Exemple #1
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def switchToData(process):
    #remove MC matching from standard PAT sequences
    #from AnalysisSpace.TreeMaker.SwitchToData import switchToData
    # remove MC matching

    coreTools.runOnData(process, outputInProcess=False)
    #coreTools.removeMCMatching(process, ["All"], outputInProcess = False)
    coreTools.removeMCMatching(process, ['METs'], "TC", outputInProcess=False)
    coreTools.removeMCMatching(process, ['METs'], "PF", outputInProcess=False)
    coreTools.removeMCMatching(process, ['METs'],
                               "AK5Calo",
                               outputInProcess=False)

    process.patDefaultSequence.remove(process.patJetPartonMatch)
    process.patDefaultSequence.remove(process.patJetPartonMatchAK5PF)
    process.patDefaultSequence.remove(process.patJetPartonMatchAK5Calo)
    process.patDefaultSequence.remove(process.patJetGenJetMatchAK5PF)
    process.patDefaultSequence.remove(process.patJetGenJetMatchAK5Calo)
    process.patDefaultSequence.remove(process.patJetFlavourId)
    process.patDefaultSequence.remove(process.patJetPartons)
    process.patDefaultSequence.remove(process.patJetPartonAssociation)
    process.patDefaultSequence.remove(process.patJetPartonAssociationAK5PF)
    process.patDefaultSequence.remove(process.patJetPartonAssociationAK5Calo)
    process.patDefaultSequence.remove(process.patJetFlavourAssociation)
    process.patDefaultSequence.remove(process.patJetFlavourAssociationAK5PF)
    process.patDefaultSequence.remove(process.patJetFlavourAssociationAK5Calo)
Exemple #2
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def miniAOD_customizeData(process):
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData(process, outputModules=[])
    process.load("RecoCTPPS.TotemRPLocal.ctppsLocalTrackLiteProducer_cff")
    process.load("RecoCTPPS.ProtonReconstruction.ctppsProtons_cff")
    task = getPatAlgosToolsTask(process)
    task.add(process.ctppsLocalTrackLiteProducer)
    task.add(process.ctppsProtons)
Exemple #3
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def miniAOD_customizeData(process):
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData( process, outputModules = [] )
    process.load("RecoCTPPS.TotemRPLocal.ctppsLocalTrackLiteProducer_cff")
    process.load("RecoCTPPS.ProtonReconstruction.ctppsProtons_cff")
    process.load("Geometry.VeryForwardGeometry.geometryRPFromDB_cfi")
    task = getPatAlgosToolsTask(process)
    from Configuration.Eras.Modifier_ctpps_2016_cff import ctpps_2016
    ctpps_2016.toModify(task, func=lambda t: t.add(process.ctppsLocalTrackLiteProducer))
    ctpps_2016.toModify(task, func=lambda t: t.add(process.ctppsProtons))
Exemple #4
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def miniAOD_customizeData(process):
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData( process, outputModules = [] )
    process.load("RecoCTPPS.TotemRPLocal.ctppsLocalTrackLiteProducer_cff")
    process.load("RecoCTPPS.ProtonReconstruction.ctppsProtons_cff")
    process.load("Geometry.VeryForwardGeometry.geometryRPFromDB_cfi")
    task = getPatAlgosToolsTask(process)
    from Configuration.Eras.Modifier_ctpps_2016_cff import ctpps_2016
    ctpps_2016.toModify(task, func=lambda t: t.add(process.ctppsLocalTrackLiteProducer))
    ctpps_2016.toModify(task, func=lambda t: t.add(process.ctppsProtons))
Exemple #5
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def miniAOD_customizeData(process):
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData( process, outputModules = [] )
    process.load("RecoPPS.Local.ctppsLocalTrackLiteProducer_cff")
    process.load("RecoPPS.ProtonReconstruction.ctppsProtons_cff")
    process.load("Geometry.VeryForwardGeometry.geometryRPFromDB_cfi")
    process.load('L1Trigger.L1TGlobal.simGtExtFakeProd_cfi')
    task = getPatAlgosToolsTask(process)
    from Configuration.Eras.Modifier_ctpps_cff import ctpps
    ctpps.toModify(task, func=lambda t: t.add(process.ctppsLocalTrackLiteProducer))
    ctpps.toModify(task, func=lambda t: t.add(process.ctppsProtons))
    from Configuration.ProcessModifiers.run2_miniAOD_UL_cff import run2_miniAOD_UL
    run2_miniAOD_UL.toModify(task, func=lambda t: t.add(process.simGtExtUnprefireable))
Exemple #6
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def removeMCUse(process):
    # Remove anything that requires MC truth.
    # from PhysicsTools.PatAlgos.tools.coreTools import removeMCMatching
    # removeMCMatching(process, ['All'])

    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData(process)

    # I have no idea why all gen processes also have to be removed by hand...
    process.patDefaultSequence.remove(process.electronMatch)
    process.patDefaultSequence.remove(process.muonMatch)
    process.patDefaultSequence.remove(process.tauMatch)
    process.patDefaultSequence.remove(process.tauGenJets)
    process.patDefaultSequence.remove(process.tauGenJetsSelectorAllHadrons)
    process.patDefaultSequence.remove(process.tauGenJetMatch)
    process.patDefaultSequence.remove(process.photonMatch)
    process.patDefaultSequence.remove(process.patJetPartonMatch)
    process.patDefaultSequence.remove(process.patJetGenJetMatch)
    process.patDefaultSequence.remove(process.patJetPartonsLegacy)
    process.patDefaultSequence.remove(process.patJetPartonAssociationLegacy)
    process.patDefaultSequence.remove(process.patJetFlavourAssociationLegacy)
    process.patDefaultSequence.remove(process.patJetPartons)
    process.patDefaultSequence.remove(process.patJetFlavourAssociation)
Exemple #7
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def switchToData(process):
  #remove MC matching from standard PAT sequences
  #from AnalysisSpace.TreeMaker.SwitchToData import switchToData
  # remove MC matching

  coreTools.runOnData(process, outputModules = [])
  #coreTools.removeMCMatching(process, ["All"], outputModules = [])
  coreTools.removeMCMatching(process, ['METs'], "TC", outputModules = [])
  coreTools.removeMCMatching(process, ['METs'], "PF", outputModules = [])
  coreTools.removeMCMatching(process, ['METs'], "AK5Calo", outputModules = [])

  process.patDefaultSequence.remove(process.patJetPartonMatch)
  process.patDefaultSequence.remove(process.patJetPartonMatchAK5PF)
  process.patDefaultSequence.remove(process.patJetPartonMatchAK5Calo)
  process.patDefaultSequence.remove(process.patJetGenJetMatchAK5PF)
  process.patDefaultSequence.remove(process.patJetGenJetMatchAK5Calo)
  process.patDefaultSequence.remove(process.patJetFlavourId)
  process.patDefaultSequence.remove(process.patJetPartons)
  process.patDefaultSequence.remove(process.patJetPartonAssociation)
  process.patDefaultSequence.remove(process.patJetPartonAssociationAK5PF)
  process.patDefaultSequence.remove(process.patJetPartonAssociationAK5Calo)
  process.patDefaultSequence.remove(process.patJetFlavourAssociation)
  process.patDefaultSequence.remove(process.patJetFlavourAssociationAK5PF)
  process.patDefaultSequence.remove(process.patJetFlavourAssociationAK5Calo)
pfTools.applyPostfix( process, 'pfIsolatedMuons'      , postfix ).isolationCut = patRefSel_refMuJets.pfMuonCombIsoCut
pfTools.applyPostfix( process, 'pfElectronsFromVertex'    , postfix ).vertices = cms.InputTag( patRefSel_refMuJets.pfVertices )
pfTools.applyPostfix( process, 'pfElectronsFromVertex'    , postfix ).d0Cut    = patRefSel_refMuJets.pfD0Cut
pfTools.applyPostfix( process, 'pfElectronsFromVertex'    , postfix ).dzCut    = patRefSel_refMuJets.pfDzCut
pfTools.applyPostfix( process, 'pfSelectedElectrons'      , postfix ).cut = patRefSel_refMuJets.pfElectronSelectionCut
pfTools.applyPostfix( process, 'pfIsolatedElectrons'      , postfix ).isolationCut = patRefSel_refMuJets.pfElectronCombIsoCut
pfTools.applyPostfix( process, 'patElectrons', postfix ).pvSrc = cms.InputTag( patRefSel_refMuJets.pfVertices )
pfTools.applyPostfix( process, 'patMuons'    , postfix ).pvSrc = cms.InputTag( patRefSel_refMuJets.pfVertices )

import TopQuarkAnalysis.Configuration.patRefSel_refMuJets_cfi as patRefSel_refMuJets_cfi

# remove MC matching, object cleaning, objects etc.
## remove MCMatching if run on Data
if options.runOnData:
  from PhysicsTools.PatAlgos.tools.coreTools import runOnData
  runOnData(process, names = [ 'PFAll' ],postfix =postfix)
  print "removeMatching"
if not runOnMC:
  runOnData( process
           , names = [ 'PFAll' ]
           , postfix = postfix
           )
PhysPatAlgCoreTools.removeSpecificPATObjects( process
                        , names = [ 'Photons', 'Taus' ]
                        , postfix = postfix
                        ) # includes 'removeCleaning'
# additional event content has to be (re-)added _after_ the call to 'removeCleaning()':
process.out.outputCommands += [ 'keep edmTriggerResults_*_*_*'
                              , 'keep *_hltTriggerSummaryAOD_*_*'
                              # vertices and beam spot
                              , 'keep *_offlineBeamSpot_*_*'
def addPlainPat(process, dataVersion, doPatTrigger=True, doPatTaus=True, doHChTauDiscriminators=True, doPatMET=True, doPatElectronID=True,
                doPatCalo=True, doBTagging=True, doPatMuonPFIsolation=False, doPatTauIsoDeposits=False,
                doTauHLTMatching=True, matchingTauTrigger=None, matchingJetTrigger=None,
                includePFCands=False):
    out = None
    outdict = process.outputModules_()
    if outdict.has_key("out"):
        out = outdict["out"]

    outputCommands = []

    # Tau Discriminators
    process.hplusPatTauSequence = cms.Sequence()
    if doPatTaus:
        process.hplusPatTauSequence = addPFTausAndDiscriminators(process, dataVersion, doPatCalo, doHChTauDiscriminators)

    # PAT Layer 0+1
    process.load("PhysicsTools.PatAlgos.patSequences_cff")

    sequence = cms.Sequence(
        process.hplusPatTauSequence
    )

    # Restrict input to AOD
    restrictInputToAOD(process, ["All"])

    # Remove MC stuff if we have collision data (has to be done any add*Collection!)
    # This also adds the L2L3Residual JEC correction to the process.patJetCorrFactors
    if dataVersion.isData():
        runOnData(process, outputInProcess = out!=None)

    # Jets
    # Produce kt6 rho for L1Fastjet
    process.load('RecoJets.Configuration.RecoPFJets_cff')
    process.kt6PFJets.doRhoFastjet = True
    process.ak5PFJets.doAreaFastjet = True
    process.ak5PFJetSequence = cms.Sequence(process.kt6PFJets * process.ak5PFJets)
   
    # Set defaults
    process.patJets.jetSource = cms.InputTag("ak5CaloJets")
    process.patJets.trackAssociationSource = cms.InputTag("ak5JetTracksAssociatorAtVertex")
    setPatJetDefaults(process.patJets)
    setPatJetCorrDefaults(process.patJetCorrFactors, dataVersion)
    process.patDefaultSequence.replace(process.patJetCorrFactors,
                                       process.ak5PFJetSequence*process.patJetCorrFactors)
    process.selectedPatJets.cut = jetPreSelection

    # The default JEC to be embedded to pat::Jets are L2Relative,
    # L3Absolute, L5Flavor and L7Parton. The default JEC to be applied
    # is L2L3Residual, or L3Absolute, or Uncorrected (in this order).

    if doPatCalo:
        # Add JPT jets
        # FIXME: Disabled for now until the JEC for JPT works again (with the latest JEC)
#        addJetCollection(process, cms.InputTag('JetPlusTrackZSPCorJetAntiKt5'),
#                         'AK5', 'JPT',
#                         doJTA        = True,
#                         doBTagging   = doBTagging,
#                         jetCorrLabel = ('AK5JPT', process.patJetCorrFactors.levels),
#                         doType1MET   = False,
#                         doL1Cleaning = False,
#                         doL1Counters = True,
#                         genJetCollection = cms.InputTag("ak5GenJets"),
#                         doJetID      = True
#        )
    
        # Add PF jets
        addJetCollection(process, cms.InputTag('ak5PFJets'),
                         'AK5', 'PF',
                         doJTA        = True,
                         doBTagging   = doBTagging,
                         jetCorrLabel = ('AK5PF', process.patJetCorrFactors.levels),
                         doType1MET   = False,
                         doL1Cleaning = False,
                         doL1Counters = True,
                         genJetCollection = cms.InputTag("ak5GenJets"),
                         doJetID      = True
        )
        setPatJetCorrDefaults(process.patJetCorrFactorsAK5PF, dataVersion, True)

    else:
        setPatJetCorrDefaults(process.patJetCorrFactors, dataVersion, True)
        switchJetCollection(process, cms.InputTag('ak5PFJets'),
                            doJTA        = True,
                            doBTagging   = doBTagging,
                            jetCorrLabel = ('AK5PF', process.patJetCorrFactors.levels),
                            doType1MET   = False,
                            genJetCollection = cms.InputTag("ak5GenJets"),
                            doJetID      = True
        )
    
    outputCommands.extend([
            "keep *_selectedPatJets_*_*",
            "keep *_selectedPatJetsAK5JPT_*_*",
            "keep *_selectedPatJetsAK5PF_*_*",
            'drop *_selectedPatJets_pfCandidates_*', ## drop for default patJets which are CaloJets
            'drop *_*PF_caloTowers_*',
            'drop *_*JPT_pfCandidates_*',
            'drop *_*Calo_pfCandidates_*',
            ])

    # Taus

    # Set default PATTauProducer options here, they should be
    # replicated to all added tau collections (and the first call to
    # addTauCollection should replace the default producer modified
    # here)
    setPatTauDefaults(process.patTaus, includePFCands)
    process.selectedPatTaus.cut = tauPreSelection

    if doPatTaus:
        if doHChTauDiscriminators:
            addHChTauDiscriminators()

        # Don't enable TCTau nor shrinking cone tau
        # if doPatCalo:
        #     tauTools.addTauCollection(process,cms.InputTag('caloRecoTauProducer'),
        #                      algoLabel = "caloReco",
        #                      typeLabel = "Tau")
        #     setPatTauDefaults(process.patTausCaloRecoTau, True)
        #     process.patTausCaloRecoTau.embedLeadTrack = not includePFCands
        #     process.patTausCaloRecoTau.embedLeadPFChargedHadrCand = False
    
        # tauTools.addTauCollection(process,cms.InputTag('shrinkingConePFTauProducer'),
        #                  algoLabel = "shrinkingCone",
        #                  typeLabel = "PFTau")
        # # Disable isoDeposits like this until the problem with doPFIsoDeposits is fixed 
        # if not doPatTauIsoDeposits:
        #     process.patTausShrinkingConePFTau.isoDeposits = cms.PSet()

        tauTools.addTauCollection(process,cms.InputTag('hpsPFTauProducer'),
                         algoLabel = "hps",
                         typeLabel = "PFTau")
        if not doPatTauIsoDeposits:
            process.patTausHpsPFTau.isoDeposits = cms.PSet()
        addPatTauIsolationEmbedding(process, process.patDefaultSequence, "HpsPFTau")

        tauTools.addTauCollection(process,cms.InputTag('hpsTancTaus'),
                                  algoLabel = "hpsTanc",
                                  typeLabel = "PFTau")
        if not doPatTauIsoDeposits:
            process.patTausHpsTancPFTau.isoDeposits = cms.PSet()
        # Disable discriminators which are not in AOD
#        del process.patTausHpsTancPFTau.tauIDSources.againstCaloMuon
#        del process.patTausHpsTancPFTau.tauIDSources.byHPSvloose
        addPatTauIsolationEmbedding(process, process.patDefaultSequence, "HpsTancPFTau")

        # Add visible taus    
        if dataVersion.isMC():
            process.VisibleTaus = cms.EDProducer("HLTTauMCProducer",
                GenParticles  = cms.untracked.InputTag("genParticles"),
                ptMinTau      = cms.untracked.double(3),
                ptMinMuon     = cms.untracked.double(3),
                ptMinElectron = cms.untracked.double(3),
                BosonID       = cms.untracked.vint32(23),
                EtaMax         = cms.untracked.double(2.5)
            )
            sequence *= process.VisibleTaus
            outputCommands.append("keep *_VisibleTaus_*_*")

    else:
        # FIXME: this is broken at the moment
        #removeSpecificPATObjects(process, ["Taus"], outputInProcess= out != None)
        process.patDefaultSequence.remove(process.patTaus)
        process.patDefaultSequence.remove(process.selectedPatTaus)

    outputCommands.extend(["drop *_selectedPatTaus_*_*",
#                           "keep *_selectedPatTausCaloRecoTau_*_*",
#                           "keep *_selectedPatTausShrinkingConePFTau_*_*",
                           "keep *_selectedPatTausHpsPFTau_*_*",
                           "keep *_selectedPatTausHpsTancPFTau_*_*",
                           #"keep *_cleanPatTaus_*_*",
                           #"drop *_cleanPatTaus_*_*",
                           #"keep *_patTaus*_*_*",
                           #"keep *_patPFTauProducerFixedCone_*_*",
                           # keep these until the embedding problem with pat::Tau is fixed
                           #"keep recoPFCandidates_particleFlow_*_*",
                           #"keep recoTracks_generalTracks_*_*"
                           ])

    # MET
    addPfMET(process, 'PF')
    if doPatCalo:
        addTcMET(process, 'TC')
    else:
        # FIXME: This is broken at the moment...
        #removeSpecificPATObjects(process, ["METs"], outputInProcess= out != None)
        #process.patDefaultSequen
        process.patDefaultSequence.remove(process.patMETCorrections)
        process.patDefaultSequence.remove(process.patMETs)
        del process.patMETCorrections
        del process.patMETs

    outputCommands.extend([
            "keep *_patMETs_*_*",
            "keep *_patMETsTC_*_*",
            "keep *_patMETsPF_*_*",
            "keep *_genMetTrue_*_*",
            ])

    # Muons
    setPatLeptonDefaults(process.patMuons, includePFCands)
    if doPatMuonPFIsolation:
        addPFMuonIsolation(process, process.patMuons, sequence, verbose=True)

    outputCommands.extend([
            "keep *_selectedPatMuons_*_*"
            ])

    # Electrons
    # In order to calculate the transverse impact parameter w.r.t.
    # beam spot instead of primary vertex, see
    setPatLeptonDefaults(process.patMuons, includePFCands)

    # Electron ID, see
    # https://twiki.cern.ch/twiki/bin/view/CMS/SimpleCutBasedEleID
    if doPatElectronID:
        addPatElectronID(process, process.patElectrons, process.patDefaultSequence)

    outputCommands.extend([
            "keep *_selectedPatElectrons_*_*"
            ])

    # Photons
#    process.patPhotons.embedGenMatch = False
    outputCommands.extend([
            "keep *_selectedPatPhotons_*_*"
            ])

    # Trigger
    if doPatTrigger:
        outMod= ''
        if out != None:
            outMod  = 'out'
        switchOnTrigger(process, hltProcess=dataVersion.getTriggerProcess(), outputModule=outMod)
        process.patTrigger.addL1Algos = cms.bool(True)
        process.patTrigger.l1ExtraMu = cms.InputTag("l1extraParticles")
        process.patTrigger.l1ExtraCenJet = cms.InputTag("l1extraParticles", "Central")
        process.patTrigger.l1ExtraTauJet = cms.InputTag("l1extraParticles", "Tau")
        process.patTrigger.l1ExtraForJet = cms.InputTag("l1extraParticles", "Forward")
        process.patTrigger.l1ExtraETM = cms.InputTag("l1extraParticles", "MET")
        process.patTrigger.l1ExtraHTM = cms.InputTag("l1extraParticles", "MHT")


        # Keep StandAlone trigger objects for enabling trigger
        # matching in the analysis phase with PAT tools
        outputCommands.extend(patTriggerStandAloneEventContent)


    # Remove cleaning step and set the event content
    if out == None:
        myRemoveCleaning(process)
    else:
        backup = out.outputCommands[:]
        myRemoveCleaning(process)
#        backup_pat = out.outputCommands[:]

        # Remove PFParticles here, they are explicitly included when needed
#        backup_pat = filter(lambda n: "selectedPatPFParticles" not in n, backup_pat)

        out.outputCommands = backup
#        out.outputCommands.extend(backup_pat)
        out.outputCommands.extend(outputCommands)

    # Build sequence
    sequence *= process.patDefaultSequence

    # Tau+HLT matching
    if doTauHLTMatching:
        sequence *= HChTriggerMatching.addTauHLTMatching(process, matchingTauTrigger, matchingJetTrigger)

    return sequence
process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")

process.source = cms.Source(
    "PoolSource",
    fileNames = cms.untracked.vstring(
        'file:/scratch/efriis/results/infn_mmt_events.root'
    ),
    eventsToProcess = cms.untracked.VEventRange('175990:120477532')
)

process.GlobalTag.globaltag = cms.string('GR_R_42_V21::All')

import PhysicsTools.PatAlgos.tools.tauTools as tautools
import PhysicsTools.PatAlgos.tools.coreTools as coreTools
tautools.switchToPFTauHPS(process)
coreTools.runOnData(process)
process.patJetCorrFactors.useRho = False

process.selectOurWeirdTau = cms.EDFilter(
    "PATTauSelector",
    src = cms.InputTag("patTaus"),
    cut = cms.string('eta <  -0.1 & eta > -0.12 & pt > 36 & pt < 38'),
    filter = cms.bool(True)
)

process.ourTauPassesDecayMode = cms.EDFilter(
    "PATTauSelector",
    src = cms.InputTag("selectOurWeirdTau"),
    cut = cms.string('tauID("decayModeFinding")'),
    filter = cms.bool(True)
)
Exemple #11
0
process.maxEvents = cms.untracked.PSet(
  input = cms.untracked.int32( 100 )
)

## Output
from PhysicsTools.PatAlgos.patEventContent_cff import patEventContentNoCleaning
process.out = cms.OutputModule(
  "PoolOutputModule"
, fileName = cms.untracked.string( 'patTuple_data.root' )
, outputCommands = cms.untracked.vstring(
    *patEventContentNoCleaning
  )
)
process.out.outputCommands += [ 'drop recoGenJets_*_*_*' ]
process.outpath = cms.EndPath(
  process.out, patAlgosToolsTask
)

## Processing
process.load( "PhysicsTools.PatAlgos.producersLayer1.patCandidates_cff" )
patAlgosToolsTask.add(process.patCandidatesTask)
#Temporary customize to the unit tests that fail due to old input samples
process.patTaus.skipMissingTauID = True

process.load( "PhysicsTools.PatAlgos.selectionLayer1.selectedPatCandidates_cff" )
patAlgosToolsTask.add(process.selectedPatCandidatesTask)

# for data:
from PhysicsTools.PatAlgos.tools.coreTools import runOnData
runOnData( process )
Exemple #12
0
def addInvHiggsProcess(
        process,
        iRunOnData=True,
        iData="ParkedData",
        iHLTFilter="MET",
        iMCSignal=False,
        iFile='/store/data/Run2012C/VBF1Parked/AOD/22Jan2013-v1/20000/40F56410-D979-E211-9843-002618943849.root',
        iMaxEvent=100):

    ###--------------------------------------------------------------
    ### Load PAT, because it insists on defining the process for you
    #from PhysicsTools.PatAlgos.patTemplate_cfg import *
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Input
    process.maxEvents.input = iMaxEvent
    process.source.fileNames = [iFile]
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### GlobalTag
    if iRunOnData == True:
        process.GlobalTag.globaltag = "FT53_V21A_AN6::All"
    else:
        process.GlobalTag.globaltag = "START53_V27::All"
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Logger
    process.load("FWCore.MessageService.MessageLogger_cfi")
    process.load("FWCore.MessageLogger.MessageLogger_cfi")
    process.MessageLogger.cerr.FwkReport = cms.untracked.PSet(
        reportEvery=cms.untracked.int32(2000),
        limit=cms.untracked.int32(10000000))
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### L1 Trigger
    process.load('L1Trigger.Skimmer.l1Filter_cfi')
    process.l1Filter.algorithms = cms.vstring('L1_ETM40')
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### HLT Trigger(s)
    # If it's MC signal, no trigger will be applied
    if iRunOnData == False and iMCSignal == True:
        iHLTFilter = "NoTrig"

    # Load hltHighLevel
    process.load('HLTrigger.HLTfilters.hltHighLevel_cfi')
    process.hltHighLevel.TriggerResultsTag = cms.InputTag(
        "TriggerResults", "", "HLT")
    process.hltHighLevel.throw = cms.bool(
        False)  # Tolerate if triggers not available
    process.hltHighLevel.andOr = cms.bool(True)  # True = OR, False = AND
    if (iRunOnData == True and iHLTFilter.find("MET") == 0):
        process.hltHighLevel.HLTPaths = cms.vstring(
            #"HLT_DiPFJet40_PFMETnoMu65_MJJ600VBF_LeadingJets_v*",
            #"HLT_DiPFJet40_PFMETnoMu65_MJJ800VBF_AllJets_v*"
            "HLT_DiJet35_MJJ700_AllJets_DEta3p5_VBF_v*",
            "HLT_DiJet30_MJJ700_AllJets_DEta3p5_VBF_v*")
    elif (iHLTFilter.find("SingleMu") == 0):
        process.hltHighLevel.HLTPaths = cms.vstring("HLT_IsoMu24_eta2p1_v*",
                                                    "HLT_Mu40_eta2p1_v*")
    #elif (iHLTFilter.find("DoubleMu")==0):
    #    process.hltHighLevel.HLTPaths = cms.vstring("HLT_Mu17_Mu8_v*")
    #elif (iHLTFilter.find("SingleElectron")==0):
    #    process.hltHighLevel.HLTPaths = cms.vstring("HLT_Ele27_WP80_v*")
    #elif (iHLTFilter.find("DoubleElectron")==0):
    #    process.hltHighLevel.HLTPaths = cms.vstring("HLT_Ele17_CaloIdT_CaloIsoVL_TrkIdVL_TrkIsoVL_Ele8_CaloIdT_CaloIsoVL_TrkIdVL_TrkIsoVL_v*")
    elif (iHLTFilter.find("NoTrig") == 0):
        process.hltHighLevel.HLTPaths = cms.vstring("*")
    else:
        process.hltHighLevel.HLTPaths = cms.vstring(
            #"HLT_DiPFJet40_PFMETnoMu65_MJJ600VBF_LeadingJets_v*",
            #"HLT_DiPFJet40_PFMETnoMu65_MJJ800VBF_AllJets_v*"
            "HLT_DiJet35_MJJ700_AllJets_DEta3p5_VBF_v*",
            "HLT_DiJet30_MJJ700_AllJets_DEta3p5_VBF_v*")

    ### VBF filter for MC Background
    process.vbfFilter = cms.EDFilter("HLTPFJetVBFFilter",
                                     saveTags=cms.bool(True),
                                     triggerType=cms.int32(85),
                                     inputTag=cms.InputTag("ak5PFJets"),
                                     leadingJetOnly=cms.bool(False),
                                     minPtHigh=cms.double(25.0),
                                     minPtLow=cms.double(25.0),
                                     maxEta=cms.double(5.0),
                                     etaOpposite=cms.bool(True),
                                     minDeltaEta=cms.double(3.0),
                                     minInvMass=cms.double(500.0))

