def addTupleAlg(self): """ Add TupleHltDecReports to TopAlg """ alg = TupleHltDecReports(self._algName) seq = Sequence("Hlt") algSeq = Sequence("TupleSequence") algSeq.Members = [alg] seq.Members += [algSeq] ApplicationMgr().HistogramPersistency = "ROOT" tupleFile = self._filename ApplicationMgr().ExtSvc += [NTupleSvc()] tup = "FILE1 DATAFILE='" + tupleFile + "' TYP='ROOT' OPT='NEW'" NTupleSvc().Output = [tup] NTupleSvc().OutputLevel = 1
def configure(datafiles, catalogs=[], castor=False): """ Job configuration """ from PhysConf.Filters import LoKi_Filters fltrs = LoKi_Filters( VOID_Code= " 0.5 < CONTAINS('/Event/Charm/Phys/DstarForPromptCharm/Particles') ") ## ## 1. Static configuration using "Configurables" ## from Configurables import DaVinci davinci = DaVinci( DataType='2010', InputType='MDST', PrintFreq=1000, EventPreFilters=fltrs.filters('Filters'), HistogramFile='RealDstar_CHARM_Histos.root', TupleFile='RealDstar_CHARM.root', ## Lumi=True) from Configurables import CondDB CondDB(UseLatestTags=['2010']) from Configurables import NTupleSvc ntSvc = NTupleSvc() ## define the input data: setData(datafiles, catalogs, castor) ## ## 2. Jump into the wonderful world of the actual Gaudi components! ## ## get the actual application manager (create if needed) gaudi = appMgr() ## create local algorithm: alg = Dstar( # 'Dstar', ## Algorithm name # ## RecoStripping-09 conventions! RootInTES='/Event/Charm', Inputs=['Phys/DstarForPromptCharm/Particles'] ## input particles ) ## finally inform Application Manager about our algorithm userSeq = gaudi.algorithm('GaudiSequencer/DaVinciUserSequence', True) userSeq.Members += [alg.name()] return SUCCESS
def applyConf(self): if not self.isPropertySet("Sequencer"): raise RuntimeError("ERROR : Sequencer not set") protoSeq = self.getProp("Sequencer") protoSeq.Context = self.getProp("Context") from Configurables import ( NTupleSvc, ChargedProtoParticleTupleAlg, ChargedProtoParticleAddRichInfo, ChargedProtoParticleAddMuonInfo, ChargedProtoCombineDLLsAlg ) # The ntuple maker protoChecker = ChargedProtoParticleTupleAlg("ChargedProtoTuple") protoChecker.NTupleLUN = "PROTOTUPLE" # Fill sequence protoSeq.Members += [protoChecker] # The output ntuple ROOT file NTupleSvc().Output += ["PROTOTUPLE DATAFILE='"+self.getProp("ProtoTupleName")+"' TYP='ROOT' OPT='NEW'"] # ANN training ntuple if self.getProp("AddANNPIDInfo") : from Configurables import ( ANNGlobalPID__ChargedProtoANNPIDTrainingTuple ) annTuple = ANNGlobalPID__ChargedProtoANNPIDTrainingTuple("ChargedProtoPIDANNTuple") annTuple.NTupleLUN = "ANNPIDTUPLE" protoSeq.Members += [annTuple] NTupleSvc().Output += ["ANNPIDTUPLE DATAFILE='"+self.getProp("ANNTupleName")+"' TYP='ROOT' OPT='NEW'"] if self.isPropertySet("OutputLevel"): annTuple.OutputLevel = self.getProp("OutputLevel") # Set output levels if self.isPropertySet("OutputLevel"): level = self.getProp("OutputLevel") protoChecker.OutputLevel = level
from Configurables import L0Conf from Configurables import NTupleSvc from Configurables import PrChecker2 from Configurables import LoKi__Hybrid__MCTool from Gaudi.Configuration import GaudiSequencer # As we haven't ran Moore L0Conf().EnsureKnownTCK = False # Required to avoid Loki issues when running PrChecker2 myFactory = LoKi__Hybrid__MCTool("MCHybridFactory") myFactory.Modules = ["LoKiMC.decorators"] PrChecker2("PrChecker2").addTool(myFactory) GaudiSequencer("CheckPatSeq").Members = [ "PrChecker", "PrChecker2", "TrackIPResolutionChecker", "TrackIPResolutionCheckerNT", "VPClusterMonitor" ] NTupleSvc().Output += ["FILE1 DATAFILE='Brunel-tuples.root' TYP='ROOT' OPT='NEW'"]
#Gauss().Phases = [ 'Generator' , 'Simulation' ] Gauss().Phases = ["Generator","GenToMCTree"] #smear primary vertices timing information def CkvPVTimeSmearActivate(): from Configurables import Generation from Configurables import BeamSpotMarkovChainSampleVertex Generation("Generation").addTool(BeamSpotMarkovChainSampleVertex, name="BeamSpotMarkovChainSampleVertex") Generation("Generation").VertexSmearingTool = "BeamSpotMarkovChainSampleVertex" appendPostConfigAction(CkvPVTimeSmearActivate) from Configurables import GiGaGeo, GaussSensPlaneDet, TupleTool # from Configurables import ApplicationMgr, NTupleSvc name = "nInter=1_Bd2KpPimPi0" name = "nInter=1_Lb2ProtonKmPi0" name = name+"_Run%i"%(GaussGen.RunNumber,) NTupleSvc().Output = [ "FILE1 DATAFILE='%s.root' TYP='ROOT' OPT='NEW'"%(name,) ] ApplicationMgr().ExtSvc += [ NTupleSvc() ] OutputStream("GaussTape").Output = "DATAFILE='PFN:%s.sim' TYP='POOL_ROOTTREE' OPT='RECREATE'"%(name,)
dv = DaVinci() dv.DDDBtag = 'head-20110914' dv.CondDBtag = 'head-20110914' dv.DataType = '2011' dv.Lumi = False dv.InputType = "MDST" if mDST else "DST" dv.UserAlgorithms = [dtt] dv.EvtMax = -1 ApplicationMgr().HistogramPersistency = "ROOT" from Configurables import HistogramPersistencySvc HistogramPersistencySvc(OutputFile='histos.root') from Configurables import NTupleSvc NTupleSvc().Output += ["DTT DATAFILE='tuples.root' TYPE='ROOT' OPT='NEW'"] NTupleSvc().OutputLevel = 1 ## Point the EventClockSvc to the RootInTES ## from Configurables import EventClockSvc, OdinTimeDecoder, TimeDecoderList ## EventClockSvc().addTool( TimeDecoderList, name = "EventTimeDecoder" ) ## EventClockSvc().EventTimeDecoder.RootInTES = locationRoot from GaudiConf import IOHelper if mDST: ## IOHelper().inputFiles(['/castor/cern.ch/user/r/raaij/test/Swimming.SwimmingMicroDST.mdst']) IOHelper().inputFiles(['Swimming.SwimmingMDST.mdst']) else: IOHelper().inputFiles( ['/project/bfys/raaij/cmtuser/Moore_v12r8/scripts/SwimTrigDST.dst'])
