db/db6/embeddingCustomizeAll_8py_source.html

 # -*- coding: utf-8 -*-


 import FWCore.ParameterSet.Config as cms


 from TauAnalysis.MCEmbeddingTools.rerunParticleFlow import rerunParticleFlow


 import os


 def customise(process):


   # Define configuration parameter default values

   from TauAnalysis.MCEmbeddingTools.setDefaults import setDefaults

   setDefaults(process)


   inputProcess = process.customization_options.inputProcessRECO.value()

   print "Input process set to '%s'" % inputProcess


   process._Process__name = "EmbeddedRECO"


   # DQM store output for muon acceptance histograms

   process.DQMStore = cms.Service("DQMStore")


   if process.customization_options.isMC.value():

     print "Input is MC"


     # select generator level muons

     process.genMuonsFromZs = cms.EDProducer("GenParticlesFromZsSelectorForMCEmbedding",

       src = cms.InputTag("genParticles", "", process.customization_options.inputProcessSIM.value()),

       pdgIdsMothers = cms.vint32(23, 22),

       pdgIdsDaughters = cms.vint32(13),

       maxDaughters = cms.int32(2),

       minDaughters = cms.int32(2),

       before_or_afterFSR = cms.string("afterFSR"),

       verbosity = cms.int32(0)

     )

     process.ProductionFilterSequence.replace(process.cleanedGeneralTracks, process.genMuonsFromZs*process.cleanedGeneralTracks)

     process.ProductionFilterSequence.replace(process.cleanedParticleFlow, process.genMuonsFromZs*process.cleanedParticleFlow)


     # produce generator level MET (= sum of neutrino momenta)

     # in case Embedding is run on Monte Carlo input

     process.genMetCalo = cms.EDProducer("MixedGenMEtProducer",

       srcGenParticles1 = cms.InputTag("genParticles", "", process.customization_options.inputProcessSIM.value()),

       srcGenParticles2 = cms.InputTag("genParticles"),

       srcRemovedMuons = cms.InputTag(process.customization_options.ZmumuCollection.getModuleLabel()),

       type = cms.string("calo"),

       isMC = cms.bool(True)

     )

     process.genMetTrue = process.genMetCalo.clone(

       type = cms.string("pf")

     )

   else:

     print "Input is Data"


     # produce generator level MET (= sum of neutrino momenta)

     # in case Embedding is run on real Data

     process.genMetCalo = cms.EDProducer("MixedGenMEtProducer",

       srcGenParticles1 = cms.InputTag(""),

       srcGenParticles2 = cms.InputTag("genParticles"),

       srcRemovedMuons = cms.InputTag(process.customization_options.ZmumuCollection.getModuleLabel()),

       type = cms.string("calo"),

       isMC = cms.bool(False)

     )

     process.genMetTrue = process.genMetCalo.clone(

       type = cms.string("pf")

     )

   for p in process.paths:

     pth = getattr(process, p)

     if "genParticles" in pth.moduleNames():

       pth.replace(process.genParticles, process.genParticles*process.genMetCalo*process.genMetTrue)


   # update InputTags defined in PFEmbeddingSource_cff.py

   print "Setting collection of Z->mumu candidates to '%s'" % process.customization_options.ZmumuCollection.getModuleLabel()

   if not (hasattr(process, "cleanedGeneralTracks") and hasattr(process, "cleanedParticleFlow")):

     process.load("TauAnalysis.MCEmbeddingTools.PFEmbeddingSource_cff")

   if process.customization_options.replaceGenOrRecMuonMomenta.value() == 'gen':

     print "Taking momenta of generated tau leptons from generator level muons"

     process.generator.src = cms.InputTag('genMuonsFromZs')

   elif process.customization_options.replaceGenOrRecMuonMomenta.value() == 'rec':

     print "Taking momenta of generated tau leptons from reconstructed muons"

     process.generator.src = process.customization_options.ZmumuCollection

   else:

     raise ValueError("Invalid Configuration parameter 'replaceGenOrRecMuonMomenta' = %s !!" % process.customization_options.replaceGenOrRecMuonMomenta.value())

