| :mod:`multiprocessing` --- Process-based parallelism |
| ==================================================== |
| |
| .. module:: multiprocessing |
| :synopsis: Process-based parallelism. |
| |
| |
| Introduction |
| ------------ |
| |
| :mod:`multiprocessing` is a package that supports spawning processes using an |
| API similar to the :mod:`threading` module. The :mod:`multiprocessing` package |
| offers both local and remote concurrency, effectively side-stepping the |
| :term:`Global Interpreter Lock` by using subprocesses instead of threads. Due |
| to this, the :mod:`multiprocessing` module allows the programmer to fully |
| leverage multiple processors on a given machine. It runs on both Unix and |
| Windows. |
| |
| The :mod:`multiprocessing` module also introduces APIs which do not have |
| analogs in the :mod:`threading` module. A prime example of this is the |
| :class:`~multiprocessing.pool.Pool` object which offers a convenient means of |
| parallelizing the execution of a function across multiple input values, |
| distributing the input data across processes (data parallelism). The following |
| example demonstrates the common practice of defining such functions in a module |
| so that child processes can successfully import that module. This basic example |
| of data parallelism using :class:`~multiprocessing.pool.Pool`, :: |
| |
| from multiprocessing import Pool |
| |
| def f(x): |
| return x*x |
| |
| if __name__ == '__main__': |
| with Pool(5) as p: |
| print(p.map(f, [1, 2, 3])) |
| |
| will print to standard output :: |
| |
| [1, 4, 9] |
| |
| |
| The :class:`Process` class |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| In :mod:`multiprocessing`, processes are spawned by creating a :class:`Process` |
| object and then calling its :meth:`~Process.start` method. :class:`Process` |
| follows the API of :class:`threading.Thread`. A trivial example of a |
| multiprocess program is :: |
| |
| from multiprocessing import Process |
| |
| def f(name): |
| print('hello', name) |
| |
| if __name__ == '__main__': |
| p = Process(target=f, args=('bob',)) |
| p.start() |
| p.join() |
| |
| To show the individual process IDs involved, here is an expanded example:: |
| |
| from multiprocessing import Process |
| import os |
| |
| def info(title): |
| print(title) |
| print('module name:', __name__) |
| print('parent process:', os.getppid()) |
| print('process id:', os.getpid()) |
| |
| def f(name): |
| info('function f') |
| print('hello', name) |
| |
| if __name__ == '__main__': |
| info('main line') |
| p = Process(target=f, args=('bob',)) |
| p.start() |
| p.join() |
| |
| For an explanation of why the ``if __name__ == '__main__'`` part is |
| necessary, see :ref:`multiprocessing-programming`. |
| |
| |
| |
| Contexts and start methods |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| .. _multiprocessing-start-methods: |
| |
| Depending on the platform, :mod:`multiprocessing` supports three ways |
| to start a process. These *start methods* are |
| |
| *spawn* |
| The parent process starts a fresh python interpreter process. The |
| child process will only inherit those resources necessary to run |
| the process objects :meth:`~Process.run` method. In particular, |
| unnecessary file descriptors and handles from the parent process |
| will not be inherited. Starting a process using this method is |
| rather slow compared to using *fork* or *forkserver*. |
| |
| Available on Unix and Windows. The default on Windows. |
| |
| *fork* |
| The parent process uses :func:`os.fork` to fork the Python |
| interpreter. The child process, when it begins, is effectively |
| identical to the parent process. All resources of the parent are |
| inherited by the child process. Note that safely forking a |
| multithreaded process is problematic. |
| |
| Available on Unix only. The default on Unix. |
| |
| *forkserver* |
| When the program starts and selects the *forkserver* start method, |
| a server process is started. From then on, whenever a new process |
| is needed, the parent process connects to the server and requests |
| that it fork a new process. The fork server process is single |
| threaded so it is safe for it to use :func:`os.fork`. No |
| unnecessary resources are inherited. |
| |
| Available on Unix platforms which support passing file descriptors |
| over Unix pipes. |
| |
| .. versionchanged:: 3.4 |
| *spawn* added on all unix platforms, and *forkserver* added for |
| some unix platforms. |
| Child processes no longer inherit all of the parents inheritable |
| handles on Windows. |
| |
| On Unix using the *spawn* or *forkserver* start methods will also |
| start a *semaphore tracker* process which tracks the unlinked named |
| semaphores created by processes of the program. When all processes |
| have exited the semaphore tracker unlinks any remaining semaphores. |
| Usually there should be none, but if a process was killed by a signal |
| there may some "leaked" semaphores. (Unlinking the named semaphores |
| is a serious matter since the system allows only a limited number, and |
| they will not be automatically unlinked until the next reboot.) |
| |
| To select a start method you use the :func:`set_start_method` in |
| the ``if __name__ == '__main__'`` clause of the main module. For |
| example:: |
| |
| import multiprocessing as mp |
| |
| def foo(q): |
| q.put('hello') |
| |
| if __name__ == '__main__': |
| mp.set_start_method('spawn') |
| q = mp.Queue() |
| p = mp.Process(target=foo, args=(q,)) |
| p.start() |
| print(q.get()) |
| p.join() |
| |
| :func:`set_start_method` should not be used more than once in the |
| program. |
| |
| Alternatively, you can use :func:`get_context` to obtain a context |
| object. Context objects have the same API as the multiprocessing |
| module, and allow one to use multiple start methods in the same |
| program. :: |
| |
| import multiprocessing as mp |
| |
| def foo(q): |
| q.put('hello') |
| |
| if __name__ == '__main__': |
| ctx = mp.get_context('spawn') |
| q = ctx.Queue() |
| p = ctx.Process(target=foo, args=(q,)) |
| p.start() |
| print(q.get()) |
| p.join() |
| |
| Note that objects related to one context may not be compatible with |
| processes for a different context. In particular, locks created using |
| the *fork* context cannot be passed to a processes started using the |
| *spawn* or *forkserver* start methods. |
| |
| A library which wants to use a particular start method should probably |
| use :func:`get_context` to avoid interfering with the choice of the |
| library user. |
| |
| |
| Exchanging objects between processes |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| :mod:`multiprocessing` supports two types of communication channel between |
| processes: |
| |
| **Queues** |
| |
| The :class:`Queue` class is a near clone of :class:`queue.Queue`. For |
| example:: |
| |
| from multiprocessing import Process, Queue |
| |
| def f(q): |
| q.put([42, None, 'hello']) |
| |
| if __name__ == '__main__': |
| q = Queue() |
| p = Process(target=f, args=(q,)) |
| p.start() |
| print(q.get()) # prints "[42, None, 'hello']" |
| p.join() |
| |
| Queues are thread and process safe. |
| |
| **Pipes** |
| |
| The :func:`Pipe` function returns a pair of connection objects connected by a |
| pipe which by default is duplex (two-way). For example:: |
| |
| from multiprocessing import Process, Pipe |
| |
| def f(conn): |
| conn.send([42, None, 'hello']) |
| conn.close() |
| |
| if __name__ == '__main__': |
| parent_conn, child_conn = Pipe() |
| p = Process(target=f, args=(child_conn,)) |
| p.start() |
| print(parent_conn.recv()) # prints "[42, None, 'hello']" |
| p.join() |
| |
| The two connection objects returned by :func:`Pipe` represent the two ends of |
| the pipe. Each connection object has :meth:`~Connection.send` and |
| :meth:`~Connection.recv` methods (among others). Note that data in a pipe |
| may become corrupted if two processes (or threads) try to read from or write |
| to the *same* end of the pipe at the same time. Of course there is no risk |
| of corruption from processes using different ends of the pipe at the same |
| time. |
| |
| |
| Synchronization between processes |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| :mod:`multiprocessing` contains equivalents of all the synchronization |
| primitives from :mod:`threading`. For instance one can use a lock to ensure |
| that only one process prints to standard output at a time:: |
| |
| from multiprocessing import Process, Lock |
| |
| def f(l, i): |
| l.acquire() |
| try: |
| print('hello world', i) |
| finally: |
| l.release() |
| |
| if __name__ == '__main__': |
| lock = Lock() |
| |
| for num in range(10): |
| Process(target=f, args=(lock, num)).start() |
| |
| Without using the lock output from the different processes is liable to get all |
| mixed up. |
| |
| |
| Sharing state between processes |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| As mentioned above, when doing concurrent programming it is usually best to |
| avoid using shared state as far as possible. This is particularly true when |
| using multiple processes. |
| |
| However, if you really do need to use some shared data then |
| :mod:`multiprocessing` provides a couple of ways of doing so. |
| |
| **Shared memory** |
| |
| Data can be stored in a shared memory map using :class:`Value` or |
| :class:`Array`. For example, the following code :: |
| |
| from multiprocessing import Process, Value, Array |
| |
| def f(n, a): |
| n.value = 3.1415927 |
| for i in range(len(a)): |
| a[i] = -a[i] |
| |
| if __name__ == '__main__': |
| num = Value('d', 0.0) |
| arr = Array('i', range(10)) |
| |
| p = Process(target=f, args=(num, arr)) |
| p.start() |
| p.join() |
| |
| print(num.value) |
| print(arr[:]) |
| |
| will print :: |
| |
| 3.1415927 |
| [0, -1, -2, -3, -4, -5, -6, -7, -8, -9] |
| |
| The ``'d'`` and ``'i'`` arguments used when creating ``num`` and ``arr`` are |
| typecodes of the kind used by the :mod:`array` module: ``'d'`` indicates a |
| double precision float and ``'i'`` indicates a signed integer. These shared |
| objects will be process and thread-safe. |
| |
| For more flexibility in using shared memory one can use the |
| :mod:`multiprocessing.sharedctypes` module which supports the creation of |
| arbitrary ctypes objects allocated from shared memory. |
| |
| **Server process** |
| |
| A manager object returned by :func:`Manager` controls a server process which |
| holds Python objects and allows other processes to manipulate them using |
| proxies. |
| |
| A manager returned by :func:`Manager` will support types |
| :class:`list`, :class:`dict`, :class:`Namespace`, :class:`Lock`, |
| :class:`RLock`, :class:`Semaphore`, :class:`BoundedSemaphore`, |
| :class:`Condition`, :class:`Event`, :class:`Barrier`, |
| :class:`Queue`, :class:`Value` and :class:`Array`. For example, :: |
| |
| from multiprocessing import Process, Manager |
| |
| def f(d, l): |
| d[1] = '1' |
| d['2'] = 2 |
| d[0.25] = None |
| l.reverse() |
| |
| if __name__ == '__main__': |
| with Manager() as manager: |
| d = manager.dict() |
| l = manager.list(range(10)) |
| |
| p = Process(target=f, args=(d, l)) |
| p.start() |
| p.join() |
| |
| print(d) |
| print(l) |
| |
| will print :: |
| |
| {0.25: None, 1: '1', '2': 2} |
| [9, 8, 7, 6, 5, 4, 3, 2, 1, 0] |
| |
| Server process managers are more flexible than using shared memory objects |
| because they can be made to support arbitrary object types. Also, a single |
| manager can be shared by processes on different computers over a network. |
| They are, however, slower than using shared memory. |
| |
| |
| Using a pool of workers |
| ~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The :class:`~multiprocessing.pool.Pool` class represents a pool of worker |
| processes. It has methods which allows tasks to be offloaded to the worker |
| processes in a few different ways. |
| |
| For example:: |
| |
| from multiprocessing import Pool |
| from time import sleep |
| |
| def f(x): |
| return x*x |
| |
| if __name__ == '__main__': |
| # start 4 worker processes |
| with Pool(processes=4) as pool: |
| |
| # print "[0, 1, 4,..., 81]" |
| print(pool.map(f, range(10))) |
| |
| # print same numbers in arbitrary order |
| for i in pool.imap_unordered(f, range(10)): |
| print(i) |
| |
| # evaluate "f(10)" asynchronously |
| res = pool.apply_async(f, [10]) |
| print(res.get(timeout=1)) # prints "100" |
| |
| # make worker sleep for 10 secs |
| res = pool.apply_async(sleep, [10]) |
| print(res.get(timeout=1)) # raises multiprocessing.TimeoutError |
| |
| # exiting the 'with'-block has stopped the pool |
| |
| Note that the methods of a pool should only ever be used by the |
| process which created it. |
| |
| .. note:: |
| |
| Functionality within this package requires that the ``__main__`` module be |
| importable by the children. This is covered in :ref:`multiprocessing-programming` |
| however it is worth pointing out here. This means that some examples, such |
