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

 # A multi-producer, multi-consumer queue.

 Empty = 'Queue.Empty' # Exception raised by get_nowait()

 class Queue:

 	# Initialize a queue object with a given maximum size
 	# (If maxsize is <= 0, the maximum size is infinite)
 	def __init__(self, maxsize):
 		import thread
 		self._init(maxsize)
 		self.mutex = thread.allocate_lock()
 		self.esema = thread.allocate_lock()
 		self.esema.acquire_lock()
 		self.fsema = thread.allocate_lock()

 	# Get an approximation of the queue size (not reliable!)
 	def qsize(self):
 		self.mutex.acquire_lock()
 		n = self._qsize()
 		self.mutex.release_lock()
 		return n

 	# Check if the queue is empty (not reliable!)
 	def empty(self):
 		self.mutex.acquire_lock()
 		n = self._empty()
 		self.mutex.release_lock()
 		return n

 	# Check if the queue is full (not reliable!)
 	def full(self):
 		self.mutex.acquire_lock()
 		n = self._full()
 		self.mutex.release_lock()
 		return n

 	# Put a new item into the queue
 	def put(self, item):
 		self.fsema.acquire_lock()
 		self.mutex.acquire_lock()
 		was_empty = self._empty()
 		self._put(item)
 		if was_empty:
 			self.esema.release_lock()
 		if not self._full():
 			self.fsema.release_lock()
 		self.mutex.release_lock()

 	# Get an item from the queue,
 	# blocking if necessary until one is available
 	def get(self):
 		self.esema.acquire_lock()
 		self.mutex.acquire_lock()
 		was_full = self._full()
 		item = self._get()
 		if was_full:
 			self.fsema.release_lock()
 		if not self._empty():
 			self.esema.release_lock()
 		self.mutex.release_lock()
 		return item

 	# Get an item from the queue if one is immediately available,
 	# raise Empty if the queue is empty or temporarily unavailable
 	def get_nowait(self):
 		locked = self.esema.acquire_lock(0)
 		self.mutex.acquire_lock()
 		if self._empty():
 			# The queue is empyt -- we can't have esema
 			self.mutex.release_lock()
 			raise Empty
 		if not locked:
 			locked = self.esema.acquire_lock(0)
 			if not locked:
 				# Somebody else has esema
 				# but we have mutex --
 				# go out of their way
 				self.mutex.release_lock()
 				raise Empty
 		was_full = self._full()
 		item = self._get()
 		if was_full:
 			self.fsema.release_lock()
 		if not self._empty():
 			self.esema.release_lock()
 		self.mutex.release_lock()
 		return item

 	# XXX Need to define put_nowait() as well.


 	# Override these methods to implement other queue organizations
 	# (e.g. stack or priority queue).
 	# These will only be called with appropriate locks held

 	# Initialize the queue representation
 	def _init(self, maxsize):
 		self.maxsize = maxsize
 		self.queue = []

 	def _qsize(self):
 		return len(self.queue)

 	# Check wheter the queue is empty
 	def _empty(self):
 		return not self.queue

 	# Check whether the queue is full
 	def _full(self):
 		return self.maxsize > 0 and len(self.queue) == self.maxsize

 	# Put a new item in the queue
 	def _put(self, item):
 		self.queue.append(item)

 	# Get an item from the queue
 	def _get(self):
 		item = self.queue[0]
 		del self.queue[0]
 		return item
	# A multi-producer, multi-consumer queue.

	Empty = 'Queue.Empty' # Exception raised by get_nowait()

	class Queue:

	# Initialize a queue object with a given maximum size
	# (If maxsize is <= 0, the maximum size is infinite)
	def __init__(self, maxsize):
	import thread
	self._init(maxsize)
	self.mutex = thread.allocate_lock()
	self.esema = thread.allocate_lock()
	self.esema.acquire_lock()
	self.fsema = thread.allocate_lock()

	# Get an approximation of the queue size (not reliable!)
	def qsize(self):
	self.mutex.acquire_lock()
	n = self._qsize()
	self.mutex.release_lock()
	return n

	# Check if the queue is empty (not reliable!)
	def empty(self):
	self.mutex.acquire_lock()
	n = self._empty()
	self.mutex.release_lock()
	return n

	# Check if the queue is full (not reliable!)
	def full(self):
	self.mutex.acquire_lock()
	n = self._full()
	self.mutex.release_lock()
	return n

	# Put a new item into the queue
	def put(self, item):
	self.fsema.acquire_lock()
	self.mutex.acquire_lock()
	was_empty = self._empty()
	self._put(item)
	if was_empty:
	self.esema.release_lock()
	if not self._full():
	self.fsema.release_lock()
	self.mutex.release_lock()

	# Get an item from the queue,
	# blocking if necessary until one is available
	def get(self):
	self.esema.acquire_lock()
	self.mutex.acquire_lock()
	was_full = self._full()
	item = self._get()
	if was_full:
	self.fsema.release_lock()
	if not self._empty():
	self.esema.release_lock()
	self.mutex.release_lock()
	return item

	# Get an item from the queue if one is immediately available,
	# raise Empty if the queue is empty or temporarily unavailable
	def get_nowait(self):
	locked = self.esema.acquire_lock(0)
	self.mutex.acquire_lock()
	if self._empty():
	# The queue is empyt -- we can't have esema
	self.mutex.release_lock()
	raise Empty
	if not locked:
	locked = self.esema.acquire_lock(0)
	if not locked:
	# Somebody else has esema
	# but we have mutex --
	# go out of their way
	self.mutex.release_lock()
	raise Empty
	was_full = self._full()
	item = self._get()
	if was_full:
	self.fsema.release_lock()
	if not self._empty():
	self.esema.release_lock()
	self.mutex.release_lock()
	return item

	# XXX Need to define put_nowait() as well.


	# Override these methods to implement other queue organizations
	# (e.g. stack or priority queue).
	# These will only be called with appropriate locks held

	# Initialize the queue representation
	def _init(self, maxsize):
	self.maxsize = maxsize
	self.queue = []

	def _qsize(self):
	return len(self.queue)

	# Check wheter the queue is empty
	def _empty(self):
	return not self.queue

	# Check whether the queue is full
	def _full(self):
	return self.maxsize > 0 and len(self.queue) == self.maxsize

	# Put a new item in the queue
	def _put(self, item):
	self.queue.append(item)

	# Get an item from the queue
	def _get(self):
	item = self.queue[0]
	del self.queue[0]
	return item