import base64 import datetime import sys import time import unittest import xmlrpclib import SimpleXMLRPCServer import threading import mimetools from test import test_support alist = [{'astring': 'foo@bar.baz.spam', 'afloat': 7283.43, 'anint': 2**20, 'ashortlong': 2, 'anotherlist': ['.zyx.41'], 'abase64': xmlrpclib.Binary(b"my dog has fleas"), 'boolean': False, 'unicode': '\u4000\u6000\u8000', 'ukey\u4000': 'regular value', 'datetime1': xmlrpclib.DateTime('20050210T11:41:23'), 'datetime2': xmlrpclib.DateTime( (2005, 2, 10, 11, 41, 23, 0, 1, -1)), 'datetime3': xmlrpclib.DateTime( datetime.datetime(2005, 2, 10, 11, 41, 23)), 'datetime4': xmlrpclib.DateTime( datetime.date(2005, 2, 10)), 'datetime5': xmlrpclib.DateTime( datetime.time(11, 41, 23)), }] class XMLRPCTestCase(unittest.TestCase): def test_dump_load(self): dump = xmlrpclib.dumps((alist,)) load = xmlrpclib.loads(dump) self.assertEquals(alist, load[0][0]) def test_dump_bare_datetime(self): # This checks that an unwrapped datetime.date object can be handled # by the marshalling code. This can't be done via test_dump_load() # since with use_datetime set to 1 the unmarshaller would create # datetime objects for the 'datetime[123]' keys as well dt = datetime.datetime(2005, 2, 10, 11, 41, 23) s = xmlrpclib.dumps((dt,)) (newdt,), m = xmlrpclib.loads(s, use_datetime=1) self.assertEquals(newdt, dt) self.assertEquals(m, None) (newdt,), m = xmlrpclib.loads(s, use_datetime=0) self.assertEquals(newdt, xmlrpclib.DateTime('20050210T11:41:23')) def test_dump_bare_date(self): # This checks that an unwrapped datetime.date object can be handled # by the marshalling code. This can't be done via test_dump_load() # since the unmarshaller produces a datetime object d = datetime.datetime(2005, 2, 10, 11, 41, 23).date() s = xmlrpclib.dumps((d,)) (newd,), m = xmlrpclib.loads(s, use_datetime=1) self.assertEquals(newd.date(), d) self.assertEquals(newd.time(), datetime.time(0, 0, 0)) self.assertEquals(m, None) (newdt,), m = xmlrpclib.loads(s, use_datetime=0) self.assertEquals(newdt, xmlrpclib.DateTime('20050210T00:00:00')) def test_dump_bare_time(self): # This checks that an unwrapped datetime.time object can be handled # by the marshalling code. This can't be done via test_dump_load() # since the unmarshaller produces a datetime object t = datetime.datetime(2005, 2, 10, 11, 41, 23).time() s = xmlrpclib.dumps((t,)) (newt,), m = xmlrpclib.loads(s, use_datetime=1) today = datetime.datetime.now().date().strftime("%Y%m%d") self.assertEquals(newt.time(), t) self.assertEquals(newt.date(), datetime.datetime.now().date()) self.assertEquals(m, None) (newdt,), m = xmlrpclib.loads(s, use_datetime=0) self.assertEquals(newdt, xmlrpclib.DateTime('%sT11:41:23'%today)) def test_bug_1164912 (self): d = xmlrpclib.DateTime() ((new_d,), dummy) = xmlrpclib.loads(xmlrpclib.dumps((d,), methodresponse=True)) self.assert_(isinstance(new_d.value, str)) # Check that the output of dumps() is still an 8-bit string s = xmlrpclib.dumps((new_d,), methodresponse=True) self.assert_(isinstance(s, str)) def test_newstyle_class(self): class T(object): pass t = T() t.x = 100 t.y = "Hello" ((t2,), dummy) = xmlrpclib.loads(xmlrpclib.dumps((t,))) self.assertEquals(t2, t.