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#![allow(
clippy::cognitive_complexity,
clippy::large_enum_variant,
clippy::needless_doctest_main
)]
#![warn(
missing_debug_implementations,
missing_docs,
rust_2018_idioms,
unreachable_pub
)]
#![deny(unused_must_use)]
#![doc(test(
no_crate_inject,
attr(deny(warnings, rust_2018_idioms), allow(dead_code, unused_variables))
))]
#![cfg_attr(docsrs, feature(doc_cfg))]
#![cfg_attr(docsrs, allow(unused_attributes))]
#![cfg_attr(loom, allow(dead_code, unreachable_pub))]
//! A runtime for writing reliable network applications without compromising speed.
//!
//! Tokio is an event-driven, non-blocking I/O platform for writing asynchronous
//! applications with the Rust programming language. At a high level, it
//! provides a few major components:
//!
//! * Tools for [working with asynchronous tasks][tasks], including
//! [synchronization primitives and channels][sync] and [timeouts, sleeps, and
//! intervals][time].
//! * APIs for [performing asynchronous I/O][io], including [TCP and UDP][net] sockets,
//! [filesystem][fs] operations, and [process] and [signal] management.
//! * A [runtime] for executing asynchronous code, including a task scheduler,
//! an I/O driver backed by the operating system's event queue (epoll, kqueue,
//! IOCP, etc...), and a high performance timer.
//!
//! Guide level documentation is found on the [website].
//!
//! [tasks]: #working-with-tasks
//! [sync]: crate::sync
//! [time]: crate::time
//! [io]: #asynchronous-io
//! [net]: crate::net
//! [fs]: crate::fs
//! [process]: crate::process
//! [signal]: crate::signal
//! [fs]: crate::fs
//! [runtime]: crate::runtime
//! [website]: https://tokio.rs/tokio/tutorial
//!
//! # A Tour of Tokio
//!
//! Tokio consists of a number of modules that provide a range of functionality
//! essential for implementing asynchronous applications in Rust. In this
//! section, we will take a brief tour of Tokio, summarizing the major APIs and
//! their uses.
//!
//! The easiest way to get started is to enable all features. Do this by
//! enabling the `full` feature flag:
//!
//! ```toml
//! tokio = { version = "1", features = ["full"] }
//! ```
//!
//! ### Authoring applications
//!
//! Tokio is great for writing applications and most users in this case shouldn't
//! worry too much about what features they should pick. If you're unsure, we suggest
//! going with `full` to ensure that you don't run into any road blocks while you're
//! building your application.
//!
//! #### Example
//!
//! This example shows the quickest way to get started with Tokio.
//!
//! ```toml
//! tokio = { version = "1", features = ["full"] }
//! ```
//!
//! ### Authoring libraries
//!
//! As a library author your goal should be to provide the lightest weight crate
//! that is based on Tokio. To achieve this you should ensure that you only enable
//! the features you need. This allows users to pick up your crate without having
//! to enable unnecessary features.
//!
//! #### Example
//!
//! This example shows how you may want to import features for a library that just
//! needs to `tokio::spawn` and use a `TcpStream`.
//!
//! ```toml
//! tokio = { version = "1", features = ["rt", "net"] }
//! ```
//!
//! ## Working With Tasks
//!
//! Asynchronous programs in Rust are based around lightweight, non-blocking
//! units of execution called [_tasks_][tasks]. The [`tokio::task`] module provides
//! important tools for working with tasks:
//!
//! * The [`spawn`] function and [`JoinHandle`] type, for scheduling a new task
//! on the Tokio runtime and awaiting the output of a spawned task, respectively,
//! * Functions for [running blocking operations][blocking] in an asynchronous
//! task context.
//!
//! The [`tokio::task`] module is present only when the "rt" feature flag
//! is enabled.
//!
