openmedialibrary_platform/Darwin/lib/python2.7/site-packages/twisted/internet/defer.py
2014-05-16 01:20:41 +02:00

1623 lines
57 KiB
Python

# -*- test-case-name: twisted.test.test_defer,twisted.test.test_defgen,twisted.internet.test.test_inlinecb -*-
# Copyright (c) Twisted Matrix Laboratories.
# See LICENSE for details.
"""
Support for results that aren't immediately available.
Maintainer: Glyph Lefkowitz
@var _NO_RESULT: The result used to represent the fact that there is no
result. B{Never ever ever use this as an actual result for a Deferred}. You
have been warned.
@var _CONTINUE: A marker left in L{Deferred.callbacks} to indicate a Deferred
chain. Always accompanied by a Deferred instance in the args tuple pointing
at the Deferred which is chained to the Deferred which has this marker.
"""
from __future__ import division, absolute_import
import traceback
import types
import warnings
from sys import exc_info
from functools import wraps
# Twisted imports
from twisted.python.compat import cmp, comparable
from twisted.python import lockfile, log, failure
from twisted.python.deprecate import warnAboutFunction
class AlreadyCalledError(Exception):
pass
class CancelledError(Exception):
"""
This error is raised by default when a L{Deferred} is cancelled.
"""
class TimeoutError(Exception):
"""
This exception is deprecated. It is used only by the deprecated
L{Deferred.setTimeout} method.
"""
def logError(err):
log.err(err)
return err
def succeed(result):
"""
Return a L{Deferred} that has already had C{.callback(result)} called.
This is useful when you're writing synchronous code to an
asynchronous interface: i.e., some code is calling you expecting a
L{Deferred} result, but you don't actually need to do anything
asynchronous. Just return C{defer.succeed(theResult)}.
See L{fail} for a version of this function that uses a failing
L{Deferred} rather than a successful one.
@param result: The result to give to the Deferred's 'callback'
method.
@rtype: L{Deferred}
"""
d = Deferred()
d.callback(result)
return d
def fail(result=None):
"""
Return a L{Deferred} that has already had C{.errback(result)} called.
See L{succeed}'s docstring for rationale.
@param result: The same argument that L{Deferred.errback} takes.
@raise NoCurrentExceptionError: If C{result} is C{None} but there is no
current exception state.
@rtype: L{Deferred}
"""
d = Deferred()
d.errback(result)
return d
def execute(callable, *args, **kw):
"""
Create a L{Deferred} from a callable and arguments.
Call the given function with the given arguments. Return a L{Deferred}
which has been fired with its callback as the result of that invocation
or its C{errback} with a L{Failure} for the exception thrown.
"""
try:
result = callable(*args, **kw)
except:
return fail()
else:
return succeed(result)
def maybeDeferred(f, *args, **kw):
"""
Invoke a function that may or may not return a L{Deferred}.
Call the given function with the given arguments. If the returned
object is a L{Deferred}, return it. If the returned object is a L{Failure},
wrap it with L{fail} and return it. Otherwise, wrap it in L{succeed} and
return it. If an exception is raised, convert it to a L{Failure}, wrap it
in L{fail}, and then return it.
@type f: Any callable
@param f: The callable to invoke
@param args: The arguments to pass to C{f}
@param kw: The keyword arguments to pass to C{f}
@rtype: L{Deferred}
@return: The result of the function call, wrapped in a L{Deferred} if
necessary.
"""
try:
result = f(*args, **kw)
except:
return fail(failure.Failure(captureVars=Deferred.debug))
if isinstance(result, Deferred):
return result
elif isinstance(result, failure.Failure):
return fail(result)
else:
return succeed(result)
def timeout(deferred):
deferred.errback(failure.Failure(TimeoutError("Callback timed out")))
def passthru(arg):
return arg
def setDebugging(on):
"""
Enable or disable L{Deferred} debugging.
When debugging is on, the call stacks from creation and invocation are
recorded, and added to any L{AlreadyCalledErrors} we raise.
"""
Deferred.debug=bool(on)
def getDebugging():
"""
Determine whether L{Deferred} debugging is enabled.
"""
return Deferred.debug
# See module docstring.
_NO_RESULT = object()
_CONTINUE = object()
class Deferred:
"""
This is a callback which will be put off until later.
Why do we want this? Well, in cases where a function in a threaded
program would block until it gets a result, for Twisted it should
not block. Instead, it should return a L{Deferred}.
This can be implemented for protocols that run over the network by
writing an asynchronous protocol for L{twisted.internet}. For methods
that come from outside packages that are not under our control, we use
threads (see for example L{twisted.enterprise.adbapi}).
For more information about Deferreds, see doc/core/howto/defer.html or
U{http://twistedmatrix.com/documents/current/core/howto/defer.html}
When creating a Deferred, you may provide a canceller function, which
will be called by d.cancel() to let you do any clean-up necessary if the
user decides not to wait for the deferred to complete.
@ivar called: A flag which is C{False} until either C{callback} or
C{errback} is called and afterwards always C{True}.
@type called: C{bool}
@ivar paused: A counter of how many unmatched C{pause} calls have been made
on this instance.
@type paused: C{int}
@ivar _suppressAlreadyCalled: A flag used by the cancellation mechanism
which is C{True} if the Deferred has no canceller and has been
cancelled, C{False} otherwise. If C{True}, it can be expected that
C{callback} or C{errback} will eventually be called and the result
should be silently discarded.
@type _suppressAlreadyCalled: C{bool}
@ivar _runningCallbacks: A flag which is C{True} while this instance is
executing its callback chain, used to stop recursive execution of
L{_runCallbacks}
@type _runningCallbacks: C{bool}
@ivar _chainedTo: If this Deferred is waiting for the result of another
Deferred, this is a reference to the other Deferred. Otherwise, C{None}.
