D7net Mini Sh3LL v1
| Current File : //lib/python3/dist-packages/__pycache__/../twisted/internet/_sslverify.py |
# -*- test-case-name: twisted.test.test_sslverify -*-
# Copyright (c) 2005 Divmod, Inc.
# Copyright (c) Twisted Matrix Laboratories.
# See LICENSE for details.
from __future__ import division, absolute_import
import itertools
import warnings
from constantly import Names, NamedConstant
from hashlib import md5
from OpenSSL import SSL, crypto
from OpenSSL._util import lib as pyOpenSSLlib
from twisted.internet.abstract import isIPAddress, isIPv6Address
from twisted.python import log
from twisted.python._oldstyle import _oldStyle
from ._idna import _idnaBytes
class TLSVersion(Names):
"""
TLS versions that we can negotiate with the client/server.
"""
SSLv3 = NamedConstant()
TLSv1_0 = NamedConstant()
TLSv1_1 = NamedConstant()
TLSv1_2 = NamedConstant()
TLSv1_3 = NamedConstant()
_tlsDisableFlags = {
TLSVersion.SSLv3: SSL.OP_NO_SSLv3,
TLSVersion.TLSv1_0: SSL.OP_NO_TLSv1,
TLSVersion.TLSv1_1: SSL.OP_NO_TLSv1_1,
TLSVersion.TLSv1_2: SSL.OP_NO_TLSv1_2,
# If we don't have TLS v1.3 yet, we can't disable it -- this is just so
# when it makes it into OpenSSL, connections knowingly bracketed to v1.2
# don't end up going to v1.3
TLSVersion.TLSv1_3: getattr(SSL, "OP_NO_TLSv1_3", 0x00),
}
def _getExcludedTLSProtocols(oldest, newest):
"""
Given a pair of L{TLSVersion} constants, figure out what versions we want
to disable (as OpenSSL is an exclusion based API).
@param oldest: The oldest L{TLSVersion} we want to allow.
@type oldest: L{TLSVersion} constant
@param newest: The newest L{TLSVersion} we want to allow, or L{None} for no
upper limit.
@type newest: L{TLSVersion} constant or L{None}
@return: The versions we want to disable.
@rtype: L{list} of L{TLSVersion} constants.
"""
versions = list(TLSVersion.iterconstants())
excludedVersions = [x for x in versions[:versions.index(oldest)]]
if newest:
excludedVersions.extend([x for x in versions[versions.index(newest):]])
return excludedVersions
class SimpleVerificationError(Exception):
"""
Not a very useful verification error.
"""
def simpleVerifyHostname(connection, hostname):
"""
Check only the common name in the certificate presented by the peer and
only for an exact match.
This is to provide I{something} in the way of hostname verification to
users who haven't installed C{service_identity}. This check is overly
strict, relies on a deprecated TLS feature (you're supposed to ignore the
commonName if the subjectAlternativeName extensions are present, I
believe), and lots of valid certificates will fail.
@param connection: the OpenSSL connection to verify.
@type connection: L{OpenSSL.SSL.Connection}
@param hostname: The hostname expected by the user.
@type hostname: L{unicode}
@raise twisted.internet.ssl.VerificationError: if the common name and
hostname don't match.
"""
commonName = connection.get_peer_certificate().get_subject().commonName
if commonName != hostname:
raise SimpleVerificationError(repr(commonName) + "!=" +
repr(hostname))
def _usablePyOpenSSL(version):
"""
Check pyOpenSSL version string whether we can use it for host verification.
@param version: A pyOpenSSL version string.
@type version: L{str}
@rtype: L{bool}
"""
major, minor = (int(part) for part in version.split(".")[:2])
return (major, minor) >= (0, 12)
def _selectVerifyImplementation():
"""
Determine if C{service_identity} is installed. If so, use it. If not, use
simplistic and incorrect checking as implemented in
L{simpleVerifyHostname}.
@return: 2-tuple of (C{verify_hostname}, C{VerificationError})
@rtype: L{tuple}
"""
whatsWrong = (
"Without the service_identity module, Twisted can perform only "
"rudimentary TLS client hostname verification. Many valid "
"certificate/hostname mappings may be rejected."
)
try:
from service_identity import VerificationError
from service_identity.pyopenssl import verify_hostname
return verify_hostname, VerificationError
except ImportError as e:
warnings.warn_explicit(
"You do not have a working installation of the "
"service_identity module: '" + str(e) + "'. "
"Please install it from "
"<https://pypi.python.org/pypi/service_identity> and make "
"sure all of its dependencies are satisfied. "
+ whatsWrong,
# Unfortunately the lineno is required.
category=UserWarning, filename="", lineno=0)
return simpleVerifyHostname, SimpleVerificationError
verifyHostname, VerificationError = _selectVerifyImplementation()
from zope.interface import Interface, implementer
from constantly import Flags, FlagConstant
from incremental import Version
from twisted.internet.defer import Deferred
from twisted.internet.error import VerifyError, CertificateError
from twisted.internet.interfaces import (
IAcceptableCiphers, ICipher, IOpenSSLClientConnectionCreator,
IOpenSSLContextFactory
)
from twisted.python import reflect, util
from twisted.python.deprecate import _mutuallyExclusiveArguments
from twisted.python.compat import nativeString, networkString, unicode
from twisted.python.failure import Failure
from twisted.python.util import FancyEqMixin
from twisted.python.deprecate import deprecated
def _sessionCounter(counter=itertools.count()):
"""
Private - shared between all OpenSSLCertificateOptions, counts up to
provide a unique session id for each context.
"""
return next(counter)
class ProtocolNegotiationSupport(Flags):
"""
L{ProtocolNegotiationSupport} defines flags which are used to indicate the
level of NPN/ALPN support provided by the TLS backend.
@cvar NOSUPPORT: There is no support for NPN or ALPN. This is exclusive
with both L{NPN} and L{ALPN}.
@cvar NPN: The implementation supports Next Protocol Negotiation.
@cvar ALPN: The implementation supports Application Layer Protocol
Negotiation.
"""
NPN = FlagConstant(0x0001)
ALPN = FlagConstant(0x0002)
# FIXME: https://twistedmatrix.com/trac/ticket/8074
# Currently flags with literal zero values behave incorrectly. However,
# creating a flag by NOTing a flag with itself appears to work totally fine, so
# do that instead.
ProtocolNegotiationSupport.NOSUPPORT = (
ProtocolNegotiationSupport.NPN ^ ProtocolNegotiationSupport.NPN
)
def protocolNegotiationMechanisms():
"""
Checks whether your versions of PyOpenSSL and OpenSSL are recent enough to
support protocol negotiation, and if they are, what kind of protocol
negotiation is supported.
@return: A combination of flags from L{ProtocolNegotiationSupport} that
indicate which mechanisms for protocol negotiation are supported.
@rtype: L{constantly.FlagConstant}
"""
support = ProtocolNegotiationSupport.NOSUPPORT
ctx = SSL.Context(SSL.SSLv23_METHOD)
try:
ctx.set_npn_advertise_callback(lambda c: None)
except (AttributeError, NotImplementedError):
pass
else:
support |= ProtocolNegotiationSupport.NPN
try:
ctx.set_alpn_select_callback(lambda c: None)
except (AttributeError, NotImplementedError):
pass
else:
support |= ProtocolNegotiationSupport.ALPN
return support
_x509names = {
'CN': 'commonName',
'commonName': 'commonName',
'O': 'organizationName',
'organizationName': 'organizationName',
'OU': 'organizationalUnitName',
'organizationalUnitName': 'organizationalUnitName',
'L': 'localityName',
'localityName': 'localityName',
'ST': 'stateOrProvinceName',
'stateOrProvinceName': 'stateOrProvinceName',
'C': 'countryName',
'countryName': 'countryName',
'emailAddress': 'emailAddress'}
class DistinguishedName(dict):
"""
Identify and describe an entity.
