def make_dhfield(self, modp_options, sigmai):
dhs = []
for modp in modp_options:
p = dh.primes[modp]
g = dh.generators[modp]
x = crypto.srand(2**(2 * self.n - 1), p - 1)
# FIXME this may be a source of performance issues
e = crypto.powmod(g, x, p)
self.xes[modp] = x
self.es[modp] = e
if sigmai:
dhs.append(
base64.b64encode(crypto.encode_mpi(e)).decode('utf-8'))
name = 'dhkeys'
else:
He = crypto.sha256(crypto.encode_mpi(e))
dhs.append(base64.b64encode(He).decode('utf-8'))
name = 'dhhashes'
return nbxmpp.DataField(name=name, typ='hidden', value=dhs)
def final_steps_alice(self, form):
srs = ""
srses = secrets.secrets().retained_secrets(self.conn.name, self.jid.getStripped())
srshash = base64.b64decode(form["srshash"])
for (secret, verified) in srses:
if self.hmac(secret, "Shared Retained Secret") == srshash:
srs = secret
break
oss = ""
k = crypto.sha256(self.k + srs + oss)
del self.k
self.do_retained_secret(k, srs)
# ks_s doesn't need to be calculated here
self.kc_s, self.km_s, self.ks_s = self.generate_initiator_keys(k)
self.kc_o, self.km_o, self.ks_o = self.generate_responder_keys(k)
# 4.6.2 Verifying Bob's Identity
self.verify_identity(form, self.d, False, "b")
# Note: If Alice discovers an error then she SHOULD ignore any encrypted
# content she received in the stanza.
if self.negotiated["logging"] == "mustnot":
self.loggable = False
self.status = "active"
self.enable_encryption = True
if self.control:
self.control.print_esession_details()
def final_steps_alice(self, form):
srs = ''
srses = secrets.secrets().retained_secrets(self.conn.name,
self.jid.getStripped())
try:
srshash = base64.b64decode(form['srshash'])
except IndexError:
return
for s in srses:
secret = s[0]
if self.hmac(secret, 'Shared Retained Secret') == srshash:
srs = secret
break
oss = ''
k = crypto.sha256(self.k + srs + oss)
del self.k
self.do_retained_secret(k, srs)
# ks_s doesn't need to be calculated here
self.kc_s, self.km_s, self.ks_s = self.generate_initiator_keys(k)
self.kc_o, self.km_o, self.ks_o = self.generate_responder_keys(k)
# 4.6.2 Verifying Bob's Identity
self.verify_identity(form, self.d, False, 'b')
# Note: If Alice discovers an error then she SHOULD ignore any encrypted
# content she received in the stanza.
if self.negotiated['logging'] == 'mustnot':
self.loggable = False
self.status = 'active'
self.enable_encryption = True
if self.control:
self.control.print_esession_details()
self.stop_archiving_for_session()
def final_steps_alice(self, form):
srs = b''
srses = secrets.secrets().retained_secrets(self.conn.name,
self.jid.getStripped())
try:
srshash = base64.b64decode(form['srshash'])
except IndexError:
return
for s in srses:
secret = s[0]
if self.hmac(secret, b'Shared Retained Secret') == srshash:
srs = secret
break
oss = b''
k = crypto.sha256(self.k + srs + oss)
del self.k
self.do_retained_secret(k, srs)
# ks_s doesn't need to be calculated here
self.kc_s, self.km_s, self.ks_s = self.generate_initiator_keys(k)
self.kc_o, self.km_o, self.ks_o = self.generate_responder_keys(k)
# 4.6.2 Verifying Bob's Identity
self.verify_identity(form, self.d, False, 'b')
