pym/_emerge/AsynchronousLock.py - mirrors/cros/chromiumos/third_party/portage_tool - Git at Google

 # Copyright 2010-2013 Gentoo Foundation
 # Distributed under the terms of the GNU General Public License v2

 import dummy_threading
 import fcntl
 import errno
 import logging
 import sys

 try:
 	import threading
 except ImportError:
 	threading = dummy_threading

 import portage
 from portage import os
 from portage.exception import TryAgain
 from portage.localization import _
 from portage.locks import lockfile, unlockfile
 from portage.util import writemsg_level
 from _emerge.AbstractPollTask import AbstractPollTask
 from _emerge.AsynchronousTask import AsynchronousTask
 from _emerge.SpawnProcess import SpawnProcess

 class AsynchronousLock(AsynchronousTask):
 	"""
 	This uses the portage.locks module to acquire a lock asynchronously,
 	using either a thread (if available) or a subprocess.

 	The default behavior is to use a process instead of a thread, since
 	there is currently no way to interrupt a thread that is waiting for
 	a lock (notably, SIGINT doesn't work because python delivers all
 	signals to the main thread).
 	"""

 	__slots__ = ('path', 'scheduler',) + \
 		('_imp', '_force_async', '_force_dummy', '_force_process', \
 		'_force_thread')

 	_use_process_by_default = True

 	def _start(self):

 		if not self._force_async:
 			try:
 				self._imp = lockfile(self.path,
 					wantnewlockfile=True, flags=os.O_NONBLOCK)
 			except TryAgain:
 				pass
 			else:
 				self.returncode = os.EX_OK
 				self._async_wait()
 				return

 		if self._force_process or \
 			(not self._force_thread and \
 			(self._use_process_by_default or threading is dummy_threading)):
 			self._imp = _LockProcess(path=self.path, scheduler=self.scheduler)
 		else:
 			self._imp = _LockThread(path=self.path,
 				scheduler=self.scheduler,
 				_force_dummy=self._force_dummy)

 		self._imp.addExitListener(self._imp_exit)
 		self._imp.start()

 	def _imp_exit(self, imp):
 		# call exit listeners
 		self.wait()

 	def _cancel(self):
 		if isinstance(self._imp, AsynchronousTask):
 			self._imp.cancel()

 	def _poll(self):
 		if isinstance(self._imp, AsynchronousTask):
 			self._imp.poll()
 		return self.returncode

 	def _wait(self):
 		if self.returncode is not None:
 			return self.returncode
 		self.returncode = self._imp.wait()
 		return self.returncode

 	def unlock(self):
 		if self._imp is None:
 			raise AssertionError('not locked')
 		if isinstance(self._imp, (_LockProcess, _LockThread)):
 			self._imp.unlock()
 		else:
 			unlockfile(self._imp)
 		self._imp = None

 class _LockThread(AbstractPollTask):
 	"""
 	This uses the portage.locks module to acquire a lock asynchronously,
 	using a background thread. After the lock is acquired, the thread
 	writes to a pipe in order to notify a poll loop running in the main
 	thread.

 	If the threading module is unavailable then the dummy_threading
 	module will be used, and the lock will be acquired synchronously
 	(before the start() method returns).
 	"""

 	__slots__ = ('path',) + \
 		('_force_dummy', '_lock_obj', '_thread',)

 	def _start(self):
 		self._registered = True
 		threading_mod = threading
 		if self._force_dummy:
 			threading_mod = dummy_threading
 		self._thread = threading_mod.Thread(target=self._run_lock)
 		self._thread.daemon = True
 		self._thread.start()

 	def _run_lock(self):
 		self._lock_obj = lockfile(self.path, wantnewlockfile=True)
 		# Thread-safe callback to EventLoop
 		self.scheduler.idle_add(self._run_lock_cb)

 	def _run_lock_cb(self):
 		self._unregister()
 		self.returncode = os.EX_OK
 		self.wait()
 		return False

 	def _cancel(self):
 		# There's currently no way to force thread termination.
 		pass

 	def unlock(self):
 		if self._lock_obj is None:
 			raise AssertionError('not locked')
 		if self.returncode is None:
 			raise AssertionError('lock not acquired yet')
 		unlockfile(self._lock_obj)
 		self._lock_obj = None

 	def _unregister(self):
 		self._registered = False

 		if self._thread is not None:
 			self._thread.join()
 			self._thread = None

 class _LockProcess(AbstractPollTask):
 	"""
 	This uses the portage.locks module to acquire a lock asynchronously,
 	using a subprocess. After the lock is acquired, the process
 	writes to a pipe in order to notify a poll loop running in the main
 	process. The unlock() method notifies the subprocess to release the
 	lock and exit.
 	"""