Distinguished names are used to provide a minimal amount of identifying
information about a certificate issuer or subject. They are commonly
created with one or more of the following fields::
commonName (CN)
organizationName (O)
organizationalUnitName (OU)
localityName (L)
stateOrProvinceName (ST)
countryName (C)
emailAddress
A L{DistinguishedName} should be constructed using keyword arguments whose
keys can be any of the field names above (as a native string), and the
values are either Unicode text which is encodable to ASCII, or L{bytes}
limited to the ASCII subset. Any fields passed to the constructor will be
set as attributes, accessible using both their extended name and their
shortened acronym. The attribute values will be the ASCII-encoded
bytes. For example::
>>> dn = DistinguishedName(commonName=b'www.example.com',
... C='US')
>>> dn.C
b'US'
>>> dn.countryName
b'US'
>>> hasattr(dn, "organizationName")
False
L{DistinguishedName} instances can also be used as dictionaries; the keys
are extended name of the fields::
>>> dn.keys()
['countryName', 'commonName']
>>> dn['countryName']
b'US'
"""
__slots__ = ()
def __init__(self, **kw):
for k, v in kw.items():
setattr(self, k, v)
def _copyFrom(self, x509name):
for name in _x509names:
value = getattr(x509name, name, None)
if value is not None:
setattr(self, name, value)
def _copyInto(self, x509name):
for k, v in self.items():
setattr(x509name, k, nativeString(v))
def __repr__(self):
return '<DN %s>' % (dict.__repr__(self)[1:-1])
def __getattr__(self, attr):
try:
return self[_x509names[attr]]
except KeyError:
raise AttributeError(attr)
def __setattr__(self, attr, value):
if attr not in _x509names:
raise AttributeError("%s is not a valid OpenSSL X509 name field" % (attr,))
realAttr = _x509names[attr]
if not isinstance(value, bytes):
value = value.encode("ascii")
self[realAttr] = value
def inspect(self):
"""
Return a multi-line, human-readable representation of this DN.
@rtype: L{str}
"""
l = []
lablen = 0
def uniqueValues(mapping):
return set(mapping.values())
for k in sorted(uniqueValues(_x509names)):
label = util.nameToLabel(k)
lablen = max(len(label), lablen)
v = getattr(self, k, None)
if v is not None:
l.append((label, nativeString(v)))
lablen += 2
for n, (label, attr) in enumerate(l):
l[n] = (label.rjust(lablen)+': '+ attr)
return '\n'.join(l)
DN = DistinguishedName
@_oldStyle
class CertBase:
"""
Base class for public (certificate only) and private (certificate + key
pair) certificates.
@ivar original: The underlying OpenSSL certificate object.
@type original: L{OpenSSL.crypto.X509}
"""
def __init__(self, original):
self.original = original
def _copyName(self, suffix):
dn = DistinguishedName()
dn._copyFrom(getattr(self.original, 'get_'+suffix)())
return dn
def getSubject(self):
"""
Retrieve the subject of this certificate.
@return: A copy of the subject of this certificate.
@rtype: L{DistinguishedName}
"""
return self._copyName('subject')
def __conform__(self, interface):
"""
Convert this L{CertBase} into a provider of the given interface.
@param interface: The interface to conform to.
@type interface: L{zope.interface.interfaces.IInterface}
@return: an L{IOpenSSLTrustRoot} provider or L{NotImplemented}
@rtype: L{IOpenSSLTrustRoot} or L{NotImplemented}
"""
if interface is IOpenSSLTrustRoot:
return OpenSSLCertificateAuthorities([self.original])
return NotImplemented
def _handleattrhelper(Class, transport, methodName):
"""
(private) Helper for L{Certificate.peerFromTransport} and
L{Certificate.hostFromTransport} which checks for incompatible handle types
and null certificates and raises the appropriate exception or returns the
appropriate certificate object.
"""
method = getattr(transport.getHandle(),
"get_%s_certificate" % (methodName,), None)
if method is None:
raise CertificateError(
"non-TLS transport %r did not have %s certificate" % (transport, methodName))
cert = method()
if cert is None:
raise CertificateError(
"TLS transport %r did not have %s certificate" % (transport, methodName))
return Class(cert)
class Certificate(CertBase):
"""
An x509 certificate.
"""
def __repr__(self):
return '<%s Subject=%s Issuer=%s>' % (self.__class__.__name__,
self.getSubject().commonName,
self.getIssuer().commonName)
def __eq__(self, other):
if isinstance(other, Certificate):
return self.dump() == other.dump()
return False
def __ne__(self, other):
return not self.__eq__(other)
@classmethod
def load(Class, requestData, format=crypto.FILETYPE_ASN1, args=()):
"""
Load a certificate from an ASN.1- or PEM-format string.
@rtype: C{Class}
"""
return Class(crypto.load_certificate(format, requestData), *args)
# We can't use super() because it is old style still, so we have to hack
# around things wanting to call the parent function
_load = load
def dumpPEM(self):
"""
Dump this certificate to a PEM-format data string.
@rtype: L{str}
"""
return self.dump(crypto.FILETYPE_PEM)
@classmethod
def loadPEM(Class, data):
"""
Load a certificate from a PEM-format data string.
@rtype: C{Class}
"""
return Class.load(data, crypto.FILETYPE_PEM)
@classmethod
def peerFromTransport(Class, transport):
"""
Get the certificate for the remote end of the given transport.
@param transport: an L{ISystemHandle} provider
@rtype: C{Class}
@raise: L{CertificateError}, if the given transport does not have a peer
certificate.
"""
return _handleattrhelper(Class, transport, 'peer')
@classmethod
def hostFromTransport(Class, transport):
"""
Get the certificate for the local end of the given transport.
@param transport: an L{ISystemHandle} provider; the transport we will
@rtype: C{Class}
@raise: L{CertificateError}, if the given transport does not have a host
certificate.
"""
return _handleattrhelper(Class, transport, 'host')
def getPublicKey(self):
"""
Get the public key for this certificate.
@rtype: L{PublicKey}
"""
return PublicKey(self.original.get_pubkey())
def dump(self, format=crypto.FILETYPE_ASN1):
return crypto.dump_certificate(format, self.original)
def serialNumber(self):
"""
Retrieve the serial number of this certificate.
@rtype: L{int}
"""
return self.original.get_serial_number()
def digest(self, method='md5'):
"""
Return a digest hash of this certificate using the specified hash
algorithm.
@param method: One of C{'md5'} or C{'sha'}.
@return: The digest of the object, formatted as b":"-delimited hex
pairs
@rtype: L{bytes}
"""
return self.original.digest(method)
def _inspect(self):
return '\n'.join(['Certificate For Subject:',
self.getSubject().inspect(),
'\nIssuer:',
self.getIssuer().inspect(),
'\nSerial Number: %d' % self.serialNumber(),
'Digest: %s' % nativeString(self.digest())])
def inspect(self):
"""
Return a multi-line, human-readable representation of this
Certificate, including information about the subject, issuer, and
public key.
"""
return '\n'.join((self._inspect(), self.getPublicKey().inspect()))
def getIssuer(self):
"""
Retrieve the issuer of this certificate.
@rtype: L{DistinguishedName}
@return: A copy of the issuer of this certificate.
"""
return self._copyName('issuer')
def options(self, *authorities):
raise NotImplementedError('Possible, but doubtful we need this yet')
class CertificateRequest(CertBase):
"""
An x509 certificate request.
Certificate requests are given to certificate authorities to be signed and
returned resulting in an actual certificate.
