# Test the support for SSL and sockets import sys import unittest import unittest.mock from test import support from test.support import socket_helper import socket import select import time import datetime import gc import os import errno import pprint import urllib.request import threading import traceback import asyncore import weakref import platform import sysconfig import functools try: import ctypes except ImportError: ctypes = None ssl = support.import_module("ssl") from ssl import TLSVersion, _TLSContentType, _TLSMessageType Py_DEBUG = hasattr(sys, 'gettotalrefcount') Py_DEBUG_WIN32 = Py_DEBUG and sys.platform == 'win32' PROTOCOLS = sorted(ssl._PROTOCOL_NAMES) HOST = socket_helper.HOST IS_LIBRESSL = ssl.OPENSSL_VERSION.startswith('LibreSSL') IS_OPENSSL_1_1_0 = not IS_LIBRESSL and ssl.OPENSSL_VERSION_INFO >= (1, 1, 0) IS_OPENSSL_1_1_1 = not IS_LIBRESSL and ssl.OPENSSL_VERSION_INFO >= (1, 1, 1) PY_SSL_DEFAULT_CIPHERS = sysconfig.get_config_var('PY_SSL_DEFAULT_CIPHERS') PROTOCOL_TO_TLS_VERSION = {} for proto, ver in ( ("PROTOCOL_SSLv23", "SSLv3"), ("PROTOCOL_TLSv1", "TLSv1"), ("PROTOCOL_TLSv1_1", "TLSv1_1"), ): try: proto = getattr(ssl, proto) ver = getattr(ssl.TLSVersion, ver) except AttributeError: continue PROTOCOL_TO_TLS_VERSION[proto] = ver def data_file(*name): return os.path.join(os.path.dirname(__file__), *name) # The custom key and certificate files used in test_ssl are generated # using Lib/test/make_ssl_certs.py. # Other certificates are simply fetched from the Internet servers they # are meant to authenticate. CERTFILE = data_file("keycert.pem") BYTES_CERTFILE = os.fsencode(CERTFILE) ONLYCERT = data_file("ssl_cert.pem") ONLYKEY = data_file("ssl_key.pem") BYTES_ONLYCERT = os.fsencode(ONLYCERT) BYTES_ONLYKEY = os.fsencode(ONLYKEY) CERTFILE_PROTECTED = data_file("keycert.passwd.pem") ONLYKEY_PROTECTED = data_file("ssl_key.passwd.pem") KEY_PASSWORD = "somepass" CAPATH = data_file("capath") BYTES_CAPATH = os.fsencode(CAPATH) CAFILE_NEURONIO = data_file("capath", "4e1295a3.0") CAFILE_CACERT = data_file("capath", "5ed36f99.0") CERTFILE_INFO = { 'issuer': ((('countryName', 'XY'),), (('localityName', 'Castle Anthrax'),), (('organizationName', 'Python Software Foundation'),), (('commonName', 'localhost'),)), 'notAfter': 'Aug 26 14:23:15 2028 GMT', 'notBefore': 'Aug 29 14:23:15 2018 GMT', 'serialNumber': '98A7CF88C74A32ED', 'subject': ((('countryName', 'XY'),), (('localityName', 'Castle Anthrax'),), (('organizationName', 'Python Software Foundation'),), (('commonName', 'localhost'),)), 'subjectAltName': (('DNS', 'localhost'),), 'version': 3 } # empty CRL CRLFILE = data_file("revocation.crl") # Two keys and certs signed by the same CA (for SNI tests) SIGNED_CERTFILE = data_file("keycert3.pem") SIGNED_CERTFILE_HOSTNAME = 'localhost' SIGNED_CERTFILE_INFO = { 'OCSP': ('http://testca.pythontest.net/testca/ocsp/',), 'caIssuers': ('http://testca.pythontest.net/testca/pycacert.cer',), 'crlDistributionPoints': ('http://testca.pythontest.net/testca/revocation.crl',), 'issuer': ((('countryName', 'XY'),), (('organizationName', 'Python Software Foundation CA'),), (('commonName', 'our-ca-server'),)), 'notAfter': 'Jul 7 14:23:16 2028 GMT', 'notBefore': 'Aug 29 14:23:16 2018 GMT', 'serialNumber': 'CB2D80995A69525C', 'subject': ((('countryName', 'XY'),), (('localityName', 'Castle Anthrax'),), (('organizationName', 'Python Software Foundation'),), (('commonName', 'localhost'),)), 'subjectAltName': (('DNS', 'localhost'),), 'version': 3 } SIGNED_CERTFILE2 = data_file("keycert4.pem") SIGNED_CERTFILE2_HOSTNAME = 'fakehostname' SIGNED_CERTFILE_ECC = data_file("keycertecc.pem") SIGNED_CERTFILE_ECC_HOSTNAME = 'localhost-ecc' # Same certificate as pycacert.pem, but without extra text in file SIGNING_CA = data_file("capath", "ceff1710.0") # cert with all kinds of subject alt names ALLSANFILE = data_file("allsans.pem") IDNSANSFILE = data_file("idnsans.pem") REMOTE_HOST = "self-signed.pythontest.net" EMPTYCERT = data_file("nullcert.pem") BADCERT = data_file("badcert.pem") NONEXISTINGCERT = data_file("XXXnonexisting.pem") BADKEY = data_file("badkey.pem") NOKIACERT = data_file("nokia.pem") NULLBYTECERT = data_file("nullbytecert.pem") TALOS_INVALID_CRLDP = data_file("talos-2019-0758.pem") DHFILE = data_file("ffdh3072.pem") BYTES_DHFILE = os.fsencode(DHFILE) # Not defined in all versions of OpenSSL OP_NO_COMPRESSION = getattr(ssl, "OP_NO_COMPRESSION", 0) OP_SINGLE_DH_USE = getattr(ssl, "OP_SINGLE_DH_USE", 0) OP_SINGLE_ECDH_USE = getattr(ssl, "OP_SINGLE_ECDH_USE", 0) OP_CIPHER_SERVER_PREFERENCE = getattr(ssl, "OP_CIPHER_SERVER_PREFERENCE", 0) OP_ENABLE_MIDDLEBOX_COMPAT = getattr(ssl, "OP_ENABLE_MIDDLEBOX_COMPAT", 0) def has_tls_protocol(protocol): """Check if a TLS protocol is available and enabled :param protocol: enum ssl._SSLMethod member or name :return: bool """ if isinstance(protocol, str): assert protocol.startswith('PROTOCOL_') protocol = getattr(ssl, protocol, None) if protocol is None: return False if protocol in { ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLS_SERVER, ssl.PROTOCOL_TLS_CLIENT }: # auto-negotiate protocols are always available return True name = protocol.name return has_tls_version(name[len('PROTOCOL_'):]) @functools.lru_cache def has_tls_version(version): """Check if a TLS/SSL version is enabled :param version: TLS version name or ssl.TLSVersion member :return: bool """ if version == "SSLv2": # never supported and not even in TLSVersion enum return False if isinstance(version, str): version = ssl.TLSVersion.__members__[version] # check compile time flags like ssl.HAS_TLSv1_2 if not getattr(ssl, f'HAS_{version.name}'): return False # check runtime and dynamic crypto policy settings. A TLS version may # be compiled in but disabled by a policy or config option. ctx = ssl.SSLContext() if ( hasattr(ctx, 'minimum_version') and ctx.minimum_version != ssl.TLSVersion.MINIMUM_SUPPORTED and version < ctx.minimum_version ): return False if ( hasattr(ctx, 'maximum_version') and ctx.maximum_version != ssl.TLSVersion.MAXIMUM_SUPPORTED and version > ctx.maximum_version ): return False return True def requires_tls_version(version): """Decorator to skip tests when a required TLS version is not available :param version: TLS version name or ssl.TLSVersion member :return: """ def decorator(func): @functools.wraps(func) def wrapper(*args, **kw): if not has_tls_version(version): raise unittest.SkipTest(f"{version} is not available.") else: return func(*args, **kw) return wrapper return decorator requires_minimum_version = unittest.skipUnless( hasattr(ssl.SSLContext, 'minimum_version'), "required OpenSSL >= 1.1.0g" ) def handle_error(prefix): exc_format = ' '.join(traceback.format_exception(*sys.exc_info())) if support.verbose: sys.stdout.write(prefix + exc_format) def can_clear_options(): # 0.9.8m or higher return ssl._OPENSSL_API_VERSION >= (0, 9, 8, 13, 15) def no_sslv2_implies_sslv3_hello(): # 0.9.7h or higher return ssl.OPENSSL_VERSION_INFO >= (0, 9, 7, 8, 15) def have_verify_flags(): # 0.9.8 or higher return ssl.OPENSSL_VERSION_INFO >= (0, 9, 8, 0, 15) def _have_secp_curves(): if not ssl.HAS_ECDH: return False ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) try: ctx.set_ecdh_curve("secp384r1") except ValueError: return False else: return True HAVE_SECP_CURVES = _have_secp_curves() def utc_offset(): #NOTE: ignore issues like #1647654 # local time = utc time + utc offset if time.daylight and time.localtime().tm_isdst > 0: return -time.altzone # seconds return -time.timezone def asn1time(cert_time): # Some versions of OpenSSL ignore seconds, see #18207 # 0.9.8.i if ssl._OPENSSL_API_VERSION == (0, 9, 8, 9, 15): fmt = "%b %d %H:%M:%S %Y GMT" dt = datetime.datetime.strptime(cert_time, fmt) dt = dt.replace(second=0) cert_time = dt.strftime(fmt) # %d adds leading zero but ASN1_TIME_print() uses leading space if cert_time[4] == "0": cert_time = cert_time[:4] + " " + cert_time[5:] return cert_time needs_sni = unittest.skipUnless(ssl.HAS_SNI, "SNI support needed for this test") def test_wrap_socket(sock, ssl_version=ssl.PROTOCOL_TLS, *, cert_reqs=ssl.CERT_NONE, ca_certs=None, ciphers=None, certfile=None, keyfile=None, **kwargs): context = ssl.SSLContext(ssl_version) if cert_reqs is not None: if cert_reqs == ssl.CERT_NONE: context.check_hostname = False context.verify_mode = cert_reqs if ca_certs is not None: context.load_verify_locations(ca_certs) if certfile is not None or keyfile is not None: context.load_cert_chain(certfile, keyfile) if ciphers is not None: context.set_ciphers(ciphers) return context.wrap_socket(sock, **kwargs) def testing_context(server_cert=SIGNED_CERTFILE): """Create context client_context, server_context, hostname = testing_context() """ if server_cert == SIGNED_CERTFILE: hostname = SIGNED_CERTFILE_HOSTNAME elif server_cert == SIGNED_CERTFILE2: hostname = SIGNED_CERTFILE2_HOSTNAME else: raise ValueError(server_cert) client_context = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) client_context.load_verify_locations(SIGNING_CA) server_context = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) server_context.load_cert_chain(server_cert) server_context.load_verify_locations(SIGNING_CA) return client_context, server_context, hostname class BasicSocketTests(unittest.TestCase): def test_constants(self): ssl.CERT_NONE ssl.CERT_OPTIONAL ssl.CERT_REQUIRED ssl.OP_CIPHER_SERVER_PREFERENCE ssl.OP_SINGLE_DH_USE if ssl.HAS_ECDH: ssl.OP_SINGLE_ECDH_USE if ssl.OPENSSL_VERSION_INFO >= (1, 0): ssl.OP_NO_COMPRESSION self.assertIn(ssl.HAS_SNI, {True, False}) self.assertIn(ssl.HAS_ECDH, {True, False}) ssl.OP_NO_SSLv2 ssl.OP_NO_SSLv3 ssl.OP_NO_TLSv1 ssl.OP_NO_TLSv1_3 if ssl.OPENSSL_VERSION_INFO >= (1, 0, 1): ssl.OP_NO_TLSv1_1 ssl.OP_NO_TLSv1_2 self.assertEqual(ssl.PROTOCOL_TLS, ssl.PROTOCOL_SSLv23) def test_private_init(self): with self.assertRaisesRegex(TypeError, "public constructor"): with socket.socket() as s: ssl.SSLSocket(s) def test_str_for_enums(self): # Make sure that the PROTOCOL_* constants have enum-like string # reprs. proto = ssl.PROTOCOL_TLS self.assertEqual(str(proto), '_SSLMethod.PROTOCOL_TLS') ctx = ssl.SSLContext(proto) self.assertIs(ctx.protocol, proto) def test_random(self): v = ssl.RAND_status() if support.verbose: sys.stdout.write("\n RAND_status is %d (%s)\n" % (v, (v and "sufficient randomness") or "insufficient randomness")) data, is_cryptographic = ssl.RAND_pseudo_bytes(16) self.assertEqual(len(data), 16) self.assertEqual(is_cryptographic, v == 1) if v: data = ssl.RAND_bytes(16) self.assertEqual(len(data), 16) else: self.assertRaises(ssl.SSLError, ssl.RAND_bytes, 16) # negative num is invalid self.assertRaises(ValueError, ssl.RAND_bytes, -5) self.assertRaises(ValueError, ssl.RAND_pseudo_bytes, -5) if hasattr(ssl, 'RAND_egd'): self.assertRaises(TypeError, ssl.RAND_egd, 1) self.assertRaises(TypeError, ssl.RAND_egd, 'foo', 1) ssl.RAND_add("this is a random string", 75.0) ssl.RAND_add(b"this is a random bytes object", 75.0) ssl.RAND_add(bytearray(b"this is a random bytearray object"), 75.0) @unittest.skipUnless(os.name == 'posix', 'requires posix') def test_random_fork(self): status = ssl.RAND_status() if not status: self.fail("OpenSSL's PRNG has insufficient randomness") rfd, wfd = os.pipe() pid = os.fork() if pid == 0: try: os.close(rfd) child_random = ssl.RAND_pseudo_bytes(16)[0] self.assertEqual(len(child_random), 16) os.write(wfd, child_random) os.close(wfd) except BaseException: os._exit(1) else: os._exit(0) else: os.close(wfd) self.addCleanup(os.close, rfd) support.wait_process(pid, exitcode=0) child_random = os.read(rfd, 16) self.assertEqual(len(child_random), 16) parent_random = ssl.RAND_pseudo_bytes(16)[0] self.assertEqual(len(parent_random), 16) self.assertNotEqual(child_random, parent_random) maxDiff = None def test_parse_cert(self): # note that this uses an 'unofficial' function in _ssl.c, # provided solely for this test, to exercise the certificate # parsing code self.assertEqual( ssl._ssl._test_decode_cert(CERTFILE), CERTFILE_INFO ) self.assertEqual( ssl._ssl._test_decode_cert(SIGNED_CERTFILE), SIGNED_CERTFILE_INFO ) # Issue #13034: the subjectAltName in some certificates # (notably projects.developer.nokia.com:443) wasn't parsed p = ssl._ssl._test_decode_cert(NOKIACERT) if support.verbose: sys.stdout.write("\n" + pprint.pformat(p) + "\n") self.assertEqual(p['subjectAltName'], (('DNS', 'projects.developer.nokia.com'), ('DNS', 'projects.forum.nokia.com')) ) # extra OCSP and AIA fields self.assertEqual(p['OCSP'], ('http://ocsp.verisign.com',)) self.assertEqual(p['caIssuers'], ('http://SVRIntl-G3-aia.verisign.com/SVRIntlG3.cer',)) self.assertEqual(p['crlDistributionPoints'], ('http://SVRIntl-G3-crl.verisign.com/SVRIntlG3.crl',)) def test_parse_cert_CVE_2019_5010(self): p = ssl._ssl._test_decode_cert(TALOS_INVALID_CRLDP) if support.verbose: sys.stdout.write("\n" + pprint.pformat(p) + "\n") self.assertEqual( p, { 'issuer': ( (('countryName', 'UK'),), (('commonName', 'cody-ca'),)), 'notAfter': 'Jun 14 18:00:58 2028 GMT', 'notBefore': 'Jun 18 18:00:58 2018 GMT', 'serialNumber': '02', 'subject': ((('countryName', 'UK'),), (('commonName', 'codenomicon-vm-2.test.lal.cisco.com'),)), 'subjectAltName': ( ('DNS', 'codenomicon-vm-2.test.lal.cisco.com'),), 'version': 3 } ) def test_parse_cert_CVE_2013_4238(self): p = ssl._ssl._test_decode_cert(NULLBYTECERT) if support.verbose: sys.stdout.write("\n" + pprint.pformat(p) + "\n") subject = ((('countryName', 'US'),), (('stateOrProvinceName', 'Oregon'),), (('localityName', 'Beaverton'),), (('organizationName', 'Python Software Foundation'),), (('organizationalUnitName', 'Python Core Development'),), (('commonName', 'null.python.org\x00example.org'),), (('emailAddress', 'python-dev@python.org'),)) self.assertEqual(p['subject'], subject) self.assertEqual(p['issuer'], subject) if ssl._OPENSSL_API_VERSION >= (0, 9, 8): san = (('DNS', 'altnull.python.org\x00example.com'), ('email', 'null@python.org\x00user@example.org'), ('URI', 'http://null.python.org\x00http://example.org'), ('IP Address', '192.0.2.1'), ('IP Address', '2001:DB8:0:0:0:0:0:1')) else: # OpenSSL 0.9.7 doesn't support IPv6 addresses in subjectAltName san = (('DNS', 'altnull.python.org\x00example.com'), ('email', 'null@python.org\x00user@example.org'), ('URI', 'http://null.python.org\x00http://example.org'), ('IP Address', '192.0.2.1'), ('IP Address', '')) self.assertEqual(p['subjectAltName'], san) def test_parse_all_sans(self): p = ssl._ssl._test_decode_cert(ALLSANFILE) self.assertEqual(p['subjectAltName'], ( ('DNS', 'allsans'), ('othername', ''), ('othername', ''), ('email', 'user@example.org'), ('DNS', 'www.example.org'), ('DirName', ((('countryName', 'XY'),), (('localityName', 'Castle Anthrax'),), (('organizationName', 'Python Software Foundation'),), (('commonName', 'dirname example'),))), ('URI', 'https://www.python.org/'), ('IP Address', '127.0.0.1'), ('IP Address', '0:0:0:0:0:0:0:1'), ('Registered ID', '1.2.3.4.5') ) ) def test_DER_to_PEM(self): with open(CAFILE_CACERT, 'r') as f: pem = f.read() d1 = ssl.PEM_cert_to_DER_cert(pem) p2 = ssl.DER_cert_to_PEM_cert(d1) d2 = ssl.PEM_cert_to_DER_cert(p2) self.assertEqual(d1, d2) if not p2.startswith(ssl.PEM_HEADER + '\n'): self.fail("DER-to-PEM didn't include correct header:\n%r\n" % p2) if not p2.endswith('\n' + ssl.PEM_FOOTER + '\n'): self.fail("DER-to-PEM didn't include correct footer:\n%r\n" % p2) def test_openssl_version(self): n = ssl.OPENSSL_VERSION_NUMBER t = ssl.OPENSSL_VERSION_INFO s = ssl.OPENSSL_VERSION self.assertIsInstance(n, int) self.assertIsInstance(t, tuple) self.assertIsInstance(s, str) # Some sanity checks follow # >= 0.9 self.assertGreaterEqual(n, 0x900000) # < 4.0 self.assertLess(n, 0x40000000) major, minor, fix, patch, status = t self.assertGreaterEqual(major, 1) self.assertLess(major, 4) self.assertGreaterEqual(minor, 0) self.assertLess(minor, 256) self.assertGreaterEqual(fix, 0) self.assertLess(fix, 256) self.assertGreaterEqual(patch, 0) self.assertLessEqual(patch, 63) self.assertGreaterEqual(status, 0) self.assertLessEqual(status, 15) # Version string as returned by {Open,Libre}SSL, the format might change if IS_LIBRESSL: self.assertTrue(s.startswith("LibreSSL {:d}".format(major)), (s, t, hex(n))) else: self.assertTrue(s.startswith("OpenSSL {:d}.{:d}.{:d}".format(major, minor, fix)), (s, t, hex(n))) @support.cpython_only def test_refcycle(self): # Issue #7943: an SSL object doesn't create reference cycles with # itself. s = socket.socket(socket.AF_INET) ss = test_wrap_socket(s) wr = weakref.ref(ss) with support.check_warnings(("", ResourceWarning)): del ss self.assertEqual(wr(), None) def test_wrapped_unconnected(self): # Methods on an unconnected SSLSocket propagate the original # OSError raise by the underlying socket object. s = socket.socket(socket.AF_INET) with test_wrap_socket(s) as ss: self.assertRaises(OSError, ss.recv, 1) self.assertRaises(OSError, ss.recv_into, bytearray(b'x')) self.assertRaises(OSError, ss.recvfrom, 1) self.assertRaises(OSError, ss.recvfrom_into, bytearray(b'x'), 1) self.assertRaises(OSError, ss.send, b'x') self.assertRaises(OSError, ss.sendto, b'x', ('0.0.0.0', 0)) self.assertRaises(NotImplementedError, ss.dup) self.assertRaises(NotImplementedError, ss.sendmsg, [b'x'], (), 0, ('0.0.0.0', 0)) self.assertRaises(NotImplementedError, ss.recvmsg, 100) self.assertRaises(NotImplementedError, ss.recvmsg_into, [bytearray(100)]) def test_timeout(self): # Issue #8524: when creating an SSL socket, the timeout of the # original socket should be retained. for timeout in (None, 0.0, 5.0): s = socket.socket(socket.AF_INET) s.settimeout(timeout) with test_wrap_socket(s) as ss: self.assertEqual(timeout, ss.gettimeout()) def test_errors_sslwrap(self): sock = socket.socket() self.assertRaisesRegex(ValueError, "certfile must be specified", ssl.wrap_socket, sock, keyfile=CERTFILE) self.assertRaisesRegex(ValueError, "certfile must be specified for server-side operations", ssl.wrap_socket, sock, server_side=True) self.assertRaisesRegex(ValueError, "certfile must be specified for server-side operations", ssl.wrap_socket, sock, server_side=True, certfile="") with ssl.wrap_socket(sock, server_side=True, certfile=CERTFILE) as s: self.assertRaisesRegex(ValueError, "can't connect in server-side mode", s.connect, (HOST, 8080)) with self.assertRaises(OSError) as cm: with socket.socket() as sock: ssl.wrap_socket(sock, certfile=NONEXISTINGCERT) self.assertEqual(cm.exception.errno, errno.ENOENT) with self.assertRaises(OSError) as cm: with socket.socket() as sock: ssl.wrap_socket(sock, certfile=CERTFILE, keyfile=NONEXISTINGCERT) self.assertEqual(cm.exception.errno, errno.ENOENT) with self.assertRaises(OSError) as cm: with socket.socket() as sock: ssl.wrap_socket(sock, certfile=NONEXISTINGCERT, keyfile=NONEXISTINGCERT) self.assertEqual(cm.exception.errno, errno.ENOENT) def bad_cert_test(self, certfile): """Check that trying to use the given client certificate fails""" certfile = os.path.join(os.path.dirname(__file__) or os.curdir, certfile) sock = socket.socket() self.addCleanup(sock.close) with self.assertRaises(ssl.SSLError): test_wrap_socket(sock, certfile=certfile) def test_empty_cert(self): """Wrapping with an empty cert file""" self.bad_cert_test("nullcert.pem") def test_malformed_cert(self): """Wrapping with a badly formatted certificate (syntax error)""" self.bad_cert_test("badcert.pem") def test_malformed_key(self): """Wrapping with a badly formatted key (syntax error)""" self.bad_cert_test("badkey.pem") def test_match_hostname(self): def ok(cert, hostname): ssl.match_hostname(cert, hostname) def fail(cert, hostname): self.assertRaises(ssl.CertificateError, ssl.match_hostname, cert, hostname) # -- Hostname matching -- cert = {'subject': ((('commonName', 'example.com'),),)} ok(cert, 'example.com') ok(cert, 'ExAmple.cOm') fail(cert, 'www.example.com') fail(cert, '.example.com') fail(cert, 'example.org') fail(cert, 'exampleXcom') cert = {'subject': ((('commonName', '*.a.com'),),)} ok(cert, 'foo.a.com') fail(cert, 'bar.foo.a.com') fail(cert, 'a.com') fail(cert, 'Xa.com') fail(cert, '.a.com') # only match wildcards when they are the only thing # in left-most segment cert = {'subject': ((('commonName', 'f*.com'),),)} fail(cert, 'foo.com') fail(cert, 'f.com') fail(cert, 'bar.com') fail(cert, 'foo.a.com') fail(cert, 'bar.foo.com') # NULL bytes are bad, CVE-2013-4073 cert = {'subject': ((('commonName', 'null.python.org\x00example.org'),),)} ok(cert, 'null.python.org\x00example.org') # or raise an error? fail(cert, 'example.org') fail(cert, 'null.python.org') # error cases with wildcards cert = {'subject': ((('commonName', '*.