Linux lhjmq-records 5.15.0-118-generic #128-Ubuntu SMP Fri Jul 5 09:28:59 UTC 2024 x86_64
Your IP : 18.224.60.19
# Copyright 2005 Divmod, Inc. See LICENSE file for details
# Copyright (c) Twisted Matrix Laboratories.
# See LICENSE for details.
"""
Tests for L{twisted.internet._sslverify}.
"""
import datetime
import itertools
import sys
from unittest import skipIf
from zope.interface import implementer
from incremental import Version
from twisted.internet import defer, interfaces, protocol, reactor
from twisted.internet._idna import _idnaText
from twisted.internet.error import CertificateError, ConnectionClosed, ConnectionLost
from twisted.python.compat import nativeString
from twisted.python.filepath import FilePath
from twisted.python.modules import getModule
from twisted.python.reflect import requireModule
from twisted.test.iosim import connectedServerAndClient
from twisted.test.test_twisted import SetAsideModule
from twisted.trial import util
from twisted.trial.unittest import SkipTest, SynchronousTestCase, TestCase
skipSSL = ""
skipSNI = ""
skipNPN = ""
skipALPN = ""
if requireModule("OpenSSL"):
import ipaddress
from OpenSSL import SSL
from OpenSSL.crypto import FILETYPE_PEM, TYPE_RSA, X509, PKey, get_elliptic_curves
from cryptography import x509
from cryptography.hazmat.backends import default_backend
from cryptography.hazmat.primitives import hashes
from cryptography.hazmat.primitives.asymmetric import rsa
from cryptography.hazmat.primitives.serialization import (
Encoding,
NoEncryption,
PrivateFormat,
)
from cryptography.x509.oid import NameOID
from twisted.internet import ssl
try:
ctx = SSL.Context(SSL.SSLv23_METHOD)
ctx.set_npn_advertise_callback(lambda c: None)
except (NotImplementedError, AttributeError):
skipNPN = (
"NPN is deprecated (and OpenSSL 1.0.1 or greater required for NPN"
" support)"
)
try:
ctx = SSL.Context(SSL.SSLv23_METHOD)
ctx.set_alpn_select_callback(lambda c: None) # type: ignore[misc,arg-type]
except NotImplementedError:
skipALPN = "OpenSSL 1.0.2 or greater required for ALPN support"
else:
skipSSL = "OpenSSL is required for SSL tests."
skipSNI = skipSSL
skipNPN = skipSSL
skipALPN = skipSSL
if not skipSSL:
from twisted.internet import _sslverify as sslverify
from twisted.internet.ssl import VerificationError, platformTrust
from twisted.protocols.tls import TLSMemoryBIOFactory
# A couple of static PEM-format certificates to be used by various tests.
A_HOST_CERTIFICATE_PEM = """
-----BEGIN CERTIFICATE-----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-----END CERTIFICATE-----
"""
A_PEER_CERTIFICATE_PEM = """
-----BEGIN CERTIFICATE-----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-----END CERTIFICATE-----
"""
A_KEYPAIR = getModule(__name__).filePath.sibling("server.pem").getContent()
def counter(counter=itertools.count()):
"""
Each time we're called, return the next integer in the natural numbers.
"""
return next(counter)
def makeCertificate(**kw):
keypair = PKey()
keypair.generate_key(TYPE_RSA, 2048)
certificate = X509()
certificate.gmtime_adj_notBefore(0)
certificate.gmtime_adj_notAfter(60 * 60 * 24 * 365) # One year
for xname in certificate.get_issuer(), certificate.get_subject():
for (k, v) in kw.items():
setattr(xname, k, nativeString(v))
certificate.set_serial_number(counter())
certificate.set_pubkey(keypair)
certificate.sign(keypair, "md5")
return keypair, certificate
def certificatesForAuthorityAndServer(serviceIdentity="example.com"):
"""
Create a self-signed CA certificate and server certificate signed by the
CA.
@param serviceIdentity: The identity (hostname) of the server.
@type serviceIdentity: L{unicode}
@return: a 2-tuple of C{(certificate_authority_certificate,
server_certificate)}
@rtype: L{tuple} of (L{sslverify.Certificate},
L{sslverify.PrivateCertificate})
"""
commonNameForCA = x509.Name(
[x509.NameAttribute(NameOID.COMMON_NAME, "Testing Example CA")]
)
commonNameForServer = x509.Name(
[x509.NameAttribute(NameOID.COMMON_NAME, "Testing Example Server")]
)
oneDay = datetime.timedelta(1, 0, 0)
privateKeyForCA = rsa.generate_private_key(
public_exponent=65537, key_size=4096, backend=default_backend()
)
publicKeyForCA = privateKeyForCA.public_key()
caCertificate = (
x509.CertificateBuilder()
.subject_name(commonNameForCA)
.issuer_name(commonNameForCA)
.not_valid_before(datetime.datetime.today() - oneDay)
.not_valid_after(datetime.datetime.today() + oneDay)
.serial_number(x509.random_serial_number())
.public_key(publicKeyForCA)
.add_extension(
x509.BasicConstraints(ca=True, path_length=9),
critical=True,
)
.sign(
private_key=privateKeyForCA,
algorithm=hashes.SHA256(),
backend=default_backend(),
)
)
privateKeyForServer = rsa.generate_private_key(
public_exponent=65537, key_size=4096, backend=default_backend()
)
publicKeyForServer = privateKeyForServer.public_key()
try:
ipAddress = ipaddress.ip_address(serviceIdentity)
except ValueError:
subjectAlternativeNames = [
x509.DNSName(serviceIdentity.encode("idna").decode("ascii"))
]
else:
subjectAlternativeNames = [x509.IPAddress(ipAddress)]
serverCertificate = (
x509.CertificateBuilder()
.subject_name(commonNameForServer)
.issuer_name(commonNameForCA)
.not_valid_before(datetime.datetime.today() - oneDay)
.not_valid_after(datetime.datetime.today() + oneDay)
.serial_number(x509.random_serial_number())
.public_key(publicKeyForServer)
.add_extension(
x509.BasicConstraints(ca=False, path_length=None),
critical=True,
)
.add_extension(
x509.SubjectAlternativeName(subjectAlternativeNames),
critical=True,
)
.sign(
private_key=privateKeyForCA,
algorithm=hashes.SHA256(),
backend=default_backend(),
)
)
caSelfCert = sslverify.Certificate.loadPEM(caCertificate.public_bytes(Encoding.PEM))
serverCert = sslverify.PrivateCertificate.loadPEM(
b"\n".join(
[
privateKeyForServer.private_bytes(
Encoding.PEM,
PrivateFormat.TraditionalOpenSSL,
NoEncryption(),
),
serverCertificate.public_bytes(Encoding.PEM),
]
)
)
return caSelfCert, serverCert
def _loopbackTLSConnection(serverOpts, clientOpts):
"""
Common implementation code for both L{loopbackTLSConnection} and
L{loopbackTLSConnectionInMemory}. Creates a loopback TLS connection
using the provided server and client context factories.
@param serverOpts: An OpenSSL context factory for the server.
@type serverOpts: C{OpenSSLCertificateOptions}, or any class with an
equivalent API.
@param clientOpts: An OpenSSL context factory for the client.
@type clientOpts: C{OpenSSLCertificateOptions}, or any class with an
equivalent API.
@return: 5-tuple of server-tls-protocol, server-inner-protocol,
client-tls-protocol, client-inner-protocol and L{IOPump}
@rtype: L{tuple}
"""
class GreetingServer(protocol.Protocol):
greeting = b"greetings!"
def connectionMade(self):
self.transport.write(self.greeting)
class ListeningClient(protocol.Protocol):
data = b""
lostReason = None
def dataReceived(self, data):
self.data += data
def connectionLost(self, reason):
self.lostReason = reason
clientWrappedProto = ListeningClient()
serverWrappedProto = GreetingServer()
plainClientFactory = protocol.Factory()
plainClientFactory.protocol = lambda: clientWrappedProto
plainServerFactory = protocol.Factory()
plainServerFactory.protocol = lambda: serverWrappedProto
clientFactory = TLSMemoryBIOFactory(
clientOpts, isClient=True, wrappedFactory=plainServerFactory
)
serverFactory = TLSMemoryBIOFactory(
serverOpts, isClient=False, wrappedFactory=plainClientFactory
)
sProto, cProto, pump = connectedServerAndClient(
lambda: serverFactory.buildProtocol(None),
lambda: clientFactory.buildProtocol(None),
)
return sProto, cProto, serverWrappedProto, clientWrappedProto, pump
def loopbackTLSConnection(trustRoot, privateKeyFile, chainedCertFile=None):
"""
Create a loopback TLS connection with the given trust and keys.
@param trustRoot: the C{trustRoot} argument for the client connection's
context.
@type trustRoot: L{sslverify.IOpenSSLTrustRoot}
@param privateKeyFile: The name of the file containing the private key.
@type privateKeyFile: L{str} (native string; file name)
@param chainedCertFile: The name of the chained certificate file.
@type chainedCertFile: L{str} (native string; file name)
@return: 3-tuple of server-protocol, client-protocol, and L{IOPump}
@rtype: L{tuple}
"""
class ContextFactory:
def getContext(self):
"""
Create a context for the server side of the connection.
@return: an SSL context using a certificate and key.
@rtype: C{OpenSSL.SSL.Context}
"""
ctx = SSL.Context(SSL.SSLv23_METHOD)
if chainedCertFile is not None:
ctx.use_certificate_chain_file(chainedCertFile)
ctx.use_privatekey_file(privateKeyFile)
# Let the test author know if they screwed something up.
ctx.check_privatekey()
return ctx
serverOpts = ContextFactory()
clientOpts = sslverify.OpenSSLCertificateOptions(trustRoot=trustRoot)
return _loopbackTLSConnection(serverOpts, clientOpts)
def loopbackTLSConnectionInMemory(
trustRoot,
privateKey,
serverCertificate,
clientProtocols=None,
serverProtocols=None,
clientOptions=None,
):
"""
Create a loopback TLS connection with the given trust and keys. Like
L{loopbackTLSConnection}, but using in-memory certificates and keys rather
than writing them to disk.
@param trustRoot: the C{trustRoot} argument for the client connection's
context.
@type trustRoot: L{sslverify.IOpenSSLTrustRoot}
@param privateKey: The private key.
@type privateKey: L{str} (native string)
@param serverCertificate: The certificate used by the server.
@type chainedCertFile: L{str} (native string)
@param clientProtocols: The protocols the client is willing to negotiate
using NPN/ALPN.
@param serverProtocols: The protocols the server is willing to negotiate
using NPN/ALPN.
@param clientOptions: The type of C{OpenSSLCertificateOptions} class to
use for the client. Defaults to C{OpenSSLCertificateOptions}.
@return: 3-tuple of server-protocol, client-protocol, and L{IOPump}
@rtype: L{tuple}
"""
if clientOptions is None:
clientOptions = sslverify.OpenSSLCertificateOptions
clientCertOpts = clientOptions(
trustRoot=trustRoot, acceptableProtocols=clientProtocols
)
serverCertOpts = sslverify.OpenSSLCertificateOptions(
privateKey=privateKey,
certificate=serverCertificate,
acceptableProtocols=serverProtocols,
)
return _loopbackTLSConnection(serverCertOpts, clientCertOpts)
def pathContainingDumpOf(testCase, *dumpables):
"""
Create a temporary file to store some serializable-as-PEM objects in, and
return its name.
@param testCase: a test case to use for generating a temporary directory.
@type testCase: L{twisted.trial.unittest.TestCase}
@param dumpables: arguments are objects from pyOpenSSL with a C{dump}
method, taking a pyOpenSSL file-type constant, such as
L{OpenSSL.crypto.FILETYPE_PEM} or L{OpenSSL.crypto.FILETYPE_ASN1}.
@type dumpables: L{tuple} of L{object} with C{dump} method taking L{int}
returning L{bytes}
@return: the path to a file where all of the dumpables were dumped in PEM
format.
