What does functools.wraps do?
When you use a decorator, you're replacing one function with another. In other words, if you have a decorator
def logged(func):
def with_logging(*args, **kwargs):
print(func.__name__ + " was called")
return func(*args, **kwargs)
return with_logging
then when you say
@logged
def f(x):
"""does some math"""
return x + x * x
it's exactly the same as saying
def f(x):
"""does some math"""
return x + x * x
f = logged(f)
and your function f
is replaced with the function with_logging
. Unfortunately, this means that if you then say
print(f.__name__)
it will print with_logging
because that's the name of your new function. In fact, if you look at the docstring for f
, it will be blank because with_logging
has no docstring, and so the docstring you wrote won't be there anymore. Also, if you look at the pydoc result for that function, it won't be listed as taking one argument x
; instead it'll be listed as taking *args
and **kwargs
because that's what with_logging takes.
If using a decorator always meant losing this information about a function, it would be a serious problem. That's why we have functools.wraps
. This takes a function used in a decorator and adds the functionality of copying over the function name, docstring, arguments list, etc. And since wraps
is itself a decorator, the following code does the correct thing:
from functools import wraps
def logged(func):
@wraps(func)
def with_logging(*args, **kwargs):
print(func.__name__ + " was called")
return func(*args, **kwargs)
return with_logging
@logged
def f(x):
"""does some math"""
return x + x * x
print(f.__name__) # prints 'f'
print(f.__doc__) # prints 'does some math'
As of python 3.5+:
@functools.wraps(f)
def g():
pass
Is an alias for g = functools.update_wrapper(g, f)
. It does exactly three things:
- it copies the
__module__
,__name__
,__qualname__
,__doc__
, and__annotations__
attributes off
ong
. This default list is inWRAPPER_ASSIGNMENTS
, you can see it in the functools source. - it updates the
__dict__
ofg
with all elements fromf.__dict__
. (seeWRAPPER_UPDATES
in the source) - it sets a new
__wrapped__=f
attribute ong
The consequence is that g
appears as having the same name, docstring, module name, and signature than f
. The only problem is that concerning the signature this is not actually true: it is just that inspect.signature
follows wrapper chains by default. You can check it by using inspect.signature(g, follow_wrapped=False)
as explained in the doc. This has annoying consequences:
- the wrapper code will execute even when the provided arguments are invalid.
- the wrapper code can not easily access an argument using its name, from the received *args, **kwargs. Indeed one would have to handle all cases (positional, keyword, default) and therefore to use something like
Signature.bind()
.
Now there is a bit of confusion between functools.wraps
and decorators, because a very frequent use case for developing decorators is to wrap functions. But both are completely independent concepts. If you're interested in understanding the difference, I implemented helper libraries for both: decopatch to write decorators easily, and makefun to provide a signature-preserving replacement for @wraps
. Note that makefun
relies on the same proven trick than the famous decorator
library.
I very often use classes, rather than functions, for my decorators. I was having some trouble with this because an object won't have all the same attributes that are expected of a function. For example, an object won't have the attribute __name__
. I had a specific issue with this that was pretty hard to trace where Django was reporting the error "object has no attribute '__name__
'". Unfortunately, for class-style decorators, I don't believe that @wrap will do the job. I have instead created a base decorator class like so:
class DecBase(object):
func = None
def __init__(self, func):
self.__func = func
def __getattribute__(self, name):
if name == "func":
return super(DecBase, self).__getattribute__(name)
return self.func.__getattribute__(name)
def __setattr__(self, name, value):
if name == "func":
return super(DecBase, self).__setattr__(name, value)
return self.func.__setattr__(name, value)
This class proxies all the attribute calls over to the function that is being decorated. So, you can now create a simple decorator that checks that 2 arguments are specified like so:
class process_login(DecBase):
def __call__(self, *args):
if len(args) != 2:
raise Exception("You can only specify two arguments")
return self.func(*args)
- Assume we have this: Simple Decorator which takes a function’s output and puts it into a string, followed by three !!!!.
def mydeco(func):
def wrapper(*args, **kwargs):
return f'{func(*args, **kwargs)}!!!'
return wrapper
- Let’s now decorate two different functions with “mydeco”:
@mydeco
def add(a, b):
'''Add two objects together, the long way'''
return a + b
@mydeco
def mysum(*args):
'''Sum any numbers together, the long way'''
total = 0
for one_item in args:
total += one_item
return total
- when run add(10,20), mysum(1,2,3,4), it worked!
>>> add(10,20)
'30!!!'
>>> mysum(1,2,3,4)
'10!!!!'
- However, the name attribute, which gives us the name of a function when we define it,
>>>add.__name__
'wrapper`
>>>mysum.__name__
'wrapper'
- Worse
>>> help(add)
Help on function wrapper in module __main__:
wrapper(*args, **kwargs)
>>> help(mysum)
Help on function wrapper in module __main__:
wrapper(*args, **kwargs)
- we can fix partially by:
def mydeco(func):
def wrapper(*args, **kwargs):
return f'{func(*args, **kwargs)}!!!'
wrapper.__name__ = func.__name__
wrapper.__doc__ = func.__doc__
return wrapper
- now we run step 5 (2nd time) again:
>>> help(add)
Help on function add in module __main__:
add(*args, **kwargs)
Add two objects together, the long way
>>> help(mysum)
Help on function mysum in module __main__:
mysum(*args, **kwargs)
Sum any numbers together, the long way
- but we can use functools.wraps (decotator tool)
from functools import wraps
def mydeco(func):
@wraps(func)
def wrapper(*args, *kwargs):
return f'{func(*args, **kwargs)}!!!'
return wrapper
- now run step 5 (3rd time) again
>>> help(add)
Help on function add in module main:
add(a, b)
Add two objects together, the long way
>>> help(mysum)
Help on function mysum in module main:
mysum(*args)
Sum any numbers together, the long way
Reference