def test_long_stream_recovered(self): """ Test a long stream of data """ file_path = os.path.join(RESOURCE_PATH, "E0000039.DAT") with open(file_path, "rb") as stream_handle: parser = WfpEngStcImodemParser( self._recov_config, None, stream_handle, lambda state, ingested: None, lambda data: None ) # start with the start time record result = parser.get_records(100) self.assert_particles(result, "E0000039_recov.yml", RESOURCE_PATH)
def test_bad_data_telemetered(self): """ Ensure that missing data causes us to miss records TODO: This test should be improved if we come up with a more accurate regex for the data sample """ file_path = os.path.join(RESOURCE_PATH, "bad_data.dat") with open(file_path, "rb") as stream_handle: parser = WfpEngStcImodemParser( self._telem_config, None, stream_handle, lambda state, ingested: None, lambda data: None ) result = parser.get_records(5) self.assert_particles(result, "bad_data_telem.yml", RESOURCE_PATH)
def test_simple_telemetered(self): """ Read test data and pull out data particles one at a time. Assert that the results are those we expected. """ file_path = os.path.join(RESOURCE_PATH, "simple.dat") with open(file_path, "rb") as stream_handle: parser = WfpEngStcImodemParser( self._telem_config, None, stream_handle, lambda state, ingested: None, lambda data: None ) result = parser.get_records(5) self.assert_particles(result, "simple_telem.yml", RESOURCE_PATH)
def test_simple_telemetered(self): """ Read test data and pull out data particles one at a time. Assert that the results are those we expected. """ file_path = os.path.join(RESOURCE_PATH, 'simple.dat') with open(file_path, 'rb') as stream_handle: parser = WfpEngStcImodemParser(self._telem_config, None, stream_handle, lambda state, ingested: None, lambda data: None) result = parser.get_records(5) self.assert_particles(result, 'simple_telem.yml', RESOURCE_PATH)
def test_bad_data_telemetered(self): """ Ensure that missing data causes us to miss records TODO: This test should be improved if we come up with a more accurate regex for the data sample """ file_path = os.path.join(RESOURCE_PATH, 'bad_data.dat') with open(file_path, 'rb') as stream_handle: parser = WfpEngStcImodemParser(self._telem_config, None, stream_handle, lambda state, ingested: None, lambda data: None) result = parser.get_records(5) self.assert_particles(result, 'bad_data_telem.yml', RESOURCE_PATH)
def test_long_stream_telemetered(self): """ Test a long stream of data """ file_path = os.path.join(RESOURCE_PATH, 'E0000039.DAT') with open(file_path, 'rb') as stream_handle: parser = WfpEngStcImodemParser(self._telem_config, None, stream_handle, lambda state, ingested: None, lambda data: None) # start with the start time record result = parser.get_records(100) self.assert_particles(result, 'E0000039_telem.yml', RESOURCE_PATH)
def test_bug_3241(self): """ This test was created to validate fixes to bug #3241 It validates the parser can parse a file recovered from Global platforms """ file_path = os.path.join(RESOURCE_PATH, 'E0000000.DAT') with open(file_path, 'rb') as stream_handle: parser = WfpEngStcImodemParser(self._recov_config, None, stream_handle, lambda state, ingested: None, lambda data: None) result = parser.get_records(100) # make sure we get 100 particles back self.assertEquals(len(result), 100) # make sure there are no errors self.assertEquals(len(self.exception_callback_value), 0)
def test_bug_3241(self): """ This test was created to validate fixes to bug #3241 It validates the parser can parse a file recovered from Global platforms """ file_path = os.path.join(RESOURCE_PATH, 'E0000000.DAT') with open(file_path, 'rb') as stream_handle: parser = WfpEngStcImodemParser( self._recov_config, None, stream_handle, lambda state, ingested: None, lambda data: None) result = parser.get_records(100) # make sure we get 100 particles back self.assertEquals(len(result), 100) # make sure there are no errors self.assertEquals(len(self.exception_callback_value), 0)
class WfpEngStcImodemParserUnitTestCase(ParserUnitTestCase): """ Wfp_eng__stc_imodem Parser unit test suite """ TEST_DATA_SHORT = "\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19R\x9d\xac" \ "\x1d\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00NR\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00" \ "\x00\x00\x00\x00\x00\x00\xf2\x00c\x00OR\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^" \ "\x00OR\x9d\xac*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O" TEST_DATA = "\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19R\x9d\xac\x1d\x00" \ "\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00NR\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00\x00" \ "\x00\x00\x00\x00\x00\xf2\x00c\x00OR\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^" \ "\x00OR\x9d\xac*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00OR\x9d\xac/C\xb8COA6\xde" \ "\x01\x00\x00\x00\x00\x00\x00\x00\x00\x00\x9d\x00p\x00QR\x9d\xac3C\x98\xe5TA733\x00\x00\x00\x00\x00\x00\x00\x00" \ "\x00\xa4\x00u\x00OR\x9d\xac8C\x9566A7!-\x00\x00\x00\x00\x00\x00\x00\x00\x00\x9a\x00o\x00OR\x9d\xac?C\xa1\xd7\xc3" \ "A6\xa6LB\x8bG\xae\x00\x00\x00\x00\x00\xb6\x00v\x00PR\x9d\xacECsS\xfeA7e\xfeB\x88\x00\x00\x00\x00\x00\x00\x00" \ "\x98\x00s\x00QR\x9d\xacKC\x89\x17\x8cA6\xe2\xecB\x84\x99\x9a\x00\x00\x00\x00\x00\xa4\x00\x81\x00PR\x9d\xacQC}\n" \ "\xbfA7\x00hB\x81G\xae\x00\x00\x00\x00\x00\xa2\x00|\x00NR\x9d\xacWCyW\xc7A6\x97\x8dB{\xe1H\x00\x00\x00\x00\x00\x9a" \ "\x00m\x00NR\x9d\xac]C\x8c!