| as the :class:`multiprocessing.pool.Pool` examples will not work in the |
| interactive interpreter. For example:: |
| |
| >>> from multiprocessing import Pool |
| >>> p = Pool(5) |
| >>> def f(x): |
| ... return x*x |
| ... |
| >>> p.map(f, [1,2,3]) |
| Process PoolWorker-1: |
| Process PoolWorker-2: |
| Process PoolWorker-3: |
| Traceback (most recent call last): |
| Traceback (most recent call last): |
| Traceback (most recent call last): |
| AttributeError: 'module' object has no attribute 'f' |
| AttributeError: 'module' object has no attribute 'f' |
| AttributeError: 'module' object has no attribute 'f' |
| |
| (If you try this it will actually output three full tracebacks |
| interleaved in a semi-random fashion, and then you may have to |
| stop the master process somehow.) |
| |
| |
| Reference |
| --------- |
| |
| The :mod:`multiprocessing` package mostly replicates the API of the |
| :mod:`threading` module. |
| |
| |
| :class:`Process` and exceptions |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| .. class:: Process(group=None, target=None, name=None, args=(), kwargs={}, \ |
| *, daemon=None) |
| |
| Process objects represent activity that is run in a separate process. The |
| :class:`Process` class has equivalents of all the methods of |
| :class:`threading.Thread`. |
| |
| The constructor should always be called with keyword arguments. *group* |
| should always be ``None``; it exists solely for compatibility with |
| :class:`threading.Thread`. *target* is the callable object to be invoked by |
| the :meth:`run()` method. It defaults to ``None``, meaning nothing is |
| called. *name* is the process name (see :attr:`name` for more details). |
| *args* is the argument tuple for the target invocation. *kwargs* is a |
| dictionary of keyword arguments for the target invocation. If provided, |
| the keyword-only *daemon* argument sets the process :attr:`daemon` flag |
| to ``True`` or ``False``. If ``None`` (the default), this flag will be |
| inherited from the creating process. |
| |
| By default, no arguments are passed to *target*. |
| |
| If a subclass overrides the constructor, it must make sure it invokes the |
| base class constructor (:meth:`Process.__init__`) before doing anything else |
| to the process. |
| |
| .. versionchanged:: 3.3 |
| Added the *daemon* argument. |
| |
| .. method:: run() |
| |
| Method representing the process's activity. |
| |
| You may override this method in a subclass. The standard :meth:`run` |
| method invokes the callable object passed to the object's constructor as |
| the target argument, if any, with sequential and keyword arguments taken |
| from the *args* and *kwargs* arguments, respectively. |
| |
| .. method:: start() |
| |
| Start the process's activity. |
| |
| This must be called at most once per process object. It arranges for the |
| object's :meth:`run` method to be invoked in a separate process. |
| |
| .. method:: join([timeout]) |
| |
| If the optional argument *timeout* is ``None`` (the default), the method |
| blocks until the process whose :meth:`join` method is called terminates. |
| If *timeout* is a positive number, it blocks at most *timeout* seconds. |
| |
| A process can be joined many times. |
| |
| A process cannot join itself because this would cause a deadlock. It is |
| an error to attempt to join a process before it has been started. |
| |
| .. attribute:: name |
| |
| The process's name. The name is a string used for identification purposes |
| only. It has no semantics. Multiple processes may be given the same |
| name. |
| |
| The initial name is set by the constructor. If no explicit name is |
| provided to the constructor, a name of the form |
| 'Process-N\ :sub:`1`:N\ :sub:`2`:...:N\ :sub:`k`' is constructed, where |
| each N\ :sub:`k` is the N-th child of its parent. |
| |
| .. method:: is_alive |
| |
| Return whether the process is alive. |
| |
| Roughly, a process object is alive from the moment the :meth:`start` |
| method returns until the child process terminates. |
| |
| .. attribute:: daemon |
| |
| The process's daemon flag, a Boolean value. This must be set before |
| :meth:`start` is called. |
| |
| The initial value is inherited from the creating process. |
| |
| When a process exits, it attempts to terminate all of its daemonic child |
| processes. |
| |
| Note that a daemonic process is not allowed to create child processes. |
| Otherwise a daemonic process would leave its children orphaned if it gets |
| terminated when its parent process exits. Additionally, these are **not** |
| Unix daemons or services, they are normal processes that will be |
| terminated (and not joined) if non-daemonic processes have exited. |
| |
| In addition to the :class:`threading.Thread` API, :class:`Process` objects |
| also support the following attributes and methods: |
| |
| .. attribute:: pid |
| |
| Return the process ID. Before the process is spawned, this will be |
| ``None``. |
| |
| .. attribute:: exitcode |
| |
| The child's exit code. This will be ``None`` if the process has not yet |
| terminated. A negative value *-N* indicates that the child was terminated |
| by signal *N*. |
| |
| .. attribute:: authkey |
| |
| The process's authentication key (a byte string). |
| |
| When :mod:`multiprocessing` is initialized the main process is assigned a |
| random string using :func:`os.urandom`. |
| |
| When a :class:`Process` object is created, it will inherit the |
| authentication key of its parent process, although this may be changed by |
| setting :attr:`authkey` to another byte string. |
| |
| See :ref:`multiprocessing-auth-keys`. |
| |
| .. attribute:: sentinel |
| |
| A numeric handle of a system object which will become "ready" when |
| the process ends. |
| |
| You can use this value if you want to wait on several events at |
| once using :func:`multiprocessing.connection.wait`. Otherwise |
| calling :meth:`join()` is simpler. |
| |
| On Windows, this is an OS handle usable with the ``WaitForSingleObject`` |
| and ``WaitForMultipleObjects`` family of API calls. On Unix, this is |
| a file descriptor usable with primitives from the :mod:`select` module. |
| |
| .. versionadded:: 3.3 |
| |
| .. method:: terminate() |
| |
| Terminate the process. On Unix this is done using the ``SIGTERM`` signal; |
| on Windows :c:func:`TerminateProcess` is used. Note that exit handlers and |
| finally clauses, etc., will not be executed. |
| |
| Note that descendant processes of the process will *not* be terminated -- |
| they will simply become orphaned. |
| |
| .. warning:: |
| |
| If this method is used when the associated process is using a pipe or |
| queue then the pipe or queue is liable to become corrupted and may |
| become unusable by other process. Similarly, if the process has |
| acquired a lock or semaphore etc. then terminating it is liable to |
| cause other processes to deadlock. |
| |
| Note that the :meth:`start`, :meth:`join`, :meth:`is_alive`, |
| :meth:`terminate` and :attr:`exitcode` methods should only be called by |
| the process that created the process object. |
| |
| Example usage of some of the methods of :class:`Process`: |
| |
| .. doctest:: |
| |
| >>> import multiprocessing, time, signal |
| >>> p = multiprocessing.Process(target=time.sleep, args=(1000,)) |
| >>> print(p, p.is_alive()) |
| <Process(Process-1, initial)> False |
| >>> p.start() |
| >>> print(p, p.is_alive()) |
| <Process(Process-1, started)> True |
| >>> p.terminate() |
| >>> time.sleep(0.1) |
| >>> print(p, p.is_alive()) |
| <Process(Process-1, stopped[SIGTERM])> False |
| >>> p.exitcode == -signal.SIGTERM |
| True |
| |
| .. exception:: ProcessError |
| |
| The base class of all :mod:`multiprocessing` exceptions. |
| |
| .. exception:: BufferTooShort |
| |
| Exception raised by :meth:`Connection.recv_bytes_into()` when the supplied |
| buffer object is too small for the message read. |
| |
| If ``e`` is an instance of :exc:`BufferTooShort` then ``e.args[0]`` will give |
| the message as a byte string. |
| |
| .. exception:: AuthenticationError |
| |
| Raised when there is an authentication error. |
| |
| .. exception:: TimeoutError |
| |
| Raised by methods with a timeout when the timeout expires. |
| |
| Pipes and Queues |
| ~~~~~~~~~~~~~~~~ |
| |
| When using multiple processes, one generally uses message passing for |
| communication between processes and avoids having to use any synchronization |
| primitives like locks. |
| |
| For passing messages one can use :func:`Pipe` (for a connection between two |
| processes) or a queue (which allows multiple producers and consumers). |
| |
| The :class:`Queue`, :class:`SimpleQueue` and :class:`JoinableQueue` types are multi-producer, |
| multi-consumer FIFO queues modelled on the :class:`queue.Queue` class in the |
| standard library. They differ in that :class:`Queue` lacks the |
| :meth:`~queue.Queue.task_done` and :meth:`~queue.Queue.join` methods introduced |
| into Python 2.5's :class:`queue.Queue` class. |
| |
| If you use :class:`JoinableQueue` then you **must** call |
| :meth:`JoinableQueue.task_done` for each task removed from the queue or else the |
| semaphore used to count the number of unfinished tasks may eventually overflow, |
| raising an exception. |
| |
| Note that one can also create a shared queue by using a manager object -- see |
| :ref:`multiprocessing-managers`. |
| |
| .. note:: |
| |
| :mod:`multiprocessing` uses the usual :exc:`queue.Empty` and |
| :exc:`queue.Full` exceptions to signal a timeout. They are not available in |
| the :mod:`multiprocessing` namespace so you need to import them from |
| :mod:`queue`. |
| |
| .. note:: |
| |
| When an object is put on a queue, the object is pickled and a |
| background thread later flushes the pickled data to an underlying |
| pipe. This has some consequences which are a little surprising, |
| but should not cause any practical difficulties -- if they really |
| bother you then you can instead use a queue created with a |
| :ref:`manager <multiprocessing-managers>`. |
| |
| (1) After putting an object on an empty queue there may be an |
| infinitesimal delay before the queue's :meth:`~Queue.empty` |
| method returns :const:`False` and :meth:`~Queue.get_nowait` can |
| return without raising :exc:`queue.Empty`. |
| |
| (2) If multiple processes are enqueuing objects, it is possible for |
| the objects to be received at the other end out-of-order. |
| However, objects enqueued by the same process will always be in |
| the expected order with respect to each other. |
| |
| .. warning:: |
| |
| If a process is killed using :meth:`Process.terminate` or :func:`os.kill` |
| while it is trying to use a :class:`Queue`, then the data in the queue is |
| likely to become corrupted. This may cause any other process to get an |
| exception when it tries to use the queue later on. |
| |
| .. warning:: |
| |
| As mentioned above, if a child process has put items on a queue (and it has |
| not used :meth:`JoinableQueue.cancel_join_thread |
| <multiprocessing.Queue.cancel_join_thread>`), then that process will |
| not terminate until all buffered items have been flushed to the pipe. |
| |
| This means that if you try joining that process you may get a deadlock unless |
| you are sure that all items which have been put on the queue have been |
| consumed. Similarly, if the child process is non-daemonic then the parent |
| process may hang on exit when it tries to join all its non-daemonic children. |
| |
| Note that a queue created using a manager does not have this issue. See |
| :ref:`multiprocessing-programming`. |
| |
| For an example of the usage of queues for interprocess communication see |
| :ref:`multiprocessing-examples`. |
| |
| |
| .. function:: Pipe([duplex]) |
| |
| Returns a pair ``(conn1, conn2)`` of :class:`Connection` objects representing |
| the ends of a pipe. |
| |
| If *duplex* is ``True`` (the default) then the pipe is bidirectional. If |
| *duplex* is ``False`` then the pipe is unidirectional: ``conn1`` can only be |
| used for receiving messages and ``conn2`` can only be used for sending |
| messages. |
| |
| |
| .. class:: Queue([maxsize]) |
| |
| Returns a process shared queue implemented using a pipe and a few |
| locks/semaphores. When a process first puts an item on the queue a feeder |
| thread is started which transfers objects from a buffer into the pipe. |
| |
| The usual :exc:`queue.Empty` and :exc:`queue.Full` exceptions from the |
| standard library's :mod:`queue` module are raised to signal timeouts. |
| |
| :class:`Queue` implements all the methods of :class:`queue.Queue` except for |
| :meth:`~queue.Queue.task_done` and :meth:`~queue.Queue.join`. |
| |
| .. method:: qsize() |
| |
| Return the approximate size of the queue. Because of |
| multithreading/multiprocessing semantics, this number is not reliable. |
| |
| Note that this may raise :exc:`NotImplementedError` on Unix platforms like |
| Mac OS X where ``sem_getvalue()`` is not implemented. |
| |