"""
@classmethod
def load(Class, requestData, requestFormat=crypto.FILETYPE_ASN1):
req = crypto.load_certificate_request(requestFormat, requestData)
dn = DistinguishedName()
dn._copyFrom(req.get_subject())
if not req.verify(req.get_pubkey()):
raise VerifyError("Can't verify that request for %r is self-signed." % (dn,))
return Class(req)
def dump(self, format=crypto.FILETYPE_ASN1):
return crypto.dump_certificate_request(format, self.original)
class PrivateCertificate(Certificate):
"""
An x509 certificate and private key.
"""
def __repr__(self):
return Certificate.__repr__(self) + ' with ' + repr(self.privateKey)
def _setPrivateKey(self, privateKey):
if not privateKey.matches(self.getPublicKey()):
raise VerifyError(
"Certificate public and private keys do not match.")
self.privateKey = privateKey
return self
def newCertificate(self, newCertData, format=crypto.FILETYPE_ASN1):
"""
Create a new L{PrivateCertificate} from the given certificate data and
this instance's private key.
"""
return self.load(newCertData, self.privateKey, format)
@classmethod
def load(Class, data, privateKey, format=crypto.FILETYPE_ASN1):
return Class._load(data, format)._setPrivateKey(privateKey)
def inspect(self):
return '\n'.join([Certificate._inspect(self),
self.privateKey.inspect()])
def dumpPEM(self):
"""
Dump both public and private parts of a private certificate to
PEM-format data.
"""
return self.dump(crypto.FILETYPE_PEM) + self.privateKey.dump(crypto.FILETYPE_PEM)
@classmethod
def loadPEM(Class, data):
"""
Load both private and public parts of a private certificate from a
chunk of PEM-format data.
"""
return Class.load(data, KeyPair.load(data, crypto.FILETYPE_PEM),
crypto.FILETYPE_PEM)
@classmethod
def fromCertificateAndKeyPair(Class, certificateInstance, privateKey):
privcert = Class(certificateInstance.original)
return privcert._setPrivateKey(privateKey)
def options(self, *authorities):
"""
Create a context factory using this L{PrivateCertificate}'s certificate
and private key.
@param authorities: A list of L{Certificate} object
@return: A context factory.
@rtype: L{CertificateOptions <twisted.internet.ssl.CertificateOptions>}
"""
options = dict(privateKey=self.privateKey.original,
certificate=self.original)
if authorities:
options.update(dict(trustRoot=OpenSSLCertificateAuthorities(
[auth.original for auth in authorities]
)))
return OpenSSLCertificateOptions(**options)
def certificateRequest(self, format=crypto.FILETYPE_ASN1,
digestAlgorithm='sha256'):
return self.privateKey.certificateRequest(
self.getSubject(),
format,
digestAlgorithm)
def signCertificateRequest(self,
requestData,
verifyDNCallback,
serialNumber,
requestFormat=crypto.FILETYPE_ASN1,
certificateFormat=crypto.FILETYPE_ASN1):
issuer = self.getSubject()
return self.privateKey.signCertificateRequest(
issuer,
requestData,
verifyDNCallback,
serialNumber,
requestFormat,
certificateFormat)
def signRequestObject(self, certificateRequest, serialNumber,
secondsToExpiry=60 * 60 * 24 * 365, # One year
digestAlgorithm='sha256'):
return self.privateKey.signRequestObject(self.getSubject(),
certificateRequest,
serialNumber,
secondsToExpiry,
digestAlgorithm)
@_oldStyle
class PublicKey:
"""
A L{PublicKey} is a representation of the public part of a key pair.
You can't do a whole lot with it aside from comparing it to other
L{PublicKey} objects.
@note: If constructing a L{PublicKey} manually, be sure to pass only a
L{OpenSSL.crypto.PKey} that does not contain a private key!
@ivar original: The original private key.
"""
def __init__(self, osslpkey):
"""
@param osslpkey: The underlying pyOpenSSL key object.
@type osslpkey: L{OpenSSL.crypto.PKey}
"""
self.original = osslpkey
def matches(self, otherKey):
"""
Does this L{PublicKey} contain the same value as another L{PublicKey}?
@param otherKey: The key to compare C{self} to.
@type otherKey: L{PublicKey}
@return: L{True} if these keys match, L{False} if not.
@rtype: L{bool}
"""
return self.keyHash() == otherKey.keyHash()
def __repr__(self):
return '<%s %s>' % (self.__class__.__name__, self.keyHash())
def keyHash(self):
"""
Compute a hash of the underlying PKey object.
The purpose of this method is to allow you to determine if two
certificates share the same public key; it is not really useful for
anything else.
In versions of Twisted prior to 15.0, C{keyHash} used a technique
involving certificate requests for computing the hash that was not
stable in the face of changes to the underlying OpenSSL library.
@return: Return a 32-character hexadecimal string uniquely identifying
this public key, I{for this version of Twisted}.
@rtype: native L{str}
"""
raw = crypto.dump_publickey(crypto.FILETYPE_ASN1, self.original)
h = md5()
h.update(raw)
return h.hexdigest()
def inspect(self):
return 'Public Key with Hash: %s' % (self.keyHash(),)
class KeyPair(PublicKey):
@classmethod
def load(Class, data, format=crypto.FILETYPE_ASN1):
return Class(crypto.load_privatekey(format, data))
def dump(self, format=crypto.FILETYPE_ASN1):
return crypto.dump_privatekey(format, self.original)
def __getstate__(self):
return self.dump()
def __setstate__(self, state):
self.__init__(crypto.load_privatekey(crypto.FILETYPE_ASN1, state))
def inspect(self):
t = self.original.type()
if t == crypto.TYPE_RSA:
ts = 'RSA'
elif t == crypto.TYPE_DSA:
ts = 'DSA'
else:
ts = '(Unknown Type!)'
L = (self.original.bits(), ts, self.keyHash())
return '%s-bit %s Key Pair with Hash: %s' % L
@classmethod
def generate(Class, kind=crypto.TYPE_RSA, size=1024):
pkey = crypto.PKey()
pkey.generate_key(kind, size)
return Class(pkey)
def newCertificate(self, newCertData, format=crypto.FILETYPE_ASN1):
return PrivateCertificate.load(newCertData, self, format)
def requestObject(self, distinguishedName, digestAlgorithm='sha256'):
req = crypto.X509Req()
req.set_pubkey(self.original)
distinguishedName._copyInto(req.get_subject())
req.sign(self.original, digestAlgorithm)
return CertificateRequest(req)
def certificateRequest(self, distinguishedName,
format=crypto.FILETYPE_ASN1,
digestAlgorithm='sha256'):
"""
Create a certificate request signed with this key.
@return: a string, formatted according to the 'format' argument.
"""
return self.requestObject(distinguishedName, digestAlgorithm).dump(format)
def signCertificateRequest(self,
issuerDistinguishedName,
requestData,
verifyDNCallback,
serialNumber,
requestFormat=crypto.FILETYPE_ASN1,
certificateFormat=crypto.FILETYPE_ASN1,
secondsToExpiry=60 * 60 * 24 * 365, # One year
digestAlgorithm='sha256'):
"""
Given a blob of certificate request data and a certificate authority's
DistinguishedName, return a blob of signed certificate data.
If verifyDNCallback returns a Deferred, I will return a Deferred which
fires the data when that Deferred has completed.
"""
hlreq = CertificateRequest.load(requestData, requestFormat)
dn = hlreq.getSubject()
vval = verifyDNCallback(dn)
def verified(value):
if not value:
raise VerifyError("DN callback %r rejected request DN %r" % (verifyDNCallback, dn))
return self.signRequestObject(issuerDistinguishedName, hlreq,
serialNumber, secondsToExpiry, digestAlgorithm).dump(certificateFormat)
if isinstance(vval, Deferred):
return vval.addCallback(verified)
else:
return verified(vval)
def signRequestObject(self,
issuerDistinguishedName,
requestObject,
serialNumber,
secondsToExpiry=60 * 60 * 24 * 365, # One year
digestAlgorithm='sha256'):
"""
Sign a CertificateRequest instance, returning a Certificate instance.
