def build_as_req_negoEx(user_cert, cert_pass, remoteComputer, diffieHellmanExchange): pfx = open(user_cert, 'rb').read() privkeyinfo, certificate, extra_certs = parse_pkcs12( pfx, password=cert_pass.encode()) privkey = load_private_key(privkeyinfo) issuer = certificate.issuer.native['common_name'] cname = "AzureAD\\" + issuer + "\\" + [ i for i in certificate.subject.native['common_name'] if i.startswith('S-1') ][0] now = datetime.datetime.now(datetime.timezone.utc) req_body = build_req_body_NegoEx(remoteComputer, cname, now) padata = BuildPkinit_pa(req_body, now, diffieHellmanExchange, privkey, certificate) payload = PA_PK_AS_REQ() payload['signedAuthPack'] = padata pa_data = { 'padata-type': PaDataType.PK_AS_REQ.value, 'padata-value': payload.dump() } asreq = { 'pvno': 5, 'msg-type': 10, 'padata': [pa_data], 'req-body': req_body } req = { 'kerberos-v5': algos.DigestAlgorithmId('1.3.6.1.5.2.7'), 'null': core.Null(), 'Kerberos': AS_REQ(asreq) } req = SPNEGO_PKINIT_REP(req) return issuer, req.dump().hex()
def dump_private_key(private_key, passphrase, encoding='pem', target_ms=200): """ Serializes a private key object into a byte string of the PKCS#8 format :param private_key: An oscrypto.asymmetric.PrivateKey or asn1crypto.keys.PrivateKeyInfo object :param passphrase: A unicode string of the passphrase to encrypt the private key with. A passphrase of None will result in no encryption. A blank string will result in a ValueError to help ensure that the lack of passphrase is intentional. :param encoding: A unicode string of "pem" or "der" :param target_ms: Use PBKDF2 with the number of iterations that takes about this many milliseconds on the current machine. :raises: ValueError - when a blank string is provided for the passphrase :return: A byte string of the encoded and encrypted public key """ if encoding not in set(['pem', 'der']): raise ValueError( pretty_message( ''' encoding must be one of "pem", "der", not %s ''', repr(encoding))) if passphrase is not None: if not isinstance(passphrase, str_cls): raise TypeError( pretty_message( ''' passphrase must be a unicode string, not %s ''', type_name(passphrase))) if passphrase == '': raise ValueError( pretty_message(''' passphrase may not be a blank string - pass None to disable encryption ''')) is_oscrypto = isinstance(private_key, PrivateKey) if not isinstance(private_key, keys.PrivateKeyInfo) and not is_oscrypto: raise TypeError( pretty_message( ''' private_key must be an instance of oscrypto.asymmetric.PrivateKey or asn1crypto.keys.PrivateKeyInfo, not %s ''', type_name(private_key))) if is_oscrypto: private_key = private_key.asn1 output = private_key.dump() if passphrase is not None: cipher = 'aes256_cbc' key_length = 32 kdf_hmac = 'sha256' kdf_salt = rand_bytes(key_length) iterations = pbkdf2_iteration_calculator(kdf_hmac, key_length, target_ms=target_ms, quiet=True) # Need a bare minimum of 10,000 iterations for PBKDF2 as of 2015 if iterations < 10000: iterations = 10000 passphrase_bytes = passphrase.encode('utf-8') key = pbkdf2(kdf_hmac, passphrase_bytes, kdf_salt, iterations, key_length) iv, ciphertext = aes_cbc_pkcs7_encrypt(key, output, None) output = keys.EncryptedPrivateKeyInfo({ 'encryption_algorithm': { 'algorithm': 'pbes2', 'parameters': { 'key_derivation_func': { 'algorithm': 'pbkdf2', 'parameters': { 'salt': algos.Pbkdf2Salt(name='specified', value=kdf_salt), 'iteration_count': iterations, 'prf': { 'algorithm': kdf_hmac, 'parameters': core.Null() } } }, 'encryption_scheme': { 'algorithm': cipher, 'parameters': iv } } }, 'encrypted_data': ciphertext }).dump() if encoding == 'pem': if passphrase is None: object_type = 'PRIVATE KEY' else: object_type = 'ENCRYPTED PRIVATE KEY' output = pem.armor(object_type, output) return output