#A6\x9f\xbeBuQ\xec\x00\x00\x00\x00\x00\x97\x00s\x00QR\x9d\xaccC\x84!9A6h\nBn\x8f\\\x00" \ "\x00\x00\x00\x00\x9f\x00v\x00NR\x9d\xaciCE\xa5UA6a|Bh=q\x00\x00\x00\x00\x00\x97\x00l\x00PR\x9d\xacoC\xa5\xa5\xad" \ "A5\x94\xafBa\\)\x00\x00\x00\x00\x00\x9b\x00n\x00RR\x9d\xacuC\\\r\x08A6\x14{B[\n=\x00\x00\x00\x00\x00\x9a\x00s\x00" \ "OR\x9d\xac{C\xa3\x0b\xb8A5F\nBT33\x00\x00\x00\x00\x00\x98\x00q\x00NR\x9d\xac\x81CO\xc0+A5\xd7\xdcBM\xd7\n\x00\x00" \ "\x00\x00\x00\x97\x00n\x00PR\x9d\xac\x87Cxp\xd0A5#\xa3BGG\xae\x00\x00\x00\x00\x00\x9b\x00n\x00PR\x9d\xac\x8dC\x84" \ "\xdd\xd9A5X\x10B@\xae\x14\x00\x00\x00\x00\x00\xa5\x00v\x00OR\x9d\xac\x93C\xa0\x85\x01A4j\x7fB:\x14{\x00\x00\x00\x00" \ "\x00\x9c\x00t\x00QR\x9d\xac\x99Cq\xa4\xdbA5:\x92B3\xc2\x8f\x00\x00\x00\x00\x00\x9c\x00x\x00PR\x9d\xac\x9fCg\x07#A5" \ "\x18+B-\x00\x00\x00\x00\x00\x00\x00\x9e\x00m\x00QR\x9d\xac\xa5C\x9bw\x96A4FtB&z\xe1\x00\x00\x00\x00\x00\xd7\x00s" \ "\x00OR\x9d\xac\xabCmP5A4\x9dJB\x1f\xd7\n\x00\x00\x00\x00\x00\x99\x00s\x00PR\x9d\xac\xb1C\xad\x960A3\x8a\tB\x19" \ "(\xf6\x00\x00\x00\x00\x00\x95\x00n\x00OR\x9d\xac\xb7C\x0c\xce]A5\x0f\xfaB\x12\xe1H\x00\x00\x00\x00\x00\x9c\x00u" \ "\x00PR\x9d\xac\xbdC\xa1\xeb\x02A3Z\x85B\x0c=q\x00\x00\x00\x00\x00\x95\x00u\x00OR\x9d\xac\xc3C$\xafOA4\xa23B\x05" \ "\xe1H\x00\x00\x00\x00\x00\x99\x00r\x00PR\x9d\xac\xc9C\xae\xddeA3\x0f(A\xfe(\xf6\x00\x00\x00\x00\x00\x9a\x00o\x00O" \ "R\x9d\xac\xcfA\xfa\xb2:A5\x0b\x0fA\xf2\x8f\\\x00\x00\x00\x00\x00\xaf\x00m\x00P\xff\xff\xff\xff\x00\x00\x00\rR\x9d" \ "\xac\xd4R\x9d\xadQ" # all flags set to zero TEST_DATA_BAD_FLAGS = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19R\x9d\xac\x1d" \ "\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00NR\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00\x00\x00" \ "\x00\x00\x00\x00\xf2\x00c\x00OR\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^\x00OR\x9d\xac" \ "*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O" # took 5 bytes out of second engineering sample TEST_DATA_BAD_ENG = "\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19R\x9d\xac\x1d" \ "\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00NR\x9d\xac!C\t!\x00\x00\x00\x00\x00" \ "\x00\x00\x00\x00\xf2\x00c\x00OR\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^\x00OR\x9d\xac" \ "*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O" def state_callback(self, state, file_ingested): """ Call back method to watch what comes in via the position callback """ self.file_ingested = file_ingested self.state_callback_value = state def pub_callback(self, pub): """ Call back method to watch what comes in via the publish callback """ self.publish_callback_value = pub def setUp(self): ParserUnitTestCase.setUp(self) self.config = { DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED: { DataSetDriverConfigKeys.PARTICLE_MODULE: 'mi.dataset.parser.wfp_eng__stc_imodem_particles', DataSetDriverConfigKeys.PARTICLE_CLASS: None, DataSetDriverConfigKeys.PARTICLE_CLASSES_DICT: { 'status_data_particle_class': WfpEngStcImodemStatusRecoveredDataParticle, 'start_data_particle_class': WfpEngStcImodemStartRecoveredDataParticle, 'engineering_data_particle_class': WfpEngStcImodemEngineeringRecoveredDataParticle } }, DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED: { DataSetDriverConfigKeys.PARTICLE_MODULE: 'mi.dataset.parser.wfp_eng__stc_imodem_particles', DataSetDriverConfigKeys.PARTICLE_CLASS: None, DataSetDriverConfigKeys.PARTICLE_CLASSES_DICT: { 'status_data_particle_class': WfpEngStcImodemStatusTelemeteredDataParticle, 'start_data_particle_class': WfpEngStcImodemStartTelemeteredDataParticle, 'engineering_data_particle_class': WfpEngStcImodemEngineeringTelemeteredDataParticle } }, } self.start_state = {StateKey.POSITION: 0} # Define test data particles and their associated timestamps which will be # compared with returned results timestamp1_time = self.timestamp_to_ntp('R\x9d\xac\x19') self.particle_a_start_time_recov = WfpEngStcImodemStartRecoveredDataParticle( b'\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19', internal_timestamp=timestamp1_time) self.particle_a_start_time_telem = WfpEngStcImodemStartTelemeteredDataParticle( b'\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19', internal_timestamp=timestamp1_time) timestamp1_eng = self.timestamp_to_ntp('R\x9d\xac\x1d') self.particle_a_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b'R\x9d\xac\x1d\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00N', internal_timestamp=timestamp1_eng) self.particle_a_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b'R\x9d\xac\x1d\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00N', internal_timestamp=timestamp1_eng) timestamp2_eng = self.timestamp_to_ntp('R\x9d\xac!') self.particle_b_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b'R\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00\x00\x00\x00\x00\x00\x00\xf2\x00c\x00O', internal_timestamp=timestamp2_eng) self.particle_b_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b'R\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00\x00\x00\x00\x00\x00\x00\xf2\x00c\x00O', internal_timestamp=timestamp2_eng) timestamp3_eng = self.timestamp_to_ntp('R\x9d\xac&') self.particle_c_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b"R\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^\x00O", internal_timestamp=timestamp3_eng) self.particle_c_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b"R\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^\x00O", internal_timestamp=timestamp3_eng) timestamp4_eng = self.timestamp_to_ntp('R\x9d\xac*') self.particle_d_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b'R\x9d\xac*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O', internal_timestamp=timestamp4_eng) self.particle_d_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b'R\x9d\xac*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O', internal_timestamp=timestamp4_eng) timestamp_last_eng = self.timestamp_to_ntp('R\x9d\xac\xcf') self.particle_last_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b'R\x9d\xac\xcfA\xfa\xb2:A5\x0b\x0fA\xf2\x8f\\\x00\x00\x00\x00\x00\xaf\x00m\x00P', internal_timestamp=timestamp_last_eng) self.particle_last_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b'R\x9d\xac\xcfA\xfa\xb2:A5\x0b\x0fA\xf2\x8f\\\x00\x00\x00\x00\x00\xaf\x00m\x00P', internal_timestamp=timestamp_last_eng) timestamp1_status = self.timestamp_to_ntp('R\x9d\xac\xd4') self.particle_a_status_recov = WfpEngStcImodemStatusRecoveredDataParticle( b'\xff\xff\xff\xff\x00\x00\x00\rR\x9d\xac\xd4R\x9d\xadQ', internal_timestamp=timestamp1_status) self.particle_a_status_telem = WfpEngStcImodemStatusTelemeteredDataParticle( b'\xff\xff\xff\xff\x00\x00\x00\rR\x9d\xac\xd4R\x9d\xadQ', internal_timestamp=timestamp1_status) # uncomment the following to generate particles in yml format for driver testing results files #self.particle_to_yml(self.particle_a_start_time_recov) #self.particle_to_yml(self.particle_a_eng) #self.particle_to_yml(self.particle_b_eng) #self.particle_to_yml(self.particle_c_eng) #self.particle_to_yml(self.particle_d_eng) #self.particle_to_yml(self.particle_a_stat) self.file_ingested = False self.state_callback_value = None self.publish_callback_value = None def timestamp_to_ntp(self, hex_timestamp): fields = struct.unpack('>I', hex_timestamp) timestamp = int(fields[0]) return ntplib.system_to_ntp_time(timestamp) def assert_result(self, result, position, particle, ingested): self.assertEqual(result, [particle]) self.assertEqual(self.file_ingested, ingested) self.assertEqual(self.parser._state[StateKey.POSITION], position) self.assertEqual(self.state_callback_value[StateKey.POSITION], position) self.assert_(isinstance(self.publish_callback_value, list)) self.assertEqual(self.publish_callback_value[0], particle) def test_simple_recovered(self): """ Read test data and pull out data particles one at a time. Assert that the results are those we expected. """ self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) # next get engineering records result = self.parser.get_records(1) self.assert_result(result, 50, self.particle_a_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 76, self.particle_b_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_recov, True) # no data left, dont move the position result = self.parser.get_records(1) self.assertEqual(result, []) self.assertEqual(self.parser._state[StateKey.POSITION], 128) self.assertEqual(self.state_callback_value[StateKey.POSITION], 128) self.assert_(isinstance(self.publish_callback_value, list)) self.assertEqual(self.publish_callback_value[0], self.particle_d_eng_recov) def test_simple_telemetered(self): """ Read test data and pull out data particles one at a time. Assert that the results are those we expected. """ self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) # next get engineering records result = self.parser.get_records(1) self.assert_result(result, 50, self.particle_a_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 76, self.particle_b_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_telem, True) # no data left, dont move the position result = self.parser.get_records(1) self.assertEqual(result, []) self.assertEqual(self.parser._state[StateKey.POSITION], 128) self.assertEqual(self.state_callback_value[StateKey.POSITION], 128) self.assert_(isinstance(self.publish_callback_value, list)) self.assertEqual(self.publish_callback_value[0], self.particle_d_eng_telem) def test_get_many_recovered(self): """ Read test data and pull out multiple data particles at one time. Assert that the results are those we expected. """ self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) result = self.parser.get_records(4) self.assertEqual(result, [self.particle_a_eng_recov, self.particle_b_eng_recov, self.particle_c_eng_recov, self.particle_d_eng_recov]) self.assertEqual(self.parser._state[StateKey.POSITION], 128) self.assertEqual(self.state_callback_value[StateKey.POSITION], 128) self.assertEqual(self.publish_callback_value[0], self.particle_a_eng_recov) self.assertEqual(self.publish_callback_value[1], self.particle_b_eng_recov) self.assertEqual(self.publish_callback_value[2], self.particle_c_eng_recov) self.assertEqual(self.publish_callback_value[3], self.particle_d_eng_recov) self.assertEqual(self.file_ingested, True) def test_get_many_telemetered(self): """ Read test data and pull out multiple data particles at one time. Assert that the results are those we expected. """ self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) result = self.parser.get_records(4) self.assertEqual(result, [self.particle_a_eng_telem, self.particle_b_eng_telem, self.particle_c_eng_telem, self.particle_d_eng_telem]) self.assertEqual(self.parser._state[StateKey.POSITION], 128) self.assertEqual(self.state_callback_value[StateKey.POSITION], 128) self.assertEqual(self.publish_callback_value[0], self.particle_a_eng_telem) self.assertEqual(self.publish_callback_value[1], self.particle_b_eng_telem) self.assertEqual(self.publish_callback_value[2], self.particle_c_eng_telem) self.assertEqual(self.publish_callback_value[3], self.particle_d_eng_telem) self.assertEqual(self.file_ingested, True) def test_long_stream_recovered(self): """ Test a long stream of data """ self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) result = self.parser.get_records(32) self.assertEqual(result[0], self.particle_a_eng_recov) self.assertEqual(result[-1], self.particle_last_eng_recov) self.assertEqual(self.parser._state[StateKey.POSITION], 856) self.assertEqual(self.state_callback_value[StateKey.POSITION], 856) self.assertEqual(self.publish_callback_value[-1], self.particle_last_eng_recov) result = self.parser.get_records(1) self.assert_result(result, 872, self.particle_a_status_recov, True) def test_long_stream_telemetered(self): """ Test a long stream of data """ self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) result = self.parser.get_records(32) self.assertEqual(result[0], self.particle_a_eng_telem) self.assertEqual(result[-1], self.particle_last_eng_telem) self.assertEqual(self.parser._state[StateKey.POSITION], 856) self.assertEqual(self.state_callback_value[StateKey.POSITION], 856) self.assertEqual(self.publish_callback_value[-1], self.particle_last_eng_telem) result = self.parser.get_records(1) self.assert_result(result, 872, self.particle_a_status_telem, True) def test_after_header_recovered(self): """ Test starting the parser in a state in the middle of processing """ new_state = {StateKey.POSITION: 24} self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), new_state, self.stream_handle, self.state_callback, self.pub_callback) # get engineering records result = self.parser.get_records(1) self.assert_result(result, 50, self.particle_a_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 76, self.particle_b_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_recov, True) def test_after_header_telemetered(self): """ Test starting the parser in a state in the middle of processing """ new_state = {StateKey.POSITION: 24} self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), new_state, self.stream_handle, self.state_callback, self.pub_callback) # get engineering records result = self.parser.get_records(1) self.assert_result(result, 50, self.particle_a_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 76, self.particle_b_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_telem, True) def test_mid_state_start_recovered(self): """ Test starting the parser in a state in the middle of processing """ new_state = {StateKey.POSITION:76} self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), new_state, self.stream_handle, self.state_callback, self.pub_callback) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_recov, True) def test_mid_state_start_telemetered(self): """ Test starting the parser in a state in the middle of processing """ new_state = {StateKey.POSITION:76} self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), new_state, self.stream_handle, self.state_callback, self.pub_callback) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_telem, True) def test_set_state_recovered(self): """ Test changing to a new state after initializing the parser and reading data, as if new data has been found and the state has changed """ new_state = {StateKey.POSITION: 76} self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) # set the new state, the essentially skips engineering a and b self.parser.set_state(new_state) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_recov, True) def test_set_state_telemetered(self): """ Test changing to a new state after initializing the parser and reading data, as if new data has been found and the state has changed """ new_state = {StateKey.POSITION: 76} self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) # set the new state, the essentially skips engineering a and b self.parser.set_state(new_state) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_telem, True) def test_bad_flags_recovered(self): """ test that we don't parse any records when the flags are not what we expect """ with self.assertRaises(SampleException): self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_BAD_FLAGS) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) def test_bad_flags_telemetered(self): """ test that we don't parse any records when the flags are not what we expect """ with self.assertRaises(SampleException): self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_BAD_FLAGS) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) def test_bad_data_recovered(self): """ Ensure that missing data causes us to miss records TODO: This test should be improved if we come up with a more accurate regex for the data sample """ self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_BAD_ENG) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) # next get engineering records result = self.parser.get_records(4) if len(result) == 4: self.fail("We got 4 records, the