20

Consider the following code

import contextlib
import abc
import asyncio

from typing import AsyncContextManager, AsyncGenerator, AsyncIterator


class Base:

    @abc.abstractmethod
    async def subscribe(self) -> AsyncContextManager[AsyncGenerator[int, None]]:
        pass

class Impl1(Base):

    @contextlib.asynccontextmanager
    async def subscribe(self) ->  AsyncIterator[ AsyncGenerator[int, None] ]: <-- mypy error here

        async def _generator():
            for i in range(5):
                await asyncio.sleep(1)
                yield i
                    
        yield _generator()

For Impl1.subscribe mypy gives the error

Signature of "subscribe" incompatible with supertype "Base"

What is the correct way to specify type hints in the above case? Or is mypy wrong here?

4
  • As a workaround you could make def _generator() abstract and implement subscribe in Base' by calling _generator(). Then in Impl1` implement def _generator().
    – Wombatz
    Commented Aug 24, 2021 at 10:50
  • you don't even need to put _generator in Base, you could just have a private _subscribe in Impl1 without the decorator (which has the contents of your current subscribe) then return contextlib.asynccontextmanager(self._subcribe()) from the actual subscribe. I suspect the problem is that mypy doesn't like you changing the type signature with the decorator, which seems odd since it's a stdlib decorator
    – joel
    Commented Aug 24, 2021 at 10:54
  • @Wombatz I simplified the code. In my code the yield generator() is guarded in try except with subclass specific init and clean-up code. So that would not work.
    – Andreas H.
    Commented Aug 24, 2021 at 11:19
  • @joel True, I remember reading that mypy should, in principle, work with the async contextmanager. But it could be a bug, or maybe I made a mistake.
    – Andreas H.
    Commented Aug 24, 2021 at 11:20

1 Answer 1

24

I just happened to come up with the same problem and found this question on the very same day, but also figured out the answer quickly.

You need to remove async from the abstract method.

To explain why, I'll simplify the case to a simple async iterator:

@abc.abstractmethod
async def foo(self) -> AsyncIterator[int]:
    pass

async def v1(self) -> AsyncIterator[int]:
    yield 0

async def v2(self) -> AsyncIterator[int]:
    return v1()

If you compare v1 and v2, you'll see that the function signature looks the same, but they actually do very different things. v2 is compatible with the abstract method, v1 is not.

When you add the async keyword, mypy infers the return type of the function to be a Coroutine. But, if you also put a yield in, it then infers the return type to be AsyncIterator:

reveal_type(foo)
# -> typing.Coroutine[Any, Any, typing.AsyncIterator[builtins.int]]
reveal_type(v1)
# -> typing.AsyncIterator[builtins.int]
reveal_type(v2)
# -> typing.Coroutine[Any, Any, typing.AsyncIterator[builtins.int]]

As you can see, the lack of a yield in the abstract method means that this is inferred as a Coroutine[..., AsyncIterator[int]]. In other words, a function used like async for i in await v2():.

By removing the async:

@abc.abstractmethod
def foo(self) -> AsyncIterator[int]:
    pass
reveal_type(foo)
# -> typing.AsyncIterator[builtins.int]

We see that the return type is now AsyncIterator and is now compatible with v1, rather than v2. In other words, a function used like async for i in v1():

You can also see that this is fundamentally the same thing as v1:

def v3(self) -> AsyncIterator[int]:
    return v1()

While the syntax is different, both v3 and v1 are functions which will return an AsyncIterator when called, which should be obvious given that we are literally returning the result of v1().

5
  • 1
    Thank you for sharing this insight. After thinking about your answer it all makes sense now. So the basic issue is that for an abstract routine mypy cannot infer between generator and normal function (since the yield is missing). Or in other words, a def or async def object has different type, depending on whether yield is in its body or not. I understand that omitting the async from the abstract routine solves the problem, but I feel it is more of a workaround than a "correct" solution (which maybe does not exist, due to the mentioned issue).
    – Andreas H.
    Commented Aug 24, 2021 at 20:23
  • async def with yield in it is actually not a coroutine but an async generator, and vice versa.
    – Andreas H.
    Commented Aug 24, 2021 at 20:25
  • 1
    Yes, but also def with a yield is a generator function and not a normal function. The problem is the legacy design of generator functions. Python infers them from the presence of yield, rather than being explicit. This is a design that was avoided with asyncio, where an explicit async is needed, rather than inferring from an await. If it were explicit, then your abstract method might look like async gen def or something similar and the problem would never have occurred.
    – Sam Bull
    Commented Aug 25, 2021 at 12:45
  • So is the following assessment correct? There is no way of distinguishing async generators from async functions returning async iterators by type hinting?
    – pwuertz
    Commented Dec 1, 2021 at 22:04
  • A function (non-async) which returns an async iterator is the same thing as an async generator (it's essentially syntax sugar). An async function which returns an async iterator is a different thing, reread the above example (v1() and v2()) and how the abstract method must be changed to match one or the other.
    – Sam Bull
    Commented Dec 2, 2021 at 10:06

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.