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606 lines
20 KiB
Python
606 lines
20 KiB
Python
5 years ago
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# cython: auto_pickle=False,embedsignature=True,always_allow_keywords=False
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"""
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Greenlet-local objects.
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This module is based on `_threading_local.py`__ from the standard
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library of Python 3.4.
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__ https://github.com/python/cpython/blob/3.4/Lib/_threading_local.py
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Greenlet-local objects support the management of greenlet-local data.
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If you have data that you want to be local to a greenlet, simply create
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a greenlet-local object and use its attributes:
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>>> mydata = local()
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>>> mydata.number = 42
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>>> mydata.number
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42
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You can also access the local-object's dictionary:
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>>> mydata.__dict__
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{'number': 42}
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>>> mydata.__dict__.setdefault('widgets', [])
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[]
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>>> mydata.widgets
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[]
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What's important about greenlet-local objects is that their data are
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local to a greenlet. If we access the data in a different greenlet:
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>>> log = []
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>>> def f():
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... items = list(mydata.__dict__.items())
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... items.sort()
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... log.append(items)
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... mydata.number = 11
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... log.append(mydata.number)
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>>> greenlet = gevent.spawn(f)
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>>> greenlet.join()
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>>> log
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[[], 11]
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we get different data. Furthermore, changes made in the other greenlet
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don't affect data seen in this greenlet:
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>>> mydata.number
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42
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Of course, values you get from a local object, including a __dict__
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attribute, are for whatever greenlet was current at the time the
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attribute was read. For that reason, you generally don't want to save
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these values across greenlets, as they apply only to the greenlet they
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came from.
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You can create custom local objects by subclassing the local class:
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>>> class MyLocal(local):
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... number = 2
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... initialized = False
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... def __init__(self, **kw):
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... if self.initialized:
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... raise SystemError('__init__ called too many times')
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... self.initialized = True
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... self.__dict__.update(kw)
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... def squared(self):
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... return self.number ** 2
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This can be useful to support default values, methods and
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initialization. Note that if you define an __init__ method, it will be
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called each time the local object is used in a separate greenlet. This
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is necessary to initialize each greenlet's dictionary.
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Now if we create a local object:
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>>> mydata = MyLocal(color='red')
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Now we have a default number:
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>>> mydata.number
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2
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an initial color:
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>>> mydata.color
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'red'
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>>> del mydata.color
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And a method that operates on the data:
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>>> mydata.squared()
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4
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As before, we can access the data in a separate greenlet:
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>>> log = []
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>>> greenlet = gevent.spawn(f)
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>>> greenlet.join()
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>>> log
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[[('color', 'red'), ('initialized', True)], 11]
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without affecting this greenlet's data:
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>>> mydata.number
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2
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>>> mydata.color
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Traceback (most recent call last):
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...
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AttributeError: 'MyLocal' object has no attribute 'color'
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Note that subclasses can define slots, but they are not greenlet
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local. They are shared across greenlets::
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>>> class MyLocal(local):
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... __slots__ = 'number'
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>>> mydata = MyLocal()
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>>> mydata.number = 42
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>>> mydata.color = 'red'
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So, the separate greenlet:
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>>> greenlet = gevent.spawn(f)
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>>> greenlet.join()
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affects what we see:
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>>> mydata.number
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11
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>>> del mydata
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.. versionchanged:: 1.1a2
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Update the implementation to match Python 3.4 instead of Python 2.5.
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This results in locals being eligible for garbage collection as soon
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as their greenlet exits.
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.. versionchanged:: 1.2.3
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Use a weak-reference to clear the greenlet link we establish in case
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the local object dies before the greenlet does.
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.. versionchanged:: 1.3a1
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Implement the methods for attribute access directly, handling
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descriptors directly here. This allows removing the use of a lock
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and facilitates greatly improved performance.
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.. versionchanged:: 1.3a1
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The ``__init__`` method of subclasses of ``local`` is no longer
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called with a lock held. CPython does not use such a lock in its
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native implementation. This could potentially show as a difference
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if code that uses multiple dependent attributes in ``__slots__``
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(which are shared across all greenlets) switches during ``__init__``.
