# -*- test-case-name: twisted.conch.test.test_conch -*-
# Copyright (c) Twisted Matrix Laboratories.
# See LICENSE for details.
import os, sys, socket
import subprocess
from itertools import count
from zope.interface import implementer
from twisted.python.reflect import requireModule
cryptography = requireModule("cryptography")
from twisted.conch.error import ConchError
if cryptography:
from twisted.conch.avatar import ConchUser
from twisted.conch.ssh.session import ISession, SSHSession, wrapProtocol
else:
from twisted.conch.interfaces import ISession
class ConchUser: pass
from twisted.cred import portal
from twisted.internet import reactor, defer, protocol
from twisted.internet.error import ProcessExitedAlready
from twisted.internet.task import LoopingCall
from twisted.internet.utils import getProcessValue
from twisted.python import filepath, log, runtime
from twisted.python.compat import unicode
from twisted.trial import unittest
try:
from twisted.conch.scripts.conch import SSHSession as StdioInteractingSession
except ImportError as e:
StdioInteractingSession = None
_reason = str(e)
del e
from twisted.conch.test.test_ssh import ConchTestRealm
from twisted.python.procutils import which
from twisted.conch.test.keydata import publicRSA_openssh, privateRSA_openssh
from twisted.conch.test.keydata import publicDSA_openssh, privateDSA_openssh
try:
from twisted.conch.test.test_ssh import ConchTestServerFactory, \
conchTestPublicKeyChecker
except ImportError:
pass
try:
import cryptography
except ImportError:
cryptography = None
try:
import pyasn1
except ImportError:
pyasn1 = None
def _has_ipv6():
""" Returns True if the system can bind an IPv6 address."""
sock = None
has_ipv6 = False
try:
sock = socket.socket(socket.AF_INET6)
sock.bind(('::1', 0))
has_ipv6 = True
except socket.error:
pass
if sock:
sock.close()
return has_ipv6
HAS_IPV6 = _has_ipv6()
class FakeStdio(object):
"""
A fake for testing L{twisted.conch.scripts.conch.SSHSession.eofReceived} and
L{twisted.conch.scripts.cftp.SSHSession.eofReceived}.
@ivar writeConnLost: A flag which records whether L{loserWriteConnection}
has been called.
"""
writeConnLost = False
def loseWriteConnection(self):
"""
Record the call to loseWriteConnection.
"""
self.writeConnLost = True
class StdioInteractingSessionTests(unittest.TestCase):
"""
Tests for L{twisted.conch.scripts.conch.SSHSession}.
"""
if StdioInteractingSession is None:
skip = _reason
def test_eofReceived(self):
"""
L{twisted.conch.scripts.conch.SSHSession.eofReceived} loses the
write half of its stdio connection.
"""
stdio = FakeStdio()
channel = StdioInteractingSession()
channel.stdio = stdio
channel.eofReceived()
self.assertTrue(stdio.writeConnLost)
class Echo(protocol.Protocol):
def connectionMade(self):
log.msg('ECHO CONNECTION MADE')
def connectionLost(self, reason):
log.msg('ECHO CONNECTION DONE')
def dataReceived(self, data):
self.transport.write(data)
if b'\n' in data:
self.transport.loseConnection()
class EchoFactory(protocol.Factory):
protocol = Echo
class ConchTestOpenSSHProcess(protocol.ProcessProtocol):
"""
Test protocol for launching an OpenSSH client process.
@ivar deferred: Set by whatever uses this object. Accessed using
L{_getDeferred}, which destroys the value so the Deferred is not
fired twice. Fires when the process is terminated.
"""
deferred = None
buf = b''
def _getDeferred(self):
d, self.deferred = self.deferred, None
return d
def outReceived(self, data):
self.buf += data
def processEnded(self, reason):
"""
Called when the process has ended.
@param reason: a Failure giving the reason for the process' end.
"""
if reason.value.exitCode != 0:
self._getDeferred().errback(
ConchError("exit code was not 0: {}".format(
reason.value.exitCode)))
else:
buf = self.buf.replace(b'\r\n', b'\n')
self._getDeferred().callback(buf)
class ConchTestForwardingProcess(protocol.ProcessProtocol):
"""
Manages a third-party process which launches a server.
Uses L{ConchTestForwardingPort} to connect to the third-party server.
Once L{ConchTestForwardingPort} has disconnected, kill the process and fire
a Deferred with the data received by the L{ConchTestForwardingPort}.