@rtype: L{str}
"""
fname = testCase.mktemp()
with open(fname, "wb") as f:
for dumpable in dumpables:
f.write(dumpable.dump(FILETYPE_PEM))
return fname
class DataCallbackProtocol(protocol.Protocol):
def dataReceived(self, data):
d, self.factory.onData = self.factory.onData, None
if d is not None:
d.callback(data)
def connectionLost(self, reason):
d, self.factory.onLost = self.factory.onLost, None
if d is not None:
d.errback(reason)
class WritingProtocol(protocol.Protocol):
byte = b"x"
def connectionMade(self):
self.transport.write(self.byte)
def connectionLost(self, reason):
self.factory.onLost.errback(reason)
class FakeContext:
"""
Introspectable fake of an C{OpenSSL.SSL.Context}.
Saves call arguments for later introspection.
Necessary because C{Context} offers poor introspection. cf. this
U{pyOpenSSL bug<https://bugs.launchpad.net/pyopenssl/+bug/1173899>}.
@ivar _method: See C{method} parameter of L{__init__}.
@ivar _options: L{int} of C{OR}ed values from calls of L{set_options}.
@ivar _certificate: Set by L{use_certificate}.
@ivar _privateKey: Set by L{use_privatekey}.
@ivar _verify: Set by L{set_verify}.
@ivar _verifyDepth: Set by L{set_verify_depth}.
@ivar _mode: Set by L{set_mode}.
@ivar _sessionID: Set by L{set_session_id}.
@ivar _extraCertChain: Accumulated L{list} of all extra certificates added
by L{add_extra_chain_cert}.
@ivar _cipherList: Set by L{set_cipher_list}.
@ivar _dhFilename: Set by L{load_tmp_dh}.
@ivar _defaultVerifyPathsSet: Set by L{set_default_verify_paths}
@ivar _ecCurve: Set by L{set_tmp_ecdh}
"""
_options = 0
def __init__(self, method):
self._method = method
self._extraCertChain = []
self._defaultVerifyPathsSet = False
self._ecCurve = None
# Note that this value is explicitly documented as the default by
# https://www.openssl.org/docs/man1.1.1/man3/
# SSL_CTX_set_session_cache_mode.html
self._sessionCacheMode = SSL.SESS_CACHE_SERVER
def set_options(self, options):
self._options |= options
def use_certificate(self, certificate):
self._certificate = certificate
def use_privatekey(self, privateKey):
self._privateKey = privateKey
def check_privatekey(self):
return None
def set_mode(self, mode):
"""
Set the mode. See L{SSL.Context.set_mode}.
@param mode: See L{SSL.Context.set_mode}.
"""
self._mode = mode
def set_verify(self, flags, callback):
self._verify = flags, callback
def set_verify_depth(self, depth):
self._verifyDepth = depth
def set_session_id(self, sessionIDContext):
# This fake should change when the upstream changes:
# https://github.com/pyca/pyopenssl/issues/845
self._sessionIDContext = sessionIDContext
def set_session_cache_mode(self, cacheMode):
"""
Set the session cache mode on the context, as per
L{SSL.Context.set_session_cache_mode}.
"""
self._sessionCacheMode = cacheMode
def get_session_cache_mode(self):
"""
Retrieve the session cache mode from the context, as per
L{SSL.Context.get_session_cache_mode}.
"""
return self._sessionCacheMode
def add_extra_chain_cert(self, cert):
self._extraCertChain.append(cert)
def set_cipher_list(self, cipherList):
self._cipherList = cipherList
def load_tmp_dh(self, dhfilename):
self._dhFilename = dhfilename
def set_default_verify_paths(self):
"""
Set the default paths for the platform.
"""
self._defaultVerifyPathsSet = True
def set_tmp_ecdh(self, curve):
"""
Set an ECDH curve. Should only be called by OpenSSL 1.0.1
code.
@param curve: See L{OpenSSL.SSL.Context.set_tmp_ecdh}
"""
self._ecCurve = curve
class ClientOptionsTests(SynchronousTestCase):
"""
Tests for L{sslverify.optionsForClientTLS}.
"""
if skipSSL:
skip = skipSSL
def test_extraKeywords(self):
"""
When passed a keyword parameter other than C{extraCertificateOptions},
L{sslverify.optionsForClientTLS} raises an exception just like a
normal Python function would.
"""
error = self.assertRaises(
TypeError,
sslverify.optionsForClientTLS,
hostname="alpha",
someRandomThing="beta",
)
self.assertEqual(
str(error),
"optionsForClientTLS() got an unexpected keyword argument "
"'someRandomThing'",
)
def test_bytesFailFast(self):
"""
If you pass L{bytes} as the hostname to
L{sslverify.optionsForClientTLS} it immediately raises a L{TypeError}.
"""
error = self.assertRaises(
TypeError, sslverify.optionsForClientTLS, b"not-actually-a-hostname.com"
)
expectedText = (
"optionsForClientTLS requires text for host names, not " + bytes.__name__
)
self.assertEqual(str(error), expectedText)
def test_dNSNameHostname(self):
"""
If you pass a dNSName to L{sslverify.optionsForClientTLS}
L{_hostnameIsDnsName} will be True
"""
options = sslverify.optionsForClientTLS("example.com")
self.assertTrue(options._hostnameIsDnsName)
def test_IPv4AddressHostname(self):
"""
If you pass an IPv4 address to L{sslverify.optionsForClientTLS}
L{_hostnameIsDnsName} will be False
"""
options = sslverify.optionsForClientTLS("127.0.0.1")
self.assertFalse(options._hostnameIsDnsName)
def test_IPv6AddressHostname(self):
"""
If you pass an IPv6 address to L{sslverify.optionsForClientTLS}
L{_hostnameIsDnsName} will be False
"""
options = sslverify.optionsForClientTLS("::1")
self.assertFalse(options._hostnameIsDnsName)
class FakeChooseDiffieHellmanEllipticCurve:
"""
A fake implementation of L{_ChooseDiffieHellmanEllipticCurve}
"""
def __init__(self, versionNumber, openSSLlib, openSSLcrypto):
"""
A no-op constructor.
"""
def configureECDHCurve(self, ctx):
"""
A null configuration.
@param ctx: An L{OpenSSL.SSL.Context} that would be
configured.
"""
class OpenSSLOptionsTestsMixin:
"""
A mixin for L{OpenSSLOptions} test cases creates client and server
certificates, signs them with a CA, and provides a L{loopback}
that creates TLS a connections with them.
"""
if skipSSL:
skip = skipSSL
serverPort = clientConn = None
onServerLost = onClientLost = None
def setUp(self):
"""
Create class variables of client and server certificates.
"""
self.sKey, self.sCert = makeCertificate(
O=b"Server Test Certificate", CN=b"server"
)
self.cKey, self.cCert = makeCertificate(
O=b"Client Test Certificate", CN=b"client"
)
self.caCert1 = makeCertificate(O=b"CA Test Certificate 1", CN=b"ca1")[1]
self.caCert2 = makeCertificate(O=b"CA Test Certificate", CN=b"ca2")[1]
self.caCerts = [self.caCert1, self.caCert2]
self.extraCertChain = self.caCerts
def tearDown(self):
if self.serverPort is not None:
self.serverPort.stopListening()
if self.clientConn is not None:
self.clientConn.disconnect()
L = []
if self.onServerLost is not None:
L.append(self.onServerLost)
if self.onClientLost is not None:
L.append(self.onClientLost)
return defer.DeferredList(L, consumeErrors=True)
def loopback(
self,
serverCertOpts,
clientCertOpts,
onServerLost=None,
onClientLost=None,
onData=None,
):
if onServerLost is None:
self.onServerLost = onServerLost = defer.Deferred()
if onClientLost is None:
self.onClientLost = onClientLost = defer.Deferred()
if onData is None:
onData = defer.Deferred()
serverFactory = protocol.ServerFactory()
serverFactory.protocol = DataCallbackProtocol
serverFactory.onLost = onServerLost
serverFactory.onData = onData
clientFactory = protocol.ClientFactory()
clientFactory.protocol = WritingProtocol
clientFactory.onLost = onClientLost
self.serverPort = reactor.listenSSL(0, serverFactory, serverCertOpts)
self.clientConn = reactor.connectSSL(
"127.0.0.1", self.serverPort.getHost().port, clientFactory, clientCertOpts
)
class OpenSSLOptionsTests(OpenSSLOptionsTestsMixin, TestCase):
"""
Tests for L{sslverify.OpenSSLOptions}.
"""
def setUp(self):
"""
Same as L{OpenSSLOptionsTestsMixin.setUp}, but it also patches
L{sslverify._ChooseDiffieHellmanEllipticCurve}.
"""
super().setUp()
self.patch(
sslverify,
"_ChooseDiffieHellmanEllipticCurve",
FakeChooseDiffieHellmanEllipticCurve,
)
def test_constructorWithOnlyPrivateKey(self):
"""
C{privateKey} and C{certificate} make only sense if both are set.
"""
self.assertRaises(
ValueError, sslverify.OpenSSLCertificateOptions, privateKey=self.sKey
)
def test_constructorWithOnlyCertificate(self):
"""
C{privateKey} and C{certificate} make only sense if both are set.
"""
self.assertRaises(
ValueError, sslverify.OpenSSLCertificateOptions, certificate=self.sCert
)
def test_constructorWithCertificateAndPrivateKey(self):
"""
Specifying C{privateKey} and C{certificate} initializes correctly.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey, certificate=self.sCert
)
self.assertEqual(opts.privateKey, self.sKey)
self.assertEqual(opts.certificate, self.sCert)
self.assertEqual(opts.extraCertChain, [])
def test_constructorDoesNotAllowVerifyWithoutCACerts(self):
"""
C{verify} must not be C{True} without specifying C{caCerts}.
"""
self.assertRaises(
ValueError,
sslverify.OpenSSLCertificateOptions,
privateKey=self.sKey,
certificate=self.sCert,
verify=True,
)
def test_constructorDoesNotAllowLegacyWithTrustRoot(self):
"""
C{verify}, C{requireCertificate}, and C{caCerts} must not be specified
by the caller (to be I{any} value, even the default!) when specifying
C{trustRoot}.
"""
self.assertRaises(
TypeError,
sslverify.OpenSSLCertificateOptions,
privateKey=self.sKey,
certificate=self.sCert,
verify=True,
trustRoot=None,
caCerts=self.caCerts,
)
self.assertRaises(
TypeError,
sslverify.OpenSSLCertificateOptions,
privateKey=self.sKey,
certificate=self.sCert,
trustRoot=None,
requireCertificate=True,
)
def test_constructorAllowsCACertsWithoutVerify(self):
"""
It's currently a NOP, but valid.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey, certificate=self.sCert, caCerts=self.caCerts
)
self.assertFalse(opts.verify)
self.assertEqual(self.caCerts, opts.caCerts)
def test_constructorWithVerifyAndCACerts(self):
"""
Specifying C{verify} and C{caCerts} initializes correctly.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
verify=True,
caCerts=self.caCerts,
)
self.assertTrue(opts.verify)
self.assertEqual(self.caCerts, opts.caCerts)
def test_constructorSetsExtraChain(self):
"""
Setting C{extraCertChain} works if C{certificate} and C{privateKey} are
set along with it.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
extraCertChain=self.extraCertChain,
)
self.assertEqual(self.extraCertChain, opts.extraCertChain)
def test_constructorDoesNotAllowExtraChainWithoutPrivateKey(self):
"""
A C{extraCertChain} without C{privateKey} doesn't make sense and is
thus rejected.
"""
self.assertRaises(
ValueError,
sslverify.OpenSSLCertificateOptions,
certificate=self.sCert,
extraCertChain=self.extraCertChain,
)
def test_constructorDoesNotAllowExtraChainWithOutPrivateKey(self):
"""
A C{extraCertChain} without C{certificate} doesn't make sense and is
thus rejected.