   # update option for removing tracks/charged PFCandidates matched to reconstructed muon

   process.cleanedGeneralTracks.selectedMuons = process.customization_options.ZmumuCollection

   process.cleanedParticleFlow.selectedMuons = process.customization_options.ZmumuCollection

   if process.customization_options.muonTrackCleaningMode.value() == 1:

     process.cleanedGeneralTracks.removeDuplicates = cms.bool(False)

     process.cleanedParticleFlow.removeDuplicates = cms.bool(False)

   elif process.customization_options.muonTrackCleaningMode.value() == 2:

     process.cleanedGeneralTracks.removeDuplicates = cms.bool(True)

     process.cleanedParticleFlow.removeDuplicates = cms.bool(True)

   else:

     raise ValueError("Invalid Configuration parameter 'muonTrackCleaningMode' = %i !!" % process.customization_options.muonTrackCleaningMode.value())


   try:

     outputModule = process.output

   except:

     pass

   try:

     outputModule = getattr(process, str(getattr(process, list(process.endpaths)[-1])))

   except:

     pass


   print "Changing event-content to AODSIM + Z->mumu candidates"

   outputModule.outputCommands = cms.untracked.vstring("drop *")

   outputModule.outputCommands.extend(process.AODSIMEventContent.outputCommands)


   # get rid of second "drop *"

   index = 0

   for item in outputModule.outputCommands[:]:

     if item == "drop *" and index != 0:

       del outputModule.outputCommands[index]

       index -= 1

     index += 1


   # keep collections of generator level muons

   outputModule.outputCommands.extend([

     'keep *_genMuonsFromZs_*_*'

   ])


   # keep collections of reconstructed muons

   outputModule.outputCommands.extend([

     'keep *_goodMuons_*_*',

     'keep *_goodMuonsPFIso_*_*',

     'keep *_highestPtMuPlus_*_*',

     'keep *_highestPtMuMinus_*_*',

     'keep *_highestPtMuPlusPFIso_*_*',

     'keep *_highestPtMuMinusPFIso_*_*'

   ])


   # keep collections of reconstructed Z -> mumu candidates

   # (with different muon isolation criteria applied)

   outputModule.outputCommands.extend([

     'keep *_goldenZmumuCandidatesGe0IsoMuons_*_*',

     'keep *_goldenZmumuCandidatesGe1IsoMuons_*_*',

     'keep *_goldenZmumuCandidatesGe2IsoMuons_*_*',

     'keep TH2DMEtoEDM_MEtoEDMConverter_*_*'

   ])


   # keep flag indicating whether event passes or fails

   #  o Z -> mumu event selection

   #  o muon -> muon + photon radiation filter

   outputModule.outputCommands.extend([

     'keep *_goldenZmumuFilterResult_*_*',

     'keep *_genMuonRadiationFilter_*_*',

     'keep *_muonRadiationFilter_*_*'

   ])


   # CV: keep HepMCProduct for embedded event,

   #     in order to run Validation/EventGenerator/python/TauValidation_cfi.py

   #     for control plots of tau polarization and decay mode information

   outputModule.outputCommands.extend([

     'keep *HepMCProduct_generator_*_*'

   ])


   # keep distance of muons traversed in ECAL and HCAL,

   # expected and removed muon energy deposits

   outputModule.outputCommands.extend([

     'keep *_muonCaloEnergyDepositsByDistance_totalDistanceMuPlus_*',

     'keep *_muonCaloEnergyDepositsByDistance_totalEnergyDepositMuPlus_*',

     'keep *_muonCaloEnergyDepositsByDistance_totalDistanceMuMinus_*',

     'keep *_muonCaloEnergyDepositsByDistance_totalEnergyDepositMuMinus_*',

     'keep *_castorreco_removedEnergyMuMinus*_*',

     'keep *_castorreco_removedEnergyMuPlus*_*',

     'keep *_hfreco_removedEnergyMuMinus*_*',

     'keep *_hfreco_removedEnergyMuPlus*_*',

     'keep *_ecalPreshowerRecHit_removedEnergyMuMinus*_*',

     'keep *_ecalPreshowerRecHit_removedEnergyMuPlus*_*',

     'keep *_ecalRecHit_removedEnergyMuMinus*_*',

     'keep *_ecalRecHit_removedEnergyMuPlus*_*',

     'keep *_hbhereco_removedEnergyMuMinus*_*',

     'keep *_hbhereco_removedEnergyMuPlus*_*',

     'keep *_horeco_removedEnergyMuMinus*_*',

     'keep *_horeco_removedEnergyMuPlus*_*',

   ])