*.a.com'),),)} fail(cert, 'bar.foo.a.com') fail(cert, 'a.com') fail(cert, 'Xa.com') fail(cert, '.a.com') cert = {'subject': ((('commonName', 'a.*.com'),),)} fail(cert, 'a.foo.com') fail(cert, 'a..com') fail(cert, 'a.com') # wildcard doesn't match IDNA prefix 'xn--' idna = 'püthon.python.org'.encode("idna").decode("ascii") cert = {'subject': ((('commonName', idna),),)} ok(cert, idna) cert = {'subject': ((('commonName', 'x*.python.org'),),)} fail(cert, idna) cert = {'subject': ((('commonName', 'xn--p*.python.org'),),)} fail(cert, idna) # wildcard in first fragment and IDNA A-labels in sequent fragments # are supported. idna = 'www*.pythön.org'.encode("idna").decode("ascii") cert = {'subject': ((('commonName', idna),),)} fail(cert, 'www.pythön.org'.encode("idna").decode("ascii")) fail(cert, 'www1.pythön.org'.encode("idna").decode("ascii")) fail(cert, 'ftp.pythön.org'.encode("idna").decode("ascii")) fail(cert, 'pythön.org'.encode("idna").decode("ascii")) # Slightly fake real-world example cert = {'notAfter': 'Jun 26 21:41:46 2011 GMT', 'subject': ((('commonName', 'linuxfrz.org'),),), 'subjectAltName': (('DNS', 'linuxfr.org'), ('DNS', 'linuxfr.com'), ('othername', ''))} ok(cert, 'linuxfr.org') ok(cert, 'linuxfr.com') # Not a "DNS" entry fail(cert, '') # When there is a subjectAltName, commonName isn't used fail(cert, 'linuxfrz.org') # A pristine real-world example cert = {'notAfter': 'Dec 18 23:59:59 2011 GMT', 'subject': ((('countryName', 'US'),), (('stateOrProvinceName', 'California'),), (('localityName', 'Mountain View'),), (('organizationName', 'Google Inc'),), (('commonName', 'mail.google.com'),))} ok(cert, 'mail.google.com') fail(cert, 'gmail.com') # Only commonName is considered fail(cert, 'California') # -- IPv4 matching -- cert = {'subject': ((('commonName', 'example.com'),),), 'subjectAltName': (('DNS', 'example.com'), ('IP Address', '10.11.12.13'), ('IP Address', '14.15.16.17'), ('IP Address', '127.0.0.1'))} ok(cert, '10.11.12.13') ok(cert, '14.15.16.17') # socket.inet_ntoa(socket.inet_aton('127.1')) == '127.0.0.1' fail(cert, '127.1') fail(cert, '14.15.16.17 ') fail(cert, '14.15.16.17 extra data') fail(cert, '14.15.16.18') fail(cert, 'example.net') # -- IPv6 matching -- if socket_helper.IPV6_ENABLED: cert = {'subject': ((('commonName', 'example.com'),),), 'subjectAltName': ( ('DNS', 'example.com'), ('IP Address', '2001:0:0:0:0:0:0:CAFE\n'), ('IP Address', '2003:0:0:0:0:0:0:BABA\n'))} ok(cert, '2001::cafe') ok(cert, '2003::baba') fail(cert, '2003::baba ') fail(cert, '2003::baba extra data') fail(cert, '2003::bebe') fail(cert, 'example.net') # -- Miscellaneous -- # Neither commonName nor subjectAltName cert = {'notAfter': 'Dec 18 23:59:59 2011 GMT', 'subject': ((('countryName', 'US'),), (('stateOrProvinceName', 'California'),), (('localityName', 'Mountain View'),), (('organizationName', 'Google Inc'),))} fail(cert, 'mail.google.com') # No DNS entry in subjectAltName but a commonName cert = {'notAfter': 'Dec 18 23:59:59 2099 GMT', 'subject': ((('countryName', 'US'),), (('stateOrProvinceName', 'California'),), (('localityName', 'Mountain View'),), (('commonName', 'mail.google.com'),)), 'subjectAltName': (('othername', 'blabla'), )} ok(cert, 'mail.google.com') # No DNS entry subjectAltName and no commonName cert = {'notAfter': 'Dec 18 23:59:59 2099 GMT', 'subject': ((('countryName', 'US'),), (('stateOrProvinceName', 'California'),), (('localityName', 'Mountain View'),), (('organizationName', 'Google Inc'),)), 'subjectAltName': (('othername', 'blabla'),)} fail(cert, 'google.com') # Empty cert / no cert self.assertRaises(ValueError, ssl.match_hostname, None, 'example.com') self.assertRaises(ValueError, ssl.match_hostname, {}, 'example.com') # Issue #17980: avoid denials of service by refusing more than one # wildcard per fragment. cert = {'subject': ((('commonName', 'a*b.example.com'),),)} with self.assertRaisesRegex( ssl.CertificateError, "partial wildcards in leftmost label are not supported"): ssl.match_hostname(cert, 'axxb.example.com') cert = {'subject': ((('commonName', 'www.*.example.com'),),)} with self.assertRaisesRegex( ssl.CertificateError, "wildcard can only be present in the leftmost label"): ssl.match_hostname(cert, 'www.sub.example.com') cert = {'subject': ((('commonName', 'a*b*.example.com'),),)} with self.assertRaisesRegex( ssl.CertificateError, "too many wildcards"): ssl.match_hostname(cert, 'axxbxxc.example.com') cert = {'subject': ((('commonName', '*'),),)} with self.assertRaisesRegex( ssl.CertificateError, "sole wildcard without additional labels are not support"): ssl.match_hostname(cert, 'host') cert = {'subject': ((('commonName', '*.com'),),)} with self.assertRaisesRegex( ssl.CertificateError, r"hostname 'com' doesn't match '\*.com'"): ssl.match_hostname(cert, 'com') # extra checks for _inet_paton() for invalid in ['1', '', '1.2.3', '256.0.0.1', '127.0.0.1/24']: with self.assertRaises(ValueError): ssl._inet_paton(invalid) for ipaddr in ['127.0.0.1', '192.168.0.1']: self.assertTrue(ssl._inet_paton(ipaddr)) if socket_helper.IPV6_ENABLED: for ipaddr in ['::1', '2001:db8:85a3::8a2e:370:7334']: self.assertTrue(ssl._inet_paton(ipaddr)) def test_server_side(self): # server_hostname doesn't work for server sockets ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) with socket.socket() as sock: self.assertRaises(ValueError, ctx.wrap_socket, sock, True, server_hostname="some.hostname") def test_unknown_channel_binding(self): # should raise ValueError for unknown type s = socket.create_server(('127.0.0.1', 0)) c = socket.socket(socket.AF_INET) c.connect(s.getsockname()) with test_wrap_socket(c, do_handshake_on_connect=False) as ss: with self.assertRaises(ValueError): ss.get_channel_binding("unknown-type") s.close() @unittest.skipUnless("tls-unique" in ssl.CHANNEL_BINDING_TYPES, "'tls-unique' channel binding not available") def test_tls_unique_channel_binding(self): # unconnected should return None for known type s = socket.socket(socket.AF_INET) with test_wrap_socket(s) as ss: self.assertIsNone(ss.get_channel_binding("tls-unique")) # the same for server-side s = socket.socket(socket.AF_INET) with test_wrap_socket(s, server_side=True, certfile=CERTFILE) as ss: self.assertIsNone(ss.get_channel_binding("tls-unique")) def test_dealloc_warn(self): ss = test_wrap_socket(socket.socket(socket.AF_INET)) r = repr(ss) with self.assertWarns(ResourceWarning) as cm: ss = None support.gc_collect() self.assertIn(r, str(cm.warning.args[0])) def test_get_default_verify_paths(self): paths = ssl.get_default_verify_paths() self.assertEqual(len(paths), 6) self.assertIsInstance(paths, ssl.DefaultVerifyPaths) with support.EnvironmentVarGuard() as env: env["SSL_CERT_DIR"] = CAPATH env["SSL_CERT_FILE"] = CERTFILE paths = ssl.get_default_verify_paths() self.assertEqual(paths.cafile, CERTFILE) self.assertEqual(paths.capath, CAPATH) @unittest.skipUnless(sys.platform == "win32", "Windows specific") def test_enum_certificates(self): self.assertTrue(ssl.enum_certificates("CA")) self.assertTrue(ssl.enum_certificates("ROOT")) self.assertRaises(TypeError, ssl.enum_certificates) self.assertRaises(WindowsError, ssl.enum_certificates, "") trust_oids = set() for storename in ("CA", "ROOT"): store = ssl.enum_certificates(storename) self.assertIsInstance(store, list) for element in store: self.assertIsInstance(element, tuple) self.assertEqual(len(element), 3) cert, enc, trust = element self.assertIsInstance(cert, bytes) self.assertIn(enc, {"x509_asn", "pkcs_7_asn"}) self.assertIsInstance(trust, (frozenset, set, bool)) if isinstance(trust, (frozenset, set)): trust_oids.update(trust) serverAuth = "1.3.6.1.5.5.7.3.1" self.assertIn(serverAuth, trust_oids) @unittest.skipUnless(sys.platform == "win32", "Windows specific") def test_enum_crls(self): self.assertTrue(ssl.enum_crls("CA")) self.assertRaises(TypeError, ssl.enum_crls) self.assertRaises(WindowsError, ssl.enum_crls, "") crls = ssl.enum_crls("CA") self.assertIsInstance(crls, list) for element in crls: self.assertIsInstance(element, tuple) self.assertEqual(len(element), 2) self.assertIsInstance(element[0], bytes) self.assertIn(element[1], {"x509_asn", "pkcs_7_asn"}) def test_asn1object(self): expected = (129, 'serverAuth', 'TLS Web Server Authentication', '1.3.6.1.5.5.7.3.1') val = ssl._ASN1Object('1.3.6.1.5.5.7.3.1') self.assertEqual(val, expected) self.assertEqual(val.nid, 129) self.assertEqual(val.shortname, 'serverAuth') self.assertEqual(val.longname, 'TLS Web Server Authentication') self.assertEqual(val.oid, '1.3.6.1.5.5.7.3.1') self.assertIsInstance(val, ssl._ASN1Object) self.assertRaises(ValueError, ssl._ASN1Object, 'serverAuth') val = ssl._ASN1Object.fromnid(129) self.assertEqual(val, expected) self.assertIsInstance(val, ssl._ASN1Object) self.assertRaises(ValueError, ssl._ASN1Object.fromnid, -1) with self.assertRaisesRegex(ValueError, "unknown NID 100000"): ssl._ASN1Object.fromnid(100000) for i in range(1000): try: obj = ssl._ASN1Object.fromnid(i) except ValueError: pass else: self.assertIsInstance(obj.nid, int) self.assertIsInstance(obj.shortname, str) self.assertIsInstance(obj.longname, str) self.assertIsInstance(obj.oid, (str, type(None))) val = ssl._ASN1Object.fromname('TLS Web Server Authentication') self.assertEqual(val, expected) self.assertIsInstance(val, ssl._ASN1Object) self.assertEqual(ssl._ASN1Object.fromname('serverAuth'), expected) self.assertEqual(ssl._ASN1Object.fromname('1.3.6.1.5.5.7.3.1'), expected) with self.assertRaisesRegex(ValueError, "unknown object 'serverauth'"): ssl._ASN1Object.fromname('serverauth') def test_purpose_enum(self): val = ssl._ASN1Object('1.3.6.1.5.5.7.3.1') self.assertIsInstance(ssl.Purpose.SERVER_AUTH, ssl._ASN1Object) self.assertEqual(ssl.Purpose.SERVER_AUTH, val) self.assertEqual(ssl.Purpose.SERVER_AUTH.nid, 129) self.assertEqual(ssl.Purpose.SERVER_AUTH.shortname, 'serverAuth') self.assertEqual(ssl.Purpose.SERVER_AUTH.oid, '1.3.6.1.5.5.7.3.1') val = ssl._ASN1Object('1.3.6.1.5.5.7.3.2') self.assertIsInstance(ssl.Purpose.CLIENT_AUTH, ssl._ASN1Object) self.assertEqual(ssl.Purpose.CLIENT_AUTH, val) self.assertEqual(ssl.Purpose.CLIENT_AUTH.nid, 130) self.assertEqual(ssl.Purpose.CLIENT_AUTH.shortname, 'clientAuth') self.assertEqual(ssl.Purpose.CLIENT_AUTH.oid, '1.3.6.1.5.5.7.3.2') def test_unsupported_dtls(self): s = socket.socket(socket.AF_INET, socket.SOCK_DGRAM) self.addCleanup(s.close) with self.assertRaises(NotImplementedError) as cx: test_wrap_socket(s, cert_reqs=ssl.CERT_NONE) self.assertEqual(str(cx.exception), "only stream sockets are supported") ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) with self.assertRaises(NotImplementedError) as cx: ctx.wrap_socket(s) self.assertEqual(str(cx.exception), "only stream sockets are supported") def cert_time_ok(self, timestring, timestamp): self.assertEqual(ssl.cert_time_to_seconds(timestring), timestamp) def cert_time_fail(self, timestring): with self.assertRaises(ValueError): ssl.cert_time_to_seconds(timestring) @unittest.skipUnless(utc_offset(), 'local time needs to be different from UTC') def test_cert_time_to_seconds_timezone(self): # Issue #19940: ssl.cert_time_to_seconds() returns wrong # results if local timezone is not UTC self.cert_time_ok("May 9 00:00:00 2007 GMT", 1178668800.0) self.cert_time_ok("Jan 5 09:34:43 2018 GMT", 1515144883.0) def test_cert_time_to_seconds(self): timestring = "Jan 5 09:34:43 2018 GMT" ts = 1515144883.0 self.cert_time_ok(timestring, ts) # accept keyword parameter, assert its name self.assertEqual(ssl.cert_time_to_seconds(cert_time=timestring), ts) # accept both %e and %d (space or zero generated by strftime) self.cert_time_ok("Jan 05 09:34:43 2018 GMT", ts) # case-insensitive self.cert_time_ok("JaN 5 09:34:43 2018 GmT", ts) self.cert_time_fail("Jan 5 09:34 2018 GMT") # no seconds self.cert_time_fail("Jan 5 09:34:43 2018") # no GMT self.cert_time_fail("Jan 5 09:34:43 2018 UTC") # not GMT timezone self.cert_time_fail("Jan 35 09:34:43 2018 GMT") # invalid day self.cert_time_fail("Jon 5 09:34:43 2018 GMT") # invalid month self.cert_time_fail("Jan 5 24:00:00 2018 GMT") # invalid hour self.cert_time_fail("Jan 5 09:60:43 2018 GMT") # invalid minute newyear_ts = 1230768000.0 # leap seconds self.cert_time_ok("Dec 31 23:59:60 2008 GMT", newyear_ts) # same timestamp self.cert_time_ok("Jan 1 00:00:00 2009 GMT", newyear_ts) self.cert_time_ok("Jan 5 09:34:59 2018 GMT", 1515144899) # allow 60th second (even if it is not a leap second) self.cert_time_ok("Jan 5 09:34:60 2018 GMT", 1515144900) # allow 2nd leap second for compatibility with time.strptime() self.cert_time_ok("Jan 5 09:34:61 2018 GMT", 1515144901) self.cert_time_fail("Jan 5 09:34:62 2018 GMT") # invalid seconds # no special treatment for the special value: # 99991231235959Z (rfc 5280) self.cert_time_ok("Dec 31 23:59:59 9999 GMT", 253402300799.0) @support.run_with_locale('LC_ALL', '') def test_cert_time_to_seconds_locale(self): # `cert_time_to_seconds()` should be locale independent def local_february_name(): return time.strftime('%b', (1, 2, 3, 4, 5, 6, 0, 0, 0)) if local_february_name().lower() == 'feb': self.skipTest("locale-specific month name needs to be " "different from C locale") # locale-independent self.cert_time_ok("Feb 9 00:00:00 2007 GMT", 1170979200.0) self.cert_time_fail(local_february_name() + " 9 00:00:00 2007 GMT") def test_connect_ex_error(self): server = socket.socket(socket.AF_INET) self.addCleanup(server.close) port = socket_helper.bind_port(server) # Reserve port but don't listen s = test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_REQUIRED) self.addCleanup(s.close) rc = s.connect_ex((HOST, port)) # Issue #19919: Windows machines or VMs hosted on Windows # machines sometimes return EWOULDBLOCK. errors = ( errno.ECONNREFUSED, errno.EHOSTUNREACH, errno.ETIMEDOUT, errno.EWOULDBLOCK, ) self.assertIn(rc, errors) class ContextTests(unittest.TestCase): def test_constructor(self): for protocol in PROTOCOLS: ssl.SSLContext(protocol) ctx = ssl.SSLContext() self.assertEqual(ctx.protocol, ssl.PROTOCOL_TLS) self.assertRaises(ValueError, ssl.SSLContext, -1) self.assertRaises(ValueError, ssl.SSLContext, 42) def test_protocol(self): for proto in PROTOCOLS: ctx = ssl.SSLContext(proto) self.assertEqual(ctx.protocol, proto) def test_ciphers(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.set_ciphers("ALL") ctx.set_ciphers("DEFAULT") with self.assertRaisesRegex(ssl.SSLError, "No cipher can be selected"): ctx.set_ciphers("^$:,;?