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

    ###--------------------------------------------------------------
    print "-----------------------------------------------"
    print "INVISIBLE HIGGS: Ntuple V12 for Parked Data"
    print "-----------------------------------------------"
    print "RunOnData = ", iRunOnData
    if iRunOnData == True:
        print "Dataset = ", iData
    else:
        if iMCSignal == True:
            print "Dataset = MC Signal or DYNoTrig"
        else:
            print "Dataset = MC Background"
    print "GlobalTag = ", process.GlobalTag.globaltag
    print "Trigger = ", process.hltHighLevel.HLTPaths
    print "Sample input file = ", iFile
    print "Max events = ", iMaxEvent
    print "-----------------------------------------------"
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Basic filters
    # Track quality filter
    process.noscraping = cms.EDFilter("FilterOutScraping",
                                      applyfilter=cms.untracked.bool(True),
                                      debugOn=cms.untracked.bool(False),
                                      numtrack=cms.untracked.uint32(10),
                                      thresh=cms.untracked.double(0.25))

    # Require a good vertex
    process.primaryVertexFilter = cms.EDFilter(
        "VertexSelector",
        src=cms.InputTag("offlinePrimaryVertices"),
        cut=cms.string(
            "!isFake && ndof > 4 && abs(z) <= 24 && position.Rho <= 2"),
        filter=cms.bool(True))
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### MET Filters
    # The iso-based HBHE noise filter
    process.load('CommonTools.RecoAlgos.HBHENoiseFilter_cfi')

    # The CSC beam halo tight filter
    process.load('RecoMET.METAnalyzers.CSCHaloFilter_cfi')

    # The HCAL laser filter
    process.load("RecoMET.METFilters.hcalLaserEventFilter_cfi")
    #process.load("EventFilter.HcalRawToDigi.hcallasereventfilter2012_cff")
    #process.hcallasereventfilter2012.eventFileName = cms.string('HCALLaser2012AllDatasets.txt.gz')
    process.load(
        "EventFilter.HcalRawToDigi.hcallaserFilterFromTriggerResult_cff")

    # The ECAL dead cell trigger primitive filter
    process.load('RecoMET.METFilters.EcalDeadCellTriggerPrimitiveFilter_cfi')

    # The EE bad SuperCrystal filter
    process.load('RecoMET.METFilters.eeBadScFilter_cfi')

    # The ECAL laser correction filter
    process.load('RecoMET.METFilters.ecalLaserCorrFilter_cfi')

    # The Good vertices collection needed by the tracking failure filter
    process.goodVertices = cms.EDFilter(
        "VertexSelector",
        filter=cms.bool(False),
        src=cms.InputTag("offlinePrimaryVertices"),
        cut=cms.string(
            "!isFake && ndof > 4 && abs(z) <= 24 && position.rho < 2"))

    # The tracking failure filter
    process.load('RecoMET.METFilters.trackingFailureFilter_cfi')

    # The tracking POG filters
    process.load('RecoMET.METFilters.trackingPOGFilters_cff')
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### customise PAT
    process.load('JetMETCorrections.Configuration.DefaultJEC_cff')

    from PhysicsTools.PatAlgos.tools.coreTools import removeMCMatching, runOnData

    if iRunOnData == True:
        removeMCMatching(process, ['All'])
        runOnData(process)

    # Add the PF MET
    from PhysicsTools.PatAlgos.tools.metTools import addPfMET
    addPfMET(process, 'PF')

    # Switch to PF jets
    from PhysicsTools.PatAlgos.tools.jetTools import switchJetCollection
    if iRunOnData == True:
        switchJetCollection(process,
                            cms.InputTag('ak5PFJets'),
                            doJTA=True,
                            doBTagging=False,
                            jetCorrLabel=('AK5PF', [
                                'L1FastJet', 'L2Relative', 'L3Absolute',
                                'L2L3Residual'
                            ]),
                            doType1MET=True,
                            genJetCollection=cms.InputTag("ak5GenJets"),
                            doJetID=False,
                            jetIdLabel="ak5")
    else:
        switchJetCollection(
            process,
            cms.InputTag('ak5PFJets'),
            doJTA=True,
            doBTagging=False,
            jetCorrLabel=('AK5PF', ['L1FastJet', 'L2Relative', 'L3Absolute']),
            doType1MET=True,
            genJetCollection=cms.InputTag("ak5GenJets"),
            doJetID=False,
            jetIdLabel="ak5")

    from PhysicsTools.PatAlgos.tools.pfTools import usePFIso
    usePFIso(process)

    process.patMuons.isoDeposits = cms.PSet()
    process.patMuons.isolationValues = cms.PSet()
    process.patElectrons.isolationValues = cms.PSet(
        pfChargedHadrons=cms.InputTag("elPFIsoValueCharged03PFIdPFIso"),
        pfChargedAll=cms.InputTag("elPFIsoValueChargedAll03PFIdPFIso"),
        pfPUChargedHadrons=cms.InputTag("elPFIsoValuePU03PFIdPFIso"),
        pfNeutralHadrons=cms.InputTag("elPFIsoValueNeutral03PFIdPFIso"),
        pfPhotons=cms.InputTag("elPFIsoValueGamma03PFIdPFIso"))
    process.patElectrons.isolationValuesNoPFId = cms.PSet(
        pfChargedHadrons=cms.InputTag("elPFIsoValueCharged03NoPFIdPFIso"),
        pfChargedAll=cms.InputTag("elPFIsoValueChargedAll03NoPFIdPFIso"),
        pfPUChargedHadrons=cms.InputTag("elPFIsoValuePU03NoPFIdPFIso"),
        pfNeutralHadrons=cms.InputTag("elPFIsoValueNeutral03NoPFIdPFIso"),
        pfPhotons=cms.InputTag("elPFIsoValueGamma03NoPFIdPFIso"))
    process.patDefaultSequence.replace(
        process.patElectrons, process.eleIsoSequence + process.patElectrons)
    process.cleanPatTaus.preselection = cms.string(
        'tauID("decayModeFinding") > 0.5 & tauID("byLooseCombinedIsolationDeltaBetaCorr") > 0.5'
    )
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Object (pre) selection
    # Jet selection
    process.selectedPatJets.cut = cms.string("pt>10. && abs(eta)<5.")

    # Remove overlaps ???
    # process.cleanPatJets.finalCut = "!hasOverlaps('electrons') && !hasOverlaps('muons')"

    # Apply loose PF jet ID
    from PhysicsTools.SelectorUtils.pfJetIDSelector_cfi import pfJetIDSelector
    process.goodPatJets = cms.EDFilter("PFJetIDSelectionFunctorFilter",
                                       filterParams=pfJetIDSelector.clone(),
                                       src=cms.InputTag("selectedPatJets"),
                                       filter=cms.bool(True))

    process.selectedPatMuons.cut = cms.string(
        "isGlobalMuon && pt>10. && abs(eta)<2.5")

    process.selectedPatElectrons.cut = cms.string("pt>10. && abs(eta)<2.5")
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Load the PU JetID sequence
    if iRunOnData == True:
        process.load("CMGTools.External.pujetidsequence_cff")
        process.puJetMva.jets = cms.InputTag("goodPatJets")
        process.puJetId.jets = cms.InputTag("goodPatJets")
    else:
        process.load("CMGTools.External.pujetidsequence_cff")
        process.puJetMva.jets = cms.InputTag("goodPatJets")
        process.puJetId.jets = cms.InputTag("goodPatJets")
        process.puJetMvaSmeared = process.puJetMva.clone()
        process.puJetIdSmeared = process.puJetId.clone()
        process.puJetMvaResUp = process.puJetMva.clone()
        process.puJetIdResUp = process.puJetId.clone()
        process.puJetMvaResDown = process.puJetMva.clone()
        process.puJetIdResDown = process.puJetId.clone()
        process.puJetMvaEnUp = process.puJetMva.clone()
        process.puJetIdEnUp = process.puJetId.clone()
        process.puJetMvaEnDown = process.puJetMva.clone()
        process.puJetIdEnDown = process.puJetId.clone()

        process.puJetIdSmeared.jets = cms.InputTag("smearedGoodPatJets")
        process.puJetMvaSmeared.jetids = cms.InputTag("puJetIdSmeared")
        process.puJetMvaSmeared.jets = cms.InputTag("smearedGoodPatJets")

        process.puJetIdResUp.jets = cms.InputTag("smearedGoodPatJetsResUp")
        process.puJetMvaResUp.jetids = cms.InputTag("puJetIdResUp")
        process.puJetMvaResUp.jets = cms.InputTag("smearedGoodPatJetsResUp")

        process.puJetIdResDown.jets = cms.InputTag("smearedGoodPatJetsResDown")
        process.puJetMvaResDown.jetids = cms.InputTag("puJetIdResDown")
        process.puJetMvaResDown.jets = cms.InputTag(
            "smearedGoodPatJetsResDown")

        process.puJetIdEnUp.jets = cms.InputTag(
            "shiftedGoodPatJetsEnUpForCorrMEt")
        process.puJetMvaEnUp.jetids = cms.InputTag("puJetIdEnUp")
        process.puJetMvaEnUp.jets = cms.InputTag(
            "shiftedGoodPatJetsEnUpForCorrMEt")

        process.puJetIdEnDown.jets = cms.InputTag(
            "shiftedGoodPatJetsEnDownForCorrMEt")
        process.puJetMvaEnDown.jetids = cms.InputTag("puJetIdEnDown")
        process.puJetMvaEnDown.jets = cms.InputTag(
            "shiftedGoodPatJetsEnDownForCorrMEt")
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### MET
    # Apply type 0 MET corrections based on PFCandidate
    process.load("JetMETCorrections.Type1MET.pfMETCorrectionType0_cfi")
    process.pfType1CorrectedMet.applyType0Corrections = cms.bool(False)
    process.pfType1CorrectedMet.srcType1Corrections = cms.VInputTag(
        cms.InputTag('pfMETcorrType0'), cms.InputTag('pfJetMETcorr', 'type1'))

    # Get loose ID/Iso muons and veto ID electrons
    process.load("InvisibleHiggs.Ntuple.PhysicsObjectCandidates_cff")

    # Get PFMET from runMEtUncertainties
    from PhysicsTools.PatUtils.tools.metUncertaintyTools import runMEtUncertainties
    process.load("JetMETCorrections.Type1MET.pfMETsysShiftCorrections_cfi")

    if iRunOnData == True:
        runMEtUncertainties(
            process,
            electronCollection=cms.InputTag('selectVetoElectrons'),
            photonCollection='',
            muonCollection='selectLooseMuons',
            tauCollection='',
            jetCollection=cms.InputTag('goodPatJets'),
            jetCorrLabel='L2L3Residual',
            doSmearJets=False,
            makeType1corrPFMEt=True,
            makeType1p2corrPFMEt=False,
            makePFMEtByMVA=False,
            makeNoPileUpPFMEt=False,
            doApplyType0corr=True,
            sysShiftCorrParameter=process.
            pfMEtSysShiftCorrParameters_2012runAvsNvtx_data,
            doApplySysShiftCorr=False,
            addToPatDefaultSequence=False,
        )
        process.patPFJetMETtype1p2Corr.jetCorrLabel = cms.string(
            'L2L3Residual')
        process.patPFJetMETtype2Corr.jetCorrLabel = cms.string('L2L3Residual')
    else:
        runMEtUncertainties(
            process,
            electronCollection=cms.InputTag('selectVetoElectrons'),
            photonCollection='',
            muonCollection='selectLooseMuons',
            tauCollection='',
            jetCollection=cms.InputTag('goodPatJets'),
            jetCorrLabel='L3Absolute',
            doSmearJets=True,
            makeType1corrPFMEt=True,
            makeType1p2corrPFMEt=False,
            makePFMEtByMVA=False,
            makeNoPileUpPFMEt=False,
            doApplyType0corr=True,
            sysShiftCorrParameter=process.
            pfMEtSysShiftCorrParameters_2012runAvsNvtx_mc,
            doApplySysShiftCorr=False,
            addToPatDefaultSequence=False,
        )

    # Fix Type0 correction module
    #process.patPFMETtype0Corr.correction.par3 = cms.double(0.909209)
    #process.patPFMETtype0Corr.correction.par2 = cms.double(0.0303531)
    #process.patPFMETtype0Corr.correction.par1 = cms.double(-0.703151)
    #process.patPFMETtype0Corr.correction.par0 = cms.double(0.0)
    # Need this line for CMSSW_5_3_11
    process.producePatPFMETCorrections.replace(
        process.patPFJetMETtype2Corr, process.patPFJetMETtype2Corr +
        process.type0PFMEtCorrectionPFCandToVertexAssociation +
        process.patPFMETtype0Corr)
    #process.producePatPFMETCorrections.replace(process.patPFJetMETtype2Corr,process.patPFJetMETtype2Corr + process.patPFMETtype0Corr)
    ###--------------------------------------------------------------

    # PAT/ntuples one step
    # Z and W candidates
    process.load('InvisibleHiggs/Ntuple/WCandidates_cff')
    process.load('InvisibleHiggs/Ntuple/ZCandidates_cff')
    # Ntuple producer
    process.load('InvisibleHiggs/Ntuple/invHiggsInfo_cfi')
    if iRunOnData == False:
        # Jet/MET uncertainty
        process.invHiggsInfo.jetTag = cms.untracked.InputTag(
            "smearedGoodPatJets")
        process.invHiggsInfo.metTag = cms.untracked.InputTag(
            "patType1CorrectedPFMet")
        process.invHiggsInfo.puJetMvaTag = cms.untracked.InputTag(
            "puJetMvaSmeared", "full53xDiscriminant")
        process.invHiggsInfo.puJetIdTag = cms.untracked.InputTag(
            "puJetMvaSmeared", "full53xId")

        # PU re-weighting
        process.invHiggsInfo.puMCFile = cms.untracked.string("PUHistS10.root")
        process.invHiggsInfo.puDataFile = cms.untracked.string(
            "PUHistRun2012All_forParked.root")
        process.invHiggsInfo.puMCHist = cms.untracked.string("pileup")
        process.invHiggsInfo.puDataHist = cms.untracked.string("pileup")
        process.invHiggsInfo.mcPYTHIA = cms.untracked.bool(True)

        process.invHiggsInfo.trigCorrFile = cms.untracked.string(
            "DataMCWeight_53X_v1.root")
    # TTree output file
    process.load("CommonTools.UtilAlgos.TFileService_cfi")
    process.TFileService.fileName = cms.string('invHiggsInfo.root')
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Tau
    # removeSpecificPATObjects( process, ['Taus'] )
    # process.patDefaultSequence.remove( process.patTaus )
    process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Trigger matching
    # from PhysicsTools.PatAlgos.tools.trigTools import *

    # process.metTriggerMatch = cms.EDProducer(
    #     "PATTriggerMatcherDRLessByR"                    # match by DeltaR only, best match by DeltaR
    #     , src     = cms.InputTag( 'patMETs' )
    #     , matched = cms.InputTag( 'patTrigger' )          # default producer label as defined in PhysicsTools/PatAlgos/python/triggerLayer1/triggerProducer_cfi.py
    #     , matchedCuts = cms.string( 'path( "HLT_MET100_v*" )' )
    #     , maxDPtRel = cms.double( 0.5 )
    #     , maxDeltaR = cms.double( 0.5 )
    #     , resolveAmbiguities    = cms.bool( True )        # only one match per trigger object
    #     , resolveByMatchQuality = cms.bool( True )        # take best match found per reco object: by DeltaR here (s. above)
    # )
    # process.jetTriggerMatch = cms.EDProducer(
    #     "PATTriggerMatcherDRLessByR"                    # match by DeltaR only, best match by DeltaR
    #     , src     = cms.InputTag( 'patJets' )
    #     , matched = cms.InputTag( 'patTrigger' )          # default producer label as defined in PhysicsTools/PatAlgos/python/triggerLayer1/triggerProducer_cfi.py
    #     , matchedCuts = cms.string( 'path( "HLT_Jet30_v*" )' )
    #     , maxDPtRel = cms.double( 0.5 )
    #     , maxDeltaR = cms.double( 0.5 )
    #     , resolveAmbiguities    = cms.bool( True )        # only one match per trigger object
    #     , resolveByMatchQuality = cms.bool( True )        # take best match found per reco object: by DeltaR here (s. above)
    # )

    # switchOnTriggerMatchEmbedding( process, [ 'metTriggerMatch', 'jetTriggerMatch' ] )
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Paths
    process.p0 = cms.Path(process.HBHENoiseFilter)
    process.p1 = cms.Path(process.CSCTightHaloFilter)
    process.p2 = cms.Path(process.hcalLaserEventFilter)
    process.p3 = cms.Path(process.EcalDeadCellTriggerPrimitiveFilter)
    process.p4 = cms.Path(process.eeBadScFilter)
    process.p5 = cms.Path(process.ecalLaserCorrFilter)
    process.p6 = cms.Path(process.goodVertices * process.trackingFailureFilter)
    process.p7 = cms.Path(process.trkPOGFilters)
    if iRunOnData == True:
        #process.p8 = cms.Path( process.hcallLaserEvent2012Filter )
        process.p8 = cms.Path(process.hcalfilter)
    else:
        process.p8 = cms.Path(process.primaryVertexFilter)

    if iRunOnData == True:
        process.p = cms.Path(
            # Trigger filter
            process.l1Filter * process.hltHighLevel *

            # Basic filters
            process.noscraping * process.primaryVertexFilter *

            # MET filters (Move to be flagged)

            # MET Correction
            process.type0PFMEtCorrection *

            # Tau
            process.recoTauClassicHPSSequence *

            # Generate PAT
            process.pfParticleSelectionSequence * process.patDefaultSequence *
            process.goodPatJets * process.PhysicsObjectSequence *
            process.metUncertaintySequence * process.puJetIdSqeuence *
            process.WSequence * process.ZSequence * process.invHiggsInfo)
    elif (iMCSignal == True):
        process.p = cms.Path(
            # Trigger filter
            #process.hltHighLevel *

            # Basic filters
            process.noscraping * process.primaryVertexFilter *

            # MET filters (Move to be flags)

            # MET Correction
            process.type0PFMEtCorrection *

            # Tau
            process.recoTauClassicHPSSequence *

            # Generate PAT
            process.pfParticleSelectionSequence * process.patDefaultSequence *
            process.goodPatJets * process.PhysicsObjectSequence *
            process.metUncertaintySequence * process.puJetIdSqeuence *
            process.puJetIdSmeared * process.puJetMvaSmeared *
            process.puJetIdResUp * process.puJetMvaResUp *
            process.puJetIdResDown * process.puJetMvaResDown *
            process.puJetIdEnUp * process.puJetMvaEnUp *
            process.puJetIdEnDown * process.puJetMvaEnDown *
            process.WSequence * process.ZSequence * process.invHiggsInfo)
    else:
        process.p = cms.Path(
            # Trigger filter
            #process.hltHighLevel *
            process.vbfFilter *

            # Basic filters
            process.noscraping * process.primaryVertexFilter *

            # MET filters (Move to be flags)

            # MET Correction
            process.type0PFMEtCorrection *

            # Tau
            process.recoTauClassicHPSSequence *

            # Generate PAT
            process.pfParticleSelectionSequence * process.patDefaultSequence *
            process.goodPatJets * process.PhysicsObjectSequence *
            process.metUncertaintySequence * process.puJetIdSqeuence *
            process.puJetIdSmeared * process.puJetMvaSmeared *
            process.puJetIdResUp * process.puJetMvaResUp *
            process.puJetIdResDown * process.puJetMvaResDown *
            process.puJetIdEnUp * process.puJetMvaEnUp *
            process.puJetIdEnDown * process.puJetMvaEnDown *
            process.WSequence * process.ZSequence * process.invHiggsInfo)
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Output
    process.out.outputCommands += [
        # trigger results
        'keep edmTriggerResults_*_*_*',
        'keep *_hltTriggerSummaryAOD_*_*'
        # L1
        ,
        'keep *_l1extraParticles_MET_RECO',
        'keep *_l1extraParticles_MHT_RECO'
        # good jets
        ,
        'keep *_goodPatJets_*_*'
        # PU jet ID
        ,
        'keep *_puJetId*_*_*',
        'keep *_puJetMva*_*_*'
        # vertices
        ,
        'keep *_offlineBeamSpot_*_*',
        'keep *_offlinePrimaryVertices*_*_*',
        'keep *_goodOfflinePrimaryVertices*_*_*',
        'keep double_*_rho_*'
    ]

    if iRunOnData == False:
        process.out.outputCommands += [
            'keep GenEventInfoProduct_*_*_*', 'keep recoGenParticles_*_*_*',
            'keep GenMETs_*_*_*', 'keep *_addPileupInfo_*_*',
            'keep LHEEventProduct_*_*_*'
        ]

    process.out.fileName = 'patTuple.root'

    del (process.out)
    del (process.outpath)
Exemple #13
0
def miniAOD_customizeData(process):
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData(process, outputModules=[])
    process.load("RecoCTPPS.TotemRPLocal.ctppsLocalTrackLiteProducer_cfi")
Exemple #14
0
    cms.PSet(type=cms.untracked.string("ObjectVariableCombined"),
             name=cms.string("SaveMuon"),
             cutList=cms.vstring("isMuon","PT5"),
             doAnd=cms.bool(True),
             ),
    cms.PSet(type=cms.untracked.string("ObjectVariableCombined"),
             name=cms.string("SaveElectron"),
             cutList=cms.vstring("isElectron","PT5"),
             doAnd=cms.bool(True),
             ),
    cms.PSet(type=cms.untracked.string("ObjectVariableCombined"),
             name=cms.string("WRITEOBJECT"),
             cutList=cms.vstring("SaveJet","SaveTrack","SaveAllOfType","SaveMuon","SaveElectron","SaveTau"),
             doAnd=cms.bool(False),
             ),
    cms.PSet(type=cms.untracked.string("Signature"),
             name=cms.string("testSignature"),
             cutList=cms.vstring(),
             ),
)
process.load('CommonTools.RecoAlgos.HBHENoiseFilterResultProducer_cfi')

# for data:
from PhysicsTools.PatAlgos.tools.coreTools import runOnData
runOnData( process ,names=['Photons', 'Electrons','Muons', 'Taus', 'METs', 'PFAll', 'PFElectrons','PFTaus','PFMuons'] )
#runOnData( process ,outputModules = [])

process.p = cms.Path(
    process.egmPhotonIDSequence *
    process.displacedAOD)
def configurePatTuple(process, isMC=True, **kwargs):

    # Stuff we always keep
    output_commands = [
#        '*',
        '*_addPileupInfo_*_*',
        'edmMergeableCounter_*_*_*',
        '*_lumiProducer_*_*',
        '*_particleFlow_*_*',
        '*_offlineBeamSpot_*_*',
        '*_generalTracks_*_*',
        '*_electronGsfTracks_*_*',
        '*_offlinePrimaryVertices*_*_*',
        '*_ak5GenJets_*_*',
        '*_hltTriggerSummaryAOD_*_*',
        'edmTriggerResults_TriggerResults_*_%s' % process.name_(),
        '*_MEtoEDMConverter*_*_%s' % process.name_(),
        'LHEEventProduct_*_*_*',
        'GenEventInfoProduct_generator_*_*',
        '*_kt6PFJetsForRhoComputationVoronoi_rho_*',
        '*_kt6PFJetsForIso_rho_*',
        '*_kt6PFJets_rho_*',
        '*_kt6PFJetsCentralHZGPho_rho_*',
        '*_kt6PFJetsCentralHZGEle_rho_*',
        '*_kt6PFJetsCentralHZGMu_rho_*',
        '*_kt6PFJetsCentralNeutralHZGMu_rho_*',
        '*_kt6PFJetsCentral_rho_*',
        '*_kt6PFJetsCentralNeutral_rho_*', #for zz muons
        '*_photonCore_*_*',
        # for Zmumu -> embedded samples
        '*_generator_weight_*', # 2k11
        "GenFilterInfo_generator_minVisPtFilter_*", #2k12
        '*_genDaughters_*_*',
        '*_boosted*_*_*',
        '*_tmfTracks_*_*',
    ]
    # Define our patTuple production sequence
    process.tuplize = cms.Sequence()
    # Only keep interesting genParticles
    process.load("FinalStateAnalysis.RecoTools.genParticleTrimmer_cfi")
    process.genParticles = process.prunedGenParticles.clone()
    if isMC:
        #process.tuplize += process.genParticles
        #output_commands.append('*_genParticles_*_%s' % process.name_())
        output_commands.append('*_genParticles_*_*')

    output_commands.append('*_tauGenJetsSelectorAllHadrons_*_*')
    output_commands.append('*_tauGenJets_*_*')
    output_commands.append('*_ak5GenJets_*_*')
    # Select vertices
    process.load("FinalStateAnalysis.RecoTools.vertexSelection_cff")
    output_commands.append('*_selectedPrimaryVertex_*_*')
    output_commands.append('*_selectPrimaryVerticesQuality_*_*')
    process.tuplize += process.selectPrimaryVertices

    # Run the ZZ recipe for rho
    from RecoJets.JetProducers.kt4PFJets_cfi import kt4PFJets \
            as zzCantDoAnythingRight

    process.kt6PFJetsForIso = zzCantDoAnythingRight.clone(
        rParam = cms.double(0.6),
        doAreaFastjet = cms.bool(True),
        doRhoFastjet = cms.bool(True),
        Rho_EtaMax = cms.double(2.5),
        Ghost_EtaMax = cms.double(2.5),
    )
    process.tuplize += process.kt6PFJetsForIso

    # Standard services
    process.load('Configuration.StandardSequences.Services_cff')
    # tack on seeds for FSA PATTuple modules
    add_fsa_random_seeds(process)
    
    
    if cmssw_major_version() == 5 and cmssw_minor_version() >= 3: 
        process.load('Configuration.Geometry.GeometryIdeal_cff')
    else:
        process.load('Configuration.StandardSequences.GeometryIdeal_cff')
        
    process.load('Configuration.StandardSequences.MagneticField_cff')
    process.load('Configuration.StandardSequences.FrontierConditions_GlobalTag_cff')

    # Rerun tau ID
    if cmssw_major_version() == 4:
        process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
        # Optimization - remove PFTauTagInfo compatibility layer
        process.recoTauClassicHPSSequence.remove(process.pfRecoTauTagInfoProducer)
        process.recoTauClassicHPSSequence.remove(process.ak5PFJetTracksAssociatorAtVertex)
        assert(process.combinatoricRecoTaus.modifiers[3].name.value() == 'TTIworkaround')
        del process.combinatoricRecoTaus.modifiers[3]
        # Don't build junky taus below 19 GeV
        process.combinatoricRecoTaus.builders[0].minPtToBuild = cms.double(17)
        process.tuplize += process.recoTauClassicHPSSequence
    else:
        # We can run less tau stuff in 52, since HPS taus already built.
        process.load("RecoTauTag.Configuration.updateHPSPFTaus_cff")
        process.tuplize += process.updateHPSPFTaus

    ## Run rho computation.  Only necessary in 42X
    if cmssw_major_version() == 4:
        from RecoJets.Configuration.RecoPFJets_cff import kt6PFJets
        kt6PFJets.Rho_EtaMax = cms.double(4.4)
        kt6PFJets.doRhoFastjet = True
        process.kt6PFJets = kt6PFJets
        process.tuplize += process.kt6PFJets

    # In 4_X we have to rerun ak5PFJets with area computation enabled.
    if cmssw_major_version() == 4:
        process.load("RecoJets.Configuration.RecoPFJets_cff")
        process.ak5PFJets.doAreaFastjet = True
        process.tuplize += process.ak5PFJets
        # Only keep the new ak5PFJets
        output_commands.append('*_ak5PFJets_*_%s' % process.name_())
    else:
        # Just keep the normal ones
        output_commands.append('*_ak5PFJets_*_*')