| .. method:: empty() |
| |
| Return ``True`` if the queue is empty, ``False`` otherwise. Because of |
| multithreading/multiprocessing semantics, this is not reliable. |
| |
| .. method:: full() |
| |
| Return ``True`` if the queue is full, ``False`` otherwise. Because of |
| multithreading/multiprocessing semantics, this is not reliable. |
| |
| .. method:: put(obj[, block[, timeout]]) |
| |
| Put obj into the queue. If the optional argument *block* is ``True`` |
| (the default) and *timeout* is ``None`` (the default), block if necessary until |
| a free slot is available. If *timeout* is a positive number, it blocks at |
| most *timeout* seconds and raises the :exc:`queue.Full` exception if no |
| free slot was available within that time. Otherwise (*block* is |
| ``False``), put an item on the queue if a free slot is immediately |
| available, else raise the :exc:`queue.Full` exception (*timeout* is |
| ignored in that case). |
| |
| .. method:: put_nowait(obj) |
| |
| Equivalent to ``put(obj, False)``. |
| |
| .. method:: get([block[, timeout]]) |
| |
| Remove and return an item from the queue. If optional args *block* is |
| ``True`` (the default) and *timeout* is ``None`` (the default), block if |
| necessary until an item is available. If *timeout* is a positive number, |
| it blocks at most *timeout* seconds and raises the :exc:`queue.Empty` |
| exception if no item was available within that time. Otherwise (block is |
| ``False``), return an item if one is immediately available, else raise the |
| :exc:`queue.Empty` exception (*timeout* is ignored in that case). |
| |
| .. method:: get_nowait() |
| |
| Equivalent to ``get(False)``. |
| |
| :class:`multiprocessing.Queue` has a few additional methods not found in |
| :class:`queue.Queue`. These methods are usually unnecessary for most |
| code: |
| |
| .. method:: close() |
| |
| Indicate that no more data will be put on this queue by the current |
| process. The background thread will quit once it has flushed all buffered |
| data to the pipe. This is called automatically when the queue is garbage |
| collected. |
| |
| .. method:: join_thread() |
| |
| Join the background thread. This can only be used after :meth:`close` has |
| been called. It blocks until the background thread exits, ensuring that |
| all data in the buffer has been flushed to the pipe. |
| |
| By default if a process is not the creator of the queue then on exit it |
| will attempt to join the queue's background thread. The process can call |
| :meth:`cancel_join_thread` to make :meth:`join_thread` do nothing. |
| |
| .. method:: cancel_join_thread() |
| |
| Prevent :meth:`join_thread` from blocking. In particular, this prevents |
| the background thread from being joined automatically when the process |
| exits -- see :meth:`join_thread`. |
| |
| A better name for this method might be |
| ``allow_exit_without_flush()``. It is likely to cause enqueued |
| data to lost, and you almost certainly will not need to use it. |
| It is really only there if you need the current process to exit |
| immediately without waiting to flush enqueued data to the |
| underlying pipe, and you don't care about lost data. |
| |
| .. note:: |
| |
| This class's functionality requires a functioning shared semaphore |
| implementation on the host operating system. Without one, the |
| functionality in this class will be disabled, and attempts to |
| instantiate a :class:`Queue` will result in an :exc:`ImportError`. See |
| :issue:`3770` for additional information. The same holds true for any |
| of the specialized queue types listed below. |
| |
| .. class:: SimpleQueue() |
| |
| It is a simplified :class:`Queue` type, very close to a locked :class:`Pipe`. |
| |
| .. method:: empty() |
| |
| Return ``True`` if the queue is empty, ``False`` otherwise. |
| |
| .. method:: get() |
| |
| Remove and return an item from the queue. |
| |
| .. method:: put(item) |
| |
| Put *item* into the queue. |
| |
| |
| .. class:: JoinableQueue([maxsize]) |
| |
| :class:`JoinableQueue`, a :class:`Queue` subclass, is a queue which |
| additionally has :meth:`task_done` and :meth:`join` methods. |
| |
| .. method:: task_done() |
| |
| Indicate that a formerly enqueued task is complete. Used by queue |
| consumers. For each :meth:`~Queue.get` used to fetch a task, a subsequent |
| call to :meth:`task_done` tells the queue that the processing on the task |
| is complete. |
| |
| If a :meth:`~queue.Queue.join` is currently blocking, it will resume when all |
| items have been processed (meaning that a :meth:`task_done` call was |
| received for every item that had been :meth:`~Queue.put` into the queue). |
| |
| Raises a :exc:`ValueError` if called more times than there were items |
| placed in the queue. |
| |
| |
| .. method:: join() |
| |
| Block until all items in the queue have been gotten and processed. |
| |
| The count of unfinished tasks goes up whenever an item is added to the |
| queue. The count goes down whenever a consumer calls |
| :meth:`task_done` to indicate that the item was retrieved and all work on |
| it is complete. When the count of unfinished tasks drops to zero, |
| :meth:`~queue.Queue.join` unblocks. |
| |
| |
| Miscellaneous |
| ~~~~~~~~~~~~~ |
| |
| .. function:: active_children() |
| |
| Return list of all live children of the current process. |
| |
| Calling this has the side effect of "joining" any processes which have |
| already finished. |
| |
| .. function:: cpu_count() |
| |
| Return the number of CPUs in the system. |
| |
| This number is not equivalent to the number of CPUs the current process can |
| use. The number of usable CPUs can be obtained with |
| ``len(os.sched_getaffinity(0))`` |
| |
| May raise :exc:`NotImplementedError`. |
| |
| .. seealso:: |
| :func:`os.cpu_count` |
| |
| .. function:: current_process() |
| |
| Return the :class:`Process` object corresponding to the current process. |
| |
| An analogue of :func:`threading.current_thread`. |
| |
| .. function:: freeze_support() |
| |
| Add support for when a program which uses :mod:`multiprocessing` has been |
| frozen to produce a Windows executable. (Has been tested with **py2exe**, |
| **PyInstaller** and **cx_Freeze**.) |
| |
| One needs to call this function straight after the ``if __name__ == |
| '__main__'`` line of the main module. For example:: |
| |
| from multiprocessing import Process, freeze_support |
| |
| def f(): |
| print('hello world!') |
| |
| if __name__ == '__main__': |
| freeze_support() |
| Process(target=f).start() |
| |
| If the ``freeze_support()`` line is omitted then trying to run the frozen |
| executable will raise :exc:`RuntimeError`. |
| |
| If the module is being run normally by the Python interpreter then |
| :func:`freeze_support` has no effect. |
| |
| .. function:: get_all_start_methods() |
| |
| Returns a list of the supported start methods, the first of which |
| is the default. The possible start methods are ``'fork'``, |
| ``'spawn'`` and ``'forkserver'``. On Windows only ``'spawn'`` is |
| available. On Unix ``'fork'`` and ``'spawn'`` are always |
| supported, with ``'fork'`` being the default. |
| |
| .. versionadded:: 3.4 |
| |
| .. function:: get_context(method=None) |
| |
| Return a context object which has the same attributes as the |
| :mod:`multiprocessing` module. |
| |
| If *method* is *None* then the default context is returned. |
| Otherwise *method* should be ``'fork'``, ``'spawn'``, |
| ``'forkserver'``. :exc:`ValueError` is raised if the specified |
| start method is not available. |
| |
| .. versionadded:: 3.4 |
| |
| .. function:: get_start_method(allow_none=False) |
| |
| Return the name of start method used for starting processes. |
| |
| If the start method has not been fixed and *allow_none* is false, |
| then the start method is fixed to the default and the name is |
| returned. If the start method has not been fixed and *allow_none* |
| is true then *None* is returned. |
| |
| The return value can be ``'fork'``, ``'spawn'``, ``'forkserver'`` |
| or *None*. ``'fork'`` is the default on Unix, while ``'spawn'`` is |
| the default on Windows. |
| |
| .. versionadded:: 3.4 |
| |
| .. function:: set_executable() |
| |
| Sets the path of the Python interpreter to use when starting a child process. |
| (By default :data:`sys.executable` is used). Embedders will probably need to |
| do some thing like :: |
| |
| set_executable(os.path.join(sys.exec_prefix, 'pythonw.exe')) |
| |
| before they can create child processes. |
| |
| .. versionchanged:: 3.4 |
| Now supported on Unix when the ``'spawn'`` start method is used. |
| |
| .. function:: set_start_method(method) |
| |
| Set the method which should be used to start child processes. |
| *method* can be ``'fork'``, ``'spawn'`` or ``'forkserver'``. |
| |
| Note that this should be called at most once, and it should be |
| protected inside the ``if __name__ == '__main__'`` clause of the |
| main module. |
| |
| .. versionadded:: 3.4 |
| |
| .. note:: |
| |
| :mod:`multiprocessing` contains no analogues of |
| :func:`threading.active_count`, :func:`threading.enumerate`, |
| :func:`threading.settrace`, :func:`threading.setprofile`, |
| :class:`threading.Timer`, or :class:`threading.local`. |
| |
| |
| Connection Objects |
| ~~~~~~~~~~~~~~~~~~ |
| |
| Connection objects allow the sending and receiving of picklable objects or |
| strings. They can be thought of as message oriented connected sockets. |
| |
| Connection objects are usually created using :func:`Pipe` -- see also |
| :ref:`multiprocessing-listeners-clients`. |
| |
| .. class:: Connection |
| |
| .. method:: send(obj) |
| |
| Send an object to the other end of the connection which should be read |
| using :meth:`recv`. |
| |
| The object must be picklable. Very large pickles (approximately 32 MB+, |
| though it depends on the OS) may raise a ValueError exception. |
| |
| .. method:: recv() |
| |
| Return an object sent from the other end of the connection using |
| :meth:`send`. Blocks until there its something to receive. Raises |
| :exc:`EOFError` if there is nothing left to receive |
| and the other end was closed. |
| |
| .. method:: fileno() |
| |
| Return the file descriptor or handle used by the connection. |
| |
| .. method:: close() |
| |
| Close the connection. |
| |
| This is called automatically when the connection is garbage collected. |
| |
| .. method:: poll([timeout]) |
| |
| Return whether there is any data available to be read. |
| |
| If *timeout* is not specified then it will return immediately. If |
| *timeout* is a number then this specifies the maximum time in seconds to |
| block. If *timeout* is ``None`` then an infinite timeout is used. |
| |
| Note that multiple connection objects may be polled at once by |
| using :func:`multiprocessing.connection.wait`. |
| |
| .. method:: send_bytes(buffer[, offset[, size]]) |
| |
| Send byte data from a :term:`bytes-like object` as a complete message. |
| |
| If *offset* is given then data is read from that position in *buffer*. If |
| *size* is given then that many bytes will be read from buffer. Very large |
| buffers (approximately 32 MB+, though it depends on the OS) may raise a |
| :exc:`ValueError` exception |
| |
| .. method:: recv_bytes([maxlength]) |
| |
| Return a complete message of byte data sent from the other end of the |
| connection as a string. Blocks until there is something to receive. |
| Raises :exc:`EOFError` if there is nothing left |
| to receive and the other end has closed. |
| |
| If *maxlength* is specified and the message is longer than *maxlength* |
| then :exc:`OSError` is raised and the connection will no longer be |
| readable. |
| |
| .. versionchanged:: 3.3 |
| This function used to raise a :exc:`IOError`, which is now an |
| alias of :exc:`OSError`. |
| |
| |
| .. method:: recv_bytes_into(buffer[, offset]) |
| |
| Read into *buffer* a complete message of byte data sent from the other end |
| of the connection and return the number of bytes in the message. Blocks |
| until there is something to receive. Raises |
| :exc:`EOFError` if there is nothing left to receive and the other end was |
| closed. |
| |
| *buffer* must be a writable :term:`bytes-like object`. If |
| *offset* is given then the message will be written into the buffer from |
| that position. Offset must be a non-negative integer less than the |
| length of *buffer* (in bytes). |
| |
| If the buffer is too short then a :exc:`BufferTooShort` exception is |
| raised and the complete message is available as ``e.args[0]`` where ``e`` |
| is the exception instance. |
| |
| .. versionchanged:: 3.3 |
| Connection objects themselves can now be transferred between processes |
| using :meth:`Connection.send` and :meth:`Connection.recv`. |
| |
| .. versionadded:: 3.3 |
| Connection objects now support the context management protocol -- see |
| :ref:`typecontextmanager`. :meth:`~contextmanager.__enter__` returns the |
| connection object, and :meth:`~contextmanager.__exit__` calls :meth:`close`. |