"""
self.assertRaises(
ValueError,
sslverify.OpenSSLCertificateOptions,
privateKey=self.sKey,
extraCertChain=self.extraCertChain,
)
def test_extraChainFilesAreAddedIfSupplied(self):
"""
If C{extraCertChain} is set and all prerequisites are met, the
specified chain certificates are added to C{Context}s that get
created.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
extraCertChain=self.extraCertChain,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
self.assertEqual(self.sKey, ctx._privateKey)
self.assertEqual(self.sCert, ctx._certificate)
self.assertEqual(self.extraCertChain, ctx._extraCertChain)
def test_extraChainDoesNotBreakPyOpenSSL(self):
"""
C{extraCertChain} doesn't break C{OpenSSL.SSL.Context} creation.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
extraCertChain=self.extraCertChain,
)
ctx = opts.getContext()
self.assertIsInstance(ctx, SSL.Context)
def test_acceptableCiphersAreAlwaysSet(self):
"""
If the user doesn't supply custom acceptable ciphers, a shipped secure
default is used. We can't check directly for it because the effective
cipher string we set varies with platforms.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
self.assertEqual(opts._cipherString.encode("ascii"), ctx._cipherList)
def test_honorsAcceptableCiphersArgument(self):
"""
If acceptable ciphers are passed, they are used.
"""
@implementer(interfaces.IAcceptableCiphers)
class FakeAcceptableCiphers:
def selectCiphers(self, _):
return [sslverify.OpenSSLCipher("sentinel")]
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
acceptableCiphers=FakeAcceptableCiphers(),
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
self.assertEqual(b"sentinel", ctx._cipherList)
def test_basicSecurityOptionsAreSet(self):
"""
Every context must have C{OP_NO_SSLv2}, C{OP_NO_COMPRESSION}, and
C{OP_CIPHER_SERVER_PREFERENCE} set.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2 | SSL.OP_NO_COMPRESSION | SSL.OP_CIPHER_SERVER_PREFERENCE
)
self.assertEqual(options, ctx._options & options)
def test_modeIsSet(self):
"""
Every context must be in C{MODE_RELEASE_BUFFERS} mode.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
self.assertEqual(SSL.MODE_RELEASE_BUFFERS, ctx._mode)
def test_singleUseKeys(self):
"""
If C{singleUseKeys} is set, every context must have
C{OP_SINGLE_DH_USE} and C{OP_SINGLE_ECDH_USE} set.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
enableSingleUseKeys=True,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = SSL.OP_SINGLE_DH_USE | SSL.OP_SINGLE_ECDH_USE
self.assertEqual(options, ctx._options & options)
def test_methodIsDeprecated(self):
"""
Passing C{method} to L{sslverify.OpenSSLCertificateOptions} is
deprecated.
"""
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
method=SSL.SSLv23_METHOD,
)
message = (
"Passing method to twisted.internet.ssl.CertificateOptions "
"was deprecated in Twisted 17.1.0. Please use a "
"combination of insecurelyLowerMinimumTo, raiseMinimumTo, "
"and lowerMaximumSecurityTo instead, as Twisted will "
"correctly configure the method."
)
warnings = self.flushWarnings([self.test_methodIsDeprecated])
self.assertEqual(1, len(warnings))
self.assertEqual(DeprecationWarning, warnings[0]["category"])
self.assertEqual(message, warnings[0]["message"])
def test_tlsv1ByDefault(self):
"""
L{sslverify.OpenSSLCertificateOptions} will make the default minimum
TLS version v1.0, if no C{method}, or C{insecurelyLowerMinimumTo} is
given.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey, certificate=self.sCert
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_SSLv3
)
self.assertEqual(options, ctx._options & options)
def test_tlsProtocolsAtLeastWithMinimum(self):
"""
Passing C{insecurelyLowerMinimumTo} along with C{raiseMinimumTo} to
L{sslverify.OpenSSLCertificateOptions} will cause it to raise an
exception.
"""
with self.assertRaises(TypeError) as e:
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
raiseMinimumTo=sslverify.TLSVersion.TLSv1_2,
insecurelyLowerMinimumTo=sslverify.TLSVersion.TLSv1_2,
)
self.assertIn("raiseMinimumTo", e.exception.args[0])
self.assertIn("insecurelyLowerMinimumTo", e.exception.args[0])
self.assertIn("exclusive", e.exception.args[0])
def test_tlsProtocolsNoMethodWithAtLeast(self):
"""
Passing C{raiseMinimumTo} along with C{method} to
L{sslverify.OpenSSLCertificateOptions} will cause it to raise an
exception.
"""
with self.assertRaises(TypeError) as e:
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
method=SSL.SSLv23_METHOD,
raiseMinimumTo=sslverify.TLSVersion.TLSv1_2,
)
self.assertIn("method", e.exception.args[0])
self.assertIn("raiseMinimumTo", e.exception.args[0])
self.assertIn("exclusive", e.exception.args[0])
def test_tlsProtocolsNoMethodWithMinimum(self):
"""
Passing C{insecurelyLowerMinimumTo} along with C{method} to
L{sslverify.OpenSSLCertificateOptions} will cause it to raise an
exception.
"""
with self.assertRaises(TypeError) as e:
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
method=SSL.SSLv23_METHOD,
insecurelyLowerMinimumTo=sslverify.TLSVersion.TLSv1_2,
)
self.assertIn("method", e.exception.args[0])
self.assertIn("insecurelyLowerMinimumTo", e.exception.args[0])
self.assertIn("exclusive", e.exception.args[0])
def test_tlsProtocolsNoMethodWithMaximum(self):
"""
Passing C{lowerMaximumSecurityTo} along with C{method} to
L{sslverify.OpenSSLCertificateOptions} will cause it to raise an
exception.
"""
with self.assertRaises(TypeError) as e:
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
method=SSL.SSLv23_METHOD,
lowerMaximumSecurityTo=sslverify.TLSVersion.TLSv1_2,
)
self.assertIn("method", e.exception.args[0])
self.assertIn("lowerMaximumSecurityTo", e.exception.args[0])
self.assertIn("exclusive", e.exception.args[0])
def test_tlsVersionRangeInOrder(self):
"""
Passing out of order TLS versions to C{insecurelyLowerMinimumTo} and
C{lowerMaximumSecurityTo} will cause it to raise an exception.
"""
with self.assertRaises(ValueError) as e:
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
insecurelyLowerMinimumTo=sslverify.TLSVersion.TLSv1_0,
lowerMaximumSecurityTo=sslverify.TLSVersion.SSLv3,
)
self.assertEqual(
e.exception.args,
(
(
"insecurelyLowerMinimumTo needs to be lower than "
"lowerMaximumSecurityTo"
),
),
)
def test_tlsVersionRangeInOrderAtLeast(self):
"""
Passing out of order TLS versions to C{raiseMinimumTo} and
C{lowerMaximumSecurityTo} will cause it to raise an exception.
"""
with self.assertRaises(ValueError) as e:
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
raiseMinimumTo=sslverify.TLSVersion.TLSv1_0,
lowerMaximumSecurityTo=sslverify.TLSVersion.SSLv3,
)
self.assertEqual(
e.exception.args,
(("raiseMinimumTo needs to be lower than " "lowerMaximumSecurityTo"),),
)
def test_tlsProtocolsreduceToMaxWithoutMin(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{lowerMaximumSecurityTo} but no C{raiseMinimumTo} or
C{insecurelyLowerMinimumTo} set, and C{lowerMaximumSecurityTo} is
below the minimum default, the minimum will be made the new maximum.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
lowerMaximumSecurityTo=sslverify.TLSVersion.SSLv3,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_TLSv1
| SSL.OP_NO_TLSv1_1
| SSL.OP_NO_TLSv1_2
| opts._OP_NO_TLSv1_3
)
self.assertEqual(options, ctx._options & options)
def test_tlsProtocolsSSLv3Only(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{insecurelyLowerMinimumTo} and C{lowerMaximumSecurityTo} set to
SSLv3, it will exclude all others.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
insecurelyLowerMinimumTo=sslverify.TLSVersion.SSLv3,
lowerMaximumSecurityTo=sslverify.TLSVersion.SSLv3,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_TLSv1
| SSL.OP_NO_TLSv1_1
| SSL.OP_NO_TLSv1_2
| opts._OP_NO_TLSv1_3
)
self.assertEqual(options, ctx._options & options)
def test_tlsProtocolsTLSv1Point0Only(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{insecurelyLowerMinimumTo} and C{lowerMaximumSecurityTo} set to v1.0,
it will exclude all others.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
insecurelyLowerMinimumTo=sslverify.TLSVersion.TLSv1_0,
lowerMaximumSecurityTo=sslverify.TLSVersion.TLSv1_0,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_SSLv3
| SSL.OP_NO_TLSv1_1
| SSL.OP_NO_TLSv1_2
| opts._OP_NO_TLSv1_3
)
self.assertEqual(options, ctx._options & options)
def test_tlsProtocolsTLSv1Point1Only(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{insecurelyLowerMinimumTo} and C{lowerMaximumSecurityTo} set to v1.1,
it will exclude all others.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
insecurelyLowerMinimumTo=sslverify.TLSVersion.TLSv1_1,
lowerMaximumSecurityTo=sslverify.TLSVersion.TLSv1_1,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_SSLv3
| SSL.OP_NO_TLSv1
| SSL.OP_NO_TLSv1_2
| opts._OP_NO_TLSv1_3
)
self.assertEqual(options, ctx._options & options)
def test_tlsProtocolsTLSv1Point2Only(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{insecurelyLowerMinimumTo} and C{lowerMaximumSecurityTo} set to v1.2,
it will exclude all others.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
insecurelyLowerMinimumTo=sslverify.TLSVersion.TLSv1_2,
lowerMaximumSecurityTo=sslverify.TLSVersion.TLSv1_2,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_SSLv3
| SSL.OP_NO_TLSv1
| SSL.OP_NO_TLSv1_1
| opts._OP_NO_TLSv1_3
)
self.assertEqual(options, ctx._options & options)
def test_tlsProtocolsAllModernTLS(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{insecurelyLowerMinimumTo} set to TLSv1.0 and
C{lowerMaximumSecurityTo} to TLSv1.2, it will exclude both SSLs and
the (unreleased) TLSv1.3.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
insecurelyLowerMinimumTo=sslverify.TLSVersion.TLSv1_0,
lowerMaximumSecurityTo=sslverify.TLSVersion.TLSv1_2,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_SSLv3
| opts._OP_NO_TLSv1_3
)
self.assertEqual(options, ctx._options & options)
def test_tlsProtocolsAtLeastAllSecureTLS(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{raiseMinimumTo} set to TLSv1.2, it will ignore all TLSs below
1.2 and SSL.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
raiseMinimumTo=sslverify.TLSVersion.TLSv1_2,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_SSLv3
| SSL.OP_NO_TLSv1
| SSL.OP_NO_TLSv1_1
)
self.assertEqual(options, ctx._options & options)
def test_tlsProtocolsAtLeastWillAcceptHigherDefault(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{raiseMinimumTo} set to a value lower than Twisted's default will
cause it to use the more secure default.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
raiseMinimumTo=sslverify.TLSVersion.SSLv3,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
# Future maintainer warning: this will break if we change our default
# up, so you should change it to add the relevant OP_NO flags when we
# do make that change and this test fails.
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_SSLv3
)
self.assertEqual(options, ctx._options & options)
self.assertEqual(opts._defaultMinimumTLSVersion, sslverify.TLSVersion.TLSv1_0)
def test_tlsProtocolsAllSecureTLS(self):
"""
When calling L{sslverify.OpenSSLCertificateOptions} with
C{insecurelyLowerMinimumTo} set to TLSv1.2, it will ignore all TLSs below
1.2 and SSL.
"""
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
insecurelyLowerMinimumTo=sslverify.TLSVersion.TLSv1_2,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
options = (
SSL.OP_NO_SSLv2
| SSL.OP_NO_COMPRESSION
| SSL.OP_CIPHER_SERVER_PREFERENCE
| SSL.OP_NO_SSLv3
| SSL.OP_NO_TLSv1
| SSL.OP_NO_TLSv1_1
)
self.assertEqual(options, ctx._options & options)
def test_dhParams(self):
"""
If C{dhParams} is set, they are loaded into each new context.
"""
class FakeDiffieHellmanParameters:
_dhFile = FilePath(b"dh.params")
dhParams = FakeDiffieHellmanParameters()
opts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
dhParameters=dhParams,
)
opts._contextFactory = FakeContext
ctx = opts.getContext()
self.assertEqual(FakeDiffieHellmanParameters._dhFile.path, ctx._dhFilename)
def test_abbreviatingDistinguishedNames(self):
"""
Check that abbreviations used in certificates correctly map to
complete names.
