upstream/mercurial-mirror Files · mercurial/thirdparty/concurrent/futures/thread.py

repository: define and use revision flag constants...

repository: define and use revision flag constants Revlogs have a per-revision 2 byte field holding integer flags that define how revision data should be interpreted. For historical reasons, these integer values are sent verbatim on the wire protocol as part of changegroup data. From a semantic standpoint, the flags that go out over the wire are different from the flags stored internally by revlogs. Failure to establish this semantic distinction creates unwanted strong coupling between revlog's internals and the wire protocol. This commit establishes new constants on the repository module that define the revision flags used by the wire protocol (and by some internal storage APIs, sadly). The changegroups internals documentation has been updated to document them explicitly. Various references throughout the repo now use the repository constants instead of the revlog constants. This is done to make it clear that we're operating on generic revision data and this isn't tied to revlogs. Differential Revision: https://phab.mercurial-scm.org/D4860

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      # Copyright 2009 Brian Quinlan. All Rights Reserved.

      # Licensed to PSF under a Contributor Agreement.

      """Implements ThreadPoolExecutor."""

      from __future__ import absolute_import

      import atexit

      from . import _base

      import itertools

      import Queue as queue

      import threading

      import weakref

      import sys

      try:

          from multiprocessing import cpu_count

      except ImportError:

          # some platforms don't have multiprocessing

          def cpu_count():

              return None

      __author__ = 'Brian Quinlan (brian@sweetapp.com)'

      # Workers are created as daemon threads. This is done to allow the interpreter

      # to exit when there are still idle threads in a ThreadPoolExecutor's thread

      # pool (i.e. shutdown() was not called). However, allowing workers to die with

      # the interpreter has two undesirable properties:

      #   - The workers would still be running during interpretor shutdown,

      #     meaning that they would fail in unpredictable ways.

      #   - The workers could be killed while evaluating a work item, which could

      #     be bad if the callable being evaluated has external side-effects e.g.

      #     writing to a file.

      #

      # To work around this problem, an exit handler is installed which tells the

      # workers to exit when their work queues are empty and then waits until the

      # threads finish.

      _threads_queues = weakref.WeakKeyDictionary()

      _shutdown = False

      def _python_exit():

          global _shutdown

          _shutdown = True

          items = list(_threads_queues.items()) if _threads_queues else ()

          for t, q in items:

              q.put(None)

          for t, q in items:

              t.join(sys.maxint)

      atexit.register(_python_exit)

      class _WorkItem(object):

          def __init__(self, future, fn, args, kwargs):

              self.future = future

              self.fn = fn

              self.args = args

              self.kwargs = kwargs

          def run(self):

              if not self.future.set_running_or_notify_cancel():

                  return

              try:

                  result = self.fn(*self.args, **self.kwargs)

              except:

                  e, tb = sys.exc_info()[1:]

                  self.future.set_exception_info(e, tb)

              else:

                  self.future.set_result(result)

      def _worker(executor_reference, work_queue):

          try:

              while True:

                  work_item = work_queue.get(block=True)

                  if work_item is not None:

                      work_item.run()

                      # Delete references to object. See issue16284

                      del work_item

                      continue

                  executor = executor_reference()

                  # Exit if:

                  #   - The interpreter is shutting down OR

                  #   - The executor that owns the worker has been collected OR

                  #   - The executor that owns the worker has been shutdown.

                  if _shutdown or executor is None or executor._shutdown:

                      # Notice other workers

                      work_queue.put(None)

                      return

                  del executor

          except:

              _base.LOGGER.critical('Exception in worker', exc_info=True)

      class ThreadPoolExecutor(_base.Executor):

          # Used to assign unique thread names when thread_name_prefix is not supplied.

          _counter = itertools.count().next

          def __init__(self, max_workers=None, thread_name_prefix=''):

              """Initializes a new ThreadPoolExecutor instance.

              Args:

                  max_workers: The maximum number of threads that can be used to

                      execute the given calls.

                  thread_name_prefix: An optional name prefix to give our threads.

              """

              if max_workers is None:

                  # Use this number because ThreadPoolExecutor is often

                  # used to overlap I/O instead of CPU work.

                  max_workers = (cpu_count() or 1) * 5

              if max_workers <= 0:

                  raise ValueError("max_workers must be greater than 0")

              self._max_workers = max_workers

              self._work_queue = queue.Queue()

              self._threads = set()

              self._shutdown = False

              self._shutdown_lock = threading.Lock()

              self._thread_name_prefix = (thread_name_prefix or

                                          ("ThreadPoolExecutor-%d" % self._counter()))

          def submit(self, fn, *args, **kwargs):

              with self._shutdown_lock:

                  if self._shutdown:

                      raise RuntimeError('cannot schedule new futures after shutdown')

                  f = _base.Future()

                  w = _WorkItem(f, fn, args, kwargs)

                  self._work_queue.put(w)

                  self._adjust_thread_count()

                  return f

          submit.__doc__ = _base.Executor.submit.__doc__

          def _adjust_thread_count(self):

              # When the executor gets lost, the weakref callback will wake up

              # the worker threads.

              def weakref_cb(_, q=self._work_queue):

                  q.put(None)

              # TODO(bquinlan): Should avoid creating new threads if there are more

              # idle threads than items in the work queue.

              num_threads = len(self._threads)

              if num_threads < self._max_workers:

                  thread_name = '%s_%d' % (self._thread_name_prefix or self,

                                           num_threads)

                  t = threading.Thread(name=thread_name, target=_worker,

                                       args=(weakref.ref(self, weakref_cb),

                                             self._work_queue))

                  t.daemon = True

                  t.start()

                  self._threads.add(t)

                  _threads_queues[t] = self._work_queue

          def shutdown(self, wait=True):

              with self._shutdown_lock:

                  self._shutdown = True

                  self._work_queue.put(None)

              if wait:

                  for t in self._threads:

                      t.join(sys.maxint)

          shutdown.__doc__ = _base.Executor.shutdown.__doc__

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				# Copyright 2009 Brian Quinlan. All Rights Reserved.
				# Licensed to PSF under a Contributor Agreement.

