From 3d57e14df7ba5f14a634295caf3b2e60da50bfe2 Mon Sep 17 00:00:00 2001 From: James Taylor Date: Fri, 6 Sep 2019 16:31:13 -0700 Subject: Remove windows python distribution from repo and add requirements.txt --- python/gevent/pool.py | 667 -------------------------------------------------- 1 file changed, 667 deletions(-) delete mode 100644 python/gevent/pool.py (limited to 'python/gevent/pool.py') diff --git a/python/gevent/pool.py b/python/gevent/pool.py deleted file mode 100644 index 48e6a7a..0000000 --- a/python/gevent/pool.py +++ /dev/null @@ -1,667 +0,0 @@ -# Copyright (c) 2009-2011 Denis Bilenko. See LICENSE for details. -""" -Managing greenlets in a group. - -The :class:`Group` class in this module abstracts a group of running -greenlets. When a greenlet dies, it's automatically removed from the -group. All running greenlets in a group can be waited on with -:meth:`Group.join`, or all running greenlets can be killed with -:meth:`Group.kill`. - -The :class:`Pool` class, which is a subclass of :class:`Group`, -provides a way to limit concurrency: its :meth:`spawn ` -method blocks if the number of greenlets in the pool has already -reached the limit, until there is a free slot. -""" -from __future__ import print_function, absolute_import, division - - -from gevent.hub import GreenletExit, getcurrent, kill as _kill -from gevent.greenlet import joinall, Greenlet -from gevent.queue import Full as QueueFull -from gevent.timeout import Timeout -from gevent.event import Event -from gevent.lock import Semaphore, DummySemaphore - -from gevent._compat import izip -from gevent._imap import IMap -from gevent._imap import IMapUnordered - -__all__ = [ - 'Group', - 'Pool', - 'PoolFull', -] - - - - -class GroupMappingMixin(object): - # Internal, non-public API class. - # Provides mixin methods for implementing mapping pools. Subclasses must define: - - def spawn(self, func, *args, **kwargs): - """ - A function that runs *func* with *args* and *kwargs*, potentially - asynchronously. Return a value with a ``get`` method that blocks - until the results of func are available, and a ``rawlink`` method - that calls a callback when the results are available. - - If this object has an upper bound on how many asyncronously executing - tasks can exist, this method may block until a slot becomes available. - """ - raise NotImplementedError() - - def _apply_immediately(self): - """ - should the function passed to apply be called immediately, - synchronously? - """ - raise NotImplementedError() - - def _apply_async_use_greenlet(self): - """ - Should apply_async directly call Greenlet.spawn(), bypassing - `spawn`? - - Return true when self.spawn would block. - """ - raise NotImplementedError() - - def _apply_async_cb_spawn(self, callback, result): - """ - Run the given callback function, possibly - asynchronously, possibly synchronously. - """ - raise NotImplementedError() - - def apply_cb(self, func, args=None, kwds=None, callback=None): - """ - :meth:`apply` the given *func(\\*args, \\*\\*kwds)*, and, if a *callback* is given, run it with the - results of *func* (unless an exception was raised.) - - The *callback* may be called synchronously or asynchronously. If called - asynchronously, it will not be tracked by this group. (:class:`Group` and :class:`Pool` - call it asynchronously in a new greenlet; :class:`~gevent.threadpool.ThreadPool` calls - it synchronously in the current greenlet.) - """ - result = self.apply(func, args, kwds) - if callback is not None: - self._apply_async_cb_spawn(callback, result) - return result - - def apply_async(self, func, args=None, kwds=None, callback=None): - """ - A variant of the :meth:`apply` method which returns a :class:`~.Greenlet` object. - - When the returned greenlet gets to run, it *will* call :meth:`apply`, - passing in *func*, *args* and *kwds*. - - 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 (unless the call failed). - - This method will never block, even if this group is full (that is, - even if :meth:`spawn` would block, this method will not). - - .. caution:: The returned greenlet may or may not be tracked - as part of this group, so :meth:`joining ` this group is - not a reliable way to wait for the results to be available or - for the returned greenlet to run; instead, join the returned - greenlet. - - .. tip:: Because :class:`~.ThreadPool` objects do not track greenlets, the returned - greenlet will never be a part of it. To reduce overhead and improve