*'dorothyx") @unittest.skipUnless(PY_SSL_DEFAULT_CIPHERS == 1, "Test applies only to Python default ciphers") def test_python_ciphers(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ciphers = ctx.get_ciphers() for suite in ciphers: name = suite['name'] self.assertNotIn("PSK", name) self.assertNotIn("SRP", name) self.assertNotIn("MD5", name) self.assertNotIn("RC4", name) self.assertNotIn("3DES", name) @unittest.skipIf(ssl.OPENSSL_VERSION_INFO < (1, 0, 2, 0, 0), 'OpenSSL too old') def test_get_ciphers(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.set_ciphers('AESGCM') names = set(d['name'] for d in ctx.get_ciphers()) self.assertIn('AES256-GCM-SHA384', names) self.assertIn('AES128-GCM-SHA256', names) def test_options(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) # OP_ALL | OP_NO_SSLv2 | OP_NO_SSLv3 is the default value default = (ssl.OP_ALL | ssl.OP_NO_SSLv2 | ssl.OP_NO_SSLv3) # SSLContext also enables these by default default |= (OP_NO_COMPRESSION | OP_CIPHER_SERVER_PREFERENCE | OP_SINGLE_DH_USE | OP_SINGLE_ECDH_USE | OP_ENABLE_MIDDLEBOX_COMPAT) self.assertEqual(default, ctx.options) ctx.options |= ssl.OP_NO_TLSv1 self.assertEqual(default | ssl.OP_NO_TLSv1, ctx.options) if can_clear_options(): ctx.options = (ctx.options & ~ssl.OP_NO_TLSv1) self.assertEqual(default, ctx.options) ctx.options = 0 # Ubuntu has OP_NO_SSLv3 forced on by default self.assertEqual(0, ctx.options & ~ssl.OP_NO_SSLv3) else: with self.assertRaises(ValueError): ctx.options = 0 def test_verify_mode_protocol(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) # Default value self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) ctx.verify_mode = ssl.CERT_OPTIONAL self.assertEqual(ctx.verify_mode, ssl.CERT_OPTIONAL) ctx.verify_mode = ssl.CERT_REQUIRED self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) ctx.verify_mode = ssl.CERT_NONE self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) with self.assertRaises(TypeError): ctx.verify_mode = None with self.assertRaises(ValueError): ctx.verify_mode = 42 ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) self.assertFalse(ctx.check_hostname) ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) self.assertTrue(ctx.check_hostname) def test_hostname_checks_common_name(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertTrue(ctx.hostname_checks_common_name) if ssl.HAS_NEVER_CHECK_COMMON_NAME: ctx.hostname_checks_common_name = True self.assertTrue(ctx.hostname_checks_common_name) ctx.hostname_checks_common_name = False self.assertFalse(ctx.hostname_checks_common_name) ctx.hostname_checks_common_name = True self.assertTrue(ctx.hostname_checks_common_name) else: with self.assertRaises(AttributeError): ctx.hostname_checks_common_name = True @requires_minimum_version @unittest.skipIf(IS_LIBRESSL, "see bpo-34001") def test_min_max_version(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) # OpenSSL default is MINIMUM_SUPPORTED, however some vendors like # Fedora override the setting to TLS 1.0. minimum_range = { # stock OpenSSL ssl.TLSVersion.MINIMUM_SUPPORTED, # Fedora 29 uses TLS 1.0 by default ssl.TLSVersion.TLSv1, # RHEL 8 uses TLS 1.2 by default ssl.TLSVersion.TLSv1_2 } maximum_range = { # stock OpenSSL ssl.TLSVersion.MAXIMUM_SUPPORTED, # Fedora 32 uses TLS 1.3 by default ssl.TLSVersion.TLSv1_3 } self.assertIn( ctx.minimum_version, minimum_range ) self.assertIn( ctx.maximum_version, maximum_range ) ctx.minimum_version = ssl.TLSVersion.TLSv1_1 ctx.maximum_version = ssl.TLSVersion.TLSv1_2 self.assertEqual( ctx.minimum_version, ssl.TLSVersion.TLSv1_1 ) self.assertEqual( ctx.maximum_version, ssl.TLSVersion.TLSv1_2 ) ctx.minimum_version = ssl.TLSVersion.MINIMUM_SUPPORTED ctx.maximum_version = ssl.TLSVersion.TLSv1 self.assertEqual( ctx.minimum_version, ssl.TLSVersion.MINIMUM_SUPPORTED ) self.assertEqual( ctx.maximum_version, ssl.TLSVersion.TLSv1 ) ctx.maximum_version = ssl.TLSVersion.MAXIMUM_SUPPORTED self.assertEqual( ctx.maximum_version, ssl.TLSVersion.MAXIMUM_SUPPORTED ) ctx.maximum_version = ssl.TLSVersion.MINIMUM_SUPPORTED self.assertIn( ctx.maximum_version, {ssl.TLSVersion.TLSv1, ssl.TLSVersion.SSLv3} ) ctx.minimum_version = ssl.TLSVersion.MAXIMUM_SUPPORTED self.assertIn( ctx.minimum_version, {ssl.TLSVersion.TLSv1_2, ssl.TLSVersion.TLSv1_3} ) with self.assertRaises(ValueError): ctx.minimum_version = 42 ctx = ssl.SSLContext(ssl.PROTOCOL_TLSv1_1) self.assertIn( ctx.minimum_version, minimum_range ) self.assertEqual( ctx.maximum_version, ssl.TLSVersion.MAXIMUM_SUPPORTED ) with self.assertRaises(ValueError): ctx.minimum_version = ssl.TLSVersion.MINIMUM_SUPPORTED with self.assertRaises(ValueError): ctx.maximum_version = ssl.TLSVersion.TLSv1 @unittest.skipUnless(have_verify_flags(), "verify_flags need OpenSSL > 0.9.8") def test_verify_flags(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) # default value tf = getattr(ssl, "VERIFY_X509_TRUSTED_FIRST", 0) self.assertEqual(ctx.verify_flags, ssl.VERIFY_DEFAULT | tf) ctx.verify_flags = ssl.VERIFY_CRL_CHECK_LEAF self.assertEqual(ctx.verify_flags, ssl.VERIFY_CRL_CHECK_LEAF) ctx.verify_flags = ssl.VERIFY_CRL_CHECK_CHAIN self.assertEqual(ctx.verify_flags, ssl.VERIFY_CRL_CHECK_CHAIN) ctx.verify_flags = ssl.VERIFY_DEFAULT self.assertEqual(ctx.verify_flags, ssl.VERIFY_DEFAULT) # supports any value ctx.verify_flags = ssl.VERIFY_CRL_CHECK_LEAF | ssl.VERIFY_X509_STRICT self.assertEqual(ctx.verify_flags, ssl.VERIFY_CRL_CHECK_LEAF | ssl.VERIFY_X509_STRICT) with self.assertRaises(TypeError): ctx.verify_flags = None def test_load_cert_chain(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) # Combined key and cert in a single file ctx.load_cert_chain(CERTFILE, keyfile=None) ctx.load_cert_chain(CERTFILE, keyfile=CERTFILE) self.assertRaises(TypeError, ctx.load_cert_chain, keyfile=CERTFILE) with self.assertRaises(OSError) as cm: ctx.load_cert_chain(NONEXISTINGCERT) self.assertEqual(cm.exception.errno, errno.ENOENT) with self.assertRaisesRegex(ssl.SSLError, "PEM lib"): ctx.load_cert_chain(BADCERT) with self.assertRaisesRegex(ssl.SSLError, "PEM lib"): ctx.load_cert_chain(EMPTYCERT) # Separate key and cert ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) ctx.load_cert_chain(ONLYCERT, ONLYKEY) ctx.load_cert_chain(certfile=ONLYCERT, keyfile=ONLYKEY) ctx.load_cert_chain(certfile=BYTES_ONLYCERT, keyfile=BYTES_ONLYKEY) with self.assertRaisesRegex(ssl.SSLError, "PEM lib"): ctx.load_cert_chain(ONLYCERT) with self.assertRaisesRegex(ssl.SSLError, "PEM lib"): ctx.load_cert_chain(ONLYKEY) with self.assertRaisesRegex(ssl.SSLError, "PEM lib"): ctx.load_cert_chain(certfile=ONLYKEY, keyfile=ONLYCERT) # Mismatching key and cert ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) with self.assertRaisesRegex(ssl.SSLError, "key values mismatch"): ctx.load_cert_chain(CAFILE_CACERT, ONLYKEY) # Password protected key and cert ctx.load_cert_chain(CERTFILE_PROTECTED, password=KEY_PASSWORD) ctx.load_cert_chain(CERTFILE_PROTECTED, password=KEY_PASSWORD.encode()) ctx.load_cert_chain(CERTFILE_PROTECTED, password=bytearray(KEY_PASSWORD.encode())) ctx.load_cert_chain(ONLYCERT, ONLYKEY_PROTECTED, KEY_PASSWORD) ctx.load_cert_chain(ONLYCERT, ONLYKEY_PROTECTED, KEY_PASSWORD.encode()) ctx.load_cert_chain(ONLYCERT, ONLYKEY_PROTECTED, bytearray(KEY_PASSWORD.encode())) with self.assertRaisesRegex(TypeError, "should be a string"): ctx.load_cert_chain(CERTFILE_PROTECTED, password=True) with self.assertRaises(ssl.SSLError): ctx.load_cert_chain(CERTFILE_PROTECTED, password="badpass") with self.assertRaisesRegex(ValueError, "cannot be longer"): # openssl has a fixed limit on the password buffer. # PEM_BUFSIZE is generally set to 1kb. # Return a string larger than this. ctx.load_cert_chain(CERTFILE_PROTECTED, password=b'a' * 102400) # Password callback def getpass_unicode(): return KEY_PASSWORD def getpass_bytes(): return KEY_PASSWORD.encode() def getpass_bytearray(): return bytearray(KEY_PASSWORD.encode()) def getpass_badpass(): return "badpass" def getpass_huge(): return b'a' * (1024 * 1024) def getpass_bad_type(): return 9 def getpass_exception(): raise Exception('getpass error') class GetPassCallable: def __call__(self): return KEY_PASSWORD def getpass(self): return KEY_PASSWORD ctx.load_cert_chain(CERTFILE_PROTECTED, password=getpass_unicode) ctx.load_cert_chain(CERTFILE_PROTECTED, password=getpass_bytes) ctx.load_cert_chain(CERTFILE_PROTECTED, password=getpass_bytearray) ctx.load_cert_chain(CERTFILE_PROTECTED, password=GetPassCallable()) ctx.load_cert_chain(CERTFILE_PROTECTED, password=GetPassCallable().getpass) with self.assertRaises(ssl.SSLError): ctx.load_cert_chain(CERTFILE_PROTECTED, password=getpass_badpass) with self.assertRaisesRegex(ValueError, "cannot be longer"): ctx.load_cert_chain(CERTFILE_PROTECTED, password=getpass_huge) with self.assertRaisesRegex(TypeError, "must return a string"): ctx.load_cert_chain(CERTFILE_PROTECTED, password=getpass_bad_type) with self.assertRaisesRegex(Exception, "getpass error"): ctx.load_cert_chain(CERTFILE_PROTECTED, password=getpass_exception) # Make sure the password function isn't called if it isn't needed ctx.load_cert_chain(CERTFILE, password=getpass_exception) def test_load_verify_locations(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) ctx.load_verify_locations(CERTFILE) ctx.load_verify_locations(cafile=CERTFILE, capath=None) ctx.load_verify_locations(BYTES_CERTFILE) ctx.load_verify_locations(cafile=BYTES_CERTFILE, capath=None) self.assertRaises(TypeError, ctx.load_verify_locations) self.assertRaises(TypeError, ctx.load_verify_locations, None, None, None) with self.assertRaises(OSError) as cm: ctx.load_verify_locations(NONEXISTINGCERT) self.assertEqual(cm.exception.errno, errno.ENOENT) with self.assertRaisesRegex(ssl.SSLError, "PEM lib"): ctx.load_verify_locations(BADCERT) ctx.load_verify_locations(CERTFILE, CAPATH) ctx.load_verify_locations(CERTFILE, capath=BYTES_CAPATH) # Issue #10989: crash if the second argument type is invalid self.assertRaises(TypeError, ctx.load_verify_locations, None, True) def test_load_verify_cadata(self): # test cadata with open(CAFILE_CACERT) as f: cacert_pem = f.read() cacert_der = ssl.PEM_cert_to_DER_cert(cacert_pem) with open(CAFILE_NEURONIO) as f: neuronio_pem = f.read() neuronio_der = ssl.PEM_cert_to_DER_cert(neuronio_pem) # test PEM ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 0) ctx.load_verify_locations(cadata=cacert_pem) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 1) ctx.load_verify_locations(cadata=neuronio_pem) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 2) # cert already in hash table ctx.load_verify_locations(cadata=neuronio_pem) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 2) # combined ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) combined = "\n".join((cacert_pem, neuronio_pem)) ctx.load_verify_locations(cadata=combined) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 2) # with junk around the certs ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) combined = ["head", cacert_pem, "other", neuronio_pem, "again", neuronio_pem, "tail"] ctx.load_verify_locations(cadata="\n".join(combined)) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 2) # test DER ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.load_verify_locations(cadata=cacert_der) ctx.load_verify_locations(cadata=neuronio_der) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 2) # cert already in hash table ctx.load_verify_locations(cadata=cacert_der) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 2) # combined ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) combined = b"".join((cacert_der, neuronio_der)) ctx.load_verify_locations(cadata=combined) self.assertEqual(ctx.cert_store_stats()["x509_ca"], 2) # error cases ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertRaises(TypeError, ctx.load_verify_locations, cadata=object) with self.assertRaisesRegex(ssl.SSLError, "no start line"): ctx.load_verify_locations(cadata="broken") with self.assertRaisesRegex(ssl.SSLError, "not enough data"): ctx.load_verify_locations(cadata=b"broken") @unittest.skipIf(Py_DEBUG_WIN32, "Avoid mixing debug/release CRT on Windows") def test_load_dh_params(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) ctx.load_dh_params(DHFILE) if os.name != 'nt': ctx.load_dh_params(BYTES_DHFILE) self.assertRaises(TypeError, ctx.load_dh_params) self.assertRaises(TypeError, ctx.load_dh_params, None) with self.assertRaises(FileNotFoundError) as cm: ctx.load_dh_params(NONEXISTINGCERT) self.assertEqual(cm.exception.errno, errno.ENOENT) with self.assertRaises(ssl.SSLError) as cm: ctx.load_dh_params(CERTFILE) def test_session_stats(self): for proto in PROTOCOLS: ctx = ssl.SSLContext(proto) self.assertEqual(ctx.session_stats(), { 'number': 0, 'connect': 0, 'connect_good': 0, 'connect_renegotiate': 0, 'accept': 0, 'accept_good': 0, 'accept_renegotiate': 0, 'hits': 0, 'misses': 0, 'timeouts': 0, 'cache_full': 0, }) def test_set_default_verify_paths(self): # There's not much we can do to test that it acts as expected, # so just check it doesn't crash or raise an exception. ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.set_default_verify_paths() @unittest.skipUnless(ssl.HAS_ECDH, "ECDH disabled on this OpenSSL build") def test_set_ecdh_curve(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) ctx.set_ecdh_curve("prime256v1") ctx.set_ecdh_curve(b"prime256v1") self.assertRaises(TypeError, ctx.set_ecdh_curve) self.assertRaises(TypeError, ctx.set_ecdh_curve, None) self.assertRaises(ValueError, ctx.set_ecdh_curve, "foo") self.assertRaises(ValueError, ctx.set_ecdh_curve, b"foo") @needs_sni def test_sni_callback(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) # set_servername_callback expects a callable, or None self.assertRaises(TypeError, ctx.set_servername_callback) self.assertRaises(TypeError, ctx.set_servername_callback, 4) self.assertRaises(TypeError, ctx.set_servername_callback, "") self.assertRaises(TypeError, ctx.set_servername_callback, ctx) def dummycallback(sock, servername, ctx): pass ctx.set_servername_callback(None) ctx.set_servername_callback(dummycallback) @needs_sni def test_sni_callback_refcycle(self): # Reference cycles through the servername callback are detected # and cleared. ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) def dummycallback(sock, servername, ctx, cycle=ctx): pass ctx.set_servername_callback(dummycallback) wr = weakref.ref(ctx) del ctx, dummycallback gc.collect() self.assertIs(wr(), None) def test_cert_store_stats(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertEqual(ctx.cert_store_stats(), {'x509_ca': 0, 'crl': 0, 'x509': 0}) ctx.load_cert_chain(CERTFILE) self.assertEqual(ctx.cert_store_stats(), {'x509_ca': 0, 'crl': 0, 'x509': 0}) ctx.load_verify_locations(CERTFILE) self.assertEqual(ctx.cert_store_stats(), {'x509_ca': 0, 'crl': 0, 'x509': 1}) ctx.load_verify_locations(CAFILE_CACERT) self.assertEqual(ctx.cert_store_stats(), {'x509_ca': 1, 'crl': 0, 'x509': 2}) def test_get_ca_certs(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertEqual(ctx.get_ca_certs(), []) # CERTFILE is not flagged as X509v3 Basic Constraints: CA:TRUE ctx.load_verify_locations(CERTFILE) self.assertEqual(ctx.get_ca_certs(), []) # but CAFILE_CACERT is a CA cert ctx.load_verify_locations(CAFILE_CACERT) self.assertEqual(ctx.get_ca_certs(), [{'issuer': ((('organizationName', 'Root CA'),), (('organizationalUnitName', 'http://www.cacert.org'),), (('commonName', 'CA Cert Signing Authority'),), (('emailAddress', 'support@cacert.org'),)), 'notAfter': asn1time('Mar 29 12:29:49 2033 GMT'), 'notBefore': asn1time('Mar 30 12:29:49 2003 GMT'), 'serialNumber': '00', 'crlDistributionPoints': ('https://www.cacert.org/revoke.crl',), 'subject': ((('organizationName', 'Root CA'),), (('organizationalUnitName', 'http://www.cacert.org'),), (('commonName', 'CA Cert Signing Authority'),), (('emailAddress', 'support@cacert.org'),)), 'version': 3}]) with open(CAFILE_CACERT) as f: pem = f.read() der = ssl.PEM_cert_to_DER_cert(pem) self.assertEqual(ctx.get_ca_certs(True), [der]) def test_load_default_certs(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.load_default_certs() ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.load_default_certs(ssl.Purpose.SERVER_AUTH) ctx.load_default_certs() ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.load_default_certs(ssl.Purpose.CLIENT_AUTH) ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertRaises(TypeError, ctx.load_default_certs, None) self.assertRaises(TypeError, ctx.load_default_certs, 'SERVER_AUTH') @unittest.skipIf(sys.platform == "win32", "not-Windows specific") @unittest.skipIf(IS_LIBRESSL, "LibreSSL doesn't support env vars") def test_load_default_certs_env(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) with support.EnvironmentVarGuard() as env: env["SSL_CERT_DIR"] = CAPATH env["SSL_CERT_FILE"] = CERTFILE ctx.load_default_certs() self.assertEqual(ctx.cert_store_stats(), {"crl": 0, "x509": 1, "x509_ca": 0}) @unittest.skipUnless(sys.platform == "win32", "Windows specific") @unittest.skipIf(hasattr(sys, "gettotalrefcount"), "Debug build does not share environment between CRTs") def test_load_default_certs_env_windows(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.load_default_certs() stats = ctx.cert_store_stats() ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) with support.EnvironmentVarGuard() as env: env["SSL_CERT_DIR"] = CAPATH env["SSL_CERT_FILE"] = CERTFILE ctx.load_default_certs() stats["x509"] += 1 self.assertEqual(ctx.cert_store_stats(), stats) def _assert_context_options(self, ctx): self.assertEqual(ctx.options & ssl.OP_NO_SSLv2, ssl.OP_NO_SSLv2) if OP_NO_COMPRESSION != 0: self.assertEqual(ctx.options & OP_NO_COMPRESSION, OP_NO_COMPRESSION) if OP_SINGLE_DH_USE != 0: self.assertEqual(ctx.options & OP_SINGLE_DH_USE, OP_SINGLE_DH_USE) if OP_SINGLE_ECDH_USE != 0: self.assertEqual(ctx.options & OP_SINGLE_ECDH_USE, OP_SINGLE_ECDH_USE) if OP_CIPHER_SERVER_PREFERENCE != 0: self.assertEqual(ctx.options & OP_CIPHER_SERVER_PREFERENCE, OP_CIPHER_SERVER_PREFERENCE) def test_create_default_context(self): ctx = ssl.create_default_context() self.assertEqual(ctx.protocol, ssl.PROTOCOL_TLS) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) self.assertTrue(ctx.check_hostname) self._assert_context_options(ctx) with open(SIGNING_CA) as f: cadata = f.read() ctx = ssl.create_default_context(cafile=SIGNING_CA, capath=CAPATH, cadata=cadata) self.assertEqual(ctx.protocol, ssl.PROTOCOL_TLS) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) self._assert_context_options(ctx) ctx = ssl.create_default_context(ssl.Purpose.CLIENT_AUTH) self.assertEqual(ctx.protocol, ssl.PROTOCOL_TLS) self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) self._assert_context_options(ctx) def test__create_stdlib_context(self): ctx = ssl._create_stdlib_context() self.assertEqual(ctx.protocol, ssl.PROTOCOL_TLS) self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) self.assertFalse(ctx.check_hostname) self._assert_context_options(ctx) ctx = ssl._create_stdlib_context(ssl.PROTOCOL_TLSv1) self.assertEqual(ctx.protocol, ssl.PROTOCOL_TLSv1) self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) self._assert_context_options(ctx) ctx = ssl._create_stdlib_context(ssl.PROTOCOL_TLSv1, cert_reqs=ssl.CERT_REQUIRED, check_hostname=True) self.assertEqual(ctx.protocol, ssl.PROTOCOL_TLSv1) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) self.assertTrue(ctx.check_hostname) self._assert_context_options(ctx) ctx = ssl._create_stdlib_context(purpose=ssl.Purpose.CLIENT_AUTH) self.assertEqual(ctx.protocol, ssl.PROTOCOL_TLS) self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) self._assert_context_options(ctx) def test_check_hostname(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) self.assertFalse(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) # Auto set CERT_REQUIRED ctx.check_hostname = True self.assertTrue(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) ctx.check_hostname = False ctx.verify_mode = ssl.CERT_REQUIRED self.assertFalse(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) # Changing verify_mode does not affect check_hostname ctx.check_hostname = False ctx.verify_mode = ssl.CERT_NONE ctx.check_hostname = False self.assertFalse(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) # Auto set ctx.check_hostname = True self.assertTrue(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) ctx.check_hostname = False ctx.verify_mode = ssl.CERT_OPTIONAL ctx.check_hostname = False self.assertFalse(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_OPTIONAL) # keep CERT_OPTIONAL ctx.check_hostname = True self.assertTrue(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_OPTIONAL) # Cannot set CERT_NONE with check_hostname enabled with self.assertRaises(ValueError): ctx.verify_mode = ssl.CERT_NONE ctx.check_hostname = False self.assertFalse(ctx.check_hostname) ctx.verify_mode = ssl.CERT_NONE self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) def test_context_client_server(self): # PROTOCOL_TLS_CLIENT has sane defaults ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertTrue(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) # PROTOCOL_TLS_SERVER has different but also sane defaults ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) self.assertFalse(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_NONE) def test_context_custom_class(self): class MySSLSocket(ssl.SSLSocket): pass class MySSLObject(ssl.SSLObject): pass ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) ctx.sslsocket_class = MySSLSocket ctx.sslobject_class = MySSLObject with ctx.wrap_socket(socket.socket(), server_side=True) as