//! [tasks]: task/index.html#what-are-tasks
//! [`tokio::task`]: crate::task
//! [`spawn`]: crate::task::spawn()
//! [`JoinHandle`]: crate::task::JoinHandle
//! [blocking]: task/index.html#blocking-and-yielding
//!
//! The [`tokio::sync`] module contains synchronization primitives to use when
//! needing to communicate or share data. These include:
//!
//! * channels ([`oneshot`], [`mpsc`], [`watch`], and [`broadcast`]), for sending values
//! between tasks,
//! * a non-blocking [`Mutex`], for controlling access to a shared, mutable
//! value,
//! * an asynchronous [`Barrier`] type, for multiple tasks to synchronize before
//! beginning a computation.
//!
//! The `tokio::sync` module is present only when the "sync" feature flag is
//! enabled.
//!
//! [`tokio::sync`]: crate::sync
//! [`Mutex`]: crate::sync::Mutex
//! [`Barrier`]: crate::sync::Barrier
//! [`oneshot`]: crate::sync::oneshot
//! [`mpsc`]: crate::sync::mpsc
//! [`watch`]: crate::sync::watch
//! [`broadcast`]: crate::sync::broadcast
//!
//! The [`tokio::time`] module provides utilities for tracking time and
//! scheduling work. This includes functions for setting [timeouts][timeout] for
//! tasks, [sleeping][sleep] work to run in the future, or [repeating an operation at an
//! interval][interval].
//!
//! In order to use `tokio::time`, the "time" feature flag must be enabled.
//!
//! [`tokio::time`]: crate::time
//! [sleep]: crate::time::sleep()
//! [interval]: crate::time::interval()
//! [timeout]: crate::time::timeout()
//!
//! Finally, Tokio provides a _runtime_ for executing asynchronous tasks. Most
//! applications can use the [`#[tokio::main]`][main] macro to run their code on the
//! Tokio runtime. However, this macro provides only basic configuration options. As
//! an alternative, the [`tokio::runtime`] module provides more powerful APIs for configuring
//! and managing runtimes. You should use that module if the `#[tokio::main]` macro doesn't
//! provide the functionality you need.
//!
//! Using the runtime requires the "rt" or "rt-multi-thread" feature flags, to
//! enable the current-thread [single-threaded scheduler][rt] and the [multi-thread
//! scheduler][rt-multi-thread], respectively. See the [`runtime` module
//! documentation][rt-features] for details. In addition, the "macros" feature
//! flag enables the `#[tokio::main]` and `#[tokio::test]` attributes.
//!
//! [main]: attr.main.html
//! [`tokio::runtime`]: crate::runtime
//! [`Builder`]: crate::runtime::Builder
//! [`Runtime`]: crate::runtime::Runtime
//! [rt]: runtime/index.html#current-thread-scheduler
//! [rt-multi-thread]: runtime/index.html#multi-thread-scheduler
//! [rt-features]: runtime/index.html#runtime-scheduler
//!
//! ## CPU-bound tasks and blocking code
//!
//! Tokio is able to concurrently run many tasks on a few threads by repeatedly
//! swapping the currently running task on each thread. However, this kind of
//! swapping can only happen at `.await` points, so code that spends a long time
//! without reaching an `.await` will prevent other tasks from running. To
//! combat this, Tokio provides two kinds of threads: Core threads and blocking
//! threads. The core threads are where all asynchronous code runs, and Tokio
//! will by default spawn one for each CPU core. The blocking threads are
//! spawned on demand, can be used to run blocking code that would otherwise
//! block other tasks from running and are kept alive when not used for a certain
//! amount of time which can be configured with [`thread_keep_alive`].
//! Since it is not possible for Tokio to swap out blocking tasks, like it
//! can do with asynchronous code, the upper limit on the number of blocking
//! threads is very large. These limits can be configured on the [`Builder`].
//!
//! To spawn a blocking task, you should use the [`spawn_blocking`] function.
//!
