pin the future on the stack. crate::pin!(future); // Creates a parker and an associated waker that unparks it. fn parker_and_waker() -> (Parker, Waker) { let parker = Parker::new(); let unparker = parker.unparker(); let waker = waker_fn(move || { unparker.unpark(); }); (parker, waker) } thread_local! { // Cached parker and waker for efficiency. static CACHE: RefCell<(Parker, Waker)> = RefCell::new(parker_and_waker()); } CACHE.with(|cache| { // Try grabbing the cached parker and waker. match cache.try_borrow_mut() { Ok(cache) => { // Use the cached parker and waker. let (parker, waker) = &*cache; let cx = &mut Context::from_waker(&waker); // Keep polling until the future is ready. loop { match future.as_mut().poll(cx) { Poll::Ready(output) => return output, Poll::Pending => parker.park(), } } } Err(_) => { // Looks like this is a recursive `block_on()` call. // Create a fresh parker and waker. let (parker, waker) = parker_and_waker(); let cx = &mut Context::from_waker(&waker); // Keep polling until the future is ready. loop { match future.as_mut().poll(cx) { Poll::Ready(output) => return output, Poll::Pending => parker.park(), } } } } }) } /// Creates a future that is always pending. /// /// # Examples /// /// ```no_run /// use futures_lite::future; /// /// # spin_on::spin_on(async { /// future::pending::<()>().await; /// unreachable!(); /// # }) /// ``` pub fn pending<T>() -> Pending<T> { Pending { _marker: PhantomData, } } /// Future for the [`pending()`] function. #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct Pending<T> { _marker: PhantomData<T>, } impl<T> Unpin for Pending<T> {} impl<T> fmt::Debug for Pending<T> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("Pending").finish() } } impl<T> Future for Pending<T> { type Output = T; fn poll(self: Pin<&mut Self>, _: &mut Context<'_>) -> Poll<T> { Poll::Pending } } /// Polls a future just once and returns an [`Option`] with the result. /// /// # Examples /// /// ``` /// use futures_lite::future; /// /// # spin_on::spin_on(async { /// assert_eq!(future::poll_once(future::pending::<()>()).await, None); /// assert_eq!(future::poll_once(future::ready(42)).await, Some(42)); /// # }) /// ``` pub fn poll_once<T, F>(f: F) -> PollOnce<F> where F: Future<Output = T>, { PollOnce { f } } pin_project! { /// Future for the [`poll_once()`] function. #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct PollOnce<F> { #[pin] f: F, } } impl<F> fmt::Debug for PollOnce<F> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("PollOnce").finish() } } impl<T, F> Future for PollOnce<F> where F: Future<Output = T>, { type Output = Option<T>; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> { match self.project().f.poll(cx) { Poll::Ready(t) => Poll::Ready(Some(t)), Poll::Pending => Poll::Ready(None), } } } /// Creates a future from a function returning [`Poll`]. /// /// # Examples /// /// ``` /// use futures_lite::future; /// use std::task::{Context, Poll}; /// /// # spin_on::spin_on(async { /// fn f(_: &mut Context<'_>) -> Poll<i32> { /// Poll::Ready(7) /// } /// /// assert_eq!(future::poll_fn(f).await, 7); /// # }) /// ``` pub fn poll_fn<T, F>(f: F) -> PollFn<F> where F: FnMut(&mut Context<'_>) -> Poll<T>, { PollFn { f } } pin_project! { /// Future for the [`poll_fn()`] function. #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct PollFn<F> { f: F, } } impl<F> fmt::Debug for PollFn<F> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("PollFn").finish() } } impl<T, F> Future for PollFn<F> where F: FnMut(&mut Context<'_>) -> Poll<T>, { type Output = T; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<T> { let this = self.project(); (this.f)(cx) } } /// Creates a future that resolves to the provided value. /// /// # Examples /// /// ``` /// use futures_lite::future; /// /// # spin_on::spin_on(async { /// assert_eq!