sock: self.assertIsInstance(sock, MySSLSocket) obj = ctx.wrap_bio(ssl.MemoryBIO(), ssl.MemoryBIO()) self.assertIsInstance(obj, MySSLObject) @unittest.skipUnless(IS_OPENSSL_1_1_1, "Test requires OpenSSL 1.1.1") def test_num_tickest(self): ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) self.assertEqual(ctx.num_tickets, 2) ctx.num_tickets = 1 self.assertEqual(ctx.num_tickets, 1) ctx.num_tickets = 0 self.assertEqual(ctx.num_tickets, 0) with self.assertRaises(ValueError): ctx.num_tickets = -1 with self.assertRaises(TypeError): ctx.num_tickets = None ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertEqual(ctx.num_tickets, 2) with self.assertRaises(ValueError): ctx.num_tickets = 1 class SSLErrorTests(unittest.TestCase): def test_str(self): # The str() of a SSLError doesn't include the errno e = ssl.SSLError(1, "foo") self.assertEqual(str(e), "foo") self.assertEqual(e.errno, 1) # Same for a subclass e = ssl.SSLZeroReturnError(1, "foo") self.assertEqual(str(e), "foo") self.assertEqual(e.errno, 1) @unittest.skipIf(Py_DEBUG_WIN32, "Avoid mixing debug/release CRT on Windows") def test_lib_reason(self): # Test the library and reason attributes ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) with self.assertRaises(ssl.SSLError) as cm: ctx.load_dh_params(CERTFILE) self.assertEqual(cm.exception.library, 'PEM') self.assertEqual(cm.exception.reason, 'NO_START_LINE') s = str(cm.exception) self.assertTrue(s.startswith("[PEM: NO_START_LINE] no start line"), s) def test_subclass(self): # Check that the appropriate SSLError subclass is raised # (this only tests one of them) ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.check_hostname = False ctx.verify_mode = ssl.CERT_NONE with socket.create_server(("127.0.0.1", 0)) as s: c = socket.create_connection(s.getsockname()) c.setblocking(False) with ctx.wrap_socket(c, False, do_handshake_on_connect=False) as c: with self.assertRaises(ssl.SSLWantReadError) as cm: c.do_handshake() s = str(cm.exception) self.assertTrue(s.startswith("The operation did not complete (read)"), s) # For compatibility self.assertEqual(cm.exception.errno, ssl.SSL_ERROR_WANT_READ) def test_bad_server_hostname(self): ctx = ssl.create_default_context() with self.assertRaises(ValueError): ctx.wrap_bio(ssl.MemoryBIO(), ssl.MemoryBIO(), server_hostname="") with self.assertRaises(ValueError): ctx.wrap_bio(ssl.MemoryBIO(), ssl.MemoryBIO(), server_hostname=".example.org") with self.assertRaises(TypeError): ctx.wrap_bio(ssl.MemoryBIO(), ssl.MemoryBIO(), server_hostname="example.org\x00evil.com") class MemoryBIOTests(unittest.TestCase): def test_read_write(self): bio = ssl.MemoryBIO() bio.write(b'foo') self.assertEqual(bio.read(), b'foo') self.assertEqual(bio.read(), b'') bio.write(b'foo') bio.write(b'bar') self.assertEqual(bio.read(), b'foobar') self.assertEqual(bio.read(), b'') bio.write(b'baz') self.assertEqual(bio.read(2), b'ba') self.assertEqual(bio.read(1), b'z') self.assertEqual(bio.read(1), b'') def test_eof(self): bio = ssl.MemoryBIO() self.assertFalse(bio.eof) self.assertEqual(bio.read(), b'') self.assertFalse(bio.eof) bio.write(b'foo') self.assertFalse(bio.eof) bio.write_eof() self.assertFalse(bio.eof) self.assertEqual(bio.read(2), b'fo') self.assertFalse(bio.eof) self.assertEqual(bio.read(1), b'o') self.assertTrue(bio.eof) self.assertEqual(bio.read(), b'') self.assertTrue(bio.eof) def test_pending(self): bio = ssl.MemoryBIO() self.assertEqual(bio.pending, 0) bio.write(b'foo') self.assertEqual(bio.pending, 3) for i in range(3): bio.read(1) self.assertEqual(bio.pending, 3-i-1) for i in range(3): bio.write(b'x') self.assertEqual(bio.pending, i+1) bio.read() self.assertEqual(bio.pending, 0) def test_buffer_types(self): bio = ssl.MemoryBIO() bio.write(b'foo') self.assertEqual(bio.read(), b'foo') bio.write(bytearray(b'bar')) self.assertEqual(bio.read(), b'bar') bio.write(memoryview(b'baz')) self.assertEqual(bio.read(), b'baz') def test_error_types(self): bio = ssl.MemoryBIO() self.assertRaises(TypeError, bio.write, 'foo') self.assertRaises(TypeError, bio.write, None) self.assertRaises(TypeError, bio.write, True) self.assertRaises(TypeError, bio.write, 1) class SSLObjectTests(unittest.TestCase): def test_private_init(self): bio = ssl.MemoryBIO() with self.assertRaisesRegex(TypeError, "public constructor"): ssl.SSLObject(bio, bio) def test_unwrap(self): client_ctx, server_ctx, hostname = testing_context() c_in = ssl.MemoryBIO() c_out = ssl.MemoryBIO() s_in = ssl.MemoryBIO() s_out = ssl.MemoryBIO() client = client_ctx.wrap_bio(c_in, c_out, server_hostname=hostname) server = server_ctx.wrap_bio(s_in, s_out, server_side=True) # Loop on the handshake for a bit to get it settled for _ in range(5): try: client.do_handshake() except ssl.SSLWantReadError: pass if c_out.pending: s_in.write(c_out.read()) try: server.do_handshake() except ssl.SSLWantReadError: pass if s_out.pending: c_in.write(s_out.read()) # Now the handshakes should be complete (don't raise WantReadError) client.do_handshake() server.do_handshake() # Now if we unwrap one side unilaterally, it should send close-notify # and raise WantReadError: with self.assertRaises(ssl.SSLWantReadError): client.unwrap() # But server.unwrap() does not raise, because it reads the client's # close-notify: s_in.write(c_out.read()) server.unwrap() # And now that the client gets the server's close-notify, it doesn't # raise either. c_in.write(s_out.read()) client.unwrap() class SimpleBackgroundTests(unittest.TestCase): """Tests that connect to a simple server running in the background""" def setUp(self): server = ThreadedEchoServer(SIGNED_CERTFILE) self.server_addr = (HOST, server.port) server.__enter__() self.addCleanup(server.__exit__, None, None, None) def test_connect(self): with test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_NONE) as s: s.connect(self.server_addr) self.assertEqual({}, s.getpeercert()) self.assertFalse(s.server_side) # this should succeed because we specify the root cert with test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_REQUIRED, ca_certs=SIGNING_CA) as s: s.connect(self.server_addr) self.assertTrue(s.getpeercert()) self.assertFalse(s.server_side) def test_connect_fail(self): # This should fail because we have no verification certs. Connection # failure crashes ThreadedEchoServer, so run this in an independent # test method. s = test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_REQUIRED) self.addCleanup(s.close) self.assertRaisesRegex(ssl.SSLError, "certificate verify failed", s.connect, self.server_addr) def test_connect_ex(self): # Issue #11326: check connect_ex() implementation s = test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_REQUIRED, ca_certs=SIGNING_CA) self.addCleanup(s.close) self.assertEqual(0, s.connect_ex(self.server_addr)) self.assertTrue(s.getpeercert()) def test_non_blocking_connect_ex(self): # Issue #11326: non-blocking connect_ex() should allow handshake # to proceed after the socket gets ready. s = test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_REQUIRED, ca_certs=SIGNING_CA, do_handshake_on_connect=False) self.addCleanup(s.close) s.setblocking(False) rc = s.connect_ex(self.server_addr) # EWOULDBLOCK under Windows, EINPROGRESS elsewhere self.assertIn(rc, (0, errno.EINPROGRESS, errno.EWOULDBLOCK)) # Wait for connect to finish select.select([], [s], [], 5.0) # Non-blocking handshake while True: try: s.do_handshake() break except ssl.SSLWantReadError: select.select([s], [], [], 5.0) except ssl.SSLWantWriteError: select.select([], [s], [], 5.0) # SSL established self.assertTrue(s.getpeercert()) def test_connect_with_context(self): # Same as test_connect, but with a separately created context ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) with ctx.wrap_socket(socket.socket(socket.AF_INET)) as s: s.connect(self.server_addr) self.assertEqual({}, s.getpeercert()) # Same with a server hostname with ctx.wrap_socket(socket.socket(socket.AF_INET), server_hostname="dummy") as s: s.connect(self.server_addr) ctx.verify_mode = ssl.CERT_REQUIRED # This should succeed because we specify the root cert ctx.load_verify_locations(SIGNING_CA) with ctx.wrap_socket(socket.socket(socket.AF_INET)) as s: s.connect(self.server_addr) cert = s.getpeercert() self.assertTrue(cert) def test_connect_with_context_fail(self): # This should fail because we have no verification certs. Connection # failure crashes ThreadedEchoServer, so run this in an independent # test method. ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) ctx.verify_mode = ssl.CERT_REQUIRED s = ctx.wrap_socket(socket.socket(socket.AF_INET)) self.addCleanup(s.close) self.assertRaisesRegex(ssl.SSLError, "certificate verify failed", s.connect, self.server_addr) def test_connect_capath(self): # Verify server certificates using the `capath` argument # NOTE: the subject hashing algorithm has been changed between # OpenSSL 0.9.8n and 1.0.0, as a result the capath directory must # contain both versions of each certificate (same content, different # filename) for this test to be portable across OpenSSL releases. ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) ctx.verify_mode = ssl.CERT_REQUIRED ctx.load_verify_locations(capath=CAPATH) with ctx.wrap_socket(socket.socket(socket.AF_INET)) as s: s.connect(self.server_addr) cert = s.getpeercert() self.assertTrue(cert) # Same with a bytes `capath` argument ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) ctx.verify_mode = ssl.CERT_REQUIRED ctx.load_verify_locations(capath=BYTES_CAPATH) with ctx.wrap_socket(socket.socket(socket.AF_INET)) as s: s.connect(self.server_addr) cert = s.getpeercert() self.assertTrue(cert) def test_connect_cadata(self): with open(SIGNING_CA) as f: pem = f.read() der = ssl.PEM_cert_to_DER_cert(pem) ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) ctx.verify_mode = ssl.CERT_REQUIRED ctx.load_verify_locations(cadata=pem) with ctx.wrap_socket(socket.socket(socket.AF_INET)) as s: s.connect(self.server_addr) cert = s.getpeercert() self.assertTrue(cert) # same with DER ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) ctx.verify_mode = ssl.CERT_REQUIRED ctx.load_verify_locations(cadata=der) with ctx.wrap_socket(socket.socket(socket.AF_INET)) as s: s.connect(self.server_addr) cert = s.getpeercert() self.assertTrue(cert) @unittest.skipIf(os.name == "nt", "Can't use a socket as a file under Windows") def test_makefile_close(self): # Issue #5238: creating a file-like object with makefile() shouldn't # delay closing the underlying "real socket" (here tested with its # file descriptor, hence skipping the test under Windows). ss = test_wrap_socket(socket.socket(socket.AF_INET)) ss.connect(self.server_addr) fd = ss.fileno() f = ss.makefile() f.close() # The fd is still open os.read(fd, 0) # Closing the SSL socket should close the fd too ss.close() gc.collect() with self.assertRaises(OSError) as e: os.read(fd, 0) self.assertEqual(e.exception.errno, errno.EBADF) def test_non_blocking_handshake(self): s = socket.socket(socket.AF_INET) s.connect(self.server_addr) s.setblocking(False) s = test_wrap_socket(s, cert_reqs=ssl.CERT_NONE, do_handshake_on_connect=False) self.addCleanup(s.close) count = 0 while True: try: count += 1 s.do_handshake() break except ssl.SSLWantReadError: select.select([s], [], []) except ssl.SSLWantWriteError: select.select([], [s], []) if support.verbose: sys.stdout.write("\nNeeded %d calls to do_handshake() to establish session.\n" % count) def test_get_server_certificate(self): _test_get_server_certificate(self, *self.server_addr, cert=SIGNING_CA) def test_get_server_certificate_fail(self): # Connection failure crashes ThreadedEchoServer, so run this in an # independent test method _test_get_server_certificate_fail(self, *self.server_addr) def test_ciphers(self): with test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_NONE, ciphers="ALL") as s: s.connect(self.server_addr) with test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_NONE, ciphers="DEFAULT") as s: s.connect(self.server_addr) # Error checking can happen at instantiation or when connecting with self.assertRaisesRegex(ssl.SSLError, "No cipher can be selected"): with socket.socket(socket.AF_INET) as sock: s = test_wrap_socket(sock, cert_reqs=ssl.CERT_NONE, ciphers="^$:,;?*'dorothyx") s.connect(self.server_addr) def test_get_ca_certs_capath(self): # capath certs are loaded on request ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx.load_verify_locations(capath=CAPATH) self.assertEqual(ctx.get_ca_certs(), []) with ctx.wrap_socket(socket.socket(socket.AF_INET), server_hostname='localhost') as s: s.connect(self.server_addr) cert = s.getpeercert() self.assertTrue(cert) self.assertEqual(len(ctx.get_ca_certs()), 1) @needs_sni def test_context_setget(self): # Check that the context of a connected socket can be replaced. ctx1 = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx1.load_verify_locations(capath=CAPATH) ctx2 = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) ctx2.load_verify_locations(capath=CAPATH) s = socket.socket(socket.AF_INET) with ctx1.wrap_socket(s, server_hostname='localhost') as ss: ss.connect(self.server_addr) self.assertIs(ss.context, ctx1) self.assertIs(ss._sslobj.context, ctx1) ss.context = ctx2 self.assertIs(ss.context, ctx2) self.assertIs(ss._sslobj.context, ctx2) def ssl_io_loop(self, sock, incoming, outgoing, func, *args, **kwargs): # A simple IO loop. Call func(*args) depending on the error we get # (WANT_READ or WANT_WRITE) move data between the socket and the BIOs. timeout = kwargs.get('timeout', support.SHORT_TIMEOUT) deadline = time.monotonic() + timeout count = 0 while True: if time.monotonic() > deadline: self.fail("timeout") errno = None count += 1 try: ret = func(*args) except ssl.SSLError as e: if e.errno not in (ssl.SSL_ERROR_WANT_READ, ssl.SSL_ERROR_WANT_WRITE): raise errno = e.errno # Get any data from the outgoing BIO irrespective of any error, and # send it to the socket. buf = outgoing.read() sock.sendall(buf) # If there's no error, we're done. For WANT_READ, we need to get # data from the socket and put it in the incoming BIO. if errno is None: break elif errno == ssl.SSL_ERROR_WANT_READ: buf = sock.recv(32768) if buf: incoming.write(buf) else: incoming.write_eof() if support.verbose: sys.stdout.write("Needed %d calls to complete %s().\n" % (count, func.__name__)) return ret def test_bio_handshake(self): sock = socket.socket(socket.AF_INET) self.addCleanup(sock.close) sock.connect(self.server_addr) incoming = ssl.MemoryBIO() outgoing = ssl.MemoryBIO() ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertTrue(ctx.check_hostname) self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) ctx.load_verify_locations(SIGNING_CA) sslobj = ctx.wrap_bio(incoming, outgoing, False, SIGNED_CERTFILE_HOSTNAME) self.assertIs(sslobj._sslobj.owner, sslobj) self.assertIsNone(sslobj.cipher()) self.assertIsNone(sslobj.version()) self.assertIsNotNone(sslobj.shared_ciphers()) self.assertRaises(ValueError, sslobj.getpeercert) if 'tls-unique' in ssl.CHANNEL_BINDING_TYPES: self.assertIsNone(sslobj.get_channel_binding('tls-unique')) self.ssl_io_loop(sock, incoming, outgoing, sslobj.do_handshake) self.assertTrue(sslobj.cipher()) self.assertIsNotNone(sslobj.shared_ciphers()) self.assertIsNotNone(sslobj.version()) self.assertTrue(sslobj.getpeercert()) if 'tls-unique' in ssl.CHANNEL_BINDING_TYPES: self.assertTrue(sslobj.get_channel_binding('tls-unique')) try: self.ssl_io_loop(sock, incoming, outgoing, sslobj.unwrap) except ssl.SSLSyscallError: # If the server shuts down the TCP connection without sending a # secure shutdown message, this is reported as SSL_ERROR_SYSCALL pass self.assertRaises(ssl.SSLError, sslobj.write, b'foo') def test_bio_read_write_data(self): sock = socket.socket(socket.AF_INET) self.addCleanup(sock.close) sock.connect(self.server_addr) incoming = ssl.MemoryBIO() outgoing = ssl.MemoryBIO() ctx = ssl.SSLContext(ssl.PROTOCOL_TLS) ctx.verify_mode = ssl.CERT_NONE sslobj = ctx.wrap_bio(incoming, outgoing, False) self.ssl_io_loop(sock, incoming, outgoing, sslobj.do_handshake) req = b'FOO\n' self.ssl_io_loop(sock, incoming, outgoing, sslobj.write, req) buf = self.ssl_io_loop(sock, incoming, outgoing, sslobj.read, 1024) self.assertEqual(buf, b'foo\n') self.ssl_io_loop(sock, incoming, outgoing, sslobj.unwrap) class NetworkedTests(unittest.TestCase): def test_timeout_connect_ex(self): # Issue #12065: on a timeout, connect_ex() should return the original # errno (mimicking the behaviour of non-SSL sockets). with socket_helper.transient_internet(REMOTE_HOST): s = test_wrap_socket(socket.socket(socket.AF_INET), cert_reqs=ssl.CERT_REQUIRED, do_handshake_on_connect=False) self.addCleanup(s.close) s.settimeout(0.0000001) rc = s.connect_ex((REMOTE_HOST, 443)) if rc == 0: self.skipTest("REMOTE_HOST responded too quickly") self.assertIn(rc, (errno.EAGAIN, errno.EWOULDBLOCK)) @unittest.skipUnless(socket_helper.IPV6_ENABLED, 'Needs IPv6') def test_get_server_certificate_ipv6(self): with socket_helper.transient_internet('ipv6.google.com'): _test_get_server_certificate(self, 'ipv6.google.com', 443) _test_get_server_certificate_fail(self, 'ipv6.google.com', 443) def _test_get_server_certificate(test, host, port, cert=None): pem = ssl.get_server_certificate((host, port)) if not pem: test.fail("No server certificate on %s:%s!" % (host, port)) pem = ssl.get_server_certificate((host, port), ca_certs=cert) if not pem: test.fail("No server certificate on %s:%s!" % (host, port)) if support.verbose: sys.stdout.write("\nVerified certificate for %s:%s is\n%s\n" % (host, port ,pem)) def _test_get_server_certificate_fail(test, host, port): try: pem = ssl.get_server_certificate((host, port), ca_certs=CERTFILE) except ssl.SSLError as x: #should fail if support.verbose: sys.stdout.write("%s\n" % x) else: test.fail("Got server certificate %s for %s:%s!" % (pem, host, port)) from test.ssl_servers import make_https_server class ThreadedEchoServer(threading.Thread): class ConnectionHandler(threading.Thread): """A mildly complicated class, because we want it to work both with and without the SSL wrapper around the socket connection, so that we can test the STARTTLS functionality.""" def __init__(self, server, connsock, addr): self.server = server self.running = False self.sock = connsock self.addr = addr self.sock.setblocking(True) self.sslconn = None threading.Thread.