//! [`Builder`]: crate::runtime::Builder
//! [`spawn_blocking`]: crate::task::spawn_blocking()
//! [`thread_keep_alive`]: crate::runtime::Builder::thread_keep_alive()
//!
//! ```
//! #[tokio::main]
//! async fn main() {
//! // This is running on a core thread.
//!
//! let blocking_task = tokio::task::spawn_blocking(|| {
//! // This is running on a blocking thread.
//! // Blocking here is ok.
//! });
//!
//! // We can wait for the blocking task like this:
//! // If the blocking task panics, the unwrap below will propagate the
//! // panic.
//! blocking_task.await.unwrap();
//! }
//! ```
//!
//! If your code is CPU-bound and you wish to limit the number of threads used
//! to run it, you should use a separate thread pool dedicated to CPU bound tasks.
//! For example, you could consider using the [rayon] library for CPU-bound
//! tasks. It is also possible to create an extra Tokio runtime dedicated to
//! CPU-bound tasks, but if you do this, you should be careful that the extra
//! runtime runs _only_ CPU-bound tasks, as IO-bound tasks on that runtime
//! will behave poorly.
//!
//! Hint: If using rayon, you can use a [`oneshot`] channel to send the result back
//! to Tokio when the rayon task finishes.
//!
//! [rayon]: https://docs.rs/rayon
//! [`oneshot`]: crate::sync::oneshot
//!
//! ## Asynchronous IO
//!
//! As well as scheduling and running tasks, Tokio provides everything you need
//! to perform input and output asynchronously.
//!
//! The [`tokio::io`] module provides Tokio's asynchronous core I/O primitives,
//! the [`AsyncRead`], [`AsyncWrite`], and [`AsyncBufRead`] traits. In addition,
//! when the "io-util" feature flag is enabled, it also provides combinators and
//! functions for working with these traits, forming as an asynchronous
//! counterpart to [`std::io`].
//!
//! Tokio also includes APIs for performing various kinds of I/O and interacting
//! with the operating system asynchronously. These include:
//!
//! * [`tokio::net`], which contains non-blocking versions of [TCP], [UDP], and
//! [Unix Domain Sockets][UDS] (enabled by the "net" feature flag),
//! * [`tokio::fs`], similar to [`std::fs`] but for performing filesystem I/O
//! asynchronously (enabled by the "fs" feature flag),
//! * [`tokio::signal`], for asynchronously handling Unix and Windows OS signals
//! (enabled by the "signal" feature flag),
//! * [`tokio::process`], for spawning and managing child processes (enabled by
//! the "process" feature flag).
//!
//! [`tokio::io`]: crate::io
//! [`AsyncRead`]: crate::io::AsyncRead
//! [`AsyncWrite`]: crate::io::AsyncWrite
//! [`AsyncBufRead`]: crate::io::AsyncBufRead
//! [`std::io`]: std::io
//! [`tokio::net`]: crate::net
//! [TCP]: crate::net::tcp
//! [UDP]: crate::net::UdpSocket
//! [UDS]: crate::net::unix
//! [`tokio::fs`]: crate::fs
//! [`std::fs`]: std::fs
//! [`tokio::signal`]: crate::signal
//! [`tokio::process`]: crate::process
//!
//! # Examples
//!
//! A simple TCP echo server:
//!
//! ```no_run
//! use tokio::net::TcpListener;
//! use tokio::io::{AsyncReadExt, AsyncWriteExt};
//!
//! #[tokio::main]
//! async fn main() -> Result<(), Box<dyn std::error::Error>> {
//! let listener = TcpListener::bind("127.0.0.1:8080").await?;
//!
//! loop {
//! let (mut socket, _) = listener.accept().await?;
//!
//! tokio::spawn(async move {
//! let mut buf = [0; 1024];
//!
//! // In a loop, read data from the socket and write the data back.
//! loop {
//! let n = match socket.read(&mut buf).await {
//! // socket closed
//! Ok(n) if n == 0 => return,
//! Ok(n) => n,
//! Err(e) => {
//! eprintln!("failed to read from socket; err = {:?}", e);
//! return;
//! }
//! };
//!