def __apply_configuration__(self) : from Configurables import ( GaudiSequencer, CombineParticles ) from PhysSelPython.Wrappers import Selection, SelectionSequence, DataOnDemand if not self.isPropertySet("Sequencer") : raise RuntimeError("ERROR : Sequence not set") seq = self.getProp("Sequencer") if self.getProp("RunSelection") : # STD particles from StandardParticles import StdLooseMuons # J/psi -> mu mu JPsiMuMuName = self.__sel_name__ JPsiMuMu = CombineParticles(JPsiMuMuName) JPsiMuMu.DecayDescriptor = "J/psi(1S) -> mu+ mu- " JPsiMuMu.CombinationCut = "(ADAMASS('J/psi(1S)') < 150*MeV)" JPsiMuMu.MotherCut = "(ADMASS('J/psi(1S)') < 130*MeV) & (VFASPF(VCHI2/VDOF)<6) & (PT > 2500*MeV)" JPsiMuMu.DaughtersCuts = {"mu+" : "(PT>1400*MeV)"\ "& (P>5*GeV)"\ "& (TRCHI2DOF<2.0)"\ "& (PPINFO(LHCb.ProtoParticle.MuonBkgLL,-10000)<-2.5)"\ "& (PPINFO(LHCb.ProtoParticle.MuonMuLL,-10000)>-10)"} self.setOptions(JPsiMuMu) JPsiMuMuSel = Selection( JPsiMuMuName+'Sel', Algorithm = JPsiMuMu, RequiredSelections = [StdLooseMuons] ) # Selection Sequence selSeq = SelectionSequence( self.__sel_name__+'Seq', TopSelection = JPsiMuMuSel ) # Run the selection sequence. seq.Members += [selSeq.sequence()] # Particle Monitoring plots if self.getProp("RunMonitors") : from Configurables import ( ParticleMonitor ) plotter = ParticleMonitor(self.__sel_name__+"Plots") if self.getProp("RunSelection") : plotter.Inputs = [ 'Phys/'+self.__sel_name__+'Sel' ] else: musel = "(PT>1400*MeV) & (P>5*GeV) & (TRCHI2DOF<2.0) & "\ "(PPINFO(LHCb.ProtoParticle.MuonBkgLL,-10000)<-2.5) & "\ "(PPINFO(LHCb.ProtoParticle.MuonMuLL,-10000)>-10)" _code = "( ( INTREE( ('mu+'==ID) & "+musel+" ) ) | ( INTREE( ('mu-'==ID) & "+musel+" ) ) )" from Configurables import FilterDesktop filter = FilterDesktop( name = self.__sel_name__+"RICHFiltered", Code = _code, Inputs = self.getProp("Candidates") ) plotter.Inputs = [ 'Phys/'+filter.name() ] seq.Members += [filter] plotter.PeakCut = "(ADMASS('J/psi(1S)')<20*MeV)" # Considering sigma = 13 plotter.SideBandCut = "(ADMASS('J/psi(1S)')>20*MeV)" # Considering sigma = 13 plotter.PlotTools = self.getProp("PlotTools") self.setOptions(plotter) seq.Members += [plotter] # Make a DST ? if self.getProp("MakeSelDST"): # Prescale from Configurables import DeterministicPrescaler scaler = DeterministicPrescaler( self.__sel_name__+'PreScale', AcceptFraction = self.getProp("DSTPreScaleFraction") ) seq.Members += [scaler] # Write the DST MyDSTWriter = SelDSTWriter( self.__sel_name__+"DST", SelectionSequences = [ selSeq ], OutputPrefix = self.__sel_name__ ) seq.Members += [MyDSTWriter.sequence()] # MC Performance checking ? if self.getProp("MCChecks") : from Configurables import ParticleEffPurMoni mcPerf = ParticleEffPurMoni(JPsiMuMuName+"MCPerf") mcPerf.Inputs = ['Phys/'+self.__sel_name__+'Sel'] self.setOptions(mcPerf) seq.Members += [mcPerf] # Ntuple ? if self.getProp("MakeNTuple") : from Configurables import ( DecayTreeTuple, TupleToolDecay, LoKi__Hybrid__FilterCriterion, LoKi__Hybrid__TupleTool, TupleToolMCBackgroundInfo, BackgroundCategory, TupleToolTrigger, TupleToolMCTruth, MCTupleToolKinematic, MCTupleToolHierarchy, TupleToolVtxIsoln, TupleToolP2VV ) JPsiMuMuTree = DecayTreeTuple( JPsiMuMuName + 'Tuple') JPsiMuMuTree.Inputs = [ 'Phys/'+JPsiMuMuName] JPsiMuMuTree.Decay = 'J/psi(1S) -> ^mu+ ^mu- ' # set some names for ntuple branchs MyBranch_jpsi = "jpsi" MyBranch_mup = "mup" MyBranch_mum = "mum" # label the branches for the particle tools JPsiMuMuTree.Branches = { MyBranch_jpsi : "J/psi(1S) : J/psi(1S) -> mu+ mu- ", MyBranch_mup : "J/psi(1S) -> ^mu+ mu- ", MyBranch_mum : "J/psi(1S) -> mu+ ^mu- ", } JPsiMuMuTree.ToolList = [ "TupleToolEventInfo" , "TupleToolGeneration" , "TupleToolMCTruth" , "TupleToolMCBackgroundInfo" , "MCTupleToolKinematic" , "TupleToolPrimaries" , "TupleToolVtxIsoln" , "TupleToolTrackInfo" , "TupleToolPid" , "TupleToolGeometry" , "TupleToolKinematic" , "TupleToolPropertime" , "TupleToolPid" , "TupleToolPrimaries" , "TupleToolTrigger" ] JPsiMuMuTree.addTool(BackgroundCategory()) JPsiMuMuTree.BackgroundCategory.SoftPhotonCut = 2000 JPsiMuMuTree.OutputLevel = INFO JPsiMuMuTree.addTool(TupleToolTrigger()) JPsiMuMuTree.TupleToolTrigger.VerboseL0 = True JPsiMuMuTree.addTool(TupleToolMCTruth()) JPsiMuMuTree.TupleToolMCTruth.addTool(MCTupleToolKinematic()) JPsiMuMuTree.TupleToolMCTruth.addTool(MCTupleToolHierarchy()) JPsiMuMuTree.TupleToolMCTruth.ToolList = [ "MCTupleToolKinematic" , "MCTupleToolHierarchy" ] JPsiMuMuTree.TupleToolMCTruth.MCTupleToolKinematic.StoreKineticInfo = True JPsiMuMuTree.TupleToolMCTruth.MCTupleToolKinematic.StoreVertexInfo = True JPsiMuMuTree.TupleToolMCTruth.MCTupleToolKinematic.StorePropertimeInfo = False JPsiMuMuTree.addTool(TupleToolVtxIsoln( OutputLevel = 6 )) JPsiMuMuTree.TupleToolVtxIsoln.IP = 2.0 JPsiMuMuTree.TupleToolVtxIsoln.InputParticles = [ "Phys/StdLooseMuons"] seq.Members += [JPsiMuMuTree] JPsiMuMuTree.NTupleLUN = "JPSIMUMU" from Configurables import NTupleSvc NTupleSvc().Output = ["JPSIMUMU DATAFILE='JpsiMuMu_Presel.root' TYP='ROOT' OPT='NEW'"]