performance, - :class:`Group` and :class:`Pool` may choose to track the returned - greenlet. These are implementation details that may change. - """ - if args is None: - args = () - if kwds is None: - kwds = {} - if self._apply_async_use_greenlet(): - # cannot call self.spawn() directly because it will block - # XXX: This is always the case for ThreadPool, but for Group/Pool - # of greenlets, this is only the case when they are full...hence - # the weasely language about "may or may not be tracked". Should we make - # Group/Pool always return true as well so it's never tracked by any - # implementation? That would simplify that logic, but could increase - # the total number of greenlets in the system and add a layer of - # overhead for the simple cases when the pool isn't full. - return Greenlet.spawn(self.apply_cb, func, args, kwds, callback) - - greenlet = self.spawn(func, *args, **kwds) - if callback is not None: - greenlet.link(pass_value(callback)) - return greenlet - - def apply(self, func, args=None, kwds=None): - """ - Rough quivalent of the :func:`apply()` builtin function blocking until - the result is ready and returning it. - - The ``func`` will *usually*, but not *always*, be run in a way - that allows the current greenlet to switch out (for example, - in a new greenlet or thread, depending on implementation). But - if the current greenlet or thread is already one that was - spawned by this pool, the pool may choose to immediately run - the `func` synchronously. - - Any exception ``func`` raises will be propagated to the caller of ``apply`` (that is, - this method will raise the exception that ``func`` raised). - """ - if args is None: - args = () - if kwds is None: - kwds = {} - if self._apply_immediately(): - return func(*args, **kwds) - return self.spawn(func, *args, **kwds).get() - - def __map(self, func, iterable): - return [g.get() for g in - [self.spawn(func, i) for i in iterable]] - - def map(self, func, iterable): - """Return a list made by applying the *func* to each element of - the iterable. - - .. seealso:: :meth:`imap` - """ - # We can't return until they're all done and in order. It - # wouldn't seem to much matter what order we wait on them in, - # so the simple, fast (50% faster than imap) solution would be: - - # return [g.get() for g in - # [self.spawn(func, i) for i in iterable]] - - # If the pool size is unlimited (or more than the len(iterable)), this - # is equivalent to imap (spawn() will never block, all of them run concurrently, - # we call get() in the order the iterable was given). - - # Now lets imagine the pool if is limited size. Suppose the - # func is time.sleep, our pool is limited to 3 threads, and - # our input is [10, 1, 10, 1, 1] We would start three threads, - # one to sleep for 10, one to sleep for 1, and the last to - # sleep for 10. We would block starting the fourth thread. At - # time 1, we would finish the second thread and start another - # one for time 1. At time 2, we would finish that one and - # start the last thread, and then begin executing get() on the first - # thread. - - # Because it's spawn that blocks, this is *also* equivalent to what - # imap would do. - - # The one remaining difference is that imap runs in its own - # greenlet, potentially changing the way the event loop runs. - # That's easy enough to do. - - g = Greenlet.spawn(self.__map, func, iterable) - return g.get() - - def map_cb(self, func, iterable, callback=None): - result = self.map(func, iterable) - if callback is not None: - callback(result) - return result - - def map_async(self, func, iterable, callback=None): - """ - A variant of the map() method which returns a Greenlet object that is executing - the map function. - - If callback is specified then it should be a callable which accepts a - single argument. - """ - return Greenlet.spawn(self.map_cb, func, iterable, callback) - - def __imap(self, cls, func, *iterables, **kwargs): - # Python 2 doesn't support the syntax that lets us mix varargs and - # a named kwarg, so we have to unpack manually - maxsize = kwargs.pop('maxsize', None) - if kwargs: - raise TypeError("Unsupported keyword arguments") - return cls.spawn(func, izip(*iterables), spawn=self.spawn, - _zipped=True, maxsize=maxsize) - - def imap(self, func, *iterables, **kwargs): - """ - imap(func, *iterables, maxsize=None) -> iterable - - An equivalent of :func:`itertools.imap`, operating in parallel. - The *func* is applied to each element yielded from each - iterable