This section outlines high-level asyncio APIs to work with coroutines and Tasks.
Source code: Lib/asyncio/coroutines.py
Coroutines declared with the async/await syntax is the preferred way of writing asyncio applications. For example, the following snippet of code prints “hello”, waits 1 second, and then prints “world”:
>>> import asyncio
>>> async def main():
... print('hello')
... await asyncio.sleep(1)
... print('world')
>>> asyncio.run(main())
hello
world
Note that simply calling a coroutine will not schedule it to be executed:
>>> main()
<coroutine object main at 0x1053bb7c8>
To actually run a coroutine, asyncio provides the following mechanisms:
The asyncio.run() function to run the top-level
entry point “main()” function (see the above example.)
Awaiting on a coroutine. The following snippet of code will print “hello” after waiting for 1 second, and then print “world” after waiting for another 2 seconds:
import asyncio
import time
async def say_after(delay, what):
await asyncio.sleep(delay)
print(what)
async def main():
print(f"started at {time.strftime('%X')}")
await say_after(1, 'hello')
await say_after(2, 'world')
print(f"finished at {time.strftime('%X')}")
asyncio.run(main())
Expected output:
started at 17:13:52
hello
world
finished at 17:13:55
The asyncio.create_task() function to run coroutines
concurrently as asyncio Tasks.
Let’s modify the above example and run two say_after coroutines
concurrently:
async def main():
task1 = asyncio.create_task(
say_after(1, 'hello'))
task2 = asyncio.create_task(
say_after(2, 'world'))
print(f"started at {time.strftime('%X')}")
# Wait until both tasks are completed (should take
# around 2 seconds.)
await task1
await task2
print(f"finished at {time.strftime('%X')}")
Note that expected output now shows that the snippet runs 1 second faster than before:
started at 17:14:32
hello
world
finished at 17:14:34
The asyncio.TaskGroup class provides a more modern
alternative to create_task().
Using this API, the last example becomes:
async def main():
async with asyncio.TaskGroup() as tg:
task1 = tg.create_task(
say_after(1, 'hello'))
task2 = tg.create_task(
say_after(2, 'world'))
print(f"started at {time.strftime('%X')}")
# The await is implicit when the context manager exits.
print(f"finished at {time.strftime('%X')}")
The timing and output should be the same as for the previous version.
Added in version 3.11: asyncio.TaskGroup.
We say that an object is an awaitable object if it can be used
in an await expression. Many asyncio APIs are designed to
accept awaitables.
There are three main types of awaitable objects: coroutines, Tasks, and Futures.
Coroutines
Python coroutines are awaitables and therefore can be awaited from other coroutines:
import asyncio
async def nested():
return 42
async def main():
# Nothing happens if we just call "nested()".
# A coroutine object is created but not awaited,
# so it *won't run at all*.
nested() # will raise a "RuntimeWarning".
# Let's do it differently now and await it:
print(await nested()) # will print "42".
asyncio.run(main())
Important
In this documentation the term “coroutine” can be used for two closely related concepts:
a coroutine function: an async def function;
a coroutine object: an object returned by calling a coroutine function.
Tasks
Tasks are used to schedule coroutines concurrently.
When a coroutine is wrapped into a Task with functions like
asyncio.create_task() the coroutine is automatically
scheduled to run soon:
import asyncio
async def nested():
return 42
async def main():
# Schedule nested() to run soon concurrently
# with "main()".
task = asyncio.create_task(nested())
# "task" can now be used to cancel "nested()", or
# can simply be awaited to wait until it is complete:
await task
asyncio.run(main())
Futures
A Future is a special low-level awaitable object that
represents an eventual result of an asynchronous operation.
When a Future object is awaited it means that the coroutine will wait until the Future is resolved in some other place.
Future objects in asyncio are needed to allow callback-based code to be used with async/await.
Normally there is no need to create Future objects at the application level code.
Future objects, sometimes exposed by libraries and some asyncio APIs, can be awaited:
async def main():
await function_that_returns_a_future_object()
# this is also valid:
await asyncio.gather(
function_that_returns_a_future_object(),
some_python_coroutine()
)
A good example of a low-level function that returns a Future object
is loop.run_in_executor().
Source code: Lib/asyncio/tasks.py
Wrap the coro coroutine into a Task
and schedule its execution. Return the Task object.
The full function signature is largely the same as that of the
Task constructor (or factory) - all of the keyword arguments to
this function are passed through to that interface.