(future::ready(7).await, 7); /// # }) /// ``` pub fn ready<T>(val: T) -> Ready<T> { Ready(Some(val)) } /// Future for the [`ready()`] function. #[derive(Debug)] #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct Ready<T>(Option<T>); impl<T> Unpin for Ready<T> {} impl<T> Future for Ready<T> { type Output = T; fn poll(mut self: Pin<&mut Self>, _cx: &mut Context<'_>) -> Poll<T> { Poll::Ready(self.0.take().expect("`Ready` polled after completion")) } } /// Wakes the current task and returns [`Poll::Pending`] once. /// /// This function is useful when we want to cooperatively give time to the task scheduler. It is /// generally a good idea to yield inside loops because that way we make sure long-running tasks /// don't prevent other tasks from running. /// /// # Examples /// /// ``` /// use futures_lite::future; /// /// # spin_on::spin_on(async { /// future::yield_now().await; /// # }) /// ``` pub fn yield_now() -> YieldNow { YieldNow(false) } /// Future for the [`yield_now()`] function. #[derive(Debug)] #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct YieldNow(bool); impl Future for YieldNow { type Output = (); fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> { if !self.0 { self.0 = true; cx.waker().wake_by_ref(); Poll::Pending } else { Poll::Ready(()) } } } /// Joins two futures, waiting for both to complete. /// /// # Examples /// /// ``` /// use futures_lite::future; /// /// # spin_on::spin_on(async { /// let a = async { 1 }; /// let b = async { 2 }; /// /// assert_eq!(future::zip(a, b).await, (1, 2)); /// # }) /// ``` pub fn zip<F1, F2>(future1: F1, future2: F2) -> Zip<F1, F2> where F1: Future, F2: Future, { Zip { future1: future1, output1: None, future2: future2, output2: None, } } pin_project! { /// Future for the [`zip()`] function. #[derive(Debug)] #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct Zip<F1, F2> where F1: Future, F2: Future, { #[pin] future1: F1, output1: Option<F1::Output>, #[pin] future2: F2, output2: Option<F2::Output>, } } impl<F1, F2> Future for Zip<F1, F2> where F1: Future, F2: Future, { type Output = (F1::Output, F2::Output); fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> { let this = self.project(); if this.output1.is_none() { if let Poll::Ready(out) = this.future1.poll(cx) { *this.output1 = Some(out); } } if this.output2.is_none() { if let Poll::Ready(out) = this.future2.poll(cx) { *this.output2 = Some(out); } } if this.output1.is_some() && this.output2.is_some() { Poll::Ready((this.output1.take().unwrap(), this.output2.take().unwrap())) } else { Poll::Pending } } } /// Joins two fallible futures, waiting for both to complete or one of them to error. /// /// # Examples /// /// ``` /// use futures_lite::future; /// /// # spin_on::spin_on(async { /// let a = async { Ok::<i32, i32>(1) }; /// let b = async { Err::<i32, i32>(2) }; /// /// assert_eq!(future::try_zip(a, b).await, Err(2)); /// # }) /// ``` pub fn try_zip<T1, T2, E, F1, F2>(future1: F1, future2: F2) -> TryZip<F1, F2> where F1: Future<Output = Result<T1, E>>, F2: Future<Output = Result<T2, E>>, { TryZip { future1: future1, output1: None, future2: future2, output2: None, } } pin_project! { /// Future for the [`try_zip()`] function. #[derive(Debug)] #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct TryZip<F1, F2> where F1: Future, F2: Future, { #[pin] future1: F1, output1: Option<F1::Output>, #[pin] future2: F2, output2: Option<F2::Output>, } } impl<T1, T2, E, F1, F2> Future for TryZip<F1, F2> where F1: Future<Output = Result<T1, E>>, F2: Future<Output = Result<T2, E>>, { type Output = Result<(T1, T2), E>; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> { let this = self.project(); if this.output1.is_none() { if let Poll::Ready(out) = this.future1.poll(cx) { match out { Ok(t) => *this.output1 = Some(Ok(t)), Err(err) => return Poll::Ready(Err(err)), } } } if this.output2.is_none() { if let Poll::Ready(out) = this.future2.poll(cx) { match out { Ok(t) => *this.output2 = Some(Ok(t)), Err(err) => return Poll::Ready(Err(err)), } } } if this.output1.is_some() && this.output2.is_some() { let res1 = this.output1.take().unwrap(); let res2 = this.output2.take().unwrap(); let t1 = res1.map_err(|_| unreachable!