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"""
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from __future__ import print_function
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from copy import copy
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from weakref import ref
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locals()['getcurrent'] = __import__('greenlet').getcurrent
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locals()['greenlet_init'] = lambda: None
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__all__ = [
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"local",
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]
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# The key used in the Thread objects' attribute dicts.
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# We keep it a string for speed but make it unlikely to clash with
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# a "real" attribute.
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key_prefix = '_gevent_local_localimpl_'
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# The overall structure is as follows:
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# For each local() object:
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# greenlet.__dict__[key_prefix + str(id(local))]
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# => _localimpl.dicts[id(greenlet)] => (ref(greenlet), {})
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# That final tuple is actually a localimpl_dict_entry object.
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def all_local_dicts_for_greenlet(greenlet):
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"""
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Internal debug helper for getting the local values associated
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with a greenlet. This is subject to change or removal at any time.
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:return: A list of ((type, id), {}) pairs, where the first element
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is the type and id of the local object and the second object is its
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instance dictionary, as seen from this greenlet.
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.. versionadded:: 1.3a2
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"""
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result = []
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id_greenlet = id(greenlet)
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greenlet_dict = greenlet.__dict__
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for k, v in greenlet_dict.items():
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if not k.startswith(key_prefix):
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continue
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local_impl = v()
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if local_impl is None:
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continue
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entry = local_impl.dicts.get(id_greenlet)
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if entry is None:
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# Not yet used in this greenlet.
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continue
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assert entry.wrgreenlet() is greenlet
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result.append((local_impl.localtypeid, entry.localdict))
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return result
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class _wrefdict(dict):
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"""A dict that can be weak referenced"""
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class _greenlet_deleted(object):
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"""
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A weakref callback for when the greenlet
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is deleted.
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If the greenlet is a `gevent.greenlet.Greenlet` and
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supplies ``rawlink``, that will be used instead of a
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weakref.
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"""
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__slots__ = ('idt', 'wrdicts')
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def __init__(self, idt, wrdicts):
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self.idt = idt
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self.wrdicts = wrdicts
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def __call__(self, _unused):
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dicts = self.wrdicts()
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if dicts:
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dicts.pop(self.idt, None)
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class _local_deleted(object):
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__slots__ = ('key', 'wrthread', 'greenlet_deleted')
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def __init__(self, key, wrthread, greenlet_deleted):
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self.key = key
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self.wrthread = wrthread
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self.greenlet_deleted = greenlet_deleted
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def __call__(self, _unused):
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thread = self.wrthread()
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if thread is not None:
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try:
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unlink = thread.unlink
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except AttributeError:
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pass
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else:
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unlink(self.greenlet_deleted)
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del thread.__dict__[self.key]
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class _localimpl(object):
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"""A class managing thread-local dicts"""
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__slots__ = ('key', 'dicts',
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'localargs', 'localkwargs',
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'localtypeid',
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'__weakref__',)
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def __init__(self, args, kwargs, local_type, id_local):
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self.key = key_prefix + str(id(self))
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# { id(greenlet) -> _localimpl_dict_entry(ref(greenlet), greenlet-local dict) }
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self.dicts = _wrefdict()
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self.localargs = args
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self.localkwargs = kwargs
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self.localtypeid = local_type, id_local
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# We need to create the thread dict in anticipation of
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# __init__ being called, to make sure we don't call it
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# again ourselves. MUST do this before setting any attributes.
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greenlet = getcurrent() # pylint:disable=undefined-variable
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_localimpl_create_dict(self, greenlet, id(greenlet))
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class _localimpl_dict_entry(object):
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"""
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The object that goes in the ``dicts`` of ``_localimpl``
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object for each thread.
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"""
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# This is a class, not just a tuple, so that cython can optimize
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# attribute access
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__slots__ = ('wrgreenlet', 'localdict')
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def __init__(self, wrgreenlet, localdict):
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self.wrgreenlet = wrgreenlet
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self.localdict = localdict
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# We use functions instead of methods so that they can be cdef'd in
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# local.pxd; if they were cdef'd as methods, they would cause
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# the creation of a pointer and a vtable. This happens
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# even if we declare the class @cython.final. functions thus save memory overhead
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# (but not pointer chasing overhead; the vtable isn't used when we declare
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# the class final).
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def _localimpl_create_dict(self, greenlet, id_greenlet):
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"""Create a new dict for the current thread, and return it."""