"""
called = False
paused = 0
_debugInfo = None
_suppressAlreadyCalled = False
# Are we currently running a user-installed callback? Meant to prevent
# recursive running of callbacks when a reentrant call to add a callback is
# used.
_runningCallbacks = False
# Keep this class attribute for now, for compatibility with code that
# sets it directly.
debug = False
_chainedTo = None
def __init__(self, canceller=None):
"""
Initialize a L{Deferred}.
@param canceller: a callable used to stop the pending operation
scheduled by this L{Deferred} when L{Deferred.cancel} is
invoked. The canceller will be passed the deferred whose
cancelation is requested (i.e., self).
If a canceller is not given, or does not invoke its argument's
C{callback} or C{errback} method, L{Deferred.cancel} will
invoke L{Deferred.errback} with a L{CancelledError}.
Note that if a canceller is not given, C{callback} or
C{errback} may still be invoked exactly once, even though
defer.py will have already invoked C{errback}, as described
above. This allows clients of code which returns a L{Deferred}
to cancel it without requiring the L{Deferred} instantiator to
provide any specific implementation support for cancellation.
New in 10.1.
@type canceller: a 1-argument callable which takes a L{Deferred}. The
return result is ignored.
"""
self.callbacks = []
self._canceller = canceller
if self.debug:
self._debugInfo = DebugInfo()
self._debugInfo.creator = traceback.format_stack()[:-1]
def addCallbacks(self, callback, errback=None,
callbackArgs=None, callbackKeywords=None,
errbackArgs=None, errbackKeywords=None):
"""
Add a pair of callbacks (success and error) to this L{Deferred}.
These will be executed when the 'master' callback is run.
@return: C{self}.
@rtype: a L{Deferred}
"""
assert callable(callback)
assert errback == None or callable(errback)
cbs = ((callback, callbackArgs, callbackKeywords),
(errback or (passthru), errbackArgs, errbackKeywords))
self.callbacks.append(cbs)
if self.called:
self._runCallbacks()
return self
def addCallback(self, callback, *args, **kw):
"""
Convenience method for adding just a callback.
See L{addCallbacks}.
"""
return self.addCallbacks(callback, callbackArgs=args,
callbackKeywords=kw)
def addErrback(self, errback, *args, **kw):
"""
Convenience method for adding just an errback.
See L{addCallbacks}.
"""
return self.addCallbacks(passthru, errback,
errbackArgs=args,
errbackKeywords=kw)
def addBoth(self, callback, *args, **kw):
"""
Convenience method for adding a single callable as both a callback
and an errback.
See L{addCallbacks}.
"""
return self.addCallbacks(callback, callback,
callbackArgs=args, errbackArgs=args,
callbackKeywords=kw, errbackKeywords=kw)
def chainDeferred(self, d):
"""
Chain another L{Deferred} to this L{Deferred}.
This method adds callbacks to this L{Deferred} to call C{d}'s callback
or errback, as appropriate. It is merely a shorthand way of performing
the following::
self.addCallbacks(d.callback, d.errback)
When you chain a deferred d2 to another deferred d1 with
d1.chainDeferred(d2), you are making d2 participate in the callback
chain of d1. Thus any event that fires d1 will also fire d2.
However, the converse is B{not} true; if d2 is fired d1 will not be
affected.
Note that unlike the case where chaining is caused by a L{Deferred}
being returned from a callback, it is possible to cause the call
stack size limit to be exceeded by chaining many L{Deferred}s
together with C{chainDeferred}.
@return: C{self}.
@rtype: a L{Deferred}
"""
d._chainedTo = self
return self.addCallbacks(d.callback, d.errback)
def callback(self, result):
"""
Run all success callbacks that have been added to this L{Deferred}.
Each callback will have its result passed as the first argument to
the next; this way, the callbacks act as a 'processing chain'. If
the success-callback returns a L{Failure} or raises an L{Exception},
processing will continue on the *error* callback chain. If a
callback (or errback) returns another L{Deferred}, this L{Deferred}
will be chained to it (and further callbacks will not run until that
L{Deferred} has a result).
An instance of L{Deferred} may only have either L{callback} or
L{errback} called on it, and only once.
@param result: The object which will be passed to the first callback
added to this L{Deferred} (via L{addCallback}).
@raise AlreadyCalledError: If L{callback} or L{errback} has already been
called on this L{Deferred}.
"""
assert not isinstance(result, Deferred)
self._startRunCallbacks(result)
def errback(self, fail=None):
"""
Run all error callbacks that have been added to this L{Deferred}.
Each callback will have its result passed as the first
argument to the next; this way, the callbacks act as a
'processing chain'. Also, if the error-callback returns a non-Failure
or doesn't raise an L{Exception}, processing will continue on the
*success*-callback chain.
If the argument that's passed to me is not a L{failure.Failure} instance,
it will be embedded in one. If no argument is passed, a
L{failure.Failure} instance will be created based on the current
traceback stack.
Passing a string as `fail' is deprecated, and will be punished with
a warning message.
An instance of L{Deferred} may only have either L{callback} or
L{errback} called on it, and only once.
@param fail: The L{Failure} object which will be passed to the first
errback added to this L{Deferred} (via L{addErrback}).
Alternatively, a L{Exception} instance from which a L{Failure} will
be constructed (with no traceback) or C{None} to create a L{Failure}
instance from the current exception state (with a traceback).
@raise AlreadyCalledError: If L{callback} or L{errback} has already been
called on this L{Deferred}.
@raise NoCurrentExceptionError: If C{fail} is C{None} but there is
no current exception state.
