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In Python 3.x, super() can be called without arguments:

class A(object):
    def x(self):
         print("Hey now")

class B(A):
    def x(self):
>>> B().x()
Hey now

In order to make this work, some compile-time magic is performed, one consequence of which is that the following code (which rebinds super to super_) fails:

super_ = super

class A(object):
    def x(self):
        print("No flipping")

class B(A):
    def x(self):
>>> B().x()
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
  File "<stdin>", line 3, in x
RuntimeError: super(): __class__ cell not found

Why is super() unable to resolve the superclass at runtime without assistance from the compiler? Are there practical situations in which this behaviour, or the underlying reason for it, could bite an unwary programmer?

... and, as a side question: are there any other examples in Python of functions, methods etc. which can be broken by rebinding them to a different name?

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Congratulations, you've found another reason for me to dislike the implicit hidden closure creation utilised for super(). –  Martijn Pieters Oct 26 '13 at 14:59
I'll let Armin do the explaining on this one. This is also another good post –  Games Brainiac Oct 26 '13 at 15:01
@MartijnPieters I knew about this after Armin's blog post! :P Then I did some exploring on my own. –  Games Brainiac Oct 26 '13 at 15:01
@GamesBrainiac: That blog post just complains about the same issue, it doesn't serve as an answer to Zero's question. I personally disagree with most of the Unicode opinions in that post, btw; the UCS2 / UCS4 issue has been resolved in Python 3.3 and up. –  Martijn Pieters Oct 26 '13 at 15:07
@MartijnPieters I realise now that it was a different post, I can't find it now. :( –  Games Brainiac Oct 26 '13 at 15:08

1 Answer 1

up vote 58 down vote accepted

The new magic super() behaviour was added to avoid violating the D.R.Y. (Don't Repeat Yourself) principle, see PEP 3135. Having to explicitly name the class by referencing it as a global is also prone to the same rebinding issues you discovered with super() itself:

class Foo(Bar):
    def baz(self):
        return super(Foo, self).baz() + 42

Spam = Foo
Foo = something_else()

The same applies to using class decorators where the decorator returns a new object, which rebinds the class name:

class Foo(Bar):
    def baz(self):
        # Now `Foo` is a *different class*
        return super(Foo, self).baz() + 42

The magic super() __class__ cell sidesteps these issues nicely by giving you access to the original class object.

The PEP was kicked off by Guido, who initially envisioned super becoming a keyword, and the idea of using a cell to look up the current class was also his. Certainly, the idea to make it a keyword was part of the first draft of the PEP.

However, it was in fact Guido himself who then stepped away from the keyword idea as 'too magical', proposing the current implementation instead. He anticipated that using a different name for super() could be a problem:

My patch uses an intermediate solution: it assumes you need __class__ whenever you use a variable named 'super'. Thus, if you (globally) rename super to supper and use supper but not super, it won't work without arguments (but it will still work if you pass it either __class__ or the actual class object); if you have an unrelated variable named super, things will work but the method will use the slightly slower call path used for cell variables.

So, in the end, it was Guido himself that proclaimed that using a super keyword did not feel right, and that providing a magic __class__ cell was an acceptable compromise.

I agree that the magic, implicit behaviour of the implementation is somewhat surprising, but super() is one of the most mis-applied functions in the language. Just take a look at all the misapplied super(type(self), self) or super(self.__class__, self) invocations found on the Internet; if any of that code was ever called from a derived class you'd end up with an infinite recursion exception. At the very least the simplified super() call, without arguments, avoids that problem.

As for the renamed super_; just reference __class__ in your method as well and it'll work again. The cell is created if you use super() or use __class__ in your method:

>>> super_ = super
>>> class A(object):
...     def x(self):
...         print("No flipping")
>>> class B(A):
...     def x(self):
...         __class__  # just referencing it is enough
...         super_().x()
>>> B().x()
No flipping
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Good write-up. It's still as clear as mud however. You are saying that super() is equivalent to an automatically instantiated function like def super(of_class=magic __class__) kind of like a self.super(); def super(self): return self.__class__? –  Charles Merriam Mar 14 '14 at 16:28
@CharlesMerriam: This post is not about how super() without arguments works; it mostly deals with the why it exists. super(), in a class method, is equivalent to super(ReferenceToClassMethodIsBeingDefinedIn, self), where ReferenceToClassMethodIsBeingDefinedIn is determined at compile time, attached to the method as a closure named __class__ and super() will look up both from the calling frame at runtime. But you don't actually need to know all this. –  Martijn Pieters Mar 14 '14 at 16:37
@CharlesMerriam: but super() is nowhere close to being an automatically instantiated function, no. –  Martijn Pieters Mar 14 '14 at 16:38

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