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localdict = {}
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key = self.key
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wrdicts = ref(self.dicts)
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# When the greenlet is deleted, remove the local dict.
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# Note that this is suboptimal if the greenlet object gets
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# caught in a reference loop. We would like to be called
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# as soon as the OS-level greenlet ends instead.
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# If we are working with a gevent.greenlet.Greenlet, we
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# can pro-actively clear out with a link, avoiding the
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# issue described above. Use rawlink to avoid spawning any
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# more greenlets.
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greenlet_deleted = _greenlet_deleted(id_greenlet, wrdicts)
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rawlink = getattr(greenlet, 'rawlink', None)
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if rawlink is not None:
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rawlink(greenlet_deleted)
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wrthread = ref(greenlet)
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else:
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wrthread = ref(greenlet, greenlet_deleted)
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# When the localimpl is deleted, remove the thread attribute.
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local_deleted = _local_deleted(key, wrthread, greenlet_deleted)
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wrlocal = ref(self, local_deleted)
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greenlet.__dict__[key] = wrlocal
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self.dicts[id_greenlet] = _localimpl_dict_entry(wrthread, localdict)
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return localdict
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_marker = object()
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def _local_get_dict(self):
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impl = self._local__impl
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# Cython can optimize dict[], but not dict.get()
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greenlet = getcurrent() # pylint:disable=undefined-variable
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idg = id(greenlet)
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try:
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entry = impl.dicts[idg]
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dct = entry.localdict
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except KeyError:
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dct = _localimpl_create_dict(impl, greenlet, idg)
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self.__init__(*impl.localargs, **impl.localkwargs)
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return dct
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def _init():
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greenlet_init() # pylint:disable=undefined-variable
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_local_attrs = {
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'_local__impl',
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'_local_type_get_descriptors',
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'_local_type_set_or_del_descriptors',
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'_local_type_del_descriptors',
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'_local_type_set_descriptors',
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'_local_type',
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'_local_type_vars',
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'__class__',
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'__cinit__',
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}
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class local(object):
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"""
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An object whose attributes are greenlet-local.
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"""
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__slots__ = tuple(_local_attrs - {'__class__', '__cinit__'})
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def __cinit__(self, *args, **kw):
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if args or kw:
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if type(self).__init__ == object.__init__:
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raise TypeError("Initialization arguments are not supported", args, kw)
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impl = _localimpl(args, kw, type(self), id(self))
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# pylint:disable=attribute-defined-outside-init
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self._local__impl = impl
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get, dels, sets_or_dels, sets = _local_find_descriptors(self)
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self._local_type_get_descriptors = get
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self._local_type_set_or_del_descriptors = sets_or_dels
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self._local_type_del_descriptors = dels
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self._local_type_set_descriptors = sets
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self._local_type = type(self)
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self._local_type_vars = set(dir(self._local_type))
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def __getattribute__(self, name): # pylint:disable=too-many-return-statements
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if name in _local_attrs:
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# The _local__impl, __cinit__, etc, won't be hit by the
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# Cython version, if we've done things right. If we haven't,
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# they will be, and this will produce an error.
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return object.__getattribute__(self, name)
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dct = _local_get_dict(self)
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if name == '__dict__':
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return dct
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# If there's no possible way we can switch, because this
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# attribute is *not* found in the class where it might be a
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# data descriptor (property), and it *is* in the dict
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# then we don't need to swizzle the dict and take the lock.
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# We don't have to worry about people overriding __getattribute__
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# because if they did, the dict-swizzling would only last as
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# long as we were in here anyway.
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# Similarly, a __getattr__ will still be called by _oga() if needed
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# if it's not in the dict.
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# Optimization: If we're not subclassed, then
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# there can be no descriptors except for methods, which will
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# never need to use __dict__.
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if self._local_type is local:
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return dct[name] if name in dct else object.__getattribute__(self, name)
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# NOTE: If this is a descriptor, this will invoke its __get__.
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# A broken descriptor that doesn't return itself when called with
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# a None for the instance argument could mess us up here.
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# But this is faster than a loop over mro() checking each class __dict__
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# manually.
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if name in dct:
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if name not in self._local_type_vars:
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# If there is a dict value, and nothing in the type,
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# it can't possibly be a descriptor, so it is just returned.