"""
if fail is None:
fail = failure.Failure(captureVars=self.debug)
elif not isinstance(fail, failure.Failure):
fail = failure.Failure(fail)
self._startRunCallbacks(fail)
def pause(self):
"""
Stop processing on a L{Deferred} until L{unpause}() is called.
"""
self.paused = self.paused + 1
def unpause(self):
"""
Process all callbacks made since L{pause}() was called.
"""
self.paused = self.paused - 1
if self.paused:
return
if self.called:
self._runCallbacks()
def cancel(self):
"""
Cancel this L{Deferred}.
If the L{Deferred} has not yet had its C{errback} or C{callback} method
invoked, call the canceller function provided to the constructor. If
that function does not invoke C{callback} or C{errback}, or if no
canceller function was provided, errback with L{CancelledError}.
If this L{Deferred} is waiting on another L{Deferred}, forward the
cancellation to the other L{Deferred}.
"""
if not self.called:
canceller = self._canceller
if canceller:
canceller(self)
else:
# Arrange to eat the callback that will eventually be fired
# since there was no real canceller.
self._suppressAlreadyCalled = True
if not self.called:
# There was no canceller, or the canceller didn't call
# callback or errback.
self.errback(failure.Failure(CancelledError()))
elif isinstance(self.result, Deferred):
# Waiting for another deferred -- cancel it instead.
self.result.cancel()
def _startRunCallbacks(self, result):
if self.called:
if self._suppressAlreadyCalled:
self._suppressAlreadyCalled = False
return
if self.debug:
if self._debugInfo is None:
self._debugInfo = DebugInfo()
extra = "\n" + self._debugInfo._getDebugTracebacks()
raise AlreadyCalledError(extra)
raise AlreadyCalledError
if self.debug:
if self._debugInfo is None:
self._debugInfo = DebugInfo()
self._debugInfo.invoker = traceback.format_stack()[:-2]
self.called = True
self.result = result
self._runCallbacks()
def _continuation(self):
"""
Build a tuple of callback and errback with L{_continue} to be used by
L{_addContinue} and L{_removeContinue} on another Deferred.
"""
return ((_CONTINUE, (self,), None),
(_CONTINUE, (self,), None))
def _runCallbacks(self):
"""
Run the chain of callbacks once a result is available.
This consists of a simple loop over all of the callbacks, calling each
with the current result and making the current result equal to the
return value (or raised exception) of that call.
If C{self._runningCallbacks} is true, this loop won't run at all, since
it is already running above us on the call stack. If C{self.paused} is
true, the loop also won't run, because that's what it means to be
paused.
The loop will terminate before processing all of the callbacks if a
C{Deferred} without a result is encountered.
If a C{Deferred} I{with} a result is encountered, that result is taken
and the loop proceeds.
@note: The implementation is complicated slightly by the fact that
chaining (associating two Deferreds with each other such that one
will wait for the result of the other, as happens when a Deferred is
returned from a callback on another Deferred) is supported
iteratively rather than recursively, to avoid running out of stack
frames when processing long chains.
"""
if self._runningCallbacks:
# Don't recursively run callbacks
return
# Keep track of all the Deferreds encountered while propagating results
# up a chain. The way a Deferred gets onto this stack is by having
# added its _continuation() to the callbacks list of a second Deferred
# and then that second Deferred being fired. ie, if ever had _chainedTo
# set to something other than None, you might end up on this stack.
chain = [self]
while chain:
current = chain[-1]
if current.paused:
# This Deferred isn't going to produce a result at all. All the
# Deferreds up the chain waiting on it will just have to...
# wait.
return
finished = True
current._chainedTo = None
while current.callbacks:
item = current.callbacks.pop(0)
callback, args, kw = item[
isinstance(current.result, failure.Failure)]
args = args or ()
kw = kw or {}
# Avoid recursion if we can.
if callback is _CONTINUE:
# Give the waiting Deferred our current result and then
# forget about that result ourselves.
chainee = args[0]
chainee.result = current.result
current.result = None
# Making sure to update _debugInfo
if current._debugInfo is not None:
current._debugInfo.failResult = None
chainee.paused -= 1
chain.append(chainee)
# Delay cleaning this Deferred and popping it from the chain
# until after we've dealt with chainee.
finished = False
break
try:
current._runningCallbacks = True
try:
current.result = callback(current.result, *args, **kw)
if current.result is current:
warnAboutFunction(
callback,
"Callback returned the Deferred "
"it was attached to; this breaks the "
"callback chain and will raise an "
"exception in the future.")
finally:
current._runningCallbacks = False
except:
# Including full frame information in the Failure is quite
# expensive, so we avoid it unless self.debug is set.
current.result = failure.Failure(captureVars=self.debug)
else:
if isinstance(current.result, Deferred):
# The result is another Deferred. If it has a result,
# we can take it and keep going.
resultResult = getattr(current.result, 'result', _NO_RESULT)
if resultResult is _NO_RESULT or isinstance(resultResult, Deferred) or current.result.paused:
# Nope, it didn't. Pause and chain.
current.pause()
current._chainedTo = current.result
# Note: current.result has no result, so it's not
# running its callbacks right now. Therefore we can
# append to the callbacks list directly instead of
# using addCallbacks.
current.result.callbacks.append(current._continuation())
break
else:
# Yep, it did. Steal it.
current.result.result = None
# Make sure _debugInfo's failure state is updated.
if current.result._debugInfo is not None:
current.result._debugInfo.failResult = None
current.result = resultResult
if finished:
# As much of the callback chain - perhaps all of it - as can be
# processed right now has been. The current Deferred is waiting on
# another Deferred or for more callbacks. Before finishing with it,
# make sure its _debugInfo is in the proper state.
if isinstance(current.result, failure.Failure):
# Stash the Failure in the _debugInfo for unhandled error
# reporting.
current.result.cleanFailure()
if current._debugInfo is None:
current._debugInfo = DebugInfo()
current._debugInfo.failResult = current.result
else:
# Clear out any Failure in the _debugInfo, since the result
# is no longer a Failure.
if current._debugInfo is not None:
current._debugInfo.failResult = None
# This Deferred is done, pop it from the chain and move back up
# to the Deferred which supplied us with our result.
chain.pop()
def __str__(self):
"""
Return a string representation of this C{Deferred}.