//! // Write the data back
//! if let Err(e) = socket.write_all(&buf[0..n]).await {
//! eprintln!("failed to write to socket; err = {:?}", e);
//! return;
//! }
//! }
//! });
//! }
//! }
//! ```
//!
//! ## Feature flags
//!
//! Tokio uses a set of [feature flags] to reduce the amount of compiled code. It
//! is possible to just enable certain features over others. By default, Tokio
//! does not enable any features but allows one to enable a subset for their use
//! case. Below is a list of the available feature flags. You may also notice
//! above each function, struct and trait there is listed one or more feature flags
//! that are required for that item to be used. If you are new to Tokio it is
//! recommended that you use the `full` feature flag which will enable all public APIs.
//! Beware though that this will pull in many extra dependencies that you may not
//! need.
//!
//! - `full`: Enables all features listed below except `test-util` and `tracing`.
//! - `rt`: Enables `tokio::spawn`, the current-thread scheduler,
//! and non-scheduler utilities.
//! - `rt-multi-thread`: Enables the heavier, multi-threaded, work-stealing scheduler.
//! - `io-util`: Enables the IO based `Ext` traits.
//! - `io-std`: Enable `Stdout`, `Stdin` and `Stderr` types.
//! - `net`: Enables `tokio::net` types such as `TcpStream`, `UnixStream` and
//! `UdpSocket`, as well as (on Unix-like systems) `AsyncFd` and (on
//! FreeBSD) `PollAio`.
//! - `time`: Enables `tokio::time` types and allows the schedulers to enable
//! the built in timer.
//! - `process`: Enables `tokio::process` types.
//! - `macros`: Enables `#[tokio::main]` and `#[tokio::test]` macros.
//! - `sync`: Enables all `tokio::sync` types.
//! - `signal`: Enables all `tokio::signal` types.
//! - `fs`: Enables `tokio::fs` types.
//! - `test-util`: Enables testing based infrastructure for the Tokio runtime.
//!
//! _Note: `AsyncRead` and `AsyncWrite` traits do not require any features and are
//! always available._
//!
//! ### Internal features
//!
//! These features do not expose any new API, but influence internal
//! implementation aspects of Tokio, and can pull in additional
//! dependencies.
//!
//! - `parking_lot`: As a potential optimization, use the _parking_lot_ crate's
//! synchronization primitives internally. MSRV may increase according to the
//! _parking_lot_ release in use.
//!
//! ### Unstable features
//!
//! Some feature flags are only available when specifying the `tokio_unstable` flag:
//!
//! - `tracing`: Enables tracing events.
//!
//! Likewise, some parts of the API are only available with the same flag:
//!
//! - [`task::Builder`]
//! - Some methods on [`task::JoinSet`]
//! - [`runtime::RuntimeMetrics`]
//! - [`runtime::Builder::unhandled_panic`]
//! - [`task::Id`]
//!
//! This flag enables **unstable** features. The public API of these features
//! may break in 1.x releases. To enable these features, the `--cfg
//! tokio_unstable` argument must be passed to `rustc` when compiling. This
//! serves to explicitly opt-in to features which may break semver conventions,
//! since Cargo [does not yet directly support such opt-ins][unstable features].
//!
//! You can specify it in your project's `.cargo/config.toml` file:
//!
//! ```toml
//! [build]
//! rustflags = ["--cfg", "tokio_unstable"]
//! ```
//!
//! Alternatively, you can specify it with an environment variable:
//!
//! ```sh
//! ## Many *nix shells:
//! export RUSTFLAGS="--cfg tokio_unstable"
//! cargo build
//! ```
//!
//! ```powershell
//! ## Windows PowerShell:
//! $Env:RUSTFLAGS="--cfg tokio_unstable"
//! cargo build
//! ```
//!
