weakref
— Weak references¶
Source code: Lib/weakref.py
The weakref
module allows the Python programmer to create weak
references to objects.
In the following, the term referent means the object which is referred to by a weak reference.
A weak reference to an object is not enough to keep the object alive: when the only remaining references to a referent are weak references, garbage collection is free to destroy the referent and reuse its memory for something else. However, until the object is actually destroyed the weak reference may return the object even if there are no strong references to it.
A primary use for weak references is to implement caches or mappings holding large objects, where it’s desired that a large object not be kept alive solely because it appears in a cache or mapping.
For example, if you have a number of large binary image objects, you may wish to
associate a name with each. If you used a Python dictionary to map names to
images, or images to names, the image objects would remain alive just because
they appeared as values or keys in the dictionaries. The
WeakKeyDictionary
and WeakValueDictionary
classes supplied by
the weakref
module are an alternative, using weak references to construct
mappings that don’t keep objects alive solely because they appear in the mapping
objects. If, for example, an image object is a value in a
WeakValueDictionary
, then when the last remaining references to that
image object are the weak references held by weak mappings, garbage collection
can reclaim the object, and its corresponding entries in weak mappings are
simply deleted.
WeakKeyDictionary
and WeakValueDictionary
use weak references
in their implementation, setting up callback functions on the weak references
that notify the weak dictionaries when a key or value has been reclaimed by
garbage collection. WeakSet
implements the set
interface,
but keeps weak references to its elements, just like a
WeakKeyDictionary
does.
finalize
provides a straight forward way to register a
cleanup function to be called when an object is garbage collected.
This is simpler to use than setting up a callback function on a raw
weak reference, since the module automatically ensures that the finalizer
remains alive until the object is collected.
Most programs should find that using one of these weak container types
or finalize
is all they need – it’s not usually necessary to
create your own weak references directly. The low-level machinery is
exposed by the weakref
module for the benefit of advanced uses.
Not all objects can be weakly referenced; those objects which can include class instances, functions written in Python (but not in C), instance methods, sets, frozensets, some file objects, generators, type objects, sockets, arrays, deques, regular expression pattern objects, and code objects.
Changed in version 3.2: Added support for thread.lock, threading.Lock, and code objects.
Several built-in types such as list
and dict
do not directly
support weak references but can add support through subclassing:
class Dict(dict):
pass
obj = Dict(red=1, green=2, blue=3) # this object is weak referenceable
CPython implementation detail: Other built-in types such as tuple
and int
do not support weak
references even when subclassed.
Extension types can easily be made to support weak references; see Weak Reference Support.
When __slots__
are defined for a given type, weak reference support is
disabled unless a '__weakref__'
string is also present in the sequence of
strings in the __slots__
declaration.
See __slots__ documentation for details.
- class weakref.ref(object[, callback])¶
Return a weak reference to object. The original object can be retrieved by calling the reference object if the referent is still alive; if the referent is no longer alive, calling the reference object will cause
None
to be returned. If callback is provided and notNone
, and the returned weakref object is still alive, the callback will be called when the object is about to be finalized; the weak reference object will be passed as the only parameter to the callback; the referent will no longer be available.It is allowable for many weak references to be constructed for the same object. Callbacks registered for each weak reference will be called from the most recently registered callback to the oldest registered callback.
Exceptions raised by the callback will be noted on the standard error output, but cannot be propagated; they are handled in exactly the same way as exceptions raised from an object’s
__del__()
method.Weak references are hashable if the object is hashable. They will maintain their hash value even after the object was deleted. If
hash()
is called the first time only after the object was deleted, the call will raiseTypeError
.Weak references support tests for equality, but not ordering. If the referents are still alive, two references have the same equality relationship as their referents (regardless of the callback). If either referent has been deleted, the references are equal only if the reference objects are the same object.
This is a subclassable type rather than a factory function.
- __callback__¶
This read-only attribute returns the callback currently associated to the weakref. If there is no callback or if the referent of the weakref is no longer alive then this attribute will have value
None
.
Changed in version 3.4: Added the
__callback__
attribute.
- weakref.proxy(object[, callback])¶
Return a proxy to object which uses a weak reference. This supports use of the proxy in most contexts instead of requiring the explicit dereferencing used with weak reference objects. The returned object will have a type of either
ProxyType
orCallableProxyType
, depending on whether object is callable. Proxy objects are not hashable regardless of the referent; this avoids a number of problems related to their fundamentally mutable nature, and prevent their use as dictionary keys. callback is the same as the parameter of the same name to theref()
function.Accessing an attribute of the proxy object after the referent is garbage collected raises
ReferenceError
.Changed in version 3.8: Extended the operator support on proxy objects to include the matrix multiplication operators
@
and@=
.
- weakref.getweakrefcount(object)¶
Return the number of weak references and proxies which refer to object.
- weakref.getweakrefs(object)¶
Return a list of all weak reference and proxy objects which refer to object.
