%PDF- %PDF-
Direktori : /proc/self/root/usr/lib/python3/dist-packages/twisted/application/ |
Current File : //proc/self/root/usr/lib/python3/dist-packages/twisted/application/internet.py |
# -*- test-case-name: twisted.application.test.test_internet,twisted.test.test_application,twisted.test.test_cooperator -*- # Copyright (c) Twisted Matrix Laboratories. # See LICENSE for details. """ Reactor-based Services Here are services to run clients, servers and periodic services using the reactor. If you want to run a server service, L{StreamServerEndpointService} defines a service that can wrap an arbitrary L{IStreamServerEndpoint <twisted.internet.interfaces.IStreamServerEndpoint>} as an L{IService}. See also L{twisted.application.strports.service} for constructing one of these directly from a descriptive string. Additionally, this module (dynamically) defines various Service subclasses that let you represent clients and servers in a Service hierarchy. Endpoints APIs should be preferred for stream server services, but since those APIs do not yet exist for clients or datagram services, many of these are still useful. They are as follows:: TCPServer, TCPClient, UNIXServer, UNIXClient, SSLServer, SSLClient, UDPServer, UNIXDatagramServer, UNIXDatagramClient, MulticastServer These classes take arbitrary arguments in their constructors and pass them straight on to their respective reactor.listenXXX or reactor.connectXXX calls. For example, the following service starts a web server on port 8080: C{TCPServer(8080, server.Site(r))}. See the documentation for the reactor.listen/connect* methods for more information. """ from random import random as _goodEnoughRandom from typing import List from automat import MethodicalMachine # type: ignore[import] from twisted.application import service from twisted.internet import task from twisted.internet.defer import ( CancelledError, Deferred, fail, maybeDeferred, succeed, ) from twisted.logger import Logger from twisted.python import log from twisted.python.failure import Failure def _maybeGlobalReactor(maybeReactor): """ @return: the argument, or the global reactor if the argument is L{None}. """ if maybeReactor is None: from twisted.internet import reactor return reactor else: return maybeReactor class _VolatileDataService(service.Service): volatile: List[str] = [] def __getstate__(self): d = service.Service.__getstate__(self) for attr in self.volatile: if attr in d: del d[attr] return d class _AbstractServer(_VolatileDataService): """ @cvar volatile: list of attribute to remove from pickling. @type volatile: C{list} @ivar method: the type of method to call on the reactor, one of B{TCP}, B{UDP}, B{SSL} or B{UNIX}. @type method: C{str} @ivar reactor: the current running reactor. @type reactor: a provider of C{IReactorTCP}, C{IReactorUDP}, C{IReactorSSL} or C{IReactorUnix}. @ivar _port: instance of port set when the service is started. @type _port: a provider of L{twisted.internet.interfaces.IListeningPort}. """ volatile = ["_port"] method: str = "" reactor = None _port = None def __init__(self, *args, **kwargs): self.args = args if "reactor" in kwargs: self.reactor = kwargs.pop("reactor") self.kwargs = kwargs def privilegedStartService(self): service.Service.privilegedStartService(self) self._port = self._getPort() def startService(self): service.Service.startService(self) if self._port is None: self._port = self._getPort() def stopService(self): service.Service.stopService(self) # TODO: if startup failed, should shutdown skip stopListening? # _port won't exist if self._port is not None: d = self._port.stopListening() del self._port return d def _getPort(self): """ Wrapper around the appropriate listen method of the reactor. @return: the port object returned by the listen method. @rtype: an object providing L{twisted.internet.interfaces.IListeningPort}. """ return getattr( _maybeGlobalReactor(self.reactor), "listen{}".format( self.method, ), )(*self.args, **self.kwargs) class _AbstractClient(_VolatileDataService): """ @cvar volatile: list of attribute to remove from pickling. @type volatile: C{list} @ivar method: the type of method to call on the reactor, one of B{TCP}, B{UDP}, B{SSL} or B{UNIX}. @type method: C{str} @ivar reactor: the current running reactor. @type reactor: a provider of C{IReactorTCP}, C{IReactorUDP}, C{IReactorSSL} or C{IReactorUnix}. @ivar _connection: instance of connection set when the service is started. @type _connection: a provider of L{twisted.internet.interfaces.IConnector}. """ volatile = ["_connection"] method: str = "" reactor = None _connection = None def __init__(self, *args, **kwargs): self.args = args if "reactor" in kwargs: self.reactor = kwargs.pop("reactor") self.kwargs = kwargs def startService(self): service.Service.startService(self) self._connection = self._getConnection() def stopService(self): service.Service.stopService(self) if self._connection is not None: self._connection.disconnect() del self._connection def _getConnection(self): """ Wrapper around the appropriate connect method of the reactor. @return: the port object returned by the connect method. @rtype: an object providing L{twisted.internet.interfaces.IConnector}. """ return getattr(_maybeGlobalReactor(self.reactor), f"connect{self.method}")( *self.args, **self.kwargs ) _clientDoc = """Connect to {tran} Call reactor.connect{tran} when the service starts, with the arguments given to the constructor. """ _serverDoc = """Serve {tran} clients Call reactor.listen{tran} when the service starts, with the arguments given to the constructor. When the service stops, stop listening. See twisted.internet.interfaces for documentation on arguments to the reactor method. """ class TCPServer(_AbstractServer): __doc__ = _serverDoc.format(tran="TCP") method = "TCP" class TCPClient(_AbstractClient): __doc__ = _clientDoc.format(tran="TCP") method = "TCP" class UNIXServer(_AbstractServer): __doc__ = _serverDoc.format(tran="UNIX") method = "UNIX" class UNIXClient(_AbstractClient): __doc__ = _clientDoc.format(tran="UNIX") method = "UNIX" class SSLServer(_AbstractServer): __doc__ = _serverDoc.format(tran="SSL") method = "SSL" class SSLClient(_AbstractClient): __doc__ = _clientDoc.format(tran="SSL") method = "SSL" class UDPServer(_AbstractServer): __doc__ = _serverDoc.format(tran="UDP") method = "UDP" class UNIXDatagramServer(_AbstractServer): __doc__ = _serverDoc.format(tran="UNIXDatagram") method = "UNIXDatagram" class UNIXDatagramClient(_AbstractClient): __doc__ = _clientDoc.format(tran="UNIXDatagram") method = "UNIXDatagram" class MulticastServer(_AbstractServer): __doc__ = _serverDoc.format(tran="Multicast") method = "Multicast" class TimerService(_VolatileDataService): """ Service to periodically call a function Every C{step} seconds call the given function with the given arguments. The service starts the calls when it starts, and cancels them when it stops. @ivar clock: Source of time. This defaults to L{None} which is causes L{twisted.internet.reactor} to be used. Feel free to set this to something else, but it probably ought to be set *before* calling L{startService}. @type clock: L{IReactorTime<twisted.internet.interfaces.IReactorTime>} @ivar call: Function and arguments to call periodically. @type call: L{tuple} of C{(callable, args, kwargs)} """ volatile = ["_loop", "_loopFinished"] def __init__(self, step, callable, *args, **kwargs): """ @param step: The number of seconds between calls. @type step: L{float} @param callable: Function to call @type callable: L{callable} @param args: Positional arguments to pass to function @param kwargs: Keyword arguments to pass to function """ self.step = step self.call = (callable, args, kwargs) self.clock = None def startService(self): service.Service.startService(self) callable, args, kwargs = self.call # we have to make a new LoopingCall each time we're started, because # an active LoopingCall remains active when serialized. If # LoopingCall were a _VolatileDataService, we wouldn't need to do # this. self._loop = task.LoopingCall(callable, *args, **kwargs) self._loop.clock = _maybeGlobalReactor(self.clock) self._loopFinished = self._loop.start(self.step, now=True) self._loopFinished.addErrback(self._failed) def _failed(self, why): # make a note that the LoopingCall is no longer looping, so we don't # try to shut it down a second time in stopService. I think this # should be in LoopingCall. -warner self._loop.running = False log.err(why) def stopService(self): """ Stop the service. @rtype: L{Deferred<defer.Deferred>} @return: a L{Deferred<defer.Deferred>} which is fired when the currently running call (if any) is finished. """ if self._loop.running: self._loop.stop() self._loopFinished.addCallback(lambda _: service.Service.stopService(self)) return