   # replace HLT process name

   # (needed for certain reprocessed Monte Carlo samples)

   hltProcessName = "HLT"

   try:

     hltProcessName = __HLT__

   except:

     pass

   try:

     process.dimuonsHLTFilter.TriggerResultsTag.processName = hltProcessName

     process.goodZToMuMuAtLeast1HLT.TrigTag.processName = hltProcessName

     process.goodZToMuMuAtLeast1HLT.triggerEvent.processName = hltProcessName

     process.hltTrigReport,HLTriggerResults.processName = hltProcessName

   except:

     pass


   # disable L1GtTrigReport module

   # (not used for anything yet, just prints error for every single event)

   if hasattr(process, 'HLTAnalyzerEndpath'):

     process.HLTAnalyzerEndpath.remove(process.hltL1GtTrigReport)


   # apply configuration parameters

   print "Setting mdtau to %i" % process.customization_options.mdtau.value()

   process.generator.Ztautau.TauolaOptions.InputCards.mdtau = process.customization_options.mdtau

   if hasattr(process.generator, "ParticleGun"):

     process.generator.ParticleGun.ExternalDecays.Tauola.InputCards.mdtau = process.customization_options.mdtau

   if process.customization_options.useTauolaPolarization.value():

     print "Enabling tau polarization effects in TAUOLA"

     # NOTE: polarization effects are only approximate,

     #       because Embedded events do not have proper parton history in HepMC::GenEvent

     #      (cf. arXiv:hep-ph/0101311 and arXiv:1201.0117)

     process.generator.Ztautau.TauolaOptions.UseTauolaPolarization = cms.bool(True)

   else:

     print "Disabling tau polarization effects in TAUOLA"

     # NOTE: tau polarization effects need to be added by reweighting Embedded events

     #       using weights computed by TauSpinner package

     process.generator.Ztautau.TauolaOptions.UseTauolaPolarization = cms.bool(False)


   print "Setting minVisibleTransverseMomentum to '%s'" % process.customization_options.minVisibleTransverseMomentum.value()

   process.generator.Ztautau.minVisibleTransverseMomentum = process.customization_options.minVisibleTransverseMomentum


   print "Setting transformationMode to %i" % process.customization_options.transformationMode.value()

   process.generator.Ztautau.transformationMode = process.customization_options.transformationMode


   print "Setting rfRotationAngle to %1.0f" % process.customization_options.rfRotationAngle.value()

   process.generator.Ztautau.rfRotationAngle = process.customization_options.rfRotationAngle


   print "Setting rfMirror to %s" % process.customization_options.rfMirror.value()

   process.generator.Ztautau.rfMirror = process.customization_options.rfMirror


   print "Setting muon radiation corrections to \"%s\"" % process.customization_options.applyMuonRadiationCorrection.value()

   process.generator.Ztautau.applyMuonRadiationCorrection = process.customization_options.applyMuonRadiationCorrection


   if process.customization_options.overrideBeamSpot.value():

     bs = cms.string("BeamSpotObjects_2009_LumiBased_SigmaZ_v28_offline")

     process.GlobalTag.toGet = cms.VPSet(

       cms.PSet(

         record = cms.string("BeamSpotObjectsRcd"),

         tag = bs,

         connect = cms.untracked.string("frontier://FrontierProd/CMS_COND_31X_BEAMSPOT")

       )

     )

     print "BeamSpot in globaltag set to '%s'" % bs

   else:

     print "BeamSpot in globaltag not changed"


   # CV: disable gen. vertex smearing

   #    (embed tau leptons exactly at Z->mumu event vertex)

   print "Disabling gen. vertex smearing"

   process.VtxSmeared = cms.EDProducer("FlatEvtVtxGenerator",

     MaxZ = cms.double(0.0),

     MaxX = cms.double(0.0),

     MaxY = cms.double(0.0),

     MinX = cms.double(0.0),

     MinY = cms.double(0.0),

     MinZ = cms.double(0.0),

     TimeOffset = cms.double(0.0),

     src = cms.InputTag("generator")

   )


   if process.customization_options.useJson.value():

     print "Enabling event selection by JSON file"

     import PhysicsTools.PythonAnalysis.LumiList as LumiList

     import FWCore.ParameterSet.Types as CfgTypes

     myLumis = LumiList.LumiList(filename = 'my.json').getCMSSWString().split(',')

     process.source.lumisToProcess = CfgTypes.untracked(CfgTypes.VLuminosityBlockRange())

     process.source.lumisToProcess.extend(myLumis)