@ivar deferred: Set by whatever uses this object. Accessed using
L{_getDeferred}, which destroys the value so the Deferred is not
fired twice. Fires when the process is terminated.
"""
deferred = None
def __init__(self, port, data):
"""
@type port: L{int}
@param port: The port on which the third-party server is listening.
(it is assumed that the server is running on localhost).
@type data: L{str}
@param data: This is sent to the third-party server. Must end with '\n'
in order to trigger a disconnect.
"""
self.port = port
self.buffer = None
self.data = data
def _getDeferred(self):
d, self.deferred = self.deferred, None
return d
def connectionMade(self):
self._connect()
def _connect(self):
"""
Connect to the server, which is often a third-party process.
Tries to reconnect if it fails because we have no way of determining
exactly when the port becomes available for listening -- we can only
know when the process starts.
"""
cc = protocol.ClientCreator(reactor, ConchTestForwardingPort, self,
self.data)
d = cc.connectTCP('127.0.0.1', self.port)
d.addErrback(self._ebConnect)
return d
def _ebConnect(self, f):
reactor.callLater(.1, self._connect)
def forwardingPortDisconnected(self, buffer):
"""
The network connection has died; save the buffer of output
from the network and attempt to quit the process gracefully,
and then (after the reactor has spun) send it a KILL signal.
"""
self.buffer = buffer
self.transport.write(b'\x03')
self.transport.loseConnection()
reactor.callLater(0, self._reallyDie)
def _reallyDie(self):
try:
self.transport.signalProcess('KILL')
except ProcessExitedAlready:
pass
def processEnded(self, reason):
"""
Fire the Deferred at self.deferred with the data collected
from the L{ConchTestForwardingPort} connection, if any.
"""
self._getDeferred().callback(self.buffer)
class ConchTestForwardingPort(protocol.Protocol):
"""
Connects to server launched by a third-party process (managed by
L{ConchTestForwardingProcess}) sends data, then reports whatever it
received back to the L{ConchTestForwardingProcess} once the connection
is ended.
"""
def __init__(self, protocol, data):
"""
@type protocol: L{ConchTestForwardingProcess}
@param protocol: The L{ProcessProtocol} which made this connection.
@type data: str
@param data: The data to be sent to the third-party server.
"""
self.protocol = protocol
self.data = data
def connectionMade(self):
self.buffer = b''
self.transport.write(self.data)
def dataReceived(self, data):
self.buffer += data
def connectionLost(self, reason):
self.protocol.forwardingPortDisconnected(self.buffer)
def _makeArgs(args, mod="conch"):
start = [sys.executable, '-c'
"""
### Twisted Preamble
import sys, os
path = os.path.abspath(sys.argv[0])
while os.path.dirname(path) != path:
if os.path.basename(path).startswith('Twisted'):
sys.path.insert(0, path)
break
path = os.path.dirname(path)
from twisted.conch.scripts.%s import run
run()""" % mod]
madeArgs = []
for arg in start + list(args):
if isinstance(arg, unicode):
arg = arg.encode("utf-8")
madeArgs.append(arg)
return madeArgs
class ConchServerSetupMixin:
if not cryptography:
skip = "can't run without cryptography"
if not pyasn1:
skip = "Cannot run without PyASN1"
realmFactory = staticmethod(lambda: ConchTestRealm(b'testuser'))
def _createFiles(self):
for f in ['rsa_test','rsa_test.pub','dsa_test','dsa_test.pub',
'kh_test']:
if os.path.exists(f):
os.remove(f)
with open('rsa_test','wb') as f:
f.write(privateRSA_openssh)
with open('rsa_test.pub','wb') as f:
f.write(publicRSA_openssh)
with open('dsa_test.pub','wb') as f:
f.write(publicDSA_openssh)
with open('dsa_test','wb') as f:
f.write(privateDSA_openssh)
os.chmod('dsa_test', 33152)
os.chmod('rsa_test', 33152)
with open('kh_test','wb') as f:
f.write(b'127.0.0.1 '+publicRSA_openssh)
def _getFreePort(self):
s = socket.socket()
s.bind(('', 0))
port = s.getsockname()[1]
s.close()
return port
def _makeConchFactory(self):
"""
Make a L{ConchTestServerFactory}, which allows us to start a
L{ConchTestServer} -- i.e. an actually listening conch.
