# Copyright 2009 Brian Quinlan. All Rights Reserved. # Licensed to PSF under a Contributor Agreement. """Implements ProcessPoolExecutor. The follow diagram and text describe the data-flow through the system: |======================= In-process =====================|== Out-of-process ==| +----------+ +----------+ +--------+ +-----------+ +---------+ | | => | Work Ids | => | | => | Call Q | => | | | | +----------+ | | +-----------+ | | | | | ... | | | | ... | | | | | | 6 | | | | 5, call() | | | | | | 7 | | | | ... | | | | Process | | ... | | Local | +-----------+ | Process | | Pool | +----------+ | Worker | | #1..n | | Executor | | Thread | | | | | +----------- + | | +-----------+ | | | | <=> | Work Items | <=> | | <= | Result Q | <= | | | | +------------+ | | +-----------+ | | | | | 6: call() | | | | ... | | | | | | future | | | | 4, result | | | | | | ... | | | | 3, except | | | +----------+ +------------+ +--------+ +-----------+ +---------+ Executor.submit() called: - creates a uniquely numbered _WorkItem and adds it to the "Work Items" dict - adds the id of the _WorkItem to the "Work Ids" queue Local worker thread: - reads work ids from the "Work Ids" queue and looks up the corresponding WorkItem from the "Work Items" dict: if the work item has been cancelled then it is simply removed from the dict, otherwise it is repackaged as a _CallItem and put in the "Call Q". New _CallItems are put in the "Call Q" until "Call Q" is full. NOTE: the size of the "Call Q" is kept small because calls placed in the "Call Q" can no longer be cancelled with Future.cancel(). - reads _ResultItems from "Result Q", updates the future stored in the "Work Items" dict and deletes the dict entry Process #1..n: - reads _CallItems from "Call Q", executes the calls, and puts the resulting _ResultItems in "Request Q" """ __author__ = 'Brian Quinlan (brian@sweetapp.com)' import atexit from concurrent.futures import _base import queue import multiprocessing import threading import weakref # Workers are created as daemon threads and processes. This is done to allow the # interpreter to exit when there are still idle processes in a # ProcessPoolExecutor's process 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/processes finish. _threads_queues = weakref.WeakKeyDictionary() _shutdown = False def _python_exit(): global _shutdown _shutdown = True items = list(_threads_queues.items()) for t, q in items: q.put(None) for t, q in items: t.join() # Controls how many more calls than processes will be queued in the call queue. # A smaller number will mean that processes spend more time idle waiting for # work while a larger number will make Future.cancel() succeed less frequently # (Futures in the call queue cannot be cancelled). EXTRA_QUEUED_CALLS = 1 class _WorkItem(object): def __init__(self, future, fn, args, kwargs): self.future = future self.fn = fn self.args = args self.kwargs = kwargs class _ResultItem(object): def __init__(self, work_id, exception=None, result=None): self.work_id = work_id self.exception = exception self.result = result class _CallItem(object): def __init__(self, work_id, fn, args, kwargs): self.work_id = work_id self.fn = fn self.args = args self.kwargs = kwargs def _process_worker(call_queue, result_queue): """Evaluates calls from call_queue and places the results in result_queue. This worker is run in a separate process. Args: call_queue: A multiprocessing.Queue of _CallItems that will be read and evaluated by the worker. result_queue: A multiprocessing.Queue of _ResultItems that will written to by the worker. shutdown: A multiprocessing.Event that will be set as a signal to the worker that it should exit when call_queue is empty. """ while True: call_item = call_queue.get(block=True) if call_item is None: # Wake up queue management thread result_queue.put(None) return try: r = call_item.fn(*call_item.args, **call_item.kwargs) except BaseException as e: result_queue.put(_ResultItem(call_item.work_id, exception=e)) else: result_queue.put(_ResultItem(call_item.work_id, result=r)) def _add_call_item_to_queue(pending_work_items, work_ids, call_queue): """Fills call_queue with _WorkItems from pending_work_items. This function never blocks. Args: pending_work_items: A dict mapping work ids to _WorkItems e.g. {5: <_WorkItem...>, 6: <_WorkItem...>, ...} work_ids: A queue.Queue of work ids e.g. Queue([5, 6, ...]). Work ids are consumed and the corresponding _WorkItems from pending_work_items are transformed into _CallItems and put in call_queue. call_queue: A multiprocessing.Queue that will be filled with _CallItems derived from _WorkItems. """ while True: if call_queue.full(): return try: work_id = work_ids.get(block=False) except queue.Empty: return else: work_item = pending_work_items[work_id] if work_item.future.set_running_or_notify_cancel(): call_queue.put(_CallItem(work_id, work_item.fn, work_item.args, work_item.kwargs), block=True) else: del pending_work_items[work_id] continue def _queue_management_worker(executor_reference, processes, pending_work_items, work_ids_queue, call_queue, result_queue): """Manages the communication between this process and the worker processes. This function is run in a local thread. Args: executor_reference: A weakref.ref to the ProcessPoolExecutor that owns this thread. Used to determine if the ProcessPoolExecutor has been garbage collected and that this function can exit. process: A list of the multiprocessing.Process instances used as workers. pending_work_items: A dict mapping work ids to _WorkItems e.g. {5: <_WorkItem...