"""
self.assertEqual(
sslverify.DN(CN=b"a", OU=b"hello"),
sslverify.DistinguishedName(
commonName=b"a", organizationalUnitName=b"hello"
),
)
self.assertNotEqual(
sslverify.DN(CN=b"a", OU=b"hello"),
sslverify.DN(CN=b"a", OU=b"hello", emailAddress=b"xxx"),
)
dn = sslverify.DN(CN=b"abcdefg")
self.assertRaises(AttributeError, setattr, dn, "Cn", b"x")
self.assertEqual(dn.CN, dn.commonName)
dn.CN = b"bcdefga"
self.assertEqual(dn.CN, dn.commonName)
def testInspectDistinguishedName(self):
n = sslverify.DN(
commonName=b"common name",
organizationName=b"organization name",
organizationalUnitName=b"organizational unit name",
localityName=b"locality name",
stateOrProvinceName=b"state or province name",
countryName=b"country name",
emailAddress=b"email address",
)
s = n.inspect()
for k in [
"common name",
"organization name",
"organizational unit name",
"locality name",
"state or province name",
"country name",
"email address",
]:
self.assertIn(k, s, f"{k!r} was not in inspect output.")
self.assertIn(k.title(), s, f"{k!r} was not in inspect output.")
def testInspectDistinguishedNameWithoutAllFields(self):
n = sslverify.DN(localityName=b"locality name")
s = n.inspect()
for k in [
"common name",
"organization name",
"organizational unit name",
"state or province name",
"country name",
"email address",
]:
self.assertNotIn(k, s, f"{k!r} was in inspect output.")
self.assertNotIn(k.title(), s, f"{k!r} was in inspect output.")
self.assertIn("locality name", s)
self.assertIn("Locality Name", s)
def test_inspectCertificate(self):
"""
Test that the C{inspect} method of L{sslverify.Certificate} returns
a human-readable string containing some basic information about the
certificate.
"""
c = sslverify.Certificate.loadPEM(A_HOST_CERTIFICATE_PEM)
pk = c.getPublicKey()
keyHash = pk.keyHash()
# Maintenance Note: the algorithm used to compute the "public key hash"
# is highly dubious and can differ between underlying versions of
# OpenSSL (and across versions of Twisted), since it is not actually
# the hash of the public key by itself. If we can get the appropriate
# APIs to get the hash of the key itself out of OpenSSL, then we should
# be able to make it statically declared inline below again rather than
# computing it here.
self.assertEqual(
c.inspect().split("\n"),
[
"Certificate For Subject:",
" Common Name: example.twistedmatrix.com",
" Country Name: US",
" Email Address: nobody@twistedmatrix.com",
" Locality Name: Boston",
" Organization Name: Twisted Matrix Labs",
" Organizational Unit Name: Security",
" State Or Province Name: Massachusetts",
"",
"Issuer:",
" Common Name: example.twistedmatrix.com",
" Country Name: US",
" Email Address: nobody@twistedmatrix.com",
" Locality Name: Boston",
" Organization Name: Twisted Matrix Labs",
" Organizational Unit Name: Security",
" State Or Province Name: Massachusetts",
"",
"Serial Number: 12345",
"Digest: C4:96:11:00:30:C3:EC:EE:A3:55:AA:ED:8C:84:85:18",
"Public Key with Hash: " + keyHash,
],
)
def test_publicKeyMatching(self):
"""
L{PublicKey.matches} returns L{True} for keys from certificates with
the same key, and L{False} for keys from certificates with different
keys.
"""
hostA = sslverify.Certificate.loadPEM(A_HOST_CERTIFICATE_PEM)
hostB = sslverify.Certificate.loadPEM(A_HOST_CERTIFICATE_PEM)
peerA = sslverify.Certificate.loadPEM(A_PEER_CERTIFICATE_PEM)
self.assertTrue(hostA.getPublicKey().matches(hostB.getPublicKey()))
self.assertFalse(peerA.getPublicKey().matches(hostA.getPublicKey()))
def test_enablingAndDisablingSessions(self):
"""
The enableSessions argument sets the session cache mode; it defaults to
False (at least until https://twistedmatrix.com/trac/ticket/9764 can be
resolved).
"""
options = sslverify.OpenSSLCertificateOptions()
self.assertEqual(options.enableSessions, False)
ctx = options.getContext()
self.assertEqual(ctx.get_session_cache_mode(), SSL.SESS_CACHE_OFF)
options = sslverify.OpenSSLCertificateOptions(enableSessions=True)
self.assertEqual(options.enableSessions, True)
ctx = options.getContext()
self.assertEqual(ctx.get_session_cache_mode(), SSL.SESS_CACHE_SERVER)
def test_certificateOptionsSerialization(self):
"""
Test that __setstate__(__getstate__()) round-trips properly.
"""
firstOpts = sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
method=SSL.SSLv23_METHOD,
verify=True,
caCerts=[self.sCert],
verifyDepth=2,
requireCertificate=False,
verifyOnce=False,
enableSingleUseKeys=False,
enableSessions=False,
fixBrokenPeers=True,
enableSessionTickets=True,
)
context = firstOpts.getContext()
self.assertIs(context, firstOpts._context)
self.assertIsNotNone(context)
state = firstOpts.__getstate__()
self.assertNotIn("_context", state)
opts = sslverify.OpenSSLCertificateOptions()
opts.__setstate__(state)
self.assertEqual(opts.privateKey, self.sKey)
self.assertEqual(opts.certificate, self.sCert)
self.assertEqual(opts.method, SSL.SSLv23_METHOD)
self.assertTrue(opts.verify)
self.assertEqual(opts.caCerts, [self.sCert])
self.assertEqual(opts.verifyDepth, 2)
self.assertFalse(opts.requireCertificate)
self.assertFalse(opts.verifyOnce)
self.assertFalse(opts.enableSingleUseKeys)
self.assertFalse(opts.enableSessions)
self.assertTrue(opts.fixBrokenPeers)
self.assertTrue(opts.enableSessionTickets)
test_certificateOptionsSerialization.suppress = [ # type: ignore[attr-defined]
util.suppress(
category=DeprecationWarning,
message=r"twisted\.internet\._sslverify\.*__[gs]etstate__",
)
]
def test_certificateOptionsSessionTickets(self):
"""
Enabling session tickets should not set the OP_NO_TICKET option.
"""
opts = sslverify.OpenSSLCertificateOptions(enableSessionTickets=True)
ctx = opts.getContext()
self.assertEqual(0, ctx.set_options(0) & 0x00004000)
def test_certificateOptionsSessionTicketsDisabled(self):
"""
Enabling session tickets should set the OP_NO_TICKET option.
"""
opts = sslverify.OpenSSLCertificateOptions(enableSessionTickets=False)
ctx = opts.getContext()
self.assertEqual(0x00004000, ctx.set_options(0) & 0x00004000)
def test_allowedAnonymousClientConnection(self):
"""
Check that anonymous connections are allowed when certificates aren't
required on the server.
"""
onData = defer.Deferred()
self.loopback(
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey, certificate=self.sCert, requireCertificate=False
),
sslverify.OpenSSLCertificateOptions(requireCertificate=False),
onData=onData,
)
return onData.addCallback(
lambda result: self.assertEqual(result, WritingProtocol.byte)
)
def test_refusedAnonymousClientConnection(self):
"""
Check that anonymous connections are refused when certificates are
required on the server.
"""
onServerLost = defer.Deferred()
onClientLost = defer.Deferred()
self.loopback(
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
verify=True,
caCerts=[self.sCert],
requireCertificate=True,
),
sslverify.OpenSSLCertificateOptions(requireCertificate=False),
onServerLost=onServerLost,
onClientLost=onClientLost,
)
d = defer.DeferredList([onClientLost, onServerLost], consumeErrors=True)
def afterLost(result):
((cSuccess, cResult), (sSuccess, sResult)) = result
self.assertFalse(cSuccess)
self.assertFalse(sSuccess)
# Win32 fails to report the SSL Error, and report a connection lost
# instead: there is a race condition so that's not totally
# surprising (see ticket #2877 in the tracker)
self.assertIsInstance(cResult.value, (SSL.Error, ConnectionLost))
self.assertIsInstance(sResult.value, SSL.Error)
return d.addCallback(afterLost)
def test_failedCertificateVerification(self):
"""
Check that connecting with a certificate not accepted by the server CA
fails.
"""
onServerLost = defer.Deferred()
onClientLost = defer.Deferred()
self.loopback(
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
verify=False,
requireCertificate=False,
),
sslverify.OpenSSLCertificateOptions(
verify=True, requireCertificate=False, caCerts=[self.cCert]
),
onServerLost=onServerLost,
onClientLost=onClientLost,
)
d = defer.DeferredList([onClientLost, onServerLost], consumeErrors=True)
def afterLost(result):
((cSuccess, cResult), (sSuccess, sResult)) = result
self.assertFalse(cSuccess)
self.assertFalse(sSuccess)
return d.addCallback(afterLost)
def test_successfulCertificateVerification(self):
"""
Test a successful connection with client certificate validation on
server side.
"""
onData = defer.Deferred()
self.loopback(
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
verify=False,
requireCertificate=False,
),
sslverify.OpenSSLCertificateOptions(
verify=True, requireCertificate=True, caCerts=[self.sCert]
),
onData=onData,
)
return onData.addCallback(
lambda result: self.assertEqual(result, WritingProtocol.byte)
)
def test_successfulSymmetricSelfSignedCertificateVerification(self):
"""
Test a successful connection with validation on both server and client
sides.
"""
onData = defer.Deferred()
self.loopback(
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
verify=True,
requireCertificate=True,
caCerts=[self.cCert],
),
sslverify.OpenSSLCertificateOptions(
privateKey=self.cKey,
certificate=self.cCert,
verify=True,
requireCertificate=True,
caCerts=[self.sCert],
),
onData=onData,
)
return onData.addCallback(
lambda result: self.assertEqual(result, WritingProtocol.byte)
)
def test_verification(self):
"""
Check certificates verification building custom certificates data.
"""
clientDN = sslverify.DistinguishedName(commonName="client")
clientKey = sslverify.KeyPair.generate()
clientCertReq = clientKey.certificateRequest(clientDN)
serverDN = sslverify.DistinguishedName(commonName="server")
serverKey = sslverify.KeyPair.generate()
serverCertReq = serverKey.certificateRequest(serverDN)
clientSelfCertReq = clientKey.certificateRequest(clientDN)
clientSelfCertData = clientKey.signCertificateRequest(
clientDN, clientSelfCertReq, lambda dn: True, 132
)
clientSelfCert = clientKey.newCertificate(clientSelfCertData)
serverSelfCertReq = serverKey.certificateRequest(serverDN)
serverSelfCertData = serverKey.signCertificateRequest(
serverDN, serverSelfCertReq, lambda dn: True, 516
)
serverSelfCert = serverKey.newCertificate(serverSelfCertData)
clientCertData = serverKey.signCertificateRequest(
serverDN, clientCertReq, lambda dn: True, 7
)
clientCert = clientKey.newCertificate(clientCertData)
serverCertData = clientKey.signCertificateRequest(
clientDN, serverCertReq, lambda dn: True, 42
)
serverCert = serverKey.newCertificate(serverCertData)
onData = defer.Deferred()
serverOpts = serverCert.options(serverSelfCert)
clientOpts = clientCert.options(clientSelfCert)
self.loopback(serverOpts, clientOpts, onData=onData)
return onData.addCallback(
lambda result: self.assertEqual(result, WritingProtocol.byte)
)
class OpenSSLOptionsECDHIntegrationTests(OpenSSLOptionsTestsMixin, TestCase):
"""
ECDH-related integration tests for L{OpenSSLOptions}.
"""
def test_ellipticCurveDiffieHellman(self):
"""
Connections use ECDH when OpenSSL supports it.