"""
req = requestObject.original
cert = crypto.X509()
issuerDistinguishedName._copyInto(cert.get_issuer())
cert.set_subject(req.get_subject())
cert.set_pubkey(req.get_pubkey())
cert.gmtime_adj_notBefore(0)
cert.gmtime_adj_notAfter(secondsToExpiry)
cert.set_serial_number(serialNumber)
cert.sign(self.original, digestAlgorithm)
return Certificate(cert)
def selfSignedCert(self, serialNumber, **kw):
dn = DN(**kw)
return PrivateCertificate.fromCertificateAndKeyPair(
self.signRequestObject(dn, self.requestObject(dn), serialNumber),
self)
KeyPair.__getstate__ = deprecated(Version("Twisted", 15, 0, 0),
"a real persistence system")(KeyPair.__getstate__)
KeyPair.__setstate__ = deprecated(Version("Twisted", 15, 0, 0),
"a real persistence system")(KeyPair.__setstate__)
class IOpenSSLTrustRoot(Interface):
"""
Trust settings for an OpenSSL context.
Note that this interface's methods are private, so things outside of
Twisted shouldn't implement it.
"""
def _addCACertsToContext(context):
"""
Add certificate-authority certificates to an SSL context whose
connections should trust those authorities.
@param context: An SSL context for a connection which should be
verified by some certificate authority.
@type context: L{OpenSSL.SSL.Context}
@return: L{None}
"""
@implementer(IOpenSSLTrustRoot)
class OpenSSLCertificateAuthorities(object):
"""
Trust an explicitly specified set of certificates, represented by a list of
L{OpenSSL.crypto.X509} objects.
"""
def __init__(self, caCerts):
"""
@param caCerts: The certificate authorities to trust when using this
object as a C{trustRoot} for L{OpenSSLCertificateOptions}.
@type caCerts: L{list} of L{OpenSSL.crypto.X509}
"""
self._caCerts = caCerts
def _addCACertsToContext(self, context):
store = context.get_cert_store()
for cert in self._caCerts:
store.add_cert(cert)
def trustRootFromCertificates(certificates):
"""
Builds an object that trusts multiple root L{Certificate}s.
When passed to L{optionsForClientTLS}, connections using those options will
reject any server certificate not signed by at least one of the
certificates in the `certificates` list.
@since: 16.0
@param certificates: All certificates which will be trusted.
@type certificates: C{iterable} of L{CertBase}
@rtype: L{IOpenSSLTrustRoot}
@return: an object suitable for use as the trustRoot= keyword argument to
L{optionsForClientTLS}
"""
certs = []
for cert in certificates:
# PrivateCertificate or Certificate are both okay
if isinstance(cert, CertBase):
cert = cert.original
else:
raise TypeError(
"certificates items must be twisted.internet.ssl.CertBase"
" instances"
)
certs.append(cert)
return OpenSSLCertificateAuthorities(certs)
@implementer(IOpenSSLTrustRoot)
class OpenSSLDefaultPaths(object):
"""
Trust the set of default verify paths that OpenSSL was built with, as
specified by U{SSL_CTX_set_default_verify_paths
<https://www.openssl.org/docs/ssl/SSL_CTX_load_verify_locations.html>}.
"""
def _addCACertsToContext(self, context):
context.set_default_verify_paths()
def platformTrust():
"""
Attempt to discover a set of trusted certificate authority certificates
(or, in other words: trust roots, or root certificates) whose trust is
managed and updated by tools outside of Twisted.
If you are writing any client-side TLS code with Twisted, you should use
this as the C{trustRoot} argument to L{CertificateOptions
<twisted.internet.ssl.CertificateOptions>}.
The result of this function should be like the up-to-date list of
certificates in a web browser. When developing code that uses
C{platformTrust}, you can think of it that way. However, the choice of
which certificate authorities to trust is never Twisted's responsibility.
Unless you're writing a very unusual application or library, it's not your
code's responsibility either. The user may use platform-specific tools for
defining which server certificates should be trusted by programs using TLS.
The purpose of using this API is to respect that decision as much as
possible.
This should be a set of trust settings most appropriate for I{client} TLS
connections; i.e. those which need to verify a server's authenticity. You
should probably use this by default for any client TLS connection that you
create. For servers, however, client certificates are typically not
verified; or, if they are, their verification will depend on a custom,
application-specific certificate authority.
@since: 14.0
@note: Currently, L{platformTrust} depends entirely upon your OpenSSL build
supporting a set of "L{default verify paths <OpenSSLDefaultPaths>}"
which correspond to certificate authority trust roots. Unfortunately,
whether this is true of your system is both outside of Twisted's
control and difficult (if not impossible) for Twisted to detect
automatically.
Nevertheless, this ought to work as desired by default on:
- Ubuntu Linux machines with the U{ca-certificates
<https://launchpad.net/ubuntu/+source/ca-certificates>} package
installed,
- macOS when using the system-installed version of OpenSSL (i.e.
I{not} one installed via MacPorts or Homebrew),
- any build of OpenSSL which has had certificate authority
certificates installed into its default verify paths (by default,
C{/usr/local/ssl/certs} if you've built your own OpenSSL), or
- any process where the C{SSL_CERT_FILE} environment variable is
set to the path of a file containing your desired CA certificates
bundle.
Hopefully soon, this API will be updated to use more sophisticated
trust-root discovery mechanisms. Until then, you can follow tickets in
the Twisted tracker for progress on this implementation on U{Microsoft
Windows <https://twistedmatrix.com/trac/ticket/6371>}, U{macOS
<https://twistedmatrix.com/trac/ticket/6372>}, and U{a fallback for
other platforms which do not have native trust management tools
<https://twistedmatrix.com/trac/ticket/6934>}.
@return: an appropriate trust settings object for your platform.
@rtype: L{IOpenSSLTrustRoot}
@raise NotImplementedError: if this platform is not yet supported by
Twisted. At present, only OpenSSL is supported.
"""
return OpenSSLDefaultPaths()
def _tolerateErrors(wrapped):
"""
Wrap up an C{info_callback} for pyOpenSSL so that if something goes wrong
the error is immediately logged and the connection is dropped if possible.
This wrapper exists because some versions of pyOpenSSL don't handle errors
from callbacks at I{all}, and those which do write tracebacks directly to
stderr rather than to a supplied logging system. This reports unexpected
errors to the Twisted logging system.
Also, this terminates the connection immediately if possible because if
you've got bugs in your verification logic it's much safer to just give up.
@param wrapped: A valid C{info_callback} for pyOpenSSL.
@type wrapped: L{callable}
@return: A valid C{info_callback} for pyOpenSSL that handles any errors in
C{wrapped}.
@rtype: L{callable}
"""
def infoCallback(connection, where, ret):
try:
return wrapped(connection, where, ret)
except:
f = Failure()
log.err(f, "Error during info_callback")
connection.get_app_data().failVerification(f)
return infoCallback
@implementer(IOpenSSLClientConnectionCreator)
class ClientTLSOptions(object):
"""
Client creator for TLS.
Private implementation type (not exposed to applications) for public
L{optionsForClientTLS} API.
@ivar _ctx: The context to use for new connections.
@type _ctx: L{OpenSSL.SSL.Context}
@ivar _hostname: The hostname to verify, as specified by the application,
as some human-readable text.
@type _hostname: L{unicode}
@ivar _hostnameBytes: The hostname to verify, decoded into IDNA-encoded
bytes. This is passed to APIs which think that hostnames are bytes,
such as OpenSSL's SNI implementation.