An optional keyword-only context argument allows specifying a
custom contextvars.Context for the coro to run in.
The current context copy is created when no context is provided.
An optional keyword-only eager_start argument allows specifying
if the task should execute eagerly during the call to create_task,
or be scheduled later. If eager_start is not passed the mode set
by loop.set_task_factory() will be used.
The task is executed in the loop returned by get_running_loop(),
RuntimeError is raised if there is no running loop in
current thread.
Note
asyncio.TaskGroup.create_task() is a new alternative
leveraging structural concurrency; it allows for waiting
for a group of related tasks with strong safety guarantees.
Important
Save a reference to the result of this function, to avoid a task disappearing mid-execution. The event loop only keeps weak references to tasks. A task that isn’t referenced elsewhere may get garbage collected at any time, even before it’s done. For reliable “fire-and-forget” background tasks, gather them in a collection:
background_tasks = set()
for i in range(10):
task = asyncio.create_task(some_coro(param=i))
# Add task to the set. This creates a strong reference.
background_tasks.add(task)
# To prevent keeping references to finished tasks forever,
# make each task remove its own reference from the set after
# completion:
task.add_done_callback(background_tasks.discard)
Added in version 3.7.
Changed in version 3.8: Added the name parameter.
Changed in version 3.11: Added the context parameter.
Changed in version 3.14: Added the eager_start parameter by passing on all kwargs.
Tasks can easily and safely be cancelled.
When a task is cancelled, asyncio.CancelledError will be raised
in the task at the next opportunity.
It is recommended that coroutines use try/finally blocks to robustly
perform clean-up logic. In case asyncio.CancelledError
is explicitly caught, it should generally be propagated when
clean-up is complete. asyncio.CancelledError directly subclasses
BaseException so most code will not need to be aware of it.
The asyncio components that enable structured concurrency, like
asyncio.TaskGroup and asyncio.timeout(),
are implemented using cancellation internally and might misbehave if
a coroutine swallows asyncio.CancelledError. Similarly, user code
should not generally call uncancel.
However, in cases when suppressing asyncio.CancelledError is
truly desired, it is necessary to also call uncancel() to completely
remove the cancellation state.
Task groups combine a task creation API with a convenient and reliable way to wait for all tasks in the group to finish.
An asynchronous context manager
holding a group of tasks.
Tasks can be added to the group using create_task().
All tasks are awaited when the context manager exits.
Added in version 3.11.
Create a task in this task group.
The signature matches that of asyncio.create_task().
If the task group is inactive (e.g. not yet entered,
already finished, or in the process of shutting down),
we will close the given coro.
Changed in version 3.13: Close the given coroutine if the task group is not active.
Changed in version 3.14: Passes on all kwargs to loop.create_task()
Example:
async def main():
async with asyncio.TaskGroup() as tg:
task1 = tg.create_task(some_coro(...))
task2 = tg.create_task(another_coro(...))
print(f"Both tasks have completed now: {task1.result()}, {task2.result()}")
The async with statement will wait for all tasks in the group to finish.
While waiting, new tasks may still be added to the group
(for example, by passing tg into one of the coroutines
and calling tg.create_task() in that coroutine).
Once the last task has finished and the async with block is exited,
no new tasks may be added to the group.
The first time any of the tasks belonging to the group fails
with an exception other than asyncio.CancelledError,
the remaining tasks in the group are cancelled.
No further tasks can then be added to the group.
At this point, if the body of the async with statement is still active
(i.e., __aexit__() hasn’t been called yet),
the task directly containing the async with statement is also cancelled.
The resulting asyncio.CancelledError will interrupt an await,
but it will not bubble out of the containing async with statement.
Once all tasks have finished, if any tasks have failed
with an exception other than asyncio.CancelledError,
those exceptions are combined in an
ExceptionGroup or BaseExceptionGroup
(as appropriate; see their documentation)
which is then raised.
Two base exceptions are treated specially:
If any task fails with KeyboardInterrupt or SystemExit,
the task group still cancels the remaining tasks and waits for them,
but then the initial KeyboardInterrupt or SystemExit
is re-raised instead of ExceptionGroup or BaseExceptionGroup.
If the body of the async with statement exits with an exception
(so __aexit__() is called with an exception set),
this is treated the same as if one of the tasks failed:
the remaining tasks are cancelled and then waited for,
and non-cancellation exceptions are grouped into an
exception group and raised.
