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I tried to implement a protocol that can run TLS over TLS using twisted.protocols.tls, an interface to OpenSSL using a memory BIO.

I implemented this as a protocol wrapper that mostly looks like a regular TCP transport, but which has startTLS and stopTLS methods for adding and removing a layer of TLS respectively. This works fine for the first layer of TLS. It also works fine if I run it over a "native" Twisted TLS transport. However, if I try to add a second TLS layer using the startTLS method provided by this wrapper, there's immediately a handshake error and the connection ends up in some unknown unusable state.

The wrapper and the two helpers that let it work looks like this:

from twisted.python.components import proxyForInterface
from twisted.internet.error import ConnectionDone
from twisted.internet.interfaces import ITCPTransport, IProtocol
from twisted.protocols.tls import TLSMemoryBIOFactory, TLSMemoryBIOProtocol
from twisted.protocols.policies import ProtocolWrapper, WrappingFactory

class TransportWithoutDisconnection(proxyForInterface(ITCPTransport)):
    """
    A proxy for a normal transport that disables actually closing the connection.
    This is necessary so that when TLSMemoryBIOProtocol notices the SSL EOF it
    doesn't actually close the underlying connection.

    All methods except loseConnection are proxied directly to the real transport.
    """
    def loseConnection(self):
        pass


class ProtocolWithoutConnectionLost(proxyForInterface(IProtocol)):
    """
    A proxy for a normal protocol which captures clean connection shutdown
    notification and sends it to the TLS stacking code instead of the protocol.
    When TLS is shutdown cleanly, this notification will arrive.  Instead of telling
    the protocol that the entire connection is gone, the notification is used to
    unstack the TLS code in OnionProtocol and hidden from the wrapped protocol.  Any
    other kind of connection shutdown (SSL handshake error, network hiccups, etc) are
    treated as real problems and propagated to the wrapped protocol.
    """
    def connectionLost(self, reason):
        if reason.check(ConnectionDone):
            self.onion._stopped()
        else:
            super(ProtocolWithoutConnectionLost, self).connectionLost(reason)


class OnionProtocol(ProtocolWrapper):
    """
    OnionProtocol is both a transport and a protocol.  As a protocol, it can run over
    any other ITransport.  As a transport, it implements stackable TLS.  That is,
    whatever application traffic is generated by the protocol running on top of
    OnionProtocol can be encapsulated in a TLS conversation.  Or, that TLS conversation
    can be encapsulated in another TLS conversation.  Or **that** TLS conversation can
    be encapsulated in yet *another* TLS conversation.

    Each layer of TLS can use different connection parameters, such as keys, ciphers,
    certificate requirements, etc.  At the remote end of this connection, each has to
    be decrypted separately, starting at the outermost and working in.  OnionProtocol
    can do this itself, of course, just as it can encrypt each layer starting with the
    innermost.
    """
    def makeConnection(self, transport):
        self._tlsStack = []
        ProtocolWrapper.makeConnection(self, transport)


    def startTLS(self, contextFactory, client, bytes=None):
        """
        Add a layer of TLS, with SSL parameters defined by the given contextFactory.

        If *client* is True, this side of the connection will be an SSL client.
        Otherwise it will be an SSL server.

        If extra bytes which may be (or almost certainly are) part of the SSL handshake
        were received by the protocol running on top of OnionProtocol, they must be
        passed here as the **bytes** parameter.
        """
        # First, create a wrapper around the application-level protocol
        # (wrappedProtocol) which can catch connectionLost and tell this OnionProtocol 
        # about it.  This is necessary to pop from _tlsStack when the outermost TLS
        # layer stops.
        connLost = ProtocolWithoutConnectionLost(self.wrappedProtocol)
        connLost.onion = self
        # Construct a new TLS layer, delivering events and application data to the
        # wrapper just created.
        tlsProtocol = TLSMemoryBIOProtocol(None, connLost, False)
        tlsProtocol.factory = TLSMemoryBIOFactory(contextFactory, client, None)