    # In the embedded samples, we need to re-run the b-tagging
    if kwargs['embedded']:
       process.load('RecoBTag/Configuration/RecoBTag_cff')
       process.load('RecoJets/JetAssociationProducers/ak5JTA_cff')
       process.ak5JetTracksAssociatorAtVertex.jets   = cms.InputTag("ak5PFJets")
       process.ak5JetTracksAssociatorAtVertex.tracks = cms.InputTag("tmfTracks")
       process.tuplize += process.ak5JetTracksAssociatorAtVertex
       process.tuplize += process.btagging

    # Run pat default sequence
    process.load("PhysicsTools.PatAlgos.patSequences_cff")
    # Embed PF Isolation in electrons & muons
    pfTools.usePFIso(process)
    # Setup H2Tau custom iso definitions
    setup_h2tau_iso(process)
    # Setup hZg custom iso definitions
    add_hZg_iso_needs(process)
    
    # Use POG recommendations for (these) electron Isos
    process.elPFIsoValueGamma04PFIdPFIso.deposits[0].vetos = cms.vstring('EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueGamma04NoPFIdPFIso.deposits[0].vetos = cms.vstring('EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueCharged04PFIdPFIso.deposits[0].vetos = cms.vstring('EcalEndcaps:ConeVeto(0.015)')
    process.elPFIsoValueCharged04NoPFIdPFIso.deposits[0].vetos = cms.vstring('EcalEndcaps:ConeVeto(0.015)')

    # Unembed junk
    process.patMuons.embedCaloMETMuonCorrs = False
    process.patMuons.embedTcMETMuonCorrs = False
    process.patMuons.embedTrack = True
    process.patMuons.pvSrc = cms.InputTag("selectedPrimaryVertex")

    # Do extra electron ID
    process.load("FinalStateAnalysis.PatTools.electrons.electronID_cff")
    process.tuplize += process.recoElectronID
    process.patElectrons.electronIDSources = process.electronIDSources
    process.patElectrons.embedTrack = True

    # Now run PAT
    process.tuplize += process.patDefaultSequence

    # Add FSR photons for ZZ analysis
    process.load("FinalStateAnalysis.PatTools.fsrPhotons_cff")
    process.tuplize += process.fsrPhotonSequence

    # Use HPS taus
    tautools.switchToPFTauHPS(process)
    # Disable tau IsoDeposits
    process.patDefaultSequence.remove(process.patPFTauIsolation)
    process.patTaus.isoDeposits = cms.PSet()
    process.patTaus.userIsolation = cms.PSet()

    # Disable gen match embedding - we keep it in the ntuple
    process.patMuons.embedGenMatch = False
    process.patElectrons.embedGenMatch = False
    process.patTaus.embedGenMatch = False
    process.patTaus.embedGenJetMatch = False

    # Use PFJets and turn on JEC
    jec = [ 'L1FastJet', 'L2Relative', 'L3Absolute' ]
    # If we are running on data (not MC), or embedded sample,
    # apply the MC-DATA residual correction.
    if not isMC or kwargs['embedded']:
        jec.extend([ 'L2L3Residual' ])

    # Define options for BTagging - these are release dependent.
    btag_options = {'doBTagging' : True}
    if cmssw_major_version() == 5:
        btag_options['btagInfo'] = [
            'impactParameterTagInfos',
            'secondaryVertexTagInfos',
            'softMuonTagInfos',
            'secondaryVertexNegativeTagInfos'
        ]
        btag_options['btagdiscriminators'] = [
            'trackCountingHighEffBJetTags',
            'simpleSecondaryVertexHighEffBJetTags',
            'combinedSecondaryVertexMVABJetTags',
            'combinedSecondaryVertexBJetTags',
        ]

    # Use AK5 PFJets
    jettools.switchJetCollection(
        process,
        cms.InputTag('ak5PFJets'),
        doJTA = False,
        jetCorrLabel = ('AK5PF', jec),
        #jetCorrLabel = None,
        doType1MET = False,
        doJetID = True,
        genJetCollection = cms.InputTag("ak5GenJets"),
        **btag_options
    )
    process.patJets.embedPFCandidates = False
    process.patJets.embedCaloTowers = False
    process.patJets.embedGenJetMatch = False
    process.patJets.addAssociatedTracks = False
    process.patJets.embedGenPartonMatch = False
    #process.patJetCorrFactors.useRho = True
    ## Let's use the same rho as in the TauID, so we don't need to do it twice.
    #process.patJetCorrFactors.rho = cms.InputTag(
        #"kt6PFJetsForRhoComputationVoronoi", "rho")

    # Use PFMEt
    mettools.addPfMET(process)
    if not isMC:
        coreTools.runOnData(process)
        process.patMETsPF.addGenMET = False
    output_commands.append('*_selectedPatJets_*_*')

    # Customize/embed all our sequences
    process.load("FinalStateAnalysis.PatTools.patJetProduction_cff")
    # We have to keep all jets (for the MVA MET...)
    process.patJetGarbageRemoval.cut = 'pt > 0'

    final_jet_collection = chain_sequence(
        process.customizeJetSequence, "patJets")
    process.customizeJetSequence.insert(0, process.patJets)
    # Make it a "complete" sequence
    process.customizeJetSequence += process.selectedPatJets
    # We can't mess up the selected pat jets because the taus use them.
    process.selectedPatJets.src = final_jet_collection
    process.patDefaultSequence.replace(process.patJets,
                                       process.customizeJetSequence)

    # Produce the electron collections
    process.load("FinalStateAnalysis.PatTools.patElectronProduction_cff")
    final_electron_collection = chain_sequence(
        process.customizeElectronSequence, "selectedPatElectrons")
    process.tuplize += process.customizeElectronSequence
    process.customizeElectronSequence.insert(0, process.selectedPatElectrons)
    process.patDefaultSequence.replace(process.selectedPatElectrons,
                                       process.customizeElectronSequence)
    # We have to do the pat Jets before the pat electrons since we embed them
    process.customizeElectronSequence.insert(0, process.selectedPatJets)
    process.cleanPatElectrons.src = final_electron_collection
    #setup the energy regression for the specific dataset
    process.patElectronEnergyCorrections.isMC  = cms.bool(bool(isMC))
    process.patElectronEnergyCorrections.isAOD = \
                                               cms.bool(bool(kwargs['isAOD']))
    process.patElectronEnergyCorrections.dataSet = \
                                     cms.string(kwargs['calibrationTarget'])

    process.load("FinalStateAnalysis.PatTools.patMuonProduction_cff")
    final_muon_collection = chain_sequence(
        process.customizeMuonSequence, "selectedPatMuons")
    process.customizeMuonSequence.insert(0, process.selectedPatMuons)
    process.patDefaultSequence.replace(process.selectedPatMuons,
                                       process.customizeMuonSequence)
    process.cleanPatMuons.src = final_muon_collection
    process.patMuonRochesterCorrectionEmbedder.isMC = cms.bool(bool(isMC))
    

    process.load("FinalStateAnalysis.PatTools.patTauProduction_cff")
    final_tau_collection = chain_sequence(
        process.customizeTauSequence, "selectedPatTaus")
    # Inject into the pat sequence
    process.customizeTauSequence.insert(0, process.selectedPatTaus)
    process.patDefaultSequence.replace(process.selectedPatTaus,
                                       process.customizeTauSequence)
    process.cleanPatTaus.src = final_tau_collection
    # Remove muons and electrons
    process.cleanPatTaus.checkOverlaps.muons.requireNoOverlaps = False
    process.cleanPatTaus.checkOverlaps.electrons.requireNoOverlaps = False
    # Apply a loose preselection
    process.cleanPatTaus.preselection = 'abs(eta) < 2.5 & pt > 17'
    # Don't apply any "final" cut
    process.cleanPatTaus.finalCut = ''

    # Setup pat::Photon Production
    process.load("FinalStateAnalysis.PatTools.patPhotonProduction_cff")
    final_photon_collection = chain_sequence(process.customizePhotonSequence,
                                             "selectedPatPhotons")
    #inject photons into pat sequence
    process.customizePhotonSequence.insert(0,process.selectedPatPhotons)
    process.patDefaultSequence.replace(process.selectedPatPhotons,
                                       process.customizePhotonSequence)
    process.cleanPatPhotons.src = final_photon_collection

    # Setup MET production
    process.load("FinalStateAnalysis.PatTools.patMETProduction_cff")
    final_met_collection = chain_sequence(
        process.customizeMETSequence, "patMETsPF")
    process.tuplize += process.customizeMETSequence
    # The MET systematics depend on all other systematics
    process.systematicsMET.tauSrc = cms.InputTag("cleanPatTaus")
    process.systematicsMET.muonSrc = cms.InputTag("cleanPatMuons")
    process.systematicsMET.electronSrc = cms.InputTag("cleanPatElectrons")

    # Keep all the data formats needed for the systematics
    output_commands.append('recoLeafCandidates_*_*_%s'
                           % process.name_())

    # Define the default lepton cleaning
    process.cleanPatElectrons.preselection = cms.string('pt > 5')
    process.cleanPatElectrons.checkOverlaps.muons.requireNoOverlaps = False
    # Make sure we don't kill any good taus by calling them electrons
    # Note that we don't actually remove these overlaps.
    process.cleanPatElectrons.checkOverlaps.taus = cms.PSet(
        src = final_tau_collection,
        algorithm = cms.string("byDeltaR"),
        preselection = cms.string(
            "tauID('decayModeFinding') > 0.5 &&"
            "tauID('byLooseCombinedIsolationDeltaBetaCorr') > 0.5 &&"
            "tauID('againstElectronLoose') > 0.5 && "
            "pt > 10"
        ),
        deltaR = cms.double(0.1),
        checkRecoComponents = cms.bool(False),
        pairCut = cms.string(""),
        requireNoOverlaps = cms.bool(False),
    )

    output_commands.append('*_cleanPatTaus_*_*')
    output_commands.append('*_cleanPatElectrons_*_*')
    output_commands.append('*_cleanPatMuons_*_*')
    output_commands.append('*_cleanPatPhotons_*_*')
    output_commands.append('*_%s_*_*' % final_met_collection.value())

    trigtools.switchOnTrigger(process)

    # Now build the PATFinalStateLS object, which holds LumiSection info.
    process.load(
        "FinalStateAnalysis.PatTools.finalStates.patFinalStateLSProducer_cfi")
    process.tuplize += process.finalStateLS
    output_commands.append('*_finalStateLS_*_*')
    if isMC:
        process.finalStateLS.xSec = kwargs['xSec']

    # Tell the framework to shut up!
    process.load("FWCore.MessageLogger.MessageLogger_cfi")
    process.MessageLogger.cerr.FwkReport.reportEvery = 1000

    # Which collections are used to build the final states
    fs_daughter_inputs = {
        'electrons' : 'cleanPatElectrons',
        'muons' : 'cleanPatMuons',
        'taus' : 'cleanPatTaus',
        'photons' : 'cleanPatPhotons',
        'jets' : 'selectedPatJets',        
        'met' : final_met_collection,
    }

    # Setup all the PATFinalState objects
    produce_final_states(process, fs_daughter_inputs, output_commands,
                         process.tuplize, kwargs['puTag'])

    return process.tuplize, output_commands
def configurePatTuple(process, isMC=True, **kwargs):
    # Stuff we always keep
    output_commands = [
        '*_addPileupInfo_*_*',
        'edmMergeableCounter_*_*_*',
        '*_lumiProducer_*_*',
        '*_particleFlow_*_*',
        '*_offlineBeamSpot_*_*',
        '*_generalTracks_*_*',
        '*_electronGsfTracks_*_*',
        '*_gsfElectrons_*_*',
        '*_gsfElectronCores_*_*',
        '*_offlinePrimaryVertices*_*_*',
        '*_ak5GenJets_*_*',
        '*_hltTriggerSummaryAOD_*_*',
        'edmTriggerResults_TriggerResults_*_%s' % process.name_(),
        '*_MEtoEDMConverter*_*_%s' % process.name_(),
        'LHEEventProduct_*_*_*',
        'GenEventInfoProduct_generator_*_*',
        '*_kt6PFJetsForRhoComputationVoronoi_rho_*',
        '*_kt6PFJetsForIso_rho_*',
        '*_kt6PFJets_rho_*',
        '*_kt6PFJetsHZGPho_rho_*',
        '*_kt6PFJetsCentralHZGEle_rho_*',
        '*_kt6PFJetsCentralHZGMu_rho_*',
        '*_kt6PFJetsCentralNeutralHZGMu_rho_*',
        '*_kt6PFJetsCentral_rho_*',
        '*_kt6PFJetsCentralNeutral_rho_*',  # for zz muons
        '*_photonCore_*_*',
        '*_boostedFsrPhotons_*_*',
        # for Zmumu -> embedded samples
        # https://twiki.cern.ch/twiki/bin/view/CMS/MuonTauReplacementRecHit
        '*_generalTracksORG_*_EmbeddedRECO',
        '*_electronGsfTracksORG_*_EmbeddedRECO',
        'double_TauSpinnerReco_TauSpinnerWT_EmbeddedSPIN',
        'double_ZmumuEvtSelEffCorrWeightProducer_weight_EmbeddedRECO',
        'double_muonRadiationCorrWeightProducer_weight_EmbeddedRECO',
        'GenFilterInfo_generator_minVisPtFilter_EmbeddedRECO',
    ]
    # Define our patTuple production sequence
    process.tuplize = cms.Sequence()
    # Only keep interesting genParticles
    process.load("FinalStateAnalysis.RecoTools.genParticleTrimmer_cfi")
    process.genParticles = process.prunedGenParticles.clone()
    if isMC:
        #process.tuplize += process.genParticles
        #output_commands.append('*_genParticles_*_%s' % process.name_())
        output_commands.append('*_genParticles_*_*')

    output_commands.append('*_tauGenJetsSelectorAllHadrons_*_*')
    output_commands.append('*_tauGenJets_*_*')
    output_commands.append('*_ak5GenJets_*_*')
    # Select vertices
    process.load("FinalStateAnalysis.RecoTools.vertexSelection_cff")
    output_commands.append('*_selectedPrimaryVertex*_*_*')
    output_commands.append('*_selectPrimaryVerticesQuality*_*_*')
    process.tuplize += process.selectPrimaryVertices

    # Run the ZZ recipe for rho
    from RecoJets.JetProducers.kt4PFJets_cfi import kt4PFJets \
        as zzCantDoAnythingRight

    process.kt6PFJetsForIso = zzCantDoAnythingRight.clone(
        rParam=cms.double(0.6),
        doAreaFastjet=cms.bool(True),
        doRhoFastjet=cms.bool(True),
        Rho_EtaMax=cms.double(2.5),
        Ghost_EtaMax=cms.double(2.5),
    )
    process.tuplize += process.kt6PFJetsForIso

    # Standard services
    process.load('Configuration.StandardSequences.Services_cff')
    # tack on seeds for FSA PATTuple modules
    add_fsa_random_seeds(process)

    if cmssw_major_version() == 5 and cmssw_minor_version() >= 3:
        process.load('Configuration.Geometry.GeometryDB_cff')
    else:
        process.load('Configuration.StandardSequences.GeometryDB_cff')

    process.load('Configuration.StandardSequences.MagneticField_cff')
    process.load(
        'Configuration.StandardSequences.FrontierConditions_GlobalTag_cff')

    # Rerun tau ID
    process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
    # Optimization - remove PFTauTagInfo compatibility layer
    process.recoTauClassicHPSSequence.remove(
        process.pfRecoTauTagInfoProducer)
    process.recoTauClassicHPSSequence.remove(
        process.ak5PFJetTracksAssociatorAtVertex)
    assert(process.combinatoricRecoTaus.modifiers[3].name.value() ==
           'TTIworkaround')
    del process.combinatoricRecoTaus.modifiers[3]
    # Don't build junky taus below 19 GeV
    process.combinatoricRecoTaus.builders[0].minPtToBuild = cms.double(17)
    process.tuplize += process.recoTauClassicHPSSequence

    ## Run rho computation.  Only necessary in 42X
    if cmssw_major_version() == 4:
        # This function call can klobber everything if it isn't done
        # before the other things are attached to the process, so do it now.
        # The klobbering would occur through usePFIso->setupPFIso->_loadPFBRECO
        from CommonTools.ParticleFlow.Tools.pfIsolation import _loadPFBRECO
        _loadPFBRECO(process)
        process.load("RecoJets.Configuration.RecoPFJets_cff")
        process.kt6PFJets.Rho_EtaMax = cms.double(4.4)
        process.kt6PFJets.doRhoFastjet = True
        process.tuplize += process.kt6PFJets

    # In 4_X we have to rerun ak5PFJets with area computation enabled.
    if cmssw_major_version() == 4:
        process.load("RecoJets.Configuration.RecoPFJets_cff")
        process.ak5PFJets.doAreaFastjet = True
        process.tuplize += process.ak5PFJets
        # Only keep the new ak5PFJets
        output_commands.append('*_ak5PFJets_*_%s' % process.name_())
    else:
        # Just keep the normal ones
        output_commands.append('*_ak5PFJets_*_*')

    # Run pat default sequence
    process.load("PhysicsTools.PatAlgos.patSequences_cff")
    # Embed PF Isolation in electrons & muons
    pfTools.usePFIso(process)
    # Setup H2Tau custom iso definitions
    setup_h2tau_iso(process)
    # Setup hZg custom iso definitions
    add_hZg_iso_needs(process)

    #alter the photon matching to accept various fakes
    # and sort matches by d-pt-rel
    if isMC:
        process.photonMatch = cms.EDProducer(
            "MCMatcherByPt",
            src=cms.InputTag("photons"),
            maxDPtRel=cms.double(100.0),
            mcPdgId=cms.vint32(),
            mcStatus=cms.vint32(1),
            resolveByMatchQuality=cms.bool(False),
            maxDeltaR=cms.double(0.3),
            checkCharge=cms.bool(False),
            resolveAmbiguities=cms.bool(True),
            matched=cms.InputTag("genParticles")
        )

    # Use POG recommendations for (these) electron Isos
    process.elPFIsoValueGamma04PFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueGamma04NoPFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueCharged04PFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.015)')
    process.elPFIsoValueCharged04NoPFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.015)')

    # Unembed junk
    process.patMuons.embedCaloMETMuonCorrs = False
    process.patMuons.embedTcMETMuonCorrs = False
    process.patMuons.embedTrack = True
    process.patMuons.pvSrc = cms.InputTag("selectedPrimaryVertex")

    # Do extra electron ID
    process.load("FinalStateAnalysis.PatTools.electrons.electronID_cff")
    if cmssw_major_version() == 4:
        process.patDefaultSequence.replace(process.patElectrons,
                                           process.recoElectronID42X +
                                           process.patElectrons)
        process.patElectrons.electronIDSources = process.electronIDSources42X
    else:
        process.patDefaultSequence.replace(process.patElectrons,
                                           process.recoElectronID5YX +
                                           process.patElectrons)
        process.patElectrons.electronIDSources = process.electronIDSources5YX

    process.electronMatch.checkCharge = cms.bool(False)
    process.patElectrons.embedTrack = False
    process.patElectrons.embedPFCandidate = False
    process.patElectrons.embedGsfElectronCore = False
    process.patElectrons.embedSuperCluster = True

    # Now run PAT
    process.tuplize += process.patDefaultSequence

    # Add FSR photons for ZZ analysis
    process.load("FinalStateAnalysis.PatTools.fsrPhotons_cff")
    process.tuplize += process.fsrPhotonSequence

    # Use HPS taus
    tautools.switchToPFTauHPS(process)
    # Disable tau IsoDeposits
    process.patDefaultSequence.remove(process.patPFTauIsolation)
    process.patTaus.isoDeposits = cms.PSet()
    process.patTaus.userIsolation = cms.PSet()

    # Disable gen match embedding - we keep it in the ntuple
    process.patMuons.embedGenMatch = False
    process.patElectrons.embedGenMatch = False
    process.patTaus.embedGenMatch = False
    process.patTaus.embedGenJetMatch = False
    process.patPhotons.embedGenMatch = False

    # Use PFJets and turn on JEC
    jec = ['L1FastJet', 'L2Relative', 'L3Absolute']
    # If we are running on data (not MC), or embedded sample,
    # apply the MC-DATA residual correction.
    if not isMC or kwargs['embedded']:
        jec.extend(['L2L3Residual'])

    # Define options for BTagging - these are release dependent.
    btag_options = {'doBTagging': True}
    if cmssw_major_version() == 5:
        btag_options['btagInfo'] = [
            'impactParameterTagInfos',
            'secondaryVertexTagInfos',
            'softMuonTagInfos',
            'secondaryVertexNegativeTagInfos'
        ]
        btag_options['btagdiscriminators'] = [
            'trackCountingHighEffBJetTags',
            'simpleSecondaryVertexHighEffBJetTags',
            'combinedSecondaryVertexMVABJetTags',
            'combinedSecondaryVertexBJetTags',
        ]

    # Use AK5 PFJets
    jettools.switchJetCollection(
        process,
        cms.InputTag('ak5PFJets'),
        doJTA=False,
        jetCorrLabel=('AK5PF', jec),
        #jetCorrLabel = None,
        doType1MET=False,
        doJetID=True,
        genJetCollection=cms.InputTag("ak5GenJets"),
        **btag_options
    )
    process.patJets.embedPFCandidates = False
    process.patJets.embedCaloTowers = False
    process.patJets.embedGenJetMatch = False
    process.patJets.addAssociatedTracks = False
    process.patJets.embedGenPartonMatch = False
    #process.patJetCorrFactors.useRho = True
    ## Let's use the same rho as in the TauID, so we don't need to do it twice.
    #process.patJetCorrFactors.rho = cms.InputTag(
        #"kt6PFJetsForRhoComputationVoronoi", "rho")

    # Use PFMEt
    mettools.addPfMET(process)
    if not isMC:
        coreTools.runOnData(process)
        process.patMETsPF.addGenMET = False
    output_commands.append('*_selectedPatJets_*_*')

    # Customize/embed all our sequences
    process.load("FinalStateAnalysis.PatTools.patJetProduction_cff")
    process.patJetGarbageRemoval.cut = 'pt > 12'

    final_jet_collection = chain_sequence(
        process.customizeJetSequence, "patJets")
    process.customizeJetSequence.insert(0, process.patJets)
    # Make it a "complete" sequence
    process.customizeJetSequence += process.selectedPatJets
    # We can't mess up the selected pat jets because the taus use them.
    process.selectedPatJets.src = final_jet_collection
    process.patDefaultSequence.replace(process.patJets,
                                       process.customizeJetSequence)

    # Produce the electron collections
    process.load("FinalStateAnalysis.PatTools.patElectronProduction_cff")

    # Electron Energy Regression and Calibrations
    process.load(
        "EgammaAnalysis.ElectronTools.electronRegressionEnergyProducer_cfi")
    process.load("EgammaAnalysis.ElectronTools.calibratedPatElectrons_cfi")

    #setup the energy regression for the specific dataset
    if kwargs['eleReg']:
        print "-- Applying Electron Regression and Calibration --"

        process.customizeElectronSequence += process.eleRegressionEnergy
        process.customizeElectronSequence += process.calibratedPatElectrons

        process.eleRegressionEnergy.energyRegressionType = cms.uint32(2)
        process.calibratedPatElectrons.correctionsType = cms.int32(2)

        if isMC:
            process.calibratedPatElectrons.inputDataset = cms.string(
                "Summer12_LegacyPaper")
        else:
            process.calibratedPatElectrons.inputDataset = cms.string(
                "22Jan2013ReReco")

        process.calibratedPatElectrons.combinationType = cms.int32(3)
        process.calibratedPatElectrons.lumiRatio = cms.double(1.0)
        process.calibratedPatElectrons.synchronization = cms.bool(True)
        process.calibratedPatElectrons.isMC = cms.bool(isMC == 1)
        process.calibratedPatElectrons.verbose = cms.bool(False)

    final_electron_collection = chain_sequence(
        process.customizeElectronSequence, "selectedPatElectrons",
        # Some of the EGamma modules have non-standard src InputTags,
        # specify them here.
        ("src", "inputPatElectronsTag", "inputElectronsTag")
    )

    process.tuplize += process.customizeElectronSequence
    process.customizeElectronSequence.insert(0, process.selectedPatElectrons)
    process.patDefaultSequence.replace(process.selectedPatElectrons,
                                       process.customizeElectronSequence)
    # We have to do the pat Jets before the pat electrons since we embed them
    process.customizeElectronSequence.insert(0, process.selectedPatJets)

    # Define cleanPatElectrons input collection
    process.cleanPatElectrons.src = final_electron_collection

    process.load("FinalStateAnalysis.PatTools.patMuonProduction_cff")
    final_muon_collection = chain_sequence(
        process.customizeMuonSequence, "selectedPatMuons")
    process.customizeMuonSequence.insert(0, process.selectedPatMuons)
    process.patDefaultSequence.replace(process.selectedPatMuons,
                                       process.customizeMuonSequence)
    process.cleanPatMuons.src = final_muon_collection
    process.patMuonRochesterCorrectionEmbedder.isMC = cms.bool(bool(isMC))

    process.load("FinalStateAnalysis.PatTools.patTauProduction_cff")
    # Require all taus to pass decay mode finding and have high PT
    process.patTauGarbageRemoval.cut = cms.string(
        "pt > 17 && abs(eta) < 2.5 && tauID('decayModeFinding')")
    final_tau_collection = chain_sequence(
        process.customizeTauSequence, "selectedPatTaus")
    # Inject into the pat sequence
    process.customizeTauSequence.insert(0, process.selectedPatTaus)
    process.patDefaultSequence.replace(process.selectedPatTaus,
                                       process.customizeTauSequence)
    process.cleanPatTaus.src = final_tau_collection
    # Remove muons and electrons
    process.cleanPatTaus.checkOverlaps.muons.requireNoOverlaps = False
    process.cleanPatTaus.checkOverlaps.electrons.requireNoOverlaps = False
    # Cuts already applied by the garbage removal
    process.cleanPatTaus.preselection = ''
    process.cleanPatTaus.finalCut = ''

    # Setup pat::Photon Production
    process.load("FinalStateAnalysis.PatTools.patPhotonProduction_cff")
    final_photon_collection = chain_sequence(process.customizePhotonSequence,
                                             "selectedPatPhotons")
    #setup PHOSPHOR for a specific dataset
    if cmssw_major_version() == 4:  # for now 2011 = CMSSW42X
        process.patPhotonPHOSPHOREmbedder.year = cms.uint32(2011)
    else:  # 2012 is 5YX
        process.patPhotonPHOSPHOREmbedder.year = cms.uint32(2012)
    process.patPhotonPHOSPHOREmbedder.isMC = cms.bool(bool(isMC))
    #inject photons into pat sequence
    process.customizePhotonSequence.insert(0, process.selectedPatPhotons)
    process.patDefaultSequence.replace(process.selectedPatPhotons,
                                       process.customizePhotonSequence)
    process.cleanPatPhotons.src = final_photon_collection

    # We cut out a lot of the junky taus and jets - but we need these
    # to correctly apply the MET uncertainties.  So, let's make a
    # non-cleaned version of the jet and tau sequence.
    process.jetsForMetSyst = helpers.cloneProcessingSnippet(
        process, process.customizeJetSequence, 'ForMETSyst')
    process.tausForMetSyst = helpers.cloneProcessingSnippet(
        process, process.customizeTauSequence, 'ForMETSyst')
    # Don't apply any cut for these
    process.patTauGarbageRemovalForMETSyst.cut = ''
    process.patJetGarbageRemovalForMETSyst.cut = ''
    process.tuplize += process.jetsForMetSyst
    process.tuplize += process.tausForMetSyst
    # We have to make our clone of cleanPatTaus separately, since e/mu
    # cleaning is applied - therefore it isn't in the customizeTausSequence.
    process.cleanPatTausForMETSyst = process.cleanPatTaus.clone(
        src=cms.InputTag(process.cleanPatTaus.src.value() + "ForMETSyst"))
    process.cleanPatTausForMETSyst.preselection = ''
    process.cleanPatTausForMETSyst.finalCut = ''
    process.patTausEmbedJetInfoForMETSyst.jetSrc = \
        final_jet_collection.value() + "ForMETSyst"
    process.tuplize += process.cleanPatTausForMETSyst