				"""Implements ThreadPoolExecutor."""

				from __future__ import absolute_import

				import atexit
				from . import _base
				import itertools
				import Queue as queue
				import threading
				import weakref
				import sys

				try:
				from multiprocessing import cpu_count
				except ImportError:
				# some platforms don't have multiprocessing
				def cpu_count():
				return None

				__author__ = 'Brian Quinlan (brian@sweetapp.com)'

				# Workers are created as daemon threads. This is done to allow the interpreter
				# to exit when there are still idle threads in a ThreadPoolExecutor's thread
				# pool (i.e. shutdown() was not called). However, allowing workers to die with
				# the interpreter has two undesirable properties:
				# - The workers would still be running during interpretor shutdown,
				# meaning that they would fail in unpredictable ways.
				# - The workers could be killed while evaluating a work item, which could
				# be bad if the callable being evaluated has external side-effects e.g.
				# writing to a file.
				#
				# To work around this problem, an exit handler is installed which tells the
				# workers to exit when their work queues are empty and then waits until the
				# threads finish.

				_threads_queues = weakref.WeakKeyDictionary()
				_shutdown = False

				def _python_exit():
				global _shutdown
				_shutdown = True
				items = list(_threads_queues.items()) if _threads_queues else ()
				for t, q in items:
				q.put(None)
				for t, q in items:
				t.join(sys.maxint)

				atexit.register(_python_exit)

				class _WorkItem(object):
				def __init__(self, future, fn, args, kwargs):
				self.future = future
				self.fn = fn
				self.args = args
				self.kwargs = kwargs

				def run(self):
				if not self.future.set_running_or_notify_cancel():
				return

				try:
				result = self.fn(self.args, *self.kwargs)
				except:
				e, tb = sys.exc_info()[1:]
				self.future.set_exception_info(e, tb)
				else:
				self.future.set_result(result)

				def _worker(executor_reference, work_queue):
				try:
				while True:
				work_item = work_queue.get(block=True)
				if work_item is not None:
				work_item.run()
				# Delete references to object. See issue16284
				del work_item
				continue
				executor = executor_reference()
				# Exit if:
				# - The interpreter is shutting down OR
				# - The executor that owns the worker has been collected OR
				# - The executor that owns the worker has been shutdown.
				if _shutdown or executor is None or executor._shutdown:
				# Notice other workers
				work_queue.put(None)
				return
				del executor
				except:
				_base.LOGGER.critical('Exception in worker', exc_info=True)


				class ThreadPoolExecutor(_base.Executor):

				# Used to assign unique thread names when thread_name_prefix is not supplied.
				_counter = itertools.count().next

				def __init__(self, max_workers=None, thread_name_prefix=''):
				"""Initializes a new ThreadPoolExecutor instance.

				Args:
				max_workers: The maximum number of threads that can be used to
				execute the given calls.
				thread_name_prefix: An optional name prefix to give our threads.
				"""
				if max_workers is None:
				# Use this number because ThreadPoolExecutor is often
				# used to overlap I/O instead of CPU work.
				max_workers = (cpu_count() or 1) * 5
				if max_workers <= 0:
				raise ValueError("max_workers must be greater than 0")

				self._max_workers = max_workers
				self._work_queue = queue.Queue()
				self._threads = set()
				self._shutdown = False
				self._shutdown_lock = threading.Lock()
				self._thread_name_prefix = (thread_name_prefix or
				("ThreadPoolExecutor-%d" % self._counter()))

				def submit(self, fn, args, *kwargs):
				with self._shutdown_lock:
				if self._shutdown:
				raise RuntimeError('cannot schedule new futures after shutdown')

				f = _base.Future()
				w = _WorkItem(f, fn, args, kwargs)

				self._work_queue.put(w)
				self._adjust_thread_count()
				return f
				submit.__doc__ = _base.Executor.submit.__doc__

				def _adjust_thread_count(self):
				# When the executor gets lost, the weakref callback will wake up
				# the worker threads.
				def weakref_cb(_, q=self._work_queue):
				q.put(None)
				# TODO(bquinlan): Should avoid creating new threads if there are more
				# idle threads than items in the work queue.
				num_threads = len(self._threads)
				if num_threads < self._max_workers:
				thread_name = '%s_%d' % (self._thread_name_prefix or self,
				num_threads)
				t = threading.Thread(name=thread_name, target=_worker,
				args=(weakref.ref(self, weakref_cb),
				self._work_queue))
				t.daemon = True
				t.start()
				self._threads.add(t)
				_threads_queues[t] = self._work_queue

				def shutdown(self, wait=True):
				with self._shutdown_lock:
				self._shutdown = True
				self._work_queue.put(None)
				if wait:
				for t in self._threads:
				t.join(sys.maxint)
				shutdown.__doc__ = _base.Executor.shutdown.__doc__