| |
| For example: |
| |
| .. doctest:: |
| |
| >>> from multiprocessing import Pipe |
| >>> a, b = Pipe() |
| >>> a.send([1, 'hello', None]) |
| >>> b.recv() |
| [1, 'hello', None] |
| >>> b.send_bytes(b'thank you') |
| >>> a.recv_bytes() |
| b'thank you' |
| >>> import array |
| >>> arr1 = array.array('i', range(5)) |
| >>> arr2 = array.array('i', [0] * 10) |
| >>> a.send_bytes(arr1) |
| >>> count = b.recv_bytes_into(arr2) |
| >>> assert count == len(arr1) * arr1.itemsize |
| >>> arr2 |
| array('i', [0, 1, 2, 3, 4, 0, 0, 0, 0, 0]) |
| |
| |
| .. warning:: |
| |
| The :meth:`Connection.recv` method automatically unpickles the data it |
| receives, which can be a security risk unless you can trust the process |
| which sent the message. |
| |
| Therefore, unless the connection object was produced using :func:`Pipe` you |
| should only use the :meth:`~Connection.recv` and :meth:`~Connection.send` |
| methods after performing some sort of authentication. See |
| :ref:`multiprocessing-auth-keys`. |
| |
| .. warning:: |
| |
| If a process is killed while it is trying to read or write to a pipe then |
| the data in the pipe is likely to become corrupted, because it may become |
| impossible to be sure where the message boundaries lie. |
| |
| |
| Synchronization primitives |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Generally synchronization primitives are not as necessary in a multiprocess |
| program as they are in a multithreaded program. See the documentation for |
| :mod:`threading` module. |
| |
| Note that one can also create synchronization primitives by using a manager |
| object -- see :ref:`multiprocessing-managers`. |
| |
| .. class:: Barrier(parties[, action[, timeout]]) |
| |
| A barrier object: a clone of :class:`threading.Barrier`. |
| |
| .. versionadded:: 3.3 |
| |
| .. class:: BoundedSemaphore([value]) |
| |
| A bounded semaphore object: a close analog of |
| :class:`threading.BoundedSemaphore`. |
| |
| A solitary difference from its close analog exists: its ``acquire`` method's |
| first argument is named *block*, as is consistent with :meth:`Lock.acquire`. |
| |
| .. note:: |
| On Mac OS X, this is indistinguishable from :class:`Semaphore` because |
| ``sem_getvalue()`` is not implemented on that platform. |
| |
| .. class:: Condition([lock]) |
| |
| A condition variable: an alias for :class:`threading.Condition`. |
| |
| If *lock* is specified then it should be a :class:`Lock` or :class:`RLock` |
| object from :mod:`multiprocessing`. |
| |
| .. versionchanged:: 3.3 |
| The :meth:`~threading.Condition.wait_for` method was added. |
| |
| .. class:: Event() |
| |
| A clone of :class:`threading.Event`. |
| |
| |
| .. class:: Lock() |
| |
| A non-recursive lock object: a close analog of :class:`threading.Lock`. |
| Once a process or thread has acquired a lock, subsequent attempts to |
| acquire it from any process or thread will block until it is released; |
| any process or thread may release it. The concepts and behaviors of |
| :class:`threading.Lock` as it applies to threads are replicated here in |
| :class:`multiprocessing.Lock` as it applies to either processes or threads, |
| except as noted. |
| |
| Note that :class:`Lock` is actually a factory function which returns an |
| instance of ``multiprocessing.synchronize.Lock`` initialized with a |
| default context. |
| |
| :class:`Lock` supports the :term:`context manager` protocol and thus may be |
| used in :keyword:`with` statements. |
| |
| .. method:: acquire(block=True, timeout=None) |
| |
| Acquire a lock, blocking or non-blocking. |
| |
| With the *block* argument set to ``True`` (the default), the method call |
| will block until the lock is in an unlocked state, then set it to locked |
| and return ``True``. Note that the name of this first argument differs |
| from that in :meth:`threading.Lock.acquire`. |
| |
| With the *block* argument set to ``False``, the method call does not |
| block. If the lock is currently in a locked state, return ``False``; |
| otherwise set the lock to a locked state and return ``True``. |
| |
| When invoked with a positive, floating-point value for *timeout*, block |
| for at most the number of seconds specified by *timeout* as long as |
| the lock can not be acquired. Invocations with a negative value for |
| *timeout* are equivalent to a *timeout* of zero. Invocations with a |
| *timeout* value of ``None`` (the default) set the timeout period to |
| infinite. Note that the treatment of negative or ``None`` values for |
| *timeout* differs from the implemented behavior in |
| :meth:`threading.Lock.acquire`. The *timeout* argument has no practical |
| implications if the *block* argument is set to ``False`` and is thus |
| ignored. Returns ``True`` if the lock has been acquired or ``False`` if |
| the timeout period has elapsed. |
| |
| |
| .. method:: release() |
| |
| Release a lock. This can be called from any process or thread, not only |
| the process or thread which originally acquired the lock. |
| |
| Behavior is the same as in :meth:`threading.Lock.release` except that |
| when invoked on an unlocked lock, a :exc:`ValueError` is raised. |
| |
| |
| .. class:: RLock() |
| |
| A recursive lock object: a close analog of :class:`threading.RLock`. A |
| recursive lock must be released by the process or thread that acquired it. |
| Once a process or thread has acquired a recursive lock, the same process |
| or thread may acquire it again without blocking; that process or thread |
| must release it once for each time it has been acquired. |
| |
| Note that :class:`RLock` is actually a factory function which returns an |
| instance of ``multiprocessing.synchronize.RLock`` initialized with a |
| default context. |
| |
| :class:`RLock` supports the :term:`context manager` protocol and thus may be |
| used in :keyword:`with` statements. |
| |
| |
| .. method:: acquire(block=True, timeout=None) |
| |
| Acquire a lock, blocking or non-blocking. |
| |
| When invoked with the *block* argument set to ``True``, block until the |
| lock is in an unlocked state (not owned by any process or thread) unless |
| the lock is already owned by the current process or thread. The current |
| process or thread then takes ownership of the lock (if it does not |
| already have ownership) and the recursion level inside the lock increments |
| by one, resulting in a return value of ``True``. Note that there are |
| several differences in this first argument's behavior compared to the |
| implementation of :meth:`threading.RLock.acquire`, starting with the name |
| of the argument itself. |
| |
| When invoked with the *block* argument set to ``False``, do not block. |
| If the lock has already been acquired (and thus is owned) by another |
| process or thread, the current process or thread does not take ownership |
| and the recursion level within the lock is not changed, resulting in |
| a return value of ``False``. If the lock is in an unlocked state, the |
| current process or thread takes ownership and the recursion level is |
| incremented, resulting in a return value of ``True``. |
| |
| Use and behaviors of the *timeout* argument are the same as in |
| :meth:`Lock.acquire`. Note that some of these behaviors of *timeout* |
| differ from the implemented behaviors in :meth:`threading.RLock.acquire`. |
| |
| |
| .. method:: release() |
| |
| Release a lock, decrementing the recursion level. If after the |
| decrement the recursion level is zero, reset the lock to unlocked (not |
| owned by any process or thread) and if any other processes or threads |
| are blocked waiting for the lock to become unlocked, allow exactly one |
| of them to proceed. If after the decrement the recursion level is still |
| nonzero, the lock remains locked and owned by the calling process or |
| thread. |
| |
| Only call this method when the calling process or thread owns the lock. |
| An :exc:`AssertionError` is raised if this method is called by a process |
| or thread other than the owner or if the lock is in an unlocked (unowned) |
| state. Note that the type of exception raised in this situation |
| differs from the implemented behavior in :meth:`threading.RLock.release`. |
| |
| |
| .. class:: Semaphore([value]) |
| |
| A semaphore object: a close analog of :class:`threading.Semaphore`. |
| |
| A solitary difference from its close analog exists: its ``acquire`` method's |
| first argument is named *block*, as is consistent with :meth:`Lock.acquire`. |
| |
| .. note:: |
| |
| On Mac OS X, ``sem_timedwait`` is unsupported, so calling ``acquire()`` with |
| a timeout will emulate that function's behavior using a sleeping loop. |
| |
| .. note:: |
| |
| If the SIGINT signal generated by :kbd:`Ctrl-C` arrives while the main thread is |
| blocked by a call to :meth:`BoundedSemaphore.acquire`, :meth:`Lock.acquire`, |
| :meth:`RLock.acquire`, :meth:`Semaphore.acquire`, :meth:`Condition.acquire` |
| or :meth:`Condition.wait` then the call will be immediately interrupted and |
| :exc:`KeyboardInterrupt` will be raised. |
| |
| This differs from the behaviour of :mod:`threading` where SIGINT will be |
| ignored while the equivalent blocking calls are in progress. |
| |
| .. note:: |
| |
| Some of this package's functionality requires a functioning shared semaphore |
| implementation on the host operating system. Without one, the |
| :mod:`multiprocessing.synchronize` module will be disabled, and attempts to |
| import it will result in an :exc:`ImportError`. See |
| :issue:`3770` for additional information. |
| |
| |
| Shared :mod:`ctypes` Objects |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| It is possible to create shared objects using shared memory which can be |
| inherited by child processes. |
| |
| .. function:: Value(typecode_or_type, *args, lock=True) |
| |
| Return a :mod:`ctypes` object allocated from shared memory. By default the |
| return value is actually a synchronized wrapper for the object. The object |
| itself can be accessed via the *value* attribute of a :class:`Value`. |
| |
| *typecode_or_type* determines the type of the returned object: it is either a |
| ctypes type or a one character typecode of the kind used by the :mod:`array` |
| module. *\*args* is passed on to the constructor for the type. |
| |
| If *lock* is ``True`` (the default) then a new recursive lock |
| object is created to synchronize access to the value. If *lock* is |
| a :class:`Lock` or :class:`RLock` object then that will be used to |
| synchronize access to the value. If *lock* is ``False`` then |
| access to the returned object will not be automatically protected |
| by a lock, so it will not necessarily be "process-safe". |
| |
| Operations like ``+=`` which involve a read and write are not |
| atomic. So if, for instance, you want to atomically increment a |
| shared value it is insufficient to just do :: |
| |
| counter.value += 1 |
| |
| Assuming the associated lock is recursive (which it is by default) |
| you can instead do :: |
| |
| with counter.get_lock(): |
| counter.value += 1 |
| |
| Note that *lock* is a keyword-only argument. |
| |
| .. function:: Array(typecode_or_type, size_or_initializer, *, lock=True) |
| |
| Return a ctypes array allocated from shared memory. By default the return |
| value is actually a synchronized wrapper for the array. |
| |
| *typecode_or_type* determines the type of the elements of the returned array: |
| it is either a ctypes type or a one character typecode of the kind used by |
| the :mod:`array` module. If *size_or_initializer* is an integer, then it |
| determines the length of the array, and the array will be initially zeroed. |
| Otherwise, *size_or_initializer* is a sequence which is used to initialize |
| the array and whose length determines the length of the array. |
| |
| If *lock* is ``True`` (the default) then a new lock object is created to |
| synchronize access to the value. If *lock* is a :class:`Lock` or |
| :class:`RLock` object then that will be used to synchronize access to the |
| value. If *lock* is ``False`` then access to the returned object will not be |
| automatically protected by a lock, so it will not necessarily be |
| "process-safe". |
| |
| Note that *lock* is a keyword only argument. |
| |
| Note that an array of :data:`ctypes.c_char` has *value* and *raw* |
| attributes which allow one to use it to store and retrieve strings. |
| |
| |
| The :mod:`multiprocessing.sharedctypes` module |
| >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> |
| |
| .. module:: multiprocessing.sharedctypes |
| :synopsis: Allocate ctypes objects from shared memory. |
| |
| The :mod:`multiprocessing.sharedctypes` module provides functions for allocating |
| :mod:`ctypes` objects from shared memory which can be inherited by child |
| processes. |
| |
| .. note:: |
| |
| Although it is possible to store a pointer in shared memory remember that |
| this will refer to a location in the address space of a specific process. |
