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use crate::{
dispatcher::{self, Dispatch},
span::Span,
};
use core::{
future::Future,
marker::Sized,
mem::ManuallyDrop,
pin::Pin,
task::{Context, Poll},
};
use pin_project_lite::pin_project;
/// Attaches spans to a [`std::future::Future`].
///
/// Extension trait allowing futures to be
/// instrumented with a `tracing` [span].
///
/// [span]: super::Span
pub trait Instrument: Sized {
/// Instruments this type with the provided [`Span`], returning an
/// `Instrumented` wrapper.
///
/// The attached [`Span`] will be [entered] every time the instrumented
/// [`Future`] is polled or [`Drop`]ped.
///
/// # Examples
///
/// Instrumenting a future:
///
/// ```rust
/// use tracing::Instrument;
///
/// # async fn doc() {
/// let my_future = async {
/// // ...
/// };
///
/// my_future
/// .instrument(tracing::info_span!("my_future"))
/// .await
/// # }
/// ```
///
/// The [`Span::or_current`] combinator can be used in combination with
/// `instrument` to ensure that the [current span] is attached to the
/// future if the span passed to `instrument` is [disabled]:
///
/// ```
/// use tracing::Instrument;
/// # mod tokio {
/// # pub(super) fn spawn(_: impl std::future::Future) {}
/// # }
///
/// let my_future = async {
/// // ...
/// };
///
/// let outer_span = tracing::info_span!("outer").entered();
///
/// // If the "my_future" span is enabled, then the spawned task will
/// // be within both "my_future" *and* "outer", since "outer" is
/// // "my_future"'s parent. However, if "my_future" is disabled,
/// // the spawned task will *not* be in any span.
/// tokio::spawn(
/// my_future
/// .instrument(tracing::debug_span!("my_future"))
/// );
///
/// // Using `Span::or_current` ensures the spawned task is instrumented
/// // with the current span, if the new span passed to `instrument` is
/// // not enabled. This means that if the "my_future" span is disabled,
/// // the spawned task will still be instrumented with the "outer" span:
/// # let my_future = async {};
/// tokio::spawn(
/// my_future
/// .instrument(tracing::debug_span!("my_future").or_current())
/// );
/// ```
///
/// [entered]: super::Span::enter()
/// [`Span::or_current`]: super::Span::or_current()
/// [current span]: super::Span::current()
/// [disabled]: super::Span::is_disabled()
/// [`Future`]: std::future::Future
fn instrument(self, span: Span) -> Instrumented<Self> {
Instrumented {
inner: ManuallyDrop::new(self),
span,
}
}
/// Instruments this type with the [current] [`Span`], returning an
/// `Instrumented` wrapper.
///
/// The attached [`Span`] will be [entered] every time the instrumented
/// [`Future`] is polled or [`Drop`]ped.
///
/// This can be used to propagate the current span when spawning a new future.
///
/// # Examples
///
/// ```rust
/// use tracing::Instrument;
///
/// # mod tokio {
/// # pub(super) fn spawn(_: impl std::future::Future) {}
/// # }
/// # async fn doc() {
/// let span = tracing::info_span!("my_span");
/// let _enter = span.enter();
///
/// // ...
///
/// let future = async {
/// tracing::debug!("this event will occur inside `my_span`");
/// // ...
/// };
/// tokio::spawn(future.in_current_span());
/// # }
/// ```
///
/// [current]: super::Span::current()
/// [entered]: super::Span::enter()
/// [`Span`]: crate::Span
/// [`Future`]: std::future::Future
#[inline]
fn in_current_span(self) -> Instrumented<Self> {
self.instrument(Span::current())
}
}
/// Extension trait allowing futures to be instrumented with
/// a `tracing` [`Subscriber`](crate::Subscriber).
#[cfg_attr(docsrs, doc(cfg(feature = "std")))]
pub trait WithSubscriber: Sized {
/// Attaches the provided [`Subscriber`] to this type, returning a
/// [`WithDispatch`] wrapper.
///
/// The attached [`Subscriber`] will be set as the [default] when the returned
/// [`Future`] is polled.
///
/// # Examples
///
/// ```
/// # use tracing::subscriber::NoSubscriber as MySubscriber;
/// # use tracing::subscriber::NoSubscriber as MyOtherSubscriber;
/// # async fn docs() {
/// use tracing::instrument::WithSubscriber;
///
/// // Set the default `Subscriber`
/// let _default = tracing::subscriber::set_default(MySubscriber::default());
///
/// tracing::info!("this event will be recorded by the default `Subscriber`");
///
/// // Create a different `Subscriber` and attach it to a future.
