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I am interested in whether there is a way to introspect a Python instance infallibly to see its __dict__ despite any obstacles that the programmer might have thrown in the way, because that would help me debug problems like unintended reference loops and dangling resources like open files.

A simpler example is: how can I see the keys of a dict subclass if the programmer has hidden keys() behind a class of its own? The way around that is to manually call the dict keys() method instead of letting inheritance call the subclass's version of the method:

# Simple example of getting to the real info
# about an instance

class KeyHidingDict(dict):
    def keys(self):
        return []  # there are no keys here!

khd = KeyHidingDict(a=1, b=2, c=3)
khd.keys()       # drat, returns []
dict.keys(khd)   # aha! returns ['a', 'b', 'c']

Now my actual question is, how can I see the __dict__ of an instance, no matter what the programmer might have done to hide it from me? If they set a __dict__ class variable then it seems to shadow the actual __dict__ of any objects inherited from that class:

# My actual question

class DunderDictHider(object):
    __dict__ = {'fake': 'dict'}

ddh = DunderDictHider()
ddh.a = 1
ddh.b = 2
print ddh.a        # prints out 1
print ddh.__dict__ # drat, prints {'fake': 'dict'}

This false value for __dict__ does not, as you can see, interfere with actual attribute setting and getting, but it does mislead dir() by hiding a and b and displaying fake as the object's instance variable instead.

Again, my goal is to write a tool that helps me introspect class instances to see “what is really going on” when I am wondering why a set of class instances is taking so much memory or holding so many files open — and even though the situation above is extremely contrived, finding a way around it would let the tool work all the time instead of saying “works great, unless the class you are looking at has… [description of the exceptional situation above].”

I had thought I would be able to infallibly grab the __dict__ with something like:

dict_descr = object.__dict__['__dict__']
print dict_descr(ddh, DunderDictHider)

But it turns out that object does not have a __dict__ descriptor. Instead, the subtype_dict() C function seems to get separately attached to each subclass of object that the programmer creates; there is no central way to name or fetch the descriptor so that it can be manually applied to objects whose class shadows it.

Any ideas, anyone? :)

share|improve this question
Thank you for helping me think further! So that is a way out if, in the inheritance hierarchy objectAB, the object B is the one shadowing its instances' __dict__ attributes. But am I correct that your idea does not help if it is class A that is defining a misleading __dict__ class attribute? – Brandon Rhodes Sep 22 '11 at 10:27

I'm not sure I'm happy with how simple this is:

>>> class DunderDictHider(object):
...     __dict__ = {'fake': 'dict'}
>>> ddh = DunderDictHider()
>>> ddh.a = 1
>>> ddh.b = 2
>>> print ddh.a
>>> print ddh.__dict__
{'fake': 'dict'}

The problem is that the class is cheating? Fix that!

>>> class DictUnhider(object):
...     pass
>>> ddh.__class__ = DictUnhider
>>> print ddh.a
>>> print ddh.__dict__
{'a': 1, 'b': 2}

And there it is. This completely fails though, if the class defines any slots.

>>> class DoesntHaveDict(object):
...     __slots__ = ['a', 'b']
>>> dhd = DoesntHaveDict()
>>> dhd.a = 1
>>> dhd.b = 2
>>> print dhd.a
>>> dhd.__class__ = DictUnhider
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: __class__ assignment: 'DoesntHaveDict' object layout differs from 'DictUnhider'
share|improve this answer
__slots__ can still define a __dict__ that will work as the normal, default slot of the same name. also, you could mask the __slots__ var even if there isn't a real slots setup in the class. – SingleNegationElimination Sep 22 '11 at 14:52
Since the whole point was to introspect objects without changing them, I had already discarded the idea of making adjustments to the class — even in the absence of other threads that might be using the object at the same time as I am examining it, this solution would require that I switch out the __class__ of whole groups of objects while I can them for resources and open files. But I will think more about whether I should really be ignoring this possibility out-of-hand. Hmm. – Brandon Rhodes Sep 22 '11 at 18:14

This one is based on Jerub answer in this topic: What is a metaclass in Python?

You can achieve what you're looking for with metaclasses.

First you need to create a metaclass:

def test_metaclass(name, bases, dict):
    print 'The Class Name is', name
    print 'The Class Bases are', bases
    print 'The dict has', len(dict), 'elems, the keys are', dict.keys()

    return dict

of course the prints are not necessery.

Then let me introduce your new DunderDictHider:

class DunderDictHider(object):
    __metaclass__ = test_metaclass
    __dict__ = {'fake': 'dict'}

Now you have access to all initialized elems by repr(DunderDictHider)

The output (with print repr(DunderDictHider) line):

The Class Name is DunderDictHider
The Class Bases are (<type 'object'>,)
The dict has 3 elems, the keys are ['__dict__', '__module__', '__metaclass__']
{'__dict__': {'fake': 'dict'}, '__module__': '__main__', '__metaclass__': <function test_metaclass at 0x1001df758>}

Each time you can try

if '__dict__' in repr(DunderDictHider)

to know whether this class tries to hide its __dict__ or not. Remember, that repr output is a string. It can be done better, but that's the idea itself.

share|improve this answer
I say it's not fair to call it a metaclass if it's a function. Sure, it's valid, but it's not a class. – Chris Morgan Sep 22 '11 at 14:03
I might be a bit confused — my question was about examining the state of (a) object instances that (b) inherit from arbitrary classes that other programmers have written and that I cannot trust to have avoided techniques that would make introspection difficult. But: (a) I see no object instance here in your answer. (b) If I do not control the classes that programmers are writing, how am I going to control the metaclasses? – Brandon Rhodes Sep 22 '11 at 18:17

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