"""
realm = self.realmFactory()
p = portal.Portal(realm)
p.registerChecker(conchTestPublicKeyChecker())
factory = ConchTestServerFactory()
factory.portal = p
return factory
def setUp(self):
self._createFiles()
self.conchFactory = self._makeConchFactory()
self.conchFactory.expectedLoseConnection = 1
self.conchServer = reactor.listenTCP(0, self.conchFactory,
interface="127.0.0.1")
self.echoServer = reactor.listenTCP(0, EchoFactory())
self.echoPort = self.echoServer.getHost().port
if HAS_IPV6:
self.echoServerV6 = reactor.listenTCP(0, EchoFactory(), interface="::1")
self.echoPortV6 = self.echoServerV6.getHost().port
def tearDown(self):
try:
self.conchFactory.proto.done = 1
except AttributeError:
pass
else:
self.conchFactory.proto.transport.loseConnection()
deferreds = [
defer.maybeDeferred(self.conchServer.stopListening),
defer.maybeDeferred(self.echoServer.stopListening),
]
if HAS_IPV6:
deferreds.append(defer.maybeDeferred(self.echoServerV6.stopListening))
return defer.gatherResults(deferreds)
class ForwardingMixin(ConchServerSetupMixin):
"""
Template class for tests of the Conch server's ability to forward arbitrary
protocols over SSH.
These tests are integration tests, not unit tests. They launch a Conch
server, a custom TCP server (just an L{EchoProtocol}) and then call
L{execute}.
L{execute} is implemented by subclasses of L{ForwardingMixin}. It should
cause an SSH client to connect to the Conch server, asking it to forward
data to the custom TCP server.
"""
def test_exec(self):
"""
Test that we can use whatever client to send the command "echo goodbye"
to the Conch server. Make sure we receive "goodbye" back from the
server.
"""
d = self.execute('echo goodbye', ConchTestOpenSSHProcess())
return d.addCallback(self.assertEqual, b'goodbye\n')
def test_localToRemoteForwarding(self):
"""
Test that we can use whatever client to forward a local port to a
specified port on the server.
"""
localPort = self._getFreePort()
process = ConchTestForwardingProcess(localPort, b'test\n')
d = self.execute('', process,
sshArgs='-N -L%i:127.0.0.1:%i'
% (localPort, self.echoPort))
d.addCallback(self.assertEqual, b'test\n')
return d
def test_remoteToLocalForwarding(self):
"""
Test that we can use whatever client to forward a port from the server
to a port locally.
"""
localPort = self._getFreePort()
process = ConchTestForwardingProcess(localPort, b'test\n')
d = self.execute('', process,
sshArgs='-N -R %i:127.0.0.1:%i'
% (localPort, self.echoPort))
d.addCallback(self.assertEqual, b'test\n')
return d
# Conventionally there is a separate adapter object which provides ISession for
# the user, but making the user provide ISession directly works too. This isn't
# a full implementation of ISession though, just enough to make these tests
# pass.
@implementer(ISession)
class RekeyAvatar(ConchUser):
"""
This avatar implements a shell which sends 60 numbered lines to whatever
connects to it, then closes the session with a 0 exit status.
60 lines is selected as being enough to send more than 2kB of traffic, the
amount the client is configured to initiate a rekey after.
"""
def __init__(self):
ConchUser.__init__(self)
self.channelLookup[b'session'] = SSHSession
def openShell(self, transport):
"""
Write 60 lines of data to the transport, then exit.
"""
proto = protocol.Protocol()
proto.makeConnection(transport)
transport.makeConnection(wrapProtocol(proto))
# Send enough bytes to the connection so that a rekey is triggered in
# the client.
def write(counter):
i = next(counter)
if i == 60:
call.stop()
transport.session.conn.sendRequest(
transport.session, b'exit-status', b'\x00\x00\x00\x00')
transport.loseConnection()
else:
line = "line #%02d\n" % (i,)
line = line.encode("utf-8")
transport.write(line)
# The timing for this loop is an educated guess (and/or the result of
# experimentation) to exercise the case where a packet is generated
# mid-rekey. Since the other side of the connection is (so far) the
# OpenSSH command line client, there's no easy way to determine when the
# rekey has been initiated. If there were, then generating a packet
# immediately at that time would be a better way to test the
# functionality being tested here.
call = LoopingCall(write, count())
call.start(0.01)
def closed(self):
"""
Ignore the close of the session.
"""
class RekeyRealm:
"""
This realm gives out new L{RekeyAvatar} instances for any avatar request.
"""
def requestAvatar(self, avatarID, mind, *interfaces):
return interfaces[0], RekeyAvatar(), lambda: None
class RekeyTestsMixin(ConchServerSetupMixin):
"""
TestCase mixin which defines tests exercising L{SSHTransportBase}'s handling
of rekeying messages.