bad data should only make 3") def test_bad_data_telemetered(self): """ Ensure that missing data causes us to miss records TODO: This test should be improved if we come up with a more accurate regex for the data sample """ self.stream_handle = StringIO(WfpEngStcImodemParserUnitTestCase.TEST_DATA_BAD_ENG) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) # next get engineering records result = self.parser.get_records(4) if len(result) == 4: self.fail("We got 4 records, the bad data should only make 3") def particle_to_yml(self, particles, filename, mode='w'): """ This is added as a testing helper, not actually as part of the parser tests. Since the same particles will be used for the driver test it is helpful to write them to .yml in the same form they need in the results.yml fids here. """ # open write append, if you want to start from scratch manually delete this fid fid = open(os.path.join(RESOURCE_PATH, filename), mode) fid.write('header:\n') fid.write(" particle_object: 'MULTIPLE'\n") fid.write(" particle_type: 'MULTIPLE'\n") fid.write('data:\n') for i in range(0, len(particles)): particle_dict = particles[i].generate_dict() fid.write(' - _index: %d\n' %(i+1)) fid.write(' particle_object: %s\n' % particles[i].__class__.__name__) fid.write(' particle_type: %s\n' % particle_dict.get('stream_name')) fid.write(' internal_timestamp: %f\n' % particle_dict.get('internal_timestamp')) for val in particle_dict.get('values'): if isinstance(val.get('value'), float): fid.write(' %s: %16.16f\n' % (val.get('value_id'), val.get('value'))) else: fid.write(' %s: %s\n' % (val.get('value_id'), val.get('value'))) fid.close()
class WfpEngStcImodemParserUnitTestCase(ParserUnitTestCase): """ Wfp_eng__stc_imodem Parser unit test suite """ TEST_DATA_SHORT = "\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19R\x9d\xac" \ "\x1d\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00NR\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00" \ "\x00\x00\x00\x00\x00\x00\xf2\x00c\x00OR\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^" \ "\x00OR\x9d\xac*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O" TEST_DATA = "\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19R\x9d\xac\x1d\x00" \ "\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00NR\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00\x00" \ "\x00\x00\x00\x00\x00\xf2\x00c\x00OR\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^" \ "\x00OR\x9d\xac*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00OR\x9d\xac/C\xb8COA6\xde" \ "\x01\x00\x00\x00\x00\x00\x00\x00\x00\x00\x9d\x00p\x00QR\x9d\xac3C\x98\xe5TA733\x00\x00\x00\x00\x00\x00\x00\x00" \ "\x00\xa4\x00u\x00OR\x9d\xac8C\x9566A7!-\x00\x00\x00\x00\x00\x00\x00\x00\x00\x9a\x00o\x00OR\x9d\xac?C\xa1\xd7\xc3" \ "A6\xa6LB\x8bG\xae\x00\x00\x00\x00\x00\xb6\x00v\x00PR\x9d\xacECsS\xfeA7e\xfeB\x88\x00\x00\x00\x00\x00\x00\x00" \ "\x98\x00s\x00QR\x9d\xacKC\x89\x17\x8cA6\xe2\xecB\x84\x99\x9a\x00\x00\x00\x00\x00\xa4\x00\x81\x00PR\x9d\xacQC}\n" \ "\xbfA7\x00hB\x81G\xae\x00\x00\x00\x00\x00\xa2\x00|\x00NR\x9d\xacWCyW\xc7A6\x97\x8dB{\xe1H\x00\x00\x00\x00\x00\x9a" \ "\x00m\x00NR\x9d\xac]C\x8c!#A6\x9f\xbeBuQ\xec\x00\x00\x00\x00\x00\x97\x00s\x00QR\x9d\xaccC\x84!9A6h\nBn\x8f\\\x00" \ "\x00\x00\x00\x00\x9f\x00v\x00NR\x9d\xaciCE\xa5UA6a|Bh=q\x00\x00\x00\x00\x00\x97\x00l\x00PR\x9d\xacoC\xa5\xa5\xad" \ "A5\x94\xafBa\\)\x00\x00\x00\x00\x00\x9b\x00n\x00RR\x9d\xacuC\\\r\x08A6\x14{B[\n=\x00\x00\x00\x00\x00\x9a\x00s\x00" \ "OR\x9d\xac{C\xa3\x0b\xb8A5F\nBT33\x00\x00\x00\x00\x00\x98\x00q\x00NR\x9d\xac\x81CO\xc0+A5\xd7\xdcBM\xd7\n\x00\x00" \ "\x00\x00\x00\x97\x00n\x00PR\x9d\xac\x87Cxp\xd0A5#\xa3BGG\xae\x00\x00\x00\x00\x00\x9b\x00n\x00PR\x9d\xac\x8dC\x84" \ "\xdd\xd9A5X\x10B@\xae\x14\x00\x00\x00\x00\x00\xa5\x00v\x00OR\x9d\xac\x93C\xa0\x85\x01A4j\x7fB:\x14{\x00\x00\x00\x00" \ "\x00\x9c\x00t\x00QR\x9d\xac\x99Cq\xa4\xdbA5:\x92B3\xc2\x8f\x00\x00\x00\x00\x00\x9c\x00x\x00PR\x9d\xac\x9fCg\x07#A5" \ "\x18+B-\x00\x00\x00\x00\x00\x00\x00\x9e\x00m\x00QR\x9d\xac\xa5C\x9bw\x96A4FtB&z\xe1\x00\x00\x00\x00\x00\xd7\x00s" \ "\x00OR\x9d\xac\xabCmP5A4\x9dJB\x1f\xd7\n\x00\x00\x00\x00\x00\x99\x00s\x00PR\x9d\xac\xb1C\xad\x960A3\x8a\tB\x19" \ "(\xf6\x00\x00\x00\x00\x00\x95\x00n\x00OR\x9d\xac\xb7C\x0c\xce]A5\x0f\xfaB\x12\xe1H\x00\x00\x00\x00\x00\x9c\x00u" \ "\x00PR\x9d\xac\xbdC\xa1\xeb\x02A3Z\x85B\x0c=q\x00\x00\x00\x00\x00\x95\x00u\x00OR\x9d\xac\xc3C$\xafOA4\xa23B\x05" \ "\xe1H\x00\x00\x00\x00\x00\x99\x00r\x00PR\x9d\xac\xc9C\xae\xddeA3\x0f(A\xfe(\xf6\x00\x00\x00\x00\x00\x9a\x00o\x00O" \ "R\x9d\xac\xcfA\xfa\xb2:A5\x0b\x0fA\xf2\x8f\\\x00\x00\x00\x00\x00\xaf\x00m\x00P\xff\xff\xff\xff\x00\x00\x00\rR\x9d" \ "\xac\xd4R\x9d\xadQ" # all flags set to zero TEST_DATA_BAD_FLAGS = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19R\x9d\xac\x1d" \ "\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00NR\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00\x00\x00" \ "\x00\x00\x00\x00\xf2\x00c\x00OR\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^\x00OR\x9d\xac" \ "*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O" # took 5 bytes out of second engineering sample TEST_DATA_BAD_ENG = "\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19R\x9d\xac\x1d" \ "\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00NR\x9d\xac!C\t!