#[repr(transparent)]
#[derive(Copy, Clone)]
pub struct Pin<P> {
- pointer: P,
+ // FIXME(#93176): this field is made `#[unstable] #[doc(hidden)] pub` to:
+ // - deter downstream users from accessing it (which would be unsound!),
+ // - let the `pin!` macro access it (such a macro requires using struct
+ // literal syntax in order to benefit from lifetime extension).
+ // Long-term, `unsafe` fields or macro hygiene are expected to offer more robust alternatives.
+ #[unstable(feature = "unsafe_pin_internals", issue = "none")]
+ #[doc(hidden)]
+ pub pointer: P,
}
// The following implementations aren't derived in order to avoid soundness
///
/// ["pinning projections"]: self#projections-and-structural-pinning
#[inline(always)]
+ #[must_use]
#[rustc_const_unstable(feature = "const_pin", issue = "76654")]
#[stable(feature = "pin", since = "1.33.0")]
pub const fn get_ref(self) -> &'a T {
#[stable(feature = "pin", since = "1.33.0")]
impl<P, U> DispatchFromDyn<Pin<U>> for Pin<P> where P: DispatchFromDyn<U> {}
+
+/// Constructs a <code>[Pin]<[&mut] T></code>, by pinning[^1] a `value: T` _locally_[^2].
+///
+/// Unlike [`Box::pin`], this does not involve a heap allocation.
+///
+/// [^1]: If the (type `T` of the) given value does not implement [`Unpin`], then this
+/// effectively pins the `value` in memory, where it will be unable to be moved.
+/// Otherwise, <code>[Pin]<[&mut] T></code> behaves like <code>[&mut] T</code>, and operations such
+/// as [`mem::replace()`][crate::mem::replace] will allow extracting that value, and therefore,
+/// moving it.
+/// See [the `Unpin` section of the `pin` module][self#unpin] for more info.
+///
+/// [^2]: This is usually dubbed "stack"-pinning. And whilst local values are almost always located
+/// in the stack (_e.g._, when within the body of a non-`async` function), the truth is that inside
+/// the body of an `async fn` or block —more generally, the body of a generator— any locals crossing
+/// an `.await` point —a `yield` point— end up being part of the state captured by the `Future` —by
+/// the `Generator`—, and thus will be stored wherever that one is.
+///
+/// ## Examples
+///
+/// ### Basic usage
+///
+/// ```rust
+/// #![feature(pin_macro)]
+/// # use core::marker::PhantomPinned as Foo;
+/// use core::pin::{pin, Pin};
+///
+/// fn stuff(foo: Pin<&mut Foo>) {
+/// // …
+/// # let _ = foo;
+/// }
+///
+/// let pinned_foo = pin!(Foo { /* … */ });
+/// stuff(pinned_foo);
+/// // or, directly:
+/// stuff(pin!(Foo { /* … */ }));
+/// ```
+///
+/// ### Manually polling a `Future` (wihout `Unpin` bounds)
+///
+/// ```rust
+/// #![feature(pin_macro)]
+/// use std::{
+/// future::Future,
+/// pin::pin,
+/// task::{Context, Poll},
+/// thread,
+/// };
+/// # use std::{sync::Arc, task::Wake, thread::Thread};
+///
+/// # /// A waker that wakes up the current thread when called.
+/// # struct ThreadWaker(Thread);
+/// #
+/// # impl Wake for ThreadWaker {
+/// # fn wake(self: Arc<Self>) {
+/// # self.0.unpark();
+/// # }
+/// # }
+/// #
+/// /// Runs a future to completion.
+/// fn block_on<Fut: Future>(fut: Fut) -> Fut::Output {
+/// let waker_that_unparks_thread = // …
+/// # Arc::new(ThreadWaker(thread::current())).into();
+/// let mut cx = Context::from_waker(&waker_that_unparks_thread);
+/// // Pin the future so it can be polled.
+/// let mut pinned_fut = pin!(fut);
+/// loop {
+/// match pinned_fut.as_mut().poll(&mut cx) {
+/// Poll::Pending => thread::park(),
+/// Poll::Ready(res) => return res,
+/// }
+/// }
+/// }
+/// #
+/// # assert_eq!(42, block_on(async { 42 }));
+/// ```
+///
+/// ### With `Generator`s
+///
+/// ```rust
+/// #![feature(generators, generator_trait, pin_macro)]
+/// use core::{
+/// ops::{Generator, GeneratorState},
+/// pin::pin,
+/// };
+///
+/// fn generator_fn() -> impl Generator<Yield = usize, Return = ()> /* not Unpin */ {
+/// // Allow generator to be self-referential (not `Unpin`)
+/// // vvvvvv so that locals can cross yield points.
+/// static || {
+/// let foo = String::from("foo"); // --+
+/// yield 0; // | <- crosses yield point!
+/// println!("{}", &foo); // <----------+
+/// yield foo.len();
+/// }
+/// }
+///
+/// fn main() {
+/// let mut generator = pin!(generator_fn());
+/// match generator.as_mut().resume(()) {
+/// GeneratorState::Yielded(0) => {},
+/// _ => unreachable!(),
+/// }
+/// match generator.as_mut().resume(()) {
+/// GeneratorState::Yielded(3) => {},
+/// _ => unreachable!(),
+/// }
+/// match generator.resume(()) {
+/// GeneratorState::Yielded(_) => unreachable!(),
+/// GeneratorState::Complete(()) => {},
+/// }
+/// }
+/// ```
+///
+/// ## Remarks
+///
+/// Precisely because a value is pinned to local storage, the resulting <code>[Pin]<[&mut] T></code>
+/// reference ends up borrowing a local tied to that block: it can't escape it.
