pub struct Runtime { /* private fields */ }
rt
only.Expand description
The Tokio runtime.
The runtime provides an I/O driver, task scheduler, timer, and blocking pool, necessary for running asynchronous tasks.
Instances of Runtime
can be created using new
, or Builder
.
However, most users will use the #[tokio::main]
annotation on
their entry point instead.
See module level documentation for more details.
§Shutdown
Shutting down the runtime is done by dropping the value, or calling
shutdown_background
or shutdown_timeout
.
Tasks spawned through Runtime::spawn
keep running until they yield.
Then they are dropped. They are not guaranteed to run to completion, but
might do so if they do not yield until completion.
Blocking functions spawned through Runtime::spawn_blocking
keep running
until they return.
The thread initiating the shutdown blocks until all spawned work has been
stopped. This can take an indefinite amount of time. The Drop
implementation waits forever for this.
The shutdown_background
and shutdown_timeout
methods can be used if
waiting forever is undesired. When the timeout is reached, spawned work that
did not stop in time and threads running it are leaked. The work continues
to run until one of the stopping conditions is fulfilled, but the thread
initiating the shutdown is unblocked.
Once the runtime has been dropped, any outstanding I/O resources bound to it will no longer function. Calling any method on them will result in an error.
§Sharing
There are several ways to establish shared access to a Tokio runtime:
Using an Arc<Runtime>
or Handle
allows you to do various
things with the runtime such as spawning new tasks or entering the runtime
context. Both types can be cloned to create a new handle that allows access
to the same runtime. By passing clones into different tasks or threads, you
will be able to access the runtime from those tasks or threads.
The difference between Arc<Runtime>
and Handle
is that
an Arc<Runtime>
will prevent the runtime from shutting down,
whereas a Handle
does not prevent that. This is because shutdown of the
runtime happens when the destructor of the Runtime
object runs.
Calls to shutdown_background
and shutdown_timeout
require exclusive
ownership of the Runtime
type. When using an Arc<Runtime>
,
this can be achieved via Arc::try_unwrap
when only one strong count
reference is left over.
The runtime context is entered using the Runtime::enter
or
Handle::enter
methods, which use a thread-local variable to store the
current runtime. Whenever you are inside the runtime context, methods such
as tokio::spawn
will use the runtime whose context you are inside.
Implementations§
Source§impl Runtime
impl Runtime
Sourcepub fn new() -> Result<Runtime>
Available on crate feature rt-multi-thread
only.
pub fn new() -> Result<Runtime>
rt-multi-thread
only.Creates a new runtime instance with default configuration values.
This results in the multi threaded scheduler, I/O driver, and time driver being initialized.
Most applications will not need to call this function directly. Instead,
they will use the #[tokio::main]
attribute. When a more complex
configuration is necessary, the runtime builder may be used.
See module level documentation for more details.
§Examples
Creating a new Runtime
with default configuration values.
use tokio::runtime::Runtime;
let rt = Runtime::new()
.unwrap();
// Use the runtime...
Sourcepub fn handle(&self) -> &Handle
pub fn handle(&self) -> &Handle
Returns a handle to the runtime’s spawner.
The returned handle can be used to spawn tasks that run on this runtime, and can
be cloned to allow moving the Handle
to other threads.
Calling Handle::block_on
on a handle to a current_thread
runtime is error-prone.
Refer to the documentation of Handle::block_on
for more.
§Examples
use tokio::runtime::Runtime;
let rt = Runtime::new()
.unwrap();
let handle = rt.handle();
// Use the handle...
Sourcepub fn spawn<F>(&self, future: F) -> JoinHandle<F::Output> ⓘ
pub fn spawn<F>(&self, future: F) -> JoinHandle<F::Output> ⓘ
Spawns a future onto the Tokio runtime.
This spawns the given future onto the runtime’s executor, usually a thread pool. The thread pool is then responsible for polling the future until it completes.
The provided future will start running in the background immediately
when spawn
is called, even if you don’t await the returned
JoinHandle
.
See module level documentation for more details.
§Examples
use tokio::runtime::Runtime;
// Create the runtime
let rt = Runtime::new().unwrap();
// Spawn a future onto the runtime
rt.spawn(async {
println!("now running on a worker thread");
});
Sourcepub fn spawn_blocking<F, R>(&self, func: F) -> JoinHandle<R> ⓘ
pub fn spawn_blocking<F, R>(&self, func: F) -> JoinHandle<R> ⓘ
Runs the provided function on an executor dedicated to blocking operations.