/// let other_subscriber = MyOtherSubscriber::default();
/// let future = async {
/// tracing::info!("this event will be recorded by the other `Subscriber`");
/// // ...
/// };
///
/// future
/// // Attach the other `Subscriber` to the future before awaiting it
/// .with_subscriber(other_subscriber)
/// .await;
///
/// // Once the future has completed, we return to the default `Subscriber`.
/// tracing::info!("this event will be recorded by the default `Subscriber`");
/// # }
/// ```
///
/// [`Subscriber`]: super::Subscriber
/// [default]: crate::dispatcher#setting-the-default-subscriber
/// [`Future`]: std::future::Future
fn with_subscriber<S>(self, subscriber: S) -> WithDispatch<Self>
where
S: Into<Dispatch>,
{
WithDispatch {
inner: self,
dispatcher: subscriber.into(),
}
}
/// Attaches the current [default] [`Subscriber`] to this type, returning a
/// [`WithDispatch`] wrapper.
///
/// The attached `Subscriber` will be set as the [default] when the returned
/// [`Future`] is polled.
///
/// This can be used to propagate the current dispatcher context when
/// spawning a new future that may run on a different thread.
///
/// # Examples
///
/// ```
/// # mod tokio {
/// # pub(super) fn spawn(_: impl std::future::Future) {}
/// # }
/// # use tracing::subscriber::NoSubscriber as MySubscriber;
/// # async fn docs() {
/// use tracing::instrument::WithSubscriber;
///
/// // Using `set_default` (rather than `set_global_default`) sets the
/// // default `Subscriber` for *this* thread only.
/// let _default = tracing::subscriber::set_default(MySubscriber::default());
///
/// let future = async {
/// // ...
/// };
///
/// // If a multi-threaded async runtime is in use, this spawned task may
/// // run on a different thread, in a different default `Subscriber`'s context.
/// tokio::spawn(future);
///
/// // However, calling `with_current_subscriber` on the future before
/// // spawning it, ensures that the current thread's default `Subscriber` is
/// // propagated to the spawned task, regardless of where it executes:
/// # let future = async { };
/// tokio::spawn(future.with_current_subscriber());
/// # }
/// ```
/// [`Subscriber`]: super::Subscriber
/// [default]: crate::dispatcher#setting-the-default-subscriber
/// [`Future`]: std::future::Future
#[inline]
fn with_current_subscriber(self) -> WithDispatch<Self> {
WithDispatch {
inner: self,
dispatcher: crate::dispatcher::get_default(|default| default.clone()),
}
}
}
pin_project! {
/// A [`Future`] that has been instrumented with a `tracing` [`Subscriber`].
///
/// This type is returned by the [`WithSubscriber`] extension trait. See that
/// trait's documentation for details.
///
/// [`Future`]: std::future::Future
/// [`Subscriber`]: crate::Subscriber
#[derive(Clone, Debug)]
#[must_use = "futures do nothing unless you `.await` or poll them"]
#[cfg_attr(docsrs, doc(cfg(feature = "std")))]
pub struct WithDispatch<T> {
#[pin]
inner: T,
dispatcher: Dispatch,
}
}
pin_project! {
/// A [`Future`] that has been instrumented with a `tracing` [`Span`].
///
/// This type is returned by the [`Instrument`] extension trait. See that
/// trait's documentation for details.
///
/// [`Future`]: std::future::Future
/// [`Span`]: crate::Span
#[project = InstrumentedProj]
#[project_ref = InstrumentedProjRef]
#[derive(Debug, Clone)]
#[must_use = "futures do nothing unless you `.await` or poll them"]
pub struct Instrumented<T> {
// `ManuallyDrop` is used here to to enter instrument `Drop` by entering
// `Span` and executing `ManuallyDrop::drop`.
#[pin]
inner: ManuallyDrop<T>,
span: Span,
}
impl<T> PinnedDrop for Instrumented<T> {
fn drop(this: Pin<&mut Self>) {
let this = this.project();
let _enter = this.span.enter();
// SAFETY: 1. `Pin::get_unchecked_mut()` is safe, because this isn't
// different from wrapping `T` in `Option` and calling
// `Pin::set(&mut this.inner, None)`, except avoiding
// additional memory overhead.