The exception passed into __aexit__(),
unless it is asyncio.CancelledError,
is also included in the exception group.
The same special case is made for
KeyboardInterrupt and SystemExit as in the previous paragraph.
Task groups are careful not to mix up the internal cancellation used to
“wake up” their __aexit__() with cancellation requests
for the task in which they are running made by other parties.
In particular, when one task group is syntactically nested in another,
and both experience an exception in one of their child tasks simultaneously,
the inner task group will process its exceptions, and then the outer task group
will receive another cancellation and process its own exceptions.
In the case where a task group is cancelled externally and also must
raise an ExceptionGroup, it will call the parent task’s
cancel() method. This ensures that a
asyncio.CancelledError will be raised at the next
await, so the cancellation is not lost.
Task groups preserve the cancellation count
reported by asyncio.Task.cancelling().
Changed in version 3.13: Improved handling of simultaneous internal and external cancellations and correct preservation of cancellation counts.
While terminating a task group is not natively supported by the standard library, termination can be achieved by adding an exception-raising task to the task group and ignoring the raised exception:
import asyncio
from asyncio import TaskGroup
class TerminateTaskGroup(Exception):
"""Exception raised to terminate a task group."""
async def force_terminate_task_group():
"""Used to force termination of a task group."""
raise TerminateTaskGroup()
async def job(task_id, sleep_time):
print(f'Task {task_id}: start')
await asyncio.sleep(sleep_time)
print(f'Task {task_id}: done')
async def main():
try:
async with TaskGroup() as group:
# spawn some tasks
group.create_task(job(1, 0.5))
group.create_task(job(2, 1.5))
# sleep for 1 second
await asyncio.sleep(1)
# add an exception-raising task to force the group to terminate
group.create_task(force_terminate_task_group())
except* TerminateTaskGroup:
pass
asyncio.run(main())
Expected output:
Task 1: start
Task 2: start
Task 1: done
Block for delay seconds.
If result is provided, it is returned to the caller when the coroutine completes.
sleep() always suspends the current task, allowing other tasks
to run.
Setting the delay to 0 provides an optimized path to allow other tasks to run. This can be used by long-running functions to avoid blocking the event loop for the full duration of the function call.
Example of coroutine displaying the current date every second for 5 seconds:
import asyncio
import datetime
async def display_date():
loop = asyncio.get_running_loop()
end_time = loop.time() + 5.0
while True:
print(datetime.datetime.now())
if (loop.time() + 1.0) >= end_time:
break
await asyncio.sleep(1)
asyncio.run(display_date())
Changed in version 3.10: Removed the loop parameter.
Changed in version 3.13: Raises ValueError if delay is nan.
Run awaitable objects in the aws sequence concurrently.
If any awaitable in aws is a coroutine, it is automatically scheduled as a Task.
If all awaitables are completed successfully, the result is an aggregate list of returned values. The order of result values corresponds to the order of awaitables in aws.
If return_exceptions is False (default), the first
raised exception is immediately propagated to the task that
awaits on gather(). Other awaitables in the aws sequence
won’t be cancelled and will continue to run.
If return_exceptions is True, exceptions are treated the
same as successful results, and aggregated in the result list.
If gather() is cancelled, all submitted awaitables
(that have not completed yet) are also cancelled.
If any Task or Future from the aws sequence is cancelled, it is
treated as if it raised CancelledError – the gather()
call is not cancelled in this case. This is to prevent the
cancellation of one submitted Task/Future to cause other
Tasks/Futures to be cancelled.
Note
A new alternative to create and run tasks concurrently and
wait for their completion is asyncio.TaskGroup. TaskGroup
provides stronger safety guarantees than gather for scheduling a nesting of subtasks:
if a task (or a subtask, a task scheduled by a task)
raises an exception, TaskGroup will, while gather will not,
cancel the remaining scheduled tasks).