# Note: If Alice discovers an error then she SHOULD ignore any encrypted
# content she received in the stanza.
if self.negotiated['logging'] == 'mustnot':
self.loggable = False
self.status = 'active'
self.enable_encryption = True
if self.control:
self.control.print_esession_details()
self.stop_archiving_for_session()
def make_dhfield(self, modp_options, sigmai):
dhs = []
for modp in modp_options:
p = dh.primes[modp]
g = dh.generators[modp]
x = crypto.srand(2 ** (2 * self.n - 1), p - 1)
# FIXME this may be a source of performance issues
e = crypto.powmod(g, x, p)
self.xes[modp] = x
self.es[modp] = e
if sigmai:
dhs.append(base64.b64encode(crypto.encode_mpi(e)))
name = 'dhkeys'
else:
He = crypto.sha256(crypto.encode_mpi(e))
dhs.append(base64.b64encode(He))
name = 'dhhashes'
return nbxmpp.DataField(name=name, typ='hidden', value=dhs)
def get_shared_secret(self, e, y, p):
if (not 1 < e < (p - 1)):
raise exceptions.NegotiationError, 'invalid DH value'
return crypto.sha256(crypto.encode_mpi(crypto.powmod(e, y, p)))
def sign(self, string):
if self.negotiated['sign_algs'] == (XmlDsig + 'rsa-sha256'):
hash = crypto.sha256(string)
return crypto.encode_mpi(gajim.pubkey.sign(hash, '')[0])
def accept_e2e_bob(self, form):
"""
4.5 esession accept (bob)
"""
response = nbxmpp.Message()
init = response.NT.init
init.setNamespace(nbxmpp.NS_ESESSION_INIT)
x = nbxmpp.DataForm(typ='result')
for field in ('nonce', 'dhkeys', 'rshashes', 'identity', 'mac'):
# FIXME: will do nothing in real world...
assert field in form.asDict(), "alice's form didn't have a %s field" \
% field
# 4.5.1 generating provisory session keys
e = crypto.decode_mpi(base64.b64decode(form['dhkeys']))
p = dh.primes[self.modp]
if crypto.sha256(crypto.encode_mpi(e)) != self.negotiated['He']:
raise NegotiationError('SHA256(e) != He')
k = self.get_shared_secret(e, self.y, p)
self.kc_o, self.km_o, self.ks_o = self.generate_initiator_keys(k)
# 4.5.2 verifying alice's identity
self.verify_identity(form, e, False, 'a')
# 4.5.4 generating bob's final session keys
srs = ''
srses = secrets.secrets().retained_secrets(self.conn.name,
self.jid.getStripped())
rshashes = [base64.b64decode(rshash) for rshash in form.getField(
'rshashes').getValues()]
for s in srses:
secret = s[0]
if self.hmac(self.n_o, secret) in rshashes:
srs = secret
break
# other shared secret
# (we're not using one)
oss = ''
k = crypto.sha256(k + srs + oss)
self.kc_s, self.km_s, self.ks_s = self.generate_responder_keys(k)
self.kc_o, self.km_o, self.ks_o = self.generate_initiator_keys(k)
# 4.5.5
if srs:
srshash = self.hmac(srs, 'Shared Retained Secret')
else:
srshash = crypto.random_bytes(32)
x.addChild(node=nbxmpp.DataField(name='FORM_TYPE',
value='urn:xmpp:ssn'))
x.addChild(node=nbxmpp.DataField(name='nonce', value=base64.b64encode(
self.n_o)))
x.addChild(node=nbxmpp.DataField(name='srshash', value=base64.b64encode(
srshash)))
for datafield in self.make_identity(x, self.d):
x.addChild(node=datafield)
init.addChild(node=x)
self.send(response)
self.do_retained_secret(k, srs)
if self.negotiated['logging'] == 'mustnot':
self.loggable = False
self.status = 'active'
self.enable_encryption = True
if self.control:
self.control.print_esession_details()
self.stop_archiving_for_session()
def verify_identity(self, form, dh_i, sigmai, i_o):
m_o = base64.b64decode(form['mac'])
id_o = base64.b64decode(form['identity'])
m_o_calculated = self.hmac(self.km_o, crypto.encode_mpi(self.c_o) + id_o)
if m_o_calculated != m_o:
raise NegotiationError('calculated m_%s differs from received m_%s' %
(i_o, i_o))
if i_o == 'a' and self.sas_algs == 'sas28x5':
# we don't need to calculate this if there's a verified retained secret
# (but we do anyways)
self.sas = crypto.sas_28x5(m_o, self.form_s)
if self.negotiated['recv_pubkey']:
plaintext = self.decrypt(id_o)
parsed = nbxmpp.Node(node='<node>' + plaintext + '</node>')
if self.negotiated['recv_pubkey'] == 'hash':
# fingerprint = parsed.getTagData('fingerprint')
# FIXME find stored pubkey or terminate session
raise NotImplementedError()
else:
if self.negotiated['sign_algs'] == (XmlDsig + 'rsa-sha256'):
keyvalue = parsed.getTag(name='RSAKeyValue', namespace=XmlDsig)
n, e = (crypto.decode_mpi(base64.b64decode(
keyvalue.getTagData(x))) for x in ('Modulus', 'Exponent'))
eir_pubkey = RSA.construct((n, long(e)))
pubkey_o = nbxmpp.c14n.c14n(keyvalue, self._is_buggy_gajim())
else:
# FIXME DSA, etc.
raise NotImplementedError()
enc_sig = parsed.getTag(name='SignatureValue',
namespace=XmlDsig).getData()
signature = (crypto.decode_mpi(base64.b64decode(enc_sig)), )
else:
mac_o = self.decrypt(id_o)
pubkey_o = ''
c7l_form = self.c7lize_mac_id(form)
content = self.n_s + self.n_o + crypto.encode_mpi(dh_i) + pubkey_o
if sigmai:
self.form_o = c7l_form
content += self.form_o
else:
form_o2 = c7l_form
content += self.form_o + form_o2
mac_o_calculated = self.hmac(self.ks_o, content)
if self.negotiated['recv_pubkey']:
hash_ = crypto.sha256(mac_o_calculated)
if not eir_pubkey.verify(hash_, signature):
raise NegotiationError('public key signature verification failed!')
elif mac_o_calculated != mac_o:
raise NegotiationError('calculated mac_%s differs from received mac_%s'
% (i_o, i_o))
def get_shared_secret(self, e, y, p):
if (not 1 < e < (p - 1)):
raise NegotiationError('invalid DH value')
return crypto.sha256(crypto.encode_mpi(crypto.powmod(e, y, p)))
def sign(self, string):
if self.negotiated['sign_algs'] == (XmlDsig + 'rsa-sha256'):
hash_ = crypto.sha256(string)
return crypto.encode_mpi(gajim.pubkey.sign(hash_, '')[0])
def get_shared_secret(self, e, y, p):
if not 1 < e < (p - 1):
raise exceptions.NegotiationError, "invalid DH value"
return crypto.sha256(crypto.encode_mpi(crypto.powmod(e, y, p)))
def accept_e2e_bob(self, form):
response = xmpp.Message()
init = response.NT.init
init.setNamespace(xmpp.NS_ESESSION_INIT)
x = xmpp.DataForm(typ="result")
for field in ("nonce", "dhkeys", "rshashes", "identity", "mac"):
assert field in form.asDict(), "alice's form didn't have a %s field" % field
# 4.5.1 generating provisory session keys
e = crypto.decode_mpi(base64.b64decode(form["dhkeys"]))
p = dh.primes[self.modp]
if crypto.sha256(crypto.encode_mpi(e)) != self.negotiated["He"]:
raise exceptions.NegotiationError, "SHA256(e) != He"
k = self.get_shared_secret(e, self.y, p)
self.kc_o, self.km_o, self.ks_o = self.generate_initiator_keys(k)
# 4.5.2 verifying alice's identity
self.verify_identity(form, e, False, "a")
# 4.5.4 generating bob's final session keys
srs = ""
srses = secrets.secrets().retained_secrets(self.conn.name, self.jid.getStripped())
rshashes = [base64.b64decode(rshash) for rshash in form.getField("rshashes").getValues()]
for (secret, verified) in srses:
if self.hmac(self.n_o, secret) in rshashes:
srs = secret
break
# other shared secret
# (we're not using one)
oss = ""
k = crypto.sha256(k + srs + oss)
self.kc_s, self.km_s, self.ks_s = self.generate_responder_keys(k)
self.kc_o, self.km_o, self.ks_o = self.generate_initiator_keys(k)
# 4.5.5
if srs:
srshash = self.hmac(srs, "Shared Retained Secret")
else:
srshash = crypto.random_bytes(32)
x.addChild(node=xmpp.DataField(name="FORM_TYPE", value="urn:xmpp:ssn"))
x.addChild(node=xmpp.DataField(name="nonce", value=base64.b64encode(self.n_o)))
x.addChild(node=xmpp.DataField(name="srshash", value=base64.b64encode(srshash)))
for datafield in self.make_identity(x, self.d):
x.addChild(node=datafield)
init.addChild(node=x)
self.send(response)
self.do_retained_secret(k, srs)
if self.negotiated["logging"] == "mustnot":
self.loggable = False