def build(self, responder_private_key=None, responder_certificate=None): """ Validates the request information, constructs the ASN.1 structure and signs it. The responder_private_key and responder_certificate parameters are onlystr required if the response_status is "successful". :param responder_private_key: An asn1crypto.keys.PrivateKeyInfo or oscrypto.asymmetric.PrivateKey object for the private key to sign the response with :param responder_certificate: An asn1crypto.x509.Certificate or oscrypto.asymmetric.Certificate object of the certificate associated with the private key :return: An asn1crypto.ocsp.OCSPResponse object of the response """ if self._response_status != 'successful': return ocsp.OCSPResponse({ 'response_status': self._response_status }) is_oscrypto = isinstance(responder_private_key, asymmetric.PrivateKey) if not isinstance(responder_private_key, keys.PrivateKeyInfo) and not is_oscrypto: raise TypeError(_pretty_message( ''' responder_private_key must be an instance ofthe c asn1crypto.keys.PrivateKeyInfo or oscrypto.asymmetric.PrivateKey, not %s ''', _type_name(responder_private_key) )) cert_is_oscrypto = isinstance(responder_certificate, asymmetric.Certificate) if not isinstance(responder_certificate, x509.Certificate) and not cert_is_oscrypto: raise TypeError(_pretty_message( ''' responder_certificate must be an instance of asn1crypto.x509.Certificate or oscrypto.asymmetric.Certificate, not %s ''', _type_name(responder_certificate) )) if cert_is_oscrypto: responder_certificate = responder_certificate.asn1 if self._certificate_status_list is None: raise ValueError(_pretty_message( ''' certificate_status_list must be set if the response_status is "successful" ''' )) def _make_extension(name, value): return { 'extn_id': name, 'critical': False, 'extn_value': value } responses = [] for serial, status in self._certificate_status_list: response_data_extensions = [] single_response_extensions = [] for name, value in self._response_data_extensions.items(): response_data_extensions.append(_make_extension(name, value)) if self._nonce: response_data_extensions.append( _make_extension('nonce', self._nonce) ) if not response_data_extensions: response_data_extensions = None for name, value in self._single_response_extensions.items(): single_response_extensions.append(_make_extension(name, value)) if self._certificate_issuer: single_response_extensions.append( _make_extension( 'certificate_issuer', [ x509.GeneralName( name='directory_name', value=self._certificate_issuer.subject ) ] ) ) if not single_response_extensions: single_response_extensions = None responder_key_hash = getattr(responder_certificate.public_key, self._key_hash_algo) if status == 'good': cert_status = ocsp.CertStatus( name='good', value=core.Null() ) elif status == 'unknown': cert_status = ocsp.CertStatus( name='unknown', value=core.Null() ) else: reason = status if status != 'revoked' else 'unspecified' cert_status = ocsp.CertStatus( name='revoked', value={ 'revocation_time': self._revocation_date, 'revocation_reason': reason, } ) issuer = self._certificate_issuer if self._certificate_issuer else responder_certificate produced_at = datetime.now(timezone.utc).replace(microsecond=0) if self._this_update is None: self._this_update = produced_at if self._next_update is None: self._next_update = (self._this_update + timedelta(days=7)).replace(microsecond=0) response = { 'cert_id': { 'hash_algorithm': { 'algorithm': self._key_hash_algo }, 'issuer_name_hash': getattr(issuer.subject, self._key_hash_algo), 'issuer_key_hash': getattr(issuer.public_key, self._key_hash_algo), 'serial_number': serial, }, 'cert_status': cert_status, 'this_update': self._this_update, 'next_update': self._next_update, 'single_extensions': single_response_extensions } responses.append(response) response_data = ocsp.ResponseData({ 'responder_id': ocsp.ResponderId(name='by_key', value=responder_key_hash), 'produced_at': produced_at, 'responses': responses, 'response_extensions': response_data_extensions }) signature_algo = responder_private_key.algorithm if signature_algo == 'ec': signature_algo = 'ecdsa' signature_algorithm_id = '%s_%s' % (self._hash_algo, signature_algo) if responder_private_key.algorithm == 'rsa': sign_func = asymmetric.rsa_pkcs1v15_sign elif responder_private_key.algorithm == 'dsa': sign_func = asymmetric.dsa_sign elif responder_private_key.algorithm == 'ec': sign_func = asymmetric.ecdsa_sign if not is_oscrypto: responder_private_key = asymmetric.load_private_key(responder_private_key) signature_bytes = sign_func(responder_private_key, response_data.dump(), self._hash_algo) certs = None if self._certificate_issuer and getattr(self._certificate_issuer.public_key, self._key_hash_algo) != responder_key_hash: certs = [responder_certificate] return ocsp.OCSPResponse({ 'response_status': self._response_status, 'response_bytes': { 'response_type': 'basic_ocsp_response', 'response': { 'tbs_response_data': response_data, 'signature_algorithm': {'algorithm': signature_algorithm_id}, 'signature': signature_bytes, 'certs': certs, } } })