>, 6: <_WorkItem...>, ...} work_ids_queue: A queue.Queue of work ids e.g. Queue([5, 6, ...]). call_queue: A multiprocessing.Queue that will be filled with _CallItems derived from _WorkItems for processing by the process workers. result_queue: A multiprocessing.Queue of _ResultItems generated by the process workers. """ nb_shutdown_processes = 0 def shutdown_one_process(): """Tell a worker to terminate, which will in turn wake us again""" nonlocal nb_shutdown_processes call_queue.put(None) nb_shutdown_processes += 1 while True: _add_call_item_to_queue(pending_work_items, work_ids_queue, call_queue) result_item = result_queue.get(block=True) if result_item is not None: work_item = pending_work_items[result_item.work_id] del pending_work_items[result_item.work_id] if result_item.exception: work_item.future.set_exception(result_item.exception) else: work_item.future.set_result(result_item.result) continue # If we come here, we either got a timeout or were explicitly woken up. # In either case, check whether we should start shutting down. executor = executor_reference() # No more work items can be added if: # - The interpreter is shutting down OR # - The executor that owns this worker has been collected OR # - The executor that owns this worker has been shutdown. if _shutdown or executor is None or executor._shutdown_thread: # Since no new work items can be added, it is safe to shutdown # this thread if there are no pending work items. if not pending_work_items: while nb_shutdown_processes < len(processes): shutdown_one_process() # If .join() is not called on the created processes then # some multiprocessing.Queue methods may deadlock on Mac OS # X. for p in processes: p.join() call_queue.close() return else: # Start shutting down by telling a process it can exit. shutdown_one_process() del executor _system_limits_checked = False _system_limited = None def _check_system_limits(): global _system_limits_checked, _system_limited if _system_limits_checked: if _system_limited: raise NotImplementedError(_system_limited) _system_limits_checked = True try: import os nsems_max = os.sysconf("SC_SEM_NSEMS_MAX") except (AttributeError, ValueError): # sysconf not available or setting not available return if nsems_max == -1: # indetermine limit, assume that limit is determined # by available memory only return if nsems_max >= 256: # minimum number of semaphores available # according to POSIX return _system_limited = "system provides too few semaphores (%d available, 256 necessary)" % nsems_max raise NotImplementedError(_system_limited) class ProcessPoolExecutor(_base.Executor): def __init__(self, max_workers=None): """Initializes a new ProcessPoolExecutor instance. Args: max_workers: The maximum number of processes that can be used to execute the given calls. If None or not given then as many worker processes will be created as the machine has processors. """ _check_system_limits() if max_workers is None: self._max_workers = multiprocessing.cpu_count() else: self._max_workers = max_workers # Make the call queue slightly larger than the number of processes to # prevent the worker processes from idling. But don't make it too big # because futures in the call queue cannot be cancelled. self._call_queue = multiprocessing.Queue(self._max_workers + EXTRA_QUEUED_CALLS) self._result_queue = multiprocessing.Queue() self._work_ids = queue.Queue() self._queue_management_thread = None self._processes = set() # Shutdown is a two-step process. self._shutdown_thread = False self._shutdown_lock = threading.Lock() self._queue_count = 0 self._pending_work_items = {} def _start_queue_management_thread(self): # When the executor gets lost, the weakref callback will wake up # the queue management thread. def weakref_cb(_, q=self._result_queue): q.put(None) if self._queue_management_thread is None: self._queue_management_thread = threading.Thread( target=_queue_management_worker, args=(weakref.ref(self, weakref_cb), self._processes, self._pending_work_items, self._work_ids, self._call_queue, self._result_queue)) self._queue_management_thread.daemon = True self._queue_management_thread.start() _threads_queues[self._queue_management_thread] = self._result_queue def _adjust_process_count(self): for _ in range(len(self._processes), self._max_workers): p = multiprocessing.Process( target=_process_worker, args=(self._call_queue, self._result_queue)) p.start() self._processes.add(p) def submit(self, fn, *args, **kwargs): with self._shutdown_lock: if self._shutdown_thread: raise RuntimeError('cannot schedule new futures after shutdown') f = _base.Future() w = _WorkItem(f, fn, args, kwargs) self._pending_work_items[self._queue_count] = w self._work_ids.put(self._queue_count) self._queue_count += 1 # Wake up queue management thread self._result_queue.put(None) self._start_queue_management_thread() self._adjust_process_count() return f submit.__doc__ = _base.Executor.submit.__doc__ def shutdown(self, wait=True): with self._shutdown_lock: self._shutdown_thread = True if self._queue_management_thread: # Wake up queue management thread self._result_queue.put(None) if wait: self._queue_management_thread.join() # To reduce the risk of openning too many files, remove references to # objects that use file descriptors. self._queue_management_thread = None self._call_queue = None self._result_queue = None self._processes = None shutdown.__doc__ = _base.Executor.shutdown.__doc__ atexit.register(_python_exit)