While serving a FastAPI request, I have a CPU-bound task to do on every element of a list. I'd like to do this processing on multiple CPU cores.

What's the proper way to do this within FastAPI? Can I use the standard multiprocessing module? All the tutorials/questions I found so far only cover I/O-bound tasks like web requests.

  • Future readers might find this answer helpful as well.
    – Chris
    Nov 29, 2023 at 10:19

2 Answers 2


async def endpoint

You could use loop.run_in_executor with ProcessPoolExecutor to start function at a separate process.

async def test_endpoint():
    loop = asyncio.get_event_loop()
    with concurrent.futures.ProcessPoolExecutor() as pool:
        result = await loop.run_in_executor(pool, cpu_bound_func)  # wait result

def endpoint

Since def endpoints are run implicitly in a separate thread, you can use the full power of modules multiprocessing and concurrent.futures. Note that inside def function, await may not be used. Samples:

def test_endpoint():
    with multiprocessing.Pool(3) as p:
        result = p.map(f, [1, 2, 3])
def test_endpoint():
    with concurrent.futures.ProcessPoolExecutor(max_workers=3) as executor:
      results = executor.map(f, [1, 2, 3])

Note: It should be remembered that creating a pool of processes in an endpoint, as well as creating a large number of threads, can lead to a slowdown in response as the number of requests increases.

Executing on the fly

The easiest and most native way to execute a function in a separate process and immediately wait for the results is to use the loop.run_in_executor with ProcessPoolExecutor.

A pool, as in the example below, can be created when the application starts and do not forget to shutdown on application exit. The number of processes used in the pool can be set using the max_workers ProcessPoolExecutor constructor parameter. If max_workers is None or not given, it will default to the number of processors on the machine.

The disadvantage of this approach is that the request handler (path operation) waits for the computation to complete in a separate process, while the client connection remains open. And if for some reason the connection is lost, then the results will have nowhere to return.

import asyncio
from concurrent.futures.process import ProcessPoolExecutor
from contextlib import asynccontextmanager
from fastapi import FastAPI

from calc import cpu_bound_func

async def lifespan(app: FastAPI):
    app.state.executor = ProcessPoolExecutor()

app = FastAPI(lifespan=lifespan)

async def run_in_process(fn, *args):
    loop = asyncio.get_event_loop()
    return await loop.run_in_executor(app.state.executor, fn, *args)  # wait and return result

async def handler(param: int):
    res = await run_in_process(cpu_bound_func, param)
    return {"result": res}

Move to background

Usually, CPU bound tasks are executed in the background. FastAPI offers the ability to run background tasks to be run after returning a response, inside which you can start and asynchronously wait for the result of your CPU bound task.

In this case, for example, you can immediately return a response of "Accepted" (HTTP code 202) and a unique task ID, continue calculations in the background, and the client can later request the status of the task using this ID.

BackgroundTasks provide some features, in particular, you can run several of them (including in dependencies). And in them you can use the resources obtained in the dependencies, which will be cleaned only when all tasks are completed, while in case of exceptions it will be possible to handle them correctly. This can be seen more clearly in this diagram.

Below is an example that performs minimal task tracking. One instance of the application running is assumed.

import asyncio
from concurrent.futures.process import ProcessPoolExecutor
from contextlib import asynccontextmanager
from http import HTTPStatus

from fastapi import BackgroundTasks
from typing import Dict
from uuid import UUID, uuid4
from fastapi import FastAPI
from pydantic import BaseModel, Field

from calc import cpu_bound_func

class Job(BaseModel):
    uid: UUID = Field(default_factory=uuid4)
    status: str = "in_progress"
    result: int = None

app = FastAPI()
jobs: Dict[UUID, Job] = {}

async def run_in_process(fn, *args):
    loop = asyncio.get_event_loop()
    return await loop.run_in_executor(app.state.executor, fn, *args)  # wait and return result

async def start_cpu_bound_task(uid: UUID, param: int) -> None:
    jobs[uid].result = await run_in_process(cpu_bound_func, param)
    jobs[uid].status = "complete"

@app.post("/new_cpu_bound_task/{param}", status_code=HTTPStatus.ACCEPTED)
async def task_handler(param: int, background_tasks: BackgroundTasks):
    new_task = Job()
    jobs[new_task.uid] = new_task
    background_tasks.add_task(start_cpu_bound_task, new_task.uid, param)
    return new_task

async def status_handler(uid: UUID):
    return jobs[uid]

async def lifespan(app: FastAPI):
    app.state.executor = ProcessPoolExecutor()

More powerful solutions

All of the above examples were pretty simple, but if you need some more powerful system for heavy distributed computing, then you can look aside message brokers RabbitMQ, Kafka, NATS and etc. And libraries using them like Celery.

  • But this way I don't have access to the result of cpu_bound_func to return, right?
    – CryingSofa
    Aug 4, 2020 at 10:55
  • 2
    In case of background executing yes, but I modified the answer for returning example. Aug 4, 2020 at 11:19
  • In my case, I wanted to update a global dict inside cpu_bound_func which did not work using the code above. Hence I ran the function directly inside of start_cpu_bound_task (without await and async) and it works. Is there any downside to my solution?
    – Rafael-WO
    Jan 10, 2022 at 7:37
  • That's not a good idea to start cpu bound function in the context of async coroutine. The most preferable is to use some interprocess communication (or cache, database) to supply state updates to the web server from the working process. The example above is just a strong simplification. Jan 12, 2022 at 13:15
  • 1
    I tried this and ended up getting AssertionError: daemonic processes are not allowed to have children Oct 12, 2022 at 15:15

We were also looking for the solution. And finally aiomultiprocess library helped us run mulitprocess in nonblocking way. We are using this pool instead of concurrent futures. It is able to run without blocking and no need to call inside background tasks.

Please check it out here: https://aiomultiprocess.omnilib.dev/en/stable/

import asyncio
from aiohttp import request
from aiomultiprocess import Pool

async def get(url):
    async with request("GET", url) as response:
        return await response.text("utf-8")

async def main():
    urls = ["https://jreese.sh", ...]
    async with Pool() as pool:
        async for result in pool.map(get, urls):
            ...  # process result

if __name__ == '__main__':
    # Python 3.7

    # Python 3.6
    # loop = asyncio.get_event_loop()
    # loop.run_until_complete(main())

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