Example:
import asyncio
async def factorial(name, number):
f = 1
for i in range(2, number + 1):
print(f"Task {name}: Compute factorial({number}), currently i={i}...")
await asyncio.sleep(1)
f *= i
print(f"Task {name}: factorial({number}) = {f}")
return f
async def main():
# Schedule three calls *concurrently*:
L = await asyncio.gather(
factorial("A", 2),
factorial("B", 3),
factorial("C", 4),
)
print(L)
asyncio.run(main())
# Expected output:
#
# Task A: Compute factorial(2), currently i=2...
# Task B: Compute factorial(3), currently i=2...
# Task C: Compute factorial(4), currently i=2...
# Task A: factorial(2) = 2
# Task B: Compute factorial(3), currently i=3...
# Task C: Compute factorial(4), currently i=3...
# Task B: factorial(3) = 6
# Task C: Compute factorial(4), currently i=4...
# Task C: factorial(4) = 24
# [2, 6, 24]
Note
If return_exceptions is false, cancelling gather() after it
has been marked done won’t cancel any submitted awaitables.
For instance, gather can be marked done after propagating an
exception to the caller, therefore, calling gather.cancel()
after catching an exception (raised by one of the awaitables) from
gather won’t cancel any other awaitables.
Changed in version 3.7: If the gather itself is cancelled, the cancellation is propagated regardless of return_exceptions.
Changed in version 3.10: Removed the loop parameter.
Deprecated since version 3.10: Deprecation warning is emitted if no positional arguments are provided or not all positional arguments are Future-like objects and there is no running event loop.
A task factory for eager task execution.
When using this factory (via loop.set_task_factory(asyncio.eager_task_factory)),
coroutines begin execution synchronously during Task construction.
Tasks are only scheduled on the event loop if they block.
This can be a performance improvement as the overhead of loop scheduling
is avoided for coroutines that complete synchronously.
A common example where this is beneficial is coroutines which employ caching or memoization to avoid actual I/O when possible.
Note
Immediate execution of the coroutine is a semantic change. If the coroutine returns or raises, the task is never scheduled to the event loop. If the coroutine execution blocks, the task is scheduled to the event loop. This change may introduce behavior changes to existing applications. For example, the application’s task execution order is likely to change.
Added in version 3.12.
Create an eager task factory, similar to eager_task_factory(),
using the provided custom_task_constructor when creating a new task instead
of the default Task.
custom_task_constructor must be a callable with the signature matching
the signature of Task.__init__.
The callable must return a asyncio.Task-compatible object.
This function returns a callable intended to be used as a task factory of an
event loop via loop.set_task_factory(factory)).
Added in version 3.12.
Protect an awaitable object
from being cancelled.
If aw is a coroutine it is automatically scheduled as a Task.
The statement:
task = asyncio.create_task(something())
res = await shield(task)
is equivalent to:
res = await something()
except that if the coroutine containing it is cancelled, the
Task running in something() is not cancelled. From the point
of view of something(), the cancellation did not happen.
Although its caller is still cancelled, so the “await” expression
still raises a CancelledError.
If something() is cancelled by other means (i.e. from within
itself) that would also cancel shield().
If it is desired to completely ignore cancellation (not recommended)
the shield() function should be combined with a try/except
clause, as follows:
task = asyncio.create_task(something())
try:
res = await shield(task)
except CancelledError:
res = None
Important
Save a reference to tasks passed to this function, to avoid a task disappearing mid-execution. The event loop only keeps weak references to tasks. A task that isn’t referenced elsewhere may get garbage collected at any time, even before it’s done.
Changed in version 3.10: Removed the loop parameter.
Deprecated since version 3.10: Deprecation warning is emitted if aw is not Future-like object and there is no running event loop.
Return an asynchronous context manager that can be used to limit the amount of time spent waiting on something.
delay can either be None, or a float/int number of
seconds to wait. If delay is None, no time limit will
be applied; this can be useful if the delay is unknown when
the context manager is created.
In either case, the context manager can be rescheduled after
creation using Timeout.reschedule().
Example:
async def main():
async with asyncio.timeout(10):
await long_running_task()
If long_running_task takes more than 10 seconds to complete,
the context manager will cancel the current task and handle
the resulting asyncio.CancelledError internally, transforming it
into a TimeoutError which can be caught and handled.
Note
The asyncio.timeout() context manager is what transforms
the asyncio.CancelledError into a TimeoutError,
which means the TimeoutError can only be caught
outside of the context manager.
Example of catching TimeoutError:
async def main():
try:
async with asyncio.timeout(10):
await long_running_task()
except TimeoutError:
print("The long operation timed out, but we've handled it.")
print("This statement will run regardless.")
The context manager produced by asyncio.timeout() can be
rescheduled to a different deadline and inspected.
An asynchronous context manager for cancelling overdue coroutines.