    # Setup MET production
    process.load("FinalStateAnalysis.PatTools.patMETProduction_cff")
    # The MET systematics depend on all other systematics
    process.systematicsMET.tauSrc = cms.InputTag("cleanPatTausForMETSyst")
    process.systematicsMET.muonSrc = cms.InputTag("cleanPatMuons")
    process.systematicsMET.electronSrc = cms.InputTag("cleanPatElectrons")

    final_met_collection = chain_sequence(
        process.customizeMETSequence, "patMETsPF")
    process.tuplize += process.customizeMETSequence
    output_commands.append('*_%s_*_*' % final_met_collection.value())

    # Make a version with the MVA MET reconstruction method
    process.load("FinalStateAnalysis.PatTools.met.mvaMetOnPatTuple_cff")
    process.tuplize += process.pfMEtMVAsequence
    mva_met_sequence = helpers.cloneProcessingSnippet(
        process, process.customizeMETSequence, "MVA")
    final_mvamet_collection = chain_sequence(
        mva_met_sequence, "patMEtMVA")
    process.tuplize += mva_met_sequence
    output_commands.append('*_%s_*_*' % final_mvamet_collection.value())

    # Keep all the data formats needed for the systematics
    output_commands.append('recoLeafCandidates_*_*_%s'
                           % process.name_())
    # We can drop to jet and tau MET specific products. They were only used for
    # computation of the MET numbers.
    output_commands.append('drop recoLeafCandidates_*ForMETSyst_*_%s'
                           % process.name_())

    # Define the default lepton cleaning
    process.cleanPatElectrons.preselection = cms.string(
        'pt > 5')
    process.cleanPatElectrons.checkOverlaps.muons.requireNoOverlaps = False
    # Make sure we don't kill any good taus by calling them electrons
    # Note that we don't actually remove these overlaps.
    process.cleanPatElectrons.checkOverlaps.taus = cms.PSet(
        src=final_tau_collection,
        algorithm=cms.string("byDeltaR"),
        preselection=cms.string(
            "tauID('decayModeFinding') > 0.5 &&"
            "tauID('byLooseCombinedIsolationDeltaBetaCorr') > 0.5 &&"
            "tauID('againstElectronLoose') > 0.5 && "
            "pt > 10"
        ),
        deltaR=cms.double(0.1),
        checkRecoComponents=cms.bool(False),
        pairCut=cms.string(""),
        requireNoOverlaps=cms.bool(False),
    )

    output_commands.append('*_cleanPatTaus_*_*')
    output_commands.append('*_cleanPatElectrons_*_*')
    output_commands.append('*_cleanPatMuons_*_*')
    output_commands.append('*_cleanPatPhotons_*_*')

    trigtools.switchOnTrigger(process)

    #configure the PAT trigger
    if kwargs['HLTprocess']:
        process.patTrigger.processName = cms.string(kwargs['HLTprocess'])
        process.patTriggerEvent.processName = cms.string(kwargs['HLTprocess'])

    # Now build the PATFinalStateLS object, which holds LumiSection info.
    process.load(
        "FinalStateAnalysis.PatTools.finalStates.patFinalStateLSProducer_cfi")
    process.tuplize += process.finalStateLS
    output_commands.append('*_finalStateLS_*_*')
    if isMC:
        process.finalStateLS.xSec = kwargs['xSec']

    # Tell the framework to shut up!
    process.load("FWCore.MessageLogger.MessageLogger_cfi")
    process.MessageLogger.cerr.FwkReport.reportEvery = 1000

    # Which collections are used to build the final states
    fs_daughter_inputs = {
        'electrons':  'cleanPatElectrons',
        'muons':  'cleanPatMuons',
        'taus':  'cleanPatTaus',
        'photons':  'cleanPatPhotons',
        'jets':  'selectedPatJets',
        'pfmet':  final_met_collection,
        'mvamet':  final_mvamet_collection,
    }

    # Setup all the PATFinalState objects
    produce_final_states(process, fs_daughter_inputs, output_commands,
                         process.tuplize, kwargs['puTag'],
                         zzMode=kwargs.get('zzMode', False))

    return process.tuplize, output_commands
def configurePatTuple(process, isMC=True, **kwargs):
    '''
    Core function for PATTuple production
    '''
    #fix argparser output
    isMC = bool(isMC)

    ########################
    ##                    ##
    ##  PATTuple content  ##
    ##                    ##
    ########################
    # Stuff we always keep
    output_commands = [
        '*_addPileupInfo_*_*',
        'edmMergeableCounter_*_*_*',
        '*_lumiProducer_*_*',
        '*_particleFlow_*_*',
        '*_offlineBeamSpot_*_*',
        '*_generalTracks_*_*',
        '*_electronGsfTracks_*_*',
        '*_gsfElectrons_*_*',
        '*_gsfElectronCores_*_*',
        '*_offlinePrimaryVertices*_*_*',
        '*_ak5GenJets_*_*',
        '*_hltTriggerSummaryAOD_*_*',
        'edmTriggerResults_TriggerResults_*_%s' % process.name_(),
        '*_MEtoEDMConverter*_*_%s' % process.name_(),
        'LHEEventProduct_*_*_*',
        'GenEventInfoProduct_generator_*_*',
        '*_kt6PFJetsForRhoComputationVoronoi_rho_*',
        '*_kt6PFJetsForIso_rho_*',
        '*_kt6PFJets_rho_*',
        '*_kt6PFJetsHZGPho_rho_*',
        '*_kt6PFJetsCentralHZGEle_rho_*',
        '*_kt6PFJetsCentralHZGMu_rho_*',
        '*_kt6PFJetsCentralNeutralHZGMu_rho_*',
        '*_kt6PFJetsCentral_rho_*',
        '*_kt6PFJetsCentralNeutral_rho_*',  # for zz muons
        '*_photonCore_*_*',
        '*_boostedFsrPhotons_*_*',
        # for Zmumu -> embedded samples
        # https://twiki.cern.ch/twiki/bin/view/CMS/MuonTauReplacementRecHit
        '*_generalTracksORG_*_EmbeddedRECO',
        '*_electronGsfTracksORG_*_EmbeddedRECO',
        'double_TauSpinnerReco_TauSpinnerWT_EmbeddedSPIN',
        'double_ZmumuEvtSelEffCorrWeightProducer_weight_EmbeddedRECO',
        'double_muonRadiationCorrWeightProducer_weight_EmbeddedRECO',
        'GenFilterInfo_generator_minVisPtFilter_EmbeddedRECO',
    ]
    # Define our patTuple production sequence
    process.tuplize = cms.Sequence()
    # Only keep interesting genParticles
    process.load("FinalStateAnalysis.RecoTools.genParticleTrimmer_cfi")
    process.genParticles = process.prunedGenParticles.clone()
    if isMC:
        #process.tuplize += process.genParticles
        #output_commands.append('*_genParticles_*_%s' % process.name_())
        output_commands.append('*_genParticles_*_*')

    output_commands.append('*_tauGenJetsSelectorAllHadrons_*_*')
    output_commands.append('*_tauGenJets_*_*')
    output_commands.append('*_ak5GenJets_*_*')

    ########################
    ##                    ##
    ##        PAT         ##
    ##                    ##
    ########################

    # Run pat default sequence
    process.load("PhysicsTools.PatAlgos.patSequences_cff")

    # Embed PF Isolation in electrons & muons
    pfTools.usePFIso(process)
    # Setup H2Tau custom iso definitions
    setup_h2tau_iso(process)
    # Setup hZg custom iso definitions
    add_hZg_iso_needs(process)

    # Now run PAT
    process.tuplize += process.patDefaultSequence

    # Add FSR photons for ZZ analysis
    process.load("FinalStateAnalysis.PatTools.fsrPhotons_cff")
    process.tuplize += process.fsrPhotonSequence

    ########################
    ##        GEN         ##
    ########################

    # Disable gen match embedding - we keep it in the ntuple
    process.patMuons.embedGenMatch = False
    process.patElectrons.embedGenMatch = False
    process.patTaus.embedGenMatch = False
    process.patTaus.embedGenJetMatch = False
    process.patPhotons.embedGenMatch = False
    if not isMC:
        coreTools.runOnData(process)

    ########################
    ##       MUONS        ##
    ########################

    # Unembed junk
    process.patMuons.embedCaloMETMuonCorrs = False
    process.patMuons.embedTcMETMuonCorrs = False
    process.patMuons.embedTrack = True
    process.patMuons.pvSrc = cms.InputTag("selectedPrimaryVertex")

    process.load("FinalStateAnalysis.PatTools.patMuonProduction_cff")
    final_muon_collection = chain_sequence(process.customizeMuonSequence,
                                           "selectedPatMuons")
    process.customizeMuonSequence.insert(0, process.selectedPatMuons)
    process.patDefaultSequence.replace(process.selectedPatMuons,
                                       process.customizeMuonSequence)
    process.cleanPatMuons.src = final_muon_collection
    process.patMuonRochesterCorrectionEmbedder.isMC = cms.bool(bool(isMC))

    ########################
    ##        TAUS        ##
    ########################

    # Use HPS taus
    tautools.switchToPFTauHPS(
        process)  #this NEEDS a sequence called patDefaultSequence
    # Disable tau IsoDeposits
    process.patDefaultSequence.remove(process.patPFTauIsolation)
    process.patTaus.isoDeposits = cms.PSet()
    process.patTaus.userIsolation = cms.PSet()

    process.load("FinalStateAnalysis.PatTools.patTauProduction_cff")
    # Require all taus to pass decay mode finding and have high PT
    process.patTauGarbageRemoval.cut = cms.string(
        "pt > 17 && abs(eta) < 2.5 && tauID('decayModeFindingNewDMs')")
    final_tau_collection = chain_sequence(process.customizeTauSequence,
                                          "selectedPatTaus")
    # Inject into the pat sequence
    process.customizeTauSequence.insert(0, process.selectedPatTaus)
    process.patDefaultSequence.replace(process.selectedPatTaus,
                                       process.customizeTauSequence)
    process.cleanPatTaus.src = final_tau_collection
    # Remove muons and electrons
    process.cleanPatTaus.checkOverlaps.muons.requireNoOverlaps = False
    process.cleanPatTaus.checkOverlaps.electrons.requireNoOverlaps = False
    # Cuts already applied by the garbage removal
    process.cleanPatTaus.preselection = ''
    process.cleanPatTaus.finalCut = ''

    ########################
    ##     ELECTRONS      ##
    ########################

    # Use POG recommendations for (these) electron Isos
    process.elPFIsoValueGamma04PFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueGamma04NoPFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueCharged04PFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.015)')
    process.elPFIsoValueCharged04NoPFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.015)')

    # Do extra electron ID
    process.load("FinalStateAnalysis.PatTools.electrons.electronID_cff")
    if cmssw_major_version() == 4:
        process.patDefaultSequence.replace(
            process.patElectrons,
            process.recoElectronID42X + process.patElectrons)
        process.patElectrons.electronIDSources = process.electronIDSources42X
    else:
        process.patDefaultSequence.replace(
            process.patElectrons,
            process.recoElectronID5YX + process.patElectrons)
        process.patElectrons.electronIDSources = process.electronIDSources5YX

    process.electronMatch.checkCharge = cms.bool(False)
    process.patElectrons.embedTrack = False
    process.patElectrons.embedPFCandidate = False
    process.patElectrons.embedGsfElectronCore = False
    process.patElectrons.embedSuperCluster = True

    # Produce the electron collections
    process.load("FinalStateAnalysis.PatTools.patElectronProduction_cff")

    # Electron Energy Regression and Calibrations
    process.load(
        "EgammaAnalysis.ElectronTools.electronRegressionEnergyProducer_cfi")
    process.load("EgammaAnalysis.ElectronTools.calibratedPatElectrons_cfi")

    #setup the energy regression for the specific dataset
    if kwargs['eleReg']:
        print "-- Applying Electron Regression and Calibration --"

        process.customizeElectronSequence += process.eleRegressionEnergy
        process.customizeElectronSequence += process.calibratedPatElectrons

        process.eleRegressionEnergy.energyRegressionType = cms.uint32(2)
        process.calibratedPatElectrons.correctionsType = cms.int32(2)

        if isMC:
            process.calibratedPatElectrons.inputDataset = cms.string(
                "Summer12_LegacyPaper")
        else:
            process.calibratedPatElectrons.inputDataset = cms.string(
                "22Jan2013ReReco")

        process.calibratedPatElectrons.combinationType = cms.int32(3)
        process.calibratedPatElectrons.lumiRatio = cms.double(1.0)
        process.calibratedPatElectrons.synchronization = cms.bool(True)
        process.calibratedPatElectrons.isMC = cms.bool(isMC == 1)
        process.calibratedPatElectrons.verbose = cms.bool(False)

    final_electron_collection = chain_sequence(
        process.customizeElectronSequence,
        "selectedPatElectrons",
        # Some of the EGamma modules have non-standard src InputTags,
        # specify them here.
        ("src", "inputPatElectronsTag", "inputElectronsTag"))

    #process.tuplize += process.customizeElectronSequence #why do we need this?
    process.customizeElectronSequence.insert(0, process.selectedPatElectrons)
    process.patDefaultSequence.replace(process.selectedPatElectrons,
                                       process.customizeElectronSequence)
    # We have to do the pat Jets before the pat electrons since we embed them
    process.customizeElectronSequence.insert(0, process.selectedPatJets)

    # Define cleanPatElectrons input collection
    process.cleanPatElectrons.src = final_electron_collection

    # Define the default lepton cleaning
    process.cleanPatElectrons.preselection = cms.string('pt > 5')
    process.cleanPatElectrons.checkOverlaps.muons.requireNoOverlaps = False
    # Make sure we don't kill any good taus by calling them electrons
    # Note that we don't actually remove these overlaps.
    process.cleanPatElectrons.checkOverlaps.taus = cms.PSet(
        src=final_tau_collection,
        algorithm=cms.string("byDeltaR"),
        preselection=cms.string(
            "tauID('decayModeFinding') > 0.5 &&"
            "tauID('byLooseCombinedIsolationDeltaBetaCorr') > 0.5 &&"
            "tauID('againstElectronLoose') > 0.5 && "
            "pt > 10"),
        deltaR=cms.double(0.1),
        checkRecoComponents=cms.bool(False),
        pairCut=cms.string(""),
        requireNoOverlaps=cms.bool(False),
    )

    ########################
    ##        JETS        ##
    ########################

    # Use PFJets and turn on JEC
    jec = ['L1FastJet', 'L2Relative', 'L3Absolute']
    # If we are running on data (not MC), or embedded sample,
    # apply the MC-DATA residual correction.
    if not isMC or kwargs['embedded']:
        jec.extend(['L2L3Residual'])

    # tmp
    # define the b-tag squences for offline reconstruction
    process.load("RecoBTag.SecondaryVertex.secondaryVertex_cff")
    process.load("RecoBTau.JetTagComputer.combinedMVA_cff")
    process.load('RecoVertex/AdaptiveVertexFinder/inclusiveVertexing_cff')
    process.load('RecoBTag/SecondaryVertex/bToCharmDecayVertexMerger_cfi')
    #process.load("PhysicsTools.PatAlgos.patSequences_cff")

    # Define options for BTagging - these are release dependent.
    btag_options = {'doBTagging': True}
    if cmssw_major_version() == 5:
        btag_options['btagInfo'] = [
            'impactParameterTagInfos', 'secondaryVertexTagInfos',
            'softMuonTagInfos', 'secondaryVertexNegativeTagInfos',
            'inclusiveSecondaryVertexFinderFilteredTagInfos'
        ]
        btag_options['btagdiscriminators'] = [
            'trackCountingHighEffBJetTags',
            'trackCountingHighPurBJetTags',
            'simpleSecondaryVertexHighEffBJetTags',
            'simpleSecondaryVertexHighPurBJetTags',
            'simpleInclusiveSecondaryVertexHighEffBJetTags',
            'simpleInclusiveSecondaryVertexHighPurBJetTags',
            'combinedSecondaryVertexMVABJetTags',
            'combinedSecondaryVertexBJetTags',
            'jetBProbabilityBJetTags',
            'jetProbabilityBJetTags',
        ]

    #Avoid embedding
    process.patJets.embedPFCandidates = True
    process.patJets.embedCaloTowers = False
    process.patJets.embedGenJetMatch = True
    process.patJets.addAssociatedTracks = True
    process.patJets.embedGenPartonMatch = True

    # Add AK5chs PFJets
    jettools.addJetCollection(process,
                              cms.InputTag('ak5PFchsJets'),
                              algoLabel="AK5",
                              typeLabel="PFchs",
                              doJTA=True,
                              jetCorrLabel=('AK5PFchs', jec),
                              doType1MET=False,
                              doL1Cleaning=False,
                              doL1Counters=False,
                              genJetCollection=cms.InputTag('ak5GenJets'),
                              doJetID=True,
                              **btag_options)

    # Use AK5 PFJets
    jettools.switchJetCollection(
        process,
        cms.InputTag('ak5PFJets'),
        doJTA=True,
        jetCorrLabel=('AK5PF', jec),
        #jetCorrLabel = None,
        doType1MET=False,
        doJetID=True,
        genJetCollection=cms.InputTag("ak5GenJets"),
        **btag_options)

    # Customize/embed all our sequences
    process.load("FinalStateAnalysis.PatTools.patJetProduction_cff")
    helpers.cloneProcessingSnippet(process, process.customizeJetSequence,
                                   'AK5PFchs')
    process.patJetGarbageRemoval.cut = 'pt > 12'
    final_jet_collection = chain_sequence(process.customizeJetSequence,
                                          "patJets")
    process.customizeJetSequence.insert(0, process.patJets)
    # Make it a "complete" sequence
    process.customizeJetSequence += process.selectedPatJets
    #    process.customizeJetSequence += process.btagging
    # We can't mess up the selected pat jets because the taus use them.
    process.selectedPatJets.src = final_jet_collection
    process.patDefaultSequence.replace(process.patJets,
                                       process.customizeJetSequence)

    process.customizeJetSequenceAK5PFchs.remove(process.patJetsPUIDAK5PFchs)
    process.customizeJetSequenceAK5PFchs.remove(
        process.pileupJetIdProducerAK5PFchs)
    process.patJetGarbageRemovalAK5PFchs.cut = 'pt > 20'
    process.patJetCorrFactorsAK5PFchs.payload = cms.string('AK5PFchs')
    final_jetchs_collection = chain_sequence(
        process.customizeJetSequenceAK5PFchs, "patJetsAK5PFchs")
    process.customizeJetSequenceAK5PFchs.insert(0, process.patJetsAK5PFchs)
    # Make it a "complete" sequence
    process.customizeJetSequenceAK5PFchs += process.selectedPatJetsAK5PFchs
    # We can't mess up the selected pat jets because the taus use them.
    process.selectedPatJetsAK5PFchs.src = final_jetchs_collection
    process.selectedPatJetsAK5chsPF = process.selectedPatJetsAK5PFchs.clone(
    )  #that's what we keep
    process.customizeJetSequenceAK5PFchs += process.selectedPatJetsAK5chsPF
    process.patDefaultSequence.replace(process.patJetsAK5PFchs,
                                       process.customizeJetSequenceAK5PFchs)

    output_commands.append('*_selectedPatJets_*_*')
    output_commands.append('*_selectedPatJetsAK5chsPF_*_*')
    output_commands.append('*SecondaryVertexTagInfo*_*_*_*')
    output_commands.append('*TrackIPTagInfo*_*_*_*')
    output_commands.append('*SoftLeptonTagInfo*_*_*_*')
    output_commands.append('*_ak5PFJets_*_*')
    output_commands.append('*_ak5PFchsJets_*_*')

    ########################
    ##        MET         ##
    ########################

    # Use PFMEt
    mettools.addPfMET(process)

    # We cut out a lot of the junky taus and jets - but we need these
    # to correctly apply the MET uncertainties.  So, let's make a
    # non-cleaned version of the jet and tau sequence.
    process.jetsForMetSyst = helpers.cloneProcessingSnippet(
        process, process.customizeJetSequence, 'ForMETSyst')
    process.tausForMetSyst = helpers.cloneProcessingSnippet(
        process, process.customizeTauSequence, 'ForMETSyst')
    # Don't apply any cut for these
    process.patTauGarbageRemovalForMETSyst.cut = ''
    process.patJetGarbageRemovalForMETSyst.cut = ''
    process.tuplize += process.jetsForMetSyst
    process.tuplize += process.tausForMetSyst
    # We have to make our clone of cleanPatTaus separately, since e/mu
    # cleaning is applied - therefore it isn't in the customizeTausSequence.
    process.cleanPatTausForMETSyst = process.cleanPatTaus.clone(
        src=cms.InputTag(process.cleanPatTaus.src.value() + "ForMETSyst"))
    process.cleanPatTausForMETSyst.preselection = ''
    process.cleanPatTausForMETSyst.finalCut = ''
    process.patTausEmbedJetInfoForMETSyst.jetSrc = \
        final_jet_collection.value() + "ForMETSyst"
    process.tuplize += process.cleanPatTausForMETSyst

    # Setup MET production
    process.load("FinalStateAnalysis.PatTools.patMETProduction_cff")
    # The MET systematics depend on all other systematics
    process.systematicsMET.tauSrc = cms.InputTag("cleanPatTausForMETSyst")
    process.systematicsMET.muonSrc = cms.InputTag("cleanPatMuons")
    process.systematicsMET.electronSrc = cms.InputTag("cleanPatElectrons")

    final_met_collection = chain_sequence(process.customizeMETSequence,
                                          "patMETsPF")
    process.tuplize += process.customizeMETSequence
    process.patMETsPF.addGenMET = bool(isMC)
    output_commands.append('*_%s_*_*' % final_met_collection.value())

    # Make a version with the MVA MET reconstruction method
    process.load("FinalStateAnalysis.PatTools.met.mvaMetOnPatTuple_cff")
    process.tuplize += process.pfMEtMVAsequence
    mva_met_sequence = helpers.cloneProcessingSnippet(
        process, process.customizeMETSequence, "MVA")
    final_mvamet_collection = chain_sequence(mva_met_sequence, "patMEtMVA")
    process.tuplize += mva_met_sequence
    output_commands.append('*_%s_*_*' % final_mvamet_collection.value())

    # Keep all the data formats needed for the systematics
    output_commands.append('recoLeafCandidates_*_*_%s' % process.name_())
    # We can drop to jet and tau MET specific products. They were only used for
    # computation of the MET numbers.
    output_commands.append('drop recoLeafCandidates_*ForMETSyst_*_%s' %
                           process.name_())

    ########################
    ##      PHOTONS       ##
    ########################

    #alter the photon matching to accept various fakes
    # and sort matches by d-pt-rel
    if isMC:
        process.photonMatch = cms.EDProducer(
            "MCMatcherByPt",
            src=cms.InputTag("photons"),
            maxDPtRel=cms.double(100.0),
            mcPdgId=cms.vint32(),
            mcStatus=cms.vint32(1),
            resolveByMatchQuality=cms.bool(False),
            maxDeltaR=cms.double(0.3),
            checkCharge=cms.bool(False),
            resolveAmbiguities=cms.bool(True),
            matched=cms.InputTag("genParticles"))

    # Setup pat::Photon Production
    process.load("FinalStateAnalysis.PatTools.patPhotonProduction_cff")
    final_photon_collection = chain_sequence(process.customizePhotonSequence,
                                             "selectedPatPhotons")
    #setup PHOSPHOR for a specific dataset
    if cmssw_major_version() == 4:  # for now 2011 = CMSSW42X
        process.patPhotonPHOSPHOREmbedder.year = cms.uint32(2011)
    else:  # 2012 is 5YX
        process.patPhotonPHOSPHOREmbedder.year = cms.uint32(2012)
    process.patPhotonPHOSPHOREmbedder.isMC = cms.bool(bool(isMC))
    #inject photons into pat sequence
    process.customizePhotonSequence.insert(0, process.selectedPatPhotons)
    process.patDefaultSequence.replace(process.selectedPatPhotons,
                                       process.customizePhotonSequence)
    process.cleanPatPhotons.src = final_photon_collection

    ########################
    ##      TRIGGER       ##
    ########################

    trigtools.switchOnTrigger(process)

    #configure the PAT trigger
    if kwargs['HLTprocess']:
        process.patTrigger.processName = cms.string(kwargs['HLTprocess'])
        process.patTriggerEvent.processName = cms.string(kwargs['HLTprocess'])

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

    output_commands.append('*_cleanPatTaus_*_*')
    output_commands.append('*_cleanPatElectrons_*_*')
    output_commands.append('*_cleanPatMuons_*_*')
    output_commands.append('*_cleanPatPhotons_*_*')

    ########################
    ##                    ##
    ##        FSA         ##
    ##                    ##
    ########################

    # Now build the PATFinalStateLS object, which holds LumiSection info.
    process.load(
        "FinalStateAnalysis.PatTools.finalStates.patFinalStateLSProducer_cfi")
    process.tuplize += process.finalStateLS
    output_commands.append('*_finalStateLS_*_*')
    if isMC:
        process.finalStateLS.xSec = kwargs['xSec']

    # Tell the framework to shut up!
    process.load("FWCore.MessageLogger.MessageLogger_cfi")
    process.MessageLogger.cerr.FwkReport.reportEvery = 1000

    # Which collections are used to build the final states
    fs_daughter_inputs = {
        'electrons': 'cleanPatElectrons',
        'muons': 'cleanPatMuons',
        'taus': 'cleanPatTaus',
        'photons': 'cleanPatPhotons',
        'jets': 'selectedPatJets',
        'pfmet': final_met_collection,
        'mvamet': final_mvamet_collection,
    }

    # Setup all the PATFinalState objects
    produce_final_states(process,
                         fs_daughter_inputs,
                         output_commands,
                         process.tuplize,
                         kwargs['puTag'],
                         zzMode=kwargs.get('zzMode', False))

    return process.tuplize, output_commands
def configurePatTuple(process, isMC=True, **kwargs):

    # Stuff we always keep
    output_commands = [
        #        '*',
        '*_addPileupInfo_*_*',
        'edmMergeableCounter_*_*_*',
        '*_lumiProducer_*_*',
        '*_particleFlow_*_*',
        '*_offlineBeamSpot_*_*',
        '*_generalTracks_*_*',
        '*_electronGsfTracks_*_*',
        '*_offlinePrimaryVertices*_*_*',
        '*_ak5GenJets_*_*',
        '*_hltTriggerSummaryAOD_*_*',
        'edmTriggerResults_TriggerResults_*_%s' % process.name_(),
        '*_MEtoEDMConverter*_*_%s' % process.name_(),
        'LHEEventProduct_*_*_*',
        'GenEventInfoProduct_generator_*_*',
        '*_kt6PFJetsForRhoComputationVoronoi_rho_*',
        '*_kt6PFJetsForIso_rho_*',
        '*_kt6PFJets_rho_*',
        '*_kt6PFJetsCentralHZGPho_rho_*',
        '*_kt6PFJetsCentralHZGEle_rho_*',
        '*_kt6PFJetsCentralHZGMu_rho_*',
        '*_kt6PFJetsCentralNeutralHZGMu_rho_*',
        '*_kt6PFJetsCentral_rho_*',
        '*_kt6PFJetsCentralNeutral_rho_*',  #for zz muons
        '*_photonCore_*_*',
        # for Zmumu -> embedded samples
        '*_generator_weight_*',  # 2k11
        "GenFilterInfo_generator_minVisPtFilter_*",  #2k12
        '*_genDaughters_*_*',
        '*_boosted*_*_*',
        '*_tmfTracks_*_*',
    ]
    # Define our patTuple production sequence
    process.tuplize = cms.Sequence()
    # Only keep interesting genParticles
    process.load("FinalStateAnalysis.RecoTools.genParticleTrimmer_cfi")
    process.genParticles = process.prunedGenParticles.clone()
    if isMC:
        #process.tuplize += process.genParticles
        #output_commands.append('*_genParticles_*_%s' % process.name_())
        output_commands.append('*_genParticles_*_*')

    output_commands.append('*_tauGenJetsSelectorAllHadrons_*_*')
    output_commands.append('*_tauGenJets_*_*')
    output_commands.append('*_ak5GenJets_*_*')
    # Select vertices
    process.load("FinalStateAnalysis.RecoTools.vertexSelection_cff")
    output_commands.append('*_selectedPrimaryVertex_*_*')
    output_commands.append('*_selectPrimaryVerticesQuality_*_*')
    process.tuplize += process.selectPrimaryVertices

