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108 lines
5.9 KiB
108 lines
5.9 KiB
4 years ago
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Before 2.3.3, Python's cyclic gc didn't pay any attention to weakrefs.
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Segfaults in Zope3 resulted.
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weakrefs in Python are designed to, at worst, let *other* objects learn
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that a given object has died, via a callback function. The weakly
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referenced object itself is not passed to the callback, and the presumption
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is that the weakly referenced object is unreachable trash at the time the
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callback is invoked.
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That's usually true, but not always. Suppose a weakly referenced object
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becomes part of a clump of cyclic trash. When enough cycles are broken by
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cyclic gc that the object is reclaimed, the callback is invoked. If it's
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possible for the callback to get at objects in the cycle(s), then it may be
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possible for those objects to access (via strong references in the cycle)
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the weakly referenced object being torn down, or other objects in the cycle
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that have already suffered a tp_clear() call. There's no guarantee that an
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object is in a sane state after tp_clear(). Bad things (including
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segfaults) can happen right then, during the callback's execution, or can
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happen at any later time if the callback manages to resurrect an insane
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object.
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Note that if it's possible for the callback to get at objects in the trash
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cycles, it must also be the case that the callback itself is part of the
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trash cycles. Else the callback would have acted as an external root to
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the current collection, and nothing reachable from it would be in cyclic
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trash either.
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More, if the callback itself is in cyclic trash, then the weakref to which
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the callback is attached must also be trash, and for the same kind of
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reason: if the weakref acted as an external root, then the callback could
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not have been cyclic trash.
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So a problem here requires that a weakref, that weakref's callback, and the
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weakly referenced object, all be in cyclic trash at the same time. This
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isn't easy to stumble into by accident while Python is running, and, indeed,
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it took quite a while to dream up failing test cases. Zope3 saw segfaults
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during shutdown, during the second call of gc in Py_Finalize, after most
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modules had been torn down. That creates many trash cycles (esp. those
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involving new-style classes), making the problem much more likely. Once you
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know what's required to provoke the problem, though, it's easy to create
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tests that segfault before shutdown.
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In 2.3.3, before breaking cycles, we first clear all the weakrefs with
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callbacks in cyclic trash. Since the weakrefs *are* trash, and there's no
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defined-- or even predictable --order in which tp_clear() gets called on
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cyclic trash, it's defensible to first clear weakrefs with callbacks. It's
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a feature of Python's weakrefs too that when a weakref goes away, the
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callback (if any) associated with it is thrown away too, unexecuted.
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Just that much is almost enough to prevent problems, by throwing away
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*almost* all the weakref callbacks that could get triggered by gc. The
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problem remaining is that clearing a weakref with a callback decrefs the
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callback object, and the callback object may *itself* be weakly referenced,
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via another weakref with another callback. So the process of clearing
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weakrefs can trigger callbacks attached to other weakrefs, and those
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latter weakrefs may or may not be part of cyclic trash.
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So, to prevent any Python code from running while gc is invoking tp_clear()
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on all the objects in cyclic trash, it's not quite enough just to invoke
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tp_clear() on weakrefs with callbacks first. Instead the weakref module
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grew a new private function (_PyWeakref_ClearRef) that does only part of
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tp_clear(): it removes the weakref from the weakly-referenced object's list
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of weakrefs, but does not decref the callback object. So calling
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_PyWeakref_ClearRef(wr) ensures that wr's callback object will never
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trigger, and (unlike weakref's tp_clear()) also prevents any callback
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associated *with* wr's callback object from triggering.
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Then we can call tp_clear on all the cyclic objects and never trigger
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Python code.
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After we do that, the callback objects still need to be decref'ed. Callbacks
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(if any) *on* the callback objects that were also part of cyclic trash won't
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get invoked, because we cleared all trash weakrefs with callbacks at the
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start. Callbacks on the callback objects that were not part of cyclic trash
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acted as external roots to everything reachable from them, so nothing
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reachable from them was part of cyclic trash, so gc didn't do any damage to
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objects reachable from them, and it's safe to call them at the end of gc.
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An alternative would have been to treat objects with callbacks like objects
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with __del__ methods, refusing to collect them, appending them to gc.garbage
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instead. That would have been much easier. Jim Fulton gave a strong
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argument against that (on Python-Dev):
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There's a big difference between __del__ and weakref callbacks.
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The __del__ method is "internal" to a design. When you design a
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class with a del method, you know you have to avoid including the
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class in cycles.
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Now, suppose you have a design that makes has no __del__ methods but
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that does use cyclic data structures. You reason about the design,
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run tests, and convince yourself you don't have a leak.
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Now, suppose some external code creates a weakref to one of your
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objects. All of a sudden, you start leaking. You can look at your
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code all you want and you won't find a reason for the leak.
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IOW, a class designer can out-think __del__ problems, but has no control
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over who creates weakrefs to his classes or class instances. The class
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user has little chance either of predicting when the weakrefs he creates
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may end up in cycles.
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Callbacks on weakref callbacks are executed in an arbitrary order, and
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that's not good (a primary reason not to collect cycles with objects with
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__del__ methods is to avoid running finalizers in an arbitrary order).
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However, a weakref callback on a weakref callback has got to be rare.
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It's possible to do such a thing, so gc has to be robust against it, but
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I doubt anyone has done it outside the test case I wrote for it.
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