\x00\x00\x00\x00\x00" \ "\x00\x00\x00\x00\xf2\x00c\x00OR\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^\x00OR\x9d\xac" \ "*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O" def state_callback(self, state, file_ingested): """ Call back method to watch what comes in via the position callback """ self.file_ingested = file_ingested self.state_callback_value = state def pub_callback(self, pub): """ Call back method to watch what comes in via the publish callback """ self.publish_callback_value = pub def setUp(self): ParserUnitTestCase.setUp(self) self.config = { DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED: { DataSetDriverConfigKeys.PARTICLE_MODULE: 'mi.dataset.parser.wfp_eng__stc_imodem_particles', DataSetDriverConfigKeys.PARTICLE_CLASS: None, DataSetDriverConfigKeys.PARTICLE_CLASSES_DICT: { 'status_data_particle_class': WfpEngStcImodemStatusRecoveredDataParticle, 'start_data_particle_class': WfpEngStcImodemStartRecoveredDataParticle, 'engineering_data_particle_class': WfpEngStcImodemEngineeringRecoveredDataParticle } }, DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED: { DataSetDriverConfigKeys.PARTICLE_MODULE: 'mi.dataset.parser.wfp_eng__stc_imodem_particles', DataSetDriverConfigKeys.PARTICLE_CLASS: None, DataSetDriverConfigKeys.PARTICLE_CLASSES_DICT: { 'status_data_particle_class': WfpEngStcImodemStatusTelemeteredDataParticle, 'start_data_particle_class': WfpEngStcImodemStartTelemeteredDataParticle, 'engineering_data_particle_class': WfpEngStcImodemEngineeringTelemeteredDataParticle } }, } self.start_state = {StateKey.POSITION: 0} # Define test data particles and their associated timestamps which will be # compared with returned results timestamp1_time = self.timestamp_to_ntp('R\x9d\xac\x19') self.particle_a_start_time_recov = WfpEngStcImodemStartRecoveredDataParticle( b'\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19', internal_timestamp=timestamp1_time) self.particle_a_start_time_telem = WfpEngStcImodemStartTelemeteredDataParticle( b'\x00\x01\x00\x00\x00\x00\x00\x00\x00\x01\x00\x01\x00\x00\x00\x00R\x9d\xab\xa2R\x9d\xac\x19', internal_timestamp=timestamp1_time) timestamp1_eng = self.timestamp_to_ntp('R\x9d\xac\x1d') self.particle_a_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b'R\x9d\xac\x1d\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00N', internal_timestamp=timestamp1_eng) self.particle_a_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b'R\x9d\xac\x1d\x00\x00\x00\x00A:6\xe3\x00\x00\x00\x00\x00\x00\x00\x00\x01\x03\x00h\x00N', internal_timestamp=timestamp1_eng) timestamp2_eng = self.timestamp_to_ntp('R\x9d\xac!') self.particle_b_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b'R\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00\x00\x00\x00\x00\x00\x00\xf2\x00c\x00O', internal_timestamp=timestamp2_eng) self.particle_b_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b'R\x9d\xac!C\t\xf2\xf7A9A!\x00\x00\x00\x00\x00\x00\x00\x00\x00\xf2\x00c\x00O', internal_timestamp=timestamp2_eng) timestamp3_eng = self.timestamp_to_ntp('R\x9d\xac&') self.particle_c_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b"R\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^\x00O", internal_timestamp=timestamp3_eng) self.particle_c_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b"R\x9d\xac&C\xbc\x9f\xa7A7'\xbb\x00\x00\x00\x00\x00\x00\x00\x00\x00\xc2\x00^\x00O", internal_timestamp=timestamp3_eng) timestamp4_eng = self.timestamp_to_ntp('R\x9d\xac*') self.particle_d_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b'R\x9d\xac*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O', internal_timestamp=timestamp4_eng) self.particle_d_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b'R\x9d\xac*C\xc5\xad\x08A6\xd5\xd0\x00\x00\x00\x00\x00\x00\x00\x00\x00\xb4\x00n\x00O', internal_timestamp=timestamp4_eng) timestamp_last_eng = self.timestamp_to_ntp('R\x9d\xac\xcf') self.particle_last_eng_recov = WfpEngStcImodemEngineeringRecoveredDataParticle( b'R\x9d\xac\xcfA\xfa\xb2:A5\x0b\x0fA\xf2\x8f\\\x00\x00\x00\x00\x00\xaf\x00m\x00P', internal_timestamp=timestamp_last_eng) self.particle_last_eng_telem = WfpEngStcImodemEngineeringTelemeteredDataParticle( b'R\x9d\xac\xcfA\xfa\xb2:A5\x0b\x0fA\xf2\x8f\\\x00\x00\x00\x00\x00\xaf\x00m\x00P', internal_timestamp=timestamp_last_eng) timestamp1_status = self.timestamp_to_ntp('R\x9d\xac\xd4') self.particle_a_status_recov = WfpEngStcImodemStatusRecoveredDataParticle( b'\xff\xff\xff\xff\x00\x00\x00\rR\x9d\xac\xd4R\x9d\xadQ', internal_timestamp=timestamp1_status) self.particle_a_status_telem = WfpEngStcImodemStatusTelemeteredDataParticle( b'\xff\xff\xff\xff\x00\x00\x00\rR\x9d\xac\xd4R\x9d\xadQ', internal_timestamp=timestamp1_status) # uncomment the following to generate particles in yml format for driver testing results files #self.particle_to_yml(self.particle_a_start_time_recov) #self.particle_to_yml(self.particle_a_eng) #self.particle_to_yml(self.particle_b_eng) #self.particle_to_yml(self.particle_c_eng) #self.particle_to_yml(self.particle_d_eng) #self.particle_to_yml(self.particle_a_stat) self.file_ingested = False self.state_callback_value = None self.publish_callback_value = None def timestamp_to_ntp(self, hex_timestamp): fields = struct.unpack('>I', hex_timestamp) timestamp = int(fields[0]) return ntplib.system_to_ntp_time(timestamp) def