579 lines
21 KiB
ReStructuredText
579 lines
21 KiB
ReStructuredText
:mod:`weakref` --- Weak references
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==================================
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.. module:: weakref
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:synopsis: Support for weak references and weak dictionaries.
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.. moduleauthor:: Fred L. Drake, Jr. <fdrake@acm.org>
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.. moduleauthor:: Neil Schemenauer <nas@arctrix.com>
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.. moduleauthor:: Martin von Löwis <martin@loewis.home.cs.tu-berlin.de>
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.. sectionauthor:: Fred L. Drake, Jr. <fdrake@acm.org>
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**Source code:** :source:`Lib/weakref.py`
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--------------
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The :mod:`weakref` module allows the Python programmer to create :dfn:`weak
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references` to objects.
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.. When making changes to the examples in this file, be sure to update
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Lib/test/test_weakref.py::libreftest too!
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In the following, the term :dfn:`referent` means the object which is referred to
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by a weak reference.
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A weak reference to an object is not enough to keep the object alive: when the
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only remaining references to a referent are weak references,
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:term:`garbage collection` is free to destroy the referent and reuse its memory
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for something else. However, until the object is actually destroyed the weak
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reference may return the object even if there are no strong references to it.
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A primary use for weak references is to implement caches or
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mappings holding large objects, where it's desired that a large object not be
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kept alive solely because it appears in a cache or mapping.
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For example, if you have a number of large binary image objects, you may wish to
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associate a name with each. If you used a Python dictionary to map names to
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images, or images to names, the image objects would remain alive just because
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they appeared as values or keys in the dictionaries. The
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:class:`WeakKeyDictionary` and :class:`WeakValueDictionary` classes supplied by
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the :mod:`weakref` module are an alternative, using weak references to construct
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mappings that don't keep objects alive solely because they appear in the mapping
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objects. If, for example, an image object is a value in a
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:class:`WeakValueDictionary`, then when the last remaining references to that
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image object are the weak references held by weak mappings, garbage collection
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can reclaim the object, and its corresponding entries in weak mappings are
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simply deleted.
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:class:`WeakKeyDictionary` and :class:`WeakValueDictionary` use weak references
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in their implementation, setting up callback functions on the weak references
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that notify the weak dictionaries when a key or value has been reclaimed by
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garbage collection. :class:`WeakSet` implements the :class:`set` interface,
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but keeps weak references to its elements, just like a
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:class:`WeakKeyDictionary` does.
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:class:`finalize` provides a straight forward way to register a
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cleanup function to be called when an object is garbage collected.
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This is simpler to use than setting up a callback function on a raw
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weak reference, since the module automatically ensures that the finalizer
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remains alive until the object is collected.
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Most programs should find that using one of these weak container types
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or :class:`finalize` is all they need -- it's not usually necessary to
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create your own weak references directly. The low-level machinery is
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exposed by the :mod:`weakref` module for the benefit of advanced uses.
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Not all objects can be weakly referenced; those objects which can include class
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instances, functions written in Python (but not in C), instance methods, sets,
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frozensets, some :term:`file objects <file object>`, :term:`generators <generator>`,
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type objects, sockets, arrays, deques, regular expression pattern objects, and code
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objects.
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.. versionchanged:: 3.2
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Added support for thread.lock, threading.Lock, and code objects.
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Several built-in types such as :class:`list` and :class:`dict` do not directly
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support weak references but can add support through subclassing::
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class Dict(dict):
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pass
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obj = Dict(red=1, green=2, blue=3) # this object is weak referenceable
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.. impl-detail::
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Other built-in types such as :class:`tuple` and :class:`int` do not support weak
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references even when subclassed.
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Extension types can easily be made to support weak references; see
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:ref:`weakref-support`.
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.. class:: ref(object[, callback])
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Return a weak reference to *object*. The original object can be retrieved by
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calling the reference object if the referent is still alive; if the referent is
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no longer alive, calling the reference object will cause :const:`None` to be
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returned. If *callback* is provided and not :const:`None`, and the returned
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weakref object is still alive, the callback will be called when the object is
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about to be finalized; the weak reference object will be passed as the only
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parameter to the callback; the referent will no longer be available.
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It is allowable for many weak references to be constructed for the same object.
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Callbacks registered for each weak reference will be called from the most
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recently registered callback to the oldest registered callback.
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Exceptions raised by the callback will be noted on the standard error output,
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but cannot be propagated; they are handled in exactly the same way as exceptions
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raised from an object's :meth:`__del__` method.
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Weak references are :term:`hashable` if the *object* is hashable. They will
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maintain their hash value even after the *object* was deleted. If
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:func:`hash` is called the first time only after the *object* was deleted,
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the call will raise :exc:`TypeError`.