self._loopFinished class CooperatorService(service.Service): """ Simple L{service.IService} which starts and stops a L{twisted.internet.task.Cooperator}. """ def __init__(self): self.coop = task.Cooperator(started=False) def coiterate(self, iterator): return self.coop.coiterate(iterator) def startService(self): self.coop.start() def stopService(self): self.coop.stop() class StreamServerEndpointService(service.Service): """ A L{StreamServerEndpointService} is an L{IService} which runs a server on a listening port described by an L{IStreamServerEndpoint <twisted.internet.interfaces.IStreamServerEndpoint>}. @ivar factory: A server factory which will be used to listen on the endpoint. @ivar endpoint: An L{IStreamServerEndpoint <twisted.internet.interfaces.IStreamServerEndpoint>} provider which will be used to listen when the service starts. @ivar _waitingForPort: a Deferred, if C{listen} has yet been invoked on the endpoint, otherwise None. @ivar _raiseSynchronously: Defines error-handling behavior for the case where C{listen(...)} raises an exception before C{startService} or C{privilegedStartService} have completed. @type _raiseSynchronously: C{bool} @since: 10.2 """ _raiseSynchronously = False def __init__(self, endpoint, factory): self.endpoint = endpoint self.factory = factory self._waitingForPort = None def privilegedStartService(self): """ Start listening on the endpoint. """ service.Service.privilegedStartService(self) self._waitingForPort = self.endpoint.listen(self.factory) raisedNow = [] def handleIt(err): if self._raiseSynchronously: raisedNow.append(err) elif not err.check(CancelledError): log.err(err) self._waitingForPort.addErrback(handleIt) if raisedNow: raisedNow[0].raiseException() self._raiseSynchronously = False def startService(self): """ Start listening on the endpoint, unless L{privilegedStartService} got around to it already. """ service.Service.startService(self) if self._waitingForPort is None: self.privilegedStartService() def stopService(self): """ Stop listening on the port if it is already listening, otherwise, cancel the attempt to listen. @return: a L{Deferred<twisted.internet.defer.Deferred>} which fires with L{None} when the port has stopped listening. """ self._waitingForPort.cancel() def stopIt(port): if port is not None: return port.stopListening() d = self._waitingForPort.addCallback(stopIt) def stop(passthrough): self.running = False return passthrough d.addBoth(stop) return d class _ReconnectingProtocolProxy: """ A proxy for a Protocol to provide connectionLost notification to a client connection service, in support of reconnecting when connections are lost. """ def __init__(self, protocol, lostNotification): """ Create a L{_ReconnectingProtocolProxy}. @param protocol: the application-provided L{interfaces.IProtocol} provider. @type protocol: provider of L{interfaces.IProtocol} which may additionally provide L{interfaces.IHalfCloseableProtocol} and L{interfaces.IFileDescriptorReceiver}. @param lostNotification: a 1-argument callable to invoke with the C{reason} when the connection is lost. """ self._protocol = protocol self._lostNotification = lostNotification def connectionLost(self, reason): """ The connection was lost. Relay this information. @param reason: The reason the connection was lost. @return: the underlying protocol's result """ try: return self._protocol.connectionLost(reason) finally: self._lostNotification(reason) def __getattr__(self, item): return getattr(self._protocol, item) def __repr__(self) -> str: return f"<{self.__class__.__name__} wrapping {self._protocol!r}>" class _DisconnectFactory: """ A L{_DisconnectFactory} is a proxy for L{IProtocolFactory} that catches C{connectionLost} notifications and relays them. """ def __init__(self, protocolFactory, protocolDisconnected): self._protocolFactory = protocolFactory self._protocolDisconnected = protocolDisconnected def buildProtocol(self, addr): """ Create a L{_ReconnectingProtocolProxy} with the disconnect-notification callback we were called with. @param addr: The address the connection is coming from. @return: a L{_ReconnectingProtocolProxy} for a protocol produced by C{self._protocolFactory} """ return _ReconnectingProtocolProxy( self._protocolFactory.buildProtocol(addr), self._protocolDisconnected ) def __getattr__(self, item): return getattr(self._protocolFactory, item) def __repr__(self) -> str: return "<{} wrapping {!r}>".format( self.