| However, the pointer is quite likely to be invalid in the context of a second |
| process and trying to dereference the pointer from the second process may |
| cause a crash. |
| |
| .. function:: RawArray(typecode_or_type, size_or_initializer) |
| |
| Return a ctypes array allocated from shared memory. |
| |
| *typecode_or_type* determines the type of the elements of the returned array: |
| it is either a ctypes type or a one character typecode of the kind used by |
| the :mod:`array` module. If *size_or_initializer* is an integer then it |
| determines the length of the array, and the array will be initially zeroed. |
| Otherwise *size_or_initializer* is a sequence which is used to initialize the |
| array and whose length determines the length of the array. |
| |
| Note that setting and getting an element is potentially non-atomic -- use |
| :func:`Array` instead to make sure that access is automatically synchronized |
| using a lock. |
| |
| .. function:: RawValue(typecode_or_type, *args) |
| |
| Return a ctypes object allocated from shared memory. |
| |
| *typecode_or_type* determines the type of the returned object: it is either a |
| ctypes type or a one character typecode of the kind used by the :mod:`array` |
| module. *\*args* is passed on to the constructor for the type. |
| |
| Note that setting and getting the value is potentially non-atomic -- use |
| :func:`Value` instead to make sure that access is automatically synchronized |
| using a lock. |
| |
| Note that an array of :data:`ctypes.c_char` has ``value`` and ``raw`` |
| attributes which allow one to use it to store and retrieve strings -- see |
| documentation for :mod:`ctypes`. |
| |
| .. function:: Array(typecode_or_type, size_or_initializer, *, lock=True) |
| |
| The same as :func:`RawArray` except that depending on the value of *lock* a |
| process-safe synchronization wrapper may be returned instead of a raw ctypes |
| array. |
| |
| If *lock* is ``True`` (the default) then a new lock object is created to |
| synchronize access to the value. If *lock* is a |
| :class:`~multiprocessing.Lock` or :class:`~multiprocessing.RLock` object |
| then that will be used to synchronize access to the |
| value. If *lock* is ``False`` then access to the returned object will not be |
| automatically protected by a lock, so it will not necessarily be |
| "process-safe". |
| |
| Note that *lock* is a keyword-only argument. |
| |
| .. function:: Value(typecode_or_type, *args, lock=True) |
| |
| The same as :func:`RawValue` except that depending on the value of *lock* a |
| process-safe synchronization wrapper may be returned instead of a raw ctypes |
| object. |
| |
| If *lock* is ``True`` (the default) then a new lock object is created to |
| synchronize access to the value. If *lock* is a :class:`~multiprocessing.Lock` or |
| :class:`~multiprocessing.RLock` object then that will be used to synchronize access to the |
| value. If *lock* is ``False`` then access to the returned object will not be |
| automatically protected by a lock, so it will not necessarily be |
| "process-safe". |
| |
| Note that *lock* is a keyword-only argument. |
| |
| .. function:: copy(obj) |
| |
| Return a ctypes object allocated from shared memory which is a copy of the |
| ctypes object *obj*. |
| |
| .. function:: synchronized(obj[, lock]) |
| |
| Return a process-safe wrapper object for a ctypes object which uses *lock* to |
| synchronize access. If *lock* is ``None`` (the default) then a |
| :class:`multiprocessing.RLock` object is created automatically. |
| |
| A synchronized wrapper will have two methods in addition to those of the |
| object it wraps: :meth:`get_obj` returns the wrapped object and |
| :meth:`get_lock` returns the lock object used for synchronization. |
| |
| Note that accessing the ctypes object through the wrapper can be a lot slower |
| than accessing the raw ctypes object. |
| |
| .. versionchanged:: 3.5 |
| Synchronized objects support the :term:`context manager` protocol. |
| |
| |
| The table below compares the syntax for creating shared ctypes objects from |
| shared memory with the normal ctypes syntax. (In the table ``MyStruct`` is some |
| subclass of :class:`ctypes.Structure`.) |
| |
| ==================== ========================== =========================== |
| ctypes sharedctypes using type sharedctypes using typecode |
| ==================== ========================== =========================== |
| c_double(2.4) RawValue(c_double, 2.4) RawValue('d', 2.4) |
| MyStruct(4, 6) RawValue(MyStruct, 4, 6) |
| (c_short * 7)() RawArray(c_short, 7) RawArray('h', 7) |
| (c_int * 3)(9, 2, 8) RawArray(c_int, (9, 2, 8)) RawArray('i', (9, 2, 8)) |
| ==================== ========================== =========================== |
| |
| |
| Below is an example where a number of ctypes objects are modified by a child |
| process:: |
| |
| from multiprocessing import Process, Lock |
| from multiprocessing.sharedctypes import Value, Array |
| from ctypes import Structure, c_double |
| |
| class Point(Structure): |
| _fields_ = [('x', c_double), ('y', c_double)] |
| |
| def modify(n, x, s, A): |
| n.value **= 2 |
| x.value **= 2 |
| s.value = s.value.upper() |
| for a in A: |
| a.x **= 2 |
| a.y **= 2 |
| |
| if __name__ == '__main__': |
| lock = Lock() |
| |
| n = Value('i', 7) |
| x = Value(c_double, 1.0/3.0, lock=False) |
| s = Array('c', b'hello world', lock=lock) |
| A = Array(Point, [(1.875,-6.25), (-5.75,2.0), (2.375,9.5)], lock=lock) |
| |
| p = Process(target=modify, args=(n, x, s, A)) |
| p.start() |
| p.join() |
| |
| print(n.value) |
| print(x.value) |
| print(s.value) |
| print([(a.x, a.y) for a in A]) |
| |
| |
| .. highlight:: none |
| |
| The results printed are :: |
| |
| 49 |
| 0.1111111111111111 |
| HELLO WORLD |
| [(3.515625, 39.0625), (33.0625, 4.0), (5.640625, 90.25)] |
| |
| .. highlight:: python3 |
| |
| |
| .. _multiprocessing-managers: |
| |
| Managers |
| ~~~~~~~~ |
| |
| Managers provide a way to create data which can be shared between different |
| processes, including sharing over a network between processes running on |
| different machines. A manager object controls a server process which manages |
| *shared objects*. Other processes can access the shared objects by using |
| proxies. |
| |
| .. function:: multiprocessing.Manager() |
| |
| Returns a started :class:`~multiprocessing.managers.SyncManager` object which |
| can be used for sharing objects between processes. The returned manager |
| object corresponds to a spawned child process and has methods which will |
| create shared objects and return corresponding proxies. |
| |
| .. module:: multiprocessing.managers |
| :synopsis: Share data between process with shared objects. |
| |
| Manager processes will be shutdown as soon as they are garbage collected or |
| their parent process exits. The manager classes are defined in the |
| :mod:`multiprocessing.managers` module: |
| |
| .. class:: BaseManager([address[, authkey]]) |
| |
| Create a BaseManager object. |
| |
| Once created one should call :meth:`start` or ``get_server().serve_forever()`` to ensure |
| that the manager object refers to a started manager process. |
| |
| *address* is the address on which the manager process listens for new |
| connections. If *address* is ``None`` then an arbitrary one is chosen. |
| |
| *authkey* is the authentication key which will be used to check the |
| validity of incoming connections to the server process. If |
| *authkey* is ``None`` then ``current_process().authkey`` is used. |
| Otherwise *authkey* is used and it must be a byte string. |
| |
| .. method:: start([initializer[, initargs]]) |
| |
| Start a subprocess to start the manager. If *initializer* is not ``None`` |
| then the subprocess will call ``initializer(*initargs)`` when it starts. |
| |
| .. method:: get_server() |
| |
| Returns a :class:`Server` object which represents the actual server under |
| the control of the Manager. The :class:`Server` object supports the |
| :meth:`serve_forever` method:: |
| |
| >>> from multiprocessing.managers import BaseManager |
| >>> manager = BaseManager(address=('', 50000), authkey=b'abc') |
| >>> server = manager.get_server() |
| >>> server.serve_forever() |
| |
| :class:`Server` additionally has an :attr:`address` attribute. |
| |
| .. method:: connect() |
| |
| Connect a local manager object to a remote manager process:: |
| |
| >>> from multiprocessing.managers import BaseManager |
| >>> m = BaseManager(address=('127.0.0.1', 5000), authkey=b'abc') |
| >>> m.connect() |
| |
| .. method:: shutdown() |
| |
| Stop the process used by the manager. This is only available if |
| :meth:`start` has been used to start the server process. |
| |
| This can be called multiple times. |
| |
| .. method:: register(typeid[, callable[, proxytype[, exposed[, method_to_typeid[, create_method]]]]]) |
| |
| A classmethod which can be used for registering a type or callable with |
| the manager class. |
| |
| *typeid* is a "type identifier" which is used to identify a particular |
| type of shared object. This must be a string. |
| |
| *callable* is a callable used for creating objects for this type |
| identifier. If a manager instance will be connected to the |
| server using the :meth:`connect` method, or if the |
| *create_method* argument is ``False`` then this can be left as |
| ``None``. |
| |
| *proxytype* is a subclass of :class:`BaseProxy` which is used to create |
| proxies for shared objects with this *typeid*. If ``None`` then a proxy |
| class is created automatically. |
| |
| *exposed* is used to specify a sequence of method names which proxies for |
| this typeid should be allowed to access using |
| :meth:`BaseProxy._callmethod`. (If *exposed* is ``None`` then |
| :attr:`proxytype._exposed_` is used instead if it exists.) In the case |
| where no exposed list is specified, all "public methods" of the shared |
| object will be accessible. (Here a "public method" means any attribute |
| which has a :meth:`~object.__call__` method and whose name does not begin |
| with ``'_'``.) |
| |
| *method_to_typeid* is a mapping used to specify the return type of those |
| exposed methods which should return a proxy. It maps method names to |
| typeid strings. (If *method_to_typeid* is ``None`` then |
| :attr:`proxytype._method_to_typeid_` is used instead if it exists.) If a |
| method's name is not a key of this mapping or if the mapping is ``None`` |
| then the object returned by the method will be copied by value. |
| |
| *create_method* determines whether a method should be created with name |
| *typeid* which can be used to tell the server process to create a new |
| shared object and return a proxy for it. By default it is ``True``. |
| |
| :class:`BaseManager` instances also have one read-only property: |
| |
| .. attribute:: address |
| |
| The address used by the manager. |
| |
| .. versionchanged:: 3.3 |
| Manager objects support the context management protocol -- see |
| :ref:`typecontextmanager`. :meth:`~contextmanager.__enter__` starts the |
| server process (if it has not already started) and then returns the |
| manager object. :meth:`~contextmanager.__exit__` calls :meth:`shutdown`. |
| |
| In previous versions :meth:`~contextmanager.__enter__` did not start the |
| manager's server process if it was not already started. |
| |
| .. class:: SyncManager |
| |
| A subclass of :class:`BaseManager` which can be used for the synchronization |
| of processes. Objects of this type are returned by |
| :func:`multiprocessing.Manager`. |
| |
| It also supports creation of shared lists and dictionaries. |
| |
| .. method:: Barrier(parties[, action[, timeout]]) |
| |
| Create a shared :class:`threading.Barrier` object and return a |
| proxy for it. |
| |
| .. versionadded:: 3.3 |
| |
| .. method:: BoundedSemaphore([value]) |
| |
| Create a shared :class:`threading.BoundedSemaphore` object and return a |
| proxy for it. |
| |
| .. method:: Condition([lock]) |
| |
| Create a shared :class:`threading.Condition` object and return a proxy for |
| it. |
| |
| If *lock* is supplied then it should be a proxy for a |
| :class:`threading.Lock` or :class:`threading.RLock` object. |
| |
| .. versionchanged:: 3.3 |
| The :meth:`~threading.Condition.wait_for` method was added. |
| |
| .. method:: Event() |
| |
| Create a shared :class:`threading.Event` object and return a proxy for it. |
| |
| .. method:: Lock() |
| |
| Create a shared :class:`threading.Lock` object and return a proxy for it. |
| |
| .. method:: Namespace() |
| |
| Create a shared :class:`Namespace` object and return a proxy for it. |
| |
| .. method:: Queue([maxsize]) |
| |
| Create a shared :class:`queue.Queue` object and return a proxy for it. |
| |
| .. method:: RLock() |
| |
| Create a shared :class:`threading.RLock` object and return a proxy for it. |
| |
| .. method:: Semaphore([value]) |
| |
| Create a shared :class:`threading.Semaphore` object and return a proxy for |
| it. |
| |
| .. method:: Array(typecode, sequence) |
| |