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Weak references support tests for equality, but not ordering. If the referents
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are still alive, two references have the same equality relationship as their
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referents (regardless of the *callback*). If either referent has been deleted,
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the references are equal only if the reference objects are the same object.
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This is a subclassable type rather than a factory function.
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.. attribute:: __callback__
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This read-only attribute returns the callback currently associated to the
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weakref. If there is no callback or if the referent of the weakref is
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no longer alive then this attribute will have value ``None``.
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.. versionchanged:: 3.4
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Added the :attr:`__callback__` attribute.
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.. function:: proxy(object[, callback])
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Return a proxy to *object* which uses a weak reference. This supports use of
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the proxy in most contexts instead of requiring the explicit dereferencing used
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with weak reference objects. The returned object will have a type of either
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``ProxyType`` or ``CallableProxyType``, depending on whether *object* is
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callable. Proxy objects are not :term:`hashable` regardless of the referent; this
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avoids a number of problems related to their fundamentally mutable nature, and
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prevent their use as dictionary keys. *callback* is the same as the parameter
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of the same name to the :func:`ref` function.
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.. function:: getweakrefcount(object)
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Return the number of weak references and proxies which refer to *object*.
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.. function:: getweakrefs(object)
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Return a list of all weak reference and proxy objects which refer to *object*.
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.. class:: WeakKeyDictionary([dict])
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Mapping class that references keys weakly. Entries in the dictionary will be
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discarded when there is no longer a strong reference to the key. This can be
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used to associate additional data with an object owned by other parts of an
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application without adding attributes to those objects. This can be especially
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useful with objects that override attribute accesses.
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.. note::
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Caution: Because a :class:`WeakKeyDictionary` is built on top of a Python
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dictionary, it must not change size when iterating over it. This can be
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difficult to ensure for a :class:`WeakKeyDictionary` because actions
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performed by the program during iteration may cause items in the
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dictionary to vanish "by magic" (as a side effect of garbage collection).
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:class:`WeakKeyDictionary` objects have an additional method that
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exposes the internal references directly. The references are not guaranteed to
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be "live" at the time they are used, so the result of calling the references
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needs to be checked before being used. This can be used to avoid creating
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references that will cause the garbage collector to keep the keys around longer
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than needed.
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.. method:: WeakKeyDictionary.keyrefs()
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Return an iterable of the weak references to the keys.
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.. class:: WeakValueDictionary([dict])
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Mapping class that references values weakly. Entries in the dictionary will be
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discarded when no strong reference to the value exists any more.
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.. note::
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Caution: Because a :class:`WeakValueDictionary` is built on top of a Python
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dictionary, it must not change size when iterating over it. This can be
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difficult to ensure for a :class:`WeakValueDictionary` because actions performed
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by the program during iteration may cause items in the dictionary to vanish "by
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magic" (as a side effect of garbage collection).
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:class:`WeakValueDictionary` objects have an additional method that has the
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same issues as the :meth:`keyrefs` method of :class:`WeakKeyDictionary`
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objects.
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.. method:: WeakValueDictionary.valuerefs()
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Return an iterable of the weak references to the values.
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.. class:: WeakSet([elements])
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Set class that keeps weak references to its elements. An element will be
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discarded when no strong reference to it exists any more.
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.. class:: WeakMethod(method)
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A custom :class:`ref` subclass which simulates a weak reference to a bound
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method (i.e., a method defined on a class and looked up on an instance).
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Since a bound method is ephemeral, a standard weak reference cannot keep
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hold of it. :class:`WeakMethod` has special code to recreate the bound
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method until either the object or the original function dies::
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>>> class C:
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... def method(self):
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... print("method called!")
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...
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>>> c = C()
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>>> r = weakref.ref(c.method)
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>>> r()
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>>> r = weakref.WeakMethod(c.method)
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>>> r()
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<bound method C.method of <__main__.C object at 0x7fc859830220>>
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>>> r()()
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method called!
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>>> del c
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>>> gc.collect()
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0
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>>> r()
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>>>
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.. versionadded:: 3.4
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.. class:: finalize(obj, func, *args, **kwargs)
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Return a callable finalizer object which will be called when *obj*
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is garbage collected. Unlike an ordinary weak reference, a finalizer
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will always survive until the reference object is collected, greatly
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simplifying lifecycle management.
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A finalizer is considered *alive* until it is called (either explicitly
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or at garbage collection), and after that it is *dead*. Calling a live
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finalizer returns the result of evaluating ``func(*arg, **kwargs)``,
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whereas calling a dead finalizer returns :const:`None`.