@type _hostnameBytes: L{bytes}
@ivar _hostnameASCII: The hostname, as transcoded into IDNA ASCII-range
unicode code points. This is pre-transcoded because the
C{service_identity} package is rather strict about requiring the
C{idna} package from PyPI for internationalized domain names, rather
than working with Python's built-in (but sometimes broken) IDNA
encoding. ASCII values, however, will always work.
@type _hostnameASCII: L{unicode}
@ivar _sendSNI: Whether or not to send the SNI with the handshake.
Will be L{False} if C{_hostname} is an IP address or L{True} if
C{_hostname} is a DNSName
@type _sendSNI: L{bool}
"""
def __init__(self, hostname, ctx):
"""
Initialize L{ClientTLSOptions}.
@param hostname: The hostname to verify as input by a human.
@type hostname: L{unicode}
@param ctx: an L{OpenSSL.SSL.Context} to use for new connections.
@type ctx: L{OpenSSL.SSL.Context}.
"""
self._ctx = ctx
self._hostname = hostname
if isIPAddress(hostname) or isIPv6Address(hostname):
self._hostnameBytes = hostname.encode('ascii')
self._sendSNI = False
else:
self._hostnameBytes = _idnaBytes(hostname)
self._sendSNI = True
self._hostnameASCII = self._hostnameBytes.decode("ascii")
ctx.set_info_callback(
_tolerateErrors(self._identityVerifyingInfoCallback)
)
def clientConnectionForTLS(self, tlsProtocol):
"""
Create a TLS connection for a client.
@note: This will call C{set_app_data} on its connection. If you're
delegating to this implementation of this method, don't ever call
C{set_app_data} or C{set_info_callback} on the returned connection,
or you'll break the implementation of various features of this
class.
@param tlsProtocol: the TLS protocol initiating the connection.
@type tlsProtocol: L{twisted.protocols.tls.TLSMemoryBIOProtocol}
@return: the configured client connection.
@rtype: L{OpenSSL.SSL.Connection}
"""
context = self._ctx
connection = SSL.Connection(context, None)
connection.set_app_data(tlsProtocol)
return connection
def _identityVerifyingInfoCallback(self, connection, where, ret):
"""
U{info_callback
<http://pythonhosted.org/pyOpenSSL/api/ssl.html#OpenSSL.SSL.Context.set_info_callback>
} for pyOpenSSL that verifies the hostname in the presented certificate
matches the one passed to this L{ClientTLSOptions}.
@param connection: the connection which is handshaking.
@type connection: L{OpenSSL.SSL.Connection}
@param where: flags indicating progress through a TLS handshake.
@type where: L{int}
@param ret: ignored
@type ret: ignored
"""
# Literal IPv4 and IPv6 addresses are not permitted
# as host names according to the RFCs
if where & SSL.SSL_CB_HANDSHAKE_START and self._sendSNI:
connection.set_tlsext_host_name(self._hostnameBytes)
elif where & SSL.SSL_CB_HANDSHAKE_DONE:
try:
verifyHostname(connection, self._hostnameASCII)
except VerificationError:
f = Failure()
transport = connection.get_app_data()
transport.failVerification(f)
def optionsForClientTLS(hostname, trustRoot=None, clientCertificate=None,
acceptableProtocols=None, **kw):
"""
Create a L{client connection creator <IOpenSSLClientConnectionCreator>} for
use with APIs such as L{SSL4ClientEndpoint
<twisted.internet.endpoints.SSL4ClientEndpoint>}, L{connectSSL
<twisted.internet.interfaces.IReactorSSL.connectSSL>}, and L{startTLS
<twisted.internet.interfaces.ITLSTransport.startTLS>}.
@since: 14.0
@param hostname: The expected name of the remote host. This serves two
purposes: first, and most importantly, it verifies that the certificate
received from the server correctly identifies the specified hostname.
The second purpose is to use the U{Server Name Indication extension
<https://en.wikipedia.org/wiki/Server_Name_Indication>} to indicate to
the server which certificate should be used.
@type hostname: L{unicode}
@param trustRoot: Specification of trust requirements of peers. This may be
a L{Certificate} or the result of L{platformTrust}. By default it is
L{platformTrust} and you probably shouldn't adjust it unless you really
know what you're doing. Be aware that clients using this interface
I{must} verify the server; you cannot explicitly pass L{None} since
that just means to use L{platformTrust}.
@type trustRoot: L{IOpenSSLTrustRoot}
@param clientCertificate: The certificate and private key that the client
will use to authenticate to the server. If unspecified, the client will
not authenticate.
@type clientCertificate: L{PrivateCertificate}
@param acceptableProtocols: The protocols this peer is willing to speak
after the TLS negotiation has completed, advertised over both ALPN and
NPN. If this argument is specified, and no overlap can be found with
the other peer, the connection will fail to be established. If the
remote peer does not offer NPN or ALPN, the connection will be
established, but no protocol wil be negotiated. Protocols earlier in
the list are preferred over those later in the list.
@type acceptableProtocols: L{list} of L{bytes}
@param extraCertificateOptions: keyword-only argument; this is a dictionary
of additional keyword arguments to be presented to
L{CertificateOptions}. Please avoid using this unless you absolutely
need to; any time you need to pass an option here that is a bug in this
interface.
@type extraCertificateOptions: L{dict}
@param kw: (Backwards compatibility hack to allow keyword-only arguments on
Python 2. Please ignore; arbitrary keyword arguments will be errors.)
@type kw: L{dict}
@return: A client connection creator.
@rtype: L{IOpenSSLClientConnectionCreator}
"""
extraCertificateOptions = kw.pop('extraCertificateOptions', None) or {}
if trustRoot is None:
trustRoot = platformTrust()
if kw:
raise TypeError(
"optionsForClientTLS() got an unexpected keyword argument"
" '{arg}'".format(
arg=kw.popitem()[0]
)
)
if not isinstance(hostname, unicode):
raise TypeError(
"optionsForClientTLS requires text for host names, not "
+ hostname.__class__.__name__
)
if clientCertificate:
extraCertificateOptions.update(
privateKey=clientCertificate.privateKey.original,
certificate=clientCertificate.original
)
certificateOptions = OpenSSLCertificateOptions(
trustRoot=trustRoot,
acceptableProtocols=acceptableProtocols,
**extraCertificateOptions
)
return ClientTLSOptions(hostname, certificateOptions.getContext())
@implementer(IOpenSSLContextFactory)
class OpenSSLCertificateOptions(object):
"""
A L{CertificateOptions <twisted.internet.ssl.CertificateOptions>} specifies
the security properties for a client or server TLS connection used with
OpenSSL.
@ivar _options: Any option flags to set on the L{OpenSSL.SSL.Context}
object that will be created.
@type _options: L{int}
@ivar _cipherString: An OpenSSL-specific cipher string.
@type _cipherString: L{unicode}
@ivar _defaultMinimumTLSVersion: The default TLS version that will be
negotiated. This should be a "safe default", with wide client and
server support, vs an optimally secure one that excludes a large number
of users. As of late 2016, TLSv1.0 is that safe default.
@type _defaultMinimumTLSVersion: L{TLSVersion} constant
"""
# Factory for creating contexts. Configurable for testability.
_contextFactory = SSL.Context
_context = None
_OP_NO_TLSv1_3 = _tlsDisableFlags[TLSVersion.TLSv1_3]
_defaultMinimumTLSVersion = TLSVersion.TLSv1_0
@_mutuallyExclusiveArguments([
['trustRoot', 'requireCertificate'],
['trustRoot', 'verify'],
['trustRoot', 'caCerts'],
['method', 'insecurelyLowerMinimumTo'],
['method', 'raiseMinimumTo'],
['raiseMinimumTo', 'insecurelyLowerMinimumTo'],
['method', 'lowerMaximumSecurityTo'],
])
def __init__(self,
privateKey=None,
certificate=None,
method=None,
verify=False,
caCerts=None,
verifyDepth=9,
requireCertificate=True,
verifyOnce=True,
enableSingleUseKeys=True,
enableSessions=True,
fixBrokenPeers=False,
enableSessionTickets=False,
extraCertChain=None,
acceptableCiphers=None,
dhParameters=None,
trustRoot=None,
acceptableProtocols=None,
raiseMinimumTo=None,
insecurelyLowerMinimumTo=None,
lowerMaximumSecurityTo=None,
):
"""
Create an OpenSSL context SSL connection context factory.