    # Run the ZZ recipe for rho
    from RecoJets.JetProducers.kt4PFJets_cfi import kt4PFJets \
            as zzCantDoAnythingRight

    process.kt6PFJetsForIso = zzCantDoAnythingRight.clone(
        rParam=cms.double(0.6),
        doAreaFastjet=cms.bool(True),
        doRhoFastjet=cms.bool(True),
        Rho_EtaMax=cms.double(2.5),
        Ghost_EtaMax=cms.double(2.5),
    )
    process.tuplize += process.kt6PFJetsForIso

    # Standard services
    process.load('Configuration.StandardSequences.Services_cff')
    # tack on seeds for FSA PATTuple modules
    add_fsa_random_seeds(process)

    if cmssw_major_version() == 5 and cmssw_minor_version() >= 3:
        process.load('Configuration.Geometry.GeometryIdeal_cff')
    else:
        process.load('Configuration.StandardSequences.GeometryIdeal_cff')

    process.load('Configuration.StandardSequences.MagneticField_cff')
    process.load(
        'Configuration.StandardSequences.FrontierConditions_GlobalTag_cff')

    # Rerun tau ID
    if cmssw_major_version() == 4:
        process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
        # Optimization - remove PFTauTagInfo compatibility layer
        process.recoTauClassicHPSSequence.remove(
            process.pfRecoTauTagInfoProducer)
        process.recoTauClassicHPSSequence.remove(
            process.ak5PFJetTracksAssociatorAtVertex)
        assert (process.combinatoricRecoTaus.modifiers[3].name.value() ==
                'TTIworkaround')
        del process.combinatoricRecoTaus.modifiers[3]
        # Don't build junky taus below 19 GeV
        process.combinatoricRecoTaus.builders[0].minPtToBuild = cms.double(17)
        process.tuplize += process.recoTauClassicHPSSequence
    else:
        # We can run less tau stuff in 52, since HPS taus already built.
        process.load("RecoTauTag.Configuration.updateHPSPFTaus_cff")
        process.tuplize += process.updateHPSPFTaus

    ## Run rho computation.  Only necessary in 42X
    if cmssw_major_version() == 4:
        from RecoJets.Configuration.RecoPFJets_cff import kt6PFJets
        kt6PFJets.Rho_EtaMax = cms.double(4.4)
        kt6PFJets.doRhoFastjet = True
        process.kt6PFJets = kt6PFJets
        process.tuplize += process.kt6PFJets

    # In 4_X we have to rerun ak5PFJets with area computation enabled.
    if cmssw_major_version() == 4:
        process.load("RecoJets.Configuration.RecoPFJets_cff")
        process.ak5PFJets.doAreaFastjet = True
        process.tuplize += process.ak5PFJets
        # Only keep the new ak5PFJets
        output_commands.append('*_ak5PFJets_*_%s' % process.name_())
    else:
        # Just keep the normal ones
        output_commands.append('*_ak5PFJets_*_*')

    # In the embedded samples, we need to re-run the b-tagging
    if kwargs['embedded']:
        process.load('RecoBTag/Configuration/RecoBTag_cff')
        process.load('RecoJets/JetAssociationProducers/ak5JTA_cff')
        process.ak5JetTracksAssociatorAtVertex.jets = cms.InputTag("ak5PFJets")
        process.ak5JetTracksAssociatorAtVertex.tracks = cms.InputTag(
            "tmfTracks")
        process.tuplize += process.ak5JetTracksAssociatorAtVertex
        process.tuplize += process.btagging

    # Run pat default sequence
    process.load("PhysicsTools.PatAlgos.patSequences_cff")
    # Embed PF Isolation in electrons & muons
    pfTools.usePFIso(process)
    # Setup H2Tau custom iso definitions
    setup_h2tau_iso(process)
    # Setup hZg custom iso definitions
    add_hZg_iso_needs(process)

    # Use POG recommendations for (these) electron Isos
    process.elPFIsoValueGamma04PFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueGamma04NoPFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueCharged04PFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.015)')
    process.elPFIsoValueCharged04NoPFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.015)')

    # Unembed junk
    process.patMuons.embedCaloMETMuonCorrs = False
    process.patMuons.embedTcMETMuonCorrs = False
    process.patMuons.embedTrack = True
    process.patMuons.pvSrc = cms.InputTag("selectedPrimaryVertex")

    # Do extra electron ID
    process.load("FinalStateAnalysis.PatTools.electrons.electronID_cff")
    process.tuplize += process.recoElectronID
    process.patElectrons.electronIDSources = process.electronIDSources
    process.patElectrons.embedTrack = True

    # Now run PAT
    process.tuplize += process.patDefaultSequence

    # Add FSR photons for ZZ analysis
    process.load("FinalStateAnalysis.PatTools.fsrPhotons_cff")
    process.tuplize += process.fsrPhotonSequence

    # Use HPS taus
    tautools.switchToPFTauHPS(process)
    # Disable tau IsoDeposits
    process.patDefaultSequence.remove(process.patPFTauIsolation)
    process.patTaus.isoDeposits = cms.PSet()
    process.patTaus.userIsolation = cms.PSet()

    # Disable gen match embedding - we keep it in the ntuple
    process.patMuons.embedGenMatch = False
    process.patElectrons.embedGenMatch = False
    process.patTaus.embedGenMatch = False
    process.patTaus.embedGenJetMatch = False

    # Use PFJets and turn on JEC
    jec = ['L1FastJet', 'L2Relative', 'L3Absolute']
    # If we are running on data (not MC), or embedded sample,
    # apply the MC-DATA residual correction.
    if not isMC or kwargs['embedded']:
        jec.extend(['L2L3Residual'])

    # Define options for BTagging - these are release dependent.
    btag_options = {'doBTagging': True}
    if cmssw_major_version() == 5:
        btag_options['btagInfo'] = [
            'impactParameterTagInfos', 'secondaryVertexTagInfos',
            'softMuonTagInfos', 'secondaryVertexNegativeTagInfos'
        ]
        btag_options['btagdiscriminators'] = [
            'trackCountingHighEffBJetTags',
            'simpleSecondaryVertexHighEffBJetTags',
            'combinedSecondaryVertexMVABJetTags',
            'combinedSecondaryVertexBJetTags',
        ]

    # Use AK5 PFJets
    jettools.switchJetCollection(
        process,
        cms.InputTag('ak5PFJets'),
        doJTA=False,
        jetCorrLabel=('AK5PF', jec),
        #jetCorrLabel = None,
        doType1MET=False,
        doJetID=True,
        genJetCollection=cms.InputTag("ak5GenJets"),
        **btag_options)
    process.patJets.embedPFCandidates = False
    process.patJets.embedCaloTowers = False
    process.patJets.embedGenJetMatch = False
    process.patJets.addAssociatedTracks = False
    process.patJets.embedGenPartonMatch = False
    #process.patJetCorrFactors.useRho = True
    ## Let's use the same rho as in the TauID, so we don't need to do it twice.
    #process.patJetCorrFactors.rho = cms.InputTag(
    #"kt6PFJetsForRhoComputationVoronoi", "rho")

    # Use PFMEt
    mettools.addPfMET(process)
    if not isMC:
        coreTools.runOnData(process)
        process.patMETsPF.addGenMET = False
    output_commands.append('*_selectedPatJets_*_*')

    # Customize/embed all our sequences
    process.load("FinalStateAnalysis.PatTools.patJetProduction_cff")
    # We have to keep all jets (for the MVA MET...)
    process.patJetGarbageRemoval.cut = 'pt > 0'

    final_jet_collection = chain_sequence(process.customizeJetSequence,
                                          "patJets")
    process.customizeJetSequence.insert(0, process.patJets)
    # Make it a "complete" sequence
    process.customizeJetSequence += process.selectedPatJets
    # We can't mess up the selected pat jets because the taus use them.
    process.selectedPatJets.src = final_jet_collection
    process.patDefaultSequence.replace(process.patJets,
                                       process.customizeJetSequence)

    # Produce the electron collections
    process.load("FinalStateAnalysis.PatTools.patElectronProduction_cff")
    final_electron_collection = chain_sequence(
        process.customizeElectronSequence, "selectedPatElectrons")
    process.tuplize += process.customizeElectronSequence
    process.customizeElectronSequence.insert(0, process.selectedPatElectrons)
    process.patDefaultSequence.replace(process.selectedPatElectrons,
                                       process.customizeElectronSequence)
    # We have to do the pat Jets before the pat electrons since we embed them
    process.customizeElectronSequence.insert(0, process.selectedPatJets)
    process.cleanPatElectrons.src = final_electron_collection
    #setup the energy regression for the specific dataset
    process.patElectronEnergyCorrections.isMC = cms.bool(bool(isMC))
    process.patElectronEnergyCorrections.isAOD = \
                                               cms.bool(bool(kwargs['isAOD']))
    process.patElectronEnergyCorrections.dataSet = \
                                     cms.string(kwargs['calibrationTarget'])

    process.load("FinalStateAnalysis.PatTools.patMuonProduction_cff")
    final_muon_collection = chain_sequence(process.customizeMuonSequence,
                                           "selectedPatMuons")
    process.customizeMuonSequence.insert(0, process.selectedPatMuons)
    process.patDefaultSequence.replace(process.selectedPatMuons,
                                       process.customizeMuonSequence)
    process.cleanPatMuons.src = final_muon_collection
    process.patMuonRochesterCorrectionEmbedder.isMC = cms.bool(bool(isMC))

    process.load("FinalStateAnalysis.PatTools.patTauProduction_cff")
    final_tau_collection = chain_sequence(process.customizeTauSequence,
                                          "selectedPatTaus")
    # Inject into the pat sequence
    process.customizeTauSequence.insert(0, process.selectedPatTaus)
    process.patDefaultSequence.replace(process.selectedPatTaus,
                                       process.customizeTauSequence)
    process.cleanPatTaus.src = final_tau_collection
    # Remove muons and electrons
    process.cleanPatTaus.checkOverlaps.muons.requireNoOverlaps = False
    process.cleanPatTaus.checkOverlaps.electrons.requireNoOverlaps = False
    # Apply a loose preselection
    process.cleanPatTaus.preselection = 'abs(eta) < 2.5 & pt > 17'
    # Don't apply any "final" cut
    process.cleanPatTaus.finalCut = ''

    # Setup pat::Photon Production
    process.load("FinalStateAnalysis.PatTools.patPhotonProduction_cff")
    final_photon_collection = chain_sequence(process.customizePhotonSequence,
                                             "selectedPatPhotons")
    #inject photons into pat sequence
    process.customizePhotonSequence.insert(0, process.selectedPatPhotons)
    process.patDefaultSequence.replace(process.selectedPatPhotons,
                                       process.customizePhotonSequence)
    process.cleanPatPhotons.src = final_photon_collection

    # Setup MET production
    process.load("FinalStateAnalysis.PatTools.patMETProduction_cff")
    final_met_collection = chain_sequence(process.customizeMETSequence,
                                          "patMETsPF")
    process.tuplize += process.customizeMETSequence
    # The MET systematics depend on all other systematics
    process.systematicsMET.tauSrc = cms.InputTag("cleanPatTaus")
    process.systematicsMET.muonSrc = cms.InputTag("cleanPatMuons")
    process.systematicsMET.electronSrc = cms.InputTag("cleanPatElectrons")

    # Keep all the data formats needed for the systematics
    output_commands.append('recoLeafCandidates_*_*_%s' % process.name_())

    # Define the default lepton cleaning
    process.cleanPatElectrons.preselection = cms.string('pt > 5')
    process.cleanPatElectrons.checkOverlaps.muons.requireNoOverlaps = False
    # Make sure we don't kill any good taus by calling them electrons
    # Note that we don't actually remove these overlaps.
    process.cleanPatElectrons.checkOverlaps.taus = cms.PSet(
        src=final_tau_collection,
        algorithm=cms.string("byDeltaR"),
        preselection=cms.string(
            "tauID('decayModeFinding') > 0.5 &&"
            "tauID('byLooseCombinedIsolationDeltaBetaCorr') > 0.5 &&"
            "tauID('againstElectronLoose') > 0.5 && "
            "pt > 10"),
        deltaR=cms.double(0.1),
        checkRecoComponents=cms.bool(False),
        pairCut=cms.string(""),
        requireNoOverlaps=cms.bool(False),
    )

    output_commands.append('*_cleanPatTaus_*_*')
    output_commands.append('*_cleanPatElectrons_*_*')
    output_commands.append('*_cleanPatMuons_*_*')
    output_commands.append('*_cleanPatPhotons_*_*')
    output_commands.append('*_%s_*_*' % final_met_collection.value())

    trigtools.switchOnTrigger(process)

    # Now build the PATFinalStateLS object, which holds LumiSection info.
    process.load(
        "FinalStateAnalysis.PatTools.finalStates.patFinalStateLSProducer_cfi")
    process.tuplize += process.finalStateLS
    output_commands.append('*_finalStateLS_*_*')
    if isMC:
        process.finalStateLS.xSec = kwargs['xSec']

    # Tell the framework to shut up!
    process.load("FWCore.MessageLogger.MessageLogger_cfi")
    process.MessageLogger.cerr.FwkReport.reportEvery = 1000

    # Which collections are used to build the final states
    fs_daughter_inputs = {
        'electrons': 'cleanPatElectrons',
        'muons': 'cleanPatMuons',
        'taus': 'cleanPatTaus',
        'photons': 'cleanPatPhotons',
        'jets': 'selectedPatJets',
        'met': final_met_collection,
    }

    # Setup all the PATFinalState objects
    produce_final_states(process, fs_daughter_inputs, output_commands,
                         process.tuplize, kwargs['puTag'])

    return process.tuplize, output_commands
Exemple #19
0
def CompactSkim(process,
                inFileNames,
                outFileName,
                Global_Tag='auto:run2_mc',
                MC=True,
                Filter=True):

    process.load('Configuration.StandardSequences.Services_cff')
    process.load('SimGeneral.HepPDTESSource.pythiapdt_cfi')
    process.load('FWCore.MessageService.MessageLogger_cfi')
    process.load('Configuration.EventContent.EventContent_cff')
    process.load('Configuration.StandardSequences.GeometryRecoDB_cff')
    process.load(
        'Configuration.StandardSequences.MagneticField_AutoFromDBCurrent_cff')
    process.load('Configuration.StandardSequences.EndOfProcess_cff')
    process.load(
        'Configuration.StandardSequences.FrontierConditions_GlobalTag_condDBv2_cff'
    )

    process.MessageLogger.cerr.FwkReport.reportEvery = 100
    process.options = cms.untracked.PSet(wantSummary=cms.untracked.bool(False))
    process.options.allowUnscheduled = cms.untracked.bool(True)
    process.source = cms.Source('PoolSource',
                                fileNames=cms.untracked.vstring(inFileNames))
    process.maxEvents = cms.untracked.PSet(input=cms.untracked.int32(-1))

    from Configuration.AlCa.GlobalTag_condDBv2 import GlobalTag
    process.GlobalTag = GlobalTag(process.GlobalTag, Global_Tag, '')

    # make patCandidates, select and clean them
    process.load('PhysicsTools.PatAlgos.producersLayer1.patCandidates_cff')
    process.load(
        'PhysicsTools.PatAlgos.selectionLayer1.selectedPatCandidates_cff')
    process.load('PhysicsTools.PatAlgos.cleaningLayer1.cleanPatCandidates_cff')
    process.patMuons.embedTrack = True

    process.selectedPatMuons.cut = cms.string(
        'muonID(\"TMOneStationTight\")'
        ' && abs(innerTrack.dxy) < 0.3'
        ' && abs(innerTrack.dz)  < 20.'
        ' && innerTrack.hitPattern.trackerLayersWithMeasurement > 5'
        ' && innerTrack.hitPattern.pixelLayersWithMeasurement > 0'
        ' && innerTrack.quality(\"highPurity\")')

    #make patTracks
    from PhysicsTools.PatAlgos.tools.trackTools import makeTrackCandidates
    makeTrackCandidates(
        process,
        label='TrackCands',  # output collection
        tracks=cms.InputTag('generalTracks'),  # input track collection
        particleType='pi+',  # particle type (for assigning a mass)
        preselection='pt > 0.7',  # preselection cut on candidates
        selection='pt > 0.7',  # selection on PAT Layer 1 objects
        isolation={},  # isolations to use (set to {} for None)
        isoDeposits=[],
        mcAs=None  # replicate MC match as the one used for Muons
    )
    process.patTrackCands.embedTrack = True

    # dimuon = Onia2MUMU
    process.load('HeavyFlavorAnalysis.Onia2MuMu.onia2MuMuPAT_cfi')
    process.onia2MuMuPAT.muons = cms.InputTag('cleanPatMuons')
    process.onia2MuMuPAT.primaryVertexTag = cms.InputTag(
        'offlinePrimaryVertices')
    process.onia2MuMuPAT.beamSpotTag = cms.InputTag('offlineBeamSpot')

    process.onia2MuMuPATCounter = cms.EDFilter(
        'CandViewCountFilter',
        src=cms.InputTag('onia2MuMuPAT'),
        minNumber=cms.uint32(1),
        filter=cms.bool(True))

    # reduce MC genParticles a la miniAOD
    process.load('PhysicsTools.PatAlgos.slimming.genParticles_cff')
    process.packedGenParticles.inputVertices = cms.InputTag(
        'offlinePrimaryVertices')

    # make photon candidate conversions for P-wave studies
    process.load(
        'HeavyFlavorAnalysis.Onia2MuMu.OniaPhotonConversionProducer_cfi')

    # add v0 with tracks embed
    process.load('HeavyFlavorAnalysis.Onia2MuMu.OniaAddV0TracksProducer_cfi')

    # Pick branches you want to keep
    SlimmedEventContent = [
        'keep recoVertexs_offlinePrimaryVertices_*_*',
        'keep *_inclusiveSecondaryVertices_*_*', 'keep *_offlineBeamSpot_*_*',
        'keep *_TriggerResults_*_HLT', 'keep *_gtDigis_*_RECO',
        'keep *_cleanPatTrackCands_*_*', 'keep *_PhotonCandidates_*_*',
        'keep *_onia2MuMuPAT_*_*', 'keep *_generalV0Candidates_*_*',
        'keep *_oniaV0Tracks_*_*', 'keep PileupSummaryInfos_*_*_*'
    ]

    if not MC:
        from PhysicsTools.PatAlgos.tools.coreTools import runOnData
        runOnData(process, outputModules=[])
    else:
        SlimmedEventContent += [
            'keep patPackedGenParticles_packedGenParticles_*_*',
            'keep recoGenParticles_prunedGenParticles_*_*',
            'keep GenFilterInfo_*_*_*',
            'keep GenEventInfoProduct_generator_*_*',
            'keep GenRunInfoProduct_*_*_*'
        ]

    process.FilterOutput = cms.Path(process.onia2MuMuPATCounter)

    process.out = cms.OutputModule(
        'PoolOutputModule',
        fileName=cms.untracked.string(outFileName),
        outputCommands=cms.untracked.vstring('drop *', *SlimmedEventContent),
        SelectEvents=cms.untracked.PSet(
            SelectEvents=cms.vstring('FilterOutput'))
        if Filter else cms.untracked.PSet())

    process.outpath = cms.EndPath(process.out)
Exemple #20
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    process.load('PhysicsTools.PatAlgos.producersLayer1.metProducer_cff')
    process.load('PhysicsTools.PatAlgos.selectionLayer1.jetSelector_cfi')
    process.patCandidates = cms.Sequence(process.makePatJets +
                                         process.makePatMETs)
    process.selectedPatCandidates = cms.Sequence(process.selectedPatJets)
    process.patDefaultSequence = cms.Sequence(process.patCandidates *
                                              process.selectedPatCandidates)
    process.load('RecoJets.Configuration.RecoPFJets_cff')
    from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection, runBTagging
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData

    #---- Choose which jet correction levels to apply
    jetcorrlabels = ['L1FastJet', 'L2Relative', 'L3Absolute']
    if isData:
        #---- For data we need to remove generator-level matching processes
        runOnData(process, ['Jets', 'METs'], "", None, [])
        jetcorrlabels.append('L2L3Residual')

    #---- Configure the addJetCollection tool
    #---- This process will make corrected jets with b-tagging included, and will make Type1-corrected MET
    process.ak5PFJets.doAreaFastjet = True
    addJetCollection(
        process,
        cms.InputTag('ak5PFJets'),
        'AK5',
        'PFCorr',
        doJTA=True,
        doBTagging=True,
        jetCorrLabel=('AK5PF', cms.vstring(jetcorrlabels)),
        doType1MET=True,
        doL1Cleaning=False,
def miniAOD_customizeData(process):
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData( process, outputModules = [] )
                   ## particleType = 'pi+',                         # particle type (for assigning a mass)
                    particleType = 'K+',                         # particle type (for assigning a mass)
                    preselection = 'pt > 0.4',                    # preselection cut on candidates
                    selection    = 'pt > 0.4',                    # selection on PAT Layer 1 objects
                    isolation    = {},                            # isolations to use (set to {} for None)
                    isoDeposits  = [],
                    mcAs         = None                           # replicate MC match as the one used for Muons
                    )



process.load('PhysicsTools.PatAlgos.slimming.genParticles_cff')
process.packedGenParticles.inputVertices = cms.InputTag('offlinePrimaryVertices')

from PhysicsTools.PatAlgos.tools.coreTools import runOnData
runOnData( process, outputModules = [] )

process.ntuple = cms.EDAnalyzer(
    'BsToPhiMuMu',

    OutputFileName = cms.string("BsToPhiMuMu_2016.root"),
    BuildBsToPhiMuMu = cms.untracked.bool(True), 

    MuonMass = cms.untracked.double(0.10565837), 
    MuonMassErr = cms.untracked.double(3.5e-9),   
    KaonMass = cms.untracked.double(0.493677), 
    KaonMassErr = cms.untracked.double(1.6e-5),
    BsMass = cms.untracked.double(5.36677),          ## put the Bs Mass (pdg value)

    # labels
    GenParticlesLabel = cms.InputTag("genParticles"),
Exemple #23
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if not useHFCandidates:
    runMETCorrectionsAndUncertainties(
        process,
        #isData=runOnData,
        pfCandColl=cms.InputTag("noHFCands"),
        reclusterJets=True,  #needed for NoHF
        recoMetFromPFCs=True,  #needed for NoHF
        postfix="NoHF")

if redoPuppi:
    from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
    makePuppiesFromMiniAOD(process)

    runMETCorrectionsAndUncertainties(
        process,
        #isData=runOnData,
        pfCandColl=cms.InputTag("puppiForMET"),
        recoMetFromPFCs=True,
        reclusterJets=True,
        jetFlavor="AK4PFPuppi",
        postfix="Puppi")

if runOnData:
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData(process)

process.out.outputCommands = cms.untracked.vstring("keep *_patPFMet*_*_*", )
process.out.fileName = cms.untracked.string('corMETMiniAOD.root')

process.MINIAODSIMoutput_step = cms.EndPath(process.out)
Exemple #24
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def CompactSkim(process,inFileNames,outFileName,Global_Tag='auto:run2_mc',MC=True,Filter=True):

   patAlgosToolsTask = getPatAlgosToolsTask(process)

   process.load('Configuration.StandardSequences.Services_cff')
   process.load('SimGeneral.HepPDTESSource.pythiapdt_cfi')
   process.load('FWCore.MessageService.MessageLogger_cfi')
   process.load('Configuration.EventContent.EventContent_cff')
   process.load('Configuration.StandardSequences.GeometryRecoDB_cff')
   process.load('Configuration.StandardSequences.MagneticField_AutoFromDBCurrent_cff')
   process.load('Configuration.StandardSequences.EndOfProcess_cff')
   patAlgosToolsTask.add(process.MEtoEDMConverter)
   process.load('Configuration.StandardSequences.FrontierConditions_GlobalTag_condDBv2_cff')

   process.MessageLogger.cerr.FwkReport.reportEvery = 100
   process.options = cms.untracked.PSet( wantSummary = cms.untracked.bool(False) )
   process.source = cms.Source('PoolSource', fileNames = cms.untracked.vstring(inFileNames))
   process.maxEvents = cms.untracked.PSet( input = cms.untracked.int32(-1) )

   from Configuration.AlCa.GlobalTag_condDBv2 import GlobalTag
   process.GlobalTag = GlobalTag(process.GlobalTag, Global_Tag, '')

   # make patCandidates, select and clean them
   process.load('PhysicsTools.PatAlgos.producersLayer1.patCandidates_cff')
   patAlgosToolsTask.add(process.patCandidatesTask)
   process.load('PhysicsTools.PatAlgos.selectionLayer1.selectedPatCandidates_cff')
   patAlgosToolsTask.add(process.selectedPatCandidatesTask)
   process.load('PhysicsTools.PatAlgos.cleaningLayer1.cleanPatCandidates_cff')
   patAlgosToolsTask.add(process.cleanPatCandidatesTask)
   process.patMuons.embedTrack  = True

   process.selectedPatMuons.cut = cms.string('muonID(\"TMOneStationTight\")'
                    ' && abs(innerTrack.dxy) < 0.3'
                    ' && abs(innerTrack.dz)  < 20.'
                    ' && innerTrack.hitPattern.trackerLayersWithMeasurement > 5'
                    ' && innerTrack.hitPattern.pixelLayersWithMeasurement > 0'
                    ' && innerTrack.quality(\"highPurity\")'
                    )

   #make patTracks
   from PhysicsTools.PatAlgos.tools.trackTools import makeTrackCandidates
   makeTrackCandidates(process,
                       label        = 'TrackCands',                  # output collection
                       tracks       = cms.InputTag('generalTracks'), # input track collection
                       particleType = 'pi+',                         # particle type (for assigning a mass)
                       preselection = 'pt > 0.7',                    # preselection cut on candidates
                       selection    = 'pt > 0.7',                    # selection on PAT Layer 1 objects
                       isolation    = {},                            # isolations to use (set to {} for None)
                       isoDeposits  = [],
                       mcAs         = None                           # replicate MC match as the one used for Muons
   )
   process.patTrackCands.embedTrack = True

   # dimuon = Onia2MUMU
   process.load('HeavyFlavorAnalysis.Onia2MuMu.onia2MuMuPAT_cfi')
   patAlgosToolsTask.add(process.onia2MuMuPAT)
   process.onia2MuMuPAT.muons=cms.InputTag('cleanPatMuons')
   process.onia2MuMuPAT.primaryVertexTag=cms.InputTag('offlinePrimaryVertices')
   process.onia2MuMuPAT.beamSpotTag=cms.InputTag('offlineBeamSpot')

   process.onia2MuMuPATCounter = cms.EDFilter('CandViewCountFilter',
      src = cms.InputTag('onia2MuMuPAT'),
      minNumber = cms.uint32(1),
      filter = cms.bool(True)
   )

   # reduce MC genParticles a la miniAOD
   process.load('PhysicsTools.PatAlgos.slimming.genParticles_cff')
   patAlgosToolsTask.add(process.genParticlesTask)
   process.packedGenParticles.inputVertices = cms.InputTag('offlinePrimaryVertices')

   # make photon candidate conversions for P-wave studies
   process.load('HeavyFlavorAnalysis.Onia2MuMu.OniaPhotonConversionProducer_cfi')
   patAlgosToolsTask.add(process.PhotonCandidates)