in *iterables* in turn, collecting the result. - - If this object has a bound on the number of active greenlets it can - contain (such as :class:`Pool`), then at most that number of tasks will operate - in parallel. - - :keyword int maxsize: If given and not-None, specifies the maximum number of - finished results that will be allowed to accumulate awaiting the reader; - more than that number of results will cause map function greenlets to begin - to block. This is most useful if there is a great disparity in the speed of - the mapping code and the consumer and the results consume a great deal of resources. - - .. note:: This is separate from any bound on the number of active parallel - tasks, though they may have some interaction (for example, limiting the - number of parallel tasks to the smallest bound). - - .. note:: Using a bound is slightly more computationally expensive than not using a bound. - - .. tip:: The :meth:`imap_unordered` method makes much better - use of this parameter. Some additional, unspecified, - number of objects may be required to be kept in memory - to maintain order by this function. - - :return: An iterable object. - - .. versionchanged:: 1.1b3 - Added the *maxsize* keyword parameter. - .. versionchanged:: 1.1a1 - Accept multiple *iterables* to iterate in parallel. - """ - return self.__imap(IMap, func, *iterables, **kwargs) - - def imap_unordered(self, func, *iterables, **kwargs): - """ - imap_unordered(func, *iterables, maxsize=None) -> iterable - - The same as :meth:`imap` except that the ordering of the results - from the returned iterator should be considered in arbitrary - order. - - This is lighter weight than :meth:`imap` and should be preferred if order - doesn't matter. - - .. seealso:: :meth:`imap` for more details. - """ - return self.__imap(IMapUnordered, func, *iterables, **kwargs) - - -class Group(GroupMappingMixin): - """ - Maintain a group of greenlets that are still running, without - limiting their number. - - Links to each item and removes it upon notification. - - Groups can be iterated to discover what greenlets they are tracking, - they can be tested to see if they contain a greenlet, and they know the - number (len) of greenlets they are tracking. If they are not tracking any - greenlets, they are False in a boolean context. - """ - - #: The type of Greenlet object we will :meth:`spawn`. This can be changed - #: on an instance or in a subclass. - greenlet_class = Greenlet - - def __init__(self, *args): - assert len(args) <= 1, args - self.greenlets = set(*args) - if args: - for greenlet in args[0]: - greenlet.rawlink(self._discard) - # each item we kill we place in dying, to avoid killing the same greenlet twice - self.dying = set() - self._empty_event = Event() - self._empty_event.set() - - def __repr__(self): - return '<%s at 0x%x %s>' % (self.__class__.__name__, id(self), self.greenlets) - - def __len__(self): - """ - Answer how many greenlets we are tracking. Note that if we are empty, - we are False in a boolean context. - """ - return len(self.greenlets) - - def __contains__(self, item): - """ - Answer if we are tracking the given greenlet. - """ - return item in self.greenlets - - def __iter__(self): - """ - Iterate across all the greenlets we are tracking, in no particular order. - """ - return iter(self.greenlets) - - def add(self, greenlet): - """ - Begin tracking the *greenlet*. - - If this group is :meth:`full`, then this method may block - until it is possible to track the greenlet. - - Typically the *greenlet* should **not** be started when - it is added because if this object blocks in this method, - then the *greenlet* may run to completion before it is tracked. - """ - try: - rawlink = greenlet.rawlink - except AttributeError: - pass # non-Greenlet greenlet, like MAIN - else: - rawlink(self._discard) - self.greenlets.add(greenlet) - self._empty_event.clear() - - def _discard(self, greenlet): - self.greenlets.discard(greenlet) - self.dying.discard(greenlet) - if not self.greenlets: - self._empty_event.set() - - def discard(self, greenlet): - """ - Stop tracking the greenlet. - """ - self._discard(greenlet) - try: - unlink = greenlet.unlink - except AttributeError: - pass # non-Greenlet greenlet, like MAIN - else: - unlink(self._discard) - - def start(self, greenlet): - """ - Add the **unstarted** *greenlet* to the collection of greenlets - this group is monitoring, and then start it. - """ - self.add(greenlet) - greenlet.start() - - def spawn(self, *args, **kwargs): # pylint:disable=arguments-differ - """ - Begin a new greenlet with the given arguments (which are passed - to the greenlet constructor) and add it to the collection of greenlets - this group is monitoring. - - :return: The newly started greenlet. - """ - greenlet = self.greenlet_class(*args, **kwargs) - self.start(greenlet) - return greenlet - -# def close(self): -# """Prevents any more tasks from being submitted to the pool""" -# self.add = RaiseException("This %s has been closed" % self.