__init__(self) self.daemon = True def wrap_conn(self): try: self.sslconn = self.server.context.wrap_socket( self.sock, server_side=True) self.server.selected_npn_protocols.append(self.sslconn.selected_npn_protocol()) self.server.selected_alpn_protocols.append(self.sslconn.selected_alpn_protocol()) except (ConnectionResetError, BrokenPipeError, ConnectionAbortedError) as e: # We treat ConnectionResetError as though it were an # SSLError - OpenSSL on Ubuntu abruptly closes the # connection when asked to use an unsupported protocol. # # BrokenPipeError is raised in TLS 1.3 mode, when OpenSSL # tries to send session tickets after handshake. # https://github.com/openssl/openssl/issues/6342 # # ConnectionAbortedError is raised in TLS 1.3 mode, when OpenSSL # tries to send session tickets after handshake when using WinSock. self.server.conn_errors.append(str(e)) if self.server.chatty: handle_error("\n server: bad connection attempt from " + repr(self.addr) + ":\n") self.running = False self.close() return False except (ssl.SSLError, OSError) as e: # OSError may occur with wrong protocols, e.g. both # sides use PROTOCOL_TLS_SERVER. # # XXX Various errors can have happened here, for example # a mismatching protocol version, an invalid certificate, # or a low-level bug. This should be made more discriminating. # # bpo-31323: Store the exception as string to prevent # a reference leak: server -> conn_errors -> exception # -> traceback -> self (ConnectionHandler) -> server self.server.conn_errors.append(str(e)) if self.server.chatty: handle_error("\n server: bad connection attempt from " + repr(self.addr) + ":\n") self.running = False self.server.stop() self.close() return False else: self.server.shared_ciphers.append(self.sslconn.shared_ciphers()) if self.server.context.verify_mode == ssl.CERT_REQUIRED: cert = self.sslconn.getpeercert() if support.verbose and self.server.chatty: sys.stdout.write(" client cert is " + pprint.pformat(cert) + "\n") cert_binary = self.sslconn.getpeercert(True) if support.verbose and self.server.chatty: sys.stdout.write(" cert binary is " + str(len(cert_binary)) + " bytes\n") cipher = self.sslconn.cipher() if support.verbose and self.server.chatty: sys.stdout.write(" server: connection cipher is now " + str(cipher) + "\n") sys.stdout.write(" server: selected protocol is now " + str(self.sslconn.selected_npn_protocol()) + "\n") return True def read(self): if self.sslconn: return self.sslconn.read() else: return self.sock.recv(1024) def write(self, bytes): if self.sslconn: return self.sslconn.write(bytes) else: return self.sock.send(bytes) def close(self): if self.sslconn: self.sslconn.close() else: self.sock.close() def run(self): self.running = True if not self.server.starttls_server: if not self.wrap_conn(): return while self.running: try: msg = self.read() stripped = msg.strip() if not stripped: # eof, so quit this handler self.running = False try: self.sock = self.sslconn.unwrap() except OSError: # Many tests shut the TCP connection down # without an SSL shutdown. This causes # unwrap() to raise OSError with errno=0! pass else: self.sslconn = None self.close() elif stripped == b'over': if support.verbose and self.server.connectionchatty: sys.stdout.write(" server: client closed connection\n") self.close() return elif (self.server.starttls_server and stripped == b'STARTTLS'): if support.verbose and self.server.connectionchatty: sys.stdout.write(" server: read STARTTLS from client, sending OK...\n") self.write(b"OK\n") if not self.wrap_conn(): return elif (self.server.starttls_server and self.sslconn and stripped == b'ENDTLS'): if support.verbose and self.server.connectionchatty: sys.stdout.write(" server: read ENDTLS from client, sending OK...\n") self.write(b"OK\n") self.sock = self.sslconn.unwrap() self.sslconn = None if support.verbose and self.server.connectionchatty: sys.stdout.write(" server: connection is now unencrypted...\n") elif stripped == b'CB tls-unique': if support.verbose and self.server.connectionchatty: sys.stdout.write(" server: read CB tls-unique from client, sending our CB data...\n") data = self.sslconn.get_channel_binding("tls-unique") self.write(repr(data).encode("us-ascii") + b"\n") elif stripped == b'PHA': if support.verbose and self.server.connectionchatty: sys.stdout.write(" server: initiating post handshake auth\n") try: self.sslconn.verify_client_post_handshake() except ssl.SSLError as e: self.write(repr(e).encode("us-ascii") + b"\n") else: self.write(b"OK\n") elif stripped == b'HASCERT': if self.sslconn.getpeercert() is not None: self.write(b'TRUE\n') else: self.write(b'FALSE\n') elif stripped == b'GETCERT': cert = self.sslconn.getpeercert() self.write(repr(cert).encode("us-ascii") + b"\n") else: if (support.verbose and self.server.connectionchatty): ctype = (self.sslconn and "encrypted") or "unencrypted" sys.stdout.write(" server: read %r (%s), sending back %r (%s)...\n" % (msg, ctype, msg.lower(), ctype)) self.write(msg.lower()) except (ConnectionResetError, ConnectionAbortedError): # XXX: OpenSSL 1.1.1 sometimes raises ConnectionResetError # when connection is not shut down gracefully. if self.server.chatty and support.verbose: sys.stdout.write( " Connection reset by peer: {}\n".format( self.addr) ) self.close() self.running = False except ssl.SSLError as err: # On Windows sometimes test_pha_required_nocert receives the # PEER_DID_NOT_RETURN_A_CERTIFICATE exception # before the 'tlsv13 alert certificate required' exception. # If the server is stopped when PEER_DID_NOT_RETURN_A_CERTIFICATE # is received test_pha_required_nocert fails with ConnectionResetError # because the underlying socket is closed if 'PEER_DID_NOT_RETURN_A_CERTIFICATE' == err.reason: if self.server.chatty and support.verbose: sys.stdout.write(err.args[1]) # test_pha_required_nocert is expecting this exception raise ssl.SSLError('tlsv13 alert certificate required') except OSError: if self.server.chatty: handle_error("Test server failure:\n") self.close() self.running = False # normally, we'd just stop here, but for the test # harness, we want to stop the server self.server.stop() def __init__(self, certificate=None, ssl_version=None, certreqs=None, cacerts=None, chatty=True, connectionchatty=False, starttls_server=False, npn_protocols=None, alpn_protocols=None, ciphers=None, context=None): if context: self.context = context else: self.context = ssl.SSLContext(ssl_version if ssl_version is not None else ssl.PROTOCOL_TLS_SERVER) self.context.verify_mode = (certreqs if certreqs is not None else ssl.CERT_NONE) if cacerts: self.context.load_verify_locations(cacerts) if certificate: self.context.load_cert_chain(certificate) if npn_protocols: self.context.set_npn_protocols(npn_protocols) if alpn_protocols: self.context.set_alpn_protocols(alpn_protocols) if ciphers: self.context.set_ciphers(ciphers) self.chatty = chatty self.connectionchatty = connectionchatty self.starttls_server = starttls_server self.sock = socket.socket() self.port = socket_helper.bind_port(self.sock) self.flag = None self.active = False self.selected_npn_protocols = [] self.selected_alpn_protocols = [] self.shared_ciphers = [] self.conn_errors = [] threading.Thread.__init__(self) self.daemon = True def __enter__(self): self.start(threading.Event()) self.flag.wait() return self def __exit__(self, *args): self.stop() self.join() def start(self, flag=None): self.flag = flag threading.Thread.start(self) def run(self): self.sock.settimeout(0.05) self.sock.listen() self.active = True if self.flag: # signal an event self.flag.set() while self.active: try: newconn, connaddr = self.sock.accept() if support.verbose and self.chatty: sys.stdout.write(' server: new connection from ' + repr(connaddr) + '\n') handler = self.ConnectionHandler(self, newconn, connaddr) handler.start() handler.join() except socket.timeout: pass except KeyboardInterrupt: self.stop() except BaseException as e: if support.verbose and self.chatty: sys.stdout.write( ' connection handling failed: ' + repr(e) + '\n') self.sock.close() def stop(self): self.active = False class AsyncoreEchoServer(threading.Thread): # this one's based on asyncore.dispatcher class EchoServer (asyncore.dispatcher): class ConnectionHandler(asyncore.dispatcher_with_send): def __init__(self, conn, certfile): self.socket = test_wrap_socket(conn, server_side=True, certfile=certfile, do_handshake_on_connect=False) asyncore.dispatcher_with_send.__init__(self, self.socket) self._ssl_accepting = True self._do_ssl_handshake() def readable(self): if isinstance(self.socket, ssl.SSLSocket): while self.socket.pending() > 0: self.handle_read_event() return True def _do_ssl_handshake(self): try: self.socket.do_handshake() except (ssl.SSLWantReadError, ssl.SSLWantWriteError): return except ssl.SSLEOFError: return self.handle_close() except ssl.SSLError: raise except OSError as err: if err.args[0] == errno.ECONNABORTED: return self.handle_close() else: self._ssl_accepting = False def handle_read(self): if self._ssl_accepting: self._do_ssl_handshake() else: data = self.recv(1024) if support.verbose: sys.stdout.write(" server: read %s from client\n" % repr(data)) if not data: self.close() else: self.send(data.lower()) def handle_close(self): self.close() if support.verbose: sys.stdout.write(" server: closed connection %s\n" % self.socket) def handle_error(self): raise def __init__(self, certfile): self.certfile = certfile sock = socket.socket(socket.AF_INET, socket.SOCK_STREAM) self.port = socket_helper.bind_port(sock, '') asyncore.dispatcher.__init__(self, sock) self.listen(5) def handle_accepted(self, sock_obj, addr): if support.verbose: sys.stdout.write(" server: new connection from %s:%s\n" %addr) self.ConnectionHandler(sock_obj, self.certfile) def handle_error(self): raise def __init__(self, certfile): self.flag = None self.active = False self.server = self.EchoServer(certfile) self.port = self.server.port threading.Thread.__init__(self) self.daemon = True def __str__(self): return "<%s %s>" % (self.__class__.__name__, self.server) def __enter__(self): self.start(threading.Event()) self.flag.wait() return self def __exit__(self, *args): if support.verbose: sys.stdout.write(" cleanup: stopping server.\n") self.stop() if support.verbose: sys.stdout.write(" cleanup: joining server thread.\n") self.join() if support.verbose: sys.stdout.write(" cleanup: successfully joined.\n") # make sure that ConnectionHandler is removed from socket_map asyncore.close_all(ignore_all=True) def start (self, flag=None): self.flag = flag threading.Thread.start(self) def run(self): self.active = True if self.flag: self.flag.set() while self.active: try: asyncore.loop(1) except: pass def stop(self): self.active = False self.server.close() def server_params_test(client_context, server_context, indata=b"FOO\n", chatty=True, connectionchatty=False, sni_name=None, session=None): """ Launch a server, connect a client to it and try various reads and writes. """ stats = {} server = ThreadedEchoServer(context=server_context, chatty=chatty, connectionchatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=sni_name, session=session) as s: s.connect((HOST, server.port)) for arg in [indata, bytearray(indata), memoryview(indata)]: if connectionchatty: if support.verbose: sys.stdout.write( " client: sending %r...\n" % indata) s.write(arg) outdata = s.read() if connectionchatty: if support.verbose: sys.stdout.write(" client: read %r\n" % outdata) if outdata != indata.lower(): raise AssertionError( "bad data <<%r>> (%d) received; expected <<%r>> (%d)\n" % (outdata[:20], len(outdata), indata[:20].lower(), len(indata))) s.write(b"over\n") if connectionchatty: if support.verbose: sys.stdout.write(" client: closing connection.\n") stats.update({ 'compression': s.compression(), 'cipher': s.cipher(), 'peercert': s.getpeercert(), 'client_alpn_protocol': s.selected_alpn_protocol(), 'client_npn_protocol': s.selected_npn_protocol(), 'version': s.version(), 'session_reused': s.session_reused, 'session': s.session, }) s.close() stats['server_alpn_protocols'] = server.selected_alpn_protocols stats['server_npn_protocols'] = server.selected_npn_protocols stats['server_shared_ciphers'] = server.shared_ciphers return stats def try_protocol_combo(server_protocol, client_protocol, expect_success, certsreqs=None, server_options=0, client_options=0): """ Try to SSL-connect using *client_protocol* to *server_protocol*. If *expect_success* is true, assert that the connection succeeds, if it's false, assert that the connection fails. Also, if *expect_success* is a string, assert that it is the protocol version actually used by the connection. """ if certsreqs is None: certsreqs = ssl.CERT_NONE certtype = { ssl.CERT_NONE: "CERT_NONE", ssl.CERT_OPTIONAL: "CERT_OPTIONAL", ssl.CERT_REQUIRED: "CERT_REQUIRED", }[certsreqs] if support.verbose: formatstr = (expect_success and " %s->%s %s\n") or " {%s->%s} %s\n" sys.stdout.write(formatstr % (ssl.get_protocol_name(client_protocol), ssl.get_protocol_name(server_protocol), certtype)) client_context = ssl.SSLContext(client_protocol) client_context.options |= client_options server_context = ssl.SSLContext(server_protocol) server_context.options |= server_options min_version = PROTOCOL_TO_TLS_VERSION.get(client_protocol, None) if (min_version is not None # SSLContext.minimum_version is only available on recent OpenSSL # (setter added in OpenSSL 1.1.0, getter added in OpenSSL 1.1.1) and hasattr(server_context, 'minimum_version') and server_protocol == ssl.PROTOCOL_TLS and server_context.minimum_version > min_version): # If OpenSSL configuration is strict and requires more recent TLS # version, we have to change the minimum to test old TLS versions. server_context.minimum_version = min_version # NOTE: we must enable "ALL" ciphers on the client, otherwise an # SSLv23 client will send an SSLv3 hello (rather than SSLv2) # starting from OpenSSL 1.0.0 (see issue #8322). if client_context.protocol == ssl.PROTOCOL_TLS: client_context.set_ciphers("ALL") for ctx in (client_context, server_context): ctx.verify_mode = certsreqs ctx.load_cert_chain(SIGNED_CERTFILE) ctx.load_verify_locations(SIGNING_CA) try: stats = server_params_test(client_context, server_context, chatty=False, connectionchatty=False) # Protocol mismatch can result in either an SSLError, or a # "Connection reset by peer" error. except ssl.SSLError: if expect_success: raise except OSError as e: if expect_success or e.errno != errno.ECONNRESET: raise else: if not expect_success: raise AssertionError( "Client protocol %s succeeded with server protocol %s!" % (ssl.get_protocol_name(client_protocol), ssl.get_protocol_name(server_protocol))) elif (expect_success is not True and expect_success != stats['version']): raise AssertionError("version mismatch: expected %r, got %r" % (expect_success, stats['version'])) class ThreadedTests(unittest.TestCase): def test_echo(self): """Basic test of an SSL client connecting to a server""" if support.verbose: sys.stdout.write("\n") for protocol in PROTOCOLS: if protocol in {ssl.PROTOCOL_TLS_CLIENT, ssl.PROTOCOL_TLS_SERVER}: continue if not has_tls_protocol(protocol): continue with self.subTest(protocol=ssl._PROTOCOL_NAMES[protocol]): context = ssl.SSLContext(protocol) context.load_cert_chain(CERTFILE) server_params_test(context, context, chatty=True, connectionchatty=True) client_context, server_context, hostname = testing_context() with self.subTest(client=ssl.PROTOCOL_TLS_CLIENT, server=ssl.PROTOCOL_TLS_SERVER): server_params_test(client_context=client_context, server_context=server_context, chatty=True, connectionchatty=True, sni_name=hostname) client_context.check_hostname = False with self.subTest(client=ssl.PROTOCOL_TLS_SERVER, server=ssl.PROTOCOL_TLS_CLIENT): with self.assertRaises(ssl.SSLError) as e: server_params_test(client_context=server_context, server_context=client_context, chatty=True, connectionchatty=True, sni_name=hostname) self.assertIn('called a function you should not call', str(e.exception)) with self.subTest(client=ssl.PROTOCOL_TLS_SERVER, server=ssl.PROTOCOL_TLS_SERVER): with self.assertRaises(ssl.SSLError) as e: server_params_test(client_context=server_context, server_context=server_context, chatty=True, connectionchatty=True) self.assertIn('called a function you should not call', str(e.exception)) with self.subTest(client=ssl.PROTOCOL_TLS_CLIENT, server=ssl.PROTOCOL_TLS_CLIENT): with self.assertRaises(ssl.SSLError) as e: server_params_test(client_context=server_context, server_context=client_context, chatty=True, connectionchatty=True) self.assertIn('called a function you should not call', str(e.exception)) def test_getpeercert(self): if support.verbose: sys.stdout.write("\n") client_context, server_context, hostname = testing_context() server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), do_handshake_on_connect=False, server_hostname=hostname) as s: s.connect((HOST, server.port)) # getpeercert() raise ValueError while the handshake isn't # done. with self.assertRaises(ValueError): s.getpeercert() s.do_handshake() cert = s.getpeercert() self.assertTrue(cert, "Can't get peer certificate.") cipher = s.cipher() if support.verbose: sys.stdout.write(pprint.pformat(cert) + '\n') sys.stdout.write("Connection cipher is " + str(cipher) + '.