//! [unstable features]: https://internals.rust-lang.org/t/feature-request-unstable-opt-in-non-transitive-crate-features/16193#why-not-a-crate-feature-2
//! [feature flags]: https://doc.rust-lang.org/cargo/reference/manifest.html#the-features-section
//!
//! ## WASM support
//!
//! Tokio has some limited support for the WASM platform. Without the
//! `tokio_unstable` flag, the following features are supported:
//!
//! * `sync`
//! * `macros`
//! * `io-util`
//! * `rt`
//! * `time`
//!
//! Enabling any other feature (including `full`) will cause a compilation
//! failure.
//!
//! The `time` module will only work on WASM platforms that have support for
//! timers (e.g. wasm32-wasi). The timing functions will panic if used on a WASM
//! platform that does not support timers.
//!
//! Note also that if the runtime becomes indefinitely idle, it will panic
//! immediately instead of blocking forever. On platforms that don't support
//! time, this means that the runtime can never be idle in any way.
//!
//! ### Unstable WASM support
//!
//! Tokio also has unstable support for some additional WASM features. This
//! requires the use of the `tokio_unstable` flag.
//!
//! Using this flag enables the use of `tokio::net` on the wasm32-wasi target.
//! However, not all methods are available on the networking types as WASI
//! currently does not support the creation of new sockets from within WASM.
//! Because of this, sockets must currently be created via the `FromRawFd`
//! trait.
// Test that pointer width is compatible. This asserts that e.g. usize is at
// least 32 bits, which a lot of components in Tokio currently assumes.
//
// TODO: improve once we have MSRV access to const eval to make more flexible.
#[cfg(not(any(
target_pointer_width = "32",
target_pointer_width = "64",
target_pointer_width = "128"
)))]
compile_error! {
"Tokio requires the platform pointer width to be 32, 64, or 128 bits"
}
// Ensure that our build script has correctly set cfg flags for wasm.
//
// Each condition is written all(a, not(b)). This should be read as
// "if a, then we must also have b".
#[cfg(any(
all(target_arch = "wasm32", not(tokio_wasm)),
all(target_arch = "wasm64", not(tokio_wasm)),
all(target_family = "wasm", not(tokio_wasm)),
all(target_os = "wasi", not(tokio_wasm)),
all(target_os = "wasi", not(tokio_wasi)),
all(target_os = "wasi", tokio_wasm_not_wasi),
all(tokio_wasm, not(any(target_arch = "wasm32", target_arch = "wasm64"))),
all(tokio_wasm_not_wasi, not(tokio_wasm)),
all(tokio_wasi, not(tokio_wasm))
))]
compile_error!("Tokio's build script has incorrectly detected wasm.");
#[cfg(all(
not(tokio_unstable),
tokio_wasm,
any(
feature = "fs",
feature = "io-std",
feature = "net",
feature = "process",
feature = "rt-multi-thread",
feature = "signal"
)
))]
compile_error!("Only features sync,macros,io-util,rt,time are supported on wasm.");
// Includes re-exports used by macros.
//
// This module is not intended to be part of the public API. In general, any
// `doc(hidden)` code is not part of Tokio's public and stable API.
#[macro_use]
#[doc(hidden)]
pub mod macros;
cfg_fs! {
pub mod fs;
}
mod future;
pub mod io;
pub mod net;
mod loom;
mod park;
cfg_process! {
pub mod process;
}
#[cfg(any(
feature = "fs",
feature = "io-std",
feature = "net",
all(windows, feature = "process"),
))]
mod blocking;
cfg_rt! {
pub mod runtime;
}
cfg_not_rt! {
cfg_io_driver_impl! {
pub(crate) mod runtime;
}
}
pub(crate) mod coop;
cfg_signal! {
pub mod signal;
}
cfg_signal_internal! {
#[cfg(not(feature = "signal"))]
#[allow(dead_code)]
#[allow(unreachable_pub)]
pub(crate) mod signal;
}
cfg_sync! {
pub mod sync;
}
cfg_not_sync! {
mod sync;
}
pub mod task;
cfg_rt! {
pub use task::spawn;
}
cfg_time! {
pub mod time;
}
mod util;
/// Due to the `Stream` trait's inclusion in `std` landing later than Tokio's 1.0
/// release, most of the Tokio stream utilities have been moved into the [`tokio-stream`]
/// crate.
