def run(): """ Run the macro """ # This input generates empty spills, to be filled by the beam maker later on my_input = MAUS.InputCppRootData() # Create an empty array of mappers, then populate it # with the functionality you want to use. my_map = MAUS.MapPyGroup() # Global my_map.append(MAUS.MapCppGlobalReconImport()) my_map.append(MAUS.MapCppGlobalTrackMatching()) my_reduce = MAUS.ReducePyDoNothing() # Then construct a MAUS output component - filename comes from datacards my_output = MAUS.OutputCppRoot() # can specify datacards here or by using appropriate command line calls datacards = io.StringIO(u"") # The Go() drives all the components you pass in, then check the file # (default simulation.out) for output MAUS.Go(my_input, my_map, my_reduce, my_output, datacards)
def run(): """ Run the macro """ # This input generates empty spills, to be filled by the beam maker later on my_input = MAUS.InputPySpillGenerator() # Create an empty array of mappers, then populate it # with the functionality you want to use. my_map = MAUS.MapPyGroup() # GEANT4 my_map.append(MAUS.MapPyBeamMaker()) # beam construction my_map.append(MAUS.MapCppSimulation()) # geant4 simulation # Pre detector set up my_map.append(MAUS.MapPyMCReconSetup()) # geant4 simulation # TOF my_map.append(MAUS.MapCppTOFMCDigitizer()) # TOF MC Digitizer my_map.append(MAUS.MapCppTOFSlabHits()) # TOF MC Slab Hits my_map.append(MAUS.MapCppTOFSpacePoints()) # TOF Space Points # SciFi my_map.append(MAUS.MapCppTrackerMCDigitization()) # SciFi electronics model my_map.append(MAUS.MapCppTrackerRecon()) # SciFi Recon # KL my_map.append(MAUS.MapCppKLMCDigitizer()) # KL MC Digitizer my_map.append(MAUS.MapCppKLCellHits()) # KL CellHit Reco # EMR my_map.append(MAUS.MapCppEMRMCDigitization()) # EMR MC Digitization my_map.append(MAUS.MapCppEMRSpacePoints()) my_map.append(MAUS.MapCppEMRRecon()) # EMR Recon # Ckov my_map.append(MAUS.MapCppCkovMCDigitizer()) # Global my_map.append(MAUS.MapCppGlobalReconImport()) my_map.append(MAUS.MapCppGlobalTrackMatching()) my_reduce = MAUS.ReducePyDoNothing() # Then construct a MAUS output component - filename comes from datacards #~ my_output = MAUS.OutputCppRoot() my_output = MAUS.OutputPyDoNothing() # can specify datacards here or by using appropriate command line calls datacards = io.StringIO(u"") # The Go() drives all the components you pass in, then check the file # (default simulation.out) for output MAUS.Go(my_input, my_map, my_reduce, my_output, datacards)
def tearDownClass(cls): # pylint: disable = C0103 """Sets a mapper and configuration, and checks that we can death() MapCppGlobalTrackMatching""" cls.mapper = MAUS.MapCppGlobalTrackMatching() if maus_cpp.globals.has_instance(): maus_cpp.globals.death() if cls.test_config != "": maus_cpp.globals.birth(cls.test_config) else: maus_cpp.globals.birth(json.dumps(MapCppGlobalTMTestCase.cfg)) # Check we death() the mapper cls.mapper.death() cls.mapper = None
def run(): """ Run the macro """ # This input generates empty spills, to be filled by the beam maker later on my_input = MAUS.InputPySpillGenerator() # Create an empty array of mappers, then populate it # with the functionality you want to use. my_map = MAUS.MapPyGroup() # G4beamline my_map.append(MAUS.MapPyBeamlineSimulation()) # GEANT4 # my_map.append(MAUS.MapPyBeamMaker()) # beam construction my_map.append(MAUS.MapCppSimulation()) # geant4 simulation # Pre detector set up my_map.append(MAUS.MapPyMCReconSetup()) # geant4 simulation # TOF my_map.append(MAUS.MapCppTOFMCDigitizer()) # TOF MC Digitizer my_map.append(MAUS.MapCppTOFSlabHits()) # TOF MC Slab Hits my_map.append(MAUS.MapCppTOFSpacePoints()) # TOF Space Points # KL