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I'm running into a problem with method overwriting.

Look at the src code below,

class Foo(object):
  def bar():
    pass # works fine

print # <function bar at 0x028A5B30>

print dir(
['__call__', '__class__', '__closure__', '__code__', '__defaults__', '__delattr__',
'__dict__', '__doc__', '__format__', '__get__', '__getattribute__', '__globals__',
'__hash__', '__init__', '__module__', '__name__', '__new__', '__reduce__',
'__reduce_ex__', '__repr__', '__setattr__', '__sizeof__', '__str__', 
'__subclasshook__', 'func_closure', 'func_code', 'func_defaults', 'func_dict', 
'func_doc', 'func_globals', 'func_name']

backup = # keep the instance of the method object = backup # overwrite with the same method object

print # <unbound method>

print dir(
['__call__', '__class__', '__cmp__', '__delattr__', '__doc__', '__format__', 
'__func__', '__get__', '__getattribute__', '__hash__', '__init__', '__new__', 
'__reduce__', '__reduce_ex__', '__repr__', '__self__', '__setattr__', '__sizeof__', 
'__str__', '__subclasshook__', 'im_class', 'im_func', 'im_self']
""" # TypeError: unbound method foo() must be called with Test instance as first argument (got nothing instead)

It is interesting that the attribute is actually the method and works just fine when invoked. I'm wondering if there's a way to recover the method with its im_func attribute? Please advice~


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2 Answers 2

up vote 6 down vote accepted

If you want it to continue to be a static method then you must tell Python so when assigning. Otherwise it will become a normal method. = staticmethod(backup)
share|improve this answer
The simple answer and solution. – Chris Morgan Aug 26 '11 at 5:51
Thanks a lot! It did the magic:) – sogno Aug 28 '11 at 13:11

If you put a function as an attribute to an object, things get confusing: due to their __get__() methods, they behave differently than they appear. In order to understand that correctly, you should read the section about data descriptors in the Python docs.

A function as is has a __get__() method which will make the function appear as a method.

Suppose you have

def f(a): pass
class C(object):
    def m(a): pass # method
    sm = staticmethod(m)
    cm = classmethod(m)
o = C()
  • f is then <function f at 0xb742c87c>, as is C.__dict__['m'].
  • f.__get__(None, object) returns a method object <unbound method object.f>. If called, it checks if it is called with an instance of the given class, in this case object. This happens with an attribute access a class containing a function as a method, or with C.m, which is equivalent to C.__dict__['m'].__get__(None, C) and yields <unbound method C.m>.
  • f.__get__(4, object) produces a <bound method object.f of 4>. which will call the original function bound to the object 4, passing it as first parameter upon every call. This happens with an attribute access to an instance of the class. o.m, consequently, calls C.__dict__['m'].__get__(o, C) and yields <bound method C.m of <__main__.C object at 0x...>>.

In short:

>>> C.__dict__['m']
<function m at 0xb73bcd84>

>>> C.m
<unbound method C.m>
>>> C.m.im_class, C.m.im_self
(<class '__main__.C'>, None)
>>> C.__dict__['m'].__get__(None, C)
<unbound method C.m>

>>> o.m
<bound method C.m of <__main__.C object at 0xb73c64ac>>
>>> o.m.im_class, o.m.im_self
(<class '__main__.C'>, <__main__.C object at 0xb73c64ac>)
>>> C.__dict__['m'].__get__(o, C)
<bound method C.m of <__main__.C object at 0xb73c64ac>>

If you apply staticmethod() to a function and then assign it to an attribute in the class, you get similiar behaviour: a staticmethod object is an object whose __get__() does not produce a method object but the original function itself. See

>>> C.__dict__['sm']
<staticmethod object at 0xb73cd62c>

<function m at 0xb73bcd84>
>>> C.__dict__['sm'].__get__(None, C)
<function m at 0xb73bcd84>

<function m at 0xb73bcd84>
>>> C.__dict__['sm'].__get__(o, C)
<function m at 0xb73bcd84>

To be complete, here's how classmethod() works:

>>> C.__dict__['cm']
<classmethod object at 0xb73cd794>

<bound method type.m of <class '__main__.C'>>
(<type 'type'>, <class '__main__.C'>)
<bound method type.m of <class '__main__.C'>>
(<type 'type'>, <class '__main__.C'>)
>>> C.__dict__['cm'].__get__(type(C), C)
<bound method type.m of <class '__main__.C'>>

That said, you can see what happens in your case: first, you have a static method. But with

backup =

you get the original function, without staticmethod applied. On the way back, = backup

, you assign the function to the attribute, making it an ordinary method of the class with the implications shown above, requiring to be called with a Foo instance (even if the function itself does not take any parameters, that is not the method object's business) and calling it automatically with another argument prepended to the others.

share|improve this answer
The detailed explanation. – Chris Morgan Aug 26 '11 at 5:51
Wow, thanks for the thorough explanation! I'm a newbie to Python. This definitely helps.:) – sogno Aug 28 '11 at 13:13
Hmm... Sounds like there's only 1 accepted answer within the thread...:( – sogno Aug 28 '11 at 13:14

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