__class__.__name__, self._protocolFactory ) def backoffPolicy( initialDelay=1.0, maxDelay=60.0, factor=1.5, jitter=_goodEnoughRandom ): """ A timeout policy for L{ClientService} which computes an exponential backoff interval with configurable parameters. @since: 16.1.0 @param initialDelay: Delay for the first reconnection attempt (default 1.0s). @type initialDelay: L{float} @param maxDelay: Maximum number of seconds between connection attempts (default 60 seconds, or one minute). Note that this value is before jitter is applied, so the actual maximum possible delay is this value plus the maximum possible result of C{jitter()}. @type maxDelay: L{float} @param factor: A multiplicative factor by which the delay grows on each failed reattempt. Default: 1.5. @type factor: L{float} @param jitter: A 0-argument callable that introduces noise into the delay. By default, C{random.random}, i.e. a pseudorandom floating-point value between zero and one. @type jitter: 0-argument callable returning L{float} @return: a 1-argument callable that, given an attempt count, returns a floating point number; the number of seconds to delay. @rtype: see L{ClientService.__init__}'s C{retryPolicy} argument. """ def policy(attempt): try: delay = min(initialDelay * (factor ** min(100, attempt)), maxDelay) except OverflowError: delay = maxDelay return delay + jitter() return policy _defaultPolicy = backoffPolicy() def _firstResult(gen): """ Return the first element of a generator and exhaust it. C{MethodicalMachine.upon}'s C{collector} argument takes a generator of output results. If the generator is exhausted, the later outputs aren't actually run. @param gen: Generator to extract values from @return: The first element of the generator. """ return list(gen)[0] class _ClientMachine: """ State machine for maintaining a single outgoing connection to an endpoint. @ivar _awaitingConnected: notifications to make when connection succeeds, fails, or is cancelled @type _awaitingConnected: list of (Deferred, count) tuples @see: L{ClientService} """ _machine = MethodicalMachine() def __init__(self, endpoint, factory, retryPolicy, clock, prepareConnection, log): """ @see: L{ClientService.__init__} @param log: The logger for the L{ClientService} instance this state machine is associated to. @type log: L{Logger} """ self._endpoint = endpoint self._failedAttempts = 0 self._stopped = False self._factory = factory self._timeoutForAttempt = retryPolicy self._clock = clock self._prepareConnection = prepareConnection self._connectionInProgress = succeed(None) self._awaitingConnected = [] self._stopWaiters = [] self._log = log @_machine.state(initial=True) def _init(self): """ The service has not been started. """ @_machine.state() def _connecting(self): """ The service has started connecting. """ @_machine.state() def _waiting(self): """ The service is waiting for the reconnection period before reconnecting. """ @_machine.state() def _connected(self): """ The service is connected. """ @_machine.state() def _disconnecting(self): """ The service is disconnecting after being asked to shutdown. """ @_machine.state() def _restarting(self): """ The service is disconnecting and has been asked to restart. """ @_machine.state() def _stopped(self): """ The service has been stopped and is disconnected. """ @_machine.input() def start(self): """ Start this L{ClientService}, initiating the connection retry loop. """ @_machine.output() def _connect(self): """ Start a connection attempt. """ factoryProxy = _DisconnectFactory( self._factory, lambda _: self._clientDisconnected() ) self._connectionInProgress = ( self._endpoint.connect(factoryProxy) .addCallback(self._runPrepareConnection) .addCallback(self._connectionMade) .addErrback(self._connectionFailed) ) def _runPrepareConnection(self, protocol): """ Run any C{prepareConnection} callback with the connected protocol, ignoring its return value but propagating any failure. @param protocol: The protocol of the connection. @type protocol: L{IProtocol} @return: Either: - A L{Deferred} that succeeds with the protocol when the C{prepareConnection} callback has executed successfully. - A L{Deferred} that fails when the C{prepareConnection} callback throws or returns a failed L{Deferred}. - The protocol, when no C{prepareConnection} callback is defined. """ if