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Exceptions raised by finalizer callbacks during garbage collection
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will be shown on the standard error output, but cannot be
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propagated. They are handled in the same way as exceptions raised
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from an object's :meth:`__del__` method or a weak reference's
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callback.
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When the program exits, each remaining live finalizer is called
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unless its :attr:`atexit` attribute has been set to false. They
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are called in reverse order of creation.
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A finalizer will never invoke its callback during the later part of
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the :term:`interpreter shutdown` when module globals are liable to have
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been replaced by :const:`None`.
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.. method:: __call__()
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If *self* is alive then mark it as dead and return the result of
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calling ``func(*args, **kwargs)``. If *self* is dead then return
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:const:`None`.
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.. method:: detach()
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If *self* is alive then mark it as dead and return the tuple
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``(obj, func, args, kwargs)``. If *self* is dead then return
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:const:`None`.
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.. method:: peek()
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If *self* is alive then return the tuple ``(obj, func, args,
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kwargs)``. If *self* is dead then return :const:`None`.
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.. attribute:: alive
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Property which is true if the finalizer is alive, false otherwise.
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.. attribute:: atexit
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A writable boolean property which by default is true. When the
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program exits, it calls all remaining live finalizers for which
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:attr:`.atexit` is true. They are called in reverse order of
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creation.
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.. note::
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It is important to ensure that *func*, *args* and *kwargs* do
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not own any references to *obj*, either directly or indirectly,
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since otherwise *obj* will never be garbage collected. In
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particular, *func* should not be a bound method of *obj*.
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.. versionadded:: 3.4
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.. data:: ReferenceType
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The type object for weak references objects.
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.. data:: ProxyType
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The type object for proxies of objects which are not callable.
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.. data:: CallableProxyType
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The type object for proxies of callable objects.
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.. data:: ProxyTypes
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Sequence containing all the type objects for proxies. This can make it simpler
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to test if an object is a proxy without being dependent on naming both proxy
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types.
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.. exception:: ReferenceError
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Exception raised when a proxy object is used but the underlying object has been
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collected. This is the same as the standard :exc:`ReferenceError` exception.
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.. seealso::
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:pep:`205` - Weak References
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The proposal and rationale for this feature, including links to earlier
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implementations and information about similar features in other languages.
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.. _weakref-objects:
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Weak Reference Objects
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----------------------
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Weak reference objects have no methods and no attributes besides
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:attr:`ref.__callback__`. A weak reference object allows the referent to be
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obtained, if it still exists, by calling it:
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>>> import weakref
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>>> class Object:
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... pass
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...
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>>> o = Object()
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>>> r = weakref.ref(o)
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>>> o2 = r()
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>>> o is o2
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True
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If the referent no longer exists, calling the reference object returns
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:const:`None`:
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>>> del o, o2
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>>> print(r())
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None
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Testing that a weak reference object is still live should be done using the
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expression ``ref() is not None``. Normally, application code that needs to use
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a reference object should follow this pattern::
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# r is a weak reference object
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o = r()
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if o is None:
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# referent has been garbage collected
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print("Object has been deallocated; can't frobnicate.")
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else:
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print("Object is still live!")
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o.do_something_useful()
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Using a separate test for "liveness" creates race conditions in threaded
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applications; another thread can cause a weak reference to become invalidated
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before the weak reference is called; the idiom shown above is safe in threaded
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applications as well as single-threaded applications.
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Specialized versions of :class:`ref` objects can be created through subclassing.
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This is used in the implementation of the :class:`WeakValueDictionary` to reduce
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the memory overhead for each entry in the mapping. This may be most useful to
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associate additional information with a reference, but could also be used to
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insert additional processing on calls to retrieve the referent.
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This example shows how a subclass of :class:`ref` can be used to store
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additional information about an object and affect the value that's returned when
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the referent is accessed::
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import weakref
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class ExtendedRef(weakref.ref):
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def __init__(self, ob, callback=None, **annotations):
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super(ExtendedRef, self).__init__(ob, callback)
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self.__counter = 0
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for k, v in annotations.items():
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setattr(self, k, v)
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def __call__(self):
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"""Return a pair containing the referent and the number of
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times the reference has been called.
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"""
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ob = super(ExtendedRef, self).__call__()
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if ob is not None:
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self.__counter += 1
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ob = (ob, self.__counter)
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return ob
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.. _weakref-example:
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Example
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-------
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This simple example shows how an application can use object IDs to retrieve
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objects that it has seen before. The IDs of the objects can then be used in
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other data structures without forcing the objects to remain alive, but the
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objects can still be retrieved by ID if they do.
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.. Example contributed by Tim Peters.
