Expand description
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, including synchronization primitives and channels and timeouts, sleeps, and intervals.
- APIs for performing asynchronous I/O, including TCP and UDP sockets, filesystem 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.
§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:
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.
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
.
tokio = { version = "1", features = ["rt", "net"] }
§Working With Tasks
Asynchronous programs in Rust are based around lightweight, non-blocking
units of execution called tasks. The tokio::task
module provides
important tools for working with tasks:
- The
spawn
function andJoinHandle
type, for scheduling a new task on the Tokio runtime and awaiting the output of a spawned task, respectively, - Functions for running blocking operations in an asynchronous task context.
The tokio::task
module is present only when the “rt” feature flag
is enabled.
The tokio::sync
module contains synchronization primitives to use when
needing to communicate or share data. These include:
- channels (
oneshot
,mpsc
,watch
, andbroadcast
), 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.
The tokio::time
module provides utilities for tracking time and
scheduling work. This includes functions for setting timeouts for
tasks, sleeping work to run in the future, or repeating an operation at an
interval.
In order to use tokio::time
, the “time” feature flag must be enabled.
Finally, Tokio provides a runtime for executing asynchronous tasks. Most
applications can use the #[tokio::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 and the multi-thread
scheduler, respectively. See the runtime
module
documentation for details. In addition, the “macros” feature
flag enables the #[tokio::main]
and #[tokio::test]
attributes.
§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. You can use the environment variable TOKIO_WORKER_THREADS
to override the default value.
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.
#[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.
§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 (enabled by the “net” feature flag),tokio::fs
, similar tostd::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).
§Examples
A simple TCP echo server:
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 excepttest-util
andtracing
.rt
: Enablestokio::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 basedExt
traits.io-std
: EnableStdout
,Stdin
andStderr
types.net
: Enablestokio::net
types such asTcpStream
,UnixStream
andUdpSocket
, as well as (on Unix-like systems)AsyncFd
and (on FreeBSD)PollAio
.time
: Enablestokio::time
types and allows the schedulers to enable the built in timer.process
: Enablestokio::process
types.macros
: Enables#[tokio::main]
and#[tokio::test]
macros.sync
: Enables alltokio::sync
types.signal
: Enables alltokio::signal
types.fs
: Enablestokio::fs
types.test-util
: Enables testing based infrastructure for the Tokio runtime.parking_lot
: As a potential optimization, use the_parking_lot_
crate’s synchronization primitives internally. Also, this dependency is necessary to construct some of our primitives in aconst
context.MSRV
may increase according to the_parking_lot_
release in use.
Note: AsyncRead
and AsyncWrite
traits do not require any features and are
always available.
§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::on_task_spawn
] - [
runtime::Builder::on_task_terminate
] - [
runtime::Builder::unhandled_panic
] runtime::TaskMeta
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.
You can specify it in your project’s .cargo/config.toml
file:
[build]
rustflags = ["--cfg", "tokio_unstable"]
[build]
section does not go in a
Cargo.toml
file. Instead it must be placed in the Cargo config
file .cargo/config.toml
.
Alternatively, you can specify it with an environment variable:
## Many *nix shells:
export RUSTFLAGS="--cfg tokio_unstable"
cargo build
## Windows PowerShell:
$Env:RUSTFLAGS="--cfg tokio_unstable"
cargo build
§Supported platforms
Tokio currently guarantees support for the following platforms:
- Linux
- Windows
- Android (API level 21)
- macOS
- iOS
- FreeBSD
Tokio will continue to support these platforms in the future. However, future releases may change requirements such as the minimum required libc version on Linux, the API level on Android, or the supported FreeBSD release.
Beyond the above platforms, Tokio is intended to work on all platforms supported by the mio crate. You can find a longer list in mio’s documentation. However, these additional platforms may become unsupported in the future.
Note that Wine is considered to be a different platform from Windows. See mio’s documentation for more information on Wine support.
§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.
Re-exports§
pub use task::spawn;
Modules§
- blocking 🔒
- Asynchronous file utilities.
- future 🔒Asynchronous values.
- Traits, helpers, and type definitions for asynchronous I/O functionality.
- loom 🔒This module abstracts over
loom
andstd::sync
depending on whether we are running tests or not. - TCP/UDP/Unix bindings for
tokio
. - The Tokio runtime.
- Due to the
Stream
trait’s inclusion instd
landing later than Tokio’s 1.0 release, most of the Tokio stream utilities have been moved into thetokio-stream
crate. - Synchronization primitives for use in asynchronous contexts.
- Asynchronous green-threads.
- Utilities for tracking time.
- trace 🔒
- util 🔒
Macros§
- Waits on multiple concurrent branches, returning when all branches complete.
- Pins a value on the stack.
- Waits on multiple concurrent branches, returning when the first branch completes, cancelling the remaining branches.
- Declares a new task-local key of type
tokio::task::LocalKey
. - Waits on multiple concurrent branches, returning when all branches complete with
Ok(_)
or on the firstErr(_)
.