"""
cname = self.__class__.__name__
result = getattr(self, 'result', _NO_RESULT)
myID = id(self)
if self._chainedTo is not None:
result = ' waiting on Deferred at 0x%x' % (id(self._chainedTo),)
elif result is _NO_RESULT:
result = ''
else:
result = ' current result: %r' % (result,)
return "<%s at 0x%x%s>" % (cname, myID, result)
__repr__ = __str__
class DebugInfo:
"""
Deferred debug helper.
"""
failResult = None
def _getDebugTracebacks(self):
info = ''
if hasattr(self, "creator"):
info += " C: Deferred was created:\n C:"
info += "".join(self.creator).rstrip().replace("\n","\n C:")
info += "\n"
if hasattr(self, "invoker"):
info += " I: First Invoker was:\n I:"
info += "".join(self.invoker).rstrip().replace("\n","\n I:")
info += "\n"
return info
def __del__(self):
"""
Print tracebacks and die.
If the *last* (and I do mean *last*) callback leaves me in an error
state, print a traceback (if said errback is a L{Failure}).
"""
if self.failResult is not None:
log.msg("Unhandled error in Deferred:", isError=True)
debugInfo = self._getDebugTracebacks()
if debugInfo != '':
log.msg("(debug: " + debugInfo + ")", isError=True)
log.err(self.failResult)
@comparable
class FirstError(Exception):
"""
First error to occur in a L{DeferredList} if C{fireOnOneErrback} is set.
@ivar subFailure: The L{Failure} that occurred.
@type subFailure: L{Failure}
@ivar index: The index of the L{Deferred} in the L{DeferredList} where
it happened.
@type index: C{int}
"""
def __init__(self, failure, index):
Exception.__init__(self, failure, index)
self.subFailure = failure
self.index = index
def __repr__(self):
"""
The I{repr} of L{FirstError} instances includes the repr of the
wrapped failure's exception and the index of the L{FirstError}.
"""
return 'FirstError[#%d, %r]' % (self.index, self.subFailure.value)
def __str__(self):
"""
The I{str} of L{FirstError} instances includes the I{str} of the
entire wrapped failure (including its traceback and exception) and
the index of the L{FirstError}.
"""
return 'FirstError[#%d, %s]' % (self.index, self.subFailure)
def __cmp__(self, other):
"""
Comparison between L{FirstError} and other L{FirstError} instances
is defined as the comparison of the index and sub-failure of each
instance. L{FirstError} instances don't compare equal to anything
that isn't a L{FirstError} instance.
@since: 8.2
"""
if isinstance(other, FirstError):
return cmp(
(self.index, self.subFailure),
(other.index, other.subFailure))
return -1
class DeferredList(Deferred):
"""
L{DeferredList} is a tool for collecting the results of several Deferreds.
This tracks a list of L{Deferred}s for their results, and makes a single
callback when they have all completed. By default, the ultimate result is a
list of (success, result) tuples, 'success' being a boolean.
L{DeferredList} exposes the same API that L{Deferred} does, so callbacks and
errbacks can be added to it in the same way.
L{DeferredList} is implemented by adding callbacks and errbacks to each
L{Deferred} in the list passed to it. This means callbacks and errbacks
added to the Deferreds before they are passed to L{DeferredList} will change
the result that L{DeferredList} sees (i.e., L{DeferredList} is not special).
Callbacks and errbacks can also be added to the Deferreds after they are
passed to L{DeferredList} and L{DeferredList} may change the result that
they see.
See the documentation for the C{__init__} arguments for more information.
@ivar _deferredList: The C{list} of L{Deferred}s to track.
"""
fireOnOneCallback = False
fireOnOneErrback = False
def __init__(self, deferredList, fireOnOneCallback=False,
fireOnOneErrback=False, consumeErrors=False):
"""
Initialize a DeferredList.
@param deferredList: The list of deferreds to track.
@type deferredList: C{list} of L{Deferred}s
@param fireOnOneCallback: (keyword param) a flag indicating that this
L{DeferredList} will fire when the first L{Deferred} in
C{deferredList} fires with a non-failure result without waiting for
any of the other Deferreds. When this flag is set, the DeferredList
will fire with a two-tuple: the first element is the result of the
Deferred which fired; the second element is the index in
C{deferredList} of that Deferred.
@type fireOnOneCallback: C{bool}
@param fireOnOneErrback: (keyword param) a flag indicating that this
L{DeferredList} will fire when the first L{Deferred} in
C{deferredList} fires with a failure result without waiting for any
of the other Deferreds. When this flag is set, if a Deferred in the
list errbacks, the DeferredList will errback with a L{FirstError}
failure wrapping the failure of that Deferred.
@type fireOnOneErrback: C{bool}
@param consumeErrors: (keyword param) a flag indicating that failures in
any of the included L{Deferreds} should not be propagated to
errbacks added to the individual L{Deferreds} after this
L{DeferredList} is constructed. After constructing the
L{DeferredList}, any errors in the individual L{Deferred}s will be
converted to a callback result of C{None}. This is useful to
prevent spurious 'Unhandled error in Deferred' messages from being
logged. This does not prevent C{fireOnOneErrback} from working.