my_map.append(MAUS.MapCppKLMCDigitizer()) # KL MC Digitizer my_map.append(MAUS.MapCppKLCellHits()) # KL CellHit Reco # SciFi # MAUS 2.5.0 #my_map.append(MAUS.MapCppTrackerMCDigitization()) # SciFi electronics model #my_map.append(MAUS.MapCppTrackerRecon()) # SciFi Recon my_map.append( MAUS.MapCppTrackerMCDigitization()) # SciFi electronics model my_map.append(MAUS.MapCppTrackerClusterRecon()) # SciFi channel clustering my_map.append( MAUS.MapCppTrackerSpacePointRecon()) # SciFi spacepoint recon my_map.append( MAUS.MapCppTrackerPatternRecognition()) # SciFi track finding my_map.append(MAUS.MapCppTrackerPRSeed()) # Set the Seed from PR my_map.append(MAUS.MapCppTrackerTrackFit()) # SciFi track fit my_map.append( MAUS.MapCppTrackerTOFReFit()) # SciFi track refit based on TOF # EMR my_map.append(MAUS.MapCppEMRMCDigitization()) # EMR MC Digitizer my_map.append(MAUS.MapCppEMRSpacePoints()) # EMR Space Points my_map.append(MAUS.MapCppEMRRecon()) # EMR Recon # Global my_map.append(MAUS.MapCppGlobalReconImport()) my_map.append(MAUS.MapCppGlobalTrackMatching()) # Then construct a MAUS output component - filename comes from datacards my_output = MAUS.OutputCppRoot() # can specify datacards here or by using appropriate command line calls datacards = io.StringIO(u"") # The Go() drives all the components you pass in, then check the file # (default simulation.out) for output MAUS.Go(my_input, my_map, MAUS.ReducePyDoNothing(), my_output, datacards)
def run(): """ Run the macro """ # Use the G4BL JSON chunks as an input to the simulation my_input = MAUS.InputPyJSON() # Create an empty array of mappers, then populate it # with the functionality you want to use. my_map = MAUS.MapPyGroup() # No need for the beam maker, as we use G4BL chunks # my_map.append(MAUS.MapPyBeamMaker()) # beam construction # Run the GEANT4 simulation my_map.append(MAUS.MapCppSimulation()) # geant4 simulation # Pre detector set up my_map.append(MAUS.MapCppMCReconSetup()) # geant4 simulation # TOF my_map.append(MAUS.MapCppTOFMCDigitizer()) # TOF MC Digitizer my_map.append(MAUS.MapCppTOFSlabHits()) # TOF MC Slab Hits my_map.append(MAUS.MapCppTOFSpacePoints()) # TOF Space Points # KL my_map.append(MAUS.MapCppKLMCDigitizer()) # KL MC Digitizer my_map.append(MAUS.MapCppKLCellHits()) # KL CellHit Reco # SciFi my_map.append( MAUS.MapCppTrackerMCDigitization()) # SciFi electronics model my_map.append(MAUS.MapCppTrackerClusterRecon()) # SciFi channel clustering my_map.append( MAUS.MapCppTrackerSpacePointRecon()) # SciFi spacepoint recon my_map.append( MAUS.MapCppTrackerPatternRecognition()) # SciFi track finding my_map.append(MAUS.MapCppTrackerPRSeed()) # Set the Seed from PR my_map.append(MAUS.MapCppTrackerTrackFit()) # SciFi track fit my_map.append( MAUS.MapCppTrackerTOFCombinedFit()) # ScifFi Tracker/TOF combined fit # EMR my_map.append(MAUS.MapCppEMRMCDigitization()) # EMR MC Digitization my_map.append(MAUS.MapCppEMRSpacePoints()) # EMR MC Digitization my_map.append(MAUS.MapCppEMRRecon()) # EMR Recon # Ckov my_map.append(MAUS.MapCppCkovMCDigitizer()) my_map.append( MAUS.MapCppGlobalReconImport()) # import tracks for global matching my_map.append(MAUS.MapCppGlobalTrackMatching()) # global track matching # Cuts # my_map.append(MAUS.MapCppCuts()) # Global Digits - post detector digitisation # Then construct a MAUS output component - filename comes from datacards my_output = MAUS.OutputCppRoot() # can specify datacards here or by using appropriate command line calls datacards = io.StringIO(u"") # The Go() drives all the components you pass in, then check the file # (default simulation.out) for output MAUS.Go(my_input, my_map, MAUS.ReducePyDoNothing(), my_output, datacards)