"""
if not get_elliptic_curves():
raise SkipTest("OpenSSL does not support ECDH.")
onData = defer.Deferred()
# TLS 1.3 cipher suites do not specify the key exchange
# mechanism:
# https://wiki.openssl.org/index.php/TLS1.3#Differences_with_TLS1.2_and_below
#
# and OpenSSL only supports ECHDE groups with TLS 1.3:
# https://wiki.openssl.org/index.php/TLS1.3#Groups
#
# so TLS 1.3 implies ECDHE. Force this test to use TLS 1.3 to
# ensure ECDH is selected when it might not be.
self.loopback(
sslverify.OpenSSLCertificateOptions(
privateKey=self.sKey,
certificate=self.sCert,
requireCertificate=False,
lowerMaximumSecurityTo=sslverify.TLSVersion.TLSv1_3,
),
sslverify.OpenSSLCertificateOptions(
requireCertificate=False,
lowerMaximumSecurityTo=sslverify.TLSVersion.TLSv1_3,
),
onData=onData,
)
@onData.addCallback
def assertECDH(_):
self.assertEqual(len(self.clientConn.factory.protocols), 1)
[clientProtocol] = self.clientConn.factory.protocols
cipher = clientProtocol.getHandle().get_cipher_name()
self.assertIn("ECDH", cipher)
return onData
class DeprecationTests(SynchronousTestCase):
"""
Tests for deprecation of L{sslverify.OpenSSLCertificateOptions}'s support
of the pickle protocol.
"""
if skipSSL:
skip = skipSSL
def test_getstateDeprecation(self):
"""
L{sslverify.OpenSSLCertificateOptions.__getstate__} is deprecated.
"""
self.callDeprecated(
(Version("Twisted", 15, 0, 0), "a real persistence system"),
sslverify.OpenSSLCertificateOptions().__getstate__,
)
def test_setstateDeprecation(self):
"""
L{sslverify.OpenSSLCertificateOptions.__setstate__} is deprecated.
"""
self.callDeprecated(
(Version("Twisted", 15, 0, 0), "a real persistence system"),
sslverify.OpenSSLCertificateOptions().__setstate__,
{},
)
class TrustRootTests(TestCase):
"""
Tests for L{sslverify.OpenSSLCertificateOptions}' C{trustRoot} argument,
L{sslverify.platformTrust}, and their interactions.
"""
if skipSSL:
skip = skipSSL
def setUp(self):
"""
Patch L{sslverify._ChooseDiffieHellmanEllipticCurve}.
"""
self.patch(
sslverify,
"_ChooseDiffieHellmanEllipticCurve",
FakeChooseDiffieHellmanEllipticCurve,
)
def test_caCertsPlatformDefaults(self):
"""
Specifying a C{trustRoot} of L{sslverify.OpenSSLDefaultPaths} when
initializing L{sslverify.OpenSSLCertificateOptions} loads the
platform-provided trusted certificates via C{set_default_verify_paths}.
"""
opts = sslverify.OpenSSLCertificateOptions(
trustRoot=sslverify.OpenSSLDefaultPaths(),
)
fc = FakeContext(SSL.TLSv1_METHOD)
opts._contextFactory = lambda method: fc
opts.getContext()
self.assertTrue(fc._defaultVerifyPathsSet)
def test_trustRootPlatformRejectsUntrustedCA(self):
"""
Specifying a C{trustRoot} of L{platformTrust} when initializing
L{sslverify.OpenSSLCertificateOptions} causes certificates issued by a
newly created CA to be rejected by an SSL connection using these
options.
Note that this test should I{always} pass, even on platforms where the
CA certificates are not installed, as long as L{platformTrust} rejects
completely invalid / unknown root CA certificates. This is simply a
smoke test to make sure that verification is happening at all.
"""
caSelfCert, serverCert = certificatesForAuthorityAndServer()
chainedCert = pathContainingDumpOf(self, serverCert, caSelfCert)
privateKey = pathContainingDumpOf(self, serverCert.privateKey)
sProto, cProto, sWrapped, cWrapped, pump = loopbackTLSConnection(
trustRoot=platformTrust(),
privateKeyFile=privateKey,
chainedCertFile=chainedCert,
)
# No data was received.
self.assertEqual(cWrapped.data, b"")
# It was an L{SSL.Error}.
self.assertEqual(cWrapped.lostReason.type, SSL.Error)
# Some combination of OpenSSL and PyOpenSSL is bad at reporting errors.
err = cWrapped.lostReason.value
self.assertEqual(err.args[0][0][2], "tlsv1 alert unknown ca")
def test_trustRootSpecificCertificate(self):
"""
Specifying a L{Certificate} object for L{trustRoot} will result in that
certificate being the only trust root for a client.
"""
caCert, serverCert = certificatesForAuthorityAndServer()
otherCa, otherServer = certificatesForAuthorityAndServer()
sProto, cProto, sWrapped, cWrapped, pump = loopbackTLSConnection(
trustRoot=caCert,
privateKeyFile=pathContainingDumpOf(self, serverCert.privateKey),
chainedCertFile=pathContainingDumpOf(self, serverCert),
)
pump.flush()
self.assertIsNone(cWrapped.lostReason)
self.assertEqual(cWrapped.data, sWrapped.greeting)
class ServiceIdentityTests(SynchronousTestCase):
"""
Tests for the verification of the peer's service's identity via the
C{hostname} argument to L{sslverify.OpenSSLCertificateOptions}.
"""
if skipSSL:
skip = skipSSL
def serviceIdentitySetup(
self,
clientHostname,
serverHostname,
serverContextSetup=lambda ctx: None,
validCertificate=True,
clientPresentsCertificate=False,
validClientCertificate=True,
serverVerifies=False,
buggyInfoCallback=False,
fakePlatformTrust=False,
useDefaultTrust=False,
):
"""
Connect a server and a client.
@param clientHostname: The I{client's idea} of the server's hostname;
passed as the C{hostname} to the
L{sslverify.OpenSSLCertificateOptions} instance.
@type clientHostname: L{unicode}
@param serverHostname: The I{server's own idea} of the server's
hostname; present in the certificate presented by the server.
@type serverHostname: L{unicode}
@param serverContextSetup: a 1-argument callable invoked with the
L{OpenSSL.SSL.Context} after it's produced.
@type serverContextSetup: L{callable} taking L{OpenSSL.SSL.Context}
returning L{None}.
@param validCertificate: Is the server's certificate valid? L{True} if
so, L{False} otherwise.
@type validCertificate: L{bool}
@param clientPresentsCertificate: Should the client present a
certificate to the server? Defaults to 'no'.
@type clientPresentsCertificate: L{bool}
@param validClientCertificate: If the client presents a certificate,
should it actually be a valid one, i.e. signed by the same CA that
the server is checking? Defaults to 'yes'.
@type validClientCertificate: L{bool}
@param serverVerifies: Should the server verify the client's
certificate? Defaults to 'no'.
@type serverVerifies: L{bool}
@param buggyInfoCallback: Should we patch the implementation so that
the C{info_callback} passed to OpenSSL to have a bug and raise an
exception (L{ZeroDivisionError})? Defaults to 'no'.
@type buggyInfoCallback: L{bool}
@param fakePlatformTrust: Should we fake the platformTrust to be the
same as our fake server certificate authority, so that we can test
it's being used? Defaults to 'no' and we just pass platform trust.
@type fakePlatformTrust: L{bool}
@param useDefaultTrust: Should we avoid passing the C{trustRoot} to
L{ssl.optionsForClientTLS}? Defaults to 'no'.
@type useDefaultTrust: L{bool}
@return: the client TLS protocol, the client wrapped protocol,
the server TLS protocol, the server wrapped protocol and
an L{IOPump} which, when its C{pump} and C{flush} methods are
called, will move data between the created client and server
protocol instances
@rtype: 5-L{tuple} of 4 L{IProtocol}s and L{IOPump}
"""
serverCA, serverCert = certificatesForAuthorityAndServer(serverHostname)
other = {}
passClientCert = None
clientCA, clientCert = certificatesForAuthorityAndServer("client")
if serverVerifies:
other.update(trustRoot=clientCA)
if clientPresentsCertificate:
if validClientCertificate:
passClientCert = clientCert
else:
bogusCA, bogus = certificatesForAuthorityAndServer("client")
passClientCert = bogus
serverOpts = sslverify.OpenSSLCertificateOptions(
privateKey=serverCert.privateKey.original,
certificate=serverCert.original,
**other,
)
serverContextSetup(serverOpts.getContext())
if not validCertificate:
serverCA, otherServer = certificatesForAuthorityAndServer(serverHostname)
if buggyInfoCallback:
def broken(*a, **k):
"""
Raise an exception.
@param a: Arguments for an C{info_callback}
@param k: Keyword arguments for an C{info_callback}
"""
1 / 0
self.patch(
sslverify.ClientTLSOptions,
"_identityVerifyingInfoCallback",
broken,
)
signature = {"hostname": clientHostname}
if passClientCert:
signature.update(clientCertificate=passClientCert)
if not useDefaultTrust:
signature.update(trustRoot=serverCA)
if fakePlatformTrust:
self.patch(sslverify, "platformTrust", lambda: serverCA)
clientOpts = sslverify.optionsForClientTLS(**signature)
class GreetingServer(protocol.Protocol):
greeting = b"greetings!"
lostReason = None
data = b""
def connectionMade(self):
self.transport.write(self.greeting)
def dataReceived(self, data):
self.data += data
def connectionLost(self, reason):
self.lostReason = reason
class GreetingClient(protocol.Protocol):
greeting = b"cheerio!"
data = b""
lostReason = None
def connectionMade(self):
self.transport.write(self.greeting)
def dataReceived(self, data):
self.data += data
def connectionLost(self, reason):
self.lostReason = reason
serverWrappedProto = GreetingServer()
clientWrappedProto = GreetingClient()
clientFactory = protocol.Factory()
clientFactory.protocol = lambda: clientWrappedProto
serverFactory = protocol.Factory()
serverFactory.protocol = lambda: serverWrappedProto
self.serverOpts = serverOpts
self.clientOpts = clientOpts
clientTLSFactory = TLSMemoryBIOFactory(
clientOpts, isClient=True, wrappedFactory=clientFactory
)
serverTLSFactory = TLSMemoryBIOFactory(
serverOpts, isClient=False, wrappedFactory=serverFactory
)
cProto, sProto, pump = connectedServerAndClient(
lambda: serverTLSFactory.buildProtocol(None),
lambda: clientTLSFactory.buildProtocol(None),
)
return cProto, sProto, clientWrappedProto, serverWrappedProto, pump
def test_invalidHostname(self):
"""
When a certificate containing an invalid hostname is received from the
server, the connection is immediately dropped.
"""
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"wrong-host.example.com",
"correct-host.example.com",
)
self.assertEqual(cWrapped.data, b"")
self.assertEqual(sWrapped.data, b"")
cErr = cWrapped.lostReason.value
sErr = sWrapped.lostReason.value
self.assertIsInstance(cErr, VerificationError)
self.assertIsInstance(sErr, ConnectionClosed)
def test_validHostname(self):
"""
Whenever a valid certificate containing a valid hostname is received,
connection proceeds normally.
"""
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"valid.example.com",
"valid.example.com",
)
self.assertEqual(cWrapped.data, b"greetings!")
cErr = cWrapped.lostReason
sErr = sWrapped.lostReason
self.assertIsNone(cErr)
self.assertIsNone(sErr)
def test_validHostnameInvalidCertificate(self):
"""
When an invalid certificate containing a perfectly valid hostname is
received, the connection is aborted with an OpenSSL error.
"""
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"valid.example.com",
"valid.example.com",
validCertificate=False,
)
self.assertEqual(cWrapped.data, b"")
self.assertEqual(sWrapped.data, b"")
cErr = cWrapped.lostReason.value
sErr = sWrapped.lostReason.value
self.assertIsInstance(cErr, SSL.Error)
self.assertIsInstance(sErr, SSL.Error)
def test_realCAsBetterNotSignOurBogusTestCerts(self):
"""
If we use the default trust from the platform, our dinky certificate
should I{really} fail.
"""
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"valid.example.com",
"valid.example.com",
validCertificate=False,
useDefaultTrust=True,
)
self.assertEqual(cWrapped.data, b"")
self.assertEqual(sWrapped.data, b"")
cErr = cWrapped.lostReason.value
sErr = sWrapped.lostReason.value
self.assertIsInstance(cErr, SSL.Error)
self.assertIsInstance(sErr, SSL.Error)
def test_butIfTheyDidItWouldWork(self):
"""
L{ssl.optionsForClientTLS} should be using L{ssl.platformTrust} by
default, so if we fake that out then it should trust ourselves again.