   #----------------------------------------------------------------------------------------------------------------------

   # CV: need to rerun particle-flow algorithm in order to create links between PFMuon -> PFBlocks -> PFClusters -> PFRecHits

   #    (configure particle-flow sequence before overwriting modules in order to mix collections

   #     of objects reconstructed and Z -> mu+ mu- event with simulated tau decay products)

   if process.customization_options.embeddingMode.value() == "RH" and process.customization_options.cleaningMode == 'PF':

     rerunParticleFlow(process, inputProcess)

     process.ProductionFilterSequence += process.rerunParticleFlowSequenceForPFMuonCleaning

   #----------------------------------------------------------------------------------------------------------------------


   # mix "general" Track collection

   process.generalTracksORG = process.generalTracks.clone()

   process.generalTracks = cms.EDProducer("TrackMixer",

     todo = cms.VPSet(

       cms.PSet(

         collection1 = cms.InputTag("generalTracksORG", "", "EmbeddedRECO"),

         collection2 = cms.InputTag("cleanedGeneralTracks")

       )

     ),

     verbosity = cms.int32(0)

   )


   for p in process.paths:

     pth = getattr(process,p)

     if "generalTracks" in pth.moduleNames():

       pth.replace(process.generalTracks, process.generalTracksORG*process.generalTracks)


   #----------------------------------------------------------------------------------------------------------------------

   # CV/TF: mixing of std::vector<Trajectory> from Zmumu event and embedded tau decay products does not work yet.

   #        For the time-being, we need to use the Trajectory objects from the embedded event

   process.trackerDrivenElectronSeedsORG = process.trackerDrivenElectronSeeds.clone()

   process.trackerDrivenElectronSeedsORG.TkColList = cms.VInputTag(

     cms.InputTag("generalTracksORG")

   )


   process.trackerDrivenElectronSeeds = cms.EDProducer("ElectronSeedTrackRefUpdater",

     PreIdLabel = process.trackerDrivenElectronSeedsORG.PreIdLabel,

     PreGsfLabel = process.trackerDrivenElectronSeedsORG.PreGsfLabel,

     targetTracks = cms.InputTag("generalTracks"),

     inSeeds = cms.InputTag("trackerDrivenElectronSeedsORG", process.trackerDrivenElectronSeedsORG.PreGsfLabel.value()),

     inPreId = cms.InputTag("trackerDrivenElectronSeedsORG", process.trackerDrivenElectronSeedsORG.PreIdLabel.value()),

   )


   for p in process.paths:

     pth = getattr(process,p)

     if "trackerDrivenElectronSeeds" in pth.moduleNames():

         pth.replace(process.trackerDrivenElectronSeeds, process.trackerDrivenElectronSeedsORG*process.trackerDrivenElectronSeeds)


   # CV: need to keep 'generalTracksORG' collection in event-content,

   #     as (at least electron based) PFCandidates will refer to it,

   #     causing exception in 'pfNoPileUp' module otherwise

   outputModule.outputCommands.extend(['keep recoTracks_generalTracksORG_*_*'])

   #----------------------------------------------------------------------------------------------------------------------


   #----------------------------------------------------------------------------------------------------------------------

   # mix collections of GSF electron tracks

   process.electronGsfTracksORG = process.electronGsfTracks.clone()

   process.electronGsfTracks = cms.EDProducer("GsfTrackMixer",

     collection1 = cms.InputTag("electronGsfTracksORG", "", "EmbeddedRECO"),

     collection2 = cms.InputTag("electronGsfTracks", "", inputProcess)

   )


   process.gsfConversionTrackProducer.TrackProducer = cms.string('electronGsfTracksORG')


   for p in process.paths:

     pth = getattr(process,p)

     if "electronGsfTracks" in pth.moduleNames():

         pth.replace(process.electronGsfTracks, process.electronGsfTracksORG*process.electronGsfTracks)


   process.generalConversionTrackProducer.TrackProducer = cms.string('generalTracksORG')

   process.uncleanedOnlyGeneralConversionTrackProducer.TrackProducer = cms.string('generalTracksORG')


   process.gsfElectronsORG = process.gsfElectrons.clone()

   process.gsfElectrons = cms.EDProducer("GSFElectronsMixer",

       col1 = cms.InputTag("gsfElectronsORG"),

       col2 = cms.InputTag("gsfElectrons", "", inputProcess)