__class__.__name__) - - def join(self, timeout=None, raise_error=False): - """ - Wait for this group to become empty *at least once*. - - If there are no greenlets in the group, returns immediately. - - .. note:: By the time the waiting code (the caller of this - method) regains control, a greenlet may have been added to - this group, and so this object may no longer be empty. (That - is, ``group.join(); assert len(group) == 0`` is not - guaranteed to hold.) This method only guarantees that the group - reached a ``len`` of 0 at some point. - - :keyword bool raise_error: If True (*not* the default), if any - greenlet that finished while the join was in progress raised - an exception, that exception will be raised to the caller of - this method. If multiple greenlets raised exceptions, which - one gets re-raised is not determined. Only greenlets currently - in the group when this method is called are guaranteed to - be checked for exceptions. - - :return bool: A value indicating whether this group became empty. - If the timeout is specified and the group did not become empty - during that timeout, then this will be a false value. Otherwise - it will be a true value. - - .. versionchanged:: 1.2a1 - Add the return value. - """ - greenlets = list(self.greenlets) if raise_error else () - result = self._empty_event.wait(timeout=timeout) - - for greenlet in greenlets: - if greenlet.exception is not None: - if hasattr(greenlet, '_raise_exception'): - greenlet._raise_exception() - raise greenlet.exception - - return result - - def kill(self, exception=GreenletExit, block=True, timeout=None): - """ - Kill all greenlets being tracked by this group. - """ - timer = Timeout._start_new_or_dummy(timeout) - try: - while self.greenlets: - for greenlet in list(self.greenlets): - if greenlet in self.dying: - continue - try: - kill = greenlet.kill - except AttributeError: - _kill(greenlet, exception) - else: - kill(exception, block=False) - self.dying.add(greenlet) - if not block: - break - joinall(self.greenlets) - except Timeout as ex: - if ex is not timer: - raise - finally: - timer.cancel() - - def killone(self, greenlet, exception=GreenletExit, block=True, timeout=None): - """ - If the given *greenlet* is running and being tracked by this group, - kill it. - """ - if greenlet not in self.dying and greenlet in self.greenlets: - greenlet.kill(exception, block=False) - self.dying.add(greenlet) - if block: - greenlet.join(timeout) - - def full(self): - """ - Return a value indicating whether this group can track more greenlets. - - In this implementation, because there are no limits on the number of - tracked greenlets, this will always return a ``False`` value. - """ - return False - - def wait_available(self, timeout=None): - """ - Block until it is possible to :meth:`spawn` a new greenlet. - - In this implementation, because there are no limits on the number - of tracked greenlets, this will always return immediately. - """ - pass - - # MappingMixin methods - - def _apply_immediately(self): - # If apply() is called from one of our own - # worker greenlets, don't spawn a new one---if we're full, that - # could deadlock. - return getcurrent() in self - - def _apply_async_cb_spawn(self, callback, result): - Greenlet.spawn(callback, result) - - def _apply_async_use_greenlet(self): - # cannot call self.spawn() because it will block, so - # use a fresh, untracked greenlet that when run will - # (indirectly) call self.spawn() for us. - return self.full() - - - -class PoolFull(QueueFull): - """ - Raised when a Pool is full and an attempt was made to - add a new greenlet to it in non-blocking mode. - """ - - -class Pool(Group): - - def __init__(self, size=None, greenlet_class=None): - """ - Create a new pool. - - A pool is like a group, but the maximum number of members - is governed by the *size* parameter. - - :keyword int size: If given, this non-negative integer is the - maximum count of active greenlets