"""
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"valid.example.com",
"valid.example.com",
useDefaultTrust=True,
fakePlatformTrust=True,
)
self.assertEqual(cWrapped.data, b"greetings!")
cErr = cWrapped.lostReason
sErr = sWrapped.lostReason
self.assertIsNone(cErr)
self.assertIsNone(sErr)
def test_clientPresentsCertificate(self):
"""
When the server verifies and the client presents a valid certificate
for that verification by passing it to
L{sslverify.optionsForClientTLS}, communication proceeds.
"""
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"valid.example.com",
"valid.example.com",
validCertificate=True,
serverVerifies=True,
clientPresentsCertificate=True,
)
self.assertEqual(cWrapped.data, b"greetings!")
cErr = cWrapped.lostReason
sErr = sWrapped.lostReason
self.assertIsNone(cErr)
self.assertIsNone(sErr)
def test_clientPresentsBadCertificate(self):
"""
When the server verifies and the client presents an invalid certificate
for that verification by passing it to
L{sslverify.optionsForClientTLS}, the connection cannot be established
with an SSL error.
"""
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"valid.example.com",
"valid.example.com",
validCertificate=True,
serverVerifies=True,
validClientCertificate=False,
clientPresentsCertificate=True,
)
self.assertEqual(cWrapped.data, b"")
cErr = cWrapped.lostReason.value
sErr = sWrapped.lostReason.value
self.assertIsInstance(cErr, SSL.Error)
self.assertIsInstance(sErr, SSL.Error)
@skipIf(skipSNI, skipSNI)
def test_hostnameIsIndicated(self):
"""
Specifying the C{hostname} argument to L{CertificateOptions} also sets
the U{Server Name Extension
<https://en.wikipedia.org/wiki/Server_Name_Indication>} TLS indication
field to the correct value.
"""
names = []
def setupServerContext(ctx):
def servername_received(conn):
names.append(conn.get_servername().decode("ascii"))
ctx.set_tlsext_servername_callback(servername_received)
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"valid.example.com", "valid.example.com", setupServerContext
)
self.assertEqual(names, ["valid.example.com"])
@skipIf(skipSNI, skipSNI)
def test_hostnameEncoding(self):
"""
Hostnames are encoded as IDNA.
"""
names = []
hello = "h\N{LATIN SMALL LETTER A WITH ACUTE}llo.example.com"
def setupServerContext(ctx):
def servername_received(conn):
serverIDNA = _idnaText(conn.get_servername())
names.append(serverIDNA)
ctx.set_tlsext_servername_callback(servername_received)
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
hello, hello, setupServerContext
)
self.assertEqual(names, [hello])
self.assertEqual(cWrapped.data, b"greetings!")
cErr = cWrapped.lostReason
sErr = sWrapped.lostReason
self.assertIsNone(cErr)
self.assertIsNone(sErr)
def test_fallback(self):
"""
L{sslverify.simpleVerifyHostname} checks string equality on the
commonName of a connection's certificate's subject, doing nothing if it
matches and raising L{VerificationError} if it doesn't.
"""
name = "something.example.com"
class Connection:
def get_peer_certificate(self):
"""
Fake of L{OpenSSL.SSL.Connection.get_peer_certificate}.
@return: A certificate with a known common name.
@rtype: L{OpenSSL.crypto.X509}
"""
cert = X509()
cert.get_subject().commonName = name
return cert
conn = Connection()
self.assertIs(
sslverify.simpleVerifyHostname(conn, "something.example.com"), None
)
self.assertRaises(
sslverify.SimpleVerificationError,
sslverify.simpleVerifyHostname,
conn,
"nonsense",
)
def test_surpriseFromInfoCallback(self):
"""
pyOpenSSL isn't always so great about reporting errors. If one occurs
in the verification info callback, it should be logged and the
connection should be shut down (if possible, anyway; the app_data could
be clobbered but there's no point testing for that).
"""
cProto, sProto, cWrapped, sWrapped, pump = self.serviceIdentitySetup(
"correct-host.example.com",
"correct-host.example.com",
buggyInfoCallback=True,
)
self.assertEqual(cWrapped.data, b"")
self.assertEqual(sWrapped.data, b"")
cErr = cWrapped.lostReason.value
sErr = sWrapped.lostReason.value
self.assertIsInstance(cErr, ZeroDivisionError)
self.assertIsInstance(sErr, (ConnectionClosed, SSL.Error))
errors = self.flushLoggedErrors(ZeroDivisionError)
self.assertTrue(errors)
def negotiateProtocol(serverProtocols, clientProtocols, clientOptions=None):
"""
Create the TLS connection and negotiate a next protocol.
@param serverProtocols: The protocols the server is willing to negotiate.
@param clientProtocols: The protocols the client is willing to negotiate.
@param clientOptions: The type of C{OpenSSLCertificateOptions} class to
use for the client. Defaults to C{OpenSSLCertificateOptions}.
@return: A L{tuple} of the negotiated protocol and the reason the
connection was lost.
"""
caCertificate, serverCertificate = certificatesForAuthorityAndServer()
trustRoot = sslverify.OpenSSLCertificateAuthorities(
[
caCertificate.original,
]
)
sProto, cProto, sWrapped, cWrapped, pump = loopbackTLSConnectionInMemory(
trustRoot=trustRoot,
privateKey=serverCertificate.privateKey.original,
serverCertificate=serverCertificate.original,
clientProtocols=clientProtocols,
serverProtocols=serverProtocols,
clientOptions=clientOptions,
)
pump.flush()
return (cProto.negotiatedProtocol, cWrapped.lostReason)
class NPNOrALPNTests(TestCase):
"""
NPN and ALPN protocol selection.
These tests only run on platforms that have a PyOpenSSL version >= 0.15,
and OpenSSL version 1.0.1 or later.
"""
if skipSSL:
skip = skipSSL
elif skipNPN:
skip = skipNPN
def test_nextProtocolMechanismsNPNIsSupported(self):
"""
When at least NPN is available on the platform, NPN is in the set of
supported negotiation protocols.
"""
supportedProtocols = sslverify.protocolNegotiationMechanisms()
self.assertTrue(sslverify.ProtocolNegotiationSupport.NPN in supportedProtocols)
def test_NPNAndALPNSuccess(self):
"""
When both ALPN and NPN are used, and both the client and server have
overlapping protocol choices, a protocol is successfully negotiated.
Further, the negotiated protocol is the first one in the list.
"""
protocols = [b"h2", b"http/1.1"]
negotiatedProtocol, lostReason = negotiateProtocol(
clientProtocols=protocols,
serverProtocols=protocols,
)
self.assertEqual(negotiatedProtocol, b"h2")
self.assertIsNone(lostReason)
def test_NPNAndALPNDifferent(self):
"""
Client and server have different protocol lists: only the common
element is chosen.
"""
serverProtocols = [b"h2", b"http/1.1", b"spdy/2"]
clientProtocols = [b"spdy/3", b"http/1.1"]
negotiatedProtocol, lostReason = negotiateProtocol(
clientProtocols=clientProtocols,
serverProtocols=serverProtocols,
)
self.assertEqual(negotiatedProtocol, b"http/1.1")
self.assertIsNone(lostReason)
def test_NPNAndALPNNoAdvertise(self):
"""
When one peer does not advertise any protocols, the connection is set
up with no next protocol.
"""
protocols = [b"h2", b"http/1.1"]
negotiatedProtocol, lostReason = negotiateProtocol(
clientProtocols=protocols,
serverProtocols=[],
)
self.assertIsNone(negotiatedProtocol)
self.assertIsNone(lostReason)
def test_NPNAndALPNNoOverlap(self):
"""
When the client and server have no overlap of protocols, the connection
fails.
"""
clientProtocols = [b"h2", b"http/1.1"]
serverProtocols = [b"spdy/3"]
negotiatedProtocol, lostReason = negotiateProtocol(
serverProtocols=clientProtocols,
clientProtocols=serverProtocols,
)
self.assertIsNone(negotiatedProtocol)
self.assertEqual(lostReason.type, SSL.Error)
class ALPNTests(TestCase):
"""
ALPN protocol selection.
These tests only run on platforms that have a PyOpenSSL version >= 0.15,
and OpenSSL version 1.0.2 or later.
This covers only the ALPN specific logic, as any platform that has ALPN
will also have NPN and so will run the NPNAndALPNTest suite as well.
"""
if skipSSL:
skip = skipSSL
elif skipALPN:
skip = skipALPN
def test_nextProtocolMechanismsALPNIsSupported(self):
"""
When ALPN is available on a platform, protocolNegotiationMechanisms
includes ALPN in the suported protocols.
"""
supportedProtocols = sslverify.protocolNegotiationMechanisms()
self.assertTrue(sslverify.ProtocolNegotiationSupport.ALPN in supportedProtocols)
class NPNAndALPNAbsentTests(TestCase):
"""
NPN/ALPN operations fail on platforms that do not support them.
These tests only run on platforms that have a PyOpenSSL version < 0.15,
an OpenSSL version earlier than 1.0.1, or an OpenSSL/cryptography built
without NPN support.
"""
if skipSSL:
skip = skipSSL
elif not skipNPN or not skipALPN:
skip = "NPN and/or ALPN is present on this platform"
def test_nextProtocolMechanismsNoNegotiationSupported(self):
"""
When neither NPN or ALPN are available on a platform, there are no
supported negotiation protocols.
"""
supportedProtocols = sslverify.protocolNegotiationMechanisms()
self.assertFalse(supportedProtocols)
def test_NPNAndALPNNotImplemented(self):
"""
A NotImplementedError is raised when using acceptableProtocols on a
platform that does not support either NPN or ALPN.
"""
protocols = [b"h2", b"http/1.1"]
self.assertRaises(
NotImplementedError,
negotiateProtocol,
serverProtocols=protocols,
clientProtocols=protocols,
)
def test_NegotiatedProtocolReturnsNone(self):
"""
negotiatedProtocol return L{None} even when NPN/ALPN aren't supported.
This works because, as neither are supported, negotiation isn't even
attempted.
"""
serverProtocols = None
clientProtocols = None
negotiatedProtocol, lostReason = negotiateProtocol(
clientProtocols=clientProtocols,
serverProtocols=serverProtocols,
)
self.assertIsNone(negotiatedProtocol)
self.assertIsNone(lostReason)
class _NotSSLTransport:
def getHandle(self):
return self
class _MaybeSSLTransport:
def getHandle(self):
return self
def get_peer_certificate(self):
return None
def get_host_certificate(self):
return None
class _ActualSSLTransport:
def getHandle(self):
return self
def get_host_certificate(self):
return sslverify.Certificate.loadPEM(A_HOST_CERTIFICATE_PEM).original
def get_peer_certificate(self):
return sslverify.Certificate.loadPEM(A_PEER_CERTIFICATE_PEM).original
class ConstructorsTests(TestCase):
if skipSSL:
skip = skipSSL
def test_peerFromNonSSLTransport(self):
"""
Verify that peerFromTransport raises an exception if the transport
passed is not actually an SSL transport.
"""
x = self.assertRaises(
CertificateError,
sslverify.Certificate.peerFromTransport,
_NotSSLTransport(),
)
self.assertTrue(str(x).startswith("non-TLS"))
def test_peerFromBlankSSLTransport(self):
"""
Verify that peerFromTransport raises an exception if the transport
passed is an SSL transport, but doesn't have a peer certificate.
"""
x = self.assertRaises(
CertificateError,
sslverify.Certificate.peerFromTransport,
_MaybeSSLTransport(),
)
self.assertTrue(str(x).startswith("TLS"))
def test_hostFromNonSSLTransport(self):
"""
Verify that hostFromTransport raises an exception if the transport
passed is not actually an SSL transport.
"""
x = self.assertRaises(
CertificateError,
sslverify.Certificate.hostFromTransport,
_NotSSLTransport(),
)
self.assertTrue(str(x).startswith("non-TLS"))
def test_hostFromBlankSSLTransport(self):
"""
Verify that hostFromTransport raises an exception if the transport
passed is an SSL transport, but doesn't have a host certificate.
"""
x = self.assertRaises(
CertificateError,
sslverify.Certificate.hostFromTransport,
_MaybeSSLTransport(),
)
self.assertTrue(str(x).startswith("TLS"))
def test_hostFromSSLTransport(self):
"""
Verify that hostFromTransport successfully creates the correct
certificate if passed a valid SSL transport.