+///
+/// The following, for instance, fails to compile:
+///
+/// ```rust,compile_fail
+/// #![feature(pin_macro)]
+/// use core::pin::{pin, Pin};
+/// # use core::{marker::PhantomPinned as Foo, mem::drop as stuff};
+///
+/// let x: Pin<&mut Foo> = {
+/// let x: Pin<&mut Foo> = pin!(Foo { /* … */ });
+/// x
+/// }; // <- Foo is dropped
+/// stuff(x); // Error: use of dropped value
+/// ```
+///
+/// <details><summary>Error message</summary>
+///
+/// ```console
+/// error[E0716]: temporary value dropped while borrowed
+/// --> src/main.rs:9:28
+/// |
+/// 8 | let x: Pin<&mut Foo> = {
+/// | - borrow later stored here
+/// 9 | let x: Pin<&mut Foo> = pin!(Foo { /* … */ });
+/// | ^^^^^^^^^^^^^^^^^^^^^ creates a temporary which is freed while still in use
+/// 10 | x
+/// 11 | }; // <- Foo is dropped
+/// | - temporary value is freed at the end of this statement
+/// |
+/// = note: consider using a `let` binding to create a longer lived value
+/// ```
+///
+/// </details>
+///
+/// This makes [`pin!`] **unsuitable to pin values when intending to _return_ them**. Instead, the
+/// value is expected to be passed around _unpinned_ until the point where it is to be consumed,
+/// where it is then useful and even sensible to pin the value locally using [`pin!`].
+///
+/// If you really need to return a pinned value, consider using [`Box::pin`] instead.
+///
+/// On the other hand, pinning to the stack[<sup>2</sup>](#fn2) using [`pin!`] is likely to be
+/// cheaper than pinning into a fresh heap allocation using [`Box::pin`]. Moreover, by virtue of not
+/// even needing an allocator, [`pin!`] is the main non-`unsafe` `#![no_std]`-compatible [`Pin`]
+/// constructor.
+///
+/// [`Box::pin`]: ../../std/boxed/struct.Box.html#method.pin
+#[unstable(feature = "pin_macro", issue = "93178")]
+#[rustc_macro_transparency = "semitransparent"]
+#[allow_internal_unstable(unsafe_pin_internals)]
+pub macro pin($value:expr $(,)?) {
+ // This is `Pin::new_unchecked(&mut { $value })`, so, for starters, let's
+ // review such a hypothetical macro (that any user-code could define):
+ //
+ // ```rust
+ // macro_rules! pin {( $value:expr ) => (
+ // match &mut { $value } { at_value => unsafe { // Do not wrap `$value` in an `unsafe` block.
+ // $crate::pin::Pin::<&mut _>::new_unchecked(at_value)
+ // }}
+ // )}
+ // ```
+ //
+ // Safety:
+ // - `type P = &mut _`. There are thus no pathological `Deref{,Mut}` impls
+ // that would break `Pin`'s invariants.
+ // - `{ $value }` is braced, making it a _block expression_, thus **moving**
+ // the given `$value`, and making it _become an **anonymous** temporary_.
+ // By virtue of being anonynomous, it can no longer be accessed, thus
+ // preventing any attemps to `mem::replace` it or `mem::forget` it, _etc._
+ //
+ // This gives us a `pin!` definition that is sound, and which works, but only
+ // in certain scenarios:
+ // - If the `pin!(value)` expression is _directly_ fed to a function call:
+ // `let poll = pin!(fut).poll(cx);`
+ // - If the `pin!(value)` expression is part of a scrutinee:
+ // ```rust
+ // match pin!(fut) { pinned_fut => {
+ // pinned_fut.as_mut().poll(...);
+ // pinned_fut.as_mut().poll(...);
+ // }} // <- `fut` is dropped here.
+ // ```
+ // Alas, it doesn't work for the more straight-forward use-case: `let` bindings.
+ // ```rust
+ // let pinned_fut = pin!(fut); // <- temporary value is freed at the end of this statement
+ // pinned_fut.poll(...) // error[E0716]: temporary value dropped while borrowed
+ // // note: consider using a `let` binding to create a longer lived value
+ // ```
+ // - Issues such as this one are the ones motivating https://github.com/rust-lang/rfcs/pull/66
+ //
+ // This makes such a macro incredibly unergonomic in practice, and the reason most macros
+ // out there had to take the path of being a statement/binding macro (_e.g._, `pin!(future);`)
+ // instead of featuring the more intuitive ergonomics of an expression macro.
+ //
+ // Luckily, there is a way to avoid the problem. Indeed, the problem stems from the fact that a
+ // temporary is dropped at the end of its enclosing statement when it is part of the parameters
+ // given to function call, which has precisely been the case with our `Pin::new_unchecked()`!
+ // For instance,
+ // ```rust
+ // let p = Pin::new_unchecked(&mut <temporary>);
+ // ```
+ // becomes:
+ // ```rust
+ // let p = { let mut anon = <temporary>; &mut anon };
+ // ```
+ //
+ // However, when using a literal braced struct to construct the value, references to temporaries
+ // can then be taken. This makes Rust change the lifespan of such temporaries so that they are,
+ // instead, dropped _at the end of the enscoping block_.
+ // For instance,
+ // ```rust
+ // let p = Pin { pointer: &mut <temporary> };
+ // ```
+ // becomes:
+ // ```rust
+ // let mut anon = <temporary>;
+ // let p = Pin { pointer: &mut anon };
+ // ```
+ // which is *exactly* what we want.
+ //
+ // See https://doc.rust-lang.org/1.58.1/reference/destructors.html#temporary-lifetime-extension
+ // for more info.
+ $crate::pin::Pin::<&mut _> { pointer: &mut { $value } }
+}