   # add v0 with tracks embed
   process.load('HeavyFlavorAnalysis.Onia2MuMu.OniaAddV0TracksProducer_cfi')
   patAlgosToolsTask.add(process.oniaV0Tracks)

   # Pick branches you want to keep
   SlimmedEventContent = [
                     'keep recoVertexs_offlinePrimaryVertices_*_*',
                     'keep *_inclusiveSecondaryVertices_*_*',
                     'keep *_offlineBeamSpot_*_*',
                     'keep *_TriggerResults_*_HLT',
                     'keep *_gtDigis_*_RECO',
                     'keep *_cleanPatTrackCands_*_*',
                     'keep *_PhotonCandidates_*_*',
                     'keep *_onia2MuMuPAT_*_*',
                     'keep *_generalV0Candidates_*_*',
                     'keep *_oniaV0Tracks_*_*',
                     'keep PileupSummaryInfos_*_*_*'
   ]

   if not MC:
      from PhysicsTools.PatAlgos.tools.coreTools import runOnData
      runOnData( process, outputModules = [] )
   else :
      SlimmedEventContent += [
                     'keep patPackedGenParticles_packedGenParticles_*_*',
                     'keep recoGenParticles_prunedGenParticles_*_*',
                     'keep GenFilterInfo_*_*_*',
                     'keep GenEventInfoProduct_generator_*_*',
                     'keep GenRunInfoProduct_*_*_*'
      ]

   process.FilterOutput = cms.Path(process.onia2MuMuPATCounter)

   process.out = cms.OutputModule('PoolOutputModule',
      fileName = cms.untracked.string(outFileName),
      outputCommands = cms.untracked.vstring('drop *', *SlimmedEventContent),
      SelectEvents = cms.untracked.PSet(SelectEvents = cms.vstring('FilterOutput')) if Filter else cms.untracked.PSet()
   )
   
   process.outpath = cms.EndPath(process.out, patAlgosToolsTask)
Exemple #25
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def miniAOD_customizeData(process):
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData( process, outputModules = [] )
    process.load("RecoCTPPS.TotemRPLocal.ctppsLocalTrackLiteProducer_cff")
    task = getPatAlgosToolsTask(process)
    task.add(process.ctppsLocalTrackLiteProducer)
def configurePatTuple(process, isMC=True, **kwargs):
    # Stuff we always keep
    output_commands = [
        '*_addPileupInfo_*_*',
        'edmMergeableCounter_*_*_*',
        '*_lumiProducer_*_*',
        '*_particleFlow_*_*',
        '*_offlineBeamSpot_*_*',
        '*_trackCandidates_*_*',
        '*_gsfTrackCandidates_*_*',
        #'*_generalTracks_*_*',
        '*_electronGsfTracks_*_*',
        '*_offlinePrimaryVertices*_*_*',
        '*_ak5PFJets_*_*',
        '*_ak5GenJets_*_*',
        '*_hltTriggerSummaryAOD_*_*',
        'edmTriggerResults_TriggerResults_*_%s' % process.name_(),
        '*_MEtoEDMConverter*_*_%s' % process.name_(),
        'LHEEventProduct_*_*_*',
        'GenEventInfoProduct_generator_*_*',
        '*_kt6PFJetsForRhoComputationVoronoi_rho_*',
        '*_kt6PFJetsForIso_rho_*',
    ]
    # Define our patTuple production sequence
    process.tuplize = cms.Sequence()
    # Only keep interesting genParticles
    process.load("FinalStateAnalysis.RecoTools.genParticleTrimmer_cfi")
    process.genParticles = process.prunedGenParticles.clone()
    if isMC:
        #process.tuplize += process.genParticles
        #output_commands.append('*_genParticles_*_%s' % process.name_())
        output_commands.append('*_genParticles_*_*')

    output_commands.append('*_tauGenJetsSelectorAllHadrons_*_*')
    output_commands.append('*_tauGenJets_*_*')
    output_commands.append('*_ak5GenJets_*_*')
    # Select vertices
    process.load("FinalStateAnalysis.RecoTools.vertexSelection_cff")
    output_commands.append('*_selectedPrimaryVertex_*_*')
    output_commands.append('*_selectPrimaryVerticesQuality_*_*')
    process.tuplize += process.selectPrimaryVertices

    # Run the ZZ recipe for rho
    from RecoJets.JetProducers.kt4PFJets_cfi import kt4PFJets \
            as zzCantDoAnythingRight
    process.kt6PFJetsForIso = zzCantDoAnythingRight.clone(
        rParam = cms.double(0.6),
        doAreaFastjet = cms.bool(True),
        doRhoFastjet = cms.bool(True),
        Rho_EtaMax = cms.double(2.5),
        Ghost_EtaMax = cms.double(2.5),
    )
    process.tuplize += process.kt6PFJetsForIso

    # Rerun tau-ID
    process.load('Configuration/StandardSequences/Services_cff')
    process.load('Configuration/StandardSequences/GeometryIdeal_cff')
    process.load('Configuration/StandardSequences/MagneticField_cff')
    process.load('Configuration/StandardSequences/FrontierConditions_GlobalTag_cff')
    process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")

    # Optimization - remove PFTauTagInfo compatibility layer
    process.recoTauClassicHPSSequence.remove(process.pfRecoTauTagInfoProducer)
    assert(process.combinatoricRecoTaus.modifiers[3].name.value() == 'TTIworkaround')
    del process.combinatoricRecoTaus.modifiers[3]

    process.tuplize += process.recoTauClassicHPSSequence
    ## Run rho computation
    #from RecoJets.Configuration.RecoPFJets_cff import kt6PFJets
    #kt6PFJets.Rho_EtaMax = cms.double(2.5)
    #kt6PFJets.doRhoFastjet = True
    #process.kt6PFJets = kt6PFJets
    #process.tuplize += process.kt6PFJets

    # Run pat default sequence
    process.load("PhysicsTools.PatAlgos.patSequences_cff")
    # Embed PF Isolation in electrons & muons
    pfTools.usePFIso(process)
    # Custom veto cones
    process.elPFIsoValuePU04PFIdPFIso.deposits.vetos = cms.vstring()
    process.elPFIsoValueChargedAll04PFIdPFIso.deposits.vetos = cms.vstring(
        'EcalBarrel:ConeVeto(0.01)','EcalEndcaps:ConeVeto(0.015)')

    # Unembed junk
    process.patMuons.embedCaloMETMuonCorrs = False
    process.patMuons.embedTcMETMuonCorrs = False
    process.patMuons.embedTrack = True
    process.patMuons.pvSrc = cms.InputTag("selectedPrimaryVertex")

    # Do extra electron ID
    process.load("FinalStateAnalysis.PatTools.electrons.electronID_cff")
    process.tuplize += process.recoElectronID
    process.patElectrons.electronIDSources = process.electronIDSources
    process.patElectrons.embedTrack = True

    # Run EGamma electron energy calibration
    process.load("EgammaCalibratedGsfElectrons.CalibratedElectronProducers.calibratedGsfElectrons_cfi")
    process.RandomNumberGeneratorService.calibratedGsfElectrons = cms.PSet(
        initialSeed = cms.untracked.uint32(1), # A frickin billion
        engineName = cms.untracked.string('TRandom3')
    )
    process.calibratedGsfElectrons.inputDataset = kwargs['dataset']
    process.calibratedGsfElectrons.isMC = bool(isMC)
    process.calibratedGsfElectrons.isAOD = True
    process.calibratedGsfElectrons.updateEnergyError = cms.bool(True)
    # Run a sanity check on the calibration configuration.
    from FinalStateAnalysis.PatTools.electrons.patElectronEmbedCalibratedGsf_cfi \
            import validate_egamma_calib_config
    validate_egamma_calib_config(process)

    process.tuplize += process.calibratedGsfElectrons
    # Keep the calibratedGsfElectrons - we embed refs to this into the
    # pat::Electrons
    output_commands.append('*_calibratedGsfElectrons_*_*')

    # Now run PAT
    process.tuplize += process.patDefaultSequence

    # Use HPS taus
    tautools.switchToPFTauHPS(process)
    # Disable tau IsoDeposits
    process.patDefaultSequence.remove(process.patPFTauIsolation)
    process.patTaus.isoDeposits = cms.PSet()
    process.patTaus.userIsolation = cms.PSet()

    # Disable gen match embedding - we keep it in the ntuple
    process.patMuons.embedGenMatch = False
    process.patElectrons.embedGenMatch = False
    process.patTaus.embedGenMatch = False
    process.patTaus.embedGenJetMatch = False

    # Use PFJets and turn on JEC
    jec = [ 'L1FastJet', 'L2Relative', 'L3Absolute' ]
    if not isMC:
        jec.extend([ 'L2L3Residual' ])
    # Use AK5 PFJets
    jettools.switchJetCollection(process,
                                 cms.InputTag('ak5PFJets'),
                                 doJTA = False,
                                 doBTagging = True,
                                 jetCorrLabel = ('AK5PF', jec),
                                 #jetCorrLabel = None,
                                 doType1MET = False,
                                 doJetID = True,
                                 genJetCollection = cms.InputTag("ak5GenJets"))
    process.patJets.embedPFCandidates = False
    process.patJets.embedCaloTowers = False
    process.patJets.embedGenJetMatch = False
    process.patJets.addAssociatedTracks = False
    process.patJets.embedGenPartonMatch = False
    process.patJetCorrFactors.useRho = True
    # Let's use the same rho as in the TauID, so we don't need to do it twice.
    process.patJetCorrFactors.rho = cms.InputTag(
        "kt6PFJetsForRhoComputationVoronoi", "rho")

    # Use PFMEt
    mettools.addPfMET(process)
    if not isMC:
        coreTools.runOnData(process)
        process.patMETsPF.addGenMET = False
    output_commands.append('patJets_selectedPatJets_*_*')

    # Customize/embed all our sequences
    process.load("FinalStateAnalysis.PatTools.patJetProduction_cff")
    # We have to keep all jets (for the MVA MET...)
    process.patJetGarbageRemoval.cut = 'pt > 0'

    final_jet_collection = chain_sequence(
        process.customizeJetSequence, "patJets")
    process.customizeJetSequence.insert(0, process.patJets)
    # Make it a "complete" sequence
    process.customizeJetSequence += process.selectedPatJets
    # We can't mess up the selected pat jets because the taus use them.
    process.selectedPatJets.src = final_jet_collection
    process.patDefaultSequence.replace(process.patJets,
                                       process.customizeJetSequence)

    # Produce the electron collections
    process.load("FinalStateAnalysis.PatTools.patElectronProduction_cff")
    final_electron_collection = chain_sequence(
        process.customizeElectronSequence, "selectedPatElectrons")
    process.tuplize += process.customizeElectronSequence
    process.customizeElectronSequence.insert(0, process.selectedPatElectrons)
    process.patDefaultSequence.replace(process.selectedPatElectrons,
                                       process.customizeElectronSequence)
    # We have to do the pat Jets before the pat electrons since we embed them
    process.customizeElectronSequence.insert(0, process.selectedPatJets)
    process.cleanPatElectrons.src = final_electron_collection
    # The "effective area" calculation needs to know if it is data/mc, etc.
    process.patElectronMVAIsoEmbedding.target = kwargs['target']
    process.patElectronEffectiveAreaEmbedder.target = kwargs['target']

    process.load("FinalStateAnalysis.PatTools.patMuonProduction_cff")
    final_muon_collection = chain_sequence(
        process.customizeMuonSequence, "selectedPatMuons")
    process.customizeMuonSequence.insert(0, process.selectedPatMuons)
    process.patDefaultSequence.replace(process.selectedPatMuons,
                                       process.customizeMuonSequence)
    process.cleanPatMuons.src = final_muon_collection
    # The "effective area" calculation needs to know if it is data/mc, etc.
    process.patMuonMVAIdIsoEmbedding.target = kwargs['target']
    process.patMuonEffectiveAreaEmbedder.target = kwargs['target']

    process.load("FinalStateAnalysis.PatTools.patTauProduction_cff")
    final_tau_collection = chain_sequence(
        process.customizeTauSequence, "selectedPatTaus")
    # Inject into the pat sequence
    process.customizeTauSequence.insert(0, process.selectedPatTaus)
    process.patDefaultSequence.replace(process.selectedPatTaus,
                                       process.customizeTauSequence)
    process.cleanPatTaus.src = final_tau_collection
    # Remove muons and electrons
    process.cleanPatTaus.checkOverlaps.muons.requireNoOverlaps = False
    process.cleanPatTaus.checkOverlaps.electrons.requireNoOverlaps = False
    # Don't apply any prselections
    process.cleanPatTaus.preselection = 'abs(eta) < 2.5 & (pt > 18 | userFloat("jetPt") > 18)'

    # Setup MET production
    process.load("FinalStateAnalysis.PatTools.patMETProduction_cff")
    final_met_collection = chain_sequence(
        process.customizeMETSequence, "patMETsPF")
    process.tuplize += process.customizeMETSequence
    # The MET systematics depend on all other systematics
    process.systematicsMET.tauSrc = cms.InputTag("cleanPatTaus")
    process.systematicsMET.muonSrc = cms.InputTag("cleanPatMuons")
    process.systematicsMET.electronSrc = cms.InputTag("cleanPatElectrons")

    # Keep all the data formats needed for the systematics
    output_commands.append('recoLeafCandidates_*_*_%s'
                           % process.name_())

    # Define the default lepton cleaning
    process.cleanPatElectrons.preselection = cms.string('pt > 5')
    process.cleanPatElectrons.checkOverlaps.muons.requireNoOverlaps = False
    # Make sure we don't kill any good taus by calling them electrons
    # Note that we don't actually remove these overlaps.
    process.cleanPatElectrons.checkOverlaps.taus = cms.PSet(
        src = final_tau_collection,
        algorithm = cms.string("byDeltaR"),
        preselection = cms.string(
            "tauID('decayModeFinding') > 0.5 &&"
            "tauID('byLooseCombinedIsolationDeltaBetaCorr') > 0.5 &&"
            "tauID('againstElectronLoose') > 0.5 && "
            "pt > 10"
        ),
        deltaR = cms.double(0.1),
        checkRecoComponents = cms.bool(False),
        pairCut = cms.string(""),
        requireNoOverlaps = cms.bool(False),
    )

    output_commands.append('*_cleanPatTaus_*_*')
    output_commands.append('*_cleanPatElectrons_*_*')
    output_commands.append('*_cleanPatMuons_*_*')
    output_commands.append('*_%s_*_*' % final_met_collection.value())

    #process.load("PhysicsTools.PatAlgos.triggerLayer1.triggerMatcher_cfi")
    #trigtools.switchOnTriggerMatchEmbedding(process)
    trigtools.switchOnTrigger(process)

    # Build the PATFinalStateEventObject
    process.load("FinalStateAnalysis.PatTools.finalStates.patFinalStateEventProducer_cfi")
    process.patFinalStateEventProducer.electronSrc = final_electron_collection
    process.patFinalStateEventProducer.muonSrc = cms.InputTag("cleanPatMuons")
    process.patFinalStateEventProducer.tauSrc = cms.InputTag("cleanPatTaus")
    process.patFinalStateEventProducer.jetSrc = cms.InputTag("selectedPatJets")
    process.patFinalStateEventProducer.metSrc = final_met_collection
    process.tuplize += process.patFinalStateEventProducer
    output_commands.append('*_patFinalStateEventProducer_*_*')
    process.patFinalStateEventProducer.puTag = cms.string(kwargs['puTag'])

    # Now build the PATFinalStateLS object, which holds LumiSection info.
    process.load(
        "FinalStateAnalysis.PatTools.finalStates.patFinalStateLSProducer_cfi")
    process.tuplize += process.finalStateLS
    output_commands.append('*_finalStateLS_*_*')
    if isMC:
        process.finalStateLS.xSec = kwargs['xSec']

    # Apply some loose PT cuts on the objects we use to create the final states
    # so the combinatorics don't blow up
    process.muonsForFinalStates = cms.EDFilter(
        "PATMuonRefSelector",
        src = cms.InputTag("cleanPatMuons"),
        cut = cms.string('pt > 4'),
        filter = cms.bool(False),
    )

    process.electronsForFinalStates = cms.EDFilter(
        "PATElectronRefSelector",
        src = cms.InputTag("cleanPatElectrons"),
        cut = cms.string('abs(eta) < 2.5 & pt > 4'),
        filter = cms.bool(False),
    )

    # Require that the PT of the jet (either corrected jet or tau)
    # to be greater than 17
    process.tausForFinalStates = cms.EDFilter(
        "PATTauRefSelector",
        src = cms.InputTag("cleanPatTaus"),
        cut = cms.string('abs(eta) < 2.5 & pt > 17 & tauID("decayModeFinding")'),
        filter = cms.bool(False),
    )

    process.selectObjectsForFinalStates = cms.Sequence(
        process.muonsForFinalStates
        + process.electronsForFinalStates
        + process.tausForFinalStates
    )

    process.tuplize += process.selectObjectsForFinalStates

    # Now build all of our DiLeptons and TriLepton final states
    lepton_types = [('Elec', cms.InputTag("electronsForFinalStates")),
                    ('Mu', cms.InputTag("muonsForFinalStates")),
                    ('Tau', cms.InputTag("tausForFinalStates"))]
    #lepton_types = [('Elec', cms.InputTag("cleanPatElectrons")),
                    #('Mu', cms.InputTag("cleanPatMuons")),
                    #('Tau', cms.InputTag("cleanPatTaus"))]

    process.buildDiLeptons = cms.Sequence()

    process.load(
        "FinalStateAnalysis.PatTools.finalStates.patFinalStatesEmbedExtraCollections_cfi")

    # Build di-lepton pairs
    for dilepton in _combinatorics(lepton_types, 2):
        # Don't build two jet states
        if (dilepton[0][0], dilepton[1][0]) == ('Tau', 'Tau'):
            continue

        # Define some basic selections for building combinations
        cuts = ['smallestDeltaR() > 0.3'] # basic x-cleaning

        producer = cms.EDProducer(
            "PAT%s%sFinalStateProducer" % (dilepton[0][0], dilepton[1][0]),
            evtSrc = cms.InputTag("patFinalStateEventProducer"),
            leg1Src = dilepton[0][1],
            leg2Src = dilepton[1][1],
            # X-cleaning
            cut = cms.string(' & '.join(cuts))
        )
        producer_name = "finalState%s%s" % (dilepton[0][0], dilepton[1][0])
        setattr(process, producer_name + "Raw", producer)
        process.buildDiLeptons += producer
        # Embed the other collections
        embedder_seq = helpers.cloneProcessingSnippet(process,
            process.patFinalStatesEmbedObjects, producer_name)
        process.buildDiLeptons += embedder_seq
        # Do some trickery so the final module has a nice output name
        final_module_name = chain_sequence(embedder_seq, producer_name + "Raw")
        final_module = getattr(process, final_module_name.value())
        final_module.setLabel(producer_name)
        setattr(process, producer_name, final_module)
        output_commands.append("*_%s_*_*" % producer_name)

    process.tuplize += process.buildDiLeptons
    # Build tri-lepton pairs
    process.buildTriLeptons = cms.Sequence()
    for trilepton in _combinatorics(lepton_types, 3):
        # Don't build three jet states
        if (trilepton[0][0], trilepton[1][0], trilepton[2][0]) == \
           ('Tau', 'Tau', 'Tau'):
            continue

        # Define some basic selections for building combinations
        cuts = ['smallestDeltaR() > 0.3'] # basic x-cleaning

        producer = cms.EDProducer(
            "PAT%s%s%sFinalStateProducer" %
            (trilepton[0][0], trilepton[1][0], trilepton[2][0]),
            evtSrc = cms.InputTag("patFinalStateEventProducer"),
            leg1Src = trilepton[0][1],
            leg2Src = trilepton[1][1],
            leg3Src = trilepton[2][1],
            # X-cleaning
            cut = cms.string(' & '.join(cuts))
        )
        producer_name = "finalState%s%s%s" % (
            trilepton[0][0], trilepton[1][0], trilepton[2][0])
        #setattr(process, producer_name, producer)
        #process.buildTriLeptons += producer
        setattr(process, producer_name + "Raw", producer)
        process.buildTriLeptons += producer
        # Embed the other collections
        embedder_seq = helpers.cloneProcessingSnippet(process,
            process.patFinalStatesEmbedObjects, producer_name)
        process.buildTriLeptons += embedder_seq
        # Do some trickery so the final module has a nice output name
        final_module_name = chain_sequence(embedder_seq, producer_name + "Raw")
        final_module = getattr(process, final_module_name.value())
        final_module.setLabel(producer_name)
        setattr(process, producer_name, final_module)
        output_commands.append("*_%s_*_*" % producer_name)
    process.tuplize += process.buildTriLeptons

    # Build 4 lepton final states
    process.buildQuadLeptons = cms.Sequence()
    for quadlepton in _combinatorics(lepton_types, 4):
        # Don't build states with more than 2 hadronic taus
        if [x[0] for x in quadlepton].count('Tau') > 2:
            continue

        # Define some basic selections for building combinations
        cuts = ['smallestDeltaR() > 0.3'] # basic x-cleaning

        producer = cms.EDProducer(
            "PAT%s%s%s%sFinalStateProducer" %
            (quadlepton[0][0], quadlepton[1][0], quadlepton[2][0],
             quadlepton[3][0]),
            evtSrc = cms.InputTag("patFinalStateEventProducer"),
            leg1Src = quadlepton[0][1],
            leg2Src = quadlepton[1][1],
            leg3Src = quadlepton[2][1],
            leg4Src = quadlepton[3][1],
            # X-cleaning
            cut = cms.string(' & '.join(cuts))
        )
        producer_name = "finalState%s%s%s%s" % (
            quadlepton[0][0], quadlepton[1][0], quadlepton[2][0],
            quadlepton[3][0]
        )
        #setattr(process, producer_name, producer)
        #process.buildTriLeptons += producer
        setattr(process, producer_name + "Raw", producer)
        process.buildQuadLeptons += producer
        # Embed the other collections
        embedder_seq = helpers.cloneProcessingSnippet(process,
            process.patFinalStatesEmbedObjects, producer_name)
        process.buildQuadLeptons += embedder_seq
        # Do some trickery so the final module has a nice output name
        final_module_name = chain_sequence(embedder_seq, producer_name + "Raw")
        final_module = getattr(process, final_module_name.value())
        final_module.setLabel(producer_name)
        setattr(process, producer_name, final_module)
        output_commands.append("*_%s_*_*" % producer_name)
    process.tuplize += process.buildQuadLeptons

    # Tell the framework to shut up!
    process.load("FWCore.MessageLogger.MessageLogger_cfi")
    process.MessageLogger.cerr.FwkReport.reportEvery = 1000

    return process.tuplize, output_commands
else:  # data
    process.output.fileName = 'miniAOD_TauReco_data.root'
    if reclusterJets:
        process.output.fileName = 'miniAOD_TauReco_ak4PFJets_data.root'
process.out = cms.EndPath(process.output)

#####
tauAtMiniTools.adaptTauToMiniAODReReco(reclusterJets)
process.p = cms.Path(
    getattr(process, ("miniAODTausSequence" + postfix if not runBoosted else
                      "miniAODTausSequenceBoosted" + postfix)))

if runType == 'data':
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData(process,
              names=['Taus'],
              outputModules=[],
              postfix=(postfix if not runBoosted else 'Boosted' + postfix))

#####
process.load('FWCore.MessageService.MessageLogger_cfi')
if process.maxEvents.input.value() > 10:
    process.MessageLogger.cerr.FwkReport.reportEvery = process.maxEvents.input.value(
    ) // 10
if process.maxEvents.input.value() > 10000 or process.maxEvents.input.value(
) < 0:
    process.MessageLogger.cerr.FwkReport.reportEvery = 1000

#####
process.options = dict(
    numberOfThreads=4,
    # numberOfThreads = 1,
Exemple #28
0
        filename=options.lumiFile).getVLuminosityBlockRange()

if options.eventList != '':
    process.source.eventsToProcess = cms.untracked.VEventRange(
        re.split(',', options.eventList))

tau_collection = 'slimmedTaus'
if options.rerunTauReco:
    tau_collection = 'selectedPatTaus'

    tauAtMiniTools.addTauReReco(process)
    tauAtMiniTools.adaptTauToMiniAODReReco(process, options.reclusterJets)

    if isData:
        from PhysicsTools.PatAlgos.tools.coreTools import runOnData
        runOnData(process, names=['Taus'], outputModules=[])

    process.combinatoricRecoTaus.builders[0].signalConeSize = cms.string(
        'max(min(0.2, 4.528/(pt()^0.8982)), 0.03)')  ## change to quantile 0.95
    process.selectedPatTaus.cut = cms.string(
        'pt > 18.'
    )  ## remove DMFinding filter (was pt > 18. && tauID(\'decayModeFindingNewDMs\')> 0.5)

# include Phase2 specific configuration only after 11_0_X
if isPhase2:
    tauIdConfig = importlib.import_module(
        'RecoTauTag.RecoTau.tools.runTauIdMVA')
    updatedTauName = "slimmedTausNewID"
    tauIdEmbedder = tauIdConfig.TauIDEmbedder(process,
                                              cms,
                                              updatedTauName=updatedTauName,
def configurePatTuple(process, isMC=True, **kwargs):
    '''
    Core function for PATTuple production
    '''
    #fix argparser output
    isMC = bool(isMC)

    ########################
    ##                    ##
    ##  PATTuple content  ##
    ##                    ##
    ########################
    # Stuff we always keep
    output_commands = [
        '*_addPileupInfo_*_*',
        'edmMergeableCounter_*_*_*',
        '*_lumiProducer_*_*',
        '*_particleFlow_*_*',
        '*_offlineBeamSpot_*_*',
        '*_generalTracks_*_*',
        '*_electronGsfTracks_*_*',
        '*_gsfElectrons_*_*',
        '*_gsfElectronCores_*_*',
        '*_offlinePrimaryVertices*_*_*',
        '*_ak5GenJets_*_*',
        '*_hltTriggerSummaryAOD_*_*',
        'edmTriggerResults_TriggerResults_*_%s' % process.name_(),
        '*_MEtoEDMConverter*_*_%s' % process.name_(),
        'LHEEventProduct_*_*_*',
        'GenEventInfoProduct_generator_*_*',
        '*_kt6PFJetsForRhoComputationVoronoi_rho_*',
        '*_kt6PFJetsForIso_rho_*',
        '*_kt6PFJets_rho_*',
        '*_kt6PFJetsHZGPho_rho_*',
        '*_kt6PFJetsCentralHZGEle_rho_*',
        '*_kt6PFJetsCentralHZGMu_rho_*',
        '*_kt6PFJetsCentralNeutralHZGMu_rho_*',
        '*_kt6PFJetsCentral_rho_*',
        '*_kt6PFJetsCentralNeutral_rho_*',  # for zz muons
        '*_photonCore_*_*',
        '*_boostedFsrPhotons_*_*',
        # for Zmumu -> embedded samples
        # https://twiki.cern.ch/twiki/bin/view/CMS/MuonTauReplacementRecHit
        '*_generalTracksORG_*_EmbeddedRECO',
        '*_electronGsfTracksORG_*_EmbeddedRECO',
        'double_TauSpinnerReco_TauSpinnerWT_EmbeddedSPIN',
        'double_ZmumuEvtSelEffCorrWeightProducer_weight_EmbeddedRECO',
        'double_muonRadiationCorrWeightProducer_weight_EmbeddedRECO',
        'GenFilterInfo_generator_minVisPtFilter_EmbeddedRECO',
    ]
    # Define our patTuple production sequence
    process.tuplize = cms.Sequence()
    # Only keep interesting genParticles
    process.load("FinalStateAnalysis.RecoTools.genParticleTrimmer_cfi")
    process.genParticles = process.prunedGenParticles.clone()
    if isMC:
        #process.tuplize += process.genParticles
        #output_commands.append('*_genParticles_*_%s' % process.name_())
        output_commands.append('*_genParticles_*_*')

    output_commands.append('*_tauGenJetsSelectorAllHadrons_*_*')
    output_commands.append('*_tauGenJets_*_*')
    output_commands.append('*_ak5GenJets_*_*')