"""
self.assertEqual(
sslverify.Certificate.hostFromTransport(
_ActualSSLTransport()
).serialNumber(),
12345,
)
def test_peerFromSSLTransport(self):
"""
Verify that peerFromTransport successfully creates the correct
certificate if passed a valid SSL transport.
"""
self.assertEqual(
sslverify.Certificate.peerFromTransport(
_ActualSSLTransport()
).serialNumber(),
12346,
)
class MultipleCertificateTrustRootTests(TestCase):
"""
Test the behavior of the trustRootFromCertificates() API call.
"""
if skipSSL:
skip = skipSSL
def test_trustRootFromCertificatesPrivatePublic(self):
"""
L{trustRootFromCertificates} accepts either a L{sslverify.Certificate}
or a L{sslverify.PrivateCertificate} instance.
"""
privateCert = sslverify.PrivateCertificate.loadPEM(A_KEYPAIR)
cert = sslverify.Certificate.loadPEM(A_HOST_CERTIFICATE_PEM)
mt = sslverify.trustRootFromCertificates([privateCert, cert])
# Verify that the returned object acts correctly when used as a
# trustRoot= param to optionsForClientTLS.
sProto, cProto, sWrap, cWrap, pump = loopbackTLSConnectionInMemory(
trustRoot=mt,
privateKey=privateCert.privateKey.original,
serverCertificate=privateCert.original,
)
# This connection should succeed
self.assertEqual(cWrap.data, b"greetings!")
self.assertIsNone(cWrap.lostReason)
def test_trustRootSelfSignedServerCertificate(self):
"""
L{trustRootFromCertificates} called with a single self-signed
certificate will cause L{optionsForClientTLS} to accept client
connections to a server with that certificate.
"""
key, cert = makeCertificate(O=b"Server Test Certificate", CN=b"server")
selfSigned = sslverify.PrivateCertificate.fromCertificateAndKeyPair(
sslverify.Certificate(cert),
sslverify.KeyPair(key),
)
trust = sslverify.trustRootFromCertificates([selfSigned])
# Since we trust this exact certificate, connections to this server
# should succeed.
sProto, cProto, sWrap, cWrap, pump = loopbackTLSConnectionInMemory(
trustRoot=trust,
privateKey=selfSigned.privateKey.original,
serverCertificate=selfSigned.original,
)
self.assertEqual(cWrap.data, b"greetings!")
self.assertIsNone(cWrap.lostReason)
def test_trustRootCertificateAuthorityTrustsConnection(self):
"""
L{trustRootFromCertificates} called with certificate A will cause
L{optionsForClientTLS} to accept client connections to a server with
certificate B where B is signed by A.
"""
caCert, serverCert = certificatesForAuthorityAndServer()
trust = sslverify.trustRootFromCertificates([caCert])
# Since we've listed the CA's certificate as a trusted cert, a
# connection to the server certificate it signed should succeed.
sProto, cProto, sWrap, cWrap, pump = loopbackTLSConnectionInMemory(
trustRoot=trust,
privateKey=serverCert.privateKey.original,
serverCertificate=serverCert.original,
)
self.assertEqual(cWrap.data, b"greetings!")
self.assertIsNone(cWrap.lostReason)
def test_trustRootFromCertificatesUntrusted(self):
"""
L{trustRootFromCertificates} called with certificate A will cause
L{optionsForClientTLS} to disallow any connections to a server with
certificate B where B is not signed by A.
"""
key, cert = makeCertificate(O=b"Server Test Certificate", CN=b"server")
serverCert = sslverify.PrivateCertificate.fromCertificateAndKeyPair(
sslverify.Certificate(cert),
sslverify.KeyPair(key),
)
untrustedCert = sslverify.Certificate(
makeCertificate(O=b"CA Test Certificate", CN=b"unknown CA")[1]
)
trust = sslverify.trustRootFromCertificates([untrustedCert])
# Since we only trust 'untrustedCert' which has not signed our
# server's cert, we should reject this connection
sProto, cProto, sWrap, cWrap, pump = loopbackTLSConnectionInMemory(
trustRoot=trust,
privateKey=serverCert.privateKey.original,
serverCertificate=serverCert.original,
)
# This connection should fail, so no data was received.
self.assertEqual(cWrap.data, b"")
# It was an L{SSL.Error}.
self.assertEqual(cWrap.lostReason.type, SSL.Error)
# Some combination of OpenSSL and PyOpenSSL is bad at reporting errors.
err = cWrap.lostReason.value
self.assertEqual(err.args[0][0][2], "tlsv1 alert unknown ca")
def test_trustRootFromCertificatesOpenSSLObjects(self):
"""
L{trustRootFromCertificates} rejects any L{OpenSSL.crypto.X509}
instances in the list passed to it.
"""
private = sslverify.PrivateCertificate.loadPEM(A_KEYPAIR)
certX509 = private.original
exception = self.assertRaises(
TypeError,
sslverify.trustRootFromCertificates,
[certX509],
)
self.assertEqual(
"certificates items must be twisted.internet.ssl.CertBase " "instances",
exception.args[0],
)
class OpenSSLCipherTests(TestCase):
"""
Tests for twisted.internet._sslverify.OpenSSLCipher.
"""
if skipSSL:
skip = skipSSL
cipherName = "CIPHER-STRING"
def test_constructorSetsFullName(self):
"""
The first argument passed to the constructor becomes the full name.
"""
self.assertEqual(
self.cipherName, sslverify.OpenSSLCipher(self.cipherName).fullName
)
def test_repr(self):
"""
C{repr(cipher)} returns a valid constructor call.
"""
cipher = sslverify.OpenSSLCipher(self.cipherName)
self.assertEqual(
cipher, eval(repr(cipher), {"OpenSSLCipher": sslverify.OpenSSLCipher})
)
def test_eqSameClass(self):
"""
Equal type and C{fullName} means that the objects are equal.
"""
cipher1 = sslverify.OpenSSLCipher(self.cipherName)
cipher2 = sslverify.OpenSSLCipher(self.cipherName)
self.assertEqual(cipher1, cipher2)
def test_eqSameNameDifferentType(self):
"""
If ciphers have the same name but different types, they're still
different.
"""
class DifferentCipher:
fullName = self.cipherName
self.assertNotEqual(
sslverify.OpenSSLCipher(self.cipherName),
DifferentCipher(),
)
class ExpandCipherStringTests(TestCase):
"""
Tests for twisted.internet._sslverify._expandCipherString.
"""
if skipSSL:
skip = skipSSL
def _test_doesNotStumbleOverEmptyList(self):
"""
If the expanded cipher list is empty, an empty L{list} is returned.
"""
self.assertEqual(
tuple(), sslverify._expandCipherString("", SSL.SSLv23_METHOD, 0)
)
def test_doesNotSwallowOtherSSLErrors(self):
"""
Only no cipher matches get swallowed, every other SSL error gets
propagated.
"""
def raiser(_):
# Unfortunately, there seems to be no way to trigger a real SSL
# error artificially.
raise SSL.Error([["", "", ""]])
ctx = FakeContext(SSL.SSLv23_METHOD)
ctx.set_cipher_list = raiser
self.patch(sslverify.SSL, "Context", lambda _: ctx)
self.assertRaises(
SSL.Error, sslverify._expandCipherString, "ALL", SSL.SSLv23_METHOD, 0
)
def test_returnsTupleOfICiphers(self):
"""
L{sslverify._expandCipherString} always returns a L{tuple} of
L{interfaces.ICipher}.
"""
ciphers = sslverify._expandCipherString("ALL", SSL.SSLv23_METHOD, 0)
self.assertIsInstance(ciphers, tuple)
bogus = []
for c in ciphers:
if not interfaces.ICipher.providedBy(c):
bogus.append(c)
self.assertEqual([], bogus)
class AcceptableCiphersTests(TestCase):
"""
Tests for twisted.internet._sslverify.OpenSSLAcceptableCiphers.
"""
if skipSSL:
skip = skipSSL
def test_selectOnEmptyListReturnsEmptyList(self):
"""
If no ciphers are available, nothing can be selected.
"""
ac = sslverify.OpenSSLAcceptableCiphers(tuple())
self.assertEqual(tuple(), ac.selectCiphers(tuple()))
def test_selectReturnsOnlyFromAvailable(self):
"""
Select only returns a cross section of what is available and what is
desirable.
"""
ac = sslverify.OpenSSLAcceptableCiphers(
[
sslverify.OpenSSLCipher("A"),
sslverify.OpenSSLCipher("B"),
]
)
self.assertEqual(
(sslverify.OpenSSLCipher("B"),),
ac.selectCiphers(
[sslverify.OpenSSLCipher("B"), sslverify.OpenSSLCipher("C")]
),
)
def test_fromOpenSSLCipherStringExpandsToTupleOfCiphers(self):
"""
If L{sslverify.OpenSSLAcceptableCiphers.fromOpenSSLCipherString} is
called it expands the string to a tuple of ciphers.
"""
ac = sslverify.OpenSSLAcceptableCiphers.fromOpenSSLCipherString("ALL")
self.assertIsInstance(ac._ciphers, tuple)
self.assertTrue(all(sslverify.ICipher.providedBy(c) for c in ac._ciphers))
class DiffieHellmanParametersTests(TestCase):
"""
Tests for twisted.internet._sslverify.OpenSSLDHParameters.
"""
if skipSSL:
skip = skipSSL
filePath = FilePath(b"dh.params")
def test_fromFile(self):
"""
Calling C{fromFile} with a filename returns an instance with that file
name saved.
"""
params = sslverify.OpenSSLDiffieHellmanParameters.fromFile(self.filePath)
self.assertEqual(self.filePath, params._dhFile)
class FakeLibState:
"""
State for L{FakeLib}
@param setECDHAutoRaises: An exception
L{FakeLib.SSL_CTX_set_ecdh_auto} should raise; if L{None},
nothing is raised.
@ivar ecdhContexts: A list of SSL contexts with which
L{FakeLib.SSL_CTX_set_ecdh_auto} was called
@type ecdhContexts: L{list} of L{OpenSSL.SSL.Context}s
@ivar ecdhValues: A list of boolean values with which
L{FakeLib.SSL_CTX_set_ecdh_auto} was called
@type ecdhValues: L{list} of L{boolean}s
"""
__slots__ = ("setECDHAutoRaises", "ecdhContexts", "ecdhValues")
def __init__(self, setECDHAutoRaises):
self.setECDHAutoRaises = setECDHAutoRaises
self.ecdhContexts = []
self.ecdhValues = []
class FakeLib:
"""
An introspectable fake of cryptography's lib object.
@param state: A L{FakeLibState} instance that contains this fake's
state.
"""
def __init__(self, state):
self._state = state
def SSL_CTX_set_ecdh_auto(self, ctx, value):
"""
Record the context and value under in the C{_state} instance
variable.
@see: L{FakeLibState}
@param ctx: An SSL context.
@type ctx: L{OpenSSL.SSL.Context}
@param value: A boolean value
@type value: L{bool}
"""
self._state.ecdhContexts.append(ctx)
self._state.ecdhValues.append(value)
if self._state.setECDHAutoRaises is not None:
raise self._state.setECDHAutoRaises
class FakeLibTests(TestCase):
"""
Tests for L{FakeLib}.
"""
def test_SSL_CTX_set_ecdh_auto(self):
"""
L{FakeLib.SSL_CTX_set_ecdh_auto} records context and value it
was called with.
"""
state = FakeLibState(setECDHAutoRaises=None)
lib = FakeLib(state)
self.assertNot(state.ecdhContexts)
self.assertNot(state.ecdhValues)
context, value = "CONTEXT", True
lib.SSL_CTX_set_ecdh_auto(context, value)
self.assertEqual(state.ecdhContexts, [context])
self.assertEqual(state.ecdhValues, [True])
def test_SSL_CTX_set_ecdh_autoRaises(self):
"""
L{FakeLib.SSL_CTX_set_ecdh_auto} raises the exception provided
by its state, while still recording its arguments.
