Lib/_threading_local.py - platform/external/python/cpython2 - Gitiles

 """Thread-local objects.

 (Note that this module provides a Python version of the threading.local
  class.  Depending on the version of Python you're using, there may be a
  faster one available.  You should always import the `local` class from
  `threading`.)

 Thread-local objects support the management of thread-local data.
 If you have data that you want to be local to a thread, simply create
 a thread-local object and use its attributes:

   >>> mydata = local()
   >>> mydata.number = 42
   >>> mydata.number
   42

 You can also access the local-object's dictionary:

   >>> mydata.__dict__
   {'number': 42}
   >>> mydata.__dict__.setdefault('widgets', [])
   []
   >>> mydata.widgets
   []

 What's important about thread-local objects is that their data are
 local to a thread. If we access the data in a different thread:

   >>> log = []
   >>> def f():
   ...     items = mydata.__dict__.items()
   ...     items.sort()
   ...     log.append(items)
   ...     mydata.number = 11
   ...     log.append(mydata.number)

   >>> import threading
   >>> thread = threading.Thread(target=f)
   >>> thread.start()
   >>> thread.join()
   >>> log
   [[], 11]

 we get different data.  Furthermore, changes made in the other thread
 don't affect data seen in this thread:

   >>> mydata.number
   42

 Of course, values you get from a local object, including a __dict__
 attribute, are for whatever thread was current at the time the
 attribute was read.  For that reason, you generally don't want to save
 these values across threads, as they apply only to the thread they
 came from.

 You can create custom local objects by subclassing the local class:

   >>> class MyLocal(local):
   ...     number = 2
   ...     initialized = False
   ...     def __init__(self, **kw):
   ...         if self.initialized:
   ...             raise SystemError('__init__ called too many times')
   ...         self.initialized = True
   ...         self.__dict__.update(kw)
   ...     def squared(self):
   ...         return self.number ** 2

 This can be useful to support default values, methods and
 initialization.  Note that if you define an __init__ method, it will be
 called each time the local object is used in a separate thread.  This
 is necessary to initialize each thread's dictionary.

 Now if we create a local object:

   >>> mydata = MyLocal(color='red')

 Now we have a default number:

   >>> mydata.number
   2

 an initial color:

   >>> mydata.color
   'red'
   >>> del mydata.color

 And a method that operates on the data:

   >>> mydata.squared()
   4

 As before, we can access the data in a separate thread:

   >>> log = []
   >>> thread = threading.Thread(target=f)
   >>> thread.start()
   >>> thread.join()
   >>> log
   [[('color', 'red'), ('initialized', True)], 11]

 without affecting this thread's data:

   >>> mydata.number
   2
   >>> mydata.color
   Traceback (most recent call last):
   ...
   AttributeError: 'MyLocal' object has no attribute 'color'

 Note that subclasses can define slots, but they are not thread
 local. They are shared across threads:

   >>> class MyLocal(local):
   ...     __slots__ = 'number'

   >>> mydata = MyLocal()
   >>> mydata.number = 42
   >>> mydata.color = 'red'

 So, the separate thread:

   >>> thread = threading.Thread(target=f)
   >>> thread.start()
   >>> thread.join()

 affects what we see:

   >>> mydata.number
   11

 >>> del mydata
 """

 __all__ = ["local"]

 # We need to use objects from the threading module, but the threading
 # module may also want to use our `local` class, if support for locals
 # isn't compiled in to the `thread` module.  This creates potential problems
 # with circular imports.  For that reason, we don't import `threading`
 # until the bottom of this file (a hack sufficient to worm around the
 # potential problems).  Note that almost all platforms do have support for
 # locals in the `thread` module, and there is no circular import problem
 # then, so problems introduced by fiddling the order of imports here won't
 # manifest on most boxes.

 class _localbase(object):
     __slots__ = '_local__key', '_local__args', '_local__lock'

     def __new__(cls, *args, **kw):
         self = object.__new__(cls)
         key = '_local__key', 'thread.local.' + str(id(self))
         object.__setattr__(self, '_local__key', key)
         object.__setattr__(self, '_local__args', (args, kw))
         object.__setattr__(self, '_local__lock', RLock())

         if (args or kw) and (cls.__init__ is object.__init__):
             raise TypeError("Initialization arguments are not supported")