self.status = "active"
self.enable_encryption = True
if self.control:
self.control.print_esession_details()
def verify_identity(self, form, dh_i, sigmai, i_o):
m_o = base64.b64decode(form["mac"])
id_o = base64.b64decode(form["identity"])
m_o_calculated = self.hmac(self.km_o, crypto.encode_mpi(self.c_o) + id_o)
if m_o_calculated != m_o:
raise exceptions.NegotiationError, "calculated m_%s differs from received m_%s" % (i_o, i_o)
if i_o == "a" and self.sas_algs == "sas28x5":
# we don't need to calculate this if there's a verified retained secret
# (but we do anyways)
self.sas = crypto.sas_28x5(m_o, self.form_s)
if self.negotiated["recv_pubkey"]:
plaintext = self.decrypt(id_o)
parsed = xmpp.Node(node="<node>" + plaintext + "</node>")
if self.negotiated["recv_pubkey"] == "hash":
fingerprint = parsed.getTagData("fingerprint")
# XXX find stored pubkey or terminate session
raise "unimplemented"
else:
if self.negotiated["sign_algs"] == (XmlDsig + "rsa-sha256"):
keyvalue = parsed.getTag(name="RSAKeyValue", namespace=XmlDsig)
n, e = map(
lambda x: crypto.decode_mpi(base64.b64decode(keyvalue.getTagData(x))), ("Modulus", "Exponent")
)
eir_pubkey = RSA.construct((n, long(e)))
pubkey_o = xmpp.c14n.c14n(keyvalue)
else:
# XXX DSA, etc.
raise "unimplemented"
enc_sig = parsed.getTag(name="SignatureValue", namespace=XmlDsig).getData()
signature = (crypto.decode_mpi(base64.b64decode(enc_sig)),)
else:
mac_o = self.decrypt(id_o)
pubkey_o = ""
c7l_form = self.c7lize_mac_id(form)
content = self.n_s + self.n_o + crypto.encode_mpi(dh_i) + pubkey_o
if sigmai:
self.form_o = c7l_form
content += self.form_o
else:
form_o2 = c7l_form
content += self.form_o + form_o2
mac_o_calculated = self.hmac(self.ks_o, content)
if self.negotiated["recv_pubkey"]:
hash = crypto.sha256(mac_o_calculated)
if not eir_pubkey.verify(hash, signature):
raise exceptions.NegotiationError, "public key signature verification failed!"
elif mac_o_calculated != mac_o:
raise exceptions.NegotiationError, "calculated mac_%s differs from received mac_%s" % (i_o, i_o)
def verify_identity(self, form, dh_i, sigmai, i_o):
m_o = base64.b64decode(form['mac'])
id_o = base64.b64decode(form['identity'])
m_o_calculated = self.hmac(self.km_o,
crypto.encode_mpi(self.c_o) + id_o)
if m_o_calculated != m_o:
raise exceptions.NegotiationError, 'calculated m_%s differs from received m_%s' % (
i_o, i_o)
if i_o == 'a' and self.sas_algs == 'sas28x5':
# we don't need to calculate this if there's a verified retained secret
# (but we do anyways)
self.sas = crypto.sas_28x5(m_o, self.form_s)
if self.negotiated['recv_pubkey']:
plaintext = self.decrypt(id_o)
parsed = xmpp.Node(node='<node>' + plaintext + '</node>')
if self.negotiated['recv_pubkey'] == 'hash':
fingerprint = parsed.getTagData('fingerprint')
# XXX find stored pubkey or terminate session
raise 'unimplemented'
else:
if self.negotiated['sign_algs'] == (XmlDsig + 'rsa-sha256'):
keyvalue = parsed.getTag(name='RSAKeyValue',
namespace=XmlDsig)
n, e = map(
lambda x: crypto.decode_mpi(
base64.b64decode(keyvalue.getTagData(x))),
('Modulus', 'Exponent'))
eir_pubkey = RSA.construct((n, long(e)))
pubkey_o = xmpp.c14n.c14n(keyvalue)
else:
# XXX DSA, etc.
raise 'unimplemented'
enc_sig = parsed.getTag(name='SignatureValue',
namespace=XmlDsig).getData()
signature = (crypto.decode_mpi(base64.b64decode(enc_sig)), )
else:
mac_o = self.decrypt(id_o)
pubkey_o = ''
c7l_form = self.c7lize_mac_id(form)
content = self.n_s + self.n_o + crypto.encode_mpi(dh_i) + pubkey_o
if sigmai:
self.form_o = c7l_form
content += self.form_o
else:
form_o2 = c7l_form
content += self.form_o + form_o2
mac_o_calculated = self.hmac(self.ks_o, content)
if self.negotiated['recv_pubkey']:
hash = crypto.sha256(mac_o_calculated)
if not eir_pubkey.verify(hash, signature):
raise exceptions.NegotiationError, 'public key signature verification failed!'
elif mac_o_calculated != mac_o:
raise exceptions.NegotiationError, 'calculated mac_%s differs from received mac_%s' % (
i_o, i_o)
def accept_e2e_bob(self, form):
response = xmpp.Message()
init = response.NT.init
init.setNamespace(xmpp.NS_ESESSION_INIT)
x = xmpp.DataForm(typ='result')
for field in ('nonce', 'dhkeys', 'rshashes', 'identity', 'mac'):
assert field in form.asDict(), "alice's form didn't have a %s field" \
% field
# 4.5.1 generating provisory session keys
e = crypto.decode_mpi(base64.b64decode(form['dhkeys']))
p = dh.primes[self.modp]
if crypto.sha256(crypto.encode_mpi(e)) != self.negotiated['He']:
raise exceptions.NegotiationError, 'SHA256(e) != He'
k = self.get_shared_secret(e, self.y, p)
self.kc_o, self.km_o, self.ks_o = self.generate_initiator_keys(k)
# 4.5.2 verifying alice's identity
self.verify_identity(form, e, False, 'a')
# 4.5.4 generating bob's final session keys
srs = ''
srses = secrets.secrets().retained_secrets(self.conn.name,
self.jid.getStripped())
rshashes = [
base64.b64decode(rshash)
for rshash in form.getField('rshashes').getValues()
]
for (secret, verified) in srses:
if self.hmac(self.n_o, secret) in rshashes:
srs = secret
break
# other shared secret
# (we're not using one)
oss = ''
k = crypto.sha256(k + srs + oss)
self.kc_s, self.km_s, self.ks_s = self.generate_responder_keys(k)
self.kc_o, self.km_o, self.ks_o = self.generate_initiator_keys(k)
# 4.5.5
if srs:
srshash = self.hmac(srs, 'Shared Retained Secret')
else:
srshash = crypto.random_bytes(32)
x.addChild(node=xmpp.DataField(name='FORM_TYPE', value='urn:xmpp:ssn'))
x.addChild(node=xmpp.DataField(name='nonce',
value=base64.b64encode(self.n_o)))
x.addChild(node=xmpp.DataField(name='srshash',
value=base64.b64encode(srshash)))
for datafield in self.make_identity(x, self.d):
x.addChild(node=datafield)
init.addChild(node=x)
self.send(response)
self.do_retained_secret(k, srs)
if self.negotiated['logging'] == 'mustnot':
self.loggable = False
self.status = 'active'
self.enable_encryption = True
if self.control:
self.control.print_esession_details()
def sign(self, string):
if self.negotiated["sign_algs"] == (XmlDsig + "rsa-sha256"):
hash = crypto.sha256(string)
return crypto.encode_mpi(gajim.pubkey.sign(hash, "")[0])