- class weakref.WeakKeyDictionary([dict])¶
Mapping class that references keys weakly. Entries in the dictionary will be discarded when there is no longer a strong reference to the key. This can be used to associate additional data with an object owned by other parts of an application without adding attributes to those objects. This can be especially useful with objects that override attribute accesses.
Note that when a key with equal value to an existing key (but not equal identity) is inserted into the dictionary, it replaces the value but does not replace the existing key. Due to this, when the reference to the original key is deleted, it also deletes the entry in the dictionary:
>>> class T(str): pass ... >>> k1, k2 = T(), T() >>> d = weakref.WeakKeyDictionary() >>> d[k1] = 1 # d = {k1: 1} >>> d[k2] = 2 # d = {k1: 2} >>> del k1 # d = {}
A workaround would be to remove the key prior to reassignment:
>>> class T(str): pass ... >>> k1, k2 = T(), T() >>> d = weakref.WeakKeyDictionary() >>> d[k1] = 1 # d = {k1: 1} >>> del d[k1] >>> d[k2] = 2 # d = {k2: 2} >>> del k1 # d = {k2: 2}
Changed in version 3.9: Added support for
|
and|=
operators, specified in PEP 584.
WeakKeyDictionary
objects have an additional method that
exposes the internal references directly. The references are not guaranteed to
be “live” at the time they are used, so the result of calling the references
needs to be checked before being used. This can be used to avoid creating
references that will cause the garbage collector to keep the keys around longer
than needed.
- WeakKeyDictionary.keyrefs()¶
Return an iterable of the weak references to the keys.
- class weakref.WeakValueDictionary([dict])¶
Mapping class that references values weakly. Entries in the dictionary will be discarded when no strong reference to the value exists any more.
Changed in version 3.9: Added support for
|
and|=
operators, as specified in PEP 584.
WeakValueDictionary
objects have an additional method that has the
same issues as the keyrefs()
method of WeakKeyDictionary
objects.
- WeakValueDictionary.valuerefs()¶
Return an iterable of the weak references to the values.
- class weakref.WeakSet([elements])¶
Set class that keeps weak references to its elements. An element will be discarded when no strong reference to it exists any more.
- class weakref.WeakMethod(method)¶
A custom
ref
subclass which simulates a weak reference to a bound method (i.e., a method defined on a class and looked up on an instance). Since a bound method is ephemeral, a standard weak reference cannot keep hold of it.WeakMethod
has special code to recreate the bound method until either the object or the original function dies:>>> class C: ... def method(self): ... print("method called!") ... >>> c = C() >>> r = weakref.ref(c.method) >>> r() >>> r = weakref.WeakMethod(c.method) >>> r() <bound method C.method of <__main__.C object at 0x7fc859830220>> >>> r()() method called! >>> del c >>> gc.collect() 0 >>> r() >>>
New in version 3.4.
- class weakref.finalize(obj, func, /, *args, **kwargs)¶
Return a callable finalizer object which will be called when obj is garbage collected. Unlike an ordinary weak reference, a finalizer will always survive until the reference object is collected, greatly simplifying lifecycle management.
A finalizer is considered alive until it is called (either explicitly or at garbage collection), and after that it is dead. Calling a live finalizer returns the result of evaluating
func(*arg, **kwargs)
, whereas calling a dead finalizer returnsNone
.Exceptions raised by finalizer callbacks during garbage collection will be shown on the standard error output, but cannot be propagated. They are handled in the same way as exceptions raised from an object’s
__del__()
method or a weak reference’s callback.When the program exits, each remaining live finalizer is called unless its
atexit
attribute has been set to false. They are called in reverse order of creation.A finalizer will never invoke its callback during the later part of the interpreter shutdown when module globals are liable to have been replaced by
None
.- __call__()¶
If self is alive then mark it as dead and return the result of calling
func(*args, **kwargs)
. If self is dead then returnNone
.
- detach()¶
If self is alive then mark it as dead and return the tuple
(obj, func, args, kwargs)
. If self is dead then returnNone
.
- peek()¶
If self is alive then return the tuple
(obj, func, args, kwargs)
. If self is dead then returnNone
.
- alive¶
Property which is true if the finalizer is alive, false otherwise.
- atexit¶
A writable boolean property which by default is true. When the program exits, it calls all remaining live finalizers for which
atexit
is true. They are called in reverse order of creation.
Note
It is important to ensure that func, args and kwargs do not own any references to obj, either directly or indirectly, since otherwise obj will never be garbage collected. In particular, func should not be a bound method of obj.
New in version 3.4.
- weakref.ReferenceType¶
The type object for weak references objects.
- weakref.ProxyType¶
The type object for proxies of objects which are not callable.
- weakref.CallableProxyType¶
The type object for proxies of callable objects.
- weakref.ProxyTypes¶
Sequence containing all the type objects for proxies. This can make it simpler to test if an object is a proxy without being dependent on naming both proxy types.