geosvc = GeoSvc("GeoSvc") geosvc.compact = geometry_path ############################################################################## # Event Data Svc ############################################################################## from Configurables import K4DataSvc dsvc = K4DataSvc("EventDataSvc", input="test-detsim10.root") ############################################################################## # NTuple Svc ############################################################################## from Configurables import NTupleSvc ntsvc = NTupleSvc("NTupleSvc") ntsvc.Output = ["MyTuples DATAFILE='result.root' OPT='NEW' TYP='ROOT'"] ############################################################################## # DumpAlg ############################################################################## from Configurables import DumpIDAlg alg = DumpIDAlg("DumpAlg") from Configurables import PodioInput podioinput = PodioInput("PodioReader", collections=["EcalBarrelCollection"]) # ApplicationMgr from Configurables import ApplicationMgr ApplicationMgr(TopAlg=[podioinput, alg],
Brunel().InputType = "DIGI" # implies also Brunel().Simulation = True Brunel().WithMC = True # implies also Brunel().Simulation = True Brunel().OutputType = "NONE" Brunel().Histograms = "Expert" TrackSys().TrackPatRecAlgorithms = [ "Truth", "FastVelo" ] Brunel().RecoSequence = ["Decoding", "Truth", "VELO" ] RecMoniConf().MoniSequence = [ ] Brunel().MCLinksSequence = [ "Tr" ] Brunel().MCCheckSequence = [ "Fit" ] from Configurables import DDDBConf DDDBConf().DbRoot = "/afs/cern.ch/user/o/ogruenbe/public/FT_upgrade/static_DDDB_FT_v4/lhcb.xml" Brunel().DDDBtag = "MC11-20111102" Brunel().CondDBtag = "sim-20111111-vc-md100" NTupleSvc().Output = ["FILE1 DATAFILE='~/w0/track.root' TYP='ROOT' OPT='NEW'"] from Configurables import LHCbApp from Gaudi.Configuration import * from GaudiConf import IOHelper IOHelper().inputFiles(['PFN:root://castorlhcb.cern.ch//castor/cern.ch/user/o/ocallot/Bs_mumu_v4_nu50.digi?svcClass=default']) Brunel().EvtMax = 1000 def doMyChanges(): from Configurables import GaudiSequencer GaudiSequencer("CaloBankHandler").Members = [] GaudiSequencer("RecoDecodingSeq").Members = [ "DecodeVeloRawBuffer/DecodeVeloClusters", "FTRawBankDecoder" ] GaudiSequencer("RecoTruthSeq").Members = [ "UnpackMCParticle", "UnpackMCVertex", "PrLHCbID2MCParticle" ] GaudiSequencer("MCLinksTrSeq").Members = ["PrTrackAssociator"]
InputLocations=['StdTightMuons'], ## input particles PP2MCs=['Relations/Rec/ProtoP/Charged'], ## PP -> MC tables NTupleLUN="MCMU") ## get input data: from LoKiExample.Bs2Jpsiphi_mm_data import Inputs as INPUT ## confgure the application itself: from Configurables import DaVinci DaVinci( DataType='DC06', ## Data type Simulation=True, ## Monte Carlo Hlt=False, # UserAlgorithms=[alg], ## let DaVinci know about local algorithm # delegate this properties to Event Selector EvtMax=500, SkipEvents=0, Input=INPUT, ## the list of input data files # delegate to Histogram Persistency Service HistogramFile="PsiPhi_Histos.root") ## n-Tuples from Configurables import NTupleSvc svc = NTupleSvc() svc.Output += ["MCMU DATAFILE='MCMuon_Tuples.root' TYP='ROOT' OPT='NEW'"] # ============================================================================= # The END # =============================================================================
ttsis.ReportStage = "Stripping" tttt = dtt.D.addTupleTool('TupleToolTISTOS') tttt.TriggerList = ['Hlt1TrackAllL0Decision', 'Hlt2CharmHadD02HH_D02KPiDecision'] tttt.VerboseHlt1 = True tttt.VerboseHlt2 = True dv = DaVinci() dv.DDDBtag = 'dddb-20120831' dv.CondDBtag = 'cond-20120831' dv.DataType = '2012' dv.Lumi = False dv.InputType = "MDST" dv.UserAlgorithms = [ killer,dtt ] dv.EvtMax = -1 dv.EnableUnpack = ['Stripping','Reconstruction'] # Where to save the output: dv.HistogramFile = "histos.root" dv.Simulation = False from Configurables import NTupleSvc NTupleSvc().Output += [ "DTT DATAFILE='SwimD2hhTuple_v14r8.root' TYPE='ROOT' OPT='NEW'"] NTupleSvc().OutputLevel = 1 from GaudiConf import IOHelper IOHelper().inputFiles(['Swimming.SwimStrippingD2hhMDST_v14r8.mdst']) # Use the CondDB to get the right database tags from Configurables import CondDB CondDB(UseOracle = False, DisableLFC = True)