that will be allowed in - this pool. A few values have special significance: - - * ``None`` (the default) places no limit on the number of - greenlets. This is useful when you need to track, but not limit, - greenlets, as with :class:`gevent.pywsgi.WSGIServer`. A :class:`Group` - may be a more efficient way to achieve the same effect. - * ``0`` creates a pool that can never have any active greenlets. Attempting - to spawn in this pool will block forever. This is only useful - if an application uses :meth:`wait_available` with a timeout and checks - :meth:`free_count` before attempting to spawn. - """ - if size is not None and size < 0: - raise ValueError('size must not be negative: %r' % (size, )) - Group.__init__(self) - self.size = size - if greenlet_class is not None: - self.greenlet_class = greenlet_class - if size is None: - factory = DummySemaphore - else: - factory = Semaphore - self._semaphore = factory(size) - - def wait_available(self, timeout=None): - """ - Wait until it's possible to spawn a greenlet in this pool. - - :param float timeout: If given, only wait the specified number - of seconds. - - .. warning:: If the pool was initialized with a size of 0, this - method will block forever unless a timeout is given. - - :return: A number indicating how many new greenlets can be put into - the pool without blocking. - - .. versionchanged:: 1.1a3 - Added the ``timeout`` parameter. - """ - return self._semaphore.wait(timeout=timeout) - - def full(self): - """ - Return a boolean indicating whether this pool is full, e.g. if - :meth:`add` would block. - - :return: False if there is room for new members, True if there isn't. - """ - return self.free_count() <= 0 - - def free_count(self): - """ - Return a number indicating *approximately* how many more members - can be added to this pool. - """ - if self.size is None: - return 1 - return max(0, self.size - len(self)) - - def start(self, greenlet, *args, **kwargs): # pylint:disable=arguments-differ - """ - start(greenlet, blocking=True, timeout=None) -> None - - Add the **unstarted** *greenlet* to the collection of greenlets - this group is monitoring and then start it. - - Parameters are as for :meth:`add`. - """ - self.add(greenlet, *args, **kwargs) - greenlet.start() - - def add(self, greenlet, blocking=True, timeout=None): # pylint:disable=arguments-differ - """ - Begin tracking the given **unstarted** greenlet, possibly blocking - until space is available. - - Usually you should call :meth:`start` to track and start the greenlet - instead of using this lower-level method, or :meth:`spawn` to - also create the greenlet. - - :keyword bool blocking: If True (the default), this function - will block until the pool has space or a timeout occurs. If - False, this function will immediately raise a Timeout if the - pool is currently full. - :keyword float timeout: The maximum number of seconds this - method will block, if ``blocking`` is True. (Ignored if - ``blocking`` is False.) - :raises PoolFull: if either ``blocking`` is False and the pool - was full, or if ``blocking`` is True and ``timeout`` was - exceeded. - - .. caution:: If the *greenlet* has already been started and - *blocking* is true, then the greenlet may run to completion - while the current greenlet blocks waiting to track it. This would - enable higher concurrency than desired. - - .. seealso:: :meth:`Group.add` - - .. versionchanged:: 1.3.0 Added the ``blocking`` and - ``timeout`` parameters. - """ - if not self._semaphore.acquire(blocking=blocking, timeout=timeout): - # We failed to acquire the semaphore. - # If blocking was True, then there was a timeout. If blocking was - # False, then there was no capacity. Either way, raise PoolFull. - raise PoolFull() - - try: - Group.add(self, greenlet) - except: - self._semaphore.release() - raise - - def _discard(self, greenlet): - Group._discard(self, greenlet) - self._semaphore.release() - - -class pass_value(object): - __slots__ = ['callback'] - - def __init__(self, callback): - self.callback = callback - - def __call__(self, source): - if source.successful(): - self.callback(source.value) - - def __hash__(self): - return hash(self.callback) - - def __eq__(self, other): - return self.callback == getattr(other, 'callback', other) - - def __str__(self): - return str(self.callback) - - def __repr__(self): - return repr(self.callback) - - def __getattr__(self, item): - assert item != 'callback' - return getattr(self.callback, item) -- cgit v1.2.3