self._prepareConnection: return maybeDeferred(self._prepareConnection, protocol).addCallback( lambda _: protocol ) return protocol @_machine.output() def _resetFailedAttempts(self): """ Reset the number of failed attempts. """ self._failedAttempts = 0 @_machine.input() def stop(self): """ Stop trying to connect and disconnect any current connection. @return: a L{Deferred} that fires when all outstanding connections are closed and all in-progress connection attempts halted. """ @_machine.output() def _waitForStop(self): """ Return a deferred that will fire when the service has finished disconnecting. @return: L{Deferred} that fires when the service has finished disconnecting. """ self._stopWaiters.append(Deferred()) return self._stopWaiters[-1] @_machine.output() def _stopConnecting(self): """ Stop pending connection attempt. """ self._connectionInProgress.cancel() @_machine.output() def _stopRetrying(self): """ Stop pending attempt to reconnect. """ self._retryCall.cancel() del self._retryCall @_machine.output() def _disconnect(self): """ Disconnect the current connection. """ self._currentConnection.transport.loseConnection() @_machine.input() def _connectionMade(self, protocol): """ A connection has been made. @param protocol: The protocol of the connection. @type protocol: L{IProtocol} """ @_machine.output() def _notifyWaiters(self, protocol): """ Notify all pending requests for a connection that a connection has been made. @param protocol: The protocol of the connection. @type protocol: L{IProtocol} """ # This should be in _resetFailedAttempts but the signature doesn't # match. self._failedAttempts = 0 self._currentConnection = protocol._protocol self._unawait(self._currentConnection) @_machine.input() def _connectionFailed(self, f): """ The current connection attempt failed. """ @_machine.output() def _wait(self): """ Schedule a retry attempt. """ self._doWait() @_machine.output() def _ignoreAndWait(self, f): """ Schedule a retry attempt, and ignore the Failure passed in. """ return self._doWait() def _doWait(self): self._failedAttempts += 1 delay = self._timeoutForAttempt(self._failedAttempts) self._log.info( "Scheduling retry {attempt} to connect {endpoint} " "in {delay} seconds.", attempt=self._failedAttempts, endpoint=self._endpoint, delay=delay, ) self._retryCall = self._clock.callLater(delay, self._reconnect) @_machine.input() def _reconnect(self): """ The wait between connection attempts is done. """ @_machine.input() def _clientDisconnected(self): """ The current connection has been disconnected. """ @_machine.output() def _forgetConnection(self): """ Forget the current connection. """ del self._currentConnection @_machine.output() def _cancelConnectWaiters(self): """ Notify all pending requests for a connection that no more connections are expected. """ self._unawait(Failure(CancelledError())) @_machine.output() def _ignoreAndCancelConnectWaiters(self, f): """ Notify all pending requests for a connection that no more connections are expected, after ignoring the Failure passed in. """ self._unawait(Failure(CancelledError())) @_machine.output() def _finishStopping(self): """ Notify all deferreds waiting on the service stopping. """ self._doFinishStopping() @_machine.output() def _ignoreAndFinishStopping(self, f): """ Notify all deferreds waiting on the service stopping, and ignore the Failure passed in. """ self._doFinishStopping() def _doFinishStopping(self): self._stopWaiters, waiting = [], self._stopWaiters for w in waiting: w.callback(None) @_machine.input() def whenConnected(self, failAfterFailures=None): """ Retrieve the currently-connected L{Protocol}, or the next one to connect. @param failAfterFailures: number of connection failures after which the Deferred will deliver a Failure (None means the Deferred will only fail if/when the service is stopped). Set this to 1 to make the very first connection failure signal an error. Use 2 to allow one failure but signal an error if the subsequent retry then fails. @type failAfterFailures: L{int} or None @return: a Deferred that fires with a protocol produced by the factory passed to C{__init__} @rtype: L{Deferred} that may: - fire with L{IProtocol} - fail with L{CancelledError} when the service is stopped - fail with e.g. L{DNSLookupError<twisted.internet.error.DNSLookupError>} or L{ConnectionRefusedError<twisted.internet.error.ConnectionRefusedError>} when