# # tell the Data On Demand Service about them # DataOnDemandSvc().AlgMap[ "/Event/Link/MC/Particles2MCTTHits" ] = TTAssoc # DataOnDemandSvc().AlgMap[ "/Event/Link/MC/Particles2MCOTHits" ] = OTAssoc # DataOnDemandSvc().AlgMap[ "/Event/Link/MC/Particles2MCITHits" ] = ITAssoc # DataOnDemandSvc().NodeMap[ "/Event/Link" ] = "DataObject" # DataOnDemandSvc().NodeMap[ "/Event/Link/MC" ] = "DataObject" #GaudiSequencer("MCLinksTrSeq").Members = ["PrTrackAssociator"] from Configurables import PatLongLivedTracking as pllt pllt().WithDebugTool = True pllt().ForceMCTrack = False pllt().TimingMeasurement = True ApplicationMgr().ExtSvc += [NTupleSvc()] fileName = "~/work/tracking_data/my/Brunel_BdJPsiKs_MagU" #fileName="Brunel_my_fisher_debug_10kev" tupleName = "FILE1 DATAFILE='" + fileName + '.root' + "' TYP='ROOT' OPT='NEW'" NTupleSvc().Output = [tupleName] NTupleSvc().OutputLevel = 1 from Configurables import TrackAssociator def doIt(): GaudiSequencer("TrackHLT2SeedPatSeq").Members += [ TrackAssociator("AssocSeed", TracksInContainer="Rec/Track/Seed") ] GaudiSequencer("MCLinksUnpackSeq").Members = [] # from Configurables import PatChecker from Configurables import PrChecker
def rawDataToNtuple(options): # print options required_options = [ "runNumber", "start", "end", "outputdir", "nEvtsPerStep", "totsteps" ] for check_opts in required_options: if not options.has_key(check_opts): print "Please specify minimal options!" print "Option \'" + check_opts + "\' is missing!" sys.exit() start = options["start"] end = options["end"] runNumber = options["runNumber"] outputdir = options["outputdir"] totsteps = options["totsteps"] nEvtsPerStep = options["nEvtsPerStep"] from Configurables import DDDBConf, CondDB, CondDBAccessSvc, NTupleSvc, EventClockSvc, Brunel, LHCbApp # if options.has_key("IgnoreHeartBeat"): # CondDB().IgnoreHeartBeat = options["IgnoreHeartBeat"] if options.has_key("addCondDBLayer"): altag = "HEAD" if options.has_key("addCondDBLayer_tag"): altag = options["addCondDBLayer_tag"] CondDB().addLayer( CondDBAccessSvc("myCond", ConnectionString="sqlite_file:" + options["addCondDBLayer"] + "/LHCBCOND", DefaultTAG=altag)) # Need this line so as to not get db errors- should be fixed properly at some point CondDB().IgnoreHeartBeat = True CondDB().EnableRunStampCheck = False # customDBs = glob.glob('/group/rich/ActiveDBSlices/*.db') # for db in customDBs: # CondDB().addLayer( CondDBAccessSvc(os.path.basename(db), ConnectionString="sqlite_file:"+db+"/LHCBCOND", DefaultTAG="HEAD") ) # importOptions('$STDOPTS/DecodeRawEvent.py') #importOptions("$STDOPTS/RootHist.opts") #importOptions("$STDOPTS/RawDataIO.opts") #DEBUG by DisplayingHitMaps=False from Configurables import MDMRich1Algorithm mdmAlg = MDMRich1Algorithm("Rich1MDCS") mdmAlg.NumberOfEventsPerStep = nEvtsPerStep mdmAlg.StoreHistos = False mdmAlg.DEBUG = False if options.has_key("StoreHistos"): mdmAlg.StoreHistos = options["StoreHistos"] if options.has_key("DEBUG"): mdmAlg.DEBUG = options["DEBUG"] print "start step: " + str(start) print "stop step: " + str(end) print "processing " + str(nEvtsPerStep * (end - start)) + " events" tuplestring = "NTuple_Run%i_Steps%04d-%04d.root" % (runNumber, start, end) if options.has_key("TupleName"): tuplestring = options["TupleName"] histoname = "Histos_Run%i_Steps%04d-%04d.root" % (runNumber, start, end) if options.has_key("HistoName"): histoname = options["HistoName"] if outputdir != "": tuplestring = "%s/%s" % (outputdir, tuplestring) histoname = "%s/%s" % (outputdir, histoname) tuplename = "RICHTUPLE1 DATAFILE=\'%s\' TYP=\'ROOT\' OPT=\'NEW\'" % ( tuplestring) # Currently put in manually. Edit here to use correct db and conddb tags LHCbApp().DDDBtag = "dddb-20150724" LHCbApp().CondDBtag = "cond-20160123" if options.has_key("DDDBtag"): LHCbApp().DDDBtag = options["DDDBtag"] if options.has_key("CondDBtag"): LHCbApp().CondDBtag = options["CondDBtag"] #customDBs = glob.glob('/group/rich/ActiveDBSlices/*.db') #for db in customDBs: # CondDB().addLayer( CondDBAccessSvc(os.path.basename(db), ConnectionString="sqlite_file:"+db+"/LHCBCOND", DefaultTAG="HEAD") ) ApplicationMgr().TopAlg += [mdmAlg] ApplicationMgr().ExtSvc += ['DataOnDemandSvc'] ApplicationMgr().EvtMax = end * nEvtsPerStep # Timing information for application from Configurables import AuditorSvc, SequencerTimerTool ApplicationMgr().ExtSvc += ['AuditorSvc'] ApplicationMgr().AuditAlgorithms = True AuditorSvc().Auditors += ['TimingAuditor'] SequencerTimerTool().OutputLevel = 4 LHCbApp().TimeStamp = True HistogramPersistencySvc().OutputFile = histoname NTupleSvc().Output = [tuplename] EventSelector().PrintFreq = 10 EventSelector().PrintFreq = nEvtsPerStep EventSelector().FirstEvent = start * nEvtsPerStep print "First event: " + str(start * nEvtsPerStep) print "Last event: " + str(end * nEvtsPerStep) #get data, will look in local cluster first, then on castor isLocal = True if options.has_key("isLocal"): isLocal = options["isLocal"] DATA_and_Year = (getData(runNumber, start, end, totsteps, isLocal)) DATA = DATA_and_Year["DATA"] if not len(DATA) > 0: print "Data not found in local, switching to CASTOR" DATA_and_Year = getData(runNumber, start, end, totsteps, not isLocal) DATA = DATA_and_Year["DATA"] if not len(DATA) > 0: print "DATA not found anywhere!" sys.exit() LHCbApp.DataType = str(DATA_and_Year["year"]) EventSelector().Input = DATA EventClockSvc().EventTimeDecoder = "OdinTimeDecoder" appMgr = GaudiPython.AppMgr() appMgr.HistogramPersistency = "ROOT" #appMgr.OutputLevel=DEBUG evtSvc = appMgr.evtSvc() esel = appMgr.evtsel() esel.PrintFreq = nEvtsPerStep appMgr.initialize() appMgr.run(nEvtsPerStep * (end - start)) appMgr.stop() appMgr.finalize()