See also
- PEP 205 - Weak References
The proposal and rationale for this feature, including links to earlier implementations and information about similar features in other languages.
Weak Reference Objects¶
Weak reference objects have no methods and no attributes besides
ref.__callback__
. A weak reference object allows the referent to be
obtained, if it still exists, by calling it:
>>> import weakref
>>> class Object:
... pass
...
>>> o = Object()
>>> r = weakref.ref(o)
>>> o2 = r()
>>> o is o2
True
If the referent no longer exists, calling the reference object returns
None
:
>>> del o, o2
>>> print(r())
None
Testing that a weak reference object is still live should be done using the
expression ref() is not None
. Normally, application code that needs to use
a reference object should follow this pattern:
# r is a weak reference object
o = r()
if o is None:
# referent has been garbage collected
print("Object has been deallocated; can't frobnicate.")
else:
print("Object is still live!")
o.do_something_useful()
Using a separate test for “liveness” creates race conditions in threaded applications; another thread can cause a weak reference to become invalidated before the weak reference is called; the idiom shown above is safe in threaded applications as well as single-threaded applications.
Specialized versions of ref
objects can be created through subclassing.
This is used in the implementation of the WeakValueDictionary
to reduce
the memory overhead for each entry in the mapping. This may be most useful to
associate additional information with a reference, but could also be used to
insert additional processing on calls to retrieve the referent.
This example shows how a subclass of ref
can be used to store
additional information about an object and affect the value that’s returned when
the referent is accessed:
import weakref
class ExtendedRef(weakref.ref):
def __init__(self, ob, callback=None, /, **annotations):
super().__init__(ob, callback)
self.__counter = 0
for k, v in annotations.items():
setattr(self, k, v)
def __call__(self):
"""Return a pair containing the referent and the number of
times the reference has been called.
"""
ob = super().__call__()
if ob is not None:
self.__counter += 1
ob = (ob, self.__counter)
return ob
Example¶
This simple example shows how an application can use object IDs to retrieve objects that it has seen before. The IDs of the objects can then be used in other data structures without forcing the objects to remain alive, but the objects can still be retrieved by ID if they do.
import weakref
_id2obj_dict = weakref.WeakValueDictionary()
def remember(obj):
oid = id(obj)
_id2obj_dict[oid] = obj
return oid
def id2obj(oid):
return _id2obj_dict[oid]
Finalizer Objects¶
The main benefit of using finalize
is that it makes it simple
to register a callback without needing to preserve the returned finalizer
object. For instance
>>> import weakref
>>> class Object:
... pass
...
>>> kenny = Object()
>>> weakref.finalize(kenny, print, "You killed Kenny!")
<finalize object at ...; for 'Object' at ...>
>>> del kenny
You killed Kenny!
The finalizer can be called directly as well. However the finalizer will invoke the callback at most once.
>>> def callback(x, y, z):
... print("CALLBACK")
... return x + y + z
...
>>> obj = Object()
>>> f = weakref.finalize(obj, callback, 1, 2, z=3)
>>> assert f.alive
>>> assert f() == 6
CALLBACK
>>> assert not f.alive
>>> f() # callback not called because finalizer dead
>>> del obj # callback not called because finalizer dead
You can unregister a finalizer using its detach()
method. This kills the finalizer and returns the arguments passed to
the constructor when it was created.
>>> obj = Object()
>>> f = weakref.finalize(obj, callback, 1, 2, z=3)
>>> f.detach()
(<...Object object ...>, <function callback ...>, (1, 2), {'z': 3})
>>> newobj, func, args, kwargs = _
>>> assert not f.alive
>>> assert newobj is obj
>>> assert func(*args, **kwargs) == 6
CALLBACK
Unless you set the atexit
attribute to
False
, a finalizer will be called when the program exits if it
is still alive. For instance
>>> obj = Object()
>>> weakref.finalize(obj, print, "obj dead or exiting")
<finalize object at ...; for 'Object' at ...>
>>> exit()
obj dead or exiting
Comparing finalizers with __del__()
methods¶
Suppose we want to create a class whose instances represent temporary directories. The directories should be deleted with their contents when the first of the following events occurs:
the object is garbage collected,
the object’s
remove()
method is called, orthe program exits.
We might try to implement the class using a __del__()
method as
follows:
class TempDir:
def __init__(self):
self.name = tempfile.mkdtemp()
def remove(self):
if self.name is not None:
shutil.rmtree(self.name)
self.name = None
@property
def removed(self):
return self.name is None
def __del__(self):
self.remove()
Starting with Python 3.4, __del__()
methods no longer prevent
reference cycles from being garbage collected, and module globals are
no longer forced to None
during interpreter shutdown.
So this code should work without any issues on CPython.
However, handling of __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
atexit.register()
, try: ... finally: ...
and with: ...
do not guarantee that cleanup occurs either.