"""
state = FakeLibState(setECDHAutoRaises=ValueError)
lib = FakeLib(state)
self.assertNot(state.ecdhContexts)
self.assertNot(state.ecdhValues)
context, value = "CONTEXT", True
self.assertRaises(ValueError, lib.SSL_CTX_set_ecdh_auto, context, value)
self.assertEqual(state.ecdhContexts, [context])
self.assertEqual(state.ecdhValues, [True])
class FakeCryptoState:
"""
State for L{FakeCrypto}
@param getEllipticCurveRaises: What
L{FakeCrypto.get_elliptic_curve} should raise; L{None} and it
won't raise anything
@param getEllipticCurveReturns: What
L{FakeCrypto.get_elliptic_curve} should return.
@ivar getEllipticCurveCalls: The arguments with which
L{FakeCrypto.get_elliptic_curve} has been called.
@type getEllipticCurveCalls: L{list}
"""
__slots__ = (
"getEllipticCurveRaises",
"getEllipticCurveReturns",
"getEllipticCurveCalls",
)
def __init__(
self,
getEllipticCurveRaises,
getEllipticCurveReturns,
):
self.getEllipticCurveRaises = getEllipticCurveRaises
self.getEllipticCurveReturns = getEllipticCurveReturns
self.getEllipticCurveCalls = []
class FakeCrypto:
"""
An introspectable fake of pyOpenSSL's L{OpenSSL.crypto} module.
@ivar state: A L{FakeCryptoState} instance
"""
def __init__(self, state):
self._state = state
def get_elliptic_curve(self, curve):
"""
A fake that records the curve with which it was called.
@param curve: see L{crypto.get_elliptic_curve}
@return: see L{FakeCryptoState.getEllipticCurveReturns}
@raises: see L{FakeCryptoState.getEllipticCurveRaises}
"""
self._state.getEllipticCurveCalls.append(curve)
if self._state.getEllipticCurveRaises is not None:
raise self._state.getEllipticCurveRaises
return self._state.getEllipticCurveReturns
class FakeCryptoTests(SynchronousTestCase):
"""
Tests for L{FakeCrypto}.
"""
def test_get_elliptic_curveRecordsArgument(self):
"""
L{FakeCrypto.test_get_elliptic_curve} records the curve with
which it was called.
"""
state = FakeCryptoState(
getEllipticCurveRaises=None,
getEllipticCurveReturns=None,
)
crypto = FakeCrypto(state)
crypto.get_elliptic_curve("a curve name")
self.assertEqual(state.getEllipticCurveCalls, ["a curve name"])
def test_get_elliptic_curveReturns(self):
"""
L{FakeCrypto.test_get_elliptic_curve} returns the value
specified by its state object and records what it was called
with.
"""
returnValue = "object"
state = FakeCryptoState(
getEllipticCurveRaises=None,
getEllipticCurveReturns=returnValue,
)
crypto = FakeCrypto(state)
self.assertIs(
crypto.get_elliptic_curve("another curve name"),
returnValue,
)
self.assertEqual(state.getEllipticCurveCalls, ["another curve name"])
def test_get_elliptic_curveRaises(self):
"""
L{FakeCrypto.test_get_elliptic_curve} raises the exception
specified by its state object.
"""
state = FakeCryptoState(
getEllipticCurveRaises=ValueError, getEllipticCurveReturns=None
)
crypto = FakeCrypto(state)
self.assertRaises(
ValueError,
crypto.get_elliptic_curve,
"yet another curve name",
)
self.assertEqual(
state.getEllipticCurveCalls,
["yet another curve name"],
)
class ChooseDiffieHellmanEllipticCurveTests(SynchronousTestCase):
"""
Tests for L{sslverify._ChooseDiffieHellmanEllipticCurve}.
@cvar OPENSSL_110: A version number for OpenSSL 1.1.0
@cvar OPENSSL_102: A version number for OpenSSL 1.0.2
@cvar OPENSSL_101: A version number for OpenSSL 1.0.1
@see:
U{https://wiki.openssl.org/index.php/Manual:OPENSSL_VERSION_NUMBER(3)}
"""
if skipSSL:
skip = skipSSL
OPENSSL_110 = 0x1010007F
OPENSSL_102 = 0x100020EF
OPENSSL_101 = 0x1000114F
def setUp(self):
self.libState = FakeLibState(setECDHAutoRaises=False)
self.lib = FakeLib(self.libState)
self.cryptoState = FakeCryptoState(
getEllipticCurveReturns=None, getEllipticCurveRaises=None
)
self.crypto = FakeCrypto(self.cryptoState)
self.context = FakeContext(SSL.SSLv23_METHOD)
def test_openSSL110(self):
"""
No configuration of contexts occurs under OpenSSL 1.1.0 and
later, because they create contexts with secure ECDH curves.
@see: U{http://twistedmatrix.com/trac/ticket/9210}
"""
chooser = sslverify._ChooseDiffieHellmanEllipticCurve(
self.OPENSSL_110,
openSSLlib=self.lib,
openSSLcrypto=self.crypto,
)
chooser.configureECDHCurve(self.context)
self.assertFalse(self.libState.ecdhContexts)
self.assertFalse(self.libState.ecdhValues)
self.assertFalse(self.cryptoState.getEllipticCurveCalls)
self.assertIsNone(self.context._ecCurve)
def test_openSSL102(self):
"""
OpenSSL 1.0.2 does not set ECDH curves by default, but
C{SSL_CTX_set_ecdh_auto} requests that a context choose a
secure set curves automatically.
"""
context = SSL.Context(SSL.SSLv23_METHOD)
chooser = sslverify._ChooseDiffieHellmanEllipticCurve(
self.OPENSSL_102,
openSSLlib=self.lib,
openSSLcrypto=self.crypto,
)
chooser.configureECDHCurve(context)
self.assertEqual(self.libState.ecdhContexts, [context._context])
self.assertEqual(self.libState.ecdhValues, [True])
self.assertFalse(self.cryptoState.getEllipticCurveCalls)
self.assertIsNone(self.context._ecCurve)
def test_openSSL102SetECDHAutoRaises(self):
"""
An exception raised by C{SSL_CTX_set_ecdh_auto} under OpenSSL
1.0.2 is suppressed because ECDH is best-effort.
"""
self.libState.setECDHAutoRaises = BaseException
context = SSL.Context(SSL.SSLv23_METHOD)
chooser = sslverify._ChooseDiffieHellmanEllipticCurve(
self.OPENSSL_102,
openSSLlib=self.lib,
openSSLcrypto=self.crypto,
)
chooser.configureECDHCurve(context)
self.assertEqual(self.libState.ecdhContexts, [context._context])
self.assertEqual(self.libState.ecdhValues, [True])
self.assertFalse(self.cryptoState.getEllipticCurveCalls)
def test_openSSL101(self):
"""
OpenSSL 1.0.1 does not set ECDH curves by default, nor does
it expose L{SSL_CTX_set_ecdh_auto}. Instead, a single ECDH
curve can be set with L{OpenSSL.SSL.Context.set_tmp_ecdh}.
"""
self.cryptoState.getEllipticCurveReturns = curve = "curve object"
chooser = sslverify._ChooseDiffieHellmanEllipticCurve(
self.OPENSSL_101,
openSSLlib=self.lib,
openSSLcrypto=self.crypto,
)
chooser.configureECDHCurve(self.context)
self.assertFalse(self.libState.ecdhContexts)
self.assertFalse(self.libState.ecdhValues)
self.assertEqual(
self.cryptoState.getEllipticCurveCalls,
[sslverify._defaultCurveName],
)
self.assertIs(self.context._ecCurve, curve)
def test_openSSL101SetECDHRaises(self):
"""
An exception raised by L{OpenSSL.SSL.Context.set_tmp_ecdh}
under OpenSSL 1.0.1 is suppressed because ECHDE is best-effort.
"""
def set_tmp_ecdh(ctx):
raise BaseException
self.context.set_tmp_ecdh = set_tmp_ecdh
chooser = sslverify._ChooseDiffieHellmanEllipticCurve(
self.OPENSSL_101,
openSSLlib=self.lib,
openSSLcrypto=self.crypto,
)
chooser.configureECDHCurve(self.context)
self.assertFalse(self.libState.ecdhContexts)
self.assertFalse(self.libState.ecdhValues)
self.assertEqual(
self.cryptoState.getEllipticCurveCalls,
[sslverify._defaultCurveName],
)
def test_openSSL101NoECC(self):
"""
Contexts created under an OpenSSL 1.0.1 that doesn't support
ECC have no configuration applied.
"""
self.cryptoState.getEllipticCurveRaises = ValueError
chooser = sslverify._ChooseDiffieHellmanEllipticCurve(
self.OPENSSL_101,
openSSLlib=self.lib,
openSSLcrypto=self.crypto,
)
chooser.configureECDHCurve(self.context)
self.assertFalse(self.libState.ecdhContexts)
self.assertFalse(self.libState.ecdhValues)
self.assertIsNone(self.context._ecCurve)
class KeyPairTests(TestCase):
"""
Tests for L{sslverify.KeyPair}.
"""
if skipSSL:
skip = skipSSL
def setUp(self):
"""
Create test certificate.
"""
self.sKey = makeCertificate(O=b"Server Test Certificate", CN=b"server")[0]
def test_getstateDeprecation(self):
"""
L{sslverify.KeyPair.__getstate__} is deprecated.
"""
self.callDeprecated(
(Version("Twisted", 15, 0, 0), "a real persistence system"),
sslverify.KeyPair(self.sKey).__getstate__,
)
def test_setstateDeprecation(self):
"""
{sslverify.KeyPair.__setstate__} is deprecated.
"""
state = sslverify.KeyPair(self.sKey).dump()
self.callDeprecated(
(Version("Twisted", 15, 0, 0), "a real persistence system"),
sslverify.KeyPair(self.sKey).__setstate__,
state,
)
def test_noTrailingNewlinePemCert(self):
noTrailingNewlineKeyPemPath = getModule("twisted.test").filePath.sibling(
"cert.pem.no_trailing_newline"
)
certPEM = noTrailingNewlineKeyPemPath.getContent()
ssl.Certificate.loadPEM(certPEM)
class SelectVerifyImplementationTests(SynchronousTestCase):
"""
Tests for L{_selectVerifyImplementation}.
"""
if skipSSL:
skip = skipSSL
def test_dependencyMissing(self):
"""
If I{service_identity} cannot be imported then
L{_selectVerifyImplementation} returns L{simpleVerifyHostname} and
L{SimpleVerificationError}.
"""
with SetAsideModule("service_identity"):
sys.modules["service_identity"] = None
result = sslverify._selectVerifyImplementation()
expected = (
sslverify.simpleVerifyHostname,
sslverify.simpleVerifyIPAddress,
sslverify.SimpleVerificationError,
)
self.assertEqual(expected, result)
test_dependencyMissing.suppress = [ # type: ignore[attr-defined]
util.suppress(
message=(
"You do not have a working installation of the "
"service_identity module"
),
),
]
def test_dependencyMissingWarning(self):
"""
If I{service_identity} cannot be imported then
L{_selectVerifyImplementation} emits a L{UserWarning} advising the user
of the exact error.
"""
with SetAsideModule("service_identity"):
sys.modules["service_identity"] = None
sslverify._selectVerifyImplementation()
[warning] = list(
warning
for warning in self.flushWarnings()
if warning["category"] == UserWarning
)
importErrors = [
# Python 3.6.3
"'import of service_identity halted; None in sys.modules'",
# Python 3
"'import of 'service_identity' halted; None in sys.modules'",
# Python 2
"'No module named service_identity'",
]
expectedMessages = []
for importError in importErrors:
expectedMessages.append(
"You do not have a working installation of the "
"service_identity module: {message}. Please install it from "
"<https://pypi.python.org/pypi/service_identity> "
"and make sure all of its dependencies are satisfied. "
"Without the service_identity module, Twisted can perform only"
" rudimentary TLS client hostname verification. Many valid "
"certificate/hostname mappings may be rejected.".format(
message=importError
)
)
self.assertIn(warning["message"], expectedMessages)
# Make sure we're abusing the warning system to a sufficient
# degree: there is no filename or line number that makes sense for
# this warning to "blame" for the problem. It is a system
# misconfiguration. So the location information should be blank
# (or as blank as we can make it).
self.assertEqual(warning["filename"], "")
self.assertEqual(warning["lineno"], 0)
|