__dict__) def test_dump_big_long(self): self.assertRaises(OverflowError, xmlrpclib.dumps, (2**99,)) def test_dump_bad_dict(self): self.assertRaises(TypeError, xmlrpclib.dumps, ({(1,2,3): 1},)) def test_dump_recursive_seq(self): l = [1,2,3] t = [3,4,5,l] l.append(t) self.assertRaises(TypeError, xmlrpclib.dumps, (l,)) def test_dump_recursive_dict(self): d = {'1':1, '2':1} t = {'3':3, 'd':d} d['t'] = t self.assertRaises(TypeError, xmlrpclib.dumps, (d,)) def test_dump_big_int(self): if sys.maxint > 2**31-1: self.assertRaises(OverflowError, xmlrpclib.dumps, (int(2**34),)) xmlrpclib.dumps((xmlrpclib.MAXINT, xmlrpclib.MININT)) self.assertRaises(OverflowError, xmlrpclib.dumps, (xmlrpclib.MAXINT+1,)) self.assertRaises(OverflowError, xmlrpclib.dumps, (xmlrpclib.MININT-1,)) def dummy_write(s): pass m = xmlrpclib.Marshaller() m.dump_int(xmlrpclib.MAXINT, dummy_write) m.dump_int(xmlrpclib.MININT, dummy_write) self.assertRaises(OverflowError, m.dump_int, xmlrpclib.MAXINT+1, dummy_write) self.assertRaises(OverflowError, m.dump_int, xmlrpclib.MININT-1, dummy_write) def test_dump_none(self): value = alist + [None] arg1 = (alist + [None],) strg = xmlrpclib.dumps(arg1, allow_none=True) self.assertEquals(value, xmlrpclib.loads(strg)[0][0]) self.assertRaises(TypeError, xmlrpclib.dumps, (arg1,)) class HelperTestCase(unittest.TestCase): def test_escape(self): self.assertEqual(xmlrpclib.escape("a&b"), "a&b") self.assertEqual(xmlrpclib.escape("ab"), "a>b") class FaultTestCase(unittest.TestCase): def test_repr(self): f = xmlrpclib.Fault(42, 'Test Fault') self.assertEqual(repr(f), "") self.assertEqual(repr(f), str(f)) def test_dump_fault(self): f = xmlrpclib.Fault(42, 'Test Fault') s = xmlrpclib.dumps((f,)) (newf,), m = xmlrpclib.loads(s) self.assertEquals(newf, {'faultCode': 42, 'faultString': 'Test Fault'}) self.assertEquals(m, None) s = xmlrpclib.Marshaller().dumps(f) self.assertRaises(xmlrpclib.Fault, xmlrpclib.loads, s) class DateTimeTestCase(unittest.TestCase): def test_default(self): t = xmlrpclib.DateTime() def test_time(self): d = 1181399930.036952 t = xmlrpclib.DateTime(d) self.assertEqual(str(t), time.strftime("%Y%m%dT%H:%M:%S", time.localtime(d))) def test_time_tuple(self): d = (2007,6,9,10,38,50,5,160,0) t = xmlrpclib.DateTime(d) self.assertEqual(str(t), '20070609T10:38:50') def test_time_struct(self): d = time.localtime(1181399930.036952) t = xmlrpclib.DateTime(d) self.assertEqual(str(t), time.strftime("%Y%m%dT%H:%M:%S", d)) def test_datetime_datetime(self): d = datetime.datetime(2007,1,2,3,4,5) t = xmlrpclib.DateTime(d) self.assertEqual(str(t), '20070102T03:04:05') def test_datetime_date(self): d = datetime.date(2007,9,8) t = xmlrpclib.DateTime(d) self.assertEqual(str(t), '20070908T00:00:00') def test_datetime_time(self): d = datetime.time(13,17,19) # allow for date rollover by checking today's or tomorrow's dates dd1 = datetime.datetime.now().date() dd2 = dd1 + datetime.timedelta(days=1) vals = (dd1.strftime('%Y%m%dT13:17:19'), dd2.strftime('%Y%m%dT13:17:19')) t = xmlrpclib.DateTime(d) self.assertEqual(str(t) in vals, True) def test_repr(self): d = datetime.datetime(2007,1,2,3,4,5) t = xmlrpclib.DateTime(d) val ="" % id(t) self.assertEqual(repr(t), val) def test_decode(self): d = ' 20070908T07:11:13 ' t1 = xmlrpclib.DateTime() t1.decode(d) tref = xmlrpclib.DateTime(datetime.datetime(2007,9,8,7,11,13)) self.assertEqual(t1, tref) t2 = xmlrpclib._datetime(d) self.assertEqual(t1, tref) class BinaryTestCase(unittest.TestCase): # XXX What should str(Binary(b"\xff")) return? I'm chosing "\xff" # for now (i.e. interpreting the binary data as Latin-1-encoded # text). But this feels very unsatisfactory. Perhaps we should # only define repr(), and return