 	__slots__ = ('path',) + \
 		('_acquired', '_kill_test', '_proc', '_files', '_reg_id', '_unlocked')

 	def _start(self):
 		in_pr, in_pw = os.pipe()
 		out_pr, out_pw = os.pipe()
 		self._files = {}
 		self._files['pipe_in'] = in_pr
 		self._files['pipe_out'] = out_pw

 		fcntl.fcntl(in_pr, fcntl.F_SETFL,
 			fcntl.fcntl(in_pr, fcntl.F_GETFL) | os.O_NONBLOCK)

 		# FD_CLOEXEC is enabled by default in Python >=3.4.
 		if sys.hexversion < 0x3040000:
 			try:
 				fcntl.FD_CLOEXEC
 			except AttributeError:
 				pass
 			else:
 				fcntl.fcntl(in_pr, fcntl.F_SETFD,
 					fcntl.fcntl(in_pr, fcntl.F_GETFD) | fcntl.FD_CLOEXEC)

 		self._reg_id = self.scheduler.io_add_watch(in_pr,
 			self.scheduler.IO_IN, self._output_handler)
 		self._registered = True
 		self._proc = SpawnProcess(
 			args=[portage._python_interpreter,
 				os.path.join(portage._bin_path, 'lock-helper.py'), self.path],
 				env=dict(os.environ, PORTAGE_PYM_PATH=portage._pym_path),
 				fd_pipes={0:out_pr, 1:in_pw, 2:sys.__stderr__.fileno()},
 				scheduler=self.scheduler)
 		self._proc.addExitListener(self._proc_exit)
 		self._proc.start()
 		os.close(out_pr)
 		os.close(in_pw)

 	def _proc_exit(self, proc):

 		if self._files is not None:
 			# Close pipe_out if it's still open, since it's useless
 			# after the process has exited. This helps to avoid
 			# "ResourceWarning: unclosed file" since Python 3.2.
 			try:
 				pipe_out = self._files.pop('pipe_out')
 			except KeyError:
 				pass
 			else:
 				os.close(pipe_out)

 		if proc.returncode != os.EX_OK:
 			# Typically, this will happen due to the
 			# process being killed by a signal.

 			if not self._acquired:
 				# If the lock hasn't been aquired yet, the
 				# caller can check the returncode and handle
 				# this failure appropriately.
 				if not (self.cancelled or self._kill_test):
 					writemsg_level("_LockProcess: %s\n" % \
 						_("failed to acquire lock on '%s'") % (self.path,),
 						level=logging.ERROR, noiselevel=-1)
 				self._unregister()
 				self.returncode = proc.returncode
 				self.wait()
 				return

 			if not self.cancelled and \
 				not self._unlocked:
 				# We don't want lost locks going unnoticed, so it's
 				# only safe to ignore if either the cancel() or
 				# unlock() methods have been previously called.
 				raise AssertionError("lock process failed with returncode %s" \
 					% (proc.returncode,))

 	def _cancel(self):
 		if self._proc is not None:
 			self._proc.cancel()

 	def _poll(self):
 		if self._proc is not None:
 			self._proc.poll()
 		return self.returncode

 	def _output_handler(self, f, event):
 		buf = None
 		if event & self.scheduler.IO_IN:
 			try:
 				buf = os.read(self._files['pipe_in'], self._bufsize)
 			except OSError as e:
 				if e.errno not in (errno.EAGAIN,):
 					raise
 		if buf:
 			self._acquired = True
 			self._unregister()
 			self.returncode = os.EX_OK
 			self.wait()

 		return True

 	def _unregister(self):
 		self._registered = False

 		if self._reg_id is not None:
 			self.scheduler.source_remove(self._reg_id)
 			self._reg_id = None

 		if self._files is not None:
 			try:
 				pipe_in = self._files.pop('pipe_in')
 			except KeyError:
 				pass
 			else:
 				os.close(pipe_in)

