Consider the following Python (runs in 2.x or 3.x):

class Outer(object):

  class Inner(object):
    def __init__(self):
      print("Inner.self", self)

o = Outer()
i = o.Inner()

I want to get my hands on o while inside Inner.__init__(). But:

  • I don't want o to be an explicit parameter to Inner.
  • I want O.Inner and o.Inner to be a class object, not something weird like a closure.

Can you suggest how I might achieve this?

Right now my best idea is to use thread local storage. In my use case, whenever I construct an o.Inner(), I'm already inside a method on o somewhere, and it wouldn't be a big deal to add

threading.local()["my o object"] = o

to my code.

This gives you an idea of the level of depravity I'm willing to consider.

  • 2
    This is one of those cases where we have to ask: "What is it that you're trying to accomplish? Because there's probably a better way to do it." In Java, you can't put two (public) classes in the same file unless one of them is inside the other. In Python, there is no such requirement, so there is probably a way to do what you want without using inner classes at all. – MatrixFrog Feb 17 '10 at 5:26
up vote 15 down vote accepted

In Python 2.6, a class decorator that's also a custom descriptor matches the specs you give:

class InnerClassDescriptor(object):
  def __init__(self, cls):
    self.cls = cls
  def __get__(self, instance, outerclass):
    class Wrapper(self.cls):
      outer = instance
    Wrapper.__name__ = self.cls.__name__
    return Wrapper

class Outer(object):
  class Inner(object):
    def __init__(self):
      print self.outer

o = Outer()
i = o.Inner()
print 'Outer is a', type(Outer)
print 'Inner is a', type(o.Inner)

This emits:

<__main__.Outer object at 0x82f90>
Outer is a <type 'type'>
Inner is a <type 'type'>

just to confirm that

o.Inner [[is]] a class object, not something weird like a closure

as per your peculiar specs. Of course it needs to be a different class each time for reentrancy -- even in a single-threaded world, the following:

o1 = Outer()
o2 = Outer()
i1 = o1.Inner
i2 = o2.Inner
print i1(), i2(), i1(), i2()

should work cleanly, and stashing o1 vs o2 anywhere else than in the classes returned by o1.Inner vs o2.Inner (e.g., in TLS) would mean horrible results for this use.

But then you didn't specify "o.Inner has to be exactly the same class object for every possible o that's an instance of Outer", so this code fully meets the specs you did give;-).

  • Marvelous! Now I must meditate whether I can live with o1.Inner != o2.Inner != Outer.Inner. Of course, bound methods != unbound methods, so it only makes sense that bound child classes != unbound child classes. – Larry Hastings Feb 17 '10 at 13:34
  • As written your approach returns a new class every time o.Inner is referenced, so "assert o.Inner == o.Inner" would fail. Caching the Wrapper class in the instance, like setattr(instance, "cache" + self.cls.__name__), then preferring the cached version where available, solves that at least. – Larry Hastings Feb 17 '10 at 13:45
  • Another tweak: if "instance" is None, then the get should return self.cls. Without this isinstance(i, Outer.Inner) returns False. – Larry Hastings Feb 21 '10 at 6:24
  • Finally, @LarryHastings has posted a recipe – xmedeko Mar 15 at 12:08

You can use a metaclass to implement a __get__ descriptor that binds the inner class to the outer one. And since you seem to be interested in only binding to a class, consider modifying the inner class in-place, unlike a function which is wrapped into a method.

>>> class Outer(object):
    class Inner(object):
        class __metaclass__(type):
            def __get__(self, instance, owner):
                self.owner = owner
                return self

>>> Outer.Inner is Outer().Inner
>>> Outer.Inner.owner is Outer

If you'd rather wrap the inner class via a subclass then replace the __get__ body with:

return type(self.__name__, (self,), {'owner': owner})
  • Let me play with it a little more, but I think this may serve my purposes better than Alex Martelli's admittedly-mind-meltingly-cool answer. If so, I'll switch my checkmark. Thanks! (And to all of you who said "it can't be done"--phooey!) – Larry Hastings Feb 17 '10 at 22:25
  • I'm giving you a check, as you did solve the problem as stated, with a creative solution that showed me something new. But I can't use this approach. The unfixable problem is that it cannot be multithread-safe. However as that was not a stated requirement I can't fault you for not handling it. – Larry Hastings Feb 21 '10 at 5:46
  • Sorry, new to Stack Overflow, I thought you could give multiple checks. I'll definitely give you an upvote, sorry for the confusion. – Larry Hastings Feb 21 '10 at 5:47

Can't be done. But with a bit of redesign:

class Outer(object):

  class _Inner(object):
    def __init__(self, outobj):
      self.outobj = outobj

  def Inner(self):
    return self._Inner(self)

o = Outer()
i = o.Inner()

print o, i.outobj
  • that’s cool. you simply specify what the inner class needs and you generate it via function from the outer object. – flying sheep May 16 '11 at 12:27
  • Actually, I think can be done (unless you are describing something else to what I think). See my answer for a demonstration. – Edward Feb 1 '16 at 17:17

You should redesign your code not to use inner classes and to explicitly pass the instance of Outer to Inner when you make it, or not to require it.

You can't (in any portable, reliable or efficient way.) Nested classes have no relation to the nesting class. They have no added value, either. Instead of using nested classes, use containment of instances -- define Outer and Inner separately, and create an instance of Inner in Outer.__init__, possibly passing Outer or the Outer instance if you need it. You can make Inner a class attribute of Outer if you insist, but it will have no special access to Outer.

  • 1
    @Thomas, so which one of the three characteristics you think my answer is missing -- seems pretty portable, reliable, and efficient to me (also pretty elegant, if I say so myself;-). The "special access" comes through Inner being a custom descriptor class (which wraps the original Inner class object via decorator syntax -- that's where the 2.6 requirement comes, as it needs to be a class decorator of course) -- so that, whenever o.Inner is accessed, o.Inner.__get__ comes into play (and gets o as an argument). – Alex Martelli Feb 17 '10 at 5:52
  • To be honest I didn't think of using a class decorator. It still seems like a nasty hack for no decent purpose. As for which of the three it lacks, obviously portability (it only works in Python 2.6 and later :) -- although I would point out that with your solution the inner class can't itself be a descriptor. And subsequent code in the class block can't use the inner class directly, which is presumably part of the reason it's an inner class in the first place. All in all I still stand by my answer that you shouldn't be creating interdependent classes like this; the complexity isn't worth it. – Thomas Wouters Apr 1 '10 at 10:55

See Access outer class from inner class in python (
for a simple reliable answer I made that only uses variables, attributes, functions and classes - no special code.

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