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Consider this code snippet:

import gc
from weakref import ref


def leak_class(create_ref):
    class Foo(object):
        # make cycle non-garbage collectable
        def __del__(self):
            pass

    if create_ref:
        # create a strong reference cycle
        Foo.bar = Foo()
    return ref(Foo)


# without reference cycle
r = leak_class(False)
gc.collect()
print r() # prints None

# with reference cycle
r = leak_class(True)
gc.collect()
print r() # prints <class '__main__.Foo'>

It creates a reference cycle that cannot be collected, because the referenced instance has a __del__ method. The cycle is created here:

# create a strong reference cycle
Foo.bar = Foo()

This is just a proof of concept, the reference could be added by some external code, a descriptor or anything. If that's not clear to you, remember that each objects mantains a reference to its class:

  +-------------+             +--------------------+
  |             |  Foo.bar    |                    |
  | Foo (class) +------------>| foo (Foo instance) |
  |             |             |                    |
  +-------------+             +----------+---------+
        ^                                |
        |         foo.__class__          |
        +--------------------------------+

If I could guarantee that Foo.bar is only accessed from Foo, the cycle wouldn't be necessary, as theoretically the instance could hold only a weak reference to its class.

Can you think of a practical way to make this work without a leak?


As some are asking why would external code modify a class but can't control its lifecycle, consider this example, similar to the real-life example I was working to:

class Descriptor(object):
    def __get__(self, obj, kls=None):
        if obj is None:
            try:
                obj = kls._my_instance
            except AttributeError:
                obj = kls()
                kls._my_instance = obj
        return obj.something()


# usage example #
class Example(object):
    foo = Descriptor()

    def something(self):
        return 100


print Example.foo

In this code only Descriptor (a non-data descriptor) is part of the API I'm implementing. Example class is an example of how the descriptor would be used.

Why does the descriptor store a reference to an instance inside the class itself? Basically for caching purposes. Descriptor required this contract with the implementor: it would be used in any class assuming that

  1. The class has a constructor with no args, that gives an "anonymous instance" (my definition)
  2. The class has some behavior-specific methods (something here).
  3. An instance of the class can stay alive for an undefined amount of time.

It doesn't assume anything about:

  1. How long it takes to construct an object
  2. Whether the class implements del or other magic methods
  3. How long the class is expected to live

Moreover the API was designed to avoid any extra load on the class implementor. I could have moved the responsibility for caching the object to the implementor, but I wanted a standard behavior.

There actually is a simple solution to this problem: make the default behavior to cache the instance (like it does in this code) but allow the implementor to override it if they have to implement __del__.

Of course this wouldn't be as simple if we assumed that the class state had to be preserved between calls.


As a starting point, I was coding a "weak object", an implementation of object that only kept a weak reference to its class:

from weakref import proxy

def make_proxy(strong_kls):
    kls = proxy(strong_kls)
    class WeakObject(object):
        def __getattribute__(self, name):
            try:
                attr = kls.__dict__[name]
            except KeyError:
                raise AttributeError(name)

            try:
                return attr.__get__(self, kls)
            except AttributeError:
                return attr
        def __setattr__(self, name, value):
            # TODO: implement...
            pass
    return WeakObject

Foo.bar = make_proxy(Foo)()

It appears to work for a limited number of use cases, but I'd have to reimplement the whole set of object methods, and I don't know how to deal with classes that override __new__.

share|improve this question
    
Make what work, exactly? What are you trying to accomplish? Why don't you just delete the attribute Foo.bar when you are done with the instance? –  BrenBarn Mar 20 '13 at 17:25
    
Assume the reference is added by external code, that has no control over the lifecycle of the instance. I stumbled upon this problem first while writing a descriptor that could be applied to any class, including Foo. –  Davide R. Mar 20 '13 at 17:27
    
So, if I understand, in your real-life case you have a local class definition, which at some point goes out of scope, and needs to get freed. But during its lifetime, some external code adds attributes to it. Can you explain how and why? –  shx2 Mar 20 '13 at 19:26
    
@shx2 I added an almost-real-life code example (after the first horizontal break) with an explanation. In my real-life problem I restricted the contract so to avoid this situation, but I'm left with my question. –  Davide R. Mar 20 '13 at 20:03
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2 Answers

For your example, why don't you store _my_instance in a dict on the descriptor class, rather than on the class holding the descriptor? You could use a weakref or WeakValueDictionary in that dict, so that when the object disappears the dict will just lose its reference and the descriptor will create a new one on the next access.