from Configurables import DummyDedxSimTool from Configurables import BetheBlochEquationDedxSimTool if dedxoption == "DummyDedxSimTool": dedx_simtool = DummyDedxSimTool("DummyDedxSimTool") elif dedxoption == "BetheBlochEquationDedxSimTool": dedx_simtool = BetheBlochEquationDedxSimTool("BetheBlochEquationDedxSimTool") dedx_simtool.material_Z = 2 dedx_simtool.material_A = 4 dedx_simtool.scale = 10 dedx_simtool.resolution = 0.0001 ############################################################################## from Configurables import NTupleSvc ntsvc = NTupleSvc("NTupleSvc") ntsvc.Output = ["MyTuples DATAFILE='DCH_digi_ana.root' OPT='NEW' TYP='ROOT'"] ############################################################################## from Configurables import DCHDigiAlg dCHDigiAlg = DCHDigiAlg("DCHDigiAlg") dCHDigiAlg.readout = "DriftChamberHitsCollection" dCHDigiAlg.drift_velocity = 40#um/ns dCHDigiAlg.mom_threshold = 0 #GeV dCHDigiAlg.SimDCHitCollection = "DriftChamberHitsCollection" dCHDigiAlg.DigiDCHitCollection = "DigiDCHitsCollection" dCHDigiAlg.AssociationCollection = "DCHAssociationCollectio" dCHDigiAlg.WriteAna = True ############################################################################## # POD I/O ##############################################################################
"Track:SubsetTracks", "Track:MarlinTrkTracks", "Vertex:KinkVertices", "Vertex:ProngVertices", "Vertex:V0Vertices", "ReconstructedParticle:KinkRecoParticles", "ReconstructedParticle:ProngRecoParticles", "ReconstructedParticle:V0RecoParticles" ] ############################################################################## from Configurables import GearSvc gearSvc = GearSvc("GearSvc") gearSvc.GearXMLFile = "Detector/DetCEPCv4/compact/FullDetGear.xml" ############################################################################## from Configurables import NTupleSvc ntsvc = NTupleSvc("NTupleSvc") ntsvc.Output = ["MyTuples DATAFILE='LCIO_Pan_ana.root' OPT='NEW' TYP='ROOT'"] ############################################################################## from Configurables import PandoraPFAlg pandoralg = PandoraPFAlg("PandoraPFAlg") pandoralg.debug = False pandoralg.use_dd4hep_geo = False pandoralg.use_dd4hep_decoder = False pandoralg.use_preshower = False pandoralg.WriteAna = True pandoralg.collections = [ "MCParticle:MCParticle", "CalorimeterHit:ECALBarrel", "CalorimeterHit:ECALEndcap", "CalorimeterHit:ECALOther", "CalorimeterHit:HCALBarrel", "CalorimeterHit:HCALEndcap", "CalorimeterHit:HCALOther", "CalorimeterHit:MUON", "CalorimeterHit:LCAL",
def __apply_configuration__(self): from Configurables import (GaudiSequencer, CombineParticles, OfflineVertexFitter) from PhysSelPython.Wrappers import Selection, SelectionSequence, DataOnDemand seq = self.getProp("Sequencer") if seq == None: raise RuntimeError("ERROR : Sequence not set") if self.getProp("RunSelection"): # STD particles from StandardParticles import StdNoPIDsPions, StdNoPIDsKaons # phi -> K+ K- Phi2KKName = self.__sel_name__ + "_Phi2KK" Phi2KK = CombineParticles(Phi2KKName) Phi2KK.DecayDescriptor = "phi(1020) -> K+ K-" Phi2KK.CombinationCut = "(ADAMASS('phi(1020)')<75*MeV)" Phi2KK.MotherCut = "(ADMASS('phi(1020)')<50*MeV) & (BPVVDCHI2>60) & (MIPDV(PRIMARY)<0.5) & (VFASPF(VCHI2) < 20)" Phi2KK.DaughtersCuts = { "K+": "(PT>300*MeV) & (P>2*GeV) & (MIPDV(PRIMARY) < 0.5) & (BPVIPCHI2() > 20)", "K-": "(PT>300*MeV) & (P>2*GeV) & (MIPDV(PRIMARY) < 0.5) & (BPVIPCHI2() > 20)" } self.setOptions(Phi2KK) Phi2KKSel = Selection(Phi2KKName + 'Sel', Algorithm=Phi2KK, RequiredSelections=[StdNoPIDsKaons]) # Bs -> J/psi phi Ds2piPhiName = self.__sel_name__ Ds2piPhi = CombineParticles(Ds2piPhiName) Ds2piPhi.DecayDescriptor = "[D_s+ -> pi+ phi(1020)]cc" Ds2piPhi.addTool(OfflineVertexFitter) Ds2piPhi.ParticleCombiners.update({"": "OfflineVertexFitter"}) Ds2piPhi.OfflineVertexFitter.useResonanceVertex = True Ds2piPhi.CombinationCut = "(ADAMASS('D_s+')<75*MeV)" Ds2piPhi.MotherCut = "(ADMASS('D_s+')<50*MeV) & (BPVDIRA>0.9999) & (BPVVDCHI2>85) & (MIPDV(PRIMARY)<0.1) & (VFASPF(VCHI2) < 10)" Ds2piPhi.DaughtersCuts = { "pi+": "(PT>300*MeV) & (P>2*GeV) & (MIPDV(PRIMARY) >0.1) & (BPVIPCHI2() > 20)" } self.setOptions(Ds2piPhi) Ds2piPhiSel = Selection( Ds2piPhiName + 'Sel', Algorithm=Ds2piPhi, RequiredSelections=[Phi2KKSel, StdNoPIDsPions]) # Selection Sequence selSeq = SelectionSequence(self.__sel_name__ + 'Seq', TopSelection=Ds2piPhiSel) # Run the selection sequence. seq.Members += [selSeq.sequence()] # Particle Monitoring plots if self.getProp("RunMonitors"): from Configurables import ParticleMonitor plotter = ParticleMonitor(self.__sel_name__ + "Plots") if self.getProp("RunSelection"): plotter.Inputs = ['Phys/' + self.__sel_name__ + 'Sel'] else: plotter.Inputs = self.getProp("Candidates") plotter.PeakCut = "(ADMASS('D_s+')<100*MeV)" plotter.SideBandCut = "(ADMASS('D_s+')>100*MeV)" plotter.PlotTools = self.getProp("PlotTools") self.setOptions(plotter) seq.Members += [plotter] # Make a DST ? if self.getProp("MakeSelDST"): # Prescale from Configurables import DeterministicPrescaler scaler = DeterministicPrescaler( self.