| Create an array and return a proxy for it. |
| |
| .. method:: Value(typecode, value) |
| |
| Create an object with a writable ``value`` attribute and return a proxy |
| for it. |
| |
| .. method:: dict() |
| dict(mapping) |
| dict(sequence) |
| |
| Create a shared ``dict`` object and return a proxy for it. |
| |
| .. method:: list() |
| list(sequence) |
| |
| Create a shared ``list`` object and return a proxy for it. |
| |
| .. note:: |
| |
| Modifications to mutable values or items in dict and list proxies will not |
| be propagated through the manager, because the proxy has no way of knowing |
| when its values or items are modified. To modify such an item, you can |
| re-assign the modified object to the container proxy:: |
| |
| # create a list proxy and append a mutable object (a dictionary) |
| lproxy = manager.list() |
| lproxy.append({}) |
| # now mutate the dictionary |
| d = lproxy[0] |
| d['a'] = 1 |
| d['b'] = 2 |
| # at this point, the changes to d are not yet synced, but by |
| # reassigning the dictionary, the proxy is notified of the change |
| lproxy[0] = d |
| |
| |
| Namespace objects |
| >>>>>>>>>>>>>>>>> |
| |
| A namespace object has no public methods, but does have writable attributes. |
| Its representation shows the values of its attributes. |
| |
| However, when using a proxy for a namespace object, an attribute beginning with |
| ``'_'`` will be an attribute of the proxy and not an attribute of the referent: |
| |
| .. doctest:: |
| |
| >>> manager = multiprocessing.Manager() |
| >>> Global = manager.Namespace() |
| >>> Global.x = 10 |
| >>> Global.y = 'hello' |
| >>> Global._z = 12.3 # this is an attribute of the proxy |
| >>> print(Global) |
| Namespace(x=10, y='hello') |
| |
| |
| Customized managers |
| >>>>>>>>>>>>>>>>>>> |
| |
| To create one's own manager, one creates a subclass of :class:`BaseManager` and |
| uses the :meth:`~BaseManager.register` classmethod to register new types or |
| callables with the manager class. For example:: |
| |
| from multiprocessing.managers import BaseManager |
| |
| class MathsClass: |
| def add(self, x, y): |
| return x + y |
| def mul(self, x, y): |
| return x * y |
| |
| class MyManager(BaseManager): |
| pass |
| |
| MyManager.register('Maths', MathsClass) |
| |
| if __name__ == '__main__': |
| with MyManager() as manager: |
| maths = manager.Maths() |
| print(maths.add(4, 3)) # prints 7 |
| print(maths.mul(7, 8)) # prints 56 |
| |
| |
| Using a remote manager |
| >>>>>>>>>>>>>>>>>>>>>> |
| |
| It is possible to run a manager server on one machine and have clients use it |
| from other machines (assuming that the firewalls involved allow it). |
| |
| Running the following commands creates a server for a single shared queue which |
| remote clients can access:: |
| |
| >>> from multiprocessing.managers import BaseManager |
| >>> import queue |
| >>> queue = queue.Queue() |
| >>> class QueueManager(BaseManager): pass |
| >>> QueueManager.register('get_queue', callable=lambda:queue) |
| >>> m = QueueManager(address=('', 50000), authkey=b'abracadabra') |
| >>> s = m.get_server() |
| >>> s.serve_forever() |
| |
| One client can access the server as follows:: |
| |
| >>> from multiprocessing.managers import BaseManager |
| >>> class QueueManager(BaseManager): pass |
| >>> QueueManager.register('get_queue') |
| >>> m = QueueManager(address=('foo.bar.org', 50000), authkey=b'abracadabra') |
| >>> m.connect() |
| >>> queue = m.get_queue() |
| >>> queue.put('hello') |
| |
| Another client can also use it:: |
| |
| >>> from multiprocessing.managers import BaseManager |
| >>> class QueueManager(BaseManager): pass |
| >>> QueueManager.register('get_queue') |
| >>> m = QueueManager(address=('foo.bar.org', 50000), authkey=b'abracadabra') |
| >>> m.connect() |
| >>> queue = m.get_queue() |
| >>> queue.get() |
| 'hello' |
| |
| Local processes can also access that queue, using the code from above on the |
| client to access it remotely:: |
| |
| >>> from multiprocessing import Process, Queue |
| >>> from multiprocessing.managers import BaseManager |
| >>> class Worker(Process): |
| ... def __init__(self, q): |
| ... self.q = q |
| ... super(Worker, self).__init__() |
| ... def run(self): |
| ... self.q.put('local hello') |
| ... |
| >>> queue = Queue() |
| >>> w = Worker(queue) |
| >>> w.start() |
| >>> class QueueManager(BaseManager): pass |
| ... |
| >>> QueueManager.register('get_queue', callable=lambda: queue) |
| >>> m = QueueManager(address=('', 50000), authkey=b'abracadabra') |
| >>> s = m.get_server() |
| >>> s.serve_forever() |
| |
| Proxy Objects |
| ~~~~~~~~~~~~~ |
| |
| A proxy is an object which *refers* to a shared object which lives (presumably) |
| in a different process. The shared object is said to be the *referent* of the |
| proxy. Multiple proxy objects may have the same referent. |
| |
| A proxy object has methods which invoke corresponding methods of its referent |
| (although not every method of the referent will necessarily be available through |
| the proxy). A proxy can usually be used in most of the same ways that its |
| referent can: |
| |
| .. doctest:: |
| |
| >>> from multiprocessing import Manager |
| >>> manager = Manager() |
| >>> l = manager.list([i*i for i in range(10)]) |
| >>> print(l) |
| [0, 1, 4, 9, 16, 25, 36, 49, 64, 81] |
| >>> print(repr(l)) |
| <ListProxy object, typeid 'list' at 0x...> |
| >>> l[4] |
| 16 |
| >>> l[2:5] |
| [4, 9, 16] |
| |
| Notice that applying :func:`str` to a proxy will return the representation of |
| the referent, whereas applying :func:`repr` will return the representation of |
| the proxy. |
| |
| An important feature of proxy objects is that they are picklable so they can be |
| passed between processes. Note, however, that if a proxy is sent to the |
| corresponding manager's process then unpickling it will produce the referent |
| itself. This means, for example, that one shared object can contain a second: |
| |
| .. doctest:: |
| |
| >>> a = manager.list() |
| >>> b = manager.list() |
| >>> a.append(b) # referent of a now contains referent of b |
| >>> print(a, b) |
| [[]] [] |
| >>> b.append('hello') |
| >>> print(a, b) |
| [['hello']] ['hello'] |
| |
| .. note:: |
| |
| The proxy types in :mod:`multiprocessing` do nothing to support comparisons |
| by value. So, for instance, we have: |
| |
| .. doctest:: |
| |
| >>> manager.list([1,2,3]) == [1,2,3] |
| False |
| |
| One should just use a copy of the referent instead when making comparisons. |
| |
| .. class:: BaseProxy |
| |
| Proxy objects are instances of subclasses of :class:`BaseProxy`. |
| |
| .. method:: _callmethod(methodname[, args[, kwds]]) |
| |
| Call and return the result of a method of the proxy's referent. |
| |
| If ``proxy`` is a proxy whose referent is ``obj`` then the expression :: |
| |
| proxy._callmethod(methodname, args, kwds) |
| |
| will evaluate the expression :: |
| |
| getattr(obj, methodname)(*args, **kwds) |
| |
| in the manager's process. |
| |
| The returned value will be a copy of the result of the call or a proxy to |
| a new shared object -- see documentation for the *method_to_typeid* |
| argument of :meth:`BaseManager.register`. |
| |
| If an exception is raised by the call, then is re-raised by |
| :meth:`_callmethod`. If some other exception is raised in the manager's |
| process then this is converted into a :exc:`RemoteError` exception and is |
| raised by :meth:`_callmethod`. |
| |
| Note in particular that an exception will be raised if *methodname* has |
| not been *exposed* |
| |
| An example of the usage of :meth:`_callmethod`: |
| |
| .. doctest:: |
| |
| >>> l = manager.list(range(10)) |
| >>> l._callmethod('__len__') |
| 10 |
| >>> l._callmethod('__getitem__', (slice(2, 7),)) # equivalent to l[2:7] |
| [2, 3, 4, 5, 6] |
| >>> l._callmethod('__getitem__', (20,)) # equivalent to l[20] |
| Traceback (most recent call last): |
| ... |
| IndexError: list index out of range |
| |
| .. method:: _getvalue() |
| |
| Return a copy of the referent. |
| |
| If the referent is unpicklable then this will raise an exception. |
| |
| .. method:: __repr__ |
| |
| Return a representation of the proxy object. |
| |
| .. method:: __str__ |
| |
| Return the representation of the referent. |
| |
| |
| Cleanup |
| >>>>>>> |
| |
| A proxy object uses a weakref callback so that when it gets garbage collected it |
| deregisters itself from the manager which owns its referent. |
| |
| A shared object gets deleted from the manager process when there are no longer |
| any proxies referring to it. |
| |
| |
| Process Pools |
| ~~~~~~~~~~~~~ |
| |
| .. module:: multiprocessing.pool |
| :synopsis: Create pools of processes. |
| |
| One can create a pool of processes which will carry out tasks submitted to it |
| with the :class:`Pool` class. |
| |
| .. class:: Pool([processes[, initializer[, initargs[, maxtasksperchild [, context]]]]]) |
| |
| A process pool object which controls a pool of worker processes to which jobs |
| can be submitted. It supports asynchronous results with timeouts and |
| callbacks and has a parallel map implementation. |
| |
| *processes* is the number of worker processes to use. If *processes* is |
| ``None`` then the number returned by :func:`os.cpu_count` is used. |
| |
| If *initializer* is not ``None`` then each worker process will call |
| ``initializer(*initargs)`` when it starts. |
| |
| *maxtasksperchild* is the number of tasks a worker process can complete |
| before it will exit and be replaced with a fresh worker process, to enable |
| unused resources to be freed. The default *maxtasksperchild* is None, which |
| means worker processes will live as long as the pool. |
| |
| *context* can be used to specify the context used for starting |
| the worker processes. Usually a pool is created using the |
| function :func:`multiprocessing.Pool` or the :meth:`Pool` method |
| of a context object. In both cases *context* is set |
| appropriately. |
| |
| Note that the methods of the pool object should only be called by |
| the process which created the pool. |
| |
| .. versionadded:: 3.2 |
| *maxtasksperchild* |
| |
| .. versionadded:: 3.4 |
| *context* |
| |
| .. note:: |
| |
| Worker processes within a :class:`Pool` typically live for the complete |
| duration of the Pool's work queue. A frequent pattern found in other |
| systems (such as Apache, mod_wsgi, etc) to free resources held by |
| workers is to allow a worker within a pool to complete only a set |
| amount of work before being exiting, being cleaned up and a new |
| process spawned to replace the old one. The *maxtasksperchild* |
| argument to the :class:`Pool` exposes this ability to the end user. |
| |
| .. method:: apply(func[, args[, kwds]]) |
| |
| Call *func* with arguments *args* and keyword arguments *kwds*. It blocks |
| until the result is ready. Given this blocks, :meth:`apply_async` is |
| better suited for performing work in parallel. Additionally, *func* |
| is only executed in one of the workers of the pool. |
| |
| .. method:: apply_async(func[, args[, kwds[, callback[, error_callback]]]]) |
| |
| A variant of the :meth:`apply` method which returns a result object. |
| |
| If *callback* is specified then it should be a callable which accepts a |
| single argument. When the result becomes ready *callback* is applied to |
| it, that is unless the call failed, in which case the *error_callback* |
| is applied instead |
| |
| If *error_callback* is specified then it should be a callable which |
| accepts a single argument. If the target function fails, then |
| the *error_callback* is called with the exception instance. |
| |
| Callbacks should complete immediately since otherwise the thread which |
| handles the results will get blocked. |
| |
| .. method:: map(func, iterable[, chunksize]) |
| |
| A parallel equivalent of the :func:`map` built-in function (it supports only |
| one *iterable* argument though). It blocks until the result is ready. |
| |
| This method chops the iterable into a number of chunks which it submits to |
| the process pool as separate tasks. The (approximate) size of these |
| chunks can be specified by setting *chunksize* to a positive integer. |
| |
| .. method:: map_async(func, iterable[, chunksize[, callback[, error_callback]]]) |
| |
| A variant of the :meth:`.map` method which returns a result object. |
| |
| If *callback* is specified then it should be a callable which accepts a |
| single argument. When the result becomes ready *callback* is applied to |
| it, that is unless the call failed, in which case the *error_callback* |
| is applied instead |
| |
| If *error_callback* is specified then it should be a callable which |
| accepts a single argument. If the target function fails, then |
| the *error_callback* is called with the exception instance. |
| |
| Callbacks should complete immediately since otherwise the thread which |
| handles the results will get blocked. |
| |
| .. method:: imap(func, iterable[, chunksize]) |
| |
| A lazier version of :meth:`map`. |
| |
