I have a class in the main project I don't want to change.

class A():
    def __init__(self, firstname, lastname):
        self.firstname = firstname
        self.lastname = lastname

    def name(self):
        # this method could be much more complex
        return self.lastname.upper()

I'm trying to build a plugin mechansim. So far so good, I have an extension point like this:

if __name__ == '__main__':
    ''' The main project has an extension point that allows me to do'''
    # for each class extension such as AExtended:
    A.name = AExtended.name
    ''' After the extensions are loaded, some behaviours may be changed'''
    a = A("John", "Doe")

A plugin can be written like this:

class AExtended(A):
    ''' This is an extension I provide through a plugin mechanism
    def name(self):
        return self.firstname + ' ' + self.lastname.upper()

This all works very well. I now get "John DOE".

My problem is that the original name() method can be quite complex. In other words, I can't afford to call self.lastname.upper() in the AExtended. I'd like to call the "super" method, which does not exist any more, because it has been overwritten.

How can I change my code, in order to achieve something like this:

class AExtended(A):
    def name(self):
        # I'm looking for a way to call the base implementation that was in A.name()
        return self.firstname + ' ' + parent.name()

Thanks for your help!

Edit: Some explanations of what I try to do.

  • I want the plugin to patch the behaviour of A. I can't afford to change existing consumers of A
  • There are many classes like A that could be changed, I'd like plugins to have full control and responsibility
  • It's true AExtended does not have to inherit from A, but it was an easy way to access self.firstname. I have no problem following a different design pattern if it can help.

I have a workaround, but it's not very elegant and hard to generalize

class AExtended(A):
    def name(self):
        # I'm looking for a way to call the base implementation that was in A.name()
        return self.firstname + ' ' + self.parentname()
#in main
A.parentname = A.name
A.name = AExtended.name
  • Yes, I read how to call the parent class method but in AExtended.name, self is a A because of the overriding – rds Jan 4 '12 at 11:42
  • I might be more lcuky with overriding a private method but I cannot change the A method name. – rds Jan 4 '12 at 11:47
  • Given your clarifications, I would suggest you change the question title. A more accurate title might be "How to call the original method when it is monkey-patched?" – Weeble Jan 4 '12 at 13:17
  • @Weeble done. I did not know this was called monkey-patching – rds Jan 4 '12 at 14:27
  • No problem, I just want you to get the best answers possible. – Weeble Jan 4 '12 at 15:57

Here's a full example of what I was hinting at. Feel free to yell at me and have me merge my answers, or downvote one or whatever, just easier to provide an alternative as a new answer. I'll let the code do the talking instead of poorly explaining it. :)

## Some shared class that is used all over the place and needs to be patched.

class A(object):
    def __init__(self):
        self.firstname = 'Bob'

    # Print my first name.
    def name(self):
        return self.firstname

    # Use this to allow patching arbitrary methods...
    def patch(cls, func_name):
        def patch_by_name(new_func):
            old_func = getattr(cls, func_name)
            def patched_func(self):
                return new_func(self, old_func)
            setattr(cls, func_name, patched_func)
        return patch_by_name

## Some other area of the code where you want to throw in a patch

class PatchedA(A):  # doesn't need to subclass, but comes in handy sometimes
    def name(self, orig_func):
        return 'I am ' + orig_func(self) + 'McWizwaz'

print 'Who are you, A class?'
print A().name()  # prints 'I am Bob McWizwaz'
  • (And of course, you're free to make it not a classmethod and just a standalone function and call it as @patch(A, 'name') instead, thus making it usable for any class anywhere.) – Spencer Jan 4 '12 at 16:46
  • Wouldn't it be easier to do put that @patch decorator outside of A and also apply it to the patching def name outside any subclass? What exactly is the purpose of a subclass PatchedA anyway, when you replace the original A's method? – Tobias Kienzler Aug 28 '13 at 7:15

This is what we call a 'decorator' pattern. Replace the original reassignment of name to have it call a function instead, which takes the original. It then returns a new function.

def name_decorator(method):
    def decorate_name(self=None):
        return stuff + method(self)
    return decorate_name
A.name = name_decorator(A.name)

Later, calling A.name will call decorate_name with self as the current instance and method will be available to it which points to the function at the time of the reassignment.