@param privateKey: A PKey object holding the private key.
@param certificate: An X509 object holding the certificate.
@param method: Deprecated, use a combination of
C{insecurelyLowerMinimumTo}, C{raiseMinimumTo}, or
C{lowerMaximumSecurityTo} instead. The SSL protocol to use, one of
C{SSLv23_METHOD}, C{SSLv2_METHOD}, C{SSLv3_METHOD}, C{TLSv1_METHOD}
(or any other method constants provided by pyOpenSSL). By default,
a setting will be used which allows TLSv1.0, TLSv1.1, and TLSv1.2.
Can not be used with C{insecurelyLowerMinimumTo},
C{raiseMinimumTo}, or C{lowerMaximumSecurityTo}
@param verify: Please use a C{trustRoot} keyword argument instead,
since it provides the same functionality in a less error-prone way.
By default this is L{False}.
If L{True}, verify certificates received from the peer and fail the
handshake if verification fails. Otherwise, allow anonymous
sessions and sessions with certificates which fail validation.
@param caCerts: Please use a C{trustRoot} keyword argument instead,
since it provides the same functionality in a less error-prone way.
List of certificate authority certificate objects to use to verify
the peer's certificate. Only used if verify is L{True} and will be
ignored otherwise. Since verify is L{False} by default, this is
L{None} by default.
@type caCerts: L{list} of L{OpenSSL.crypto.X509}
@param verifyDepth: Depth in certificate chain down to which to verify.
If unspecified, use the underlying default (9).
@param requireCertificate: Please use a C{trustRoot} keyword argument
instead, since it provides the same functionality in a less
error-prone way.
If L{True}, do not allow anonymous sessions; defaults to L{True}.
@param verifyOnce: If True, do not re-verify the certificate on session
resumption.
@param enableSingleUseKeys: If L{True}, generate a new key whenever
ephemeral DH and ECDH parameters are used to prevent small subgroup
attacks and to ensure perfect forward secrecy.
@param enableSessions: If True, set a session ID on each context. This
allows a shortened handshake to be used when a known client
reconnects.
@param fixBrokenPeers: If True, enable various non-spec protocol fixes
for broken SSL implementations. This should be entirely safe,
according to the OpenSSL documentation, but YMMV. This option is
now off by default, because it causes problems with connections
between peers using OpenSSL 0.9.8a.
@param enableSessionTickets: If L{True}, enable session ticket
extension for session resumption per RFC 5077. Note there is no
support for controlling session tickets. This option is off by
default, as some server implementations don't correctly process
incoming empty session ticket extensions in the hello.
@param extraCertChain: List of certificates that I{complete} your
verification chain if the certificate authority that signed your
C{certificate} isn't widely supported. Do I{not} add
C{certificate} to it.
@type extraCertChain: C{list} of L{OpenSSL.crypto.X509}
@param acceptableCiphers: Ciphers that are acceptable for connections.
Uses a secure default if left L{None}.
@type acceptableCiphers: L{IAcceptableCiphers}
@param dhParameters: Key generation parameters that are required for
Diffie-Hellman key exchange. If this argument is left L{None},
C{EDH} ciphers are I{disabled} regardless of C{acceptableCiphers}.
@type dhParameters: L{DiffieHellmanParameters
<twisted.internet.ssl.DiffieHellmanParameters>}
@param trustRoot: Specification of trust requirements of peers. If
this argument is specified, the peer is verified. It requires a
certificate, and that certificate must be signed by one of the
certificate authorities specified by this object.
Note that since this option specifies the same information as
C{caCerts}, C{verify}, and C{requireCertificate}, specifying any of
those options in combination with this one will raise a
L{TypeError}.
@type trustRoot: L{IOpenSSLTrustRoot}
@param acceptableProtocols: The protocols this peer is willing to speak
after the TLS negotiation has completed, advertised over both ALPN
and NPN. If this argument is specified, and no overlap can be
found with the other peer, the connection will fail to be
established. If the remote peer does not offer NPN or ALPN, the
connection will be established, but no protocol wil be negotiated.
Protocols earlier in the list are preferred over those later in the
list.
@type acceptableProtocols: L{list} of L{bytes}
@param raiseMinimumTo: The minimum TLS version that you want to use, or
Twisted's default if it is higher. Use this if you want to make
your client/server more secure than Twisted's default, but will
accept Twisted's default instead if it moves higher than this
value. You probably want to use this over
C{insecurelyLowerMinimumTo}.
@type raiseMinimumTo: L{TLSVersion} constant
@param insecurelyLowerMinimumTo: The minimum TLS version to use,
possibky lower than Twisted's default. If not specified, it is a
generally considered safe default (TLSv1.0). If you want to raise
your minimum TLS version to above that of this default, use
C{raiseMinimumTo}. DO NOT use this argument unless you are
absolutely sure this is what you want.
@type insecurelyLowerMinimumTo: L{TLSVersion} constant
@param lowerMaximumSecurityTo: The maximum TLS version to use. If not
specified, it is the most recent your OpenSSL supports. You only
want to set this if the peer that you are communicating with has
problems with more recent TLS versions, it lowers your security
when communicating with newer peers. DO NOT use this argument
unless you are absolutely sure this is what you want.
@type lowerMaximumSecurityTo: L{TLSVersion} constant
@raise ValueError: when C{privateKey} or C{certificate} are set without
setting the respective other.
@raise ValueError: when C{verify} is L{True} but C{caCerts} doesn't
specify any CA certificates.
@raise ValueError: when C{extraCertChain} is passed without specifying
C{privateKey} or C{certificate}.
@raise ValueError: when C{acceptableCiphers} doesn't yield any usable
ciphers for the current platform.
@raise TypeError: if C{trustRoot} is passed in combination with
C{caCert}, C{verify}, or C{requireCertificate}. Please prefer
C{trustRoot} in new code, as its semantics are less tricky.
@raise TypeError: if C{method} is passed in combination with
C{tlsProtocols}. Please prefer the more explicit C{tlsProtocols}
in new code.
@raises NotImplementedError: If acceptableProtocols were provided but
no negotiation mechanism is available.