 	def unlock(self):
 		if self._proc is None:
 			raise AssertionError('not locked')
 		if self.returncode is None:
 			raise AssertionError('lock not acquired yet')
 		if self.returncode != os.EX_OK:
 			raise AssertionError("lock process failed with returncode %s" \
 				% (self.returncode,))
 		self._unlocked = True
 		os.write(self._files['pipe_out'], b'\0')
 		os.close(self._files['pipe_out'])
 		self._files = None
 		self._proc.wait()
 		self._proc = None
	# Copyright 2010-2013 Gentoo Foundation
	# Distributed under the terms of the GNU General Public License v2

	import dummy_threading
	import fcntl
	import errno
	import logging
	import sys

	try:
	import threading
	except ImportError:
	threading = dummy_threading

	import portage
	from portage import os
	from portage.exception import TryAgain
	from portage.localization import _
	from portage.locks import lockfile, unlockfile
	from portage.util import writemsg_level
	from _emerge.AbstractPollTask import AbstractPollTask
	from _emerge.AsynchronousTask import AsynchronousTask
	from _emerge.SpawnProcess import SpawnProcess

	class AsynchronousLock(AsynchronousTask):
	"""
	This uses the portage.locks module to acquire a lock asynchronously,
	using either a thread (if available) or a subprocess.

	The default behavior is to use a process instead of a thread, since
	there is currently no way to interrupt a thread that is waiting for
	a lock (notably, SIGINT doesn't work because python delivers all
	signals to the main thread).
	"""

	__slots__ = ('path', 'scheduler',) + \
	('_imp', '_force_async', '_force_dummy', '_force_process', \
	'_force_thread')

	_use_process_by_default = True

	def _start(self):

	if not self._force_async:
	try:
	self._imp = lockfile(self.path,
	wantnewlockfile=True, flags=os.O_NONBLOCK)
	except TryAgain:
	pass
	else:
	self.returncode = os.EX_OK
	self._async_wait()
	return

	if self._force_process or \
	(not self._force_thread and \
	(self._use_process_by_default or threading is dummy_threading)):
	self._imp = _LockProcess(path=self.path, scheduler=self.scheduler)
	else:
	self._imp = _LockThread(path=self.path,
	scheduler=self.scheduler,
	_force_dummy=self._force_dummy)

	self._imp.addExitListener(self._imp_exit)
	self._imp.start()

	def _imp_exit(self, imp):
	# call exit listeners
	self.wait()

	def _cancel(self):
	if isinstance(self._imp, AsynchronousTask):
	self._imp.cancel()

	def _poll(self):
	if isinstance(self._imp, AsynchronousTask):
	self._imp.poll()
	return self.returncode

	def _wait(self):
	if self.returncode is not None:
	return self.returncode
	self.returncode = self._imp.wait()
	return self.returncode

	def unlock(self):
	if self._imp is None:
	raise AssertionError('not locked')
	if isinstance(self._imp, (_LockProcess, _LockThread)):
	self._imp.unlock()
	else:
	unlockfile(self._imp)
	self._imp = None

	class _LockThread(AbstractPollTask):
	"""
	This uses the portage.locks module to acquire a lock asynchronously,
	using a background thread. After the lock is acquired, the thread
	writes to a pipe in order to notify a poll loop running in the main
	thread.

	If the threading module is unavailable then the dummy_threading
	module will be used, and the lock will be acquired synchronously
	(before the start() method returns).
	"""

	__slots__ = ('path',) + \
	('_force_dummy', '_lock_obj', '_thread',)

	def _start(self):
	self._registered = True
	threading_mod = threading
	if self._force_dummy:
	threading_mod = dummy_threading
	self._thread = threading_mod.Thread(target=self._run_lock)
	self._thread.daemon = True
	self._thread.start()

	def _run_lock(self):
	self._lock_obj = lockfile(self.path, wantnewlockfile=True)
	# Thread-safe callback to EventLoop
	self.scheduler.idle_add(self._run_lock_cb)

	def _run_lock_cb(self):
	self._unregister()
	self.returncode = os.EX_OK
	self.wait()
	return False

	def _cancel(self):
	# There's currently no way to force thread termination.
	pass

	def unlock(self):
	if self._lock_obj is None:
	raise AssertionError('not locked')
	if self.returncode is None:
	raise AssertionError('lock not acquired yet')
	unlockfile(self._lock_obj)
	self._lock_obj = None

	def _unregister(self):
	self._registered = False

	if self._thread is not None:
	self._thread.join()
	self._thread = None

	class _LockProcess(AbstractPollTask):
	"""
	This uses the portage.locks module to acquire a lock asynchronously,
	using a subprocess. After the lock is acquired, the process
	writes to a pipe in order to notify a poll loop running in the main
	process. The unlock() method notifies the subprocess to release the
	lock and exit.
	"""