   )

   for p in process.paths:

     pth = getattr(process,p)

     if "gsfElectrons" in pth.moduleNames():

       pth.replace(process.gsfElectrons, process.gsfElectronsORG*process.gsfElectrons)

   #----------------------------------------------------------------------------------------------------------------------


   # dE/dx information for mixed track collections not yet implemented in 'TracksMixer' module,

   # disable usage of dE/dx information in all event reconstruction modules for now

   for p in process.paths:

     pth = getattr(process,p)

     for mod in pth.moduleNames():

       if mod.find("dedx") != -1 and mod.find("Zmumu") == -1:

         if mod.find("ForPFMuonCleaning") == -1:

           print "Removing %s" % mod

         module = getattr(process, mod)

         pth.remove(module)


   # CV: Compute expected energy deposits of muon in EB/EE, HB/HE and HO:

   #      (1) compute distance traversed by muons produced in Z -> mu+ mu- decay

   #          through individual calorimeter cells

   #      (2) scale distances by expected energy loss dE/dx of muon

   from TrackingTools.TrackAssociator.default_cfi import TrackAssociatorParameterBlock

   process.muonCaloDistances = cms.EDProducer('MuonCaloDistanceProducer',

     trackAssociator = TrackAssociatorParameterBlock.TrackAssociatorParameters,

     selectedMuons = process.customization_options.ZmumuCollection)

   process.ProductionFilterSequence += process.muonCaloDistances


   # mix collections of L1Extra objects

   l1ExtraCollections = [

       [ "L1EmParticle",     "Isolated"    ],

       [ "L1EmParticle",     "NonIsolated" ],

       [ "L1EtMissParticle", "MET"         ],

       [ "L1EtMissParticle", "MHT"         ],

       [ "L1JetParticle",    "Central"     ],

       [ "L1JetParticle",    "Forward"     ],

       [ "L1JetParticle",    "Tau"         ],

       [ "L1MuonParticle",   ""            ]

   ]

   l1extraParticleCollections = []

   for l1ExtraCollection in l1ExtraCollections:

       inputType = l1ExtraCollection[0]

       pluginType = None

       srcVeto = cms.InputTag('')

       dRveto = 0.

       if inputType == "L1EmParticle":

           pluginType = "L1ExtraEmParticleMixerPlugin"

           srcSelectedMuons = process.customization_options.ZmumuCollection

           dRveto = 0.3

       elif inputType == "L1EtMissParticle":

           pluginType = "L1ExtraMEtMixerPlugin"

       elif inputType == "L1JetParticle":

           pluginType = "L1ExtraJetParticleMixerPlugin"

           srcSelectedMuons = process.customization_options.ZmumuCollection

           dRveto = 0.3

       elif inputType == "L1MuonParticle":

           pluginType = "L1ExtraMuonParticleMixerPlugin"

           srcSelectedMuons = process.customization_options.ZmumuCollection

           dRveto = 0.8

       else:

           raise ValueError("Invalid L1Extra type = %s !!" % inputType)

       instanceLabel = l1ExtraCollection[1]

       l1extraParticleCollections.append(cms.PSet(

           pluginType = cms.string(pluginType),

       instanceLabel = cms.string(instanceLabel),

       srcSelectedMuons2 = srcSelectedMuons,

           dRveto2 = cms.double(dRveto)))

       if inputType == 'L1EtMissParticle':

         l1extraParticleCollections[-1].srcMuons = cms.InputTag("muonCaloDistances", "muons")

         l1extraParticleCollections[-1].distanceMapMuPlus = cms.InputTag("muonCaloDistances", "distancesMuPlus")

         l1extraParticleCollections[-1].distanceMapMuMinus = cms.InputTag("muonCaloDistances", "distancesMuPlus")

         l1extraParticleCollections[-1].H_Calo_AbsEtaLt12 = cms.double(process.customization_options.muonCaloCleaningSF.value()*0.75)

         l1extraParticleCollections[-1].H_Calo_AbsEta12to17 = cms.double(process.customization_options.muonCaloCleaningSF.value()*0.6)

         l1extraParticleCollections[-1].H_Calo_AbsEtaGt17 = cms.double(process.customization_options.muonCaloCleaningSF.value()*0.3)


   process.l1extraParticlesORG = process.l1extraParticles.clone()

   process.l1extraParticles = cms.EDProducer('L1ExtraMixer',

       src1 = cms.InputTag("l1extraParticlesORG"),

       src2 = cms.InputTag("l1extraParticles", "", inputProcess),

       collections = cms.VPSet(l1extraParticleCollections)