Prefer using asyncio.timeout() or asyncio.timeout_at()
rather than instantiating Timeout directly.
when should be an absolute time at which the context should time out,
as measured by the event loop’s clock:
If when is None, the timeout will never trigger.
If when < loop.time(), the timeout will trigger on the next
iteration of the event loop.
Example:
async def main():
try:
# We do not know the timeout when starting, so we pass ``None``.
async with asyncio.timeout(None) as cm:
# We know the timeout now, so we reschedule it.
new_deadline = get_running_loop().time() + 10
cm.reschedule(new_deadline)
await long_running_task()
except TimeoutError:
pass
if cm.expired():
print("Looks like we haven't finished on time.")
Timeout context managers can be safely nested.
Added in version 3.11.
Similar to asyncio.timeout(), except when is the absolute time
to stop waiting, or None.
Example:
async def main():
loop = get_running_loop()
deadline = loop.time() + 20
try:
async with asyncio.timeout_at(deadline):
await long_running_task()
except TimeoutError:
print("The long operation timed out, but we've handled it.")
print("This statement will run regardless.")
Added in version 3.11.
Wait for the aw awaitable to complete with a timeout.
If aw is a coroutine it is automatically scheduled as a Task.
timeout can either be None or a float or int number of seconds
to wait for. If timeout is None, block until the future
completes.
If a timeout occurs, it cancels the task and raises
TimeoutError.
To avoid the task cancellation,
wrap it in shield().
The function will wait until the future is actually cancelled, so the total wait time may exceed the timeout. If an exception happens during cancellation, it is propagated.
If the wait is cancelled, the future aw is also cancelled.
Example:
async def eternity():
# Sleep for one hour
await asyncio.sleep(3600)
print('yay!')
async def main():
# Wait for at most 1 second
try:
await asyncio.wait_for(eternity(), timeout=1.0)
except TimeoutError:
print('timeout!')
asyncio.run(main())
# Expected output:
#
# timeout!
Changed in version 3.7: When aw is cancelled due to a timeout, wait_for waits
for aw to be cancelled. Previously, it raised
TimeoutError immediately.
Changed in version 3.10: Removed the loop parameter.
Changed in version 3.11: Raises TimeoutError instead of asyncio.TimeoutError.
Run Future and Task instances in the aws
iterable concurrently and block until the condition specified
by return_when.
The aws iterable must not be empty.
Returns two sets of Tasks/Futures: (done, pending).
Usage:
done, pending = await asyncio.wait(aws)
timeout (a float or int), if specified, can be used to control the maximum number of seconds to wait before returning.
Note that this function does not raise TimeoutError.
Futures or Tasks that aren’t done when the timeout occurs are simply
returned in the second set.
return_when indicates when this function should return. It must be one of the following constants:
Constant |
Description |
|---|---|
|
The function will return when any future finishes or is cancelled. |
|
The function will return when any future finishes by raising an
exception. If no future raises an exception
then it is equivalent to |
|
The function will return when all futures finish or are cancelled. |
Unlike wait_for(), wait() does not cancel the
futures when a timeout occurs.
Changed in version 3.10: Removed the loop parameter.
Changed in version 3.11: Passing coroutine objects to wait() directly is forbidden.
Changed in version 3.12: Added support for generators yielding tasks.
Run awaitable objects in the aws iterable concurrently. The returned object can be iterated to obtain the results of the awaitables as they finish.
The object returned by as_completed() can be iterated as an
asynchronous iterator or a plain iterator. When asynchronous
iteration is used, the originally-supplied awaitables are yielded if they
are tasks or futures. This makes it easy to correlate previously-scheduled
tasks with their results. Example:
ipv4_connect = create_task(open_connection("127.0.0.1", 80))
ipv6_connect = create_task(open_connection("::1", 80))
tasks = [ipv4_connect, ipv6_connect]
async for earliest_connect in as_completed(tasks):
# earliest_connect is done. The result can be obtained by
# awaiting it or calling earliest_connect.result()
reader, writer = await earliest_connect
if earliest_connect is ipv6_connect:
print("IPv6 connection established.")
else:
print("IPv4 connection established.")
During asynchronous iteration, implicitly-created tasks will be yielded for supplied awaitables that aren’t tasks or futures.