"""
realmFactory = RekeyRealm
def test_clientRekey(self):
"""
After a client-initiated rekey is completed, application data continues
to be passed over the SSH connection.
"""
process = ConchTestOpenSSHProcess()
d = self.execute("", process, '-o RekeyLimit=2K')
def finished(result):
expectedResult = '\n'.join(['line #%02d' % (i,) for i in range(60)]) + '\n'
expectedResult = expectedResult.encode("utf-8")
self.assertEqual(result, expectedResult)
d.addCallback(finished)
return d
class OpenSSHClientMixin:
if not which('ssh'):
skip = "no ssh command-line client available"
def execute(self, remoteCommand, process, sshArgs=''):
"""
Connects to the SSH server started in L{ConchServerSetupMixin.setUp} by
running the 'ssh' command line tool.
@type remoteCommand: str
@param remoteCommand: The command (with arguments) to run on the
remote end.
@type process: L{ConchTestOpenSSHProcess}
@type sshArgs: str
@param sshArgs: Arguments to pass to the 'ssh' process.
@return: L{defer.Deferred}
"""
# PubkeyAcceptedKeyTypes does not exist prior to OpenSSH 7.0 so we
# first need to check if we can set it. If we can, -V will just print
# the version without doing anything else; if we can't, we will get a
# configuration error.
d = getProcessValue(
which('ssh')[0], ('-o', 'PubkeyAcceptedKeyTypes=ssh-dss', '-V'))
def hasPAKT(status):
if status == 0:
opts = '-oPubkeyAcceptedKeyTypes=ssh-dss '
else:
opts = ''
process.deferred = defer.Deferred()
# Pass -F /dev/null to avoid the user's configuration file from
# being loaded, as it may contain settings that cause our tests to
# fail or hang.
cmdline = ('ssh -2 -l testuser -p %i '
'-F /dev/null '
'-oUserKnownHostsFile=kh_test '
'-oPasswordAuthentication=no '
# Always use the RSA key, since that's the one in kh_test.
'-oHostKeyAlgorithms=ssh-rsa '
'-a '
'-i dsa_test ') + opts + sshArgs + \
' 127.0.0.1 ' + remoteCommand
port = self.conchServer.getHost().port
cmds = (cmdline % port).split()
encodedCmds = []
for cmd in cmds:
if isinstance(cmd, unicode):
cmd = cmd.encode("utf-8")
encodedCmds.append(cmd)
reactor.spawnProcess(process, which('ssh')[0], encodedCmds)
return process.deferred
return d.addCallback(hasPAKT)
class OpenSSHKeyExchangeTests(ConchServerSetupMixin, OpenSSHClientMixin,
unittest.TestCase):
"""
Tests L{SSHTransportBase}'s key exchange algorithm compatibility with
OpenSSH.
"""
def assertExecuteWithKexAlgorithm(self, keyExchangeAlgo):
"""
Call execute() method of L{OpenSSHClientMixin} with an ssh option that
forces the exclusive use of the key exchange algorithm specified by
keyExchangeAlgo
@type keyExchangeAlgo: L{str}
@param keyExchangeAlgo: The key exchange algorithm to use
@return: L{defer.Deferred}
"""
kexAlgorithms = []
try:
output = subprocess.check_output([which('ssh')[0], '-Q', 'kex'],
stderr=subprocess.STDOUT)
if not isinstance(output, str):
output = output.decode("utf-8")
kexAlgorithms = output.split()
except:
pass
if keyExchangeAlgo not in kexAlgorithms:
raise unittest.SkipTest(
"{} not supported by ssh client".format(
keyExchangeAlgo))
d = self.execute('echo hello', ConchTestOpenSSHProcess(),
'-oKexAlgorithms=' + keyExchangeAlgo)
return d.addCallback(self.assertEqual, b'hello\n')
def test_ECDHSHA256(self):
"""
The ecdh-sha2-nistp256 key exchange algorithm is compatible with
OpenSSH
"""
return self.assertExecuteWithKexAlgorithm(
'ecdh-sha2-nistp256')
def test_ECDHSHA384(self):
"""
The ecdh-sha2-nistp384 key exchange algorithm is compatible with
OpenSSH
"""
return self.assertExecuteWithKexAlgorithm(
'ecdh-sha2-nistp384')
def test_ECDHSHA521(self):
"""
The ecdh-sha2-nistp521 key exchange algorithm is compatible with
OpenSSH
"""
return self.assertExecuteWithKexAlgorithm(
'ecdh-sha2-nistp521')
def test_DH_GROUP14(self):
"""
The diffie-hellman-group14-sha1 key exchange algorithm is compatible
with OpenSSH.
