"""TLS Lite + Twisted.""" from twisted.protocols.policies import ProtocolWrapper, WrappingFactory from twisted.python.failure import Failure from AsyncStateMachine import AsyncStateMachine from gdata.tlslite.TLSConnection import TLSConnection from gdata.tlslite.errors import * import socket import errno #The TLSConnection is created around a "fake socket" that #plugs it into the underlying Twisted transport class _FakeSocket: def __init__(self, wrapper): self.wrapper = wrapper self.data = "" def send(self, data): ProtocolWrapper.write(self.wrapper, data) return len(data) def recv(self, numBytes): if self.data == "": raise socket.error, (errno.EWOULDBLOCK, "") returnData = self.data[:numBytes] self.data = self.data[numBytes:] return returnData class TLSTwistedProtocolWrapper(ProtocolWrapper, AsyncStateMachine): """This class can wrap Twisted protocols to add TLS support. Below is a complete example of using TLS Lite with a Twisted echo server. There are two server implementations below. Echo is the original protocol, which is oblivious to TLS. Echo1 subclasses Echo and negotiates TLS when the client connects. Echo2 subclasses Echo and negotiates TLS when the client sends "STARTTLS":: from twisted.internet.protocol import Protocol, Factory from twisted.internet import reactor from twisted.protocols.policies import WrappingFactory from twisted.protocols.basic import LineReceiver from twisted.python import log from twisted.python.failure import Failure import sys from tlslite.api import * s = open("./serverX509Cert.pem").read() x509 = X509() x509.parse(s) certChain = X509CertChain([x509]) s = open("./serverX509Key.pem").read() privateKey = parsePEMKey(s, private=True) verifierDB = VerifierDB("verifierDB") verifierDB.open() class Echo(LineReceiver): def connectionMade(self): self.transport.write("Welcome to the echo server!\\r\\n") def lineReceived(self, line): self.transport.write(line + "\\r\\n") class Echo1(Echo): def connectionMade(self): if not self.transport.tlsStarted: self.transport.setServerHandshakeOp(certChain=certChain, privateKey=privateKey, verifierDB=verifierDB) else: Echo.connectionMade(self) def connectionLost(self, reason): pass #Handle any TLS exceptions here class Echo2(Echo): def lineReceived(self, data): if data == "STARTTLS": self.transport.setServerHandshakeOp(certChain=certChain, privateKey=privateKey, verifierDB=verifierDB) else: Echo.lineReceived(self, data) def connectionLost(self, reason): pass #Handle any TLS exceptions here factory = Factory() factory.protocol = Echo1 #factory.protocol = Echo2 wrappingFactory = WrappingFactory(factory) wrappingFactory.protocol = TLSTwistedProtocolWrapper log.startLogging(sys.stdout) reactor.listenTCP(1079, wrappingFactory) reactor.run() This class works as follows: Data comes in and is given to the AsyncStateMachine for handling. AsyncStateMachine will forward events to this class, and we'll pass them on to the ProtocolHandler, which will proxy them to the wrapped protocol. The wrapped protocol may then call back into this class, and these calls will be proxied into the AsyncStateMachine. The call graph looks like this: - self.dataReceived - AsyncStateMachine.inReadEvent - self.out(Connect|Close|Read)Event - ProtocolWrapper.(connectionMade|loseConnection|dataReceived) - self.(loseConnection|write|writeSequence) - AsyncStateMachine.(setCloseOp|setWriteOp) """ #WARNING: IF YOU COPY-AND-PASTE THE ABOVE CODE, BE SURE TO REMOVE #THE EXTRA ESCAPING AROUND "\\r\\n" def __init__(self, factory, wrappedProtocol): ProtocolWrapper.__init__(self, factory, wrappedProtocol) AsyncStateMachine.__init__(self) self.fakeSocket = _FakeSocket(self) self.tlsConnection = TLSConnection(self.fakeSocket) self.tlsStarted = False self.connectionLostCalled = False def connectionMade(self): try: ProtocolWrapper.connectionMade(self) except TLSError, e: self.connectionLost(Failure(e)) ProtocolWrapper.loseConnection(self) def dataReceived(self, data): try: if not self.tlsStarted: ProtocolWrapper.dataReceived(self, data) else: self.fakeSocket.data += data while self.fakeSocket.data: AsyncStateMachine.inReadEvent(self) except TLSError, e: self.connectionLost(Failure(e)) ProtocolWrapper.loseConnection(self) def connectionLost(self, reason): if not self.connectionLostCalled: ProtocolWrapper.connectionLost(self, reason) self.connectionLostCalled = True def outConnectEvent(self): ProtocolWrapper.connectionMade(self) def outCloseEvent(self): ProtocolWrapper.loseConnection(self) def outReadEvent(self, data): if data == "": ProtocolWrapper.loseConnection(self) else: ProtocolWrapper.dataReceived(self, data) def setServerHandshakeOp(self, **args): self.tlsStarted = True AsyncStateMachine.setServerHandshakeOp(self, **args) def loseConnection(self): if not self.tlsStarted: ProtocolWrapper.loseConnection(self) else: AsyncStateMachine.setCloseOp(self) def write(self, data): if not self.tlsStarted: ProtocolWrapper.write(self, data) else: #Because of the FakeSocket, write operations are guaranteed to #terminate immediately. AsyncStateMachine.setWriteOp(self, data) def writeSequence(self, seq): if not self.tlsStarted: ProtocolWrapper.writeSequence(self, seq) else: #Because of the FakeSocket, write operations are guaranteed to #terminate immediately. AsyncStateMachine.setWriteOp(self, "".join(seq))