@type consumeErrors: C{bool}
"""
self._deferredList = list(deferredList)
self.resultList = [None] * len(self._deferredList)
Deferred.__init__(self)
if len(self._deferredList) == 0 and not fireOnOneCallback:
self.callback(self.resultList)
# These flags need to be set *before* attaching callbacks to the
# deferreds, because the callbacks use these flags, and will run
# synchronously if any of the deferreds are already fired.
self.fireOnOneCallback = fireOnOneCallback
self.fireOnOneErrback = fireOnOneErrback
self.consumeErrors = consumeErrors
self.finishedCount = 0
index = 0
for deferred in self._deferredList:
deferred.addCallbacks(self._cbDeferred, self._cbDeferred,
callbackArgs=(index,SUCCESS),
errbackArgs=(index,FAILURE))
index = index + 1
def _cbDeferred(self, result, index, succeeded):
"""
(internal) Callback for when one of my deferreds fires.
"""
self.resultList[index] = (succeeded, result)
self.finishedCount += 1
if not self.called:
if succeeded == SUCCESS and self.fireOnOneCallback:
self.callback((result, index))
elif succeeded == FAILURE and self.fireOnOneErrback:
self.errback(failure.Failure(FirstError(result, index)))
elif self.finishedCount == len(self.resultList):
self.callback(self.resultList)
if succeeded == FAILURE and self.consumeErrors:
result = None
return result
def cancel(self):
"""
Cancel this L{DeferredList}.
If the L{DeferredList} hasn't fired yet, cancel every L{Deferred} in
the list.
If the L{DeferredList} has fired, including the case where the
C{fireOnOneCallback}/C{fireOnOneErrback} flag is set and the
L{DeferredList} fires because one L{Deferred} in the list fires with a
non-failure/failure result, do nothing in the C{cancel} method.
"""
if not self.called:
for deferred in self._deferredList:
try:
deferred.cancel()
except:
log.err(
_why="Exception raised from user supplied canceller")
def _parseDListResult(l, fireOnOneErrback=False):
if __debug__:
for success, value in l:
assert success
return [x[1] for x in l]
def gatherResults(deferredList, consumeErrors=False):
"""
Returns, via a L{Deferred}, a list with the results of the given
L{Deferred}s - in effect, a "join" of multiple deferred operations.
The returned L{Deferred} will fire when I{all} of the provided L{Deferred}s
have fired, or when any one of them has failed.
This method can be cancelled by calling the C{cancel} method of the
L{Deferred}, all the L{Deferred}s in the list will be cancelled.
This differs from L{DeferredList} in that you don't need to parse
the result for success/failure.
@type deferredList: C{list} of L{Deferred}s
@param consumeErrors: (keyword param) a flag, defaulting to False,
indicating that failures in any of the given L{Deferreds} should not be
propagated to errbacks added to the individual L{Deferreds} after this
L{gatherResults} invocation. Any such errors in the individual
L{Deferred}s will be converted to a callback result of C{None}. This
is useful to prevent spurious 'Unhandled error in Deferred' messages
from being logged. This parameter is available since 11.1.0.
@type consumeErrors: C{bool}
"""
d = DeferredList(deferredList, fireOnOneErrback=True,
consumeErrors=consumeErrors)
d.addCallback(_parseDListResult)
return d
# Constants for use with DeferredList
SUCCESS = True
FAILURE = False
## deferredGenerator
class waitForDeferred:
"""
See L{deferredGenerator}.
"""
def __init__(self, d):
if not isinstance(d, Deferred):
raise TypeError("You must give waitForDeferred a Deferred. You gave it %r." % (d,))
self.d = d
def getResult(self):
if isinstance(self.result, failure.Failure):
self.result.raiseException()
return self.result
def _deferGenerator(g, deferred):
"""
See L{deferredGenerator}.
"""
result = None
# This function is complicated by the need to prevent unbounded recursion
# arising from repeatedly yielding immediately ready deferreds. This while
# loop and the waiting variable solve that by manually unfolding the
# recursion.
waiting = [True, # defgen is waiting for result?
None] # result
while 1:
try:
result = next(g)
except StopIteration:
deferred.callback(result)
return deferred
except:
deferred.errback()
return deferred
# Deferred.callback(Deferred) raises an error; we catch this case
# early here and give a nicer error message to the user in case
# they yield a Deferred.
if isinstance(result, Deferred):
return fail(TypeError("Yield waitForDeferred(d), not d!"))
if isinstance(result, waitForDeferred):
# a waitForDeferred was yielded, get the result.
# Pass result in so it don't get changed going around the loop
# This isn't a problem for waiting, as it's only reused if
# gotResult has already been executed.
def gotResult(r, result=result):
result.result = r
if waiting[0]:
waiting[0] = False
waiting[1] = r
else:
_deferGenerator(g, deferred)
result.d.addBoth(gotResult)
if waiting[0]:
# Haven't called back yet, set flag so that we get reinvoked
# and return from the loop
waiting[0] = False
return deferred
# Reset waiting to initial values for next loop
waiting[0] = True
waiting[1] = None
result = None
def deferredGenerator(f):
"""
L{deferredGenerator} and L{waitForDeferred} help you write
L{Deferred}-using code that looks like a regular sequential function.
Consider the use of L{inlineCallbacks} instead, which can accomplish
the same thing in a more concise manner.
There are two important functions involved: L{waitForDeferred}, and
L{deferredGenerator}. They are used together, like this::
@deferredGenerator
def thingummy():
thing = waitForDeferred(makeSomeRequestResultingInDeferred())
yield thing
thing = thing.getResult()
print thing #the result! hoorj!