"""
if (privateKey is None) != (certificate is None):
raise ValueError(
"Specify neither or both of privateKey and certificate")
self.privateKey = privateKey
self.certificate = certificate
# Set basic security options: disallow insecure SSLv2, disallow TLS
# compression to avoid CRIME attack, make the server choose the
# ciphers.
self._options = (
SSL.OP_NO_SSLv2 | SSL.OP_NO_COMPRESSION |
SSL.OP_CIPHER_SERVER_PREFERENCE
)
# Set the mode to Release Buffers, which demallocs send/recv buffers on
# idle TLS connections to save memory
self._mode = SSL.MODE_RELEASE_BUFFERS
if method is None:
self.method = SSL.SSLv23_METHOD
if raiseMinimumTo:
if (lowerMaximumSecurityTo and
raiseMinimumTo > lowerMaximumSecurityTo):
raise ValueError(
("raiseMinimumTo needs to be lower than "
"lowerMaximumSecurityTo"))
if raiseMinimumTo > self._defaultMinimumTLSVersion:
insecurelyLowerMinimumTo = raiseMinimumTo
if insecurelyLowerMinimumTo is None:
insecurelyLowerMinimumTo = self._defaultMinimumTLSVersion
# If you set the max lower than the default, but don't set the
# minimum, pull it down to that
if (lowerMaximumSecurityTo and
insecurelyLowerMinimumTo > lowerMaximumSecurityTo):
insecurelyLowerMinimumTo = lowerMaximumSecurityTo
if (lowerMaximumSecurityTo and
insecurelyLowerMinimumTo > lowerMaximumSecurityTo):
raise ValueError(
("insecurelyLowerMinimumTo needs to be lower than "
"lowerMaximumSecurityTo"))
excludedVersions = _getExcludedTLSProtocols(
insecurelyLowerMinimumTo, lowerMaximumSecurityTo)
for version in excludedVersions:
self._options |= _tlsDisableFlags[version]
else:
warnings.warn(
("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."),
DeprecationWarning, stacklevel=3)
# Otherwise respect the application decision.
self.method = method
if verify and not caCerts:
raise ValueError("Specify client CA certificate information if and"
" only if enabling certificate verification")
self.verify = verify
if extraCertChain is not None and None in (privateKey, certificate):
raise ValueError("A private key and a certificate are required "
"when adding a supplemental certificate chain.")
if extraCertChain is not None:
self.extraCertChain = extraCertChain
else:
self.extraCertChain = []
self.caCerts = caCerts
self.verifyDepth = verifyDepth
self.requireCertificate = requireCertificate
self.verifyOnce = verifyOnce
self.enableSingleUseKeys = enableSingleUseKeys
if enableSingleUseKeys:
self._options |= SSL.OP_SINGLE_DH_USE | SSL.OP_SINGLE_ECDH_USE
self.enableSessions = enableSessions
self.fixBrokenPeers = fixBrokenPeers
if fixBrokenPeers:
self._options |= SSL.OP_ALL
self.enableSessionTickets = enableSessionTickets
if not enableSessionTickets:
self._options |= SSL.OP_NO_TICKET
self.dhParameters = dhParameters
self._ecChooser = _ChooseDiffieHellmanEllipticCurve(
SSL.OPENSSL_VERSION_NUMBER,
openSSLlib=pyOpenSSLlib,
openSSLcrypto=crypto,
)
if acceptableCiphers is None:
acceptableCiphers = defaultCiphers
# This needs to run when method and _options are finalized.
self._cipherString = u':'.join(
c.fullName
for c in acceptableCiphers.selectCiphers(
_expandCipherString(u'ALL', self.method, self._options)
)
)
if self._cipherString == u'':
raise ValueError(
'Supplied IAcceptableCiphers yielded no usable ciphers '
'on this platform.'
)
if trustRoot is None:
if self.verify:
trustRoot = OpenSSLCertificateAuthorities(caCerts)
else:
self.verify = True
self.requireCertificate = True
trustRoot = IOpenSSLTrustRoot(trustRoot)
self.trustRoot = trustRoot
if acceptableProtocols is not None and not protocolNegotiationMechanisms():
raise NotImplementedError(
"No support for protocol negotiation on this platform."
)
self._acceptableProtocols = acceptableProtocols
def __getstate__(self):
d = self.__dict__.copy()
try:
del d['_context']
except KeyError:
pass
return d
def __setstate__(self, state):
self.__dict__ = state
def getContext(self):
"""
Return an L{OpenSSL.SSL.Context} object.
"""
if self._context is None:
self._context = self._makeContext()
return self._context
def _makeContext(self):
ctx = self._contextFactory(self.method)
ctx.set_options(self._options)
ctx.set_mode(self._mode)
if self.certificate is not None and self.privateKey is not None:
ctx.use_certificate(self.certificate)
ctx.use_privatekey(self.privateKey)
for extraCert in self.extraCertChain:
ctx.add_extra_chain_cert(extraCert)
# Sanity check
ctx.check_privatekey()
verifyFlags = SSL.VERIFY_NONE
if self.verify:
verifyFlags = SSL.VERIFY_PEER
if self.requireCertificate:
verifyFlags |= SSL.VERIFY_FAIL_IF_NO_PEER_CERT
if self.verifyOnce:
verifyFlags |= SSL.VERIFY_CLIENT_ONCE
self.trustRoot._addCACertsToContext(ctx)
# It'd be nice if pyOpenSSL let us pass None here for this behavior (as
# the underlying OpenSSL API call allows NULL to be passed). It
# doesn't, so we'll supply a function which does the same thing.
def _verifyCallback(conn, cert, errno, depth, preverify_ok):
return preverify_ok
ctx.set_verify(verifyFlags, _verifyCallback)
if self.verifyDepth is not None:
ctx.set_verify_depth(self.verifyDepth)
if self.enableSessions:
name = "%s-%d" % (reflect.qual(self.__class__), _sessionCounter())
sessionName = md5(networkString(name)).hexdigest()
ctx.set_session_id(sessionName.encode('ascii'))
if self.dhParameters:
ctx.load_tmp_dh(self.dhParameters._dhFile.path)
ctx.set_cipher_list(self._cipherString.encode('ascii'))
self._ecChooser.configureECDHCurve(ctx)
if self._acceptableProtocols:
# Try to set NPN and ALPN. _acceptableProtocols cannot be set by
# the constructor unless at least one mechanism is supported.
_setAcceptableProtocols(ctx, self._acceptableProtocols)
return ctx
OpenSSLCertificateOptions.__getstate__ = deprecated(
Version("Twisted", 15, 0, 0),
"a real persistence system")(OpenSSLCertificateOptions.__getstate__)
OpenSSLCertificateOptions.__setstate__ = deprecated(
Version("Twisted", 15, 0, 0),
"a real persistence system")(OpenSSLCertificateOptions.__setstate__)
@implementer(ICipher)
class OpenSSLCipher(FancyEqMixin, object):
"""
A representation of an OpenSSL cipher.
"""
compareAttributes = ('fullName',)
def __init__(self, fullName):
"""
@param fullName: The full name of the cipher. For example
C{u"ECDHE-RSA-AES256-GCM-SHA384"}.
@type fullName: L{unicode}
"""
self.fullName = fullName
def __repr__(self):
"""
A runnable representation of the cipher.
"""
return 'OpenSSLCipher({0!r})'.format(self.fullName)
def _expandCipherString(cipherString, method, options):
"""
Expand C{cipherString} according to C{method} and C{options} to a list
of explicit ciphers that are supported by the current platform.
@param cipherString: An OpenSSL cipher string to expand.
@type cipherString: L{unicode}
@param method: An OpenSSL method like C{SSL.TLSv1_METHOD} used for
determining the effective ciphers.
@param options: OpenSSL options like C{SSL.OP_NO_SSLv3} ORed together.
@type options: L{int}
@return: The effective list of explicit ciphers that results from the
arguments on the current platform.
@rtype: L{list} of L{ICipher}
"""
ctx = SSL.Context(method)
ctx.set_options(options)
try:
ctx.set_cipher_list(cipherString.encode('ascii'))
except SSL.Error as e:
if e.args[0][0][2] == 'no cipher match':
return []
else:
raise
conn = SSL.Connection(ctx, None)
ciphers = conn.get_cipher_list()
if isinstance(ciphers[0], unicode):
return [OpenSSLCipher(cipher) for cipher in ciphers]
else:
return [OpenSSLCipher(cipher.decode('ascii')) for cipher in ciphers]
@implementer(IAcceptableCiphers)
class OpenSSLAcceptableCiphers(object):
"""
A representation of ciphers that are acceptable for TLS connections.
"""
def __init__(self, ciphers):
self._ciphers = ciphers
def selectCiphers(self, availableCiphers):
return [cipher
for cipher in self._ciphers
if cipher in availableCiphers]
@classmethod
def fromOpenSSLCipherString(cls, cipherString):
"""
Create a new instance using an OpenSSL cipher string.