         # We need to create the thread dict in anticipation of
         # __init__ being called, to make sure we don't call it
         # again ourselves.
         dict = object.__getattribute__(self, '__dict__')
         current_thread().__dict__[key] = dict

         return self

 def _patch(self):
     key = object.__getattribute__(self, '_local__key')
     d = current_thread().__dict__.get(key)
     if d is None:
         d = {}
         current_thread().__dict__[key] = d
         object.__setattr__(self, '__dict__', d)

         # we have a new instance dict, so call out __init__ if we have
         # one
         cls = type(self)
         if cls.__init__ is not object.__init__:
             args, kw = object.__getattribute__(self, '_local__args')
             cls.__init__(self, *args, **kw)
     else:
         object.__setattr__(self, '__dict__', d)

 class local(_localbase):

     def __getattribute__(self, name):
         lock = object.__getattribute__(self, '_local__lock')
         lock.acquire()
         try:
             _patch(self)
             return object.__getattribute__(self, name)
         finally:
             lock.release()

     def __setattr__(self, name, value):
         if name == '__dict__':
             raise AttributeError(
                 "%r object attribute '__dict__' is read-only"
                 % self.__class__.__name__)
         lock = object.__getattribute__(self, '_local__lock')
         lock.acquire()
         try:
             _patch(self)
             return object.__setattr__(self, name, value)
         finally:
             lock.release()

     def __delattr__(self, name):
         if name == '__dict__':
             raise AttributeError(
                 "%r object attribute '__dict__' is read-only"
                 % self.__class__.__name__)
         lock = object.__getattribute__(self, '_local__lock')
         lock.acquire()
         try:
             _patch(self)
             return object.__delattr__(self, name)
         finally:
             lock.release()

     def __del__(self):
         import threading

         key = object.__getattribute__(self, '_local__key')

         try:
             # We use the non-locking API since we might already hold the lock
             # (__del__ can be called at any point by the cyclic GC).
             threads = threading._enumerate()
         except:
             # If enumerating the current threads fails, as it seems to do
             # during shutdown, we'll skip cleanup under the assumption
             # that there is nothing to clean up.
             return

         for thread in threads:
             try:
                 __dict__ = thread.__dict__
             except AttributeError:
                 # Thread is dying, rest in peace.
                 continue

             if key in __dict__:
                 try:
                     del __dict__[key]
                 except KeyError:
                     pass # didn't have anything in this thread

 from threading import current_thread, RLock
	"""Thread-local objects.

	(Note that this module provides a Python version of the threading.local
	class. Depending on the version of Python you're using, there may be a
	faster one available. You should always import the `local` class from
	`threading`.)

	Thread-local objects support the management of thread-local data.
	If you have data that you want to be local to a thread, simply create
	a thread-local object and use its attributes:

	>>> mydata = local()
	>>> mydata.number = 42
	>>> mydata.number
	42

	You can also access the local-object's dictionary:

	>>> mydata.__dict__
	{'number': 42}
	>>> mydata.__dict__.setdefault('widgets', [])
	[]
	>>> mydata.widgets
	[]

	What's important about thread-local objects is that their data are
	local to a thread. If we access the data in a different thread:

	>>> log = []
	>>> def f():
	... items = mydata.__dict__.items()
	... items.sort()
	... log.append(items)
	... mydata.number = 11
	... log.append(mydata.number)

	>>> import threading
	>>> thread = threading.Thread(target=f)
	>>> thread.start()
	>>> thread.join()
	>>> log
	[[], 11]

	we get different data. Furthermore, changes made in the other thread
	don't affect data seen in this thread:

	>>> mydata.number
	42

	Of course, values you get from a local object, including a __dict__
	attribute, are for whatever thread was current at the time the
	attribute was read. For that reason, you generally don't want to save
	these values across threads, as they apply only to the thread they
	came from.

	You can create custom local objects by subclassing the local class:

	>>> class MyLocal(local):
	... number = 2
	... initialized = False
	... def __init__(self, **kw):
	... if self.initialized:
	... raise SystemError('__init__ called too many times')
	... self.initialized = True
	... self.__dict__.update(kw)
	... def squared(self):
	... return self.number ** 2

	This can be useful to support default values, methods and
	initialization. Note that if you define an __init__ method, it will be
	called each time the local object is used in a separate thread. This
	is necessary to initialize each thread's dictionary.