| The *chunksize* argument is the same as the one used by the :meth:`.map` |
| method. For very long iterables using a large value for *chunksize* can |
| make the job complete **much** faster than using the default value of |
| ``1``. |
| |
| Also if *chunksize* is ``1`` then the :meth:`!next` method of the iterator |
| returned by the :meth:`imap` method has an optional *timeout* parameter: |
| ``next(timeout)`` will raise :exc:`multiprocessing.TimeoutError` if the |
| result cannot be returned within *timeout* seconds. |
| |
| .. method:: imap_unordered(func, iterable[, chunksize]) |
| |
| The same as :meth:`imap` except that the ordering of the results from the |
| returned iterator should be considered arbitrary. (Only when there is |
| only one worker process is the order guaranteed to be "correct".) |
| |
| .. method:: starmap(func, iterable[, chunksize]) |
| |
| Like :meth:`map` except that the elements of the *iterable* are expected |
| to be iterables that are unpacked as arguments. |
| |
| Hence an *iterable* of ``[(1,2), (3, 4)]`` results in ``[func(1,2), |
| func(3,4)]``. |
| |
| .. versionadded:: 3.3 |
| |
| .. method:: starmap_async(func, iterable[, chunksize[, callback[, error_back]]]) |
| |
| A combination of :meth:`starmap` and :meth:`map_async` that iterates over |
| *iterable* of iterables and calls *func* with the iterables unpacked. |
| Returns a result object. |
| |
| .. versionadded:: 3.3 |
| |
| .. method:: close() |
| |
| Prevents any more tasks from being submitted to the pool. Once all the |
| tasks have been completed the worker processes will exit. |
| |
| .. method:: terminate() |
| |
| Stops the worker processes immediately without completing outstanding |
| work. When the pool object is garbage collected :meth:`terminate` will be |
| called immediately. |
| |
| .. method:: join() |
| |
| Wait for the worker processes to exit. One must call :meth:`close` or |
| :meth:`terminate` before using :meth:`join`. |
| |
| .. versionadded:: 3.3 |
| Pool objects now support the context management protocol -- see |
| :ref:`typecontextmanager`. :meth:`~contextmanager.__enter__` returns the |
| pool object, and :meth:`~contextmanager.__exit__` calls :meth:`terminate`. |
| |
| |
| .. class:: AsyncResult |
| |
| The class of the result returned by :meth:`Pool.apply_async` and |
| :meth:`Pool.map_async`. |
| |
| .. method:: get([timeout]) |
| |
| Return the result when it arrives. If *timeout* is not ``None`` and the |
| result does not arrive within *timeout* seconds then |
| :exc:`multiprocessing.TimeoutError` is raised. If the remote call raised |
| an exception then that exception will be reraised by :meth:`get`. |
| |
| .. method:: wait([timeout]) |
| |
| Wait until the result is available or until *timeout* seconds pass. |
| |
| .. method:: ready() |
| |
| Return whether the call has completed. |
| |
| .. method:: successful() |
| |
| Return whether the call completed without raising an exception. Will |
| raise :exc:`AssertionError` if the result is not ready. |
| |
| The following example demonstrates the use of a pool:: |
| |
| from multiprocessing import Pool |
| |
| def f(x): |
| return x*x |
| |
| if __name__ == '__main__': |
| with Pool(processes=4) as pool: # start 4 worker processes |
| result = pool.apply_async(f, (10,)) # evaluate "f(10)" asynchronously |
| print(result.get(timeout=1)) # prints "100" unless your computer is *very* slow |
| |
| print(pool.map(f, range(10))) # prints "[0, 1, 4,..., 81]" |
| |
| it = pool.imap(f, range(10)) |
| print(next(it)) # prints "0" |
| print(next(it)) # prints "1" |
| print(it.next(timeout=1)) # prints "4" unless your computer is *very* slow |
| |
| import time |
| result = pool.apply_async(time.sleep, (10,)) |
| print(result.get(timeout=1)) # raises TimeoutError |
| |
| |
| .. _multiprocessing-listeners-clients: |
| |
| Listeners and Clients |
| ~~~~~~~~~~~~~~~~~~~~~ |
| |
| .. module:: multiprocessing.connection |
| :synopsis: API for dealing with sockets. |
| |
| Usually message passing between processes is done using queues or by using |
| :class:`~multiprocessing.Connection` objects returned by |
| :func:`~multiprocessing.Pipe`. |
| |
| However, the :mod:`multiprocessing.connection` module allows some extra |
| flexibility. It basically gives a high level message oriented API for dealing |
| with sockets or Windows named pipes. It also has support for *digest |
| authentication* using the :mod:`hmac` module, and for polling |
| multiple connections at the same time. |
| |
| |
| .. function:: deliver_challenge(connection, authkey) |
| |
| Send a randomly generated message to the other end of the connection and wait |
| for a reply. |
| |
| If the reply matches the digest of the message using *authkey* as the key |
| then a welcome message is sent to the other end of the connection. Otherwise |
| :exc:`~multiprocessing.AuthenticationError` is raised. |
| |
| .. function:: answer_challenge(connection, authkey) |
| |
| Receive a message, calculate the digest of the message using *authkey* as the |
| key, and then send the digest back. |
| |
| If a welcome message is not received, then |
| :exc:`~multiprocessing.AuthenticationError` is raised. |
| |
| .. function:: Client(address[, family[, authenticate[, authkey]]]) |
| |
| Attempt to set up a connection to the listener which is using address |
| *address*, returning a :class:`~multiprocessing.Connection`. |
| |
| The type of the connection is determined by *family* argument, but this can |
| generally be omitted since it can usually be inferred from the format of |
| *address*. (See :ref:`multiprocessing-address-formats`) |
| |
| If *authenticate* is ``True`` or *authkey* is a byte string then digest |
| authentication is used. The key used for authentication will be either |
| *authkey* or ``current_process().authkey`` if *authkey* is ``None``. |
| If authentication fails then |
| :exc:`~multiprocessing.AuthenticationError` is raised. See |
| :ref:`multiprocessing-auth-keys`. |
| |
| .. class:: Listener([address[, family[, backlog[, authenticate[, authkey]]]]]) |
| |
| A wrapper for a bound socket or Windows named pipe which is 'listening' for |
| connections. |
| |
| *address* is the address to be used by the bound socket or named pipe of the |
| listener object. |
| |
| .. note:: |
| |
| If an address of '0.0.0.0' is used, the address will not be a connectable |
| end point on Windows. If you require a connectable end-point, |
| you should use '127.0.0.1'. |
| |
| *family* is the type of socket (or named pipe) to use. This can be one of |
| the strings ``'AF_INET'`` (for a TCP socket), ``'AF_UNIX'`` (for a Unix |
| domain socket) or ``'AF_PIPE'`` (for a Windows named pipe). Of these only |
| the first is guaranteed to be available. If *family* is ``None`` then the |
| family is inferred from the format of *address*. If *address* is also |
| ``None`` then a default is chosen. This default is the family which is |
| assumed to be the fastest available. See |
| :ref:`multiprocessing-address-formats`. Note that if *family* is |
| ``'AF_UNIX'`` and address is ``None`` then the socket will be created in a |
| private temporary directory created using :func:`tempfile.mkstemp`. |
| |
| If the listener object uses a socket then *backlog* (1 by default) is passed |
| to the :meth:`~socket.socket.listen` method of the socket once it has been |
| bound. |
| |
| If *authenticate* is ``True`` (``False`` by default) or *authkey* is not |
| ``None`` then digest authentication is used. |
| |
| If *authkey* is a byte string then it will be used as the |
| authentication key; otherwise it must be *None*. |
| |
| If *authkey* is ``None`` and *authenticate* is ``True`` then |
| ``current_process().authkey`` is used as the authentication key. If |
| *authkey* is ``None`` and *authenticate* is ``False`` then no |
| authentication is done. If authentication fails then |
| :exc:`~multiprocessing.AuthenticationError` is raised. |
| See :ref:`multiprocessing-auth-keys`. |
| |
| .. method:: accept() |
| |
| Accept a connection on the bound socket or named pipe of the listener |
| object and return a :class:`~multiprocessing.Connection` object. If |
| authentication is attempted and fails, then |
| :exc:`~multiprocessing.AuthenticationError` is raised. |
| |
| .. method:: close() |
| |
| Close the bound socket or named pipe of the listener object. This is |
| called automatically when the listener is garbage collected. However it |
| is advisable to call it explicitly. |
| |
| Listener objects have the following read-only properties: |
| |
| .. attribute:: address |
| |
| The address which is being used by the Listener object. |
| |
| .. attribute:: last_accepted |
| |
| The address from which the last accepted connection came. If this is |
| unavailable then it is ``None``. |
| |
| .. versionadded:: 3.3 |
| Listener objects now support the context management protocol -- see |
| :ref:`typecontextmanager`. :meth:`~contextmanager.__enter__` returns the |
| listener object, and :meth:`~contextmanager.__exit__` calls :meth:`close`. |
| |
| .. function:: wait(object_list, timeout=None) |
| |
| Wait till an object in *object_list* is ready. Returns the list of |
| those objects in *object_list* which are ready. If *timeout* is a |
| float then the call blocks for at most that many seconds. If |
| *timeout* is ``None`` then it will block for an unlimited period. |
| A negative timeout is equivalent to a zero timeout. |
| |
| For both Unix and Windows, an object can appear in *object_list* if |
| it is |
| |
| * a readable :class:`~multiprocessing.Connection` object; |
| * a connected and readable :class:`socket.socket` object; or |
| * the :attr:`~multiprocessing.Process.sentinel` attribute of a |
| :class:`~multiprocessing.Process` object. |
| |
| A connection or socket object is ready when there is data available |
| to be read from it, or the other end has been closed. |
| |
| **Unix**: ``wait(object_list, timeout)`` almost equivalent |
| ``select.select(object_list, [], [], timeout)``. The difference is |
| that, if :func:`select.select` is interrupted by a signal, it can |
| raise :exc:`OSError` with an error number of ``EINTR``, whereas |
| :func:`wait` will not. |
| |
| **Windows**: An item in *object_list* must either be an integer |
| handle which is waitable (according to the definition used by the |
| documentation of the Win32 function ``WaitForMultipleObjects()``) |
| or it can be an object with a :meth:`fileno` method which returns a |
| socket handle or pipe handle. (Note that pipe handles and socket |
| handles are **not** waitable handles.) |
| |
| .. versionadded:: 3.3 |
| |
| |
| **Examples** |
| |
| The following server code creates a listener which uses ``'secret password'`` as |
| an authentication key. It then waits for a connection and sends some data to |
| the client:: |
| |
| from multiprocessing.connection import Listener |
| from array import array |
| |
| address = ('localhost', 6000) # family is deduced to be 'AF_INET' |
| |
| with Listener(address, authkey=b'secret password') as listener: |
| with listener.accept() as conn: |
| print('connection accepted from', listener.last_accepted) |
| |
| conn.send([2.25, None, 'junk', float]) |
| |
| conn.send_bytes(b'hello') |
| |
| conn.send_bytes(array('i', [42, 1729])) |
| |
| The following code connects to the server and receives some data from the |
| server:: |
| |
| from multiprocessing.connection import Client |
| from array import array |
| |
| address = ('localhost', 6000) |
| |
| with Client(address, authkey=b'secret password') as conn: |
| print(conn.recv()) # => [2.25, None, 'junk', float] |
| |
| print(conn.recv_bytes()) # => 'hello' |
| |
| arr = array('i', [0, 0, 0, 0, 0]) |
| print(conn.recv_bytes_into(arr)) # => 8 |
| print(arr) # => array('i', [42, 1729, 0, 0, 0]) |
| |
| The following code uses :func:`~multiprocessing.connection.wait` to |
| wait for messages from multiple processes at once:: |
| |
| import time, random |
| from multiprocessing import Process, Pipe, current_process |
| from multiprocessing.connection import wait |
| |
| def foo(w): |
| for i in range(10): |
| w.send((i, current_process().name)) |
| w.close() |
| |
| if __name__ == '__main__': |
| readers = [] |
| |
| for i in range(4): |
| r, w = Pipe(duplex=False) |
| readers.append(r) |
| p = Process(target=foo, args=(w,)) |
| p.start() |
| # We close the writable end of the pipe now to be sure that |
| # p is the only process which owns a handle for it. This |
| # ensures that when p closes its handle for the writable end, |
| # wait() will promptly report the readable end as being ready. |
| w.close() |
| |
| while readers: |
| for r in wait(readers): |
| try: |
| msg = r.recv() |
| except EOFError: |
| readers.remove(r) |
| else: |
| print(msg) |
| |
| |
| .. _multiprocessing-address-formats: |
| |
| Address Formats |
| >>>>>>>>>>>>>>> |
| |
| * An ``'AF_INET'`` address is a tuple of the form ``(hostname, port)`` where |