        # Push the previous transport and protocol onto the stack so they can be
        # retrieved when this new TLS layer stops.
        self._tlsStack.append((self.transport, self.wrappedProtocol))

        # Create a transport for the new TLS layer to talk to.  This is a passthrough
        # to the OnionProtocol's current transport, except for capturing loseConnection
        # to avoid really closing the underlying connection.
        transport = TransportWithoutDisconnection(self.transport)

        # Make the new TLS layer the current protocol and transport.
        self.wrappedProtocol = self.transport = tlsProtocol

        # And connect the new TLS layer to the previous outermost transport.
        self.transport.makeConnection(transport)

        # If the application accidentally got some bytes from the TLS handshake, deliver
        # them to the new TLS layer.
        if bytes is not None:
            self.wrappedProtocol.dataReceived(bytes)


    def stopTLS(self):
        """
        Remove a layer of TLS.
        """
        # Just tell the current TLS layer to shut down.  When it has done so, we'll get
        # notification in *_stopped*.
        self.transport.loseConnection()


    def _stopped(self):
        # A TLS layer has completely shut down.  Throw it away and move back to the
        # TLS layer it was wrapping (or possibly back to the original non-TLS
        # transport).
        self.transport, self.wrappedProtocol = self._tlsStack.pop()

I have simple client and server programs for exercising this, available from launchpad (bzr branch lp:~exarkun/+junk/onion). When I use it to call the startTLS method above twice, with no intervening call to stopTLS, this OpenSSL error comes up:

OpenSSL.SSL.Error: [('SSL routines', 'SSL23_GET_SERVER_HELLO', 'unknown protocol')]

Why do things go wrong?

share|improve this question
2  
Why are you trying to use TLS in TLS? –  Jumbogram Mar 6 '11 at 20:40
4  
Why not? ;) I actually have no real use for this at the moment. I was prompted to explore it by another stackoverflow question (which has since been deleted by its author, unfortunately). However, it might be a useful thing to do to implement something like Tor, an onion routing network. –  Jean-Paul Calderone Mar 6 '11 at 23:14
9  
My normal network debugging method is 'use wireshark', which doesn't work well when the data you want to look at is encrypted. Can you have the outer layers use TLS_RSA_WITH_NULL_MD5, so that you can have a meaningful packet capture? –  Jumbogram Mar 10 '11 at 3:13
1  
Good idea. I'll give that a try soon. –  Jean-Paul Calderone Mar 10 '11 at 14:31
1  
You might have to special-configure it. 'openssl ciphers' won't list it, but 'openssl ciphers NULL' does. –  Jumbogram Mar 10 '11 at 22:49

2 Answers 2

You may need to inform the remote device that you wish to start an environment and allocate resources for the second layer before you start it up, if that device has the capabilities.

share|improve this answer
1  
Thanks. The failing example all runs over localhost though. The "device" is the code in the bzr branch at lp:~exarkun/+junk/onion. –  Jean-Paul Calderone May 20 '11 at 13:19

If you are using the same TLS parameters for both layers and you are connecting to the same host, then you are probably using the same key-pair for both layers of encryption. Try using a different key-pair for the nested layer, such as tunneling to a third host/port. i.e: localhost:30000 (client) -> localhost:8080 (TLS layer 1 using key-pair A) -> localhost:8081 (TLS layer 2 using key-pair B).

share|improve this answer
1  
Why would using the same key pair be a problem? –  Jean-Paul Calderone Jul 20 '11 at 10:53
1  
I agree with @Jumbogram in that TLS-in-TLS should technically work, so it occurred to me that there may be something in the math that breaks down in a scenario with double-encryption. I haven't been able to reproduce the failure with straight RSA, though. –  Leo Accend Jul 20 '11 at 21:57
    
@LeoAccend - if you haven't been able to reproduce the failure, what code are you using where it works? –  Glyph Feb 18 '13 at 19:52

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