\n') if 'subject' not in cert: self.fail("No subject field in certificate: %s." % pprint.pformat(cert)) if ((('organizationName', 'Python Software Foundation'),) not in cert['subject']): self.fail( "Missing or invalid 'organizationName' field in certificate subject; " "should be 'Python Software Foundation'.") self.assertIn('notBefore', cert) self.assertIn('notAfter', cert) before = ssl.cert_time_to_seconds(cert['notBefore']) after = ssl.cert_time_to_seconds(cert['notAfter']) self.assertLess(before, after) @unittest.skipUnless(have_verify_flags(), "verify_flags need OpenSSL > 0.9.8") def test_crl_check(self): if support.verbose: sys.stdout.write("\n") client_context, server_context, hostname = testing_context() tf = getattr(ssl, "VERIFY_X509_TRUSTED_FIRST", 0) self.assertEqual(client_context.verify_flags, ssl.VERIFY_DEFAULT | tf) # VERIFY_DEFAULT should pass server = ThreadedEchoServer(context=server_context, chatty=True) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) cert = s.getpeercert() self.assertTrue(cert, "Can't get peer certificate.") # VERIFY_CRL_CHECK_LEAF without a loaded CRL file fails client_context.verify_flags |= ssl.VERIFY_CRL_CHECK_LEAF server = ThreadedEchoServer(context=server_context, chatty=True) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: with self.assertRaisesRegex(ssl.SSLError, "certificate verify failed"): s.connect((HOST, server.port)) # now load a CRL file. The CRL file is signed by the CA. client_context.load_verify_locations(CRLFILE) server = ThreadedEchoServer(context=server_context, chatty=True) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) cert = s.getpeercert() self.assertTrue(cert, "Can't get peer certificate.") def test_check_hostname(self): if support.verbose: sys.stdout.write("\n") client_context, server_context, hostname = testing_context() # correct hostname should verify server = ThreadedEchoServer(context=server_context, chatty=True) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) cert = s.getpeercert() self.assertTrue(cert, "Can't get peer certificate.") # incorrect hostname should raise an exception server = ThreadedEchoServer(context=server_context, chatty=True) with server: with client_context.wrap_socket(socket.socket(), server_hostname="invalid") as s: with self.assertRaisesRegex( ssl.CertificateError, "Hostname mismatch, certificate is not valid for 'invalid'."): s.connect((HOST, server.port)) # missing server_hostname arg should cause an exception, too server = ThreadedEchoServer(context=server_context, chatty=True) with server: with socket.socket() as s: with self.assertRaisesRegex(ValueError, "check_hostname requires server_hostname"): client_context.wrap_socket(s) def test_ecc_cert(self): client_context = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) client_context.load_verify_locations(SIGNING_CA) client_context.set_ciphers('ECDHE:ECDSA:!NULL:!aRSA') hostname = SIGNED_CERTFILE_ECC_HOSTNAME server_context = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) # load ECC cert server_context.load_cert_chain(SIGNED_CERTFILE_ECC) # correct hostname should verify server = ThreadedEchoServer(context=server_context, chatty=True) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) cert = s.getpeercert() self.assertTrue(cert, "Can't get peer certificate.") cipher = s.cipher()[0].split('-') self.assertTrue(cipher[:2], ('ECDHE', 'ECDSA')) def test_dual_rsa_ecc(self): client_context = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) client_context.load_verify_locations(SIGNING_CA) # TODO: fix TLSv1.3 once SSLContext can restrict signature # algorithms. client_context.options |= ssl.OP_NO_TLSv1_3 # only ECDSA certs client_context.set_ciphers('ECDHE:ECDSA:!NULL:!aRSA') hostname = SIGNED_CERTFILE_ECC_HOSTNAME server_context = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) # load ECC and RSA key/cert pairs server_context.load_cert_chain(SIGNED_CERTFILE_ECC) server_context.load_cert_chain(SIGNED_CERTFILE) # correct hostname should verify server = ThreadedEchoServer(context=server_context, chatty=True) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) cert = s.getpeercert() self.assertTrue(cert, "Can't get peer certificate.") cipher = s.cipher()[0].split('-') self.assertTrue(cipher[:2], ('ECDHE', 'ECDSA')) def test_check_hostname_idn(self): if support.verbose: sys.stdout.write("\n") server_context = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) server_context.load_cert_chain(IDNSANSFILE) context = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) context.verify_mode = ssl.CERT_REQUIRED context.check_hostname = True context.load_verify_locations(SIGNING_CA) # correct hostname should verify, when specified in several # different ways idn_hostnames = [ ('könig.idn.pythontest.net', 'xn--knig-5qa.idn.pythontest.net'), ('xn--knig-5qa.idn.pythontest.net', 'xn--knig-5qa.idn.pythontest.net'), (b'xn--knig-5qa.idn.pythontest.net', 'xn--knig-5qa.idn.pythontest.net'), ('königsgäßchen.idna2003.pythontest.net', 'xn--knigsgsschen-lcb0w.idna2003.pythontest.net'), ('xn--knigsgsschen-lcb0w.idna2003.pythontest.net', 'xn--knigsgsschen-lcb0w.idna2003.pythontest.net'), (b'xn--knigsgsschen-lcb0w.idna2003.pythontest.net', 'xn--knigsgsschen-lcb0w.idna2003.pythontest.net'), # ('königsgäßchen.idna2008.pythontest.net', # 'xn--knigsgchen-b4a3dun.idna2008.pythontest.net'), ('xn--knigsgchen-b4a3dun.idna2008.pythontest.net', 'xn--knigsgchen-b4a3dun.idna2008.pythontest.net'), (b'xn--knigsgchen-b4a3dun.idna2008.pythontest.net', 'xn--knigsgchen-b4a3dun.idna2008.pythontest.net'), ] for server_hostname, expected_hostname in idn_hostnames: server = ThreadedEchoServer(context=server_context, chatty=True) with server: with context.wrap_socket(socket.socket(), server_hostname=server_hostname) as s: self.assertEqual(s.server_hostname, expected_hostname) s.connect((HOST, server.port)) cert = s.getpeercert() self.assertEqual(s.server_hostname, expected_hostname) self.assertTrue(cert, "Can't get peer certificate.") # incorrect hostname should raise an exception server = ThreadedEchoServer(context=server_context, chatty=True) with server: with context.wrap_socket(socket.socket(), server_hostname="python.example.org") as s: with self.assertRaises(ssl.CertificateError): s.connect((HOST, server.port)) def test_wrong_cert_tls12(self): """Connecting when the server rejects the client's certificate Launch a server with CERT_REQUIRED, and check that trying to connect to it with a wrong client certificate fails. """ client_context, server_context, hostname = testing_context() # load client cert that is not signed by trusted CA client_context.load_cert_chain(CERTFILE) # require TLS client authentication server_context.verify_mode = ssl.CERT_REQUIRED # TLS 1.3 has different handshake client_context.maximum_version = ssl.TLSVersion.TLSv1_2 server = ThreadedEchoServer( context=server_context, chatty=True, connectionchatty=True, ) with server, \ client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: try: # Expect either an SSL error about the server rejecting # the connection, or a low-level connection reset (which # sometimes happens on Windows) s.connect((HOST, server.port)) except ssl.SSLError as e: if support.verbose: sys.stdout.write("\nSSLError is %r\n" % e) except OSError as e: if e.errno != errno.ECONNRESET: raise if support.verbose: sys.stdout.write("\nsocket.error is %r\n" % e) else: self.fail("Use of invalid cert should have failed!") @requires_tls_version('TLSv1_3') def test_wrong_cert_tls13(self): client_context, server_context, hostname = testing_context() # load client cert that is not signed by trusted CA client_context.load_cert_chain(CERTFILE) server_context.verify_mode = ssl.CERT_REQUIRED server_context.minimum_version = ssl.TLSVersion.TLSv1_3 client_context.minimum_version = ssl.TLSVersion.TLSv1_3 server = ThreadedEchoServer( context=server_context, chatty=True, connectionchatty=True, ) with server, \ client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: # TLS 1.3 perform client cert exchange after handshake s.connect((HOST, server.port)) try: s.write(b'data') s.read(4) except ssl.SSLError as e: if support.verbose: sys.stdout.write("\nSSLError is %r\n" % e) except OSError as e: if e.errno != errno.ECONNRESET: raise if support.verbose: sys.stdout.write("\nsocket.error is %r\n" % e) else: self.fail("Use of invalid cert should have failed!") def test_rude_shutdown(self): """A brutal shutdown of an SSL server should raise an OSError in the client when attempting handshake. """ listener_ready = threading.Event() listener_gone = threading.Event() s = socket.socket() port = socket_helper.bind_port(s, HOST) # `listener` runs in a thread. It sits in an accept() until # the main thread connects. Then it rudely closes the socket, # and sets Event `listener_gone` to let the main thread know # the socket is gone. def listener(): s.listen() listener_ready.set() newsock, addr = s.accept() newsock.close() s.close() listener_gone.set() def connector(): listener_ready.wait() with socket.socket() as c: c.connect((HOST, port)) listener_gone.wait() try: ssl_sock = test_wrap_socket(c) except OSError: pass else: self.fail('connecting to closed SSL socket should have failed') t = threading.Thread(target=listener) t.start() try: connector() finally: t.join() def test_ssl_cert_verify_error(self): if support.verbose: sys.stdout.write("\n") server_context = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) server_context.load_cert_chain(SIGNED_CERTFILE) context = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) server = ThreadedEchoServer(context=server_context, chatty=True) with server: with context.wrap_socket(socket.socket(), server_hostname=SIGNED_CERTFILE_HOSTNAME) as s: try: s.connect((HOST, server.port)) except ssl.SSLError as e: msg = 'unable to get local issuer certificate' self.assertIsInstance(e, ssl.SSLCertVerificationError) self.assertEqual(e.verify_code, 20) self.assertEqual(e.verify_message, msg) self.assertIn(msg, repr(e)) self.assertIn('certificate verify failed', repr(e)) @requires_tls_version('SSLv2') def test_protocol_sslv2(self): """Connecting to an SSLv2 server with various client options""" if support.verbose: sys.stdout.write("\n") try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_SSLv2, True) try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_SSLv2, True, ssl.CERT_OPTIONAL) try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_SSLv2, True, ssl.CERT_REQUIRED) try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_TLS, False) if has_tls_version('SSLv3'): try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_SSLv3, False) try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_TLSv1, False) # SSLv23 client with specific SSL options if no_sslv2_implies_sslv3_hello(): # No SSLv2 => client will use an SSLv3 hello on recent OpenSSLs try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_TLS, False, client_options=ssl.OP_NO_SSLv2) try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_TLS, False, client_options=ssl.OP_NO_SSLv3) try_protocol_combo(ssl.PROTOCOL_SSLv2, ssl.PROTOCOL_TLS, False, client_options=ssl.OP_NO_TLSv1) def test_PROTOCOL_TLS(self): """Connecting to an SSLv23 server with various client options""" if support.verbose: sys.stdout.write("\n") if has_tls_version('SSLv2'): try: try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_SSLv2, True) except OSError as x: # this fails on some older versions of OpenSSL (0.9.7l, for instance) if support.verbose: sys.stdout.write( " SSL2 client to SSL23 server test unexpectedly failed:\n %s\n" % str(x)) if has_tls_version('SSLv3'): try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_SSLv3, False) try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLS, True) if has_tls_version('TLSv1'): try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLSv1, 'TLSv1') if has_tls_version('SSLv3'): try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_SSLv3, False, ssl.CERT_OPTIONAL) try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLS, True, ssl.CERT_OPTIONAL) if has_tls_version('TLSv1'): try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLSv1, 'TLSv1', ssl.CERT_OPTIONAL) if has_tls_version('SSLv3'): try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_SSLv3, False, ssl.CERT_REQUIRED) try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLS, True, ssl.CERT_REQUIRED) if has_tls_version('TLSv1'): try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLSv1, 'TLSv1', ssl.CERT_REQUIRED) # Server with specific SSL options if has_tls_version('SSLv3'): try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_SSLv3, False, server_options=ssl.OP_NO_SSLv3) # Will choose TLSv1 try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLS, True, server_options=ssl.OP_NO_SSLv2 | ssl.OP_NO_SSLv3) if has_tls_version('TLSv1'): try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLSv1, False, server_options=ssl.OP_NO_TLSv1) @requires_tls_version('SSLv3') def test_protocol_sslv3(self): """Connecting to an SSLv3 server with various client options""" if support.verbose: sys.stdout.write("\n") try_protocol_combo(ssl.PROTOCOL_SSLv3, ssl.PROTOCOL_SSLv3, 'SSLv3') try_protocol_combo(ssl.PROTOCOL_SSLv3, ssl.PROTOCOL_SSLv3, 'SSLv3', ssl.CERT_OPTIONAL) try_protocol_combo(ssl.PROTOCOL_SSLv3, ssl.PROTOCOL_SSLv3, 'SSLv3', ssl.CERT_REQUIRED) if has_tls_version('SSLv2'): try_protocol_combo(ssl.PROTOCOL_SSLv3, ssl.PROTOCOL_SSLv2, False) try_protocol_combo(ssl.PROTOCOL_SSLv3, ssl.PROTOCOL_TLS, False, client_options=ssl.OP_NO_SSLv3) try_protocol_combo(ssl.PROTOCOL_SSLv3, ssl.PROTOCOL_TLSv1, False) if no_sslv2_implies_sslv3_hello(): # No SSLv2 => client will use an SSLv3 hello on recent OpenSSLs try_protocol_combo(ssl.PROTOCOL_SSLv3, ssl.PROTOCOL_TLS, False, client_options=ssl.OP_NO_SSLv2) @requires_tls_version('TLSv1') def test_protocol_tlsv1(self): """Connecting to a TLSv1 server with various client options""" if support.verbose: sys.stdout.write("\n") try_protocol_combo(ssl.PROTOCOL_TLSv1, ssl.PROTOCOL_TLSv1, 'TLSv1') try_protocol_combo(ssl.PROTOCOL_TLSv1, ssl.PROTOCOL_TLSv1, 'TLSv1', ssl.CERT_OPTIONAL) try_protocol_combo(ssl.PROTOCOL_TLSv1, ssl.PROTOCOL_TLSv1, 'TLSv1', ssl.CERT_REQUIRED) if has_tls_version('SSLv2'): try_protocol_combo(ssl.PROTOCOL_TLSv1, ssl.PROTOCOL_SSLv2, False) if has_tls_version('SSLv3'): try_protocol_combo(ssl.PROTOCOL_TLSv1, ssl.PROTOCOL_SSLv3, False) try_protocol_combo(ssl.PROTOCOL_TLSv1, ssl.PROTOCOL_TLS, False, client_options=ssl.OP_NO_TLSv1) @requires_tls_version('TLSv1_1') def test_protocol_tlsv1_1(self): """Connecting to a TLSv1.1 server with various client options. Testing against older TLS versions.""" if support.verbose: sys.stdout.write("\n") try_protocol_combo(ssl.PROTOCOL_TLSv1_1, ssl.PROTOCOL_TLSv1_1, 'TLSv1.1') if has_tls_version('SSLv2'): try_protocol_combo(ssl.PROTOCOL_TLSv1_1, ssl.PROTOCOL_SSLv2, False) if has_tls_version('SSLv3'): try_protocol_combo(ssl.PROTOCOL_TLSv1_1, ssl.PROTOCOL_SSLv3, False) try_protocol_combo(ssl.PROTOCOL_TLSv1_1, ssl.PROTOCOL_TLS, False, client_options=ssl.OP_NO_TLSv1_1) try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLSv1_1, 'TLSv1.1') try_protocol_combo(ssl.PROTOCOL_TLSv1_1, ssl.PROTOCOL_TLSv1_2, False) try_protocol_combo(ssl.PROTOCOL_TLSv1_2, ssl.PROTOCOL_TLSv1_1, False) @requires_tls_version('TLSv1_2') def test_protocol_tlsv1_2(self): """Connecting to a TLSv1.2 server with various client options. Testing against older TLS versions.""" if support.verbose: sys.stdout.write("\n") try_protocol_combo(ssl.PROTOCOL_TLSv1_2, ssl.PROTOCOL_TLSv1_2, 'TLSv1.2', server_options=ssl.OP_NO_SSLv3|ssl.OP_NO_SSLv2, client_options=ssl.OP_NO_SSLv3|ssl.OP_NO_SSLv2,) if has_tls_version('SSLv2'): try_protocol_combo(ssl.PROTOCOL_TLSv1_2, ssl.PROTOCOL_SSLv2, False) if has_tls_version('SSLv3'): try_protocol_combo(ssl.PROTOCOL_TLSv1_2, ssl.PROTOCOL_SSLv3, False) try_protocol_combo(ssl.PROTOCOL_TLSv1_2, ssl.PROTOCOL_TLS, False, client_options=ssl.OP_NO_TLSv1_2) try_protocol_combo(ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLSv1_2, 'TLSv1.2') try_protocol_combo(ssl.PROTOCOL_TLSv1_2, ssl.PROTOCOL_TLSv1, False) try_protocol_combo(ssl.PROTOCOL_TLSv1, ssl.PROTOCOL_TLSv1_2, False) try_protocol_combo(ssl.PROTOCOL_TLSv1_2, ssl.PROTOCOL_TLSv1_1, False) try_protocol_combo(ssl.PROTOCOL_TLSv1_1, ssl.PROTOCOL_TLSv1_2, False) def test_starttls(self): """Switching from clear text to encrypted and back again.""" msgs = (b"msg 1", b"MSG 2", b"STARTTLS", b"MSG 3", b"msg 4", b"ENDTLS", b"msg 5", b"msg 6") server = ThreadedEchoServer(CERTFILE, starttls_server=True, chatty=True, connectionchatty=True) wrapped = False with server: s = socket.socket() s.setblocking(True) s.connect((HOST, server.port)) if support.verbose: sys.stdout.write("\n") for indata in msgs: if support.verbose: sys.stdout.write( " client: sending %r...\n" % indata) if wrapped: conn.write(indata) outdata = conn.read() else: s.send(indata) outdata = s.recv(1024) msg = outdata.strip().lower() if indata == b"STARTTLS" and msg.startswith(b"ok"): # STARTTLS ok, switch to secure mode if support.verbose: sys.stdout.write( " client: read %r from server, starting TLS...\n" % msg) conn = test_wrap_socket(s) wrapped = True elif indata == b"ENDTLS" and msg.startswith(b"ok"): # ENDTLS ok, switch back to clear text if support.verbose: sys.stdout.write( " client: read %r from server, ending TLS...\n" % msg) s = conn.unwrap() wrapped = False else: if support.verbose: sys.stdout.write( " client: read %r from server\n" % msg) if support.verbose: sys.stdout.write(" client: closing connection.\n") if wrapped: conn.write(b"over\n") else: s.send(b"over\n") if wrapped: conn.close() else: s.close() def test_socketserver(self): """Using socketserver to create and manage SSL connections.""" server = make_https_server(self, certfile=SIGNED_CERTFILE) # try to connect if support.verbose: sys.stdout.write('\n') with open(CERTFILE, 'rb') as f: d1 = f.read() d2 = '' # now fetch the same data from the HTTPS server url = 'https://localhost:%d/%s' % ( server.port, os.path.split(CERTFILE)[1]) context = ssl.create_default_context(cafile=SIGNING_CA) f = urllib.request.urlopen(url, context=context) try: dlen = f.info().get("content-length") if dlen and (int(dlen) > 0): d2 = f.read(int(dlen)) if support.verbose: sys.stdout.write( " client: read %d bytes from remote server '%s'\n" % (len(d2), server)) finally: f.close() self.assertEqual(d1, d2) def test_asyncore_server(self): """Check the example asyncore integration.""" if support.verbose: sys.stdout.write("\n") indata = b"FOO\n" server = AsyncoreEchoServer(CERTFILE) with server: s = test_wrap_socket(socket.socket()) s.connect(('127.0.0.1', server.port)) if support.verbose: sys.stdout.write( " client: sending %r...\n" % indata) s.write(indata) outdata = s.read() if support.verbose: sys.stdout.write(" client: read %r\n" % outdata) if outdata != indata.lower(): self.fail( "bad data <<%r>> (%d) received; expected <<%r>> (%d)\n" % (outdata[:20], len(outdata), indata[:20].lower(), len(indata))) s.write(b"over\n") if support.verbose: sys.stdout.write(" client: closing connection.\n") s.close() if support.verbose: sys.stdout.write(" client: connection closed.\n") def test_recv_send(self): """Test recv(), send() and friends.""" if support.verbose: sys.stdout.write("\n") server = ThreadedEchoServer(CERTFILE, certreqs=ssl.CERT_NONE, ssl_version=ssl.PROTOCOL_TLS_SERVER, cacerts=CERTFILE, chatty=True, connectionchatty=False) with server: s = test_wrap_socket(socket.socket(), server_side=False, certfile=CERTFILE, ca_certs=CERTFILE, cert_reqs=ssl.CERT_NONE, ssl_version=ssl.PROTOCOL_TLS_CLIENT) s.connect((HOST, server.port)) # helper methods for standardising recv* method signatures def _recv_into(): b = bytearray(b"\0"*100) count = s.recv_into(b) return b[:count] def _recvfrom_into(): b = bytearray(b"\0"*100) count, addr = s.recvfrom_into(b) return b[:count] # (name, method, expect success?, *args, return value func) send_methods = [ ('send', s.send, True, [], len), ('sendto', s.sendto, False, ["some.address"], len), ('sendall', s.sendall, True, [], lambda x: None), ] # (name, method, whether to expect success, *args) recv_methods = [ ('recv', s.recv, True, []), ('recvfrom', s.recvfrom, False, ["some.address"]), ('recv_into', _recv_into, True, []), ('recvfrom_into', _recvfrom_into, False, []), ] data_prefix = "PREFIX_" for (meth_name, send_meth, expect_success, args, ret_val_meth) in send_methods: indata = (data_prefix + meth_name).encode('ascii') try: ret = send_meth(indata, *args) msg = "sending with {}".format(meth_name) self.assertEqual(ret, ret_val_meth(indata), msg=msg) outdata = s.read() if outdata != indata.lower(): self.fail( "While sending with <<{name:s}>> bad data " "<<{outdata:r}>> ({nout:d}) received; " "expected <<{indata:r}>> ({nin:d})\n".format( name=meth_name, outdata=outdata[:20], nout=len(outdata), indata=indata[:20], nin=len(indata) ) ) except ValueError as e: if expect_success: self.fail( "Failed to send with method <<{name:s}>>; " "expected to succeed.