§Examples
use tokio::runtime::Runtime;
// Create the runtime
let rt = Runtime::new().unwrap();
// Spawn a blocking function onto the runtime
rt.spawn_blocking(|| {
println!("now running on a worker thread");
});
Sourcepub fn block_on<F: Future>(&self, future: F) -> F::Output
pub fn block_on<F: Future>(&self, future: F) -> F::Output
Runs a future to completion on the Tokio runtime. This is the runtime’s entry point.
This runs the given future on the current thread, blocking until it is complete, and yielding its resolved result. Any tasks or timers which the future spawns internally will be executed on the runtime.
§Non-worker future
Note that the future required by this function does not run as a worker. The expectation is that other tasks are spawned by the future here. Awaiting on other futures from the future provided here will not perform as fast as those spawned as workers.
§Multi thread scheduler
When the multi thread scheduler is used this will allow futures to run within the io driver and timer context of the overall runtime.
Any spawned tasks will continue running after block_on
returns.
§Current thread scheduler
When the current thread scheduler is enabled block_on
can be called concurrently from multiple threads. The first call
will take ownership of the io and timer drivers. This means
other threads which do not own the drivers will hook into that one.
When the first block_on
completes, other threads will be able to
“steal” the driver to allow continued execution of their futures.
Any spawned tasks will be suspended after block_on
returns. Calling
block_on
again will resume previously spawned tasks.
§Panics
This function panics if the provided future panics, or if called within an asynchronous execution context.
§Examples
use tokio::runtime::Runtime;
// Create the runtime
let rt = Runtime::new().unwrap();
// Execute the future, blocking the current thread until completion
rt.block_on(async {
println!("hello");
});
Sourcepub fn enter(&self) -> EnterGuard<'_>
pub fn enter(&self) -> EnterGuard<'_>
Enters the runtime context.
This allows you to construct types that must have an executor
available on creation such as Sleep
or TcpStream
. It will
also allow you to call methods such as tokio::spawn
.
§Example
use tokio::runtime::Runtime;
use tokio::task::JoinHandle;
fn function_that_spawns(msg: String) -> JoinHandle<()> {
// Had we not used `rt.enter` below, this would panic.
tokio::spawn(async move {
println!("{}", msg);
})
}
fn main() {
let rt = Runtime::new().unwrap();
let s = "Hello World!".to_string();
// By entering the context, we tie `tokio::spawn` to this executor.
let _guard = rt.enter();
let handle = function_that_spawns(s);
// Wait for the task before we end the test.
rt.block_on(handle).unwrap();
}
Sourcepub fn shutdown_timeout(self, duration: Duration)
pub fn shutdown_timeout(self, duration: Duration)
Shuts down the runtime, waiting for at most duration
for all spawned
work to stop.
See the struct level documentation for more details.
§Examples
use tokio::runtime::Runtime;
use tokio::task;
use std::thread;
use std::time::Duration;
fn main() {
let runtime = Runtime::new().unwrap();
runtime.block_on(async move {
task::spawn_blocking(move || {
thread::sleep(Duration::from_secs(10_000));
});
});
runtime.shutdown_timeout(Duration::from_millis(100));
}
Sourcepub fn shutdown_background(self)
pub fn shutdown_background(self)
Shuts down the runtime, without waiting for any spawned work to stop.
This can be useful if you want to drop a runtime from within another runtime.
Normally, dropping a runtime will block indefinitely for spawned blocking tasks
to complete, which would normally not be permitted within an asynchronous context.
By calling shutdown_background()
, you can drop the runtime from such a context.
Note however, that because we do not wait for any blocking tasks to complete, this may result in a resource leak (in that any blocking tasks are still running until they return.
See the struct level documentation for more details.
This function is equivalent to calling shutdown_timeout(Duration::from_nanos(0))
.
use tokio::runtime::Runtime;
fn main() {
let runtime = Runtime::new().unwrap();
runtime.block_on(async move {
let inner_runtime = Runtime::new().unwrap();
// ...
inner_runtime.shutdown_background();
});
}
Sourcepub fn metrics(&self) -> RuntimeMetrics
pub fn metrics(&self) -> RuntimeMetrics
Returns a view that lets you get information about how the runtime is performing.
Trait Implementations§
impl RefUnwindSafe for Runtime
impl UnwindSafe for Runtime
Auto Trait Implementations§
Blanket Implementations§
Source§impl<T> BorrowMut<T> for Twhere
T: ?Sized,
impl<T> BorrowMut<T> for Twhere
T: ?Sized,
Source§fn borrow_mut(&mut self) -> &mut T
fn borrow_mut(&mut self) -> &mut T
Layout§
Note: Most layout information is completely unstable and may even differ between compilations. The only exception is types with certain repr(...)
attributes. Please see the Rust Reference's “Type Layout” chapter for details on type layout guarantees.
Size: 80 bytes