()).unwrap(); let t2 = res2.map_err(|_| unreachable!()).unwrap(); Poll::Ready(Ok((t1, t2))) } else { Poll::Pending } } } /// Returns the result of the future that completes first, preferring `future1` if both are ready. /// /// If you need to treat the two futures fairly without a preference for either, use the [`race()`] /// function or the [`FutureExt::race()`] method. /// /// # Examples /// /// ``` /// use futures_lite::future::{self, pending, ready}; /// /// # spin_on::spin_on(async { /// assert_eq!(future::or(ready(1), pending()).await, 1); /// assert_eq!(future::or(pending(), ready(2)).await, 2); /// /// // The first future wins. /// assert_eq!(future::or(ready(1), ready(2)).await, 1); /// # }) /// ``` pub fn or<T, F1, F2>(future1: F1, future2: F2) -> Or<F1, F2> where F1: Future<Output = T>, F2: Future<Output = T>, { Or { future1, future2 } } pin_project! { /// Future for the [`or()`] function and the [`FutureExt::or()`] method. #[derive(Debug)] #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct Or<F1, F2> { #[pin] future1: F1, #[pin] future2: F2, } } impl<T, F1, F2> Future for Or<F1, F2> where F1: Future<Output = T>, F2: Future<Output = T>, { type Output = T; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> { let this = self.project(); if let Poll::Ready(t) = this.future1.poll(cx) { return Poll::Ready(t); } if let Poll::Ready(t) = this.future2.poll(cx) { return Poll::Ready(t); } Poll::Pending } } /// Returns the result of the future that completes first, with no preference if both are ready. /// /// Each time [`Race`] is polled, the two inner futures are polled in random order. Therefore, no /// future takes precedence over the other if both can complete at the same time. /// /// If you have preference for one of the futures, use the [`or()`] function or the /// [`FutureExt::or()`] method. /// /// # Examples /// /// ``` /// use futures_lite::future::{self, pending, ready}; /// /// # spin_on::spin_on(async { /// assert_eq!(future::race(ready(1), pending()).await, 1); /// assert_eq!(future::race(pending(), ready(2)).await, 2); /// /// // One of the two futures is randomly chosen as the winner. /// let res = future::race(ready(1), ready(2)).await; /// # }) /// ``` #[cfg(feature = "std")] pub fn race<T, F1, F2>(future1: F1, future2: F2) -> Race<F1, F2> where F1: Future<Output = T>, F2: Future<Output = T>, { Race { future1, future2 } } #[cfg(feature = "std")] pin_project! { /// Future for the [`race()`] function and the [`FutureExt::race()`] method. #[derive(Debug)] #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct Race<F1, F2> { #[pin] future1: F1, #[pin] future2: F2, } } #[cfg(feature = "std")] impl<T, F1, F2> Future for Race<F1, F2> where F1: Future<Output = T>, F2: Future<Output = T>, { type Output = T; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> { let this = self.project(); if fastrand::bool() { if let Poll::Ready(t) = this.future1.poll(cx) { return Poll::Ready(t); } if let Poll::Ready(t) = this.future2.poll(cx) { return Poll::Ready(t); } } else { if let Poll::Ready(t) = this.future2.poll(cx) { return Poll::Ready(t); } if let Poll::Ready(t) = this.future1.poll(cx) { return Poll::Ready(t); } } Poll::Pending } } #[cfg(feature = "std")] pin_project! { /// Future for the [`FutureExt::catch_unwind()`] method. #[derive(Debug)] #[must_use = "futures do nothing unless you `.await` or poll them"] pub struct CatchUnwind<F> { #[pin] inner: F, } } #[cfg(feature = "std")] impl<F: Future + UnwindSafe> Future for CatchUnwind<F> { type Output = Result<F::Output, Box<dyn Any + Send>>; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> { let this = self.project(); catch_unwind(AssertUnwindSafe(|| this.inner.poll(cx)))?.map(Ok) } } /// Type alias for `Pin<Box<dyn Future<Output = T> + Send + 'static>>`. /// /// # Examples /// /// ``` /// use futures_lite::future::{self, FutureExt}; /// /// // These two lines are equivalent: /// let f1: future::Boxed<i32> = async { 1 + 2 }.boxed(); /// let f2: future::Boxed<i32> = Box::pin(async { 1 + 2 }); /// ``` #[cfg(feature = "alloc")] pub type Boxed<T> = Pin<Box<dyn Future<Output = T> + Send + 'static>>; /// Type alias for `Pin<Box<dyn Future<Output = T> + 'static>>`. /// /// # Examples /// /// ``` /// use futures_lite::future::{self, FutureExt}; /// /// // These two lines are equivalent: /// let f1: future::BoxedLocal<i32> = async { 1 + 2 }.boxed_local(); /// let f2: future::BoxedLocal<i32> = Box::pin(async { 1 + 2 }); /// ``` #[cfg(feature = "alloc")] pub type BoxedLocal<T> = Pin<Box<dyn Future<Output = T> + 'static>>; /// Extension trait for [`Future`]. pub trait FutureExt: Future { /// A convenience for calling [`Future::poll()`] on `!`[`Unpin`] types. fn poll(&mut self, cx: &mut Context<'_>) -> Poll<Self::Output> where Self: Unpin, { Future::poll(Pin::new(self), cx) } /// Returns the result of `self` or `other` future, preferring `self` if both are ready. /// /// If you need to treat the two futures fairly without a preference for either, use the /// [`race()`] function or the [`FutureExt::race()`] method. /// /// # Examples /// /// ``` /// use futures_lite::future::{pending, ready, FutureExt}; /// /// # spin_on::spin_on(async { /// assert_eq!(ready(1).or(pending()).await, 1); /// assert_eq!(pending().or(ready(2)).await, 2); /// /// // The first future wins. /// assert_eq!(ready(1).or(ready(2)).await, 1); /// # }) /// ``` fn or<F>(self, other: F) -> Or<Self, F> where Self: Sized, F: Future<Output = Self::Output>, { Or { future1: self, future2: other, } } /// Returns the result of `self` or `other` future, with no preference if both are ready. /// /// Each time [`Race`] is polled, the two inner futures are polled in random order. Therefore, /// no future takes precedence over the other if both can complete at the same time. /// /// If you have preference for one of the futures, use the [`or()`] function or the /// [`FutureExt::or()`] method. /// /// # Examples /// /// ``` /// use futures_lite::future::{pending, ready, FutureExt}; /// /// # spin_on::spin_on(async { /// assert_eq!(ready(1).race(pending()).await, 1); /// assert_eq!(pending().race(ready(2)).await, 2); /// /// // One of the two futures is randomly chosen as the winner. /// let res = ready(1).race(ready(2)).await; /// # }) /// ``` #[cfg(feature = "std")] fn race<F>(self, other: F) -> Race<Self, F> where Self: Sized, F: Future<Output = Self::Output>, { Race { future1: self, future2: other, } } /// Catches panics while polling the future. /// /// # Examples /// /// ``` /// use futures_lite::future::FutureExt; /// /// # spin_on::spin_on(async { /// let fut1 = async {}.catch_unwind(); /// let fut2 = async { panic!() }.catch_unwind(); /// /// assert!(fut1.await.is_ok()); /// assert!(fut2.await.is_err()); /// # }) /// ``` #[cfg(feature = "std")] fn catch_unwind(self) -> CatchUnwind<Self> where Self: Sized + UnwindSafe, { CatchUnwind { inner: self } } /// Boxes the future and changes its type to `dyn Future + Send + 'a`. /// /// # Examples /// /// ``` /// use futures_lite::future::{self, FutureExt}; /// /// # spin_on::spin_on(async { /// let a = future::ready('a'); /// let b = future::pending(); /// /// // Futures of different types can be stored in /// // the same collection when they are boxed: /// let futures = vec![a.boxed(), b.boxed()]; /// # }) /// ``` #[cfg(feature = "alloc")] fn boxed<'a>(self) -> Pin<Box<dyn Future<Output = Self::Output> + Send + 'a>> where Self: Sized + Send + 'a, { Box::pin(self) } /// Boxes the future and changes its type to `dyn Future + 'a`. /// /// # Examples /// /// ``` /// use futures_lite::future::{self, FutureExt}; /// /// # spin_on::spin_on(async { /// let a = future::ready('a'); /// let b = future::pending(); /// /// // Futures of different types can be stored in /// // the same collection when they are boxed: /// let futures = vec![a.boxed_local(), b.boxed_local()]; /// # }) /// ``` #[cfg(feature = "alloc")] fn boxed_local<'a>(self) -> Pin<Box<dyn Future<Output = Self::Output> + 'a>> where Self: Sized + 'a, { Box::pin(self) } } impl<F: Future + ?Sized> FutureExt for F {}