\n".format(name=meth_name) ) if not str(e).startswith(meth_name): self.fail( "Method <<{name:s}>> failed with unexpected " "exception message: {exp:s}\n".format( name=meth_name, exp=e ) ) for meth_name, recv_meth, expect_success, args in recv_methods: indata = (data_prefix + meth_name).encode('ascii') try: s.send(indata) outdata = recv_meth(*args) if outdata != indata.lower(): self.fail( "While receiving with <<{name:s}>> bad data " "<<{outdata:r}>> ({nout:d}) received; " "expected <<{indata:r}>> ({nin:d})\n".format( name=meth_name, outdata=outdata[:20], nout=len(outdata), indata=indata[:20], nin=len(indata) ) ) except ValueError as e: if expect_success: self.fail( "Failed to receive with method <<{name:s}>>; " "expected to succeed.\n".format(name=meth_name) ) if not str(e).startswith(meth_name): self.fail( "Method <<{name:s}>> failed with unexpected " "exception message: {exp:s}\n".format( name=meth_name, exp=e ) ) # consume data s.read() # read(-1, buffer) is supported, even though read(-1) is not data = b"data" s.send(data) buffer = bytearray(len(data)) self.assertEqual(s.read(-1, buffer), len(data)) self.assertEqual(buffer, data) # sendall accepts bytes-like objects if ctypes is not None: ubyte = ctypes.c_ubyte * len(data) byteslike = ubyte.from_buffer_copy(data) s.sendall(byteslike) self.assertEqual(s.read(), data) # Make sure sendmsg et al are disallowed to avoid # inadvertent disclosure of data and/or corruption # of the encrypted data stream self.assertRaises(NotImplementedError, s.dup) self.assertRaises(NotImplementedError, s.sendmsg, [b"data"]) self.assertRaises(NotImplementedError, s.recvmsg, 100) self.assertRaises(NotImplementedError, s.recvmsg_into, [bytearray(100)]) s.write(b"over\n") self.assertRaises(ValueError, s.recv, -1) self.assertRaises(ValueError, s.read, -1) s.close() def test_recv_zero(self): server = ThreadedEchoServer(CERTFILE) server.__enter__() self.addCleanup(server.__exit__, None, None) s = socket.create_connection((HOST, server.port)) self.addCleanup(s.close) s = test_wrap_socket(s, suppress_ragged_eofs=False) self.addCleanup(s.close) # recv/read(0) should return no data s.send(b"data") self.assertEqual(s.recv(0), b"") self.assertEqual(s.read(0), b"") self.assertEqual(s.read(), b"data") # Should not block if the other end sends no data s.setblocking(False) self.assertEqual(s.recv(0), b"") self.assertEqual(s.recv_into(bytearray()), 0) def test_nonblocking_send(self): server = ThreadedEchoServer(CERTFILE, certreqs=ssl.CERT_NONE, ssl_version=ssl.PROTOCOL_TLS_SERVER, cacerts=CERTFILE, chatty=True, connectionchatty=False) with server: s = test_wrap_socket(socket.socket(), server_side=False, certfile=CERTFILE, ca_certs=CERTFILE, cert_reqs=ssl.CERT_NONE, ssl_version=ssl.PROTOCOL_TLS_CLIENT) s.connect((HOST, server.port)) s.setblocking(False) # If we keep sending data, at some point the buffers # will be full and the call will block buf = bytearray(8192) def fill_buffer(): while True: s.send(buf) self.assertRaises((ssl.SSLWantWriteError, ssl.SSLWantReadError), fill_buffer) # Now read all the output and discard it s.setblocking(True) s.close() def test_handshake_timeout(self): # Issue #5103: SSL handshake must respect the socket timeout server = socket.socket(socket.AF_INET) host = "127.0.0.1" port = socket_helper.bind_port(server) started = threading.Event() finish = False def serve(): server.listen() started.set() conns = [] while not finish: r, w, e = select.select([server], [], [], 0.1) if server in r: # Let the socket hang around rather than having # it closed by garbage collection. conns.append(server.accept()[0]) for sock in conns: sock.close() t = threading.Thread(target=serve) t.start() started.wait() try: try: c = socket.socket(socket.AF_INET) c.settimeout(0.2) c.connect((host, port)) # Will attempt handshake and time out self.assertRaisesRegex(socket.timeout, "timed out", test_wrap_socket, c) finally: c.close() try: c = socket.socket(socket.AF_INET) c = test_wrap_socket(c) c.settimeout(0.2) # Will attempt handshake and time out self.assertRaisesRegex(socket.timeout, "timed out", c.connect, (host, port)) finally: c.close() finally: finish = True t.join() server.close() def test_server_accept(self): # Issue #16357: accept() on a SSLSocket created through # SSLContext.wrap_socket(). context = ssl.SSLContext(ssl.PROTOCOL_TLS) context.verify_mode = ssl.CERT_REQUIRED context.load_verify_locations(SIGNING_CA) context.load_cert_chain(SIGNED_CERTFILE) server = socket.socket(socket.AF_INET) host = "127.0.0.1" port = socket_helper.bind_port(server) server = context.wrap_socket(server, server_side=True) self.assertTrue(server.server_side) evt = threading.Event() remote = None peer = None def serve(): nonlocal remote, peer server.listen() # Block on the accept and wait on the connection to close. evt.set() remote, peer = server.accept() remote.send(remote.recv(4)) t = threading.Thread(target=serve) t.start() # Client wait until server setup and perform a connect. evt.wait() client = context.wrap_socket(socket.socket()) client.connect((host, port)) client.send(b'data') client.recv() client_addr = client.getsockname() client.close() t.join() remote.close() server.close() # Sanity checks. self.assertIsInstance(remote, ssl.SSLSocket) self.assertEqual(peer, client_addr) def test_getpeercert_enotconn(self): context = ssl.SSLContext(ssl.PROTOCOL_TLS) with context.wrap_socket(socket.socket()) as sock: with self.assertRaises(OSError) as cm: sock.getpeercert() self.assertEqual(cm.exception.errno, errno.ENOTCONN) def test_do_handshake_enotconn(self): context = ssl.SSLContext(ssl.PROTOCOL_TLS) with context.wrap_socket(socket.socket()) as sock: with self.assertRaises(OSError) as cm: sock.do_handshake() self.assertEqual(cm.exception.errno, errno.ENOTCONN) def test_no_shared_ciphers(self): client_context, server_context, hostname = testing_context() # OpenSSL enables all TLS 1.3 ciphers, enforce TLS 1.2 for test client_context.options |= ssl.OP_NO_TLSv1_3 # Force different suites on client and server client_context.set_ciphers("AES128") server_context.set_ciphers("AES256") with ThreadedEchoServer(context=server_context) as server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: with self.assertRaises(OSError): s.connect((HOST, server.port)) self.assertIn("no shared cipher", server.conn_errors[0]) def test_version_basic(self): """ Basic tests for SSLSocket.version(). More tests are done in the test_protocol_*() methods. """ context = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) context.check_hostname = False context.verify_mode = ssl.CERT_NONE with ThreadedEchoServer(CERTFILE, ssl_version=ssl.PROTOCOL_TLS_SERVER, chatty=False) as server: with context.wrap_socket(socket.socket()) as s: self.assertIs(s.version(), None) self.assertIs(s._sslobj, None) s.connect((HOST, server.port)) if IS_OPENSSL_1_1_1 and has_tls_version('TLSv1_3'): self.assertEqual(s.version(), 'TLSv1.3') elif ssl.OPENSSL_VERSION_INFO >= (1, 0, 2): self.assertEqual(s.version(), 'TLSv1.2') else: # 0.9.8 to 1.0.1 self.assertIn(s.version(), ('TLSv1', 'TLSv1.2')) self.assertIs(s._sslobj, None) self.assertIs(s.version(), None) @requires_tls_version('TLSv1_3') def test_tls1_3(self): context = ssl.SSLContext(ssl.PROTOCOL_TLS) context.load_cert_chain(CERTFILE) context.options |= ( ssl.OP_NO_TLSv1 | ssl.OP_NO_TLSv1_1 | ssl.OP_NO_TLSv1_2 ) with ThreadedEchoServer(context=context) as server: with context.wrap_socket(socket.socket()) as s: s.connect((HOST, server.port)) self.assertIn(s.cipher()[0], { 'TLS_AES_256_GCM_SHA384', 'TLS_CHACHA20_POLY1305_SHA256', 'TLS_AES_128_GCM_SHA256', }) self.assertEqual(s.version(), 'TLSv1.3') @requires_minimum_version @requires_tls_version('TLSv1_2') def test_min_max_version_tlsv1_2(self): client_context, server_context, hostname = testing_context() # client TLSv1.0 to 1.2 client_context.minimum_version = ssl.TLSVersion.TLSv1 client_context.maximum_version = ssl.TLSVersion.TLSv1_2 # server only TLSv1.2 server_context.minimum_version = ssl.TLSVersion.TLSv1_2 server_context.maximum_version = ssl.TLSVersion.TLSv1_2 with ThreadedEchoServer(context=server_context) as server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) self.assertEqual(s.version(), 'TLSv1.2') @requires_minimum_version @requires_tls_version('TLSv1_1') def test_min_max_version_tlsv1_1(self): client_context, server_context, hostname = testing_context() # client 1.0 to 1.2, server 1.0 to 1.1 client_context.minimum_version = ssl.TLSVersion.TLSv1 client_context.maximum_version = ssl.TLSVersion.TLSv1_2 server_context.minimum_version = ssl.TLSVersion.TLSv1 server_context.maximum_version = ssl.TLSVersion.TLSv1_1 with ThreadedEchoServer(context=server_context) as server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) self.assertEqual(s.version(), 'TLSv1.1') @requires_minimum_version @requires_tls_version('TLSv1_2') @requires_tls_version('TLSv1') def test_min_max_version_mismatch(self): client_context, server_context, hostname = testing_context() # client 1.0, server 1.2 (mismatch) server_context.maximum_version = ssl.TLSVersion.TLSv1_2 server_context.minimum_version = ssl.TLSVersion.TLSv1_2 client_context.maximum_version = ssl.TLSVersion.TLSv1 client_context.minimum_version = ssl.TLSVersion.TLSv1 with ThreadedEchoServer(context=server_context) as server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: with self.assertRaises(ssl.SSLError) as e: s.connect((HOST, server.port)) self.assertIn("alert", str(e.exception)) @requires_minimum_version @requires_tls_version('SSLv3') def test_min_max_version_sslv3(self): client_context, server_context, hostname = testing_context() server_context.minimum_version = ssl.TLSVersion.SSLv3 client_context.minimum_version = ssl.TLSVersion.SSLv3 client_context.maximum_version = ssl.TLSVersion.SSLv3 with ThreadedEchoServer(context=server_context) as server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) self.assertEqual(s.version(), 'SSLv3') @unittest.skipUnless(ssl.HAS_ECDH, "test requires ECDH-enabled OpenSSL") def test_default_ecdh_curve(self): # Issue #21015: elliptic curve-based Diffie Hellman key exchange # should be enabled by default on SSL contexts. context = ssl.SSLContext(ssl.PROTOCOL_TLS) context.load_cert_chain(CERTFILE) # TLSv1.3 defaults to PFS key agreement and no longer has KEA in # cipher name. context.options |= ssl.OP_NO_TLSv1_3 # Prior to OpenSSL 1.0.0, ECDH ciphers have to be enabled # explicitly using the 'ECCdraft' cipher alias. Otherwise, # our default cipher list should prefer ECDH-based ciphers # automatically. if ssl.OPENSSL_VERSION_INFO < (1, 0, 0): context.set_ciphers("ECCdraft:ECDH") with ThreadedEchoServer(context=context) as server: with context.wrap_socket(socket.socket()) as s: s.connect((HOST, server.port)) self.assertIn("ECDH", s.cipher()[0]) @unittest.skipUnless("tls-unique" in ssl.CHANNEL_BINDING_TYPES, "'tls-unique' channel binding not available") def test_tls_unique_channel_binding(self): """Test tls-unique channel binding.""" if support.verbose: sys.stdout.write("\n") client_context, server_context, hostname = testing_context() server = ThreadedEchoServer(context=server_context, chatty=True, connectionchatty=False) with server: with client_context.wrap_socket( socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) # get the data cb_data = s.get_channel_binding("tls-unique") if support.verbose: sys.stdout.write( " got channel binding data: {0!r}\n".format(cb_data)) # check if it is sane self.assertIsNotNone(cb_data) if s.version() == 'TLSv1.3': self.assertEqual(len(cb_data), 48) else: self.assertEqual(len(cb_data), 12) # True for TLSv1 # and compare with the peers version s.write(b"CB tls-unique\n") peer_data_repr = s.read().strip() self.assertEqual(peer_data_repr, repr(cb_data).encode("us-ascii")) # now, again with client_context.wrap_socket( socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) new_cb_data = s.get_channel_binding("tls-unique") if support.verbose: sys.stdout.write( "got another channel binding data: {0!r}\n".format( new_cb_data) ) # is it really unique self.assertNotEqual(cb_data, new_cb_data) self.assertIsNotNone(cb_data) if s.version() == 'TLSv1.3': self.assertEqual(len(cb_data), 48) else: self.assertEqual(len(cb_data), 12) # True for TLSv1 s.write(b"CB tls-unique\n") peer_data_repr = s.read().strip() self.assertEqual(peer_data_repr, repr(new_cb_data).encode("us-ascii")) def test_compression(self): client_context, server_context, hostname = testing_context() stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) if support.verbose: sys.stdout.write(" got compression: {!r}\n".format(stats['compression'])) self.assertIn(stats['compression'], { None, 'ZLIB', 'RLE' }) @unittest.skipUnless(hasattr(ssl, 'OP_NO_COMPRESSION'), "ssl.OP_NO_COMPRESSION needed for this test") def test_compression_disabled(self): client_context, server_context, hostname = testing_context() client_context.options |= ssl.OP_NO_COMPRESSION server_context.options |= ssl.OP_NO_COMPRESSION stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) self.assertIs(stats['compression'], None) @unittest.skipIf(Py_DEBUG_WIN32, "Avoid mixing debug/release CRT on Windows") def test_dh_params(self): # Check we can get a connection with ephemeral Diffie-Hellman client_context, server_context, hostname = testing_context() # test scenario needs TLS <= 1.2 client_context.options |= ssl.OP_NO_TLSv1_3 server_context.load_dh_params(DHFILE) server_context.set_ciphers("kEDH") server_context.options |= ssl.OP_NO_TLSv1_3 stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) cipher = stats["cipher"][0] parts = cipher.split("-") if "ADH" not in parts and "EDH" not in parts and "DHE" not in parts: self.fail("Non-DH cipher: " + cipher[0]) @unittest.skipUnless(HAVE_SECP_CURVES, "needs secp384r1 curve support") @unittest.skipIf(IS_OPENSSL_1_1_1, "TODO: Test doesn't work on 1.1.1") def test_ecdh_curve(self): # server secp384r1, client auto client_context, server_context, hostname = testing_context() server_context.set_ecdh_curve("secp384r1") server_context.set_ciphers("ECDHE:!eNULL:!aNULL") server_context.options |= ssl.OP_NO_TLSv1 | ssl.OP_NO_TLSv1_1 stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) # server auto, client secp384r1 client_context, server_context, hostname = testing_context() client_context.set_ecdh_curve("secp384r1") server_context.set_ciphers("ECDHE:!eNULL:!aNULL") server_context.options |= ssl.OP_NO_TLSv1 | ssl.OP_NO_TLSv1_1 stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) # server / client curve mismatch client_context, server_context, hostname = testing_context() client_context.set_ecdh_curve("prime256v1") server_context.set_ecdh_curve("secp384r1") server_context.set_ciphers("ECDHE:!eNULL:!aNULL") server_context.options |= ssl.OP_NO_TLSv1 | ssl.OP_NO_TLSv1_1 try: stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) except ssl.SSLError: pass else: # OpenSSL 1.0.2 does not fail although it should. if IS_OPENSSL_1_1_0: self.fail("mismatch curve did not fail") def test_selected_alpn_protocol(self): # selected_alpn_protocol() is None unless ALPN is used. client_context, server_context, hostname = testing_context() stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) self.assertIs(stats['client_alpn_protocol'], None) @unittest.skipUnless(ssl.HAS_ALPN, "ALPN support required") def test_selected_alpn_protocol_if_server_uses_alpn(self): # selected_alpn_protocol() is None unless ALPN is used by the client. client_context, server_context, hostname = testing_context() server_context.set_alpn_protocols(['foo', 'bar']) stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) self.assertIs(stats['client_alpn_protocol'], None) @unittest.skipUnless(ssl.HAS_ALPN, "ALPN support needed for this test") def test_alpn_protocols(self): server_protocols = ['foo', 'bar', 'milkshake'] protocol_tests = [ (['foo', 'bar'], 'foo'), (['bar', 'foo'], 'foo'), (['milkshake'], 'milkshake'), (['http/3.0', 'http/4.0'], None) ] for client_protocols, expected in protocol_tests: client_context, server_context, hostname = testing_context() server_context.set_alpn_protocols(server_protocols) client_context.set_alpn_protocols(client_protocols) try: stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) except ssl.SSLError as e: stats = e if (expected is None and IS_OPENSSL_1_1_0 and ssl.OPENSSL_VERSION_INFO < (1, 1, 0, 6)): # OpenSSL 1.1.0 to 1.1.0e raises handshake error self.assertIsInstance(stats, ssl.SSLError) else: msg = "failed trying %s (s) and %s (c).\n" \ "was expecting %s, but got %%s from the %%s" \ % (str(server_protocols), str(client_protocols), str(expected)) client_result = stats['client_alpn_protocol'] self.assertEqual(client_result, expected, msg % (client_result, "client")) server_result = stats['server_alpn_protocols'][-1] \ if len(stats['server_alpn_protocols']) else 'nothing' self.assertEqual(server_result, expected, msg % (server_result, "server")) def test_selected_npn_protocol(self): # selected_npn_protocol() is None unless NPN is used client_context, server_context, hostname = testing_context() stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) self.assertIs(stats['client_npn_protocol'], None) @unittest.skipUnless(ssl.HAS_NPN, "NPN support needed for this test") def test_npn_protocols(self): server_protocols = ['http/1.1', 'spdy/2'] protocol_tests = [ (['http/1.1', 'spdy/2'], 'http/1.1'), (['spdy/2', 'http/1.1'], 'http/1.1'), (['spdy/2', 'test'], 'spdy/2'), (['abc', 'def'], 'abc') ] for client_protocols, expected in protocol_tests: client_context, server_context, hostname = testing_context() server_context.set_npn_protocols(server_protocols) client_context.set_npn_protocols(client_protocols) stats = server_params_test(client_context, server_context, chatty=True, connectionchatty=True, sni_name=hostname) msg = "failed trying %s (s) and %s (c).\n" \ "was expecting %s, but got %%s from the %%s" \ % (str(server_protocols), str(client_protocols), str(expected)) client_result = stats['client_npn_protocol'] self.assertEqual(client_result, expected, msg % (client_result, "client")) server_result = stats['server_npn_protocols'][-1] \ if len(stats['server_npn_protocols']) else 'nothing' self.assertEqual(server_result, expected, msg % (server_result, "server")) def sni_contexts(self): server_context = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) server_context.load_cert_chain(SIGNED_CERTFILE) other_context = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) other_context.load_cert_chain(SIGNED_CERTFILE2) client_context = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) client_context.load_verify_locations(SIGNING_CA) return server_context, other_context, client_context def check_common_name(self, stats, name): cert = stats['peercert'] self.assertIn((('commonName', name),), cert['subject']) @needs_sni def test_sni_callback(self): calls = [] server_context, other_context, client_context = self.sni_contexts() client_context.check_hostname = False def servername_cb(ssl_sock, server_name, initial_context): calls.append((server_name, initial_context)) if server_name is not None: ssl_sock.context = other_context server_context.set_servername_callback(servername_cb) stats = server_params_test(client_context, server_context, chatty=True, sni_name='supermessage') # The hostname was fetched properly, and the certificate was # changed for the connection. self.assertEqual(calls, [("supermessage", server_context)]) # CERTFILE4 was selected self.check_common_name(stats, 'fakehostname') calls = [] # The callback is called with server_name=None stats = server_params_test(client_context, server_context, chatty=True, sni_name=None) self.assertEqual(calls, [(None, server_context)]) self.check_common_name(stats, SIGNED_CERTFILE_HOSTNAME) # Check disabling the callback calls = [] server_context.set_servername_callback(None) stats = server_params_test(client_context, server_context, chatty=True, sni_name='notfunny') # Certificate didn't change self.check_common_name(stats, SIGNED_CERTFILE_HOSTNAME) self.assertEqual(calls, []) @needs_sni def test_sni_callback_alert(self): # Returning a TLS alert is reflected to the connecting client server_context, other_context, client_context = self.sni_contexts() def cb_returning_alert(ssl_sock, server_name, initial_context): return ssl.ALERT_DESCRIPTION_ACCESS_DENIED server_context.set_servername_callback(cb_returning_alert) with self.assertRaises(ssl.SSLError) as cm: stats = server_params_test(client_context, server_context, chatty=False, sni_name='supermessage') self.assertEqual(cm.exception.reason, 'TLSV1_ALERT_ACCESS_DENIED') @needs_sni def test_sni_callback_raising(self): # Raising fails the connection with a TLS handshake failure alert. server_context, other_context, client_context = self.sni_contexts() def cb_raising(ssl_sock, server_name, initial_context): 1/0 server_context.set_servername_callback(cb_raising) with support.catch_unraisable_exception() as catch: with self.assertRaises(ssl.SSLError) as cm: stats = server_params_test(client_context, server_context, chatty=False, sni_name='supermessage') self.assertEqual(cm.exception.reason, 'SSLV3_ALERT_HANDSHAKE_FAILURE') self.assertEqual(catch.unraisable.exc_type, ZeroDivisionError) @needs_sni def test_sni_callback_wrong_return_type(self): # Returning the wrong return type terminates the TLS connection # with an internal error alert. server_context, other_context, client_context = self.sni_contexts() def cb_wrong_return_type(ssl_sock, server_name, initial_context): return "foo" server_context.set_servername_callback(cb_wrong_return_type) with support.catch_unraisable_exception() as catch: with self.assertRaises(ssl.SSLError) as cm: stats = server_params_test(client_context, server_context, chatty=False, sni_name='supermessage') self.assertEqual(cm.exception.reason, 'TLSV1_ALERT_INTERNAL_ERROR') self.assertEqual(catch.unraisable.exc_type, TypeError) def test_shared_ciphers(self): client_context, server_context, hostname = testing_context() client_context.set_ciphers("AES128:AES256") server_context.set_ciphers("AES256") expected_algs = [ "AES256", "AES-256", # TLS 1.3 ciphers are always enabled "TLS_CHACHA20", "TLS_AES", ] stats = server_params_test(client_context, server_context, sni_name=hostname) ciphers = stats['server_shared_ciphers'][0] self.assertGreater(len(ciphers), 0) for name, tls_version, bits in ciphers: if not any(alg in name for alg in expected_algs): self.fail(name) def test_read_write_after_close_raises_valuerror(self): client_context, server_context, hostname = testing_context() server = ThreadedEchoServer(context=server_context, chatty=False) with server: s = client_context.wrap_socket(socket.socket(), server_hostname=hostname) s.connect((HOST, server.port)) s.close() self.assertRaises(ValueError, s.read, 1024) self.assertRaises(ValueError, s.write, b'hello') def test_sendfile(self): TEST_DATA = b"x" * 512 with open(support.TESTFN, 'wb') as f: f.write(TEST_DATA) self.addCleanup(support.unlink, support.TESTFN) context = ssl.SSLContext(ssl.PROTOCOL_TLS) context.verify_mode = ssl.CERT_REQUIRED context.load_verify_locations(SIGNING_CA) context.load_cert_chain(SIGNED_CERTFILE) server = ThreadedEchoServer(context=context, chatty=False) with server: with context.wrap_socket(socket.socket()) as s: s.connect((HOST, server.port)) with open(support.TESTFN, 'rb') as file: s.sendfile(file) self.assertEqual(s.recv(1024), TEST_DATA) def test_session(self): client_context, server_context, hostname = testing_context() # TODO: sessions aren't compatible with TLSv1.3 yet client_context.options |= ssl.OP_NO_TLSv1_3 # first connection without session stats = server_params_test(client_context, server_context, sni_name=hostname) session = stats['session'] self.assertTrue(session.id) self.assertGreater(session.time, 0) self.assertGreater(session.timeout, 0) self.assertTrue(session.has_ticket) if ssl.OPENSSL_VERSION_INFO > (1, 0, 1): self.assertGreater(session.ticket_lifetime_hint, 0) self.assertFalse(stats['session_reused']) sess_stat = server_context.session_stats() self.assertEqual(sess_stat['accept'], 1) self.assertEqual(sess_stat['hits'], 0) # reuse session stats = server_params_test(client_context, server_context, session=session, sni_name=hostname) sess_stat = server_context.session_stats() self.assertEqual(sess_stat['accept'], 2) self.assertEqual(sess_stat['hits'], 1) self.assertTrue(stats['session_reused']) session2 = stats['session'] self.assertEqual(session2.id, session.id) self.assertEqual(session2, session) self.assertIsNot(session2, session) self.assertGreaterEqual(session2.time, session.time) self.assertGreaterEqual(session2.timeout, session.timeout) # another one without session stats = server_params_test(client_context, server_context, sni_name=hostname) self.assertFalse(stats['session_reused']) session3 = stats['session'] self.assertNotEqual(session3.id, session.id) self.assertNotEqual(session3, session) sess_stat = server_context.session_stats() self.assertEqual(sess_stat['accept'], 3) self.assertEqual(sess_stat['hits'], 1) # reuse session again stats = server_params_test(client_context, server_context, session=session, sni_name=hostname) self.assertTrue(stats['session_reused']) session4 = stats['session'] self.assertEqual(session4.id, session.id) self.assertEqual(session4, session) self.assertGreaterEqual(session4.time, session.time) self.assertGreaterEqual(session4.timeout, session.timeout) sess_stat = server_context.session_stats() self.assertEqual(sess_stat['accept'], 4) self.assertEqual(sess_stat['hits'], 2) def test_session_handling(self): client_context, server_context, hostname = testing_context() client_context2, _, _ = testing_context() # TODO: session reuse does not work with TLSv1.3 client_context.options |= ssl.OP_NO_TLSv1_3 client_context2.options |= ssl.OP_NO_TLSv1_3 server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: # session is None before handshake self.assertEqual(s.session, None) self.assertEqual(s.session_reused, None) s.connect((HOST, server.port)) session = s.session self.assertTrue(session) with self.assertRaises(TypeError) as e: s.session = object self.assertEqual(str(e.exception), 'Value is not a SSLSession.') with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) # cannot set session after handshake with self.assertRaises(ValueError) as e: s.session = session self.assertEqual(str(e.exception), 'Cannot set session after handshake.') with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: # can set session before handshake and before the # connection was established s.session = session s.connect((HOST, server.port)) self.assertEqual(s.session.id, session.id) self.assertEqual(s.session, session) self.assertEqual(s.session_reused, True) with client_context2.wrap_socket(socket.socket(), server_hostname=hostname) as s: # cannot re-use session with a different SSLContext with self.assertRaises(ValueError) as e: s.session = session s.connect((HOST, server.port)) self.assertEqual(str(e.exception), 'Session refers to a different SSLContext.') @unittest.skipUnless(has_tls_version('TLSv1_3'), "Test needs TLS 1.3") class TestPostHandshakeAuth(unittest.TestCase): def test_pha_setter(self): protocols = [ ssl.PROTOCOL_TLS, ssl.PROTOCOL_TLS_SERVER, ssl.PROTOCOL_TLS_CLIENT ] for protocol in protocols: ctx = ssl.SSLContext(protocol) self.assertEqual(ctx.post_handshake_auth, False) ctx.post_handshake_auth = True self.assertEqual(ctx.post_handshake_auth, True) ctx.verify_mode = ssl.CERT_REQUIRED self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) self.assertEqual(ctx.post_handshake_auth, True) ctx.post_handshake_auth = False self.assertEqual(ctx.verify_mode, ssl.CERT_REQUIRED) self.assertEqual(ctx.post_handshake_auth, False) ctx.verify_mode = ssl.CERT_OPTIONAL ctx.post_handshake_auth = True self.assertEqual(ctx.verify_mode, ssl.CERT_OPTIONAL) self.assertEqual(ctx.post_handshake_auth, True) def test_pha_required(self): client_context, server_context, hostname = testing_context() server_context.post_handshake_auth = True server_context.verify_mode = ssl.CERT_REQUIRED client_context.post_handshake_auth = True client_context.load_cert_chain(SIGNED_CERTFILE) server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'FALSE\n') s.write(b'PHA') self.assertEqual(s.recv(1024), b'OK\n') s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'TRUE\n') # PHA method just returns true when cert is already available s.write(b'PHA') self.assertEqual(s.recv(1024), b'OK\n') s.write(b'GETCERT') cert_text = s.recv(4096).decode('us-ascii') self.assertIn('Python Software Foundation CA', cert_text) def test_pha_required_nocert(self): client_context, server_context, hostname = testing_context() server_context.post_handshake_auth = True server_context.verify_mode = ssl.CERT_REQUIRED client_context.post_handshake_auth = True # Ignore expected SSLError in ConnectionHandler of ThreadedEchoServer # (it is only raised sometimes on Windows) with support.catch_threading_exception() as cm: server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) s.write(b'PHA') # receive CertificateRequest self.assertEqual(s.recv(1024), b'OK\n') # send empty Certificate + Finish s.write(b'HASCERT') # receive alert with self.assertRaisesRegex( ssl.SSLError, 'tlsv13 alert certificate required'): s.recv(1024) def test_pha_optional(self): if support.verbose: sys.stdout.write("\n") client_context, server_context, hostname = testing_context() server_context.post_handshake_auth = True server_context.verify_mode = ssl.CERT_REQUIRED client_context.post_handshake_auth = True client_context.load_cert_chain(SIGNED_CERTFILE) # check CERT_OPTIONAL server_context.verify_mode = ssl.CERT_OPTIONAL server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'FALSE\n') s.write(b'PHA') self.assertEqual(s.recv(1024), b'OK\n') s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'TRUE\n') def test_pha_optional_nocert(self): if support.verbose: sys.stdout.write("\n") client_context, server_context, hostname = testing_context() server_context.post_handshake_auth = True server_context.verify_mode = ssl.CERT_OPTIONAL client_context.post_handshake_auth = True server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'FALSE\n') s.write(b'PHA') self.assertEqual(s.recv(1024), b'OK\n') # optional doesn't fail when client does not have a cert s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'FALSE\n') def test_pha_no_pha_client(self): client_context, server_context, hostname = testing_context() server_context.post_handshake_auth = True server_context.verify_mode = ssl.CERT_REQUIRED client_context.load_cert_chain(SIGNED_CERTFILE) server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) with self.assertRaisesRegex(ssl.SSLError, 'not server'): s.verify_client_post_handshake() s.write(b'PHA') self.assertIn(b'extension not received', s.recv(1024)) def test_pha_no_pha_server(self): # server doesn't have PHA enabled, cert is requested in handshake client_context, server_context, hostname = testing_context() server_context.verify_mode = ssl.CERT_REQUIRED client_context.post_handshake_auth = True client_context.load_cert_chain(SIGNED_CERTFILE) server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'TRUE\n') # PHA doesn't fail if there is already a cert s.write(b'PHA') self.assertEqual(s.recv(1024), b'OK\n') s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'TRUE\n') def test_pha_not_tls13(self): # TLS 1.2 client_context, server_context, hostname = testing_context() server_context.verify_mode = ssl.CERT_REQUIRED client_context.maximum_version = ssl.TLSVersion.TLSv1_2 client_context.post_handshake_auth = True client_context.load_cert_chain(SIGNED_CERTFILE) server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) # PHA fails for TLS != 1.3 s.write(b'PHA') self.assertIn(b'WRONG_SSL_VERSION', s.recv(1024)) def test_bpo37428_pha_cert_none(self): # verify that post_handshake_auth does not implicitly enable cert # validation. hostname = SIGNED_CERTFILE_HOSTNAME client_context = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) client_context.post_handshake_auth = True client_context.load_cert_chain(SIGNED_CERTFILE) # no cert validation and CA on client side client_context.check_hostname = False client_context.verify_mode = ssl.CERT_NONE server_context = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) server_context.load_cert_chain(SIGNED_CERTFILE) server_context.load_verify_locations(SIGNING_CA) server_context.post_handshake_auth = True server_context.verify_mode = ssl.CERT_REQUIRED server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'FALSE\n') s.write(b'PHA') self.assertEqual(s.recv(1024), b'OK\n') s.write(b'HASCERT') self.assertEqual(s.recv(1024), b'TRUE\n') # server cert has not been validated self.assertEqual(s.getpeercert(), {}) HAS_KEYLOG = hasattr(ssl.SSLContext, 'keylog_filename') requires_keylog = unittest.skipUnless( HAS_KEYLOG, 'test requires OpenSSL 1.1.1 with keylog callback') class TestSSLDebug(unittest.TestCase): def keylog_lines(self, fname=support.TESTFN): with open(fname) as f: return len(list(f)) @requires_keylog @unittest.skipIf(Py_DEBUG_WIN32, "Avoid mixing debug/release CRT on Windows") def test_keylog_defaults(self): self.addCleanup(support.unlink, support.TESTFN) ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertEqual(ctx.keylog_filename, None) self.assertFalse(os.path.isfile(support.TESTFN)) ctx.keylog_filename = support.TESTFN self.assertEqual(ctx.keylog_filename, support.TESTFN) self.assertTrue(os.path.isfile(support.TESTFN)) self.assertEqual(self.keylog_lines(), 1) ctx.keylog_filename = None self.assertEqual(ctx.keylog_filename, None) with self.assertRaises((IsADirectoryError, PermissionError)): # Windows raises PermissionError ctx.keylog_filename = os.path.dirname( os.path.abspath(support.TESTFN)) with self.assertRaises(TypeError): ctx.keylog_filename = 1 @requires_keylog @unittest.skipIf(Py_DEBUG_WIN32, "Avoid mixing debug/release CRT on Windows") def test_keylog_filename(self): self.addCleanup(support.unlink, support.TESTFN) client_context, server_context, hostname = testing_context() client_context.keylog_filename = support.TESTFN server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) # header, 5 lines for TLS 1.3 self.assertEqual(self.keylog_lines(), 6) client_context.keylog_filename = None server_context.keylog_filename = support.TESTFN server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) self.assertGreaterEqual(self.keylog_lines(), 11) client_context.keylog_filename = support.TESTFN server_context.keylog_filename = support.TESTFN server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) self.assertGreaterEqual(self.keylog_lines(), 21) client_context.keylog_filename = None server_context.keylog_filename = None @requires_keylog @unittest.skipIf(sys.flags.ignore_environment, "test is not compatible with ignore_environment") @unittest.skipIf(Py_DEBUG_WIN32, "Avoid mixing debug/release CRT on Windows") def test_keylog_env(self): self.addCleanup(support.unlink, support.TESTFN) with unittest.mock.patch.dict(os.environ): os.environ['SSLKEYLOGFILE'] = support.TESTFN self.assertEqual(os.environ['SSLKEYLOGFILE'], support.TESTFN) ctx = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) self.assertEqual(ctx.keylog_filename, None) ctx = ssl.create_default_context() self.assertEqual(ctx.keylog_filename, support.TESTFN) ctx = ssl._create_stdlib_context() self.assertEqual(ctx.keylog_filename, support.TESTFN) def test_msg_callback(self): client_context, server_context, hostname = testing_context() def msg_cb(conn, direction, version, content_type, msg_type, data): pass self.assertIs(client_context._msg_callback, None) client_context._msg_callback = msg_cb self.assertIs(client_context._msg_callback, msg_cb) with self.assertRaises(TypeError): client_context._msg_callback = object() def test_msg_callback_tls12(self): client_context, server_context, hostname = testing_context() client_context.options |= ssl.OP_NO_TLSv1_3 msg = [] def msg_cb(conn, direction, version, content_type, msg_type, data): self.assertIsInstance(conn, ssl.SSLSocket) self.assertIsInstance(data, bytes) self.assertIn(direction, {'read', 'write'}) msg.append((direction, version, content_type, msg_type)) client_context._msg_callback = msg_cb server = ThreadedEchoServer(context=server_context, chatty=False) with server: with client_context.wrap_socket(socket.socket(), server_hostname=hostname) as s: s.connect((HOST, server.port)) self.assertIn( ("read", TLSVersion.TLSv1_2, _TLSContentType.HANDSHAKE, _TLSMessageType.SERVER_KEY_EXCHANGE), msg ) self.assertIn( ("write", TLSVersion.TLSv1_2, _TLSContentType.CHANGE_CIPHER_SPEC, _TLSMessageType.CHANGE_CIPHER_SPEC), msg ) def test_main(verbose=False): if support.verbose: plats = { 'Mac': platform.mac_ver, 'Windows': platform.win32_ver, } for name, func in plats.items(): plat = func() if plat and plat[0]: plat = '%s %r' % (name, plat) break else: plat = repr(platform.platform()) print("test_ssl: testing with %r %r" % (ssl.OPENSSL_VERSION, ssl.OPENSSL_VERSION_INFO)) print(" under %s" % plat) print(" HAS_SNI = %r" % ssl.HAS_SNI) print(" OP_ALL = 0x%8x" % ssl.OP_ALL) try: print(" OP_NO_TLSv1_1 = 0x%8x" % ssl.OP_NO_TLSv1_1) except AttributeError: pass for filename in [ CERTFILE, BYTES_CERTFILE, ONLYCERT, ONLYKEY, BYTES_ONLYCERT, BYTES_ONLYKEY, SIGNED_CERTFILE, SIGNED_CERTFILE2, SIGNING_CA, BADCERT, BADKEY, EMPTYCERT]: if not os.path.exists(filename): raise support.TestFailed("Can't read certificate file %r" % filename) tests = [ ContextTests, BasicSocketTests, SSLErrorTests, MemoryBIOTests, SSLObjectTests, SimpleBackgroundTests, ThreadedTests, TestPostHandshakeAuth, TestSSLDebug ] if support.is_resource_enabled('network'): tests.append(NetworkedTests) thread_info = support.threading_setup() try: support.run_unittest(*tests) finally: support.threading_cleanup(*thread_info) if __name__ == "__main__": test_main()