L{waitForDeferred} returns something that you should immediately yield; when
your generator is resumed, calling C{thing.getResult()} will either give you
the result of the L{Deferred} if it was a success, or raise an exception if it
was a failure. Calling C{getResult} is B{absolutely mandatory}. If you do
not call it, I{your program will not work}.
L{deferredGenerator} takes one of these waitForDeferred-using generator
functions and converts it into a function that returns a L{Deferred}. The
result of the L{Deferred} will be the last value that your generator yielded
unless the last value is a L{waitForDeferred} instance, in which case the
result will be C{None}. If the function raises an unhandled exception, the
L{Deferred} will errback instead. Remember that C{return result} won't work;
use C{yield result; return} in place of that.
Note that not yielding anything from your generator will make the L{Deferred}
result in C{None}. Yielding a L{Deferred} from your generator is also an error
condition; always yield C{waitForDeferred(d)} instead.
The L{Deferred} returned from your deferred generator may also errback if your
generator raised an exception. For example::
@deferredGenerator
def thingummy():
thing = waitForDeferred(makeSomeRequestResultingInDeferred())
yield thing
thing = thing.getResult()
if thing == 'I love Twisted':
# will become the result of the Deferred
yield 'TWISTED IS GREAT!'
return
else:
# will trigger an errback
raise Exception('DESTROY ALL LIFE')
Put succinctly, these functions connect deferred-using code with this 'fake
blocking' style in both directions: L{waitForDeferred} converts from a
L{Deferred} to the 'blocking' style, and L{deferredGenerator} converts from the
'blocking' style to a L{Deferred}.
"""
@wraps(f)
def unwindGenerator(*args, **kwargs):
return _deferGenerator(f(*args, **kwargs), Deferred())
return unwindGenerator
## inlineCallbacks
class _DefGen_Return(BaseException):
def __init__(self, value):
self.value = value
def returnValue(val):
"""
Return val from a L{inlineCallbacks} generator.
Note: this is currently implemented by raising an exception
derived from L{BaseException}. You might want to change any
'except:' clauses to an 'except Exception:' clause so as not to
catch this exception.
Also: while this function currently will work when called from
within arbitrary functions called from within the generator, do
not rely upon this behavior.
"""
raise _DefGen_Return(val)
def _inlineCallbacks(result, g, deferred):
"""
See L{inlineCallbacks}.
"""
# This function is complicated by the need to prevent unbounded recursion
# arising from repeatedly yielding immediately ready deferreds. This while
# loop and the waiting variable solve that by manually unfolding the
# recursion.
waiting = [True, # waiting for result?
None] # result
while 1:
try:
# Send the last result back as the result of the yield expression.
isFailure = isinstance(result, failure.Failure)
if isFailure:
result = result.throwExceptionIntoGenerator(g)
else:
result = g.send(result)
except StopIteration:
# fell off the end, or "return" statement
deferred.callback(None)
return deferred
except _DefGen_Return as e:
# returnValue() was called; time to give a result to the original
# Deferred. First though, let's try to identify the potentially
# confusing situation which results when returnValue() is
# accidentally invoked from a different function, one that wasn't
# decorated with @inlineCallbacks.
# The traceback starts in this frame (the one for
# _inlineCallbacks); the next one down should be the application
# code.
appCodeTrace = exc_info()[2].tb_next
if isFailure:
# If we invoked this generator frame by throwing an exception
# into it, then throwExceptionIntoGenerator will consume an
# additional stack frame itself, so we need to skip that too.
appCodeTrace = appCodeTrace.tb_next
# Now that we've identified the frame being exited by the
# exception, let's figure out if returnValue was called from it
# directly. returnValue itself consumes a stack frame, so the
# application code will have a tb_next, but it will *not* have a
# second tb_next.
if appCodeTrace.tb_next.tb_next:
# If returnValue was invoked non-local to the frame which it is
# exiting, identify the frame that ultimately invoked
# returnValue so that we can warn the user, as this behavior is
# confusing.
ultimateTrace = appCodeTrace
while ultimateTrace.tb_next.tb_next:
ultimateTrace = ultimateTrace.tb_next
filename = ultimateTrace.tb_frame.f_code.co_filename
lineno = ultimateTrace.tb_lineno
warnings.warn_explicit(
"returnValue() in %r causing %r to exit: "
"returnValue should only be invoked by functions decorated "
"with inlineCallbacks" % (
ultimateTrace.tb_frame.f_code.co_name,
appCodeTrace.tb_frame.f_code.co_name),
DeprecationWarning, filename, lineno)
deferred.callback(e.value)
return deferred
except:
deferred.errback()
return deferred
if isinstance(result, Deferred):
# a deferred was yielded, get the result.
def gotResult(r):
if waiting[0]:
waiting[0] = False
waiting[1] = r
else:
_inlineCallbacks(r, g, deferred)
result.addBoth(gotResult)
if waiting[0]:
# Haven't called back yet, set flag so that we get reinvoked
# and return from the loop
waiting[0] = False
return deferred
result = waiting[1]
# Reset waiting to initial values for next loop. gotResult uses
# waiting, but this isn't a problem because gotResult is only
# executed once, and if it hasn't been executed yet, the return
# branch above would have been taken.
waiting[0] = True
waiting[1] = None
return deferred
def inlineCallbacks(f):
"""
inlineCallbacks helps you write L{Deferred}-using code that looks like a
regular sequential function. For example::
@inlineCallBacks
def thingummy():
thing = yield makeSomeRequestResultingInDeferred()
print(thing) # the result! hoorj!
When you call anything that results in a L{Deferred}, you can simply yield it;
your generator will automatically be resumed when the Deferred's result is
available. The generator will be sent the result of the L{Deferred} with the
'send' method on generators, or if the result was a failure, 'throw'.
