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Say I want to make a decorator for methods defined in a class. I want that decorator, when invoked, to be able to set an attribute on the class defining the method (in order to register it in a list of methods that serve a particular purpose).

In Python 2, the im_class method accomplishes this nicely:

def decorator(method):
  cls = method.im_class
  cls.foo = 'bar'
  return method

However, in Python 3, no such attribute (or a replacement for it) seems to exist. I suppose the idea was that you could call type(method.__self__) to get the class, but this does not work for unbound methods, since __self__ == None in that case.

NOTE: This question is actually a bit irrelevant for my case, since I've chosen instead to set an attribute on the method itself and then have the instance scan through all of its methods looking for that attribute at the appropriate time. I am also (currently) using Python 2.6. However, I am curious if there is any replacement for the version 2 functionality, and if not, what the rationale was for removing it completely.

EDIT: I just found this question. This makes it seem like the best solution is just to avoid it like I have. I'm still wondering why it was removed though.

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3  
The removal of unbound methods is documented here: docs.python.org/py3k/whatsnew/… –  Ned Deily Aug 28 '10 at 5:05
3  
Guido van Rossum's rationale for removing unbound methods can be found here: mail.python.org/pipermail/python-dev/2005-January/050625.html, and the blog mentioned in that post is here: artima.com/weblogs/viewpost.jsp?thread=86641 –  unutbu Aug 28 '10 at 10:48
    
Thanks to all of you. That was exactly what I was looking for. –  Tim Yates Aug 28 '10 at 15:56

2 Answers 2

up vote 16 down vote accepted

The point you appear to be missing is, in Python 3 the "unbound method" type has entirely disappeared -- a method, until and unless it's bound, is just a function, without the weird "type-checking" unbound methods used to perform. This makes the language simpler!

To wit...:

>>> class X:
...   def Y(self): pass
... 
>>> type(X.Y)
<class 'function'>

and voila -- one less subtle concept and distinction to worry about. Such simplifications are the core advantage of Python 3 wrt Python 2, which (over the years) had been accumulating so many subtleties that it was in danger (if features kept being added to it) of really losing its status as a simple language. With Python 3, simplicity is back!-)

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2  
That makes sense. I didn't even realize there was extra functionality for methods like the first-argument type checking--I just thought they would be normal functions with a few extra attributes. With that, I can completely understand the removal. –  Tim Yates Aug 28 '10 at 16:04
2  
@Tim, yes, the check that the first argument was of an instance of the .im_class (including subclasses thereof of course) is why im_class was kept in the first place (and the same layer of indirectness wrapped around functions to make unbound methods, as needs to be wrapped anyway to make bound ones). The underlying function always was (and still is for bound methods) the .im_func, BTW, never the method object itself. –  Alex Martelli Aug 29 '10 at 0:01
2  
"With Python 3, simplicity is back!" sounds like it would make a good bumper sticker (or laptop sticker). –  Mu Mind Oct 5 '12 at 3:21

I thought it would be worthwhile writing something that does it best at guessing the defining class. For completeness' sake this answer also addresses bound methods.

TL;DR

The final version of our function successfully overcomes most simple cases, and a few pitfalls as well.
In a nutshell, its handling differentiates between bound methods and “unbound methods“ (functions) since in Python 3 there is no reliable way to extract the enclosing class from an “unbound method".

The resulting function is:

def get_class_that_defined_method(meth):
    if inspect.ismethod(meth):
        for cls in inspect.getmro(meth.__self__.__class__):
           if meth.__name__ in cls.__dict__: 
                return cls
        meth = meth.__func__ # fallback to __qualname__ parsing
    if inspect.isfunction(meth):
        cls = getattr(inspect.getmodule(meth),
                      meth.__qualname__.split('.<locals>', 1)[0].rsplit('.', 1)[0])
        if isinstance(cls, type):
            return cls
    return None # not required since None would have been implicitly returned anyway

A small request

If you decide to use this implementation, and encounter any caveats, please comment and describe what happened.


“Unbound methods” are regular functions

First of all, it's worth noting the following change made in `Python 3' (see Guido's motivation here):

The concept of “unbound methods” has been removed from the language. When referencing a method as a class attribute, you now get a plain function object.

This makes it practically impossible to reliably extract the class in which a certain “unbound method“ was defined unless it's bound to an object of that class (or of one of its subclasses).

Handling bound methods

So, let us first handle the “easier case“ in which we have a bound method. Note that the bound method must be written in Python, as described in inspect.ismethod's documentation.

def get_class_that_defined_method(meth):
    # meth must be a bound method
    if not inspect.ismethod(meth):
        return None
    for cls in inspect.getmro(meth.__self__.__class__):
        if meth.__name__ in cls.__dict__: 
            return cls
    return None # not required since None would have been implicitly returned anyway

However, this solution is not perfect and has its perils, as methods can be assigned in runtime, rendering their name possibly different than that of the attribute that they are assigned to (see example below). This problem exists also in Python 2. A possible workaround would be to iterate over all of the class's attributes, looking for a function whose code object is exactly identical to that of the specified method.