assert_result(self, result, position, particle, ingested): self.assertEqual(result, [particle]) self.assertEqual(self.file_ingested, ingested) self.assertEqual(self.parser._state[StateKey.POSITION], position) self.assertEqual(self.state_callback_value[StateKey.POSITION], position) self.assert_(isinstance(self.publish_callback_value, list)) self.assertEqual(self.publish_callback_value[0], particle) def test_simple_recovered(self): """ Read test data and pull out data particles one at a time. Assert that the results are those we expected. """ self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) # next get engineering records result = self.parser.get_records(1) self.assert_result(result, 50, self.particle_a_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 76, self.particle_b_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_recov, True) # no data left, dont move the position result = self.parser.get_records(1) self.assertEqual(result, []) self.assertEqual(self.parser._state[StateKey.POSITION], 128) self.assertEqual(self.state_callback_value[StateKey.POSITION], 128) self.assert_(isinstance(self.publish_callback_value, list)) self.assertEqual(self.publish_callback_value[0], self.particle_d_eng_recov) def test_simple_telemetered(self): """ Read test data and pull out data particles one at a time. Assert that the results are those we expected. """ self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) # next get engineering records result = self.parser.get_records(1) self.assert_result(result, 50, self.particle_a_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 76, self.particle_b_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_telem, True) # no data left, dont move the position result = self.parser.get_records(1) self.assertEqual(result, []) self.assertEqual(self.parser._state[StateKey.POSITION], 128) self.assertEqual(self.state_callback_value[StateKey.POSITION], 128) self.assert_(isinstance(self.publish_callback_value, list)) self.assertEqual(self.publish_callback_value[0], self.particle_d_eng_telem) def test_get_many_recovered(self): """ Read test data and pull out multiple data particles at one time. Assert that the results are those we expected. """ self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) result = self.parser.get_records(4) self.assertEqual(result, [ self.particle_a_eng_recov, self.particle_b_eng_recov, self.particle_c_eng_recov, self.particle_d_eng_recov ]) self.assertEqual(self.parser._state[StateKey.POSITION], 128) self.assertEqual(self.state_callback_value[StateKey.POSITION], 128) self.assertEqual(self.publish_callback_value[0], self.particle_a_eng_recov) self.assertEqual(self.publish_callback_value[1], self.particle_b_eng_recov) self.assertEqual(self.publish_callback_value[2], self.particle_c_eng_recov) self.assertEqual(self.publish_callback_value[3], self.particle_d_eng_recov) self.assertEqual(self.file_ingested, True) def test_get_many_telemetered(self): """ Read test data and pull out multiple data particles at one time. Assert that the results are those we expected. """ self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) result = self.parser.get_records(4) self.assertEqual(result, [ self.particle_a_eng_telem, self.particle_b_eng_telem, self.particle_c_eng_telem, self.particle_d_eng_telem ]) self.assertEqual(self.parser._state[StateKey.POSITION], 128) self.assertEqual(self.state_callback_value[StateKey.POSITION], 128) self.assertEqual(self.publish_callback_value[0], self.particle_a_eng_telem) self.assertEqual(self.publish_callback_value[1], self.particle_b_eng_telem) self.assertEqual(self.publish_callback_value[2], self.particle_c_eng_telem) self.assertEqual(self.publish_callback_value[3], self.particle_d_eng_telem) self.assertEqual(self.file_ingested, True) def test_long_stream_recovered(self): """ Test a long stream of data """ self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) result = self.parser.get_records(32) self.assertEqual(result[0], self.particle_a_eng_recov) self.assertEqual(result[-1], self.particle_last_eng_recov) self.assertEqual(self.parser._state[StateKey.POSITION], 856) self.assertEqual(self.state_callback_value[StateKey.POSITION], 856) self.assertEqual(self.publish_callback_value[-1], self.particle_last_eng_recov) result = self.parser.get_records(1) self.assert_result(result, 872, self.particle_a_status_recov, True) def test_long_stream_telemetered(self): """ Test a long stream of data """ self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) result = self.parser.get_records(32) self.assertEqual(result[0], self.particle_a_eng_telem) self.assertEqual(result[-1], self.particle_last_eng_telem) self.assertEqual(self.parser._state[StateKey.POSITION], 856) self.assertEqual(self.state_callback_value[StateKey.POSITION], 856) self.assertEqual(self.publish_callback_value[-1], self.particle_last_eng_telem) result = self.parser.get_records(1) self.assert_result(result, 872, self.particle_a_status_telem, True) def test_after_header_recovered(self): """ Test starting the parser in a state in the middle of processing """ new_state = {StateKey.POSITION: 24} self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), new_state, self.stream_handle, self.state_callback, self.pub_callback) # get engineering records result = self.parser.get_records(1) self.assert_result(result, 50, self.particle_a_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 76, self.particle_b_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_recov, True) def