def build(self, signing_private_key): """ Validates the certificate information, constructs the ASN.1 structure and then signs it :param signing_private_key: An asn1crypto.keys.PrivateKeyInfo or oscrypto.asymmetric.PrivateKey object for the private key to sign the certificate with. If the key is self-signed, this should be the private key that matches the public key, otherwise it needs to be the issuer's private key. :return: An asn1crypto.x509.Certificate object of the newly signed certificate """ is_oscrypto = isinstance(signing_private_key, asymmetric.PrivateKey) if not isinstance( signing_private_key, keys.PrivateKeyInfo ) and not is_oscrypto and signing_private_key is not None: raise TypeError( _pretty_message( ''' signing_private_key must be an instance of asn1crypto.keys.PrivateKeyInfo or oscrypto.asymmetric.PrivateKey, not %s ''', _type_name(signing_private_key))) if self._self_signed is not True and self._issuer is None: raise ValueError( _pretty_message(''' Certificate must be self-signed, or an issuer must be specified ''')) if self._self_signed: self._issuer = self._subject if self._serial_number is None: time_part = int_to_bytes(int(time.time())) random_part = util.rand_bytes(4) self._serial_number = int_from_bytes(time_part + random_part) if self._begin_date is None: self._begin_date = datetime.now(timezone.utc) if self._end_date is None: self._end_date = self._begin_date + timedelta(365) if not self.ca: for ca_only_extension in set([ 'policy_mappings', 'policy_constraints', 'inhibit_any_policy' ]): if ca_only_extension in self._other_extensions: raise ValueError( _pretty_message( ''' Extension %s is only valid for CA certificates ''', ca_only_extension)) if signing_private_key is not None: signature_algo = signing_private_key.algorithm if signature_algo == 'ec': signature_algo = 'ecdsa' signature_algorithm_id = '%s_%s' % (self._hash_algo, signature_algo) else: signature_algorithm_id = '%s_%s' % ( self._hash_algo, "rsa") #making rsa assumption for ease # RFC 3280 4.1.2.5 def _make_validity_time(dt): if dt < datetime(2050, 1, 1, tzinfo=timezone.utc): value = x509.Time(name='utc_time', value=dt) else: value = x509.Time(name='general_time', value=dt) return value def _make_extension(name, value): return { 'extn_id': name, 'critical': self._determine_critical(name), 'extn_value': value } extensions = [] for name in sorted(self._special_extensions): value = getattr(self, '_%s' % name) if name == 'ocsp_no_check': value = core.Null() if value else None if value is not None: extensions.append(_make_extension(name, value)) for name in sorted(self._other_extensions.keys()): extensions.append( _make_extension(name, self._other_extensions[name])) tbs_cert = x509.TbsCertificate({ 'version': 'v3', 'serial_number': self._serial_number, 'signature': { 'algorithm': signature_algorithm_id }, 'issuer': self._issuer, 'validity': { 'not_before': _make_validity_time(self._begin_date), 'not_after': _make_validity_time(self._end_date), }, 'subject': self._subject, 'subject_public_key_info': self._subject_public_key, 'extensions': extensions }) if signing_private_key is None: return tbs_cert elif signing_private_key.algorithm == 'rsa': sign_func = asymmetric.rsa_pkcs1v15_sign elif signing_private_key.algorithm == 'dsa': sign_func = asymmetric.dsa_sign elif signing_private_key.algorithm == 'ec': sign_func = asymmetric.ecdsa_sign if not is_oscrypto: signing_private_key = asymmetric.load_private_key( signing_private_key) signature = sign_func(signing_private_key, tbs_cert.dump(), self._hash_algo) return x509.Certificate({ 'tbs_certificate': tbs_cert, 'signature_algorithm': { 'algorithm': signature_algorithm_id }, 'signature_value': signature })