Handling “unbound methods“

Now that we got that out of the way, we can suggest a hack that tries to handle “unbound methods”. The hack, its rationale, and some discouragement words can be found in this answer. It relies on manually parsing the __qualname__ attribute, available only from `Python 3.3', is highly unrecommended, but should work for simple cases:

def get_class_that_defined_method(meth):
    if inspect.isfunction(meth):
        return getattr(inspect.getmodule(meth),
                       meth.__qualname__.split('.<locals>', 1)[0].rsplit('.', 1)[0])
    return None # not required since None would have been implicitly returned anyway

Combining both approaches

Since inspect.isfunction and inspect.ismethod are mutually exclusive, combining both approaches into a single solution gives us the following (with added logging facilities for the upcoming examples):

def get_class_that_defined_method(meth):
    if inspect.ismethod(meth):
        print('this is a method')
        for cls in inspect.getmro(meth.__self__.__class__):
            if meth.__name__ in cls.__dict__: 
                return cls
    if inspect.isfunction(meth):
        print('this is a function')
        return getattr(inspect.getmodule(meth),
                       meth.__qualname__.split('.<locals>', 1)[0].rsplit('.', 1)[0])
    print('this is neither a function nor a method')
    return None # not required since None would have been implicitly returned anyway

Execution example

>>> class A:
...     def a(self): pass
... 
>>> class B:
...     def b(self): pass
... 
>>> class C(A, B):
...     def a(self): pass
... 
>>> A.a
<function A.a at 0x7f13b58dfc80>
>>> get_class_that_defined_method(A.a)
this is a function
<class '__main__.A'>
>>>
>>> A().a
<bound method A.a of <__main__.A object at 0x7f13b58ca9e8>>
>>> get_class_that_defined_method(A().a)
this is a method
<class '__main__.A'>
>>>
>>> C.a
<function C.a at 0x7f13b58dfea0>
>>> get_class_that_defined_method(C.a)
this is a function
<class '__main__.C'>
>>>
>>> C().a
<bound method C.a of <__main__.C object at 0x7f13b58ca9e8>>
>>> get_class_that_defined_method(C().a)
this is a method
<class '__main__.C'>
>>>
>>> C.b
<function B.b at 0x7f13b58dfe18>
>>> get_class_that_defined_method(C.b)
this is a function
<class '__main__.B'>
>>>
>>> C().b
<bound method C.b of <__main__.C object at 0x7f13b58ca9e8>>
>>> get_class_that_defined_method(C().b)
this is a method
<class '__main__.B'>

So far, so good, but...

>>> def x(self): pass
... 
>>> class Z:
...     y = x
...     z = (lambda: lambda: 1)() # this returns the inner function
...     @classmethod
...     def class_meth(cls): pass
...     @staticmethod
...     def static_meth(): pass
...
>>> Z.y
<function x at 0x7f13b58dfa60>
>>> get_class_that_defined_method(Z.y)
this is a function
<function x at 0x7f13b58dfa60>
>>>
>>> Z().y
<bound method Z.x of <__main__.Z object at 0x7f13b58ca9e8>>
>>> get_class_that_defined_method(Z().y)
this is a method
this is neither a function nor a method
>>>
>>> Z.z
<function Z.<lambda>.<locals>.<lambda> at 0x7f13b58d40d0>
>>> get_class_that_defined_method(Z.z)
this is a function
<class '__main__.Z'>
>>>
>>> Z().z
<bound method Z.<lambda> of <__main__.Z object at 0x7f13b58ca9e8>>
>>> get_class_that_defined_method(Z().z)
this is a method
this is neither a function nor a method
>>>
>>> Z.class_meth
<bound method type.class_meth of <class '__main__.Z'>>
>>> get_class_that_defined_method(Z.class_meth)
this is a method
this is neither a function nor a method
>>>
>>> Z().class_meth
<bound method type.class_meth of <class '__main__.Z'>>
>>> get_class_that_defined_method(Z().class_meth)
this is a method
this is neither a function nor a method
>>>
>>> Z.static_meth
<function Z.static_meth at 0x7f13b58d4158>
>>> get_class_that_defined_method(Z.static_meth)
this is a function
<class '__main__.Z'>
>>>
>>> Z().static_meth
<function Z.static_meth at 0x7f13b58d4158>
>>> get_class_that_defined_method(Z().static_meth)
this is a function
<class '__main__.Z'>

Final touches

  • The outcome generated by Z.y can be partially fixed (to return None) by verifying that the returned value is a class, before actually returning it.
  • The outcome generated by Z().z can be fixed by falling back to parsing the function's __qualname__ attribute (the function can be extracted via meth.__func__).
  • The outcome generated by Z.class_meth and Z().class_meth is incorrect because accessing a class method always returns a bound method, whose __self__ attribute is the class itself, rather than its object. Thus, further accessing the __class__ attribute on top of that __self__ attribute doesn't work as expected:

    >>> Z().class_meth
    <bound method type.class_meth of <class '__main__.Z'>>
    >>> Z().class_meth.__self__
    <class '__main__.Z'>
    >>> Z().class_meth.__self__.__class__
    <class 'type'>
    

    This can be fixed by checking whether the method's __self__ attribute returns an instance of type. However, this might be confusing when our function is invoked against methods of a metaclass, so we'll leave it as is for now.

Here is the final version:

def get_class_that_defined_method(meth):
    if inspect.ismethod(meth):
        for cls in inspect.getmro(meth.__self__.__class__):
            if meth.__name__ in cls.__dict__: 
                return cls
        meth = meth.__func__ # fallback to __qualname__ parsing
    if inspect.isfunction(meth):
        cls = getattr(inspect.getmodule(meth),
                      meth.__qualname__.split('.<locals>', 1)[0].rsplit('.', 1)[0])
        if isinstance(cls, type):
            return cls
    return None # not required since None would have been implicitly returned anyway

Surprisingly, this also fixes the outcome of Z.class_meth and Z().class_meth which now correctly return Z. This is because the __func__ attribute of a class method returns a regular function whose __qualname__ attribute may be parsed:

>>> Z().class_meth.__func__
<function Z.class_meth at 0x7f13b58d4048>
>>> Z().class_meth.__func__.__qualname__
'Z.class_meth'
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