the number of consecutive failed connection attempts equals the value of "failAfterFailures" """ @_machine.output() def _currentConnection(self, failAfterFailures=None): """ Return the currently connected protocol. @return: L{Deferred} that is fired with currently connected protocol. """ return succeed(self._currentConnection) @_machine.output() def _noConnection(self, failAfterFailures=None): """ Notify the caller that no connection is expected. @return: L{Deferred} that is fired with L{CancelledError}. """ return fail(CancelledError()) @_machine.output() def _awaitingConnection(self, failAfterFailures=None): """ Return a deferred that will fire with the next connected protocol. @return: L{Deferred} that will fire with the next connected protocol. """ result = Deferred() self._awaitingConnected.append((result, failAfterFailures)) return result @_machine.output() def _deferredSucceededWithNone(self): """ Return a deferred that has already fired with L{None}. @return: A L{Deferred} that has already fired with L{None}. """ return succeed(None) def _unawait(self, value): """ Fire all outstanding L{ClientService.whenConnected} L{Deferred}s. @param value: the value to fire the L{Deferred}s with. """ self._awaitingConnected, waiting = [], self._awaitingConnected for (w, remaining) in waiting: w.callback(value) @_machine.output() def _deliverConnectionFailure(self, f): """ Deliver connection failures to any L{ClientService.whenConnected} L{Deferred}s that have met their failAfterFailures threshold. @param f: the Failure to fire the L{Deferred}s with. """ ready = [] notReady = [] for (w, remaining) in self._awaitingConnected: if remaining is None: notReady.append((w, remaining)) elif remaining <= 1: ready.append(w) else: notReady.append((w, remaining - 1)) self._awaitingConnected = notReady for w in ready: w.callback(f) # State Transitions _init.upon(start, enter=_connecting, outputs=[_connect]) _init.upon( stop, enter=_stopped, outputs=[_deferredSucceededWithNone], collector=_firstResult, ) _connecting.upon(start, enter=_connecting, outputs=[]) # Note that this synchonously triggers _connectionFailed in the # _disconnecting state. _connecting.upon( stop, enter=_disconnecting, outputs=[_waitForStop, _stopConnecting], collector=_firstResult, ) _connecting.upon(_connectionMade, enter=_connected, outputs=[_notifyWaiters]) _connecting.upon( _connectionFailed, enter=_waiting, outputs=[_ignoreAndWait, _deliverConnectionFailure], ) _waiting.upon(start, enter=_waiting, outputs=[]) _waiting.upon( stop, enter=_stopped, outputs=[_waitForStop, _cancelConnectWaiters, _stopRetrying, _finishStopping], collector=_firstResult, ) _waiting.upon(_reconnect, enter=_connecting, outputs=[_connect]) _connected.upon(start, enter=_connected, outputs=[]) _connected.upon( stop, enter=_disconnecting, outputs=[_waitForStop, _disconnect], collector=_firstResult, ) _connected.upon( _clientDisconnected, enter=_waiting, outputs=[_forgetConnection, _wait] ) _disconnecting.upon(start, enter=_restarting, outputs=[_resetFailedAttempts]) _disconnecting.upon( stop, enter=_disconnecting, outputs=[_waitForStop], collector=_firstResult ) _disconnecting.upon( _clientDisconnected, enter=_stopped, outputs=[_cancelConnectWaiters, _finishStopping, _forgetConnection], ) # Note that this is triggered synchonously with the transition from # _connecting _disconnecting.upon( _connectionFailed, enter=_stopped, outputs=[_ignoreAndCancelConnectWaiters, _ignoreAndFinishStopping], ) _restarting.upon(start, enter=_restarting, outputs=[]) _restarting.upon( stop, enter=_disconnecting, outputs=[_waitForStop], collector=_firstResult ) _restarting.upon( _clientDisconnected, enter=_connecting, outputs=[_finishStopping, _connect] ) _stopped.upon(start, enter=_connecting, outputs=[_connect]) _stopped.upon( stop, enter=_stopped, outputs=[_deferredSucceededWithNone], collector=_firstResult, ) _init.upon( whenConnected, enter=_init, outputs=[_awaitingConnection], collector=_firstResult, ) _connecting.upon( whenConnected, enter=_connecting, outputs=[_awaitingConnection], collector=_firstResult, ) _waiting.upon( whenConnected, enter=_waiting, outputs=[_awaitingConnection], collector=_firstResult, ) _connected.upon( whenConnected, enter=_connected, outputs=[_currentConnection], collector=_firstResult, ) _disconnecting.upon( whenConnected, enter=_disconnecting, outputs=[_awaitingConnection], collector=_firstResult, ) _restarting.upon( whenConnected, enter=_restarting, outputs=[_awaitingConnection], collector=_firstResult, ) _stopped.upon( whenConnected, enter=_stopped, outputs=[_noConnection], collector=_firstResult ) class ClientService(service.Service): """ A L{ClientService} maintains a single outgoing connection to a client endpoint, reconnecting after a configurable timeout when a connection fails, either before or after connecting. @since: 16.1.0 """ _log = Logger() def __init__( self, endpoint, factory, retryPolicy=None, clock=None, prepareConnection=None ): """ @param endpoint: A L{stream client endpoint <interfaces.IStreamClientEndpoint>} provider which will be used to connect when the service starts. @param factory: A L{protocol factory <interfaces.IProtocolFactory>} which will be used to create clients for the endpoint. @param retryPolicy: A policy configuring how long L{ClientService} will wait between attempts to connect to C{endpoint}. @type retryPolicy: callable taking (the number of failed connection attempts made in a row (L{int})) and returning the number of seconds to wait before making another attempt. @param clock: The clock used to schedule reconnection. It's mainly useful to be parametrized in tests. If the factory is serialized, this attribute will not be serialized, and the default value (the reactor) will be restored when deserialized. @type clock: L{IReactorTime} @param prepareConnection: A single argument L{callable} that may return a L{Deferred}. It will be called once with the L{protocol <interfaces.IProtocol>} each time a new connection is made. It may call methods on the protocol to prepare it for use (e.g. authenticate) or validate it (check its health). The C{prepareConnection} callable may raise an exception or return a L{Deferred} which fails to reject the connection. A rejected connection is not used to fire an L{Deferred} returned by L{whenConnected}. Instead, L{ClientService} handles the failure and continues as if the connection attempt were a failure (incrementing the counter passed to C{retryPolicy}). L{Deferred}s returned by L{whenConnected} will not fire until any L{Deferred} returned by the C{prepareConnection} callable fire. Otherwise its successful return value is consumed, but ignored. Present Since Twisted 18.7.0 @type prepareConnection: L{callable} """ clock = _maybeGlobalReactor(clock) retryPolicy = _defaultPolicy if retryPolicy is None else retryPolicy self._machine = _ClientMachine( endpoint, factory, retryPolicy, clock, prepareConnection=prepareConnection, log=self._log, ) def whenConnected(self, failAfterFailures=None): """ Retrieve the currently-connected L{Protocol}, or the next one to connect. @param failAfterFailures: number of connection failures after which the Deferred will deliver a Failure (None means the Deferred will only fail if/when the service is stopped). Set this to 1 to make the very first connection failure signal an error. Use 2 to allow one failure but signal an error if the subsequent retry then fails. @type failAfterFailures: L{int} or None @return: a Deferred that fires with a protocol produced by the factory passed to C{__init__} @rtype: L{Deferred} that may: - fire with L{IProtocol} - fail with L{CancelledError} when the service is stopped - fail with e.g. L{DNSLookupError<twisted.internet.error.DNSLookupError>} or L{ConnectionRefusedError<twisted.internet.error.ConnectionRefusedError>} when the number of consecutive failed connection attempts equals the value of "failAfterFailures" """ return self._machine.whenConnected(failAfterFailures) def startService(self): """ Start this L{ClientService}, initiating the connection retry loop. """ if self.running: self._log.warn("Duplicate ClientService.startService {log_source}") return super().startService() self._machine.start() def stopService(self): """ Stop attempting to reconnect and close any existing connections. @return: a L{Deferred} that fires when all outstanding connections are closed and all in-progress connection attempts halted. """ super().stopService() return self._machine.stop() __all__ = [ "TimerService", "CooperatorService", "MulticastServer", "StreamServerEndpointService", "UDPServer", "ClientService", "TCPServer", "TCPClient", "UNIXServer", "UNIXClient", "SSLServer", "SSLClient", "UNIXDatagramServer", "UNIXDatagramClient", ]