Take these two following functions:

import asyncio

def a():
    for index in range(2):
        # Capture `index` as `local_index` in case awaiting is postponed.
        async def next_index(local_index=index):
            # Simulate network request.
            await asyncio.sleep(0)

            return local_index

        yield next_index()

async def b():
    for index in range(2):
        # Simulate network request.
        await asyncio.sleep(0)

        yield index

a returns an Iterable[Awaitable[int]]. b returns an AsyncIterable[int]. Iteration for both can be done like so:

async def main():
    for index in a():
        print(await index)

    async for index in b():




The key thing from the above example is that I was able to yield Awaitables without an outer async because the inner function is async.

  1. Is there anything an AsyncIterable[T] allows over an Iterable[Awaitable[T]] in terms of functionality?

I also have a very related question. From PEP 492 - Asynchronous Iterators and "async for":

An asynchronous iterator object must implement an anext method (or, if defined with CPython C API, tp_as_async.am_anext slot) returning an awaitable.

  1. Because an outer async was not required to yield Awaitables, does __anext__ offer exclusive functionality over a synchronous __next__ returning Awaitables?

This is where I'm probably missing something, but from my current understanding, the asynchronous protocol and StopAsyncIteration look like they can be mimicked using the synchronous protocol and StopIteration (with less brevity of course).

1 Answer 1


One big issue you're missing is how the end of the loop is handled.

An asynchronous iterator's __anext__ returns an awaitable, which can suspend, raise StopIteration with a value to produce the next element, or raise StopAsyncIteration to signal the end of the loop. (The PEP says "To stop iteration __anext__ must raise a StopAsyncIteration exception.", but the StopAsyncIteration exception really happens when the awaitable is awaited, not synchronously when __anext__ is called.)

In contrast, if you try to make a regular iterable with awaitable elements, then the iterator's __next__ needs to raise StopIteration to end the loop.

This means that __next__ can't return until it knows whether or not there will be another element. __next__ is synchronous, so while it's figuring this out, control cannot return to the event loop. This means you might waste a bunch of time synchronously waiting for network traffic or something while all other work stalls.

You can work around this with even more manual handling, but it gets really awkward on both ends, especially the iterator's end, and you need some sort of equivalent of StopAsyncIteration to disambiguate "here's the next element" from "loop's done".

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