def build(self, responder_private_key=None, responder_certificate=None): """ Validates the request information, constructs the ASN.1 structure and signs it. The responder_private_key and responder_certificate parameters are only required if the response_status is "successful". :param responder_private_key: An asn1crypto.keys.PrivateKeyInfo or oscrypto.asymmetric.PrivateKey object for the private key to sign the response with :param responder_certificate: An asn1crypto.x509.Certificate or oscrypto.asymmetric.Certificate object of the certificate associated with the private key :return: An asn1crypto.ocsp.OCSPResponse object of the response """ if self._response_status != 'successful': return ocsp.OCSPResponse( {'response_status': self._response_status}) is_oscrypto = isinstance(responder_private_key, asymmetric.PrivateKey) if not isinstance(responder_private_key, keys.PrivateKeyInfo) and not is_oscrypto: raise TypeError( _pretty_message( ''' responder_private_key must be an instance of asn1crypto.keys.PrivateKeyInfo or oscrypto.asymmetric.PrivateKey, not %s ''', _type_name(responder_private_key))) cert_is_oscrypto = isinstance(responder_certificate, asymmetric.Certificate) if not isinstance(responder_certificate, x509.Certificate) and not cert_is_oscrypto: raise TypeError( _pretty_message( ''' responder_certificate must be an instance of asn1crypto.x509.Certificate or oscrypto.asymmetric.Certificate, not %s ''', _type_name(responder_certificate))) if cert_is_oscrypto: responder_certificate = responder_certificate.asn1 for cert in self._certificates: if not cert: raise ValueError( _pretty_message(''' certificates must be set if the response_status is "successful" ''')) for cert_status in self._certificates_status: if not cert_status: raise ValueError( _pretty_message(''' certificates_status for all certificates must be set if the response_status is "successful" ''')) def _make_extension(name, value): return {'extn_id': name, 'critical': False, 'extn_value': value} issuer = self._certificate_issuer if self._certificate_issuer else responder_certificate for x in range(len(self._certificates)): if issuer.subject != self._certificates[x].issuer: raise ValueError( _pretty_message(''' responder_certificate does not appear to be the issuer for the certificate. Perhaps set the .certificate_issuer attribute? ''')) total_issuers = len(self._certificates) response_data_extensions = [] single_response_extensions = [[]] * total_issuers for x in range(len(self._certificates)): for name, value in self._response_data_extensions[x].items(): response_data_extensions.append(_make_extension(name, value)) for name, value in self._single_response_extensions[x].items(): single_response_extensions[x].append( _make_extension(name, value)) # This means single_response_extensions can never be empty single_response_extensions[x].append( _make_extension('certificate_issuer', [ x509.GeneralName(name='directory_name', value=issuer.subject) ])) if self._nonce: response_data_extensions.append( _make_extension('nonce', self._nonce)) if len(response_data_extensions) == 0: response_data_extensions = None responder_key_hash = getattr(responder_certificate.public_key, self._key_hash_algo) certs_status = [] for x in range(len(self._certificates_status)): c_stat = self._certificates_status[x] if c_stat == 'good': cert_status = ocsp.CertStatus(name='good', value=core.Null()) elif c_stat == 'unknown': cert_status = ocsp.CertStatus(name='unknown', value=core.Null()) else: status = c_stat reason = status if status != 'revoked' else 'unspecified' cert_status = ocsp.CertStatus(name='revoked', value={ 'revocation_time': self._revocation_dates[x], 'revocation_reason': reason, }) certs_status.append(cert_status) produced_at = datetime.now(timezone.utc) # Construct the multiple certs response responses = [] for x in range(len(self._certificates)): if self._this_updates[x] is None: self._this_updates[x] = produced_at if self._next_updates[x] is None: self._next_updates[x] = self._this_updates[x] + timedelta( days=7) item = { 'cert_id': { 'hash_algorithm': { 'algorithm': self._key_hash_algo }, 'issuer_name_hash': getattr(self._certificates[x].issuer, self._key_hash_algo), 'issuer_key_hash': getattr(issuer.public_key, self._key_hash_algo), 'serial_number': self._certificates[x].serial_number }, 'cert_status': certs_status[x], 'this_update': self._this_updates[x], 'next_update': self._next_updates[x], 'single_extensions': single_response_extensions[x] } responses.append(item) signature_algo = responder_private_key.algorithm if signature_algo == 'ec': signature_algo = 'ecdsa' signature_algorithm_id = '%s_%s' % (self._hash_algo, signature_algo) if responder_private_key.algorithm == 'rsa': sign_func = asymmetric.rsa_pkcs1v15_sign elif