   )

   for p in process.paths:

       pth = getattr(process,p)

       if "l1extraParticles" in pth.moduleNames():

           pth.replace(process.l1extraParticles, process.l1extraParticlesORG*process.l1extraParticles)


   if process.customization_options.embeddingMode.value() == "PF":

     print "Using PF-embedding"

     from TauAnalysis.MCEmbeddingTools.embeddingCustomizePF import customise as customisePF

     customisePF(process, inputProcess)

   elif process.customization_options.embeddingMode.value() == "RH":

     print "Using RH-embedding"

     from TauAnalysis.MCEmbeddingTools.embeddingCustomizeRH import customise as customiseRH

     customiseRH(process, inputProcess)

   else:

     raise ValueError("Invalid Configuration parameter 'embeddingMode' = %s !!" % process.customization_options.embeddingMode.value())


   # it should be the best solution to take the original beam spot for the

   # reconstruction of the new primary vertex

   # use the one produced earlier, do not produce your own

   for s in process.sequences:

      seq = getattr(process,s)

      seq.remove(process.offlineBeamSpot)


   try:

     process.metreco.remove(process.BeamHaloId)

   except:

     pass


   try:

     outputModule = process.output

   except:

     pass

   try:

     outputModule = getattr(process, str(getattr(process, list(process.endpaths)[-1])))

   except:

     pass


   process.filterEmptyEv.src = cms.untracked.InputTag("generator", "", "EmbeddedRECO")


   try:

     process.schedule.remove(process.DQM_FEDIntegrity_v3)

   except:

     pass


   process.load("TauAnalysis/MCEmbeddingTools/ZmumuStandaloneSelection_cff")

   process.goldenZmumuFilter.src = process.customization_options.ZmumuCollection

   if process.customization_options.applyZmumuSkim.value():

     print "Enabling Zmumu skim"

     process.load("TrackingTools/TransientTrack/TransientTrackBuilder_cfi")

     for path in process.paths:

       if process.customization_options.isMC.value():

         getattr(process,path)._seq = process.goldenZmumuFilterSequence * getattr(process,path)._seq

       else:

         getattr(process,path)._seq = process.goldenZmumuFilterSequenceData * getattr(process,path)._seq

     process.options = cms.untracked.PSet(

       wantSummary = cms.untracked.bool(True)

     )

     # CV: keep track of Z->mumu selection efficiency

     process.goldenZmumuFilterResult = cms.EDProducer("CandViewCountEventSelFlagProducer",

       src = process.customization_options.ZmumuCollection,

       minNumber = cms.uint32(1)

     )

     process.goldenZmumuFilterEfficiencyPath = cms.Path(process.goldenZmumuSelectionSequence + process.goldenZmumuFilterResult + process.MEtoEDMConverter)

     process.schedule.append(process.goldenZmumuFilterEfficiencyPath)

   else:

     print "Zmumu skim disabled"


   # CV: keep track of which events pass/fail muon -> muon + photon radiation filters

   #     on generator and reconstruction level, but do not actually reject any events

   if process.customization_options.isMC.value():

     process.load("TauAnalysis/MCEmbeddingTools/genMuonRadiationFilter_cfi")

     process.genMuonRadiationFilter.srcGenParticles = cms.InputTag('genParticles::%s' % process.customization_options.inputProcessSIM.value())

     process.genMuonRadiationFilter.invert = cms.bool(False)

     process.genMuonRadiationFilter.filter = cms.bool(False)

     process.reconstruction_step += process.genMuonRadiationFilter

   # CV: keep track of which events pass/fail muon -> muon + photon radiation filter,

   #     but do not actually reject any events

   process.load("TauAnalysis/MCEmbeddingTools/muonRadiationFilter_cfi")

   process.particleFlowPtrsForMuonRadiationFilter.src = cms.InputTag('particleFlow', '', inputProcess)

   process.muonRadiationFilter.srcSelectedMuons = process.customization_options.ZmumuCollection

   process.muonRadiationFilter.invert = cms.bool(False)

   process.muonRadiationFilter.filter = cms.bool(False)

