Lib/_weakrefset.py - platform/external/python/cpython3 - Gitiles

 # Access WeakSet through the weakref module.
 # This code is separated-out because it is needed
 # by abc.py to load everything else at startup.

 from _weakref import ref

 __all__ = ['WeakSet']

 class WeakSet:
     def __init__(self, data=None):
         self.data = set()
         def _remove(item, selfref=ref(self)):
             self = selfref()
             if self is not None:
                 self.data.discard(item)
         self._remove = _remove
         if data is not None:
             self.update(data)

     def __iter__(self):
         for itemref in self.data:
             item = itemref()
             if item is not None:
                 yield item

     def __len__(self):
         return sum(x() is not None for x in self.data)

     def __contains__(self, item):
         return ref(item) in self.data

     def __reduce__(self):
         return (self.__class__, (list(self),),
                 getattr(self, '__dict__', None))

     def add(self, item):
         self.data.add(ref(item, self._remove))

     def clear(self):
         self.data.clear()

     def copy(self):
         return self.__class__(self)

     def pop(self):
         while True:
             try:
                 itemref = self.data.pop()
             except KeyError:
                 raise KeyError('pop from empty WeakSet')
             item = itemref()
             if item is not None:
                 return item

     def remove(self, item):
         self.data.remove(ref(item))

     def discard(self, item):
         self.data.discard(ref(item))

     def update(self, other):
         if isinstance(other, self.__class__):
             self.data.update(other.data)
         else:
             for element in other:
                 self.add(element)
     def __ior__(self, other):
         self.update(other)
         return self

     # Helper functions for simple delegating methods.
     def _apply(self, other, method):
         if not isinstance(other, self.__class__):
             other = self.__class__(other)
         newdata = method(other.data)
         newset = self.__class__()
         newset.data = newdata
         return newset

     def difference(self, other):
         return self._apply(other, self.data.difference)
     __sub__ = difference

     def difference_update(self, other):
         if self is other:
             self.data.clear()
         else:
             self.data.difference_update(ref(item) for item in other)
     def __isub__(self, other):
         if self is other:
             self.data.clear()
         else:
             self.data.difference_update(ref(item) for item in other)
         return self

     def intersection(self, other):
         return self._apply(other, self.data.intersection)
     __and__ = intersection

     def intersection_update(self, other):
         self.data.intersection_update(ref(item) for item in other)
     def __iand__(self, other):
         self.data.intersection_update(ref(item) for item in other)
         return self

     def issubset(self, other):
         return self.data.issubset(ref(item) for item in other)
     __lt__ = issubset

     def __le__(self, other):
         return self.data <= set(ref(item) for item in other)

     def issuperset(self, other):
         return self.data.issuperset(ref(item) for item in other)
     __gt__ = issuperset

     def __ge__(self, other):
         return self.data >= set(ref(item) for item in other)

     def __eq__(self, other):
         if not isinstance(other, self.__class__):
             return NotImplemented
         return self.data == set(ref(item) for item in other)

     def symmetric_difference(self, other):
         return self._apply(other, self.data.symmetric_difference)
     __xor__ = symmetric_difference

     def symmetric_difference_update(self, other):
         if self is other:
             self.data.clear()
         else:
             self.data.symmetric_difference_update(ref(item) for item in other)
     def __ixor__(self, other):
         if self is other:
             self.data.clear()
         else:
             self.data.symmetric_difference_update(ref(item) for item in other)
         return self

     def union(self, other):
         return self._apply(other, self.data.union)
     __or__ = union

     def isdisjoint(self, other):
         return len(self.intersection(other)) == 0
	# Access WeakSet through the weakref module.
	# This code is separated-out because it is needed
	# by abc.py to load everything else at startup.

	from _weakref import ref

	__all__ = ['WeakSet']

	class WeakSet:
	def __init__(self, data=None):
	self.data = set()
	def _remove(item, selfref=ref(self)):
	self = selfref()
	if self is not None:
	self.data.discard(item)
	self._remove = _remove
	if data is not None:
	self.update(data)

	def __iter__(self):
	for itemref in self.data:
	item = itemref()
	if item is not None:
	yield item

	def __len__(self):
	return sum(x() is not None for x in self.data)

	def __contains__(self, item):
	return ref(item) in self.data

	def __reduce__(self):
	return (self.__class__, (list(self),),
	getattr(self, '__dict__', None))

	def add(self, item):
	self.data.add(ref(item, self._remove))

	def clear(self):
	self.data.clear()

	def copy(self):
	return self.__class__(self)

	def pop(self):
	while True:
	try:
	itemref = self.data.pop()
	except KeyError:
	raise KeyError('pop from empty WeakSet')
	item = itemref()
	if item is not None:
	return item

	def remove(self, item):
	self.data.remove(ref(item))

	def discard(self, item):
	self.data.discard(ref(item))

	def update(self, other):
	if isinstance(other, self.__class__):
	self.data.update(other.data)
	else:
	for element in other:
	self.add(element)
	def __ior__(self, other):
	self.update(other)
	return self

	# Helper functions for simple delegating methods.
	def _apply(self, other, method):
	if not isinstance(other, self.__class__):
	other = self.__class__(other)
	newdata = method(other.data)
	newset = self.__class__()
	newset.data = newdata
	return newset

	def difference(self, other):
	return self._apply(other, self.data.difference)
	__sub__ = difference

	def difference_update(self, other):
	if self is other:
	self.data.clear()
	else:
	self.data.difference_update(ref(item) for item in other)
	def __isub__(self, other):
	if self is other:
	self.data.clear()
	else:
	self.data.difference_update(ref(item) for item in other)
	return self

	def intersection(self, other):
	return self._apply(other, self.data.intersection)
	__and__ = intersection

	def intersection_update(self, other):
	self.data.intersection_update(ref(item) for item in other)
	def __iand__(self, other):
	self.data.intersection_update(ref(item) for item in other)
	return self

	def issubset(self, other):
	return self.data.issubset(ref(item) for item in other)
	__lt__ = issubset

	def __le__(self, other):
	return self.data <= set(ref(item) for item in other)

	def issuperset(self, other):
	return self.data.issuperset(ref(item) for item in other)
	__gt__ = issuperset

	def __ge__(self, other):
	return self.data >= set(ref(item) for item in other)

	def __eq__(self, other):
	if not isinstance(other, self.__class__):
	return NotImplemented
	return self.data == set(ref(item) for item in other)

	def symmetric_difference(self, other):
	return self._apply(other, self.data.symmetric_difference)
	__xor__ = symmetric_difference

	def symmetric_difference_update(self, other):
	if self is other:
	self.data.clear()
	else:
	self.data.symmetric_difference_update(ref(item) for item in other)
	def __ixor__(self, other):
	if self is other:
	self.data.clear()
	else:
	self.data.symmetric_difference_update(ref(item) for item in other)
	return self

	def union(self, other):
	return self._apply(other, self.data.union)
	__or__ = union

	def isdisjoint(self, other):
	return len(self.intersection(other)) == 0