"""
return self.assertExecuteWithKexAlgorithm(
'diffie-hellman-group14-sha1')
def test_DH_GROUP_EXCHANGE_SHA1(self):
"""
The diffie-hellman-group-exchange-sha1 key exchange algorithm is
compatible with OpenSSH.
"""
return self.assertExecuteWithKexAlgorithm(
'diffie-hellman-group-exchange-sha1')
def test_DH_GROUP_EXCHANGE_SHA256(self):
"""
The diffie-hellman-group-exchange-sha256 key exchange algorithm is
compatible with OpenSSH.
"""
return self.assertExecuteWithKexAlgorithm(
'diffie-hellman-group-exchange-sha256')
def test_unsupported_algorithm(self):
"""
The list of key exchange algorithms supported
by OpenSSH client is obtained with C{ssh -Q kex}.
"""
self.assertRaises(unittest.SkipTest,
self.assertExecuteWithKexAlgorithm,
'unsupported-algorithm')
class OpenSSHClientForwardingTests(ForwardingMixin, OpenSSHClientMixin,
unittest.TestCase):
"""
Connection forwarding tests run against the OpenSSL command line client.
"""
def test_localToRemoteForwardingV6(self):
"""
Forwarding of arbitrary IPv6 TCP connections via SSH.
"""
localPort = self._getFreePort()
process = ConchTestForwardingProcess(localPort, b'test\n')
d = self.execute('', process,
sshArgs='-N -L%i:[::1]:%i'
% (localPort, self.echoPortV6))
d.addCallback(self.assertEqual, b'test\n')
return d
if not HAS_IPV6:
test_localToRemoteForwardingV6.skip = "Requires IPv6 support"
class OpenSSHClientRekeyTests(RekeyTestsMixin, OpenSSHClientMixin,
unittest.TestCase):
"""
Rekeying tests run against the OpenSSL command line client.
"""
class CmdLineClientTests(ForwardingMixin, unittest.TestCase):
"""
Connection forwarding tests run against the Conch command line client.
"""
if runtime.platformType == 'win32':
skip = "can't run cmdline client on win32"
def execute(self, remoteCommand, process, sshArgs='', conchArgs=None):
"""
As for L{OpenSSHClientTestCase.execute}, except it runs the 'conch'
command line tool, not 'ssh'.
"""
if conchArgs is None:
conchArgs = []
process.deferred = defer.Deferred()
port = self.conchServer.getHost().port
cmd = ('-p {} -l testuser '
'--known-hosts kh_test '
'--user-authentications publickey '
'-a '
'-i dsa_test '
'-v '.format(port) + sshArgs +
' 127.0.0.1 ' + remoteCommand)
cmds = _makeArgs(conchArgs + cmd.split())
env = os.environ.copy()
env['PYTHONPATH'] = os.pathsep.join(sys.path)
encodedCmds = []
encodedEnv = {}
for cmd in cmds:
if isinstance(cmd, unicode):
cmd = cmd.encode("utf-8")
encodedCmds.append(cmd)
for var in env:
val = env[var]
if isinstance(var, unicode):
var = var.encode("utf-8")
if isinstance(val, unicode):
val = val.encode("utf-8")
encodedEnv[var] = val
reactor.spawnProcess(process, sys.executable, encodedCmds, env=encodedEnv)
return process.deferred
def test_runWithLogFile(self):
"""
It can store logs to a local file.
"""
def cb_check_log(result):
logContent = logPath.getContent()
self.assertIn(b'Log opened.', logContent)
logPath = filepath.FilePath(self.mktemp())
d = self.execute(
remoteCommand='echo goodbye',
process=ConchTestOpenSSHProcess(),
conchArgs=['--log', '--logfile', logPath.path,
'--host-key-algorithms', 'ssh-rsa']
)
d.addCallback(self.assertEqual, b'goodbye\n')
d.addCallback(cb_check_log)
return d
def test_runWithNoHostAlgorithmsSpecified(self):
"""
Do not use --host-key-algorithms flag on command line.
"""
d = self.execute(
remoteCommand='echo goodbye',
process=ConchTestOpenSSHProcess()
)
d.addCallback(self.assertEqual, b'goodbye\n')
return d