@param cipherString: An OpenSSL cipher string that describes what
cipher suites are acceptable.
See the documentation of U{OpenSSL
<http://www.openssl.org/docs/apps/ciphers.html#CIPHER_STRINGS>} or
U{Apache
<http://httpd.apache.org/docs/2.4/mod/mod_ssl.html#sslciphersuite>}
for details.
@type cipherString: L{unicode}
@return: Instance representing C{cipherString}.
@rtype: L{twisted.internet.ssl.AcceptableCiphers}
"""
return cls(_expandCipherString(
nativeString(cipherString),
SSL.SSLv23_METHOD, SSL.OP_NO_SSLv2 | SSL.OP_NO_SSLv3)
)
# A secure default.
# Sources for more information on TLS ciphers:
#
# - https://wiki.mozilla.org/Security/Server_Side_TLS
# - https://www.ssllabs.com/projects/best-practices/index.html
# - https://hynek.me/articles/hardening-your-web-servers-ssl-ciphers/
#
# The general intent is:
# - Prefer cipher suites that offer perfect forward secrecy (DHE/ECDHE),
# - prefer ECDHE over DHE for better performance,
# - prefer any AES-GCM and ChaCha20 over any AES-CBC for better performance and
# security,
# - prefer AES-GCM to ChaCha20 because AES hardware support is common,
# - disable NULL authentication, MD5 MACs and DSS for security reasons.
#
defaultCiphers = OpenSSLAcceptableCiphers.fromOpenSSLCipherString(
"TLS13-AES-256-GCM-SHA384:TLS13-CHACHA20-POLY1305-SHA256:"
"TLS13-AES-128-GCM-SHA256:"
"ECDH+AESGCM:ECDH+CHACHA20:DH+AESGCM:DH+CHACHA20:ECDH+AES256:DH+AES256:"
"ECDH+AES128:DH+AES:RSA+AESGCM:RSA+AES:"
"!aNULL:!MD5:!DSS"
)
_defaultCurveName = u"prime256v1"
class _ChooseDiffieHellmanEllipticCurve(object):
"""
Chooses the best elliptic curve for Elliptic Curve Diffie-Hellman
key exchange, and provides a C{configureECDHCurve} method to set
the curve, when appropriate, on a new L{OpenSSL.SSL.Context}.
The C{configureECDHCurve} method will be set to one of the
following based on the provided OpenSSL version and configuration:
- L{_configureOpenSSL110}
- L{_configureOpenSSL102}
- L{_configureOpenSSL101}
- L{_configureOpenSSL101NoCurves}.
@param openSSLVersion: The OpenSSL version number.
@type openSSLVersion: L{int}
@see: L{OpenSSL.SSL.OPENSSL_VERSION_NUMBER}
@param openSSLlib: The OpenSSL C{cffi} library module.
@param openSSLlib: The OpenSSL L{crypto} module.
@see: L{crypto}
"""
def __init__(self, openSSLVersion, openSSLlib, openSSLcrypto):
self._openSSLlib = openSSLlib
self._openSSLcrypto = openSSLcrypto
if openSSLVersion >= 0x10100000:
self.configureECDHCurve = self._configureOpenSSL110
elif openSSLVersion >= 0x10002000:
self.configureECDHCurve = self._configureOpenSSL102
else:
try:
self._ecCurve = openSSLcrypto.get_elliptic_curve(
_defaultCurveName)
except ValueError:
# The get_elliptic_curve method raises a ValueError
# when the curve does not exist.
self.configureECDHCurve = self._configureOpenSSL101NoCurves
else:
self.configureECDHCurve = self._configureOpenSSL101
def _configureOpenSSL110(self, ctx):
"""
OpenSSL 1.1.0 Contexts are preconfigured with an optimal set
of ECDH curves. This method does nothing.
@param ctx: L{OpenSSL.SSL.Context}
"""
def _configureOpenSSL102(self, ctx):
"""
Have the context automatically choose elliptic curves for
ECDH. Run on OpenSSL 1.0.2 and OpenSSL 1.1.0+, but only has
an effect on OpenSSL 1.0.2.
@param ctx: The context which .
@type ctx: L{OpenSSL.SSL.Context}
"""
ctxPtr = ctx._context
try:
self._openSSLlib.SSL_CTX_set_ecdh_auto(ctxPtr, True)
except:
pass
def _configureOpenSSL101(self, ctx):
"""
Set the default elliptic curve for ECDH on the context. Only
run on OpenSSL 1.0.1.
@param ctx: The context on which to set the ECDH curve.
@type ctx: L{OpenSSL.SSL.Context}
"""
try:
ctx.set_tmp_ecdh(self._ecCurve)
except:
pass
def _configureOpenSSL101NoCurves(self, ctx):
"""
No elliptic curves are available on OpenSSL 1.0.1. We can't
set anything, so do nothing.
@param ctx: The context on which to set the ECDH curve.
@type ctx: L{OpenSSL.SSL.Context}
"""
class OpenSSLDiffieHellmanParameters(object):
"""
A representation of key generation parameters that are required for
Diffie-Hellman key exchange.
"""
def __init__(self, parameters):
self._dhFile = parameters
@classmethod
def fromFile(cls, filePath):
"""
Load parameters from a file.
Such a file can be generated using the C{openssl} command line tool as
following:
C{openssl dhparam -out dh_param_1024.pem -2 1024}
Please refer to U{OpenSSL's C{dhparam} documentation
<http://www.openssl.org/docs/apps/dhparam.html>} for further details.
@param filePath: A file containing parameters for Diffie-Hellman key
exchange.
@type filePath: L{FilePath <twisted.python.filepath.FilePath>}
@return: An instance that loads its parameters from C{filePath}.
@rtype: L{DiffieHellmanParameters
<twisted.internet.ssl.DiffieHellmanParameters>}
"""
return cls(filePath)
def _setAcceptableProtocols(context, acceptableProtocols):
"""
Called to set up the L{OpenSSL.SSL.Context} for doing NPN and/or ALPN
negotiation.
@param context: The context which is set up.
@type context: L{OpenSSL.SSL.Context}
@param acceptableProtocols: The protocols this peer is willing to speak
after the TLS negotiation has completed, advertised over both ALPN and
NPN. If this argument is specified, and no overlap can be found with
the other peer, the connection will fail to be established. If the
remote peer does not offer NPN or ALPN, the connection will be
established, but no protocol wil be negotiated. Protocols earlier in
the list are preferred over those later in the list.
@type acceptableProtocols: L{list} of L{bytes}
"""
def protoSelectCallback(conn, protocols):
"""
NPN client-side and ALPN server-side callback used to select
the next protocol. Prefers protocols found earlier in
C{_acceptableProtocols}.
@param conn: The context which is set up.
@type conn: L{OpenSSL.SSL.Connection}
@param conn: Protocols advertised by the other side.
@type conn: L{list} of L{bytes}
"""
overlap = set(protocols) & set(acceptableProtocols)
for p in acceptableProtocols:
if p in overlap:
return p
else:
return b''
# If we don't actually have protocols to negotiate, don't set anything up.
# Depending on OpenSSL version, failing some of the selection callbacks can
# cause the handshake to fail, which is presumably not what was intended
# here.
if not acceptableProtocols:
return
supported = protocolNegotiationMechanisms()
if supported & ProtocolNegotiationSupport.NPN:
def npnAdvertiseCallback(conn):
return acceptableProtocols
context.set_npn_advertise_callback(npnAdvertiseCallback)
context.set_npn_select_callback(protoSelectCallback)
if supported & ProtocolNegotiationSupport.ALPN:
context.set_alpn_select_callback(protoSelectCallback)
context.set_alpn_protos(acceptableProtocols)
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