@asyncio.coroutine vs async def
Question:
With the asyncio library I’ve seen,
@asyncio.coroutine
def function():
...
and
async def function():
...
used interchangeably.
Is there any functional difference between the two?
Answers:
async def is a new syntax from Python 3.5.
You could use await, async with and async for inside async defs.
@coroutine is a functional analogue for async def but it works in Python 3.4+ and utilizes yield from construction instead of await.
For practical perspective just never use @coroutine if your Python is 3.5+.
From Python 3.5 coroutines formally became a distinct type and thus the async def syntax, along with await statements.
Prior to that, Python 3.4 created coroutines by wrapping regular functions into generators, hence the decorator syntax, and the more generator-like yield from.
Yes, there are functional differences between native coroutines using async def syntax and generator-based coroutines using the asyncio.coroutine decorator.
According to PEP 492, which introduces the async def syntax:
-
Native coroutine objects do not implement __iter__ and
__next__ methods. Therefore, they cannot be iterated over or passed
to iter(), list(), tuple() and other built-ins. They also
cannot be used in a for..in loop.
An attempt to use __iter__ or __next__ on a native coroutine
object will result in a TypeError .
-
Plain generators cannot yield from native coroutines: doing so
will result in a TypeError .
-
generator-based coroutines (for asyncio code must be decorated with
@asyncio.coroutine) can yield from native coroutine objects.
-
inspect.isgenerator() and inspect.isgeneratorfunction() return False for native coroutine objects and native coroutine functions.
Point 1 above means that while coroutine functions defined using the @asyncio.coroutine decorator syntax can behave as traditional generator functions, those defined with the async def syntax cannot.
Here are two minimal, ostensibly equivalent coroutine functions defined with the two syntaxes:
import asyncio
@asyncio.coroutine
def decorated(x):
yield from x
async def native(x):
await x
Although the bytecode for these two functions is almost identical:
>>> import dis
>>> dis.dis(decorated)
5 0 LOAD_FAST 0 (x)
3 GET_YIELD_FROM_ITER
4 LOAD_CONST 0 (None)
7 YIELD_FROM
8 POP_TOP
9 LOAD_CONST 0 (None)
12 RETURN_VALUE
>>> dis.dis(native)
8 0 LOAD_FAST 0 (x)
3 GET_AWAITABLE
4 LOAD_CONST 0 (None)
7 YIELD_FROM
8 POP_TOP
9 LOAD_CONST 0 (None)
12 RETURN_VALUE
… the only difference being GET_YIELD_FROM_ITER vs GET_AWAITABLE, they behave completely differently when an attempt is made to iterate over the objects they return:
>>> list(decorated('foo'))
['f', 'o', 'o']
>>> list(native('foo'))
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: 'coroutine' object is not iterable
Obviously 'foo' is not an awaitable, so the attempt to call native() with it doesn’t make much sense, but the point is hopefully clear that the coroutine object it returns is not iterable, regardless of its argument.
A more detailed investigation of the async/await syntax by Brett Cannon: How the heck does async/await work in Python 3.5? covers this difference in more depth.
With the asyncio library I’ve seen,
@asyncio.coroutine
def function():
...
and
async def function():
...
used interchangeably.
Is there any functional difference between the two?
async def is a new syntax from Python 3.5.
You could use await, async with and async for inside async defs.
@coroutine is a functional analogue for async def but it works in Python 3.4+ and utilizes yield from construction instead of await.
For practical perspective just never use @coroutine if your Python is 3.5+.
From Python 3.5 coroutines formally became a distinct type and thus the async def syntax, along with await statements.
Prior to that, Python 3.4 created coroutines by wrapping regular functions into generators, hence the decorator syntax, and the more generator-like yield from.
Yes, there are functional differences between native coroutines using async def syntax and generator-based coroutines using the asyncio.coroutine decorator.
According to PEP 492, which introduces the async def syntax:
Native coroutine objects do not implement
__iter__and
__next__methods. Therefore, they cannot be iterated over or passed
toiter(),list(),tuple()and other built-ins. They also
cannot be used in afor..inloop.An attempt to use
__iter__or__next__on a native coroutine
object will result in a TypeError .Plain generators cannot
yield fromnative coroutines: doing so
will result in a TypeError .generator-based coroutines (for asyncio code must be decorated with
@asyncio.coroutine) canyield fromnative coroutine objects.
inspect.isgenerator()andinspect.isgeneratorfunction()returnFalsefor native coroutine objects and native coroutine functions.
Point 1 above means that while coroutine functions defined using the @asyncio.coroutine decorator syntax can behave as traditional generator functions, those defined with the async def syntax cannot.
Here are two minimal, ostensibly equivalent coroutine functions defined with the two syntaxes:
import asyncio
@asyncio.coroutine
def decorated(x):
yield from x
async def native(x):
await x
Although the bytecode for these two functions is almost identical:
>>> import dis
>>> dis.dis(decorated)
5 0 LOAD_FAST 0 (x)
3 GET_YIELD_FROM_ITER
4 LOAD_CONST 0 (None)
7 YIELD_FROM
8 POP_TOP
9 LOAD_CONST 0 (None)
12 RETURN_VALUE
>>> dis.dis(native)
8 0 LOAD_FAST 0 (x)
3 GET_AWAITABLE
4 LOAD_CONST 0 (None)
7 YIELD_FROM
8 POP_TOP
9 LOAD_CONST 0 (None)
12 RETURN_VALUE
… the only difference being GET_YIELD_FROM_ITER vs GET_AWAITABLE, they behave completely differently when an attempt is made to iterate over the objects they return:
>>> list(decorated('foo'))
['f', 'o', 'o']
>>> list(native('foo'))
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: 'coroutine' object is not iterable
Obviously 'foo' is not an awaitable, so the attempt to call native() with it doesn’t make much sense, but the point is hopefully clear that the coroutine object it returns is not iterable, regardless of its argument.
A more detailed investigation of the async/await syntax by Brett Cannon: How the heck does async/await work in Python 3.5? covers this difference in more depth.