  • +1 because python decorators are doing exactly what I want. I'll accept this answer when I can check it can be generalized. – rds Jan 4 '12 at 14:20
  • I use Python 3. What syntax sugar can help? – rds Jan 4 '12 at 14:21
  • See: docs.python.org/reference/compound%5Fstmts.html#function - rather than do explicit overrides, you can place @my_decorator right before any function def you want to decorate. – Spencer Jan 4 '12 at 14:26
  • Lemme phrase that better... A would define functions, along with a foo method whose sole purpose is to do what I originally pasted. It takes a function and returns a closure. Later, someone can subclass it and put @foo before their name() impl, which at runtime causes the patch/punch to happen. Direct consumers of A get the subclass' version w/ out having to touch all that code. – Spencer Jan 4 '12 at 14:36
  • Decorators syntax exist since python 2.4. – Ski Jan 4 '12 at 16:20
class ABase(object):
    def name(self):

class A(object):

class AExtension(ABase):
    def name(self):
        return ABase.name(self)

A.name = AExtension.name
  • I'm not sure I understand what class should be used. I need to copy all methods from ABase to A (A.name=ABase.name etc) and then load extensions (A.name=AExtension.name)? – rds Jan 4 '12 at 13:16
  • A already has all methods of ABase because A extends ABase. But overall the idea of reassigning methods to other class looks suspicious. You might find some ideas how to correctly a minimal plugin architecture in this topic: stackoverflow.com/questions/932069/… – Ski Jan 4 '12 at 13:28
  • @Skirmantas, it's not uncommon to decorate functions like he wants to do. Newer versions of the language even support syntactic sugar to make my example even easier to write. – Spencer Jan 4 '12 at 13:48
  • @Skirmantas Thanks for the pointer (already opened in the past :-). I actually build my plugin mechanism from Mary Alchin's simple plugin framework. I have already a couple of extensions point at strategic places. However, I think it would be overkill to place extension points everywhere (particularly in the model). That's why I'd rather let plugins overwrites some parts if they want to. – rds Jan 4 '12 at 14:18
  • You don't even need to put the patching def name in any (sub)class, do you? – Tobias Kienzler Aug 28 '13 at 7:17

One option that might not always be the best in a language like Python is to use the @override decorator from this non-standard package. But this is a viable option only if your two functions work on different types or different number of arguments. Other than that, there's not much you can do, besides renaming your function.

  • Interesting package, but I don't see how it can help me :-/ – rds Jan 4 '12 at 13:21

Standing on the shoulders of giants (@spencer), here's a bit more generic sample. It lets one patch a class Original without touching its source code. In this version, parameters fly all over the place, and a reference to an arbitrary context is given to the new method.

class Original:
    def f( self, a, b = None ):
        print( "f", a, b )
        self.g( b )

    def g( self, b ):
        print( "g", b )

class Patcher:
    def prepare_class( self, clazz ):
        def on_class_patcher( cls, func_name, context ):
            def patch_by_name( new_func) :
                old_func = getattr( cls, func_name )
                def patched_func( self, *args, **kwargs ):
                    return new_func( self, old_func, context, *args, **kwargs )
                setattr( cls, func_name, patched_func )
            return patch_by_name

        setattr( clazz, "patch", on_class_patcher )

class Another:
    def log( self, level, info ):
        print( level, info )

Now, let's patch something:

obj = Original()
obj.f( 1, b = "hello" )

p = Patcher()
p.prepare_class( clazz = Original )

logger = Another()

@Original.patch( "f", context = logger  )
def new_f( self, old_f, context, a, b ):
    print( "new_f", a, b )
    context.log( "zzz", a )
    old_f( self, a, b )

obj = Original()
obj.f( 1, b = "hello" )

And the output is:

f 1 hello
g hello
new_f 1 hello
zzz 1
f 1 hello
g hello

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