When used as a plain iterator, each iteration yields a new coroutine that returns the result or raises the exception of the next completed awaitable. This pattern is compatible with Python versions older than 3.13:
ipv4_connect = create_task(open_connection("127.0.0.1", 80))
ipv6_connect = create_task(open_connection("::1", 80))
tasks = [ipv4_connect, ipv6_connect]
for next_connect in as_completed(tasks):
# next_connect is not one of the original task objects. It must be
# awaited to obtain the result value or raise the exception of the
# awaitable that finishes next.
reader, writer = await next_connect
A TimeoutError is raised if the timeout occurs before all awaitables
are done. This is raised by the async for loop during asynchronous
iteration or by the coroutines yielded during plain iteration.
Changed in version 3.10: Removed the loop parameter.
Deprecated since version 3.10: Deprecation warning is emitted if not all awaitable objects in the aws iterable are Future-like objects and there is no running event loop.
Changed in version 3.12: Added support for generators yielding tasks.
Changed in version 3.13: The result can now be used as either an asynchronous iterator or as a plain iterator (previously it was only a plain iterator).
Asynchronously run function func in a separate thread.
Any *args and **kwargs supplied for this function are directly passed
to func. Also, the current contextvars.Context is propagated,
allowing context variables from the event loop thread to be accessed in the
separate thread.
Return a coroutine that can be awaited to get the eventual result of func.
This coroutine function is primarily intended to be used for executing IO-bound functions/methods that would otherwise block the event loop if they were run in the main thread. For example:
def blocking_io():
print(f"start blocking_io at {time.strftime('%X')}")
# Note that time.sleep() can be replaced with any blocking
# IO-bound operation, such as file operations.
time.sleep(1)
print(f"blocking_io complete at {time.strftime('%X')}")
async def main():
print(f"started main at {time.strftime('%X')}")
await asyncio.gather(
asyncio.to_thread(blocking_io),
asyncio.sleep(1))
print(f"finished main at {time.strftime('%X')}")
asyncio.run(main())
# Expected output:
#
# started main at 19:50:53
# start blocking_io at 19:50:53
# blocking_io complete at 19:50:54
# finished main at 19:50:54
Directly calling blocking_io() in any coroutine would block the event loop
for its duration, resulting in an additional 1 second of run time. Instead,
by using asyncio.to_thread(), we can run it in a separate thread without
blocking the event loop.
Note
Due to the GIL, asyncio.to_thread() can typically only be used
to make IO-bound functions non-blocking. However, for extension modules
that release the GIL or alternative Python implementations that don’t
have one, asyncio.to_thread() can also be used for CPU-bound functions.
Added in version 3.9.
Submit a coroutine to the given event loop. Thread-safe.
Return a concurrent.futures.Future to wait for the result
from another OS thread.
This function is meant to be called from a different OS thread than the one where the event loop is running. Example:
def in_thread(loop: asyncio.AbstractEventLoop) -> None:
# Run some blocking IO
pathlib.Path("example.txt").write_text("hello world", encoding="utf8")
# Create a coroutine
coro = asyncio.sleep(1, result=3)
# Submit the coroutine to a given loop
future = asyncio.run_coroutine_threadsafe(coro, loop)
# Wait for the result with an optional timeout argument
assert future.result(timeout=2) == 3
async def amain() -> None:
# Get the running loop
loop = asyncio.get_running_loop()
# Run something in a thread
await asyncio.to_thread(in_thread, loop)
It’s also possible to run the other way around. Example:
@contextlib.contextmanager
def loop_in_thread() -> Generator[asyncio.AbstractEventLoop]:
loop_fut = concurrent.futures.Future[asyncio.AbstractEventLoop]()
stop_event = asyncio.Event()
async def main() -> None:
loop_fut.set_result(asyncio.get_running_loop())
await stop_event.wait()
with concurrent.futures.ThreadPoolExecutor(1) as tpe:
complete_fut = tpe.submit(asyncio.run, main())
for fut in concurrent.futures.as_completed((loop_fut, complete_fut)):
if fut is loop_fut:
loop = loop_fut.result()
try:
yield loop
finally:
loop.call_soon_threadsafe(stop_event.set)
else:
fut.result()
# Create a loop in another thread
with loop_in_thread() as loop:
# Create a coroutine
coro = asyncio.sleep(1, result=3)
# Submit the coroutine to a given loop
future = asyncio.run_coroutine_threadsafe(coro, loop)
# Wait for the result with an optional timeout argument
assert future.result(timeout=2) == 3
If an exception is raised in the coroutine, the returned Future will be notified. It can also be used to cancel the task in the event loop:
try:
result = future.result(timeout)
except TimeoutError:
print('The coroutine took too long, cancelling the task...')
future.cancel()
except Exception as exc:
print(f'The coroutine raised an exception: {exc!r}')
else:
print(f'The coroutine returned: {result!r}')
See the concurrency and multithreading section of the documentation.