Things that are not L{Deferred}s may also be yielded, and your generator
will be resumed with the same object sent back. This means C{yield}
performs an operation roughly equivalent to L{maybeDeferred}.
Your inlineCallbacks-enabled generator will return a L{Deferred} object, which
will result in the return value of the generator (or will fail with a
failure object if your generator raises an unhandled exception). Note that
you can't use C{return result} to return a value; use C{returnValue(result)}
instead. Falling off the end of the generator, or simply using C{return}
will cause the L{Deferred} to have a result of C{None}.
Be aware that L{returnValue} will not accept a L{Deferred} as a parameter.
If you believe the thing you'd like to return could be a L{Deferred}, do
this::
result = yield result
returnValue(result)
The L{Deferred} returned from your deferred generator may errback if your
generator raised an exception::
@inlineCallbacks
def thingummy():
thing = yield makeSomeRequestResultingInDeferred()
if thing == 'I love Twisted':
# will become the result of the Deferred
returnValue('TWISTED IS GREAT!')
else:
# will trigger an errback
raise Exception('DESTROY ALL LIFE')
"""
@wraps(f)
def unwindGenerator(*args, **kwargs):
try:
gen = f(*args, **kwargs)
except _DefGen_Return:
raise TypeError(
"inlineCallbacks requires %r to produce a generator; instead"
"caught returnValue being used in a non-generator" % (f,))
if not isinstance(gen, types.GeneratorType):
raise TypeError(
"inlineCallbacks requires %r to produce a generator; "
"instead got %r" % (f, gen))
return _inlineCallbacks(None, gen, Deferred())
return unwindGenerator
## DeferredLock/DeferredQueue
class _ConcurrencyPrimitive(object):
def __init__(self):
self.waiting = []
def _releaseAndReturn(self, r):
self.release()
return r
def run(*args, **kwargs):
"""
Acquire, run, release.
This function takes a callable as its first argument and any
number of other positional and keyword arguments. When the
lock or semaphore is acquired, the callable will be invoked
with those arguments.
The callable may return a L{Deferred}; if it does, the lock or
semaphore won't be released until that L{Deferred} fires.
@return: L{Deferred} of function result.
"""
if len(args) < 2:
if not args:
raise TypeError("run() takes at least 2 arguments, none given.")
raise TypeError("%s.run() takes at least 2 arguments, 1 given" % (
args[0].__class__.__name__,))
self, f = args[:2]
args = args[2:]
def execute(ignoredResult):
d = maybeDeferred(f, *args, **kwargs)
d.addBoth(self._releaseAndReturn)
return d
d = self.acquire()
d.addCallback(execute)
return d
class DeferredLock(_ConcurrencyPrimitive):
"""
A lock for event driven systems.
@ivar locked: C{True} when this Lock has been acquired, false at all other
times. Do not change this value, but it is useful to examine for the
equivalent of a "non-blocking" acquisition.
"""
locked = False
def _cancelAcquire(self, d):
"""
Remove a deferred d from our waiting list, as the deferred has been
canceled.
Note: We do not need to wrap this in a try/except to catch d not
being in self.waiting because this canceller will not be called if
d has fired. release() pops a deferred out of self.waiting and
calls it, so the canceller will no longer be called.
@param d: The deferred that has been canceled.
"""
self.waiting.remove(d)
def acquire(self):
"""
Attempt to acquire the lock. Returns a L{Deferred} that fires on
lock acquisition with the L{DeferredLock} as the value. If the lock
is locked, then the Deferred is placed at the end of a waiting list.
@return: a L{Deferred} which fires on lock acquisition.
@rtype: a L{Deferred}
"""
d = Deferred(canceller=self._cancelAcquire)
if self.locked:
self.waiting.append(d)
else:
self.locked = True
d.callback(self)
return d
def release(self):
"""
Release the lock. If there is a waiting list, then the first
L{Deferred} in that waiting list will be called back.
Should be called by whomever did the L{acquire}() when the shared
resource is free.
"""
assert self.locked, "Tried to release an unlocked lock"
self.locked = False
if self.waiting:
# someone is waiting to acquire lock
self.locked = True
d = self.waiting.pop(0)
d.callback(self)
class DeferredSemaphore(_ConcurrencyPrimitive):
"""
A semaphore for event driven systems.
If you are looking into this as a means of limiting parallelism, you might
find L{twisted.internet.task.Cooperator} more useful.
@ivar tokens: At most this many users may acquire this semaphore at
once.
@type tokens: C{int}
@ivar limit: The difference between C{tokens} and the number of users
which have currently acquired this semaphore.
@type limit: C{int}
"""
def __init__(self, tokens):
_ConcurrencyPrimitive.__init__(self)
if tokens < 1:
raise ValueError("DeferredSemaphore requires tokens >= 1")
self.tokens = tokens
self.limit = tokens
def _cancelAcquire(self, d):
"""
Remove a deferred d from our waiting list, as the deferred has been
canceled.
Note: We do not need to wrap this in a try/except to catch d not
being in self.waiting because this canceller will not be called if
d has fired. release() pops a deferred out of self.waiting and
calls it, so the canceller will no longer be called.
@param d: The deferred that has been canceled.
"""
self.waiting.remove(d)
def acquire(self):
"""
Attempt to acquire the token.
@return: a L{Deferred} which fires on token acquisition.
"""
assert self.tokens >= 0, "Internal inconsistency?? tokens should never be negative"
d = Deferred(canceller=self._cancelAcquire)
if not self.tokens:
self.waiting.append(d)
else:
self.tokens = self.tokens - 1
d.callback(self)
return d
def release(self):
"""
Release the token.