	Now if we create a local object:

	>>> mydata = MyLocal(color='red')

	Now we have a default number:

	>>> mydata.number
	2

	an initial color:

	>>> mydata.color
	'red'
	>>> del mydata.color

	And a method that operates on the data:

	>>> mydata.squared()
	4

	As before, we can access the data in a separate thread:

	>>> log = []
	>>> thread = threading.Thread(target=f)
	>>> thread.start()
	>>> thread.join()
	>>> log
	[[('color', 'red'), ('initialized', True)], 11]

	without affecting this thread's data:

	>>> mydata.number
	2
	>>> mydata.color
	Traceback (most recent call last):
	...
	AttributeError: 'MyLocal' object has no attribute 'color'

	Note that subclasses can define slots, but they are not thread
	local. They are shared across threads:

	>>> class MyLocal(local):
	... __slots__ = 'number'

	>>> mydata = MyLocal()
	>>> mydata.number = 42
	>>> mydata.color = 'red'

	So, the separate thread:

	>>> thread = threading.Thread(target=f)
	>>> thread.start()
	>>> thread.join()

	affects what we see:

	>>> mydata.number
	11

	>>> del mydata
	"""

	__all__ = ["local"]

	# We need to use objects from the threading module, but the threading
	# module may also want to use our `local` class, if support for locals
	# isn't compiled in to the `thread` module. This creates potential problems
	# with circular imports. For that reason, we don't import `threading`
	# until the bottom of this file (a hack sufficient to worm around the
	# potential problems). Note that almost all platforms do have support for
	# locals in the `thread` module, and there is no circular import problem
	# then, so problems introduced by fiddling the order of imports here won't
	# manifest on most boxes.

	class _localbase(object):
	__slots__ = '_local__key', '_local__args', '_local__lock'

	def __new__(cls, args, *kw):
	self = object.__new__(cls)
	key = '_local__key', 'thread.local.' + str(id(self))
	object.__setattr__(self, '_local__key', key)
	object.__setattr__(self, '_local__args', (args, kw))
	object.__setattr__(self, '_local__lock', RLock())

	if (args or kw) and (cls.__init__ is object.__init__):
	raise TypeError("Initialization arguments are not supported")

	# We need to create the thread dict in anticipation of
	# __init__ being called, to make sure we don't call it
	# again ourselves.
	dict = object.__getattribute__(self, '__dict__')
	current_thread().__dict__[key] = dict

	return self

	def _patch(self):
	key = object.__getattribute__(self, '_local__key')
	d = current_thread().__dict__.get(key)
	if d is None:
	d = {}
	current_thread().__dict__[key] = d
	object.__setattr__(self, '__dict__', d)

	# we have a new instance dict, so call out __init__ if we have
	# one
	cls = type(self)
	if cls.__init__ is not object.__init__:
	args, kw = object.__getattribute__(self, '_local__args')
	cls.__init__(self, args, *kw)
	else:
	object.__setattr__(self, '__dict__', d)

	class local(_localbase):

	def __getattribute__(self, name):
	lock = object.__getattribute__(self, '_local__lock')
	lock.acquire()
	try:
	_patch(self)
	return object.__getattribute__(self, name)
	finally:
	lock.release()

	def __setattr__(self, name, value):
	if name == '__dict__':
	raise AttributeError(
	"%r object attribute '__dict__' is read-only"
	% self.__class__.__name__)
	lock = object.__getattribute__(self, '_local__lock')
	lock.acquire()
	try:
	_patch(self)
	return object.__setattr__(self, name, value)
	finally:
	lock.release()

	def __delattr__(self, name):
	if name == '__dict__':
	raise AttributeError(
	"%r object attribute '__dict__' is read-only"
	% self.__class__.__name__)
	lock = object.__getattribute__(self, '_local__lock')
	lock.acquire()
	try:
	_patch(self)
	return object.__delattr__(self, name)
	finally:
	lock.release()

	def __del__(self):
	import threading

	key = object.__getattribute__(self, '_local__key')

	try:
	# We use the non-locking API since we might already hold the lock
	# (__del__ can be called at any point by the cyclic GC).
	threads = threading._enumerate()
	except:
	# If enumerating the current threads fails, as it seems to do
	# during shutdown, we'll skip cleanup under the assumption
	# that there is nothing to clean up.
	return

	for thread in threads:
	try:
	__dict__ = thread.__dict__
	except AttributeError:
	# Thread is dying, rest in peace.
	continue

	if key in __dict__:
	try:
	del __dict__[key]
	except KeyError:
	pass # didn't have anything in this thread

	from threading import current_thread, RLock