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::
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import weakref
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_id2obj_dict = weakref.WeakValueDictionary()
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def remember(obj):
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oid = id(obj)
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_id2obj_dict[oid] = obj
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return oid
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def id2obj(oid):
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return _id2obj_dict[oid]
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.. _finalize-examples:
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Finalizer Objects
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-----------------
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The main benefit of using :class:`finalize` is that it makes it simple
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to register a callback without needing to preserve the returned finalizer
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object. For instance
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>>> import weakref
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>>> class Object:
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... pass
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...
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>>> kenny = Object()
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>>> weakref.finalize(kenny, print, "You killed Kenny!") #doctest:+ELLIPSIS
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<finalize object at ...; for 'Object' at ...>
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>>> del kenny
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You killed Kenny!
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The finalizer can be called directly as well. However the finalizer
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will invoke the callback at most once.
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>>> def callback(x, y, z):
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... print("CALLBACK")
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... return x + y + z
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...
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>>> obj = Object()
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>>> f = weakref.finalize(obj, callback, 1, 2, z=3)
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>>> assert f.alive
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>>> assert f() == 6
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CALLBACK
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>>> assert not f.alive
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>>> f() # callback not called because finalizer dead
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>>> del obj # callback not called because finalizer dead
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You can unregister a finalizer using its :meth:`~finalize.detach`
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method. This kills the finalizer and returns the arguments passed to
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the constructor when it was created.
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>>> obj = Object()
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>>> f = weakref.finalize(obj, callback, 1, 2, z=3)
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>>> f.detach() #doctest:+ELLIPSIS
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(<...Object object ...>, <function callback ...>, (1, 2), {'z': 3})
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>>> newobj, func, args, kwargs = _
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>>> assert not f.alive
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>>> assert newobj is obj
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>>> assert func(*args, **kwargs) == 6
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CALLBACK
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Unless you set the :attr:`~finalize.atexit` attribute to
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:const:`False`, a finalizer will be called when the program exits if it
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is still alive. For instance
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.. doctest::
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:options: +SKIP
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>>> obj = Object()
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>>> weakref.finalize(obj, print, "obj dead or exiting")
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<finalize object at ...; for 'Object' at ...>
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>>> exit()
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obj dead or exiting
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Comparing finalizers with :meth:`__del__` methods
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-------------------------------------------------
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Suppose we want to create a class whose instances represent temporary
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directories. The directories should be deleted with their contents
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when the first of the following events occurs:
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* the object is garbage collected,
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* the object's :meth:`remove` method is called, or
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* the program exits.
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We might try to implement the class using a :meth:`__del__` method as
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follows::
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class TempDir:
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def __init__(self):
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self.name = tempfile.mkdtemp()
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def remove(self):
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if self.name is not None:
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shutil.rmtree(self.name)
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self.name = None
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@property
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def removed(self):
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return self.name is None
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def __del__(self):
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self.remove()
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Starting with Python 3.4, :meth:`__del__` methods no longer prevent
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reference cycles from being garbage collected, and module globals are
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no longer forced to :const:`None` during :term:`interpreter shutdown`.
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So this code should work without any issues on CPython.
|
|
|
|
However, handling of :meth:`__del__` methods is notoriously implementation
|
|
specific, since it depends on internal details of the interpreter's garbage
|
|
collector implementation.
|
|
|
|
A more robust alternative can be to define a finalizer which only references
|
|
the specific functions and objects that it needs, rather than having access
|
|
to the full state of the object::
|
|
|
|
class TempDir:
|
|
def __init__(self):
|
|
self.name = tempfile.mkdtemp()
|
|
self._finalizer = weakref.finalize(self, shutil.rmtree, self.name)
|
|
|
|
def remove(self):
|
|
self._finalizer()
|
|
|
|
@property
|
|
def removed(self):
|
|
return not self._finalizer.alive
|
|
|
|
Defined like this, our finalizer only receives a reference to the details
|
|
it needs to clean up the directory appropriately. If the object never gets
|
|
garbage collected the finalizer will still be called at exit.
|
|
|
|
The other advantage of weakref based finalizers is that they can be used to
|
|
register finalizers for classes where the definition is controlled by a
|
|
third party, such as running code when a module is unloaded::
|
|
|
|
import weakref, sys
|
|
def unloading_module():
|
|
# implicit reference to the module globals from the function body
|
|
weakref.finalize(sys.modules[__name__], unloading_module)
|
|
|
|
|
|
.. note::
|
|
|
|
If you create a finalizer object in a daemonic thread just as the program
|
|
exits then there is the possibility that the finalizer
|
|
does not get called at exit. However, in a daemonic thread
|
|
:func:`atexit.register`, ``try: ... finally: ...`` and ``with: ...``
|
|
do not guarantee that cleanup occurs either.
|