Unlike other asyncio functions this function requires the loop argument to be passed explicitly.
Added in version 3.5.1.
Return the currently running Task instance, or None if
no task is running.
If loop is None get_running_loop() is used to get
the current loop.
Added in version 3.7.
Return a set of not yet finished Task objects run by
the loop.
If loop is None, get_running_loop() is used for getting
current loop.
Added in version 3.7.
Return True if obj is a coroutine object.
Added in version 3.4.
A Future-like object that runs a Python
coroutine. Not thread-safe.
Tasks are used to run coroutines in event loops. If a coroutine awaits on a Future, the Task suspends the execution of the coroutine and waits for the completion of the Future. When the Future is done, the execution of the wrapped coroutine resumes.
Event loops use cooperative scheduling: an event loop runs one Task at a time. While a Task awaits for the completion of a Future, the event loop runs other Tasks, callbacks, or performs IO operations.
Use the high-level asyncio.create_task() function to create
Tasks, or the low-level loop.create_task() or
ensure_future() functions. Manual instantiation of Tasks
is discouraged.
To cancel a running Task use the cancel() method. Calling it
will cause the Task to throw a CancelledError exception into
the wrapped coroutine. If a coroutine is awaiting on a future-like
object during cancellation, the awaited object will be cancelled.
cancelled() can be used to check if the Task was cancelled.
The method returns True if the wrapped coroutine did not
suppress the CancelledError exception and was actually
cancelled.
asyncio.Task inherits from Future all of its
APIs except Future.set_result() and
Future.set_exception().
An optional keyword-only context argument allows specifying a
custom contextvars.Context for the coro to run in.
If no context is provided, the Task copies the current context
and later runs its coroutine in the copied context.
An optional keyword-only eager_start argument allows eagerly starting
the execution of the asyncio.Task at task creation time.
If set to True and the event loop is running, the task will start
executing the coroutine immediately, until the first time the coroutine
blocks. If the coroutine returns or raises without blocking, the task
will be finished eagerly and will skip scheduling to the event loop.
Changed in version 3.7: Added support for the contextvars module.
Changed in version 3.8: Added the name parameter.
Deprecated since version 3.10: Deprecation warning is emitted if loop is not specified and there is no running event loop.
Changed in version 3.11: Added the context parameter.
Changed in version 3.12: Added the eager_start parameter.
Return True if the Task is done.
A Task is done when the wrapped coroutine either returned a value, raised an exception, or the Task was cancelled.
Return the result of the Task.
If the Task is done, the result of the wrapped coroutine is returned (or if the coroutine raised an exception, that exception is re-raised.)
If the Task has been cancelled, this method raises
a CancelledError exception.
If the Task’s result isn’t yet available, this method raises
an InvalidStateError exception.
Return the exception of the Task.
If the wrapped coroutine raised an exception that exception
is returned. If the wrapped coroutine returned normally
this method returns None.
If the Task has been cancelled, this method raises a
CancelledError exception.
If the Task isn’t done yet, this method raises an
InvalidStateError exception.
Add a callback to be run when the Task is done.
This method should only be used in low-level callback-based code.
See the documentation of Future.add_done_callback()
for more details.
Remove callback from the callbacks list.
This method should only be used in low-level callback-based code.
See the documentation of Future.remove_done_callback()
for more details.
Return the list of stack frames for this Task.
If the wrapped coroutine is not done, this returns the stack where it is suspended. If the coroutine has completed successfully or was cancelled, this returns an empty list. If the coroutine was terminated by an exception, this returns the list of traceback frames.
The frames are always ordered from oldest to newest.
Only one stack frame is returned for a suspended coroutine.
The optional limit argument sets the maximum number of frames to return; by default all available frames are returned. The ordering of the returned list differs depending on whether a stack or a traceback is returned: the newest frames of a stack are returned, but the oldest frames of a traceback are returned. (This matches the behavior of the traceback module.)
Print the stack or traceback for this Task.
This produces output similar to that of the traceback module
for the frames retrieved by get_stack().
The limit argument is passed to get_stack() directly.