// 2. `ManuallyDrop::drop()` is safe, because
// `PinnedDrop::drop()` is guaranteed to be called only
// once.
unsafe { ManuallyDrop::drop(this.inner.get_unchecked_mut()) }
}
}
}
impl<'a, T> InstrumentedProj<'a, T> {
/// Get a mutable reference to the [`Span`] a pinned mutable reference to
/// the wrapped type.
fn span_and_inner_pin_mut(self) -> (&'a mut Span, Pin<&'a mut T>) {
// SAFETY: As long as `ManuallyDrop<T>` does not move, `T` won't move
// and `inner` is valid, because `ManuallyDrop::drop` is called
// only inside `Drop` of the `Instrumented`.
let inner = unsafe { self.inner.map_unchecked_mut(|v| &mut **v) };
(self.span, inner)
}
}
impl<'a, T> InstrumentedProjRef<'a, T> {
/// Get a reference to the [`Span`] a pinned reference to the wrapped type.
fn span_and_inner_pin_ref(self) -> (&'a Span, Pin<&'a T>) {
// SAFETY: As long as `ManuallyDrop<T>` does not move, `T` won't move
// and `inner` is valid, because `ManuallyDrop::drop` is called
// only inside `Drop` of the `Instrumented`.
let inner = unsafe { self.inner.map_unchecked(|v| &**v) };
(self.span, inner)
}
}
// === impl Instrumented ===
impl<T: Future> Future for Instrumented<T> {
type Output = T::Output;
fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
let (span, inner) = self.project().span_and_inner_pin_mut();
let _enter = span.enter();
inner.poll(cx)
}
}
impl<T: Sized> Instrument for T {}
impl<T> Instrumented<T> {
/// Borrows the `Span` that this type is instrumented by.
pub fn span(&self) -> &Span {
&self.span
}
/// Mutably borrows the `Span` that this type is instrumented by.
pub fn span_mut(&mut self) -> &mut Span {
&mut self.span
}
/// Borrows the wrapped type.
pub fn inner(&self) -> &T {
&self.inner
}
/// Mutably borrows the wrapped type.
pub fn inner_mut(&mut self) -> &mut T {
&mut self.inner
}
/// Get a pinned reference to the wrapped type.
pub fn inner_pin_ref(self: Pin<&Self>) -> Pin<&T> {
self.project_ref().span_and_inner_pin_ref().1
}
/// Get a pinned mutable reference to the wrapped type.
pub fn inner_pin_mut(self: Pin<&mut Self>) -> Pin<&mut T> {
self.project().span_and_inner_pin_mut().1
}
/// Consumes the `Instrumented`, returning the wrapped type.
///
/// Note that this drops the span.
pub fn into_inner(self) -> T {
// To manually destructure `Instrumented` without `Drop`, we
// move it into a ManuallyDrop and use pointers to its fields
let this = ManuallyDrop::new(self);
let span: *const Span = &this.span;
let inner: *const ManuallyDrop<T> = &this.inner;
// SAFETY: Those pointers are valid for reads, because `Drop` didn't
// run, and properly aligned, because `Instrumented` isn't
// `#[repr(packed)]`.
let _span = unsafe { span.read() };
let inner = unsafe { inner.read() };
ManuallyDrop::into_inner(inner)
}
}
// === impl WithDispatch ===
#[cfg(feature = "std")]
#[cfg_attr(docsrs, doc(cfg(feature = "std")))]
impl<T: Future> Future for WithDispatch<T> {
type Output = T::Output;
fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
let this = self.project();
let dispatcher = this.dispatcher;
let future = this.inner;
let _default = dispatcher::set_default(dispatcher);
future.poll(cx)
}
}
#[cfg_attr(docsrs, doc(cfg(feature = "std")))]
impl<T: Sized> WithSubscriber for T {}
#[cfg(feature = "std")]
#[cfg_attr(docsrs, doc(cfg(feature = "std")))]
impl<T> WithDispatch<T> {
/// Borrows the [`Dispatch`] that is entered when this type is polled.
pub fn dispatcher(&self) -> &Dispatch {
&self.dispatcher
}
/// Borrows the wrapped type.
pub fn inner(&self) -> &T {
&self.inner
}
/// Mutably borrows the wrapped type.
pub fn inner_mut(&mut self) -> &mut T {
&mut self.inner
}
/// Get a pinned reference to the wrapped type.
pub fn inner_pin_ref(self: Pin<&Self>) -> Pin<&T> {
self.project_ref().inner
}
/// Get a pinned mutable reference to the wrapped type.
pub fn inner_pin_mut(self: Pin<&mut Self>) -> Pin<&mut T> {
self.project().inner
}
/// Consumes the `Instrumented`, returning the wrapped type.
///
/// Note that this drops the span.
pub fn into_inner(self) -> T {
self.inner
}
}