   process.reconstruction_step += process.muonRadiationFilterSequence


   # CV: disable ECAL/HCAL noise simulation

   if process.customization_options.disableCaloNoise.value():

     print "Disabling ECAL/HCAL noise simulation"

     process.simEcalUnsuppressedDigis.doNoise = cms.bool(False)

     process.simEcalUnsuppressedDigis.doESNoise = cms.bool(False)

     process.simHcalUnsuppressedDigis.doNoise = cms.bool(False)

     process.simHcalUnsuppressedDigis.doThermalNoise = cms.bool(False)

   else:

     print "Keeping ECAL/HCAL noise simulation enabled"


   # AB: The following producers are currently commented out. These mostly produce correction

   # factors from input .root files. Such binary files are not desirable to have in a CMSSW

   # release, so they are not included at the moment. A possible solution is to store and look

   # up the correction factors via the Frontier DB.

   """

   # CV: apply/do not apply muon momentum corrections determined by Rochester group

   if process.customization_options.replaceGenOrRecMuonMomenta.value() == "rec" and hasattr(process, "goldenZmumuSelectionSequence"):

     if process.customization_options.applyRochesterMuonCorr.value():

       print "Enabling Rochester muon momentum corrections"

       process.patMuonsForZmumuSelectionRochesterMomentumCorr = cms.EDProducer("RochesterCorrPATMuonProducer",

         src = cms.InputTag('patMuonsForZmumuSelection'),

         isMC = cms.bool(process.customization_options.isMC.value())

       )

       process.goldenZmumuSelectionSequence.replace(process.patMuonsForZmumuSelection, process.patMuonsForZmumuSelection*process.patMuonsForZmumuSelectionRochesterMomentumCorr)

       process.goodMuons.src = cms.InputTag('patMuonsForZmumuSelectionRochesterMomentumCorr')

   else:

     print "Rochester muon momentum corrections disabled"


   if process.customization_options.applyMuonRadiationCorrection.value() != "":

     print "Muon -> muon + photon radiation correction enabled"

     process.load("TauAnalysis/MCEmbeddingTools/muonRadiationCorrWeightProducer_cfi")

     if process.customization_options.applyMuonRadiationCorrection.value() == "photos":

       process.muonRadiationCorrWeightProducer.lutDirectoryRef = cms.string('genMuonRadCorrAnalyzerPHOTOS')

       process.muonRadiationCorrWeightProducer.lutDirectoryOthers = cms.PSet(

         Summer12mcMadgraph = cms.string('genMuonRadCorrAnalyzer')

       )

     elif process.customization_options.applyMuonRadiationCorrection.value() == "pythia":

       process.muonRadiationCorrWeightProducer.lutDirectoryRef = cms.string('genMuonRadCorrAnalyzerPYTHIA')

       process.muonRadiationCorrWeightProducer.lutDirectoryOthers = cms.PSet(

         Summer12mcMadgraph = cms.string('genMuonRadCorrAnalyzer')

       )

     else:

       raise ValueError("Invalid Configuration parameter 'applyMuonRadiationCorrection' = %s !!" % process.customization_options.applyMuonRadiationCorrection.value())

     process.reconstruction_step += process.muonRadiationCorrWeightProducer

     outputModule.outputCommands.extend([

       'keep *_muonRadiationCorrWeightProducer_*_*',

       'keep *_generator_muonsBeforeRad_*',

       'keep *_generator_muonsAfterRad_*'

     ])

   else:

     print "Muon -> muon + photon radiation correction disabled"


   # CV: compute reweighting factors to compensate for smearing of di-muon Pt and mass distributions caused by:

   #    o (mis)reconstruction of muon momenta

   #    o muon -> muon + photon radiation corrections

   #

   #     mdtau values are defined in http:marpix1.in2p3.fr/Physics/biblio_top/mc_toprex_405.ps.gz

   #

   embeddingKineReweightTable = {

     (115, 'elec1_9to30had1_15'): ('TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_ePt9to30tauPtGt18_genEmbedded.root', 'TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_ePt9to30tauPtGt18_recEmbedded.root'),

     (115, 'elec1_20had1_18'): ('TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_ePtGt20tauPtGt18_genEmbedded.root', 'TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_ePtGt20tauPtGt18_recEmbedded.root'),