The file argument is an I/O stream to which the output
is written; by default output is written to sys.stdout.
Return the coroutine object wrapped by the Task.
Note
This will return None for Tasks which have already
completed eagerly. See the Eager Task Factory.
Added in version 3.8.
Changed in version 3.12: Newly added eager task execution means result may be None.
Return the contextvars.Context object
associated with the task.
Added in version 3.12.
Return the name of the Task.
If no name has been explicitly assigned to the Task, the default asyncio Task implementation generates a default name during instantiation.
Added in version 3.8.
Set the name of the Task.
The value argument can be any object, which is then converted to a string.
In the default Task implementation, the name will be visible
in the repr() output of a task object.
Added in version 3.8.
Request the Task to be cancelled.
If the Task is already done or cancelled, return False,
otherwise, return True.
The method arranges for a CancelledError exception to be thrown
into the wrapped coroutine on the next cycle of the event loop.
The coroutine then has a chance to clean up or even deny the
request by suppressing the exception with a try …
… except CancelledError … finally block.
Therefore, unlike Future.cancel(), Task.cancel() does
not guarantee that the Task will be cancelled, although
suppressing cancellation completely is not common and is actively
discouraged. Should the coroutine nevertheless decide to suppress
the cancellation, it needs to call Task.uncancel() in addition
to catching the exception.
If the Task being cancelled is currently awaiting on a future-like object, that awaited object will also be cancelled. This cancellation propagates down the entire chain of awaited objects.
Changed in version 3.9: Added the msg parameter.
Changed in version 3.11: The msg parameter is propagated from cancelled task to its awaiter.
The following example illustrates how coroutines can intercept the cancellation request:
async def cancel_me():
print('cancel_me(): before sleep')
try:
# Wait for 1 hour
await asyncio.sleep(3600)
except asyncio.CancelledError:
print('cancel_me(): cancel sleep')
raise
finally:
print('cancel_me(): after sleep')
async def main():
# Create a "cancel_me" Task
task = asyncio.create_task(cancel_me())
# Wait for 1 second
await asyncio.sleep(1)
task.cancel()
try:
await task
except asyncio.CancelledError:
print("main(): cancel_me is cancelled now")
asyncio.run(main())
# Expected output:
#
# cancel_me(): before sleep
# cancel_me(): cancel sleep
# cancel_me(): after sleep
# main(): cancel_me is cancelled now
Return True if the Task is cancelled.
The Task is cancelled when the cancellation was requested with
cancel() and the wrapped coroutine propagated the
CancelledError exception thrown into it.
Decrement the count of cancellation requests to this Task.
Returns the remaining number of cancellation requests.
Note that once execution of a cancelled task completed, further
calls to uncancel() are ineffective.
Added in version 3.11.
This method is used by asyncio’s internals and isn’t expected to be
used by end-user code. In particular, if a Task gets successfully
uncancelled, this allows for elements of structured concurrency like
Task Groups and asyncio.timeout() to continue running,
isolating cancellation to the respective structured block.
For example:
async def make_request_with_timeout():
try:
async with asyncio.timeout(1):
# Structured block affected by the timeout:
await make_request()
await make_another_request()
except TimeoutError:
log("There was a timeout")
# Outer code not affected by the timeout:
await unrelated_code()
While the block with make_request() and make_another_request()
might get cancelled due to the timeout, unrelated_code() should
continue running even in case of the timeout. This is implemented
with uncancel(). TaskGroup context managers use
uncancel() in a similar fashion.
If end-user code is, for some reason, suppressing cancellation by
catching CancelledError, it needs to call this method to remove
the cancellation state.
When this method decrements the cancellation count to zero,
the method checks if a previous cancel() call had arranged
for CancelledError to be thrown into the task.
If it hasn’t been thrown yet, that arrangement will be
rescinded (by resetting the internal _must_cancel flag).
Changed in version 3.13: Changed to rescind pending cancellation requests upon reaching zero.
Return the number of pending cancellation requests to this Task, i.e.,
the number of calls to cancel() less the number of
uncancel() calls.
Note that if this number is greater than zero but the Task is
still executing, cancelled() will still return False.
This is because this number can be lowered by calling uncancel(),
which can lead to the task not being cancelled after all if the
cancellation requests go down to zero.
This method is used by asyncio’s internals and isn’t expected to be
used by end-user code. See uncancel() for more details.
Added in version 3.11.