| *hostname* is a string and *port* is an integer. |
| |
| * An ``'AF_UNIX'`` address is a string representing a filename on the |
| filesystem. |
| |
| * An ``'AF_PIPE'`` address is a string of the form |
| :samp:`r'\\\\.\\pipe\\{PipeName}'`. To use :func:`Client` to connect to a named |
| pipe on a remote computer called *ServerName* one should use an address of the |
| form :samp:`r'\\\\{ServerName}\\pipe\\{PipeName}'` instead. |
| |
| Note that any string beginning with two backslashes is assumed by default to be |
| an ``'AF_PIPE'`` address rather than an ``'AF_UNIX'`` address. |
| |
| |
| .. _multiprocessing-auth-keys: |
| |
| Authentication keys |
| ~~~~~~~~~~~~~~~~~~~ |
| |
| When one uses :meth:`Connection.recv <multiprocessing.Connection.recv>`, the |
| data received is automatically |
| unpickled. Unfortunately unpickling data from an untrusted source is a security |
| risk. Therefore :class:`Listener` and :func:`Client` use the :mod:`hmac` module |
| to provide digest authentication. |
| |
| An authentication key is a byte string which can be thought of as a |
| password: once a connection is established both ends will demand proof |
| that the other knows the authentication key. (Demonstrating that both |
| ends are using the same key does **not** involve sending the key over |
| the connection.) |
| |
| If authentication is requested but no authentication key is specified then the |
| return value of ``current_process().authkey`` is used (see |
| :class:`~multiprocessing.Process`). This value will automatically inherited by |
| any :class:`~multiprocessing.Process` object that the current process creates. |
| This means that (by default) all processes of a multi-process program will share |
| a single authentication key which can be used when setting up connections |
| between themselves. |
| |
| Suitable authentication keys can also be generated by using :func:`os.urandom`. |
| |
| |
| Logging |
| ~~~~~~~ |
| |
| Some support for logging is available. Note, however, that the :mod:`logging` |
| package does not use process shared locks so it is possible (depending on the |
| handler type) for messages from different processes to get mixed up. |
| |
| .. currentmodule:: multiprocessing |
| .. function:: get_logger() |
| |
| Returns the logger used by :mod:`multiprocessing`. If necessary, a new one |
| will be created. |
| |
| When first created the logger has level :data:`logging.NOTSET` and no |
| default handler. Messages sent to this logger will not by default propagate |
| to the root logger. |
| |
| Note that on Windows child processes will only inherit the level of the |
| parent process's logger -- any other customization of the logger will not be |
| inherited. |
| |
| .. currentmodule:: multiprocessing |
| .. function:: log_to_stderr() |
| |
| This function performs a call to :func:`get_logger` but in addition to |
| returning the logger created by get_logger, it adds a handler which sends |
| output to :data:`sys.stderr` using format |
| ``'[%(levelname)s/%(processName)s] %(message)s'``. |
| |
| Below is an example session with logging turned on:: |
| |
| >>> import multiprocessing, logging |
| >>> logger = multiprocessing.log_to_stderr() |
| >>> logger.setLevel(logging.INFO) |
| >>> logger.warning('doomed') |
| [WARNING/MainProcess] doomed |
| >>> m = multiprocessing.Manager() |
| [INFO/SyncManager-...] child process calling self.run() |
| [INFO/SyncManager-...] created temp directory /.../pymp-... |
| [INFO/SyncManager-...] manager serving at '/.../listener-...' |
| >>> del m |
| [INFO/MainProcess] sending shutdown message to manager |
| [INFO/SyncManager-...] manager exiting with exitcode 0 |
| |
| For a full table of logging levels, see the :mod:`logging` module. |
| |
| |
| The :mod:`multiprocessing.dummy` module |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| .. module:: multiprocessing.dummy |
| :synopsis: Dumb wrapper around threading. |
| |
| :mod:`multiprocessing.dummy` replicates the API of :mod:`multiprocessing` but is |
| no more than a wrapper around the :mod:`threading` module. |
| |
| |
| .. _multiprocessing-programming: |
| |
| Programming guidelines |
| ---------------------- |
| |
| There are certain guidelines and idioms which should be adhered to when using |
| :mod:`multiprocessing`. |
| |
| |
| All start methods |
| ~~~~~~~~~~~~~~~~~ |
| |
| The following applies to all start methods. |
| |
| Avoid shared state |
| |
| As far as possible one should try to avoid shifting large amounts of data |
| between processes. |
| |
| It is probably best to stick to using queues or pipes for communication |
| between processes rather than using the lower level synchronization |
| primitives. |
| |
| Picklability |
| |
| Ensure that the arguments to the methods of proxies are picklable. |
| |
| Thread safety of proxies |
| |
| Do not use a proxy object from more than one thread unless you protect it |
| with a lock. |
| |
| (There is never a problem with different processes using the *same* proxy.) |
| |
| Joining zombie processes |
| |
| On Unix when a process finishes but has not been joined it becomes a zombie. |
| There should never be very many because each time a new process starts (or |
| :func:`~multiprocessing.active_children` is called) all completed processes |
| which have not yet been joined will be joined. Also calling a finished |
| process's :meth:`Process.is_alive <multiprocessing.Process.is_alive>` will |
| join the process. Even so it is probably good |
| practice to explicitly join all the processes that you start. |
| |
| Better to inherit than pickle/unpickle |
| |
| When using the *spawn* or *forkserver* start methods many types |
| from :mod:`multiprocessing` need to be picklable so that child |
| processes can use them. However, one should generally avoid |
| sending shared objects to other processes using pipes or queues. |
| Instead you should arrange the program so that a process which |
| needs access to a shared resource created elsewhere can inherit it |
| from an ancestor process. |
| |
| Avoid terminating processes |
| |
| Using the :meth:`Process.terminate <multiprocessing.Process.terminate>` |
| method to stop a process is liable to |
| cause any shared resources (such as locks, semaphores, pipes and queues) |
| currently being used by the process to become broken or unavailable to other |
| processes. |
| |
| Therefore it is probably best to only consider using |
| :meth:`Process.terminate <multiprocessing.Process.terminate>` on processes |
| which never use any shared resources. |
| |
| Joining processes that use queues |
| |
| Bear in mind that a process that has put items in a queue will wait before |
| terminating until all the buffered items are fed by the "feeder" thread to |
| the underlying pipe. (The child process can call the |
| :meth:`Queue.cancel_join_thread <multiprocessing.Queue.cancel_join_thread>` |
| method of the queue to avoid this behaviour.) |
| |
| This means that whenever you use a queue you need to make sure that all |
| items which have been put on the queue will eventually be removed before the |
| process is joined. Otherwise you cannot be sure that processes which have |
| put items on the queue will terminate. Remember also that non-daemonic |
| processes will be joined automatically. |
| |
| An example which will deadlock is the following:: |
| |
| from multiprocessing import Process, Queue |
| |
| def f(q): |
| q.put('X' * 1000000) |
| |
| if __name__ == '__main__': |
| queue = Queue() |
| p = Process(target=f, args=(queue,)) |
| p.start() |
| p.join() # this deadlocks |
| obj = queue.get() |
| |
| A fix here would be to swap the last two lines (or simply remove the |
| ``p.join()`` line). |
| |
| Explicitly pass resources to child processes |
| |
| On Unix using the *fork* start method, a child process can make |
| use of a shared resource created in a parent process using a |
| global resource. However, it is better to pass the object as an |
| argument to the constructor for the child process. |
| |
| Apart from making the code (potentially) compatible with Windows |
| and the other start methods this also ensures that as long as the |
| child process is still alive the object will not be garbage |
| collected in the parent process. This might be important if some |
| resource is freed when the object is garbage collected in the |
| parent process. |
| |
| So for instance :: |
| |
| from multiprocessing import Process, Lock |
| |
| def f(): |
| ... do something using "lock" ... |
| |
| if __name__ == '__main__': |
| lock = Lock() |
| for i in range(10): |
| Process(target=f).start() |
| |
| should be rewritten as :: |
| |
| from multiprocessing import Process, Lock |
| |
| def f(l): |
| ... do something using "l" ... |
| |
| if __name__ == '__main__': |
| lock = Lock() |
| for i in range(10): |
| Process(target=f, args=(lock,)).start() |
| |
| Beware of replacing :data:`sys.stdin` with a "file like object" |
| |
| :mod:`multiprocessing` originally unconditionally called:: |
| |
| os.close(sys.stdin.fileno()) |
| |
| in the :meth:`multiprocessing.Process._bootstrap` method --- this resulted |
| in issues with processes-in-processes. This has been changed to:: |
| |
| sys.stdin.close() |
| sys.stdin = open(os.devnull) |
| |
| Which solves the fundamental issue of processes colliding with each other |
| resulting in a bad file descriptor error, but introduces a potential danger |
| to applications which replace :func:`sys.stdin` with a "file-like object" |
| with output buffering. This danger is that if multiple processes call |
| :meth:`~io.IOBase.close()` on this file-like object, it could result in the same |
| data being flushed to the object multiple times, resulting in corruption. |
| |
| If you write a file-like object and implement your own caching, you can |
| make it fork-safe by storing the pid whenever you append to the cache, |
| and discarding the cache when the pid changes. For example:: |
| |
| @property |
| def cache(self): |
| pid = os.getpid() |
| if pid != self._pid: |
| self._pid = pid |
| self._cache = [] |
| return self._cache |
| |
| For more information, see :issue:`5155`, :issue:`5313` and :issue:`5331` |
| |
| The *spawn* and *forkserver* start methods |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| There are a few extra restriction which don't apply to the *fork* |
| start method. |
| |
| More picklability |
| |
| Ensure that all arguments to :meth:`Process.__init__` are |
| picklable. This means, in particular, that bound or unbound |
| methods cannot be used directly as the ``target`` (unless you use |
| the *fork* start method) --- just define a function and use that |
| instead. |
| |
| Also, if you subclass :class:`~multiprocessing.Process` then make sure that |
| instances will be picklable when the :meth:`Process.start |
| <multiprocessing.Process.start>` method is called. |
| |
| Global variables |
| |
| Bear in mind that if code run in a child process tries to access a global |
| variable, then the value it sees (if any) may not be the same as the value |
| in the parent process at the time that :meth:`Process.start |
| <multiprocessing.Process.start>` was called. |
| |
| However, global variables which are just module level constants cause no |
| problems. |
| |
| Safe importing of main module |
| |
| Make sure that the main module can be safely imported by a new Python |
| interpreter without causing unintended side effects (such a starting a new |
| process). |
| |
| For example, using the *spawn* or *forkserver* start method |
| running the following module would fail with a |
| :exc:`RuntimeError`:: |
| |
| from multiprocessing import Process |
| |
| def foo(): |
| print('hello') |
| |
| p = Process(target=foo) |
| p.start() |
| |
| Instead one should protect the "entry point" of the program by using ``if |
| __name__ == '__main__':`` as follows:: |
| |
| from multiprocessing import Process, freeze_support, set_start_method |
| |
| def foo(): |
| print('hello') |
| |
| if __name__ == '__main__': |
| freeze_support() |
| set_start_method('spawn') |
| p = Process(target=foo) |
| p.start() |
| |
| (The ``freeze_support()`` line can be omitted if the program will be run |
| normally instead of frozen.) |
| |
| This allows the newly spawned Python interpreter to safely import the module |
| and then run the module's ``foo()`` function. |
| |
| Similar restrictions apply if a pool or manager is created in the main |
| module. |
| |
| |
| .. _multiprocessing-examples: |
| |
| Examples |
| -------- |
| |
| Demonstration of how to create and use customized managers and proxies: |
| |
| .. literalinclude:: ../includes/mp_newtype.py |
| :language: python3 |
| |
| |
| Using :class:`~multiprocessing.pool.Pool`: |
| |
| .. literalinclude:: ../includes/mp_pool.py |
| :language: python3 |
| |
| |
| An example showing how to use queues to feed tasks to a collection of worker |
| processes and collect the results: |
| |
| .. literalinclude:: ../includes/mp_workers.py |