Should be called by whoever did the L{acquire}() when the shared
resource is free.
"""
assert self.tokens < self.limit, "Someone released me too many times: too many tokens!"
self.tokens = self.tokens + 1
if self.waiting:
# someone is waiting to acquire token
self.tokens = self.tokens - 1
d = self.waiting.pop(0)
d.callback(self)
class QueueOverflow(Exception):
pass
class QueueUnderflow(Exception):
pass
class DeferredQueue(object):
"""
An event driven queue.
Objects may be added as usual to this queue. When an attempt is
made to retrieve an object when the queue is empty, a L{Deferred} is
returned which will fire when an object becomes available.
@ivar size: The maximum number of objects to allow into the queue
at a time. When an attempt to add a new object would exceed this
limit, L{QueueOverflow} is raised synchronously. C{None} for no limit.
@ivar backlog: The maximum number of L{Deferred} gets to allow at
one time. When an attempt is made to get an object which would
exceed this limit, L{QueueUnderflow} is raised synchronously. C{None}
for no limit.
"""
def __init__(self, size=None, backlog=None):
self.waiting = []
self.pending = []
self.size = size
self.backlog = backlog
def _cancelGet(self, d):
"""
Remove a deferred d from our waiting list, as the deferred has been
canceled.
Note: We do not need to wrap this in a try/except to catch d not
being in self.waiting because this canceller will not be called if
d has fired. put() pops a deferred out of self.waiting and calls
it, so the canceller will no longer be called.
@param d: The deferred that has been canceled.
"""
self.waiting.remove(d)
def put(self, obj):
"""
Add an object to this queue.
@raise QueueOverflow: Too many objects are in this queue.
"""
if self.waiting:
self.waiting.pop(0).callback(obj)
elif self.size is None or len(self.pending) < self.size:
self.pending.append(obj)
else:
raise QueueOverflow()
def get(self):
"""
Attempt to retrieve and remove an object from the queue.
@return: a L{Deferred} which fires with the next object available in
the queue.
@raise QueueUnderflow: Too many (more than C{backlog})
L{Deferred}s are already waiting for an object from this queue.
"""
if self.pending:
return succeed(self.pending.pop(0))
elif self.backlog is None or len(self.waiting) < self.backlog:
d = Deferred(canceller=self._cancelGet)
self.waiting.append(d)
return d
else:
raise QueueUnderflow()
class AlreadyTryingToLockError(Exception):
"""
Raised when L{DeferredFilesystemLock.deferUntilLocked} is called twice on a
single L{DeferredFilesystemLock}.
"""
class DeferredFilesystemLock(lockfile.FilesystemLock):
"""
A L{FilesystemLock} that allows for a L{Deferred} to be fired when the lock is
acquired.
@ivar _scheduler: The object in charge of scheduling retries. In this
implementation this is parameterized for testing.
@ivar _interval: The retry interval for an L{IReactorTime} based scheduler.
@ivar _tryLockCall: A L{DelayedCall} based on C{_interval} that will manage
the next retry for aquiring the lock.
@ivar _timeoutCall: A L{DelayedCall} based on C{deferUntilLocked}'s timeout
argument. This is in charge of timing out our attempt to acquire the
lock.
"""
_interval = 1
_tryLockCall = None
_timeoutCall = None
def __init__(self, name, scheduler=None):
"""
@param name: The name of the lock to acquire
@param scheduler: An object which provides L{IReactorTime}
"""
lockfile.FilesystemLock.__init__(self, name)
if scheduler is None:
from twisted.internet import reactor
scheduler = reactor
self._scheduler = scheduler
def deferUntilLocked(self, timeout=None):
"""
Wait until we acquire this lock. This method is not safe for
concurrent use.
@type timeout: C{float} or C{int}
@param timeout: the number of seconds after which to time out if the
lock has not been acquired.
@return: a L{Deferred} which will callback when the lock is acquired, or
errback with a L{TimeoutError} after timing out or an
L{AlreadyTryingToLockError} if the L{deferUntilLocked} has already
been called and not successfully locked the file.
"""
if self._tryLockCall is not None:
return fail(
AlreadyTryingToLockError(
"deferUntilLocked isn't safe for concurrent use."))
def _cancelLock(reason):
"""
Cancel a L{DeferredFilesystemLock.deferUntilLocked} call.
@type reason: L{failure.Failure}
@param reason: The reason why the call is cancelled.
"""
self._tryLockCall.cancel()
self._tryLockCall = None
if self._timeoutCall is not None and self._timeoutCall.active():
self._timeoutCall.cancel()
self._timeoutCall = None
if self.lock():
d.callback(None)
else:
d.errback(reason)
d = Deferred(lambda deferred: _cancelLock(CancelledError()))
def _tryLock():
if self.lock():
if self._timeoutCall is not None:
self._timeoutCall.cancel()
self._timeoutCall = None
self._tryLockCall = None
d.callback(None)
else:
if timeout is not None and self._timeoutCall is None:
reason = failure.Failure(TimeoutError(
"Timed out aquiring lock: %s after %fs" % (
self.name,
timeout)))
self._timeoutCall = self._scheduler.callLater(
timeout, _cancelLock, reason)
self._tryLockCall = self._scheduler.callLater(
self._interval, _tryLock)
_tryLock()
return d
__all__ = ["Deferred", "DeferredList", "succeed", "fail", "FAILURE", "SUCCESS",
"AlreadyCalledError", "TimeoutError", "gatherResults",
"maybeDeferred",
"waitForDeferred", "deferredGenerator", "inlineCallbacks",
"returnValue",
"DeferredLock", "DeferredSemaphore", "DeferredQueue",
"DeferredFilesystemLock", "AlreadyTryingToLockError",
]