///
/// # Why was `Stream` not included in Tokio 1.0?
///
/// Originally, we had planned to ship Tokio 1.0 with a stable `Stream` type
/// but unfortunately the [RFC] had not been merged in time for `Stream` to
/// reach `std` on a stable compiler in time for the 1.0 release of Tokio. For
/// this reason, the team has decided to move all `Stream` based utilities to
/// the [`tokio-stream`] crate. While this is not ideal, once `Stream` has made
/// it into the standard library and the MSRV period has passed, we will implement
/// stream for our different types.
///
/// While this may seem unfortunate, not all is lost as you can get much of the
/// `Stream` support with `async/await` and `while let` loops. It is also possible
/// to create a `impl Stream` from `async fn` using the [`async-stream`] crate.
///
/// [`tokio-stream`]: https://docs.rs/tokio-stream
/// [`async-stream`]: https://docs.rs/async-stream
/// [RFC]: https://github.com/rust-lang/rfcs/pull/2996
///
/// # Example
///
/// Convert a [`sync::mpsc::Receiver`] to an `impl Stream`.
///
/// ```rust,no_run
/// use tokio::sync::mpsc;
///
/// let (tx, mut rx) = mpsc::channel::<usize>(16);
///
/// let stream = async_stream::stream! {
/// while let Some(item) = rx.recv().await {
/// yield item;
/// }
/// };
/// ```
pub mod stream {}
// local re-exports of platform specific things, allowing for decent
// documentation to be shimmed in on docs.rs
#[cfg(docsrs)]
pub mod doc;
#[cfg(docsrs)]
#[allow(unused)]
pub(crate) use self::doc::os;
#[cfg(not(docsrs))]
#[allow(unused)]
pub(crate) use std::os;
#[cfg(docsrs)]
#[allow(unused)]
pub(crate) use self::doc::winapi;
#[cfg(all(not(docsrs), windows, feature = "net"))]
#[allow(unused)]
pub(crate) use winapi;
cfg_macros! {
/// Implementation detail of the `select!` macro. This macro is **not**
/// intended to be used as part of the public API and is permitted to
/// change.
#[doc(hidden)]
pub use tokio_macros::select_priv_declare_output_enum;
/// Implementation detail of the `select!` macro. This macro is **not**
/// intended to be used as part of the public API and is permitted to
/// change.
#[doc(hidden)]
pub use tokio_macros::select_priv_clean_pattern;
cfg_rt! {
#[cfg(feature = "rt-multi-thread")]
#[cfg(not(test))] // Work around for rust-lang/rust#62127
#[cfg_attr(docsrs, doc(cfg(feature = "macros")))]
#[doc(inline)]
pub use tokio_macros::main;
#[cfg(feature = "rt-multi-thread")]
#[cfg_attr(docsrs, doc(cfg(feature = "macros")))]
#[doc(inline)]
pub use tokio_macros::test;
cfg_not_rt_multi_thread! {
#[cfg(not(test))] // Work around for rust-lang/rust#62127
#[doc(inline)]
pub use tokio_macros::main_rt as main;
#[doc(inline)]
pub use tokio_macros::test_rt as test;
}
}
// Always fail if rt is not enabled.
cfg_not_rt! {
#[cfg(not(test))]
#[doc(inline)]
pub use tokio_macros::main_fail as main;
#[doc(inline)]
pub use tokio_macros::test_fail as test;
}
}
// TODO: rm
#[cfg(feature = "io-util")]
#[cfg(test)]
fn is_unpin<T: Unpin>() {}