    ########################
    ##                    ##
    ##        PAT         ##
    ##                    ##
    ########################

    # Run pat default sequence
    process.load("PhysicsTools.PatAlgos.patSequences_cff")

    # Embed PF Isolation in electrons & muons
    pfTools.usePFIso(process)
    # Setup H2Tau custom iso definitions
    setup_h2tau_iso(process)
    # Setup hZg custom iso definitions
    add_hZg_iso_needs(process)

    # Now run PAT
    process.tuplize += process.patDefaultSequence

    # Add FSR photons for ZZ analysis
    process.load("FinalStateAnalysis.PatTools.fsrPhotons_cff")
    process.tuplize += process.fsrPhotonSequence

    ########################
    ##        GEN         ##
    ########################

    # Disable gen match embedding - we keep it in the ntuple
    process.patMuons.embedGenMatch = False
    process.patElectrons.embedGenMatch = False
    process.patTaus.embedGenMatch = False
    process.patTaus.embedGenJetMatch = False
    process.patPhotons.embedGenMatch = False
    if not isMC:
        coreTools.runOnData(process)

    ########################
    ##       MUONS        ##
    ########################

    # Unembed junk
    process.patMuons.embedCaloMETMuonCorrs = False
    process.patMuons.embedTcMETMuonCorrs = False
    process.patMuons.embedTrack = True
    process.patMuons.pvSrc = cms.InputTag("selectedPrimaryVertex")

    process.load("FinalStateAnalysis.PatTools.patMuonProduction_cff")
    final_muon_collection = chain_sequence(
        process.customizeMuonSequence, "selectedPatMuons")
    process.customizeMuonSequence.insert(0, process.selectedPatMuons)
    process.patDefaultSequence.replace(process.selectedPatMuons,
                                       process.customizeMuonSequence)
    process.cleanPatMuons.src = final_muon_collection
    process.patMuonRochesterCorrectionEmbedder.isMC = cms.bool(bool(isMC))

    ########################
    ##        TAUS        ##
    ########################

    # Use HPS taus
    tautools.switchToPFTauHPS(process) #this NEEDS a sequence called patDefaultSequence
    # Disable tau IsoDeposits
    process.patDefaultSequence.remove(process.patPFTauIsolation)
    process.patTaus.isoDeposits = cms.PSet()
    process.patTaus.userIsolation = cms.PSet()

    process.load("FinalStateAnalysis.PatTools.patTauProduction_cff")
    # Require all taus to pass decay mode finding and have high PT
    process.patTauGarbageRemoval.cut = cms.string(
        "pt > 17 && abs(eta) < 2.5 && tauID('decayModeFindingNewDMs')")
    final_tau_collection = chain_sequence(
        process.customizeTauSequence, "selectedPatTaus")
    # Inject into the pat sequence
    process.customizeTauSequence.insert(0, process.selectedPatTaus)
    process.patDefaultSequence.replace(process.selectedPatTaus,
                                       process.customizeTauSequence)
    process.cleanPatTaus.src = final_tau_collection
    # Remove muons and electrons
    process.cleanPatTaus.checkOverlaps.muons.requireNoOverlaps = False
    process.cleanPatTaus.checkOverlaps.electrons.requireNoOverlaps = False
    # Cuts already applied by the garbage removal
    process.cleanPatTaus.preselection = ''
    process.cleanPatTaus.finalCut = ''

    ########################
    ##     ELECTRONS      ##
    ########################

    # Use POG recommendations for (these) electron Isos
    process.elPFIsoValueGamma04PFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueGamma04NoPFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.08)')
    process.elPFIsoValueCharged04PFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.015)')
    process.elPFIsoValueCharged04NoPFIdPFIso.deposits[0].vetos = cms.vstring(
        'EcalEndcaps:ConeVeto(0.015)')

    # Do extra electron ID
    process.load("FinalStateAnalysis.PatTools.electrons.electronID_cff")
    if cmssw_major_version() == 4:
        process.patDefaultSequence.replace(process.patElectrons,
                                           process.recoElectronID42X +
                                           process.patElectrons)
        process.patElectrons.electronIDSources = process.electronIDSources42X
    else:
        process.patDefaultSequence.replace(process.patElectrons,
                                           process.recoElectronID5YX +
                                           process.patElectrons)
        process.patElectrons.electronIDSources = process.electronIDSources5YX

    process.electronMatch.checkCharge = cms.bool(False)
    process.patElectrons.embedTrack = False
    process.patElectrons.embedPFCandidate = False
    process.patElectrons.embedGsfElectronCore = False
    process.patElectrons.embedSuperCluster = True

    # Produce the electron collections
    process.load("FinalStateAnalysis.PatTools.patElectronProduction_cff")

    # Electron Energy Regression and Calibrations
    process.load(
        "EgammaAnalysis.ElectronTools.electronRegressionEnergyProducer_cfi")
    process.load("EgammaAnalysis.ElectronTools.calibratedPatElectrons_cfi")

    #setup the energy regression for the specific dataset
    if kwargs['eleReg']:
        print "-- Applying Electron Regression and Calibration --"

        process.customizeElectronSequence += process.eleRegressionEnergy
        process.customizeElectronSequence += process.calibratedPatElectrons

        process.eleRegressionEnergy.energyRegressionType = cms.uint32(2)
        process.calibratedPatElectrons.correctionsType = cms.int32(2)

        if isMC:
            process.calibratedPatElectrons.inputDataset = cms.string(
                "Summer12_LegacyPaper")
        else:
            process.calibratedPatElectrons.inputDataset = cms.string(
                "22Jan2013ReReco")

        process.calibratedPatElectrons.combinationType = cms.int32(3)
        process.calibratedPatElectrons.lumiRatio = cms.double(1.0)
        process.calibratedPatElectrons.synchronization = cms.bool(True)
        process.calibratedPatElectrons.isMC = cms.bool(isMC == 1)
        process.calibratedPatElectrons.verbose = cms.bool(False)

    final_electron_collection = chain_sequence(
        process.customizeElectronSequence, "selectedPatElectrons",
        # Some of the EGamma modules have non-standard src InputTags,
        # specify them here.
        ("src", "inputPatElectronsTag", "inputElectronsTag")
    )

    #process.tuplize += process.customizeElectronSequence #why do we need this?
    process.customizeElectronSequence.insert(0, process.selectedPatElectrons)
    process.patDefaultSequence.replace(process.selectedPatElectrons,
                                       process.customizeElectronSequence)
    # We have to do the pat Jets before the pat electrons since we embed them
    process.customizeElectronSequence.insert(0, process.selectedPatJets)

    # Define cleanPatElectrons input collection
    process.cleanPatElectrons.src = final_electron_collection

    # Define the default lepton cleaning
    process.cleanPatElectrons.preselection = cms.string(
        'pt > 5')
    process.cleanPatElectrons.checkOverlaps.muons.requireNoOverlaps = False
    # Make sure we don't kill any good taus by calling them electrons
    # Note that we don't actually remove these overlaps.
    process.cleanPatElectrons.checkOverlaps.taus = cms.PSet(
        src=final_tau_collection,
        algorithm=cms.string("byDeltaR"),
        preselection=cms.string(
            "tauID('decayModeFinding') > 0.5 &&"
            "tauID('byLooseCombinedIsolationDeltaBetaCorr') > 0.5 &&"
            "tauID('againstElectronLoose') > 0.5 && "
            "pt > 10"
        ),
        deltaR=cms.double(0.1),
        checkRecoComponents=cms.bool(False),
        pairCut=cms.string(""),
        requireNoOverlaps=cms.bool(False),
    )

    ########################
    ##        JETS        ##
    ########################

    # Use PFJets and turn on JEC
    jec = ['L1FastJet', 'L2Relative', 'L3Absolute']
    # If we are running on data (not MC), or embedded sample,
    # apply the MC-DATA residual correction.
    if not isMC or kwargs['embedded']:
        jec.extend(['L2L3Residual'])

    # tmp
    # define the b-tag squences for offline reconstruction
    process.load("RecoBTag.SecondaryVertex.secondaryVertex_cff")
    process.load("RecoBTau.JetTagComputer.combinedMVA_cff")
    process.load('RecoVertex/AdaptiveVertexFinder/inclusiveVertexing_cff')
    process.load('RecoBTag/SecondaryVertex/bToCharmDecayVertexMerger_cfi')
    #process.load("PhysicsTools.PatAlgos.patSequences_cff")

    # Define options for BTagging - these are release dependent.
    btag_options = {'doBTagging': True}
    if cmssw_major_version() == 5:
        btag_options['btagInfo'] = [
            'impactParameterTagInfos',
            'secondaryVertexTagInfos',
            'softMuonTagInfos',
            'secondaryVertexNegativeTagInfos',
            'inclusiveSecondaryVertexFinderFilteredTagInfos'
        ]
        btag_options['btagdiscriminators'] = [
            'trackCountingHighEffBJetTags',
            'trackCountingHighPurBJetTags',    
            'simpleSecondaryVertexHighEffBJetTags',
            'simpleSecondaryVertexHighPurBJetTags',
            'simpleInclusiveSecondaryVertexHighEffBJetTags',
            'simpleInclusiveSecondaryVertexHighPurBJetTags',        
            'combinedSecondaryVertexMVABJetTags',
            'combinedSecondaryVertexBJetTags',
            'jetBProbabilityBJetTags', 
            'jetProbabilityBJetTags',   
        ]

    #Avoid embedding
    process.patJets.embedPFCandidates = True
    process.patJets.embedCaloTowers = False
    process.patJets.embedGenJetMatch = True
    process.patJets.addAssociatedTracks = True
    process.patJets.embedGenPartonMatch = True

    # Add AK5chs PFJets
    jettools.addJetCollection(
        process,
        cms.InputTag('ak5PFchsJets'),
        algoLabel = "AK5",
        typeLabel = "PFchs",
        doJTA              = True,
        jetCorrLabel       = ('AK5PFchs', jec),
        doType1MET         = False,
        doL1Cleaning       = False,
        doL1Counters       = False,
        genJetCollection   = cms.InputTag('ak5GenJets'),
        doJetID            = True,
        **btag_options
    )

    # Use AK5 PFJets
    jettools.switchJetCollection(
        process,
        cms.InputTag('ak5PFJets'),
        doJTA=True,
        jetCorrLabel=('AK5PF', jec),
        #jetCorrLabel = None,
        doType1MET=False,
        doJetID=True,
        genJetCollection=cms.InputTag("ak5GenJets"),
        **btag_options
    )

    # Customize/embed all our sequences
    process.load("FinalStateAnalysis.PatTools.patJetProduction_cff")
    helpers.cloneProcessingSnippet( process, process.customizeJetSequence, 'AK5PFchs' )
    process.patJetGarbageRemoval.cut = 'pt > 12'
    final_jet_collection = chain_sequence(
        process.customizeJetSequence, "patJets")
    process.customizeJetSequence.insert(0, process.patJets)
    # Make it a "complete" sequence
    process.customizeJetSequence += process.selectedPatJets
#    process.customizeJetSequence += process.btagging
    # We can't mess up the selected pat jets because the taus use them.
    process.selectedPatJets.src = final_jet_collection
    process.patDefaultSequence.replace(process.patJets,
                                       process.customizeJetSequence)

    process.customizeJetSequenceAK5PFchs.remove( process.patJetsPUIDAK5PFchs )
    process.customizeJetSequenceAK5PFchs.remove( process.pileupJetIdProducerAK5PFchs )
    process.patJetGarbageRemovalAK5PFchs.cut = 'pt > 20'
    process.patJetCorrFactorsAK5PFchs.payload = cms.string('AK5PFchs') 
    final_jetchs_collection = chain_sequence(
        process.customizeJetSequenceAK5PFchs, "patJetsAK5PFchs")
    process.customizeJetSequenceAK5PFchs.insert(0, process.patJetsAK5PFchs)
    # Make it a "complete" sequence
    process.customizeJetSequenceAK5PFchs += process.selectedPatJetsAK5PFchs
    # We can't mess up the selected pat jets because the taus use them.
    process.selectedPatJetsAK5PFchs.src = final_jetchs_collection
    process.selectedPatJetsAK5chsPF  = process.selectedPatJetsAK5PFchs.clone() #that's what we keep
    process.customizeJetSequenceAK5PFchs += process.selectedPatJetsAK5chsPF
    process.patDefaultSequence.replace(process.patJetsAK5PFchs,
                                       process.customizeJetSequenceAK5PFchs)

    output_commands.append('*_selectedPatJets_*_*')
    output_commands.append('*_selectedPatJetsAK5chsPF_*_*')
    output_commands.append('*SecondaryVertexTagInfo*_*_*_*')
    output_commands.append('*TrackIPTagInfo*_*_*_*')
    output_commands.append('*SoftLeptonTagInfo*_*_*_*')
    output_commands.append('*_ak5PFJets_*_*')
    output_commands.append('*_ak5PFchsJets_*_*')

    ########################
    ##        MET         ##
    ########################

    # Use PFMEt
    mettools.addPfMET(process)

    # We cut out a lot of the junky taus and jets - but we need these
    # to correctly apply the MET uncertainties.  So, let's make a
    # non-cleaned version of the jet and tau sequence.
    process.jetsForMetSyst = helpers.cloneProcessingSnippet(
        process, process.customizeJetSequence, 'ForMETSyst')
    process.tausForMetSyst = helpers.cloneProcessingSnippet(
        process, process.customizeTauSequence, 'ForMETSyst')
    # Don't apply any cut for these
    process.patTauGarbageRemovalForMETSyst.cut = ''
    process.patJetGarbageRemovalForMETSyst.cut = ''
    process.tuplize += process.jetsForMetSyst
    process.tuplize += process.tausForMetSyst
    # We have to make our clone of cleanPatTaus separately, since e/mu
    # cleaning is applied - therefore it isn't in the customizeTausSequence.
    process.cleanPatTausForMETSyst = process.cleanPatTaus.clone(
        src=cms.InputTag(process.cleanPatTaus.src.value() + "ForMETSyst"))
    process.cleanPatTausForMETSyst.preselection = ''
    process.cleanPatTausForMETSyst.finalCut = ''
    process.patTausEmbedJetInfoForMETSyst.jetSrc = \
        final_jet_collection.value() + "ForMETSyst"
    process.tuplize += process.cleanPatTausForMETSyst

    # Setup MET production
    process.load("FinalStateAnalysis.PatTools.patMETProduction_cff")
    # The MET systematics depend on all other systematics
    process.systematicsMET.tauSrc = cms.InputTag("cleanPatTausForMETSyst")
    process.systematicsMET.muonSrc = cms.InputTag("cleanPatMuons")
    process.systematicsMET.electronSrc = cms.InputTag("cleanPatElectrons")

    final_met_collection = chain_sequence(
        process.customizeMETSequence, "patMETsPF")
    process.tuplize += process.customizeMETSequence
    process.patMETsPF.addGenMET = bool(isMC)
    output_commands.append('*_%s_*_*' % final_met_collection.value())

    # Make a version with the MVA MET reconstruction method
    process.load("FinalStateAnalysis.PatTools.met.mvaMetOnPatTuple_cff")
    process.tuplize += process.pfMEtMVAsequence
    mva_met_sequence = helpers.cloneProcessingSnippet(
        process, process.customizeMETSequence, "MVA")
    final_mvamet_collection = chain_sequence(
        mva_met_sequence, "patMEtMVA")
    process.tuplize += mva_met_sequence
    output_commands.append('*_%s_*_*' % final_mvamet_collection.value())

    # Keep all the data formats needed for the systematics
    output_commands.append('recoLeafCandidates_*_*_%s'
                           % process.name_())
    # We can drop to jet and tau MET specific products. They were only used for
    # computation of the MET numbers.
    output_commands.append('drop recoLeafCandidates_*ForMETSyst_*_%s'
                           % process.name_())

    ########################
    ##      PHOTONS       ##
    ########################

    #alter the photon matching to accept various fakes
    # and sort matches by d-pt-rel
    if isMC:
        process.photonMatch = cms.EDProducer(
            "MCMatcherByPt",
            src=cms.InputTag("photons"),
            maxDPtRel=cms.double(100.0),
            mcPdgId=cms.vint32(),
            mcStatus=cms.vint32(1),
            resolveByMatchQuality=cms.bool(False),
            maxDeltaR=cms.double(0.3),
            checkCharge=cms.bool(False),
            resolveAmbiguities=cms.bool(True),
            matched=cms.InputTag("genParticles")
        )

    # Setup pat::Photon Production
    process.load("FinalStateAnalysis.PatTools.patPhotonProduction_cff")
    final_photon_collection = chain_sequence(process.customizePhotonSequence,
                                             "selectedPatPhotons")
    #setup PHOSPHOR for a specific dataset
    if cmssw_major_version() == 4:  # for now 2011 = CMSSW42X
        process.patPhotonPHOSPHOREmbedder.year = cms.uint32(2011)
    else:  # 2012 is 5YX
        process.patPhotonPHOSPHOREmbedder.year = cms.uint32(2012)
    process.patPhotonPHOSPHOREmbedder.isMC = cms.bool(bool(isMC))
    #inject photons into pat sequence
    process.customizePhotonSequence.insert(0, process.selectedPatPhotons)
    process.patDefaultSequence.replace(process.selectedPatPhotons,
                                       process.customizePhotonSequence)
    process.cleanPatPhotons.src = final_photon_collection

    ########################
    ##      TRIGGER       ##
    ########################

    trigtools.switchOnTrigger(process)

    #configure the PAT trigger
    if kwargs['HLTprocess']:
        process.patTrigger.processName = cms.string(kwargs['HLTprocess'])
        process.patTriggerEvent.processName = cms.string(kwargs['HLTprocess'])

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

    output_commands.append('*_cleanPatTaus_*_*')
    output_commands.append('*_cleanPatElectrons_*_*')
    output_commands.append('*_cleanPatMuons_*_*')
    output_commands.append('*_cleanPatPhotons_*_*')

    ########################
    ##                    ##
    ##        FSA         ##
    ##                    ##
    ########################

    # Now build the PATFinalStateLS object, which holds LumiSection info.
    process.load(
        "FinalStateAnalysis.PatTools.finalStates.patFinalStateLSProducer_cfi")
    process.tuplize += process.finalStateLS
    output_commands.append('*_finalStateLS_*_*')
    if isMC:
        process.finalStateLS.xSec = kwargs['xSec']

    # Tell the framework to shut up!
    process.load("FWCore.MessageLogger.MessageLogger_cfi")
    process.MessageLogger.cerr.FwkReport.reportEvery = 1000

    # Which collections are used to build the final states
    fs_daughter_inputs = {
        'electrons':  'cleanPatElectrons',
        'muons':  'cleanPatMuons',
        'taus':  'cleanPatTaus',
        'photons':  'cleanPatPhotons',
        'jets':  'selectedPatJets',
        'pfmet':  final_met_collection,
        'mvamet':  final_mvamet_collection,
    }

    # Setup all the PATFinalState objects
    produce_final_states(process, fs_daughter_inputs, output_commands,
                         process.tuplize, kwargs['puTag'],
                         zzMode=kwargs.get('zzMode', False))

    return process.tuplize, output_commands
Exemple #30
0
                                'abs(eta) < 2.5 && ' \
                                'numberOfDaughters > 1 && ' \
                                'neutralHadronEnergyFraction < 0.99 && ' \
                                'neutralEmEnergyFraction < 0.99 && ' \
                                '(abs(eta) >= 2.4 || (chargedEmEnergyFraction < 0.99 && chargedHadronEnergyFraction > 0. && chargedMultiplicity > 0))'

# The PAT producers need to know whether we're running on MC events or
# data; for the latter, this next part is mainly to remove the MC
# truth matching. (Each reconstructed PAT object stores a pointer to
# the generator-level object that is its closest match, with matching
# done in delta-R = sqrt((delta eta)^2 + (delta phi)^2; see
# plugins/PAT2Ntuple.cc for an example of accessing these matches.)

from PhysicsTools.PatAlgos.tools.coreTools import runOnData
if not runOnMC:
    runOnData(process, names=['PFAll'], postfix='PF')

# We remove PAT photons here because they are not fully commisssioned
# in PF. (You could turn them on to check their performance.) This
# also turns off a cleaning step, which in the default PAT workflow
# tries to remove overlap between the physics object collections
# (e.g. removing muons from being reconstructed as degenerate "jets"),
# but this is not necessary with PF/the GED, especially with the top
# projections described above enabled.

from PhysicsTools.PatAlgos.tools.coreTools import removeSpecificPATObjects
removeSpecificPATObjects(process, names=['Photons'], postfix='PF')

# Now we configure the job to keep ttbar events in all three decay
# modes. For hadronic, we will require that there be four
# reconstructed jets (the main hadronic trigger requires this anyway).
def addInvHiggsProcess(process, iRunOnData=True, iData="PromptC2", iHLTFilter="MET", iMCSignal=False, iFile='/store/data/Run2012C/MET/AOD/PromptReco-v2/000/203/002/04BCEC26-AA02-E211-A81D-003048CF99BA.root', iMaxEvent=100):
    
    ###--------------------------------------------------------------
    ### Load PAT, because it insists on defining the process for you
    #from PhysicsTools.PatAlgos.patTemplate_cfg import *
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### Input
    process.maxEvents.input   = iMaxEvent
    process.source.fileNames  = [iFile]
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### GlobalTag
    if iRunOnData == True:
        if (iData.find("Jul13")==0):
            process.GlobalTag.globaltag = "FT_53_V6C_AN3::All"
        elif (iData.find("Aug06")==0):
            process.GlobalTag.globaltag = "FT_53_V6C_AN3::All"
        elif (iData.find("Aug24")==0):
            process.GlobalTag.globaltag = "FT53_V10A_AN3::All"
        elif (iData.find("PromptC2")==0):
            process.GlobalTag.globaltag = "GR_P_V42_AN3::All"
        elif (iData.find("PromptD")==0):
            process.GlobalTag.globaltag = "GR_P_V42_AN3::All"
        elif (iData.find("Dec11")==0): #Run201191
            process.GlobalTag.globaltag = "FT_P_V42C_AN3::All"
        else:
            process.GlobalTag.globaltag = "GR_P_V42_AN3::All"
    else:
        process.GlobalTag.globaltag = "START53_V7G::All"
    ###--------------------------------------------------------------

    
    ###--------------------------------------------------------------
    ### Logger
    process.load("FWCore.MessageService.MessageLogger_cfi")
    process.load("FWCore.MessageLogger.MessageLogger_cfi")
    process.MessageLogger.cerr.FwkReport = cms.untracked.PSet(
        reportEvery = cms.untracked.int32(2000),
        limit = cms.untracked.int32(10000000)
        )
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### HLT Trigger(s)
    # If it's MC signal, no trigger will be applied
    if iRunOnData == False and iMCSignal == True:
        iHLTFilter = "NoTrig"

    # Load hltHighLevel
    process.load('HLTrigger.HLTfilters.hltHighLevel_cfi')
    process.hltHighLevel.TriggerResultsTag = cms.InputTag("TriggerResults","","HLT")
    process.hltHighLevel.throw = cms.bool(False)  # Tolerate if triggers not available
    process.hltHighLevel.andOr = cms.bool(True)   # True = OR, False = AND
    if (iHLTFilter.find("MET")==0):
        process.hltHighLevel.HLTPaths = cms.vstring(
            "HLT_DiPFJet40_PFMETnoMu65_MJJ600VBF_LeadingJets_v*",
            "HLT_DiPFJet40_PFMETnoMu65_MJJ800VBF_AllJets_v*"
            )
    elif (iHLTFilter.find("SingleMu")==0):
        process.hltHighLevel.HLTPaths = cms.vstring("HLT_IsoMu24_eta2p1_v*","HLT_Mu40_eta2p1_v*")
    elif (iHLTFilter.find("DoubleMu")==0):
        process.hltHighLevel.HLTPaths = cms.vstring("HLT_Mu17_Mu8_v*")
    elif (iHLTFilter.find("SingleElectron")==0):
        process.hltHighLevel.HLTPaths = cms.vstring("HLT_Ele27_WP80_v*")
    elif (iHLTFilter.find("DoubleElectron")==0):
        process.hltHighLevel.HLTPaths = cms.vstring("HLT_Ele17_CaloIdT_CaloIsoVL_TrkIdVL_TrkIsoVL_Ele8_CaloIdT_CaloIsoVL_TrkIdVL_TrkIsoVL_v*")
    elif (iHLTFilter.find("NoTrig")==0):
        process.hltHighLevel.HLTPaths = cms.vstring("*")
    else:
        process.hltHighLevel.HLTPaths = cms.vstring(
            "HLT_DiPFJet40_PFMETnoMu65_MJJ600VBF_LeadingJets_v*",
            "HLT_DiPFJet40_PFMETnoMu65_MJJ800VBF_AllJets_v*"
            )
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    print "-----------------------------------------------"
    print "INVISIBLE HIGGS: Ntuple V10"
    print "-----------------------------------------------"
    print "RunOnData = ", iRunOnData
    if iRunOnData == True:
        print "Dataset = ", iData
    else:
        if iMCSignal == True:
            print "Dataset = MC Signal"
        else:
            print "Dataset = MC Background"
    print "GlobalTag = ", process.GlobalTag.globaltag
    print "Trigger = ", process.hltHighLevel.HLTPaths
    print "Sample input file = ", iFile
    print "Max events = ", iMaxEvent
    print "-----------------------------------------------"
    ###--------------------------------------------------------------

    
    ###-------------------------------------------------------------- 
    ### Basic filters
    # Track quality filter
    process.noscraping = cms.EDFilter(
        "FilterOutScraping",
        applyfilter = cms.untracked.bool(True),
        debugOn = cms.untracked.bool(False),
        numtrack = cms.untracked.uint32(10),
        thresh = cms.untracked.double(0.25)
        )

    # Require a good vertex
    process.primaryVertexFilter = cms.EDFilter(
        "VertexSelector",
        src = cms.InputTag("offlinePrimaryVertices"),
        cut = cms.string("!isFake && ndof > 4 && abs(z) <= 24 && position.Rho <= 2"),
        filter = cms.bool(True)
        )
    ###-------------------------------------------------------------- 


    ###--------------------------------------------------------------
    ### MET Filters
    # The iso-based HBHE noise filter
    process.load('CommonTools.RecoAlgos.HBHENoiseFilter_cfi')

    # The CSC beam halo tight filter
    process.load('RecoMET.METAnalyzers.CSCHaloFilter_cfi')
    
    # The HCAL laser filter
    process.load("RecoMET.METFilters.hcalLaserEventFilter_cfi")
    process.load("EventFilter.HcalRawToDigi.hcallasereventfilter2012_cff")
    process.hcallasereventfilter2012.eventFileName = cms.string('HCALLaser2012AllDatasets.txt.gz')
    
    # The ECAL dead cell trigger primitive filter
    process.load('RecoMET.METFilters.EcalDeadCellTriggerPrimitiveFilter_cfi')
    
    # The EE bad SuperCrystal filter
    process.load('RecoMET.METFilters.eeBadScFilter_cfi')
    
    # The ECAL laser correction filter
    process.load('RecoMET.METFilters.ecalLaserCorrFilter_cfi')
    
    # The Good vertices collection needed by the tracking failure filter
    process.goodVertices = cms.EDFilter(
        "VertexSelector",
        filter = cms.bool(False),
        src = cms.InputTag("offlinePrimaryVertices"),
        cut = cms.string("!isFake && ndof > 4 && abs(z) <= 24 && position.rho < 2")
        )

    # The tracking failure filter
    process.load('RecoMET.METFilters.trackingFailureFilter_cfi')

    # The tracking POG filters
    process.load('RecoMET.METFilters.trackingPOGFilters_cff')
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### customise PAT
    process.load('JetMETCorrections.Configuration.DefaultJEC_cff')

    from PhysicsTools.PatAlgos.tools.coreTools import removeMCMatching,runOnData

    if iRunOnData == True:
        removeMCMatching(process, ['All'])
        runOnData(process)

    # Add the PF MET
    from PhysicsTools.PatAlgos.tools.metTools import addPfMET
    addPfMET(process, 'PF')

    # Switch to PF jets
    from PhysicsTools.PatAlgos.tools.jetTools import switchJetCollection
    if iRunOnData == True:
        switchJetCollection(process, 
                            cms.InputTag('ak5PFJets'),   
                            doJTA            = True,            
                            doBTagging       = True,            
                            jetCorrLabel     = ('AK5PF', ['L1FastJet', 'L2Relative', 'L3Absolute', 'L2L3Residual']),
                            doType1MET       = True,            
                            doJetID          = False,
                            jetIdLabel       = "ak5"
                            )
    else:
        switchJetCollection(process, 
                            cms.InputTag('ak5PFJets'),   
                            doJTA            = True,            
                            doBTagging       = True,            
                            jetCorrLabel     = ('AK5PF', ['L1FastJet', 'L2Relative', 'L3Absolute']),
                            doType1MET       = True,            
                            genJetCollection = cms.InputTag("ak5GenJetsNoNu"),
                            doJetID          = False,
                            jetIdLabel       = "ak5"
                            )

    from PhysicsTools.PatAlgos.tools.pfTools import usePFIso
    usePFIso(process)

    process.patMuons.isoDeposits = cms.PSet()
    process.patMuons.isolationValues = cms.PSet()
    process.patElectrons.isolationValues = cms.PSet(
        pfChargedHadrons = cms.InputTag("elPFIsoValueCharged03PFIdPFIso"),
        pfChargedAll = cms.InputTag("elPFIsoValueChargedAll03PFIdPFIso"),
        pfPUChargedHadrons = cms.InputTag("elPFIsoValuePU03PFIdPFIso"),
        pfNeutralHadrons = cms.InputTag("elPFIsoValueNeutral03PFIdPFIso"),
        pfPhotons = cms.InputTag("elPFIsoValueGamma03PFIdPFIso")
        )
    process.patElectrons.isolationValuesNoPFId = cms.PSet(
        pfChargedHadrons = cms.InputTag("elPFIsoValueCharged03NoPFIdPFIso"),
        pfChargedAll = cms.InputTag("elPFIsoValueChargedAll03NoPFIdPFIso"),
        pfPUChargedHadrons = cms.InputTag("elPFIsoValuePU03NoPFIdPFIso"),
        pfNeutralHadrons = cms.InputTag("elPFIsoValueNeutral03NoPFIdPFIso"),
        pfPhotons = cms.InputTag("elPFIsoValueGamma03NoPFIdPFIso")
        )
    process.patDefaultSequence.replace(process.patElectrons,process.eleIsoSequence+process.patElectrons)
    process.cleanPatTaus.preselection = cms.string('tauID("decayModeFinding") > 0.5 & tauID("byLooseCombinedIsolationDeltaBetaCorr") > 0.5')
    ###--------------------------------------------------------------
    

    ###--------------------------------------------------------------
    ### Object (pre) selection
    # Jet selection
    process.selectedPatJets.cut = cms.string("pt>10. && abs(eta)<5.")