	__slots__ = ('path',) + \
	('_acquired', '_kill_test', '_proc', '_files', '_reg_id', '_unlocked')

	def _start(self):
	in_pr, in_pw = os.pipe()
	out_pr, out_pw = os.pipe()
	self._files = {}
	self._files['pipe_in'] = in_pr
	self._files['pipe_out'] = out_pw

	fcntl.fcntl(in_pr, fcntl.F_SETFL,
	fcntl.fcntl(in_pr, fcntl.F_GETFL) \| os.O_NONBLOCK)

	# FD_CLOEXEC is enabled by default in Python >=3.4.
	if sys.hexversion < 0x3040000:
	try:
	fcntl.FD_CLOEXEC
	except AttributeError:
	pass
	else:
	fcntl.fcntl(in_pr, fcntl.F_SETFD,
	fcntl.fcntl(in_pr, fcntl.F_GETFD) \| fcntl.FD_CLOEXEC)

	self._reg_id = self.scheduler.io_add_watch(in_pr,
	self.scheduler.IO_IN, self._output_handler)
	self._registered = True
	self._proc = SpawnProcess(
	args=[portage._python_interpreter,
	os.path.join(portage._bin_path, 'lock-helper.py'), self.path],
	env=dict(os.environ, PORTAGE_PYM_PATH=portage._pym_path),
	fd_pipes={0:out_pr, 1:in_pw, 2:sys.__stderr__.fileno()},
	scheduler=self.scheduler)
	self._proc.addExitListener(self._proc_exit)
	self._proc.start()
	os.close(out_pr)
	os.close(in_pw)

	def _proc_exit(self, proc):

	if self._files is not None:
	# Close pipe_out if it's still open, since it's useless
	# after the process has exited. This helps to avoid
	# "ResourceWarning: unclosed file" since Python 3.2.
	try:
	pipe_out = self._files.pop('pipe_out')
	except KeyError:
	pass
	else:
	os.close(pipe_out)

	if proc.returncode != os.EX_OK:
	# Typically, this will happen due to the
	# process being killed by a signal.

	if not self._acquired:
	# If the lock hasn't been aquired yet, the
	# caller can check the returncode and handle
	# this failure appropriately.
	if not (self.cancelled or self._kill_test):
	writemsg_level("_LockProcess: %s\n" % \
	_("failed to acquire lock on '%s'") % (self.path,),
	level=logging.ERROR, noiselevel=-1)
	self._unregister()
	self.returncode = proc.returncode
	self.wait()
	return

	if not self.cancelled and \
	not self._unlocked:
	# We don't want lost locks going unnoticed, so it's
	# only safe to ignore if either the cancel() or
	# unlock() methods have been previously called.
	raise AssertionError("lock process failed with returncode %s" \
	% (proc.returncode,))

	def _cancel(self):
	if self._proc is not None:
	self._proc.cancel()

	def _poll(self):
	if self._proc is not None:
	self._proc.poll()
	return self.returncode

	def _output_handler(self, f, event):
	buf = None
	if event & self.scheduler.IO_IN:
	try:
	buf = os.read(self._files['pipe_in'], self._bufsize)
	except OSError as e:
	if e.errno not in (errno.EAGAIN,):
	raise
	if buf:
	self._acquired = True
	self._unregister()
	self.returncode = os.EX_OK
	self.wait()

	return True

	def _unregister(self):
	self._registered = False

	if self._reg_id is not None:
	self.scheduler.source_remove(self._reg_id)
	self._reg_id = None

	if self._files is not None:
	try:
	pipe_in = self._files.pop('pipe_in')
	except KeyError:
	pass
	else:
	os.close(pipe_in)

	def unlock(self):
	if self._proc is None:
	raise AssertionError('not locked')
	if self.returncode is None:
	raise AssertionError('lock not acquired yet')
	if self.returncode != os.EX_OK:
	raise AssertionError("lock process failed with returncode %s" \
	% (self.returncode,))
	self._unlocked = True
	os.write(self._files['pipe_out'], b'\0')
	os.close(self._files['pipe_out'])
	self._files = None
	self._proc.wait()
	self._proc = None