r"Binary(b'\xff')" instead? def test_default(self): t = xmlrpclib.Binary() self.assertEqual(str(t), '') def test_string(self): d = b'\x01\x02\x03abc123\xff\xfe' t = xmlrpclib.Binary(d) self.assertEqual(str(t), str(d, "latin-1")) def test_decode(self): d = b'\x01\x02\x03abc123\xff\xfe' de = base64.encodestring(d) t1 = xmlrpclib.Binary() t1.decode(de) self.assertEqual(str(t1), str(d, "latin-1")) t2 = xmlrpclib._binary(de) self.assertEqual(str(t2), str(d, "latin-1")) PORT = None def http_server(evt, numrequests): class TestInstanceClass: def div(self, x, y): '''This is the div function''' return x // y try: serv = SimpleXMLRPCServer.SimpleXMLRPCServer(("localhost", 0), logRequests=False, bind_and_activate=False) serv.server_bind() global PORT PORT = serv.socket.getsockname()[1] serv.server_activate() serv.register_introspection_functions() serv.register_multicall_functions() serv.register_function(pow) serv.register_function(lambda x,y: x+y, 'add') serv.register_instance(TestInstanceClass()) # handle up to 'numrequests' requests while numrequests > 0: serv.handle_request() numrequests -= 1 except socket.timeout: pass finally: serv.socket.close() PORT = None evt.set() class SimpleServerTestCase(unittest.TestCase): def setUp(self): # enable traceback reporting SimpleXMLRPCServer.SimpleXMLRPCServer._send_traceback_header = True self.evt = threading.Event() # start server thread to handle requests serv_args = (self.evt, 1) threading.Thread(target=http_server, args=serv_args).start() # wait for port to be assigned to server n = 1000 while n > 0 and PORT is None: time.sleep(0.001) n -= 1 time.sleep(0.5) def tearDown(self): # wait on the server thread to terminate self.evt.wait() # disable traceback reporting SimpleXMLRPCServer.SimpleXMLRPCServer._send_traceback_header = False def test_simple1(self): try: p = xmlrpclib.ServerProxy('http://localhost:%d' % PORT) self.assertEqual(p.pow(6,8), 6**8) except xmlrpclib.ProtocolError as e: # protocol error; provide additional information in test output self.fail("%s\n%s" % (e, e.headers)) def test_introspection1(self): try: p = xmlrpclib.ServerProxy('http://localhost:%d' % PORT) meth = p.system.listMethods() expected_methods = set(['pow', 'div', 'add', 'system.listMethods', 'system.methodHelp', 'system.methodSignature', 'system.multicall']) self.assertEqual(set(meth), expected_methods) except xmlrpclib.ProtocolError as e: # protocol error; provide additional information in test output self.fail("%s\n%s" % (e, e.headers)) def test_introspection2(self): try: p = xmlrpclib.ServerProxy('http://localhost:%d' % PORT) divhelp = p.system.methodHelp('div') self.assertEqual(divhelp, 'This is the div function') except xmlrpclib.ProtocolError as e: # protocol error; provide additional information in test output self.fail("%s\n%s" % (e, e.headers)) def test_introspection3(self): # the SimpleXMLRPCServer doesn't support signatures, but # at least check that we can try making the call try: p = xmlrpclib.ServerProxy('http://localhost:%d' % PORT) divsig = p.system.methodSignature('div') self.assertEqual(divsig, 'signatures not supported') except xmlrpclib.ProtocolError as e: # protocol error; provide additional information in test output self.fail("%s\n%s" % (e, e.headers)) def test_multicall(self): try: p = xmlrpclib.ServerProxy('http://localhost:%d' % PORT) multicall = xmlrpclib.MultiCall(p) multicall.add(2,3) multicall.pow(6,8) multicall.div(127,42) add_result, pow_result, div_result = multicall() self.assertEqual(add_result, 2+3) self.assertEqual(pow_result, 6**8) self.assertEqual(div_result, 127//42) except xmlrpclib.ProtocolError as e: # protocol error; provide additional information in test output self.fail("%s\n%s" % (e, e.headers)) # This is a contrived way to make a failure occur on the server side # in order to test the _send_traceback_header flag on the server class FailingMessageClass(mimetools.Message): def __getitem__(self, key): key = key.lower() if key == 'content-length': return 'I am broken' return mimetools.Message.__getitem__(self, key) class FailingServerTestCase(unittest.TestCase): def setUp(self): self.evt = threading.Event() # start server thread to handle requests serv_args = (self.evt, 1) threading.Thread(target=http_server, args=serv_args).start() # wait for port to be assigned to server n = 1000 while n > 0 and PORT is None: time.sleep(0.001) n -= 1 time.sleep(0.5) def tearDown(self): # wait on the server thread to terminate self.evt.wait() # reset flag SimpleXMLRPCServer.SimpleXMLRPCServer._send_traceback_header = False # reset message class SimpleXMLRPCServer.SimpleXMLRPCRequestHandler.MessageClass = mimetools.Message def test_basic(self): # check that flag is false by default flagval = SimpleXMLRPCServer.SimpleXMLRPCServer._send_traceback_header self.assertEqual(flagval, False) # enable traceback reporting SimpleXMLRPCServer.SimpleXMLRPCServer._send_traceback_header = True # test a call that shouldn't fail just as a smoke test try: p = xmlrpclib.ServerProxy('http://localhost:%d' % PORT) self.assertEqual(p.pow(6,8), 6**8) except xmlrpclib.ProtocolError as e: # protocol error; provide additional information in test output self.fail("%s\n%s" % (e, e.headers)) def test_fail_no_info(self): # use the broken message class SimpleXMLRPCServer.SimpleXMLRPCRequestHandler.MessageClass = FailingMessageClass try: p = xmlrpclib.ServerProxy('http://localhost:%d' % PORT) p.pow(6,8) except xmlrpclib.ProtocolError as e: # The two server-side error headers shouldn't be sent back in this case self.assertTrue(e.headers.get("X-exception") is None) self.assertTrue(e.headers.get("X-traceback") is None) else: self.fail('ProtocolError not raised') def test_fail_with_info(self): # use the broken message class SimpleXMLRPCServer.SimpleXMLRPCRequestHandler.MessageClass = FailingMessageClass # Check that errors in the server send back exception/traceback # info when flag is set SimpleXMLRPCServer.SimpleXMLRPCServer._send_traceback_header = True try: p = xmlrpclib.ServerProxy('http://localhost:%d' % PORT) p.pow(6,8) except xmlrpclib.ProtocolError as e: # We should get error info in the response expected_err = "invalid literal for int() with base 10: 'I am broken'" self.assertEqual(e.headers.get("x-exception"), expected_err) self.assertTrue(e.headers.get("x-traceback") is not None) else: self.fail('ProtocolError not raised') def test_main(): xmlrpc_tests = [XMLRPCTestCase, HelperTestCase, DateTimeTestCase, BinaryTestCase, FaultTestCase] # The test cases against a SimpleXMLRPCServer raise a socket error # 10035 (WSAEWOULDBLOCK) in the server thread handle_request call when # run on Windows. This only happens on the first test to run, but it # fails every time and so these tests are skipped on win32 platforms. if sys.platform != 'win32': xmlrpc_tests.append(SimpleServerTestCase) xmlrpc_tests.append(FailingServerTestCase) test_support.run_unittest(*xmlrpc_tests) if __name__ == "__main__": test_main()