test_after_header_telemetered(self): """ Test starting the parser in a state in the middle of processing """ new_state = {StateKey.POSITION: 24} self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), new_state, self.stream_handle, self.state_callback, self.pub_callback) # get engineering records result = self.parser.get_records(1) self.assert_result(result, 50, self.particle_a_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 76, self.particle_b_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_telem, True) def test_mid_state_start_recovered(self): """ Test starting the parser in a state in the middle of processing """ new_state = {StateKey.POSITION: 76} self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), new_state, self.stream_handle, self.state_callback, self.pub_callback) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_recov, True) def test_mid_state_start_telemetered(self): """ Test starting the parser in a state in the middle of processing """ new_state = {StateKey.POSITION: 76} self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), new_state, self.stream_handle, self.state_callback, self.pub_callback) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_telem, True) def test_set_state_recovered(self): """ Test changing to a new state after initializing the parser and reading data, as if new data has been found and the state has changed """ new_state = {StateKey.POSITION: 76} self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) # set the new state, the essentially skips engineering a and b self.parser.set_state(new_state) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_recov, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_recov, True) def test_set_state_telemetered(self): """ Test changing to a new state after initializing the parser and reading data, as if new data has been found and the state has changed """ new_state = {StateKey.POSITION: 76} self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_SHORT) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) # set the new state, the essentially skips engineering a and b self.parser.set_state(new_state) result = self.parser.get_records(1) self.assert_result(result, 102, self.particle_c_eng_telem, False) result = self.parser.get_records(1) self.assert_result(result, 128, self.particle_d_eng_telem, True) def test_bad_flags_recovered(self): """ test that we don't parse any records when the flags are not what we expect """ with self.assertRaises(SampleException): self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_BAD_FLAGS) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) def test_bad_flags_telemetered(self): """ test that we don't parse any records when the flags are not what we expect """ with self.assertRaises(SampleException): self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_BAD_FLAGS) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) def test_bad_data_recovered(self): """ Ensure that missing data causes us to miss records TODO: This test should be improved if we come up with a more accurate regex for the data sample """ self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_BAD_ENG) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_RECOVERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_recov, False) # next get engineering records result = self.parser.get_records(4) if len(result) == 4: self.fail("We got 4 records, the bad data should only make 3") def test_bad_data_telemetered(self): """ Ensure that missing data causes us to miss records TODO: This test should be improved if we come up with a more accurate regex for the data sample """ self.stream_handle = StringIO( WfpEngStcImodemParserUnitTestCase.TEST_DATA_BAD_ENG) self.parser = WfpEngStcImodemParser( self.config.get(DataTypeKey.WFP_ENG_STC_IMODEM_TELEMETERED), self.start_state, self.stream_handle, self.state_callback, self.pub_callback) # start with the start time record result = self.parser.get_records(1) self.assert_result(result, 24, self.particle_a_start_time_telem, False) # next get engineering records result = self.parser.get_records(4) if len(result) == 4: self.fail("We got 4 records, the bad data should only make 3") def particle_to_yml(self, particles, filename, mode='w'): """ This is added as a testing helper, not actually as part of the parser tests. Since the same particles will be used for the driver test it is helpful to write them to .yml in the same form they need in the results.yml fids here. """ # open write append, if you want to start from scratch manually delete this fid fid = open(os.path.join(RESOURCE_PATH, filename), mode) fid.write('header:\n') fid.write(" particle_object: 'MULTIPLE'\n") fid.write(" particle_type: 'MULTIPLE'\n") fid.write('data:\n') for i in range(0, len(particles)): particle_dict = particles[i].generate_dict() fid.write(' - _index: %d\n' % (i + 1)) fid.write(' particle_object: %s\n' % particles[i].__class__.__name__) fid.write(' particle_type: %s\n' % particle_dict.get('stream_name')) fid.write(' internal_timestamp: %f\n' % particle_dict.get('internal_timestamp')) for val in particle_dict.get('values'): if isinstance(val.get('value'), float): fid.write(' %s: %16.16f\n' % (val.get('value_id'), val.get('value'))) else: fid.write(' %s: %s\n' % (val.get('value_id'), val.get('value'))) fid.close()