__sel_name__ + 'PreScale', AcceptFraction=self.getProp("DSTPreScaleFraction")) seq.Members += [scaler] # Write the DST MyDSTWriter = SelDSTWriter(self.__sel_name__ + "DST", SelectionSequences=[selSeq], OutputPrefix=self.__sel_name__) seq.Members += [MyDSTWriter.sequence()] # MC Performance checking ? if self.getProp("MCChecks"): from Configurables import ParticleEffPurMoni mcPerf = ParticleEffPurMoni(Ds2piPhiName + "MCPerf") mcPerf.Inputs = ['Phys/' + self.__sel_name__ + 'Sel'] self.setOptions(mcPerf) seq.Members += [mcPerf] # Ntuple ? if self.getProp("MakeNTuple"): outputLevel = INFO from Configurables import ( DecayTreeTuple, TupleToolDecay, TupleToolMCTruth, TupleToolMCBackgroundInfo, TupleToolGeometry, TupleToolKinematic, TupleToolPrimaries, TupleToolEventInfo, MCTupleToolHierarchy, MCTupleToolKinematic, TupleToolPid, TupleToolTrackInfo, TupleToolVtxIsoln, LoKi__Hybrid__TupleTool) Tuple = DecayTreeTuple(Ds2piPhiName + "Tuple") Tuple.Inputs = ["Phys/" + Ds2piPhiName] Tuple.Decay = "[D_s+ -> ^pi+ (^phi(1020) => ^K+ ^K-)]cc" Tuple.Branches = { "pion": "[D_s+ -> ^pi+ (phi(1020) => K+ K-)]cc", "kaonplus": "[D_s+ -> pi+ (phi(1020) => ^K+ K-)]cc", "kaonminus": "[D_s+ -> pi+ (phi(1020) => K+ ^K-)]cc", "phi": "[D_s+ -> pi+ (^phi(1020) => K+ K-)]cc", "D_s": "[D_s+]cc :[D_s+ -> pi+ (phi(1020) => K+ K-)]cc" } Tuple.addTool(TupleToolDecay, name='pion') Tuple.addTool(TupleToolDecay, name='phi') Tuple.addTool(TupleToolDecay, name='kaonplus') Tuple.addTool(TupleToolDecay, name='kaonminus') Tuple.addTool(TupleToolDecay, name='D_s') # k+ specific kaonplusLoKiTool = LoKi__Hybrid__TupleTool('kaonplusLoKiTool') kaonplusLoKiTool.Variables = { "LOKI_PIDK": "PIDK", "LOKI_PIDe": "PIDe", "LOKI_PIDpi": "PIDpi", "LOKI_PIDp": "PIDp", "LOKI_PIDmu": "PIDmu", "LOKI_PIDK_PIDpi": "PIDK-PIDpi", "LOKI_PIDK_PIDe": "PIDK-PIDe", "LOKI_PIDK_PIDmu": "PIDK-PIDmu", "LOKI_PIDK_PIDp": "PIDK-PIDp" } Tuple.kaonplus.addTool(kaonplusLoKiTool, name='kaonplusLoKiTool') Tuple.kaonplus.ToolList = [ 'LoKi::Hybrid::TupleTool/kaonplusLoKiTool' ] # k- specific kaonminusLoKiTool = LoKi__Hybrid__TupleTool('kaonminusLoKiTool') kaonminusLoKiTool.Variables = { "LOKI_PIDK": "PIDK", "LOKI_PIDe": "PIDe", "LOKI_PIDpi": "PIDpi", "LOKI_PIDp": "PIDp", "LOKI_PIDmu": "PIDmu", "LOKI_PIDK_PIDpi": "PIDK-PIDpi", "LOKI_PIDK_PIDe": "PIDK-PIDe", "LOKI_PIDK_PIDmu": "PIDK-PIDmu", "LOKI_PIDK_PIDp": "PIDK-PIDp" } Tuple.kaonminus.addTool(kaonminusLoKiTool, name='kaonminusLoKiTool') Tuple.kaonminus.ToolList = [ 'LoKi::Hybrid::TupleTool/kaonminusLoKiTool' ] # pi+ specific pionLoKiTool = LoKi__Hybrid__TupleTool('pionLoKiTool') pionLoKiTool.Variables = { "LOKI_PIDK": "PIDK", "LOKI_PIDe": "PIDe", "LOKI_PIDpi": "PIDpi", "LOKI_PIDp": "PIDp", "LOKI_PIDmu": "PIDmu", "LOKI_PIDpi_PIDK": "PIDpi-PIDK", "LOKI_PIDpi_PIDe": "PIDpi-PIDe", "LOKI_PIDpi_PIDmu": "PIDpi-PIDmu", "LOKI_PIDpi_PIDp": "PIDpi-PIDp" } Tuple.pion.addTool(pionLoKiTool, name='pionLoKiTool') Tuple.pion.ToolList = ['LoKi::Hybrid::TupleTool/pionLoKiTool'] # phi specific phiLoKiTool = LoKi__Hybrid__TupleTool('phiLoKiTool') phiLoKiTool.Variables = {} Tuple.phi.addTool(phiLoKiTool, name='phiLoKiTool') Tuple.phi.ToolList = ['LoKi::Hybrid::TupleTool/phiLoKiTool'] # D_s specific DsLoKiTool = LoKi__Hybrid__TupleTool('DsLoKiTool') DsLoKiTool.Variables = {} Tuple.D_s.addTool(DsLoKiTool, name='DsLoKiTool') Tuple.D_s.ToolList = ["LoKi::Hybrid::TupleTool/DsLoKiTool"] # Common to all particles LoKiTool = LoKi__Hybrid__TupleTool('LoKiTool') LoKiTool.Variables = { "LOKI_ABSID": "ABSID", "LOKI_BPVIPCHI2": "BPVIPCHI2()", "LOKI_BPVDIRA": "BPVDIRA", "LOKI_BPVLTFITCHI2": "BPVLTFITCHI2('PropertimeFitter/properTime:PUBLIC')", "LOKI_BPVLTCHI2": "BPVLTCHI2('PropertimeFitter/properTime:PUBLIC')", "LOKI_BPVLTIME": "BPVLTIME('PropertimeFitter/properTime:PUBLIC')", "LOKI_BPVVDCHI2": "BPVVDCHI2", "LOKI_ID": "ID", "LOKI_MIPDV_PRIMARY": "MIPDV(PRIMARY)", "LOKI_MIPCHI2DV_PRIMARY": "MIPCHI2DV(PRIMARY)", "LOKI_MM": "MM", "LOKI_M": "M", "LOKI_P": "P", "LOKI_PT": "PT", "LOKI_TRCHI2": "TRCHI2", "LOKI_TRCHI2DOF": "TRCHI2DOF", "LOKI_VFASPF_VCHI2": "VFASPF(VCHI2)", "LOKI_VFASPF_VDOF": "VFASPF(VDOF)" } Tuple.addTool(LoKiTool, name='LoKiTool') Tuple.ToolList = [ "LoKi::Hybrid::TupleTool/LoKiTool", "TupleToolEventInfo", "TupleToolGeometry", "TupleToolKinematic", "TupleToolMCBackgroundInfo", "TupleToolPid", "TupleToolPrimaries", "TupleToolTrackInfo", "TupleToolVtxIsoln", "TupleToolMCTruth" ] Tuple.addTool(TupleToolEventInfo) Tuple.TupleToolEventInfo.OutputLevel = outputLevel Tuple.addTool(TupleToolGeometry) Tuple.TupleToolGeometry.OutputLevel = outputLevel Tuple.addTool(TupleToolKinematic) Tuple.TupleToolKinematic.OutputLevel = outputLevel Tuple.addTool(TupleToolMCBackgroundInfo) Tuple.TupleToolMCBackgroundInfo.OutputLevel = outputLevel Tuple.addTool(MCTupleToolHierarchy) Tuple.MCTupleToolHierarchy.OutputLevel = outputLevel Tuple.addTool(TupleToolMCTruth) Tuple.TupleToolMCTruth.OutputLevel = outputLevel Tuple.TupleToolMCTruth.addTool(MCTupleToolKinematic()) Tuple.TupleToolMCTruth.addTool(MCTupleToolHierarchy()) Tuple.TupleToolMCTruth.ToolList = [ "MCTupleToolKinematic", "MCTupleToolHierarchy" ] Tuple.TupleToolMCTruth.MCTupleToolKinematic.StoreKineticInfo = True Tuple.TupleToolMCTruth.MCTupleToolKinematic.StoreVertexInfo = True Tuple.TupleToolMCTruth.MCTupleToolKinematic.StorePropertimeInfo = True Tuple.TupleToolMCTruth.MCTupleToolKinematic.OutputLevel = outputLevel Tuple.addTool(TupleToolPid) Tuple.TupleToolPid.OutputLevel = outputLevel Tuple.addTool(TupleToolPrimaries) Tuple.TupleToolPrimaries.OutputLevel = outputLevel Tuple.addTool(TupleToolTrackInfo) Tuple.TupleToolTrackInfo.OutputLevel = outputLevel Tuple.addTool(TupleToolVtxIsoln) Tuple.TupleToolVtxIsoln.OutputLevel = outputLevel seq.Members += [Tuple] Tuple.NTupleLUN = "DSPHIPI" from Configurables import NTupleSvc NTupleSvc().Output = [ "DSPHIPI DATAFILE='DsToPhiPi.root' TYP='ROOT' OPT='NEW'" ]
def expertMonitoring(self, sequence): # Define the RICH ntuple file if self.getProp("NTupleProduce"): from Configurables import NTupleSvc NTupleSvc().Output += [ "RICHTUPLE1 DATAFILE='rich.tuples.root' TYP='ROOT' OPT='NEW'" ] checks = self.getHistoOptions("Monitors") tkTypes = self.getTrackTypes("RecoTrackTypes") check = "RichFuncCKResPlots" if check in checks: if "HistoProduce" in self.richTools().ckResolution().properties(): self.richTools().ckResolution( ).HistoProduce = self.getProp("Histograms") != "None" check = "RichPixelPositions" if check in checks: from Configurables import Rich__Rec__MC__PixelPositionMonitor seq = self.newSeq(sequence, check) seq.Members += [ Rich__Rec__MC__PixelPositionMonitor("RiRecPixelPosMoni") ] check = "HPDHitPlots" if check in checks: from Configurables import (Rich__Rec__HPDHitsMoni, GaudiSequencer) seq = self.newSeq(sequence, check) seq.IgnoreFilterPassed = True seq.Members += [Rich__Rec__HPDHitsMoni("HPDHitsMoni")] if not self.getProp("Simulation"): lSeq = self.newSeq(seq, check + "L0") lSeq.ReturnOK = True lSeq.Members = self.l0Filters() + [ Rich__Rec__HPDHitsMoni("HPDL0HitsMoni") ] check = "RichTrackGeometry" if check in checks: from Configurables import Rich__Rec__MC__TrackGeomMoni seq = self.newSeq(sequence, check) for trackType in tkTypes: name = "RiRec" + self.trackSelName(trackType) + "GeomMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__TrackGeomMoni, name, trackType) ] check = "RichTrackResolution" if check in checks: from Configurables import Rich__Rec__MC__TrackResolutionMoni seq = self.newSeq(sequence, check) for trackType in tkTypes: name = "RiRec" + self.trackSelName(trackType) + "TkResMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__TrackResolutionMoni, name, trackType) ] check = "RichCKThetaResolution" if check in checks: from Configurables import Rich__Rec__MC__CherenkovAngleMonitor seq = self.newSeq(sequence, check) for trackType in tkTypes: name = "RiRecPhotAng" + self.trackSelName(trackType) + "Moni" seq.Members += [ self.createMonitor(Rich__Rec__MC__CherenkovAngleMonitor, name, trackType) ] check = "RichTrackCKResolutions" if check in checks: from Configurables import Rich__Rec__MC__CherenkovResMoni seq = self.newSeq(sequence, check) for trackType in tkTypes: name = "RiRec" + self.trackSelName(trackType) + "CKResMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__CherenkovResMoni, name, trackType) ] check = "RichPhotonSignal" if check in checks: from Configurables import Rich__Rec__MC__PhotonSignalMonitor seq = self.newSeq(sequence, check) for trackType in tkTypes: name = "RiRecPhotSig" + self.trackSelName(trackType) + "TkMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__PhotonSignalMonitor, name, trackType) ] check = "RichPhotonGeometry" if check in checks: from Configurables import Rich__Rec__MC__PhotonGeomMonitor seq = self.newSeq(sequence, check) for trackType in tkTypes: name = "RiRecPhotGeom" + self.trackSelName( trackType) + "TkMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__PhotonGeomMonitor, name, trackType) ] check = "RichPhotonTrajectory" if check in checks: from Configurables import Rich__Rec__MC__PhotonTrajectoryMonitor seq = self.newSeq(sequence, check) for trackType in tkTypes: name = "RiRecPhotTraj" + self.trackSelName( trackType) + "TkMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__PhotonTrajectoryMonitor, name, trackType) ] check = "RichPhotonRecoCompare" if check in checks: from Configurables import Rich__Rec__MC__PhotonRecoCompare seq = self.newSeq(sequence, check) self.toolRegistry().Tools += [ "Rich::Rec::PhotonRecoUsingQuarticSoln/BaselinePhotonReco" ] for trackType in tkTypes: name = "RiRecPhotCompare" + self.trackSelName( trackType) + "TkMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__PhotonRecoCompare, name, trackType) ] check = "PhotonRecoEfficiency" if check in checks: recotools = [ "Rich::Rec::PhotonCreator/ForcedRichPhotonCreator", "Rich::Rec::PhotonRecoUsingQuarticSoln/ForcedPhotonReco", "Rich::Rec::SimplePhotonPredictor/ForcedRichPhotonPredictor" ] self.toolRegistry().Tools += recotools self.recoConf().toolRegistry().Tools += recotools seq = self.newSeq(sequence, check) for trackType in tkTypes: context = self.getTrackContext(trackType) from Configurables import (Rich__Rec__PhotonCreator, Rich__Rec__SimplePhotonPredictor) forcedCreator = Rich__Rec__PhotonCreator( context + ".ForcedRichPhotonCreator") forcedCreator.MinAllowedCherenkovTheta = [0.0, 0.0, 0.0] forcedCreator.MaxAllowedCherenkovTheta = [999, 999, 999] forcedCreator.MinPhotonProbability = [1e-99, 1e-99, 1e-99] forcedCreator.NSigma = [999, 999, 999] forcedCreator.PhotonPredictor = "ForcedRichPhotonPredictor" forcedCreator.PhotonRecoTool = "ForcedPhotonReco" forcedPredictor = Rich__Rec__SimplePhotonPredictor( context + ".ForcedRichPhotonPredictor") forcedPredictor.MinTrackROI = [0.0, 0.0, 0.0] forcedPredictor.MaxTrackROI = [9999, 9999, 9999] from Configurables import Rich__Rec__MC__PhotonRecoEffMonitor name = "RiRecPhotEff" + self.trackSelName(trackType) + "TkMoni" mon = self.createMonitor(Rich__Rec__MC__PhotonRecoEffMonitor, name, trackType) seq.Members += [mon] check = "RichPhotonRayTracingTests" if check in checks: from Configurables import Rich__Rec__MC__PhotonRayTraceTest seq = self.newSeq(sequence, check) self.toolRegistry().Tools += [ "Rich::Rec::PhotonRecoUsingQuarticSoln/BaselinePhotonReco" ] for trackType in tkTypes: name = "RiRecPhotRayTrace" + self.trackSelName( trackType) + "TkMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__PhotonRayTraceTest, name, trackType) ] check = "RichTrackRayTracingTests" if check in checks: from Configurables import Rich__Rec__MC__PhotonRecoRayTraceTest seq = self.newSeq(sequence, check) moniA = Rich__Rec__MC__PhotonRecoRayTraceTest( "PhotRayTraceTestSimple") moniA.FullHPDsInRayTracing = False moniB = Rich__Rec__MC__PhotonRecoRayTraceTest( "PhotRayTraceTestFull") moniB.FullHPDsInRayTracing = True seq.Members += [moniA, moniB] check = "RichStereoFitterTests" if check in checks: from Configurables import Rich__Rec__MC__StereoPhotonFitTest seq = self.newSeq(sequence, check) for trackType in tkTypes: name = "RiRecStereoFitter" + self.trackSelName( trackType) + "TkMoni" seq.Members += [ self.createMonitor(Rich__Rec__MC__StereoPhotonFitTest, name, trackType) ] check = "RichGhostTracks" if check in checks: from Configurables import Rich__Rec__MC__GhostTrackMoni seq = self.newSeq(sequence, check) seq.Members += [ self.createMonitor(Rich__Rec__MC__GhostTrackMoni, "RichGhostsMoni") ] check = "RichDataObjectChecks" if check in checks: from Configurables import Rich__Rec__DataObjVerifier seq = self.newSeq(sequence, check) moni = Rich__Rec__DataObjVerifier("RichRecObjPrint") moni.PrintPixels = True moni.PrintTracks = True moni.PrintSegments = True moni.PrintPhotons = True seq.Members += [moni] check = "RichRecoTiming" if check in checks: from Configurables import (AuditorSvc, ChronoAuditor, Rich__Rec__TimeMonitor) # Enable ChronoAuditor chronoAuditor = "ChronoAuditor" if chronoAuditor not in AuditorSvc().Auditors: AuditorSvc().Auditors += [chronoAuditor] ChronoAuditor().Enable = True seq = self.newSeq(sequence, check) cont = self.getProp("Context") # RICH reconstruction only (tracks,pixels,photons) moni = self.createMonitor(Rich__Rec__TimeMonitor, "RichRecoTime") moni.TimingName = "RichRecInit" + cont + "Seq" moni.Algorithms = [moni.TimingName] seq.Members += [moni] # RICH PID only moni = self.createMonitor(Rich__Rec__TimeMonitor, "RichPIDTime") moni.TimingName = "Rich" + cont + "PIDSeq" moni.Algorithms = [moni.TimingName] seq.Members += [moni] # overall RICH reconstruction moni = self.createMonitor(Rich__Rec__TimeMonitor, "OverallRichTime") moni.TimingName = "RecoRICHSeq" moni.Algorithms = [moni.TimingName] seq.Members += [moni] # overall track reconstruction moni = self.createMonitor(Rich__Rec__TimeMonitor, "OverallTrackTime") moni.TimingName = "RecoTrSeq" moni.Algorithms = [moni.TimingName] seq.Members += [moni] check = "RichTracksToTextFile" if check in checks: from Configurables import Rich__Rec__MC__DumpRichTracksToTextFileAlg as RichTracksToText moni = self.createMonitor(RichTracksToText, "RichTracksToText") sequence.Members += [moni] check = "RichHitsToTextFile" if check in checks: from Configurables import Rich__Rec__MC__DumpRichHitsToTextFileAlg as RichHitsToText moni = self.createMonitor(RichHitsToText, "RichHitsToText") sequence.Members += [moni] check = "RichPerfFromData" if check in checks: pass
from Configurables import LHCbApp, ApplicationMgr, DataOnDemandSvc, Boole from Configurables import SimConf, DigiConf, DecodeRawEvent from Configurables import CondDB, DDDBConf # ROOT persistency for histograms importOptions('$STDOPTS/RootHist.opts') from Configurables import RootHistCnv__PersSvc RootHistCnv__PersSvc('RootHistCnv').ForceAlphaIds = True # RootHistSvc('RootHistSvc').OutputFile = 'histo.root' HistogramPersistencySvc().OutputFile = fileName.replace(".root", "") + '_histos.root' from Configurables import NTupleSvc NTupleSvc().Output = [ "FILE1 DATAFILE='" + fileName.replace(".root", "") + "_tuple.root' TYP='ROOT' OPT='NEW'" ] from LinkerInstances.eventassoc import * import ROOT as R import array def resetSipmVals(sipimValPtr): for layer in sipimValPtr: for adcID in layer: for adcChan in layer[adcID]: adcChan[0] = 0