    # Remove overlaps ???
    # process.cleanPatJets.finalCut = "!hasOverlaps('electrons') && !hasOverlaps('muons')"

    # Apply loose PF jet ID
    from PhysicsTools.SelectorUtils.pfJetIDSelector_cfi import pfJetIDSelector
    process.goodPatJets = cms.EDFilter("PFJetIDSelectionFunctorFilter",
                                       filterParams = pfJetIDSelector.clone(),
                                       src = cms.InputTag("selectedPatJets"),
                                       filter = cms.bool(True)
                                       )

    process.selectedPatMuons.cut = cms.string("isGlobalMuon && pt>10. && abs(eta)<2.5")
    
    process.selectedPatElectrons.cut = cms.string("pt>10. && abs(eta)<2.5")
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### Load the PU JetID sequence
    if iRunOnData == True:
    	process.load("CMGTools.External.pujetidsequence_cff")
    	process.puJetMva.jets = cms.InputTag("goodPatJets")
    	process.puJetId.jets = cms.InputTag("goodPatJets")
    else:
        process.load("CMGTools.External.pujetidsequence_cff")
        process.puJetMva.jets		= cms.InputTag("goodPatJets")
        process.puJetId.jets 		= cms.InputTag("goodPatJets")
	process.puJetMvaSmeared		= process.puJetMva.clone()
	process.puJetIdSmeared		= process.puJetId.clone()  
	process.puJetMvaResUp 		= process.puJetMva.clone()
	process.puJetIdResUp 		= process.puJetId.clone()
        process.puJetMvaResDown		= process.puJetMva.clone()
        process.puJetIdResDown  	= process.puJetId.clone()
        process.puJetMvaEnUp   		= process.puJetMva.clone()
        process.puJetIdEnUp    		= process.puJetId.clone()
        process.puJetMvaEnDown 		= process.puJetMva.clone()
        process.puJetIdEnDown  		= process.puJetId.clone()

        process.puJetIdSmeared.jets     = cms.InputTag("smearedGoodPatJetsWithGaussian")
        process.puJetMvaSmeared.jetids  = cms.InputTag("puJetIdSmeared")
        process.puJetMvaSmeared.jets    = cms.InputTag("smearedGoodPatJetsWithGaussian")

	process.puJetIdResUp.jets 	= cms.InputTag("smearedGoodPatJetsResUpWithGaussian")
	process.puJetMvaResUp.jetids 	= cms.InputTag("puJetIdResUp")
	process.puJetMvaResUp.jets 	= cms.InputTag("smearedGoodPatJetsResUpWithGaussian")

        process.puJetIdResDown.jets     = cms.InputTag("smearedGoodPatJetsResDownWithGaussian")
        process.puJetMvaResDown.jetids  = cms.InputTag("puJetIdResDown")
        process.puJetMvaResDown.jets    = cms.InputTag("smearedGoodPatJetsResDownWithGaussian")

        process.puJetIdEnUp.jets        = cms.InputTag("shiftedGoodPatJetsEnUpForCorrMEtWithGaussian")
        process.puJetMvaEnUp.jetids     = cms.InputTag("puJetIdEnUp")
        process.puJetMvaEnUp.jets       = cms.InputTag("shiftedGoodPatJetsEnUpForCorrMEtWithGaussian")

        process.puJetIdEnDown.jets      = cms.InputTag("shiftedGoodPatJetsEnDownForCorrMEtWithGaussian")
        process.puJetMvaEnDown.jetids   = cms.InputTag("puJetIdEnDown")
        process.puJetMvaEnDown.jets     = cms.InputTag("shiftedGoodPatJetsEnDownForCorrMEtWithGaussian")

	# For jet without Gaussian smearing collection
	process.puJetMvaSmearedNoGaussian	= process.puJetMva.clone()
	process.puJetIdSmearedNoGaussian	= process.puJetId.clone()
	process.puJetMvaResUpNoGaussian         = process.puJetMva.clone()
        process.puJetIdResUpNoGaussian          = process.puJetId.clone()
        process.puJetMvaResDownNoGaussian       = process.puJetMva.clone()
        process.puJetIdResDownNoGaussian        = process.puJetId.clone()
        process.puJetMvaEnUpNoGaussian          = process.puJetMva.clone()
        process.puJetIdEnUpNoGaussian           = process.puJetId.clone()
        process.puJetMvaEnDownNoGaussian        = process.puJetMva.clone()
        process.puJetIdEnDownNoGaussian         = process.puJetId.clone()

	process.puJetIdSmearedNoGaussian.jets     = cms.InputTag("smearedGoodPatJetsNoGaussian")
        process.puJetMvaSmearedNoGaussian.jetids  = cms.InputTag("puJetIdSmearedNoGaussian")
        process.puJetMvaSmearedNoGaussian.jets    = cms.InputTag("smearedGoodPatJetsNoGaussian")

        process.puJetIdResUpNoGaussian.jets       = cms.InputTag("smearedGoodPatJetsResUpNoGaussian")
        process.puJetMvaResUpNoGaussian.jetids    = cms.InputTag("puJetIdResUpNoGaussian")
        process.puJetMvaResUpNoGaussian.jets      = cms.InputTag("smearedGoodPatJetsResUpNoGaussian")

        process.puJetIdResDownNoGaussian.jets     = cms.InputTag("smearedGoodPatJetsResDownNoGaussian")
        process.puJetMvaResDownNoGaussian.jetids  = cms.InputTag("puJetIdResDownNoGaussian")
        process.puJetMvaResDownNoGaussian.jets    = cms.InputTag("smearedGoodPatJetsResDownNoGaussian")

        process.puJetIdEnUpNoGaussian.jets        = cms.InputTag("shiftedGoodPatJetsEnUpForCorrMEtNoGaussian")
        process.puJetMvaEnUpNoGaussian.jetids     = cms.InputTag("puJetIdEnUpNoGaussian")
        process.puJetMvaEnUpNoGaussian.jets       = cms.InputTag("shiftedGoodPatJetsEnUpForCorrMEtNoGaussian")

        process.puJetIdEnDownNoGaussian.jets      = cms.InputTag("shiftedGoodPatJetsEnDownForCorrMEtNoGaussian")
        process.puJetMvaEnDownNoGaussian.jetids   = cms.InputTag("puJetIdEnDownNoGaussian")
        process.puJetMvaEnDownNoGaussian.jets     = cms.InputTag("shiftedGoodPatJetsEnDownForCorrMEtNoGaussian")
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### MET
    # Apply type 0 MET corrections based on PFCandidate
    process.load("JetMETCorrections.Type1MET.pfMETCorrectionType0_cfi")
    process.pfType1CorrectedMet.applyType0Corrections = cms.bool(False)
    process.pfType1CorrectedMet.srcType1Corrections = cms.VInputTag(
        cms.InputTag('pfMETcorrType0'),
        cms.InputTag('pfJetMETcorr', 'type1')
        )

    # Get loose ID/Iso muons and veto ID electrons
    process.load("InvisibleHiggs.Ntuple.PhysicsObjectCandidates_cff")

    # Get PFMET from runMEtUncertainties
    from PhysicsTools.PatUtils.tools.metUncertaintyTools import runMEtUncertainties
    process.load("JetMETCorrections.Type1MET.pfMETsysShiftCorrections_cfi")

    if iRunOnData == True:
        runMEtUncertainties(process,
                            electronCollection = cms.InputTag('selectVetoElectrons'),
                            photonCollection = '',
                            muonCollection = 'selectLooseMuons',
                            tauCollection = '',
                            jetCollection = cms.InputTag('goodPatJets'),
                            jetCorrLabel = 'L2L3Residual',
                            doSmearJets = False,
                            makeType1corrPFMEt = True,
                            makeType1p2corrPFMEt = False,
                            makePFMEtByMVA = False,
                            makeNoPileUpPFMEt = False,
                            doApplyType0corr = True,
                            sysShiftCorrParameter = process.pfMEtSysShiftCorrParameters_2012runAvsNvtx_data,
                            doApplySysShiftCorr = False,
			    addToPatDefaultSequence = False,
			    postfix = ''
                            )
        process.patPFJetMETtype1p2Corr.jetCorrLabel = cms.string('L2L3Residual')
        process.patPFJetMETtype2Corr.jetCorrLabel = cms.string('L2L3Residual')
    else:
        runMEtUncertainties(process,
                            electronCollection = cms.InputTag('selectVetoElectrons'),
                            photonCollection = '',
                            muonCollection = 'selectLooseMuons',
                            tauCollection = '',
                            jetCollection = cms.InputTag('goodPatJets'),
                            jetCorrLabel = 'L3Absolute',
                            doSmearJets = True,
                            makeType1corrPFMEt = True,
                            makeType1p2corrPFMEt = False,
                            makePFMEtByMVA = False,
                            makeNoPileUpPFMEt = False,
                            doApplyType0corr = True,
                            sysShiftCorrParameter = process.pfMEtSysShiftCorrParameters_2012runAvsNvtx_mc,
                            doApplySysShiftCorr = False,
			    addToPatDefaultSequence = False,
			    postfix = 'WithGaussian'
                            )
        runMEtUncertainties(process,
                            electronCollection = cms.InputTag('selectVetoElectrons'),
                            photonCollection = '',
                            muonCollection = 'selectLooseMuons',
                            tauCollection = '',
                            jetCollection = cms.InputTag('goodPatJets'),
                            jetCorrLabel = 'L3Absolute',
                            doSmearJets = True,
                            makeType1corrPFMEt = True,
                            makeType1p2corrPFMEt = False,
                            makePFMEtByMVA = False,
                            makeNoPileUpPFMEt = False,
                            doApplyType0corr = True,
                            sysShiftCorrParameter = process.pfMEtSysShiftCorrParameters_2012runAvsNvtx_mc,
                            doApplySysShiftCorr = False,
                            addToPatDefaultSequence = False,
                            postfix = 'NoGaussian'
                            )
	# Turn off gaussian smearing
    	process.smearedGoodPatJetsNoGaussian.doGaussian = cms.int32(0)
    	process.smearedGoodPatJetsResUpNoGaussian.doGaussian = cms.int32(0)
    	process.smearedGoodPatJetsResDownNoGaussian.doGaussian = cms.int32(0)

    # Fix Type0 correction module
    process.patPFMETtype0Corr.correction.par3 = cms.double(0.909209)
    process.patPFMETtype0Corr.correction.par2 = cms.double(0.0303531)
    process.patPFMETtype0Corr.correction.par1 = cms.double(-0.703151)
    process.patPFMETtype0Corr.correction.par0 = cms.double(0.0)
    ###--------------------------------------------------------------

    # PAT/ntuples one step  
    # Z and W candidates    
    process.load('InvisibleHiggs/Ntuple/WCandidates_cff')
    process.load('InvisibleHiggs/Ntuple/ZCandidates_cff')
    # Ntuple producer       
    process.load('InvisibleHiggs/Ntuple/invHiggsInfo_cfi')
    if iRunOnData == False: 
        # Jet/MET uncertainty
        process.invHiggsInfo.jetTag      = cms.untracked.InputTag("smearedGoodPatJetsWithGaussian")
        process.invHiggsInfo.metTag      = cms.untracked.InputTag("patType1CorrectedPFMetWithGaussian")
        process.invHiggsInfo.puJetMvaTag = cms.untracked.InputTag("puJetMvaSmeared", "fullDiscriminant")
        process.invHiggsInfo.puJetIdTag  = cms.untracked.InputTag("puJetMvaSmeared", "fullId")
                            
        # PU re-weighting   
        process.invHiggsInfo.puMCFile    = cms.untracked.string("PUHistS10.root")
        process.invHiggsInfo.puDataFile  = cms.untracked.string("PUHistRun2012All_forV9.root")
        process.invHiggsInfo.puMCHist    = cms.untracked.string("pileup")
        process.invHiggsInfo.puDataHist  = cms.untracked.string("pileup")
        process.invHiggsInfo.mcPYTHIA    = cms.untracked.bool(True)
        
        process.invHiggsInfo.trigCorrFile   = cms.untracked.string("DataMCWeight_53X_v1.root")

	process.invHiggsInfo.leptCorrFile   = cms.untracked.string("leptonWeights.root")
    # TTree output file     
    process.load("CommonTools.UtilAlgos.TFileService_cfi")
    process.TFileService.fileName = cms.string('invHiggsInfo_MC.root')
    ###--------------------------------------------------------------

    ###--------------------------------------------------------------
    ### Tau
    # removeSpecificPATObjects( process, ['Taus'] )
    # process.patDefaultSequence.remove( process.patTaus )
    process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### Trigger matching
    # from PhysicsTools.PatAlgos.tools.trigTools import *

    # process.metTriggerMatch = cms.EDProducer(
    #     "PATTriggerMatcherDRLessByR"                    # match by DeltaR only, best match by DeltaR
    #     , src     = cms.InputTag( 'patMETs' )
    #     , matched = cms.InputTag( 'patTrigger' )          # default producer label as defined in PhysicsTools/PatAlgos/python/triggerLayer1/triggerProducer_cfi.py
    #     , matchedCuts = cms.string( 'path( "HLT_MET100_v*" )' )
    #     , maxDPtRel = cms.double( 0.5 )
    #     , maxDeltaR = cms.double( 0.5 )
    #     , resolveAmbiguities    = cms.bool( True )        # only one match per trigger object
    #     , resolveByMatchQuality = cms.bool( True )        # take best match found per reco object: by DeltaR here (s. above)
    # )
    # process.jetTriggerMatch = cms.EDProducer(
    #     "PATTriggerMatcherDRLessByR"                    # match by DeltaR only, best match by DeltaR
    #     , src     = cms.InputTag( 'patJets' )
    #     , matched = cms.InputTag( 'patTrigger' )          # default producer label as defined in PhysicsTools/PatAlgos/python/triggerLayer1/triggerProducer_cfi.py
    #     , matchedCuts = cms.string( 'path( "HLT_Jet30_v*" )' )
    #     , maxDPtRel = cms.double( 0.5 )
    #     , maxDeltaR = cms.double( 0.5 )
    #     , resolveAmbiguities    = cms.bool( True )        # only one match per trigger object
    #     , resolveByMatchQuality = cms.bool( True )        # take best match found per reco object: by DeltaR here (s. above)
    # )
    
    # switchOnTriggerMatchEmbedding( process, [ 'metTriggerMatch', 'jetTriggerMatch' ] )
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### Paths
    process.p0 = cms.Path( process.HBHENoiseFilter )
    process.p1 = cms.Path( process.CSCTightHaloFilter )
    process.p2 = cms.Path( process.hcalLaserEventFilter )
    process.p3 = cms.Path( process.EcalDeadCellTriggerPrimitiveFilter )
    process.p4 = cms.Path( process.eeBadScFilter )
    process.p5 = cms.Path( process.ecalLaserCorrFilter )
    process.p6 = cms.Path( process.goodVertices * process.trackingFailureFilter )
    process.p7 = cms.Path( process.trkPOGFilters )
    process.p8 = cms.Path( process.hcallLaserEvent2012Filter )

    if iRunOnData == True:
    	process.p = cms.Path(    
        	# Trigger filter
        	process.hltHighLevel *
        
        	# Basic filters
        	process.noscraping *
        	process.primaryVertexFilter *
        	
        	# MET filters (Move to be flags)
        
        	# MET Correction
        	process.type0PFMEtCorrection *
        
        	# Tau
        	process.recoTauClassicHPSSequence *
        
        	# Generate PAT
        	process.pfParticleSelectionSequence *
        	process.patDefaultSequence *
        	process.goodPatJets *
		process.PhysicsObjectSequence *
		process.metUncertaintySequence *
        	process.puJetIdSqeuence *
		process.WSequence *
                process.ZSequence *
                process.invHiggsInfo
		)
    else:
        process.p = cms.Path(
                # Trigger filter
                process.hltHighLevel *

                # Basic filters
                process.noscraping *
                process.primaryVertexFilter *

                # MET filters (Move to be flags)

                # MET Correction
                process.type0PFMEtCorrection *

                # Tau
                process.recoTauClassicHPSSequence *

                # Generate PAT
                process.pfParticleSelectionSequence *
        	process.genParticlesForJetsNoNu *
                process.ak5GenJetsNoNu *
                process.patDefaultSequence *
                process.goodPatJets *
                process.PhysicsObjectSequence *
                process.metUncertaintySequenceWithGaussian *
		process.metUncertaintySequenceNoGaussian *
                process.puJetIdSqeuence *
		process.puJetIdSmeared *
		process.puJetMvaSmeared *
        	process.puJetIdResUp *
		process.puJetMvaResUp *
         	process.puJetIdResDown *
        	process.puJetMvaResDown *
        	process.puJetIdEnUp *
        	process.puJetMvaEnUp *
        	process.puJetIdEnDown *
        	process.puJetMvaEnDown *
                process.puJetIdSmearedNoGaussian *
                process.puJetMvaSmearedNoGaussian *
                process.puJetIdResUpNoGaussian *
                process.puJetMvaResUpNoGaussian *
                process.puJetIdResDownNoGaussian *
                process.puJetMvaResDownNoGaussian *
                process.puJetIdEnUpNoGaussian *
                process.puJetMvaEnUpNoGaussian *
                process.puJetIdEnDownNoGaussian *
                process.puJetMvaEnDownNoGaussian *
		process.WSequence *
        	process.ZSequence *
                process.invHiggsInfo
        	)
    ###--------------------------------------------------------------


    ###--------------------------------------------------------------
    ### Output
    process.out.outputCommands += [
        # trigger results
        'keep edmTriggerResults_*_*_*'
        ,'keep *_hltTriggerSummaryAOD_*_*'
        # L1
        ,'keep *_l1extraParticles_MET_RECO'
        ,'keep *_l1extraParticles_MHT_RECO'
        # good jets
        ,'keep *_goodPatJets_*_*'
        # PU jet ID
        ,'keep *_puJetId*_*_*'
        ,'keep *_puJetMva*_*_*'
        # vertices
        ,'keep *_offlineBeamSpot_*_*'
        ,'keep *_offlinePrimaryVertices*_*_*'
        ,'keep *_goodOfflinePrimaryVertices*_*_*'
        ,'keep double_*_rho_*'
        ]

    if iRunOnData == False:
        process.out.outputCommands += ['keep GenEventInfoProduct_*_*_*'
                                       ,'keep recoGenParticles_*_*_*'
                                       ,'keep GenMETs_*_*_*'
                                       ,'keep *_addPileupInfo_*_*'
                                       ,'keep LHEEventProduct_*_*_*'
				       ,'keep ak5GenJets_*_*_*'
                                       ,'keep ak5GenJetsNoNu_*_*_*'
                                       ]
        
    process.out.fileName = 'patTuple.root'

    del(process.out)
    del(process.outpath)
Exemple #32
0
def miniAOD_customizeData(process):
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData
    runOnData(process, outputModules=[])
Exemple #33
0
def pat_tuple_process(runOnMC=True, suppress_stdout=True):
    process = cms.Process('PAT')
    process.maxEvents = cms.untracked.PSet(input = cms.untracked.int32(100))
    process.source = cms.Source('PoolSource', fileNames = cms.untracked.vstring('/store/mc/Summer12_DR53X/TTJets_HadronicMGDecays_8TeV-madgraph/AODSIM/PU_S10_START53_V7A-v1/00001/FCAF3F92-5A16-E211-ACCC-E0CB4E19F95A.root' if runOnMC else '/store/data/Run2012B/MultiJet1Parked/AOD/05Nov2012-v2/10000/0003D331-5C49-E211-8210-00259020081C.root'))
    process.options = cms.untracked.PSet(wantSummary = cms.untracked.bool(False))
    process.load('FWCore.MessageLogger.MessageLogger_cfi')
    process.MessageLogger.cerr.FwkReport.reportEvery = 1000000
    process.MessageLogger.cerr.threshold = 'INFO'
    process.MessageLogger.categories.append('PATSummaryTables')
    process.MessageLogger.cerr.PATSummaryTables = cms.untracked.PSet(limit = cms.untracked.int32(-1))
    for category in ['TwoTrackMinimumDistance']:
        process.MessageLogger.categories.append(category)
        setattr(process.MessageLogger.cerr, category, cms.untracked.PSet(limit=cms.untracked.int32(0)))
    process.load('Configuration.Geometry.GeometryIdeal_cff')
    process.load('Configuration.StandardSequences.MagneticField_AutoFromDBCurrent_cff')
    process.load('Configuration.StandardSequences.FrontierConditions_GlobalTag_cff')
    process.GlobalTag.globaltag = 'START53_V27::All' if runOnMC else 'FT53_V21A_AN6::All'
    
    from PhysicsTools.PatAlgos.patEventContent_cff import patEventContent
    process.out = cms.OutputModule('PoolOutputModule',
                                   fileName = cms.untracked.string('pat.root'),
                                   SelectEvents = cms.untracked.PSet(SelectEvents = cms.vstring('p')),
                                   outputCommands = cms.untracked.vstring(*patEventContent),
                                   )
    process.outp = cms.EndPath(process.out)
    
    process.load('JMTucker.Tools.PATTupleSelection_cfi')
    
    # Event cleaning, with MET cleaning recommendations from
    # https://twiki.cern.ch/twiki/bin/view/CMS/MissingETOptionalFilters
    process.load('HLTrigger.special.hltPhysicsDeclared_cfi')
    process.hltPhysicsDeclared.L1GtReadoutRecordTag = 'gtDigis'
    from DPGAnalysis.Skims.goodvertexSkim_cff import noscraping as FilterOutScraping
    process.FilterOutScraping = FilterOutScraping
    process.load('CommonTools.ParticleFlow.goodOfflinePrimaryVertices_cfi')
    process.goodOfflinePrimaryVertices.filter = cms.bool(True)
    process.load('RecoMET.METFilters.metFilters_cff')
    process.trackingFailureFilter.VertexSource = 'goodOfflinePrimaryVertices'
    
    # Instead of filtering out events at tupling time, schedule separate
    # paths for all the "good data" filters so that the results of them
    # get stored in a small TriggerResults::PAT object, which can be
    # accessed later. Make one path for each so they can be accessed
    # separately in the TriggerResults object; the "All" path that is the
    # product of all of the filters isn't necessary but it's nice for
    # convenience.
    process.eventCleaningAll = cms.Path()
    for name in process.jtupleParams.eventFilters.value():
        negate = name.startswith('~')
        name = name.replace('~', '')
        filter_obj = getattr(process, name)
        if negate:
            filter_obj = ~filter_obj
        setattr(process, 'eventCleaning' + name, cms.Path(filter_obj))
        process.eventCleaningAll *= filter_obj
    
    ################################################################################
    
    # PAT/PF2PAT configuration inspired by TopQuarkAnalysis/Configuration
    # (test/patRefSel_allJets_cfg.py and included modules) with tag
    # V07-00-01.
    
    # First, turn off stdout so that the spam from PAT/PF2PAT doesn't
    # flood the screen (especially useful in batch job submission).
    if suppress_stdout:
        print 'tuple.py: PAT would spam a lot of stuff to stdout... hiding it.'
        from cStringIO import StringIO
        old_stdout = sys.stdout
        sys.stdout = buf = StringIO()
    
    jecLevels = ['L1FastJet', 'L2Relative', 'L3Absolute']
    if not runOnMC:
        jecLevels.append('L2L3Residual')
    #jecLevels += ['L5Flavor', 'L7Parton']
    
    postfix = 'PF'
    def processpostfix(name):
        return getattr(process, name + postfix)
    def setprocesspostfix(name, obj):
        setattr(process, name + postfix, obj)
    def InputTagPostFix(name):
        return cms.InputTag(name + postfix)
    
    process.load('PhysicsTools.PatAlgos.patSequences_cff')
    from PhysicsTools.PatAlgos.tools.pfTools import usePF2PAT
    usePF2PAT(process,
              runPF2PAT = True,
              runOnMC = runOnMC,
              jetAlgo = 'AK5',
              postfix = postfix,
              jetCorrections = ('AK5PFchs', jecLevels), # 'chs': using PFnoPU
              typeIMetCorrections = True,
              pvCollection = cms.InputTag('goodOfflinePrimaryVertices'),
              )
    
    processpostfix('pfNoPileUp')  .enable = True  # usePFnoPU
    processpostfix('pfNoMuon')    .enable = True  # useNoMuon
    processpostfix('pfNoElectron').enable = True  # useNoElectron
    processpostfix('pfNoJet')     .enable = True  # useNoJet
    processpostfix('pfNoTau')     .enable = True  # useNoTau
    
    processpostfix('pfPileUp').checkClosestZVertex = False
    processpostