Function tokio::task::blocking::spawn_blocking
source · pub fn spawn_blocking<F, R>(f: F) -> JoinHandle<R> ⓘ
Expand description
Runs the provided closure on a thread where blocking is acceptable.
In general, issuing a blocking call or performing a lot of compute in a future without yielding is problematic, as it may prevent the executor from driving other futures forward. This function runs the provided closure on a thread dedicated to blocking operations. See the CPU-bound tasks and blocking code section for more information.
Tokio will spawn more blocking threads when they are requested through this
function until the upper limit configured on the Builder
is reached.
After reaching the upper limit, the tasks are put in a queue.
The thread limit is very large by default, because spawn_blocking
is often
used for various kinds of IO operations that cannot be performed
asynchronously. When you run CPU-bound code using spawn_blocking
, you
should keep this large upper limit in mind. When running many CPU-bound
computations, a semaphore or some other synchronization primitive should be
used to limit the number of computation executed in parallel. Specialized
CPU-bound executors, such as rayon, may also be a good fit.
This function is intended for non-async operations that eventually finish on
their own. If you want to spawn an ordinary thread, you should use
thread::spawn
instead.
Be aware that tasks spawned using spawn_blocking
cannot be aborted
because they are not async. If you call abort
on a spawn_blocking
task, then this will not have any effect, and the task will continue
running normally. The exception is if the task has not started running
yet; in that case, calling abort
may prevent the task from starting.
When you shut down the executor, it will wait indefinitely for all blocking operations to
finish. You can use shutdown_timeout
to stop waiting for them after a
certain timeout. Be aware that this will still not cancel the tasks — they
are simply allowed to keep running after the method returns. It is possible
for a blocking task to be cancelled if it has not yet started running, but this
is not guaranteed.
Note that if you are using the single threaded runtime, this function will still spawn additional threads for blocking operations. The current-thread scheduler’s single thread is only used for asynchronous code.
§Related APIs and patterns for bridging asynchronous and blocking code
In simple cases, it is sufficient to have the closure accept input parameters at creation time and return a single value (or struct/tuple, etc.).
For more complex situations in which it is desirable to stream data to or from
the synchronous context, the mpsc channel
has blocking_send
and
blocking_recv
methods for use in non-async code such as the thread created
by spawn_blocking
.
Another option is SyncIoBridge
for cases where the synchronous context
is operating on byte streams. For example, you might use an asynchronous
HTTP client such as hyper to fetch data, but perform complex parsing
of the payload body using a library written for synchronous I/O.
Finally, see also Bridging with sync code for discussions around the opposite case of using Tokio as part of a larger synchronous codebase.
§Examples
Pass an input value and receive result of computation:
use tokio::task;
// Initial input
let mut v = "Hello, ".to_string();
let res = task::spawn_blocking(move || {
// Stand-in for compute-heavy work or using synchronous APIs
v.push_str("world");
// Pass ownership of the value back to the asynchronous context
v
}).await?;
// `res` is the value returned from the thread
assert_eq!(res.as_str(), "Hello, world");
Use a channel:
use tokio::task;
use tokio::sync::mpsc;
let (tx, mut rx) = mpsc::channel(2);
let start = 5;
let worker = task::spawn_blocking(move || {
for x in 0..10 {
// Stand in for complex computation
tx.blocking_send(start + x).unwrap();
}
});
let mut acc = 0;
while let Some(v) = rx.recv().await {
acc += v;
}
assert_eq!(acc, 95);
worker.await.unwrap();