responder_private_key.algorithm == 'dsa': sign_func = asymmetric.dsa_sign elif responder_private_key.algorithm == 'ec': sign_func = asymmetric.ecdsa_sign if not is_oscrypto: responder_private_key = asymmetric.load_private_key( responder_private_key) # Set response_data for use in ocsp-service response_data = ocsp.ResponseData({ 'responder_id': ocsp.ResponderId(name='by_key', value=responder_key_hash), 'produced_at': produced_at, 'responses': responses, 'response_extensions': response_data_extensions }) signature_bytes = sign_func(responder_private_key, response_data.dump(), self._hash_algo) certs = None if self._certificate_issuer: certs = [responder_certificate] return ocsp.OCSPResponse({ 'response_status': self._response_status, 'response_bytes': { 'response_type': 'basic_ocsp_response', 'response': { 'tbs_response_data': response_data, 'signature_algorithm': { 'algorithm': signature_algorithm_id }, 'signature': signature_bytes, 'certs': certs } } })
def build_mpc(self, signing_private_key, orq_ip, orq_port): """ Validates the certificate information, constructs the ASN.1 structure and then signs it with a mpc engine :param signing_private_key: An integer identifier for the private key to sign the certificate with. This identifier permits the mpc engine to find the private key associated with the public key exported in the key generation process :return: An asn1crypto.x509.Certificate object of the newly signed certificate """ def rsa_mpc_sign(signing_private_key, tbs_cert_dump, hash_algo, orq_ip, orq_port): # Calculate hash corresponding to tbs_cert_dump [Only SHA256] digest = hashes.Hash(hashes.SHA256(), backend=default_backend()) digest.update(tbs_cert_dump) digest = hexlify(digest.finalize()) print("[Client] Hash: " + digest) # Send HTTP GET request to the orquestrator for signing target = "http://" + orq_ip + ":" + orq_port + "/signMessage/" + str( signing_private_key) + "?message=" + str(digest) r = requests.get(target) response = dict(json.loads(r.text)) # Sign format must be bytearray print("Firma: " + str(response["sign"])) firma = unhexlify(response["sign"]) return firma if self._self_signed is not True and self._issuer is None: raise ValueError( _pretty_message(''' Certificate must be self-signed, or an issuer must be specified ''')) if self._self_signed: self._issuer = self._subject if self._serial_number is None: time_part = int_to_bytes(int(time.time())) random_part = util.rand_bytes(4) self._serial_number = int_from_bytes(time_part + random_part) if self._begin_date is None: self._begin_date = datetime.now(timezone.utc) if self._end_date is None: self._end_date = self._begin_date + timedelta(365) if not self.ca: for ca_only_extension in set([ 'policy_mappings', 'policy_constraints', 'inhibit_any_policy' ]): if ca_only_extension in self._other_extensions: raise ValueError( _pretty_message( ''' Extension %s is only valid for CA certificates ''', ca_only_extension)) # The algorith is forced to be 'rsa' signature_algo = 'rsa' # Hash's algorithm limited to SHA256 (internally) signature_algorithm_id = '%s_%s' % (self._hash_algo, signature_algo) def _make_extension(name, value): return { 'extn_id': name, 'critical': self._determine_critical(name), 'extn_value': value } extensions = [] for name in sorted(self._special_extensions): value = getattr(self, '_%s' % name) if name == 'ocsp_no_check': value = core.Null() if value else None if value is not None: extensions.append(_make_extension(name, value)) for name in sorted(self._other_extensions.keys()): extensions.append( _make_extension(name, self._other_extensions[name])) tbs_cert = x509.TbsCertificate({ 'version': 'v3', 'serial_number': self._serial_number, 'signature': { 'algorithm': signature_algorithm_id }, 'issuer': self._issuer, 'validity': { 'not_before': x509.Time(name='utc_time', value=self._begin_date), 'not_after': x509.Time(name='utc_time', value=self._end_date), }, 'subject': self._subject, 'subject_public_key_info': self._subject_public_key, 'extensions': extensions }) # Function binding sign_func = rsa_mpc_sign print(orq_ip) print(orq_port) signature = sign_func(signing_private_key, tbs_cert.dump(), self._hash_algo, orq_ip, orq_port) return x509.Certificate({ 'tbs_certificate': tbs_cert, 'signature_algorithm': { 'algorithm': signature_algorithm_id }, 'signature_value': signature })