     (116, 'mu1_7to25had1_15'): ('TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_muPt7to25tauPtGt18_genEmbedded.root', 'TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_muPt7to25tauPtGt18_recEmbedded.root'),

     (116, 'mu1_16had1_18'): ('TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_muPtGt16tauPtGt18_genEmbedded.root', 'TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_muPtGt16tauPtGt18_recEmbedded.root'),

     (121, 'elec1_17elec2_8'): ('TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_emu_genEmbedding.root', 'TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_emu_recEmbedding.root'),

     (122, 'mu1_18mu2_8'): ('TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_emu_genEmbedding.root', 'TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_emu_recEmbedding.root'),

     (123, 'tau1_18tau2_8'): ('TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_emu_genEmbedding.root', 'TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_emu_recEmbedding.root'),

     (132, 'had1_30had2_30'): ('TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_tautau_genEmbedding.root', 'TauAnalysis/MCEmbeddingTools/data/embeddingKineReweight_tautau_recEmbedding.root')

   }


   key = (process.customization_options.mdtau.value(), process.customization_options.minVisibleTransverseMomentum.value())

   if key in embeddingKineReweightTable:

     process.load("TauAnalysis/MCEmbeddingTools/embeddingKineReweight_cff")


     genEmbeddingReweightFile, recEmbeddingReweightFile = embeddingKineReweightTable[key]

     process.embeddingKineReweightGENembedding.inputFileName = cms.FileInPath(genEmbeddingReweightFile)

     process.embeddingKineReweightRECembedding.inputFileName = cms.FileInPath(recEmbeddingReweightFile)


     process.reconstruction_step += process.embeddingKineReweightSequence

     outputModule.outputCommands.extend([

       'keep *_embeddingKineReweight*_*_*'

     ])

   else:

     print 'Do not produce embeddingKineWeights for mdtau=%d, minVisibleTransverseMomuntem=%s !!' % (key[0], key[1])


   # CV: compute weights for correcting Embedded samples

   #     for efficiency with which Zmumu events used as input for Embedding production were selected

   process.load("TauAnalysis/MCEmbeddingTools/ZmumuEvtSelEffCorrWeightProducer_cfi")

   process.ZmumuEvtSelEffCorrWeightProducer.selectedMuons = process.customization_options.ZmumuCollection

   process.ZmumuEvtSelEffCorrWeightProducer.verbosity = cms.int32(0)

   process.reconstruction_step += process.ZmumuEvtSelEffCorrWeightProducer

   outputModule.outputCommands.extend([

     'keep *_ZmumuEvtSelEffCorrWeightProducer_*_*'

   ])

   """


   # TauSpinner

 #  process.RandomNumberGeneratorService.TauSpinnerReco = cms.PSet(

 #    initialSeed = cms.untracked.uint32(123456789),

 #    engineName = cms.untracked.string('HepJamesRandom')

 #  )


 #  process.load('GeneratorInterface.ExternalDecays.TauSpinner_cfi')

 #  #process.TauSpinnerReco.isTauolaConfigured = cms.bool(True)

 #  process.reconstruction_step += process.TauSpinnerReco

 #  outputModule.outputCommands.extend([

 #    'keep *_TauSpinnerReco_*_*'

 #  ])


   return(process)

Config

mathSSE::return
return((rh^lh)&mask)

default_cfi

LumiList.LumiList
Definition: LumiList.py:18

embeddingCustomizeAll.customise
def customise
Definition: embeddingCustomizeAll.py:9

setDefaults
Definition: setDefaults.py:1

split
double split
Definition: MVATrainer.cc:139

rerunParticleFlow
Definition: rerunParticleFlow.py:1

list
How EventSelector::AcceptEvent() decides whether to accept an event for output otherwise it is excluding the probing of A single or multiple positive and the trigger will pass if any such matching triggers are PASS or EXCEPTION[A criterion thatmatches no triggers at all is detected and causes a throw.] A single negative with an expectation of appropriate bit checking in the decision and the trigger will pass if any such matching triggers are FAIL or EXCEPTION A wildcarded negative criterion that matches more than one trigger in the trigger list("!*","!HLTx*"if it matches 2 triggers or more) will accept the event if all the matching triggers are FAIL.It will reject the event if any of the triggers are PASS or EXCEPTION(this matches the behavior of"!*"before the partial wildcard feature was incorporated).Triggers which are in the READY state are completely ignored.(READY should never be returned since the trigger paths have been run