Edit: I think you have a misunderstanding about the possibility of collecting the class while the instance lives on. Methods in Python are stored on the class, not the instance (barring peculiar tricks). If you have an object obj of class Class, and you allowed Class to be garbage collected while obj still exists, then calling a method obj.meth() on the object would fail, because the method would have disappeared along with the class. That is why your only option is to weaken your class->obj reference; even if you could make objects weakly reference their class, all it would do is break the class if the weakness ever "took effect" (i.e., if the class were collected while an instance still existed).

share|improve this answer
    
Yes, that's a possibility I considered. The problem here is that, if the class could be dinamically created (as in the example), the dictionary would become crowded. Maybe with a dead-refs pruning step. Real-life problem? Possibly not, but I don't want to feel limited by an implementation detail of the language. :) –  Davide R. Mar 20 '13 at 21:26
    
Oh, sorry, I missed one of the points in your answer. The strong reference to the instance is needed to keep it alive. Otherwise I wouldn't store the reference in the first place. –  Davide R. Mar 20 '13 at 21:28
    
@DavideR.: "Crowded"? Are you saying you're worried the dict will get too big? By setting cls._my_instance all you are doing is setting a key in the class's dict, so there's no getting around that. –  BrenBarn Mar 20 '13 at 21:31
    
@DavideR.: I guess I haven't really understood your question. If you insist on keeping the object alive with your reference, then you cannot avoid a reference cycle. The solution is to not keep the object alive. From your example, I don't see that you need to keep it alive. If you're just keeping it for caching, letting the object be collected is just invalidating the cache when it dies, which seems perfectly reasonable. –  BrenBarn Mar 20 '13 at 21:34
1  
@DavideR.: I added a bit more explanation. Because methods are stored on the class, not the instance, you have no hope of being able to garbage collect the class while the instance is still alive. The instance needs a strong reference to the class to ensure that it can access its methods. –  BrenBarn Mar 20 '13 at 21:47
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The problem you're facing is just a special case of the general ref-cycle-with-__del__ problem.

I don't see anything unusual in the way the cycles are created in your case, which is to say, you should resort to the standard ways of avoiding the general problem.

I think implementing and using a weak object would be hard to get right, and you would still need to remember to use it in all places where you define __del__. It doesn't sound like the best approach.

Instead, you should try the following:

  1. consider not defining __del__ in your class (recommended)
  2. in classes which define __del__, avoid reference cycles (in general, it might be hard/impossible to make sure no cycles are created anywhere in your code. In your case, seems like you want the cycles to exist)
  3. explicitly break the cycles, using del (if there are appropriate points to do that in your code)
  4. scan the gc.garbage list, and explicitly break reference cycles (using del)
share|improve this answer
    
I'm sorry this is not really an answer to my question, but rather a way to avoid the problem. This still has value for the community, but it's not dealing with the core of the question. –  Davide R. Mar 20 '13 at 20:48
    
Anyway I would argue that there is something inherently special in this specific ref-cycle problem. Some ref-cycles can be broken by properly using weak references. This can't be done here as objects apparently must contain a strong reference to their own class. –  Davide R. Mar 20 '13 at 20:56
    
@DavideR.: Yes, but why does your descriptor have to give the class a strong reference to the object? Why don't you store that information weakly, somewhere else (not on the class)? –  BrenBarn Mar 20 '13 at 20:59
    
@DavidR: Points 3 and 4 in this answer are ways to solve the problem. –  BrenBarn Mar 20 '13 at 21:34
    
No, because I can't know whenever it is appropriate to del (given the example in the question). The only way to know, AFAIK, is via weakref callbacks. –  Davide R. Mar 21 '13 at 8:38
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