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return dct[name]
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# It's in the type *and* in the dict. If the type value is
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# a data descriptor (defines __get__ *and* either __set__ or
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# __delete__), then the type wins. If it's a non-data descriptor
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# (defines just __get__), then the instance wins. If it's not a
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# descriptor at all (doesn't have __get__), the instance wins.
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# NOTE that the docs for descriptors say that these methods must be
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# defined on the *class* of the object in the type.
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if name not in self._local_type_get_descriptors:
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# Entirely not a descriptor. Instance wins.
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return dct[name]
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if name in self._local_type_set_or_del_descriptors:
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# A data descriptor.
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# arbitrary code execution while these run. If they touch self again,
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# they'll call back into us and we'll repeat the dance.
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type_attr = getattr(self._local_type, name)
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return type(type_attr).__get__(type_attr, self, self._local_type)
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||
|
# Last case is a non-data descriptor. Instance wins.
|
||
|
return dct[name]
|
||
|
|
||
|
if name in self._local_type_vars:
|
||
|
# Not in the dictionary, but is found in the type. It could be
|
||
|
# a non-data descriptor still. Some descriptors, like @staticmethod,
|
||
|
# return objects (functions, in this case), that are *themselves*
|
||
|
# descriptors, which when invoked, again, would do the wrong thing.
|
||
|
# So we can't rely on getattr() on the type for them, we have to
|
||
|
# look through the MRO dicts ourself.
|
||
|
if name not in self._local_type_get_descriptors:
|
||
|
# Not a descriptor, can't execute code. So all we need is
|
||
|
# the return value of getattr() on our type.
|
||
|
return getattr(self._local_type, name)
|
||
|
|
||
|
for base in self._local_type.mro():
|
||
|
bd = base.__dict__
|
||
|
if name in bd:
|
||
|
attr_on_type = bd[name]
|
||
|
result = type(attr_on_type).__get__(attr_on_type, self, self._local_type)
|
||
|
return result
|
||
|
|
||
|
# It wasn't in the dict and it wasn't in the type.
|
||
|
# So the next step is to invoke type(self)__getattr__, if it
|
||
|
# exists, otherwise raise an AttributeError.
|
||
|
# we will invoke type(self).__getattr__ or raise an attribute error.
|
||
|
if hasattr(self._local_type, '__getattr__'):
|
||
|
return self._local_type.__getattr__(self, name)
|
||
|
raise AttributeError("%r object has no attribute '%s'"
|
||
|
% (self._local_type.__name__, name))
|
||
|
|
||
|
def __setattr__(self, name, value):
|
||
|
if name == '__dict__':
|
||
|
raise AttributeError(
|
||
|
"%r object attribute '__dict__' is read-only"
|
||
|
% type(self))
|
||
|
|
||
|
if name in _local_attrs:
|
||
|
object.__setattr__(self, name, value)
|
||
|
return
|
||
|
|
||
|
dct = _local_get_dict(self)
|
||
|
|
||
|
if self._local_type is local:
|
||
|
# Optimization: If we're not subclassed, we can't
|
||
|
# have data descriptors, so this goes right in the dict.
|
||
|
dct[name] = value
|
||
|
return
|
||
|
|
||
|
if name in self._local_type_vars:
|
||
|
if name in self._local_type_set_descriptors:
|
||
|
type_attr = getattr(self._local_type, name, _marker)
|
||
|
# A data descriptor, like a property or a slot.
|
||
|
type(type_attr).__set__(type_attr, self, value)
|
||
|
return
|
||
|
# Otherwise it goes directly in the dict
|
||
|
dct[name] = value
|
||
|
|
||
|
def __delattr__(self, name):
|
||
|
if name == '__dict__':
|
||
|
raise AttributeError(
|
||
|
"%r object attribute '__dict__' is read-only"
|
||
|
% self.__class__.__name__)
|
||
|
|
||
|
if name in self._local_type_vars:
|
||
|
if name in self._local_type_del_descriptors:
|
||
|
# A data descriptor, like a property or a slot.
|
||
|
type_attr = getattr(self._local_type, name, _marker)
|
||
|
type(type_attr).__delete__(type_attr, self)
|
||
|
return
|
||
|
# Otherwise it goes directly in the dict
|
||
|
|
||
|
# Begin inlined function _get_dict()
|
||
|
dct = _local_get_dict(self)
|
||
|
|
||
|
try:
|
||
|
del dct[name]
|
||
|
except KeyError:
|
||
|
raise AttributeError(name)
|
||
|
|
||
|
def __copy__(self):
|
||
|
impl = self._local__impl
|
||
|
entry = impl.dicts[id(getcurrent())] # pylint:disable=undefined-variable
|
||
|
|
||
|
dct = entry.localdict
|
||
|
duplicate = copy(dct)
|
||
|
|
||
|
cls = type(self)
|
||
|
instance = cls(*impl.localargs, **impl.localkwargs)
|
||
|
_local__copy_dict_from(instance, impl, duplicate)
|
||
|
return instance
|
||
|
|
||
|
def _local__copy_dict_from(self, impl, duplicate):
|
||
|
current = getcurrent() # pylint:disable=undefined-variable
|
||
|
currentId = id(current)
|
||
|
new_impl = self._local__impl
|
||
|
assert new_impl is not impl
|
||
|
entry = new_impl.dicts[currentId]
|
||
|
new_impl.dicts[currentId] = _localimpl_dict_entry(entry.wrgreenlet, duplicate)
|
||
|
|
||
|
def _local_find_descriptors(self):
|
||
|
type_self = type(self)
|
||
|
gets = set()
|
||
|
dels = set()
|
||
|
set_or_del = set()
|
||
|
sets = set()
|
||
|
mro = list(type_self.mro())
|
||
|
|
||
|
for attr_name in dir(type_self):
|
||
|
# Conventionally, descriptors when called on a class
|
||
|
# return themself, but not all do. Notable exceptions are
|
||
|
# in the zope.interface package, where things like __provides__
|
||
|
# return other class attributes. So we can't use getattr, and instead
|
||
|
# walk up the dicts
|
||
|
for base in mro:
|
||
|
bd = base.__dict__
|
||
|
if attr_name in bd:
|
||
|
attr = bd[attr_name]
|
||
|
break
|
||
|
else:
|
||
|
raise AttributeError(attr_name)
|
||
|
|
||
|
type_attr = type(attr)
|
||
|
if hasattr(type_attr, '__get__'):
|
||
|
gets.add(attr_name)
|
||
|
if hasattr(type_attr, '__delete__'):
|
||
|
dels.add(attr_name)
|
||
|
set_or_del.add(attr_name)
|
||
|
if hasattr(type_attr, '__set__'):
|
||
|
sets.add(attr_name)
|
||
|
|
||
|
return (gets, dels, set_or_del, sets)
|
||
|
|
||
|
# Cython doesn't let us use __new__, it requires
|
||
|
# __cinit__. But we need __new__ if we're not compiled
|
||
|
# (e.g., on PyPy). So we set it at runtime. Cython
|
||
|
# will raise an error if we're compiled.
|
||
|
def __new__(cls, *args, **kw):
|
||
|
self = super(local, cls).__new__(cls)
|
||
|
# We get the cls in *args for some reason
|
||
|
# too when we do it this way....except on PyPy3, which does
|
||
|
# not *unless* it's wrapped in a classmethod (which it is)
|
||
|
self.__cinit__(*args[1:], **kw)
|
||
|
return self
|
||
|
|
||
|
try:
|
||
|
# PyPy2/3 and CPython handle adding a __new__ to the class
|
||
|
# in different ways. In CPython and PyPy3, it must be wrapped with classmethod;
|
||
|
# in PyPy2, it must not. In either case, the args that get passed to
|
||
|
# it are stil wrong.
|
||
|
local.__new__ = 'None'
|
||
|
except TypeError: # pragma: no cover
|
||
|
# Must be compiled
|
||
|
pass
|
||
|
else:
|
||
|
from gevent._compat import PYPY
|
||
|
from gevent._compat import PY2
|
||
|
if PYPY and PY2:
|
||
|
local.__new__ = __new__
|
||
|
else:
|
||
|
local.__new__ = classmethod(__new__)
|
||
|
|
||
|
del PYPY
|
||
|
del PY2
|
||
|
|
||
|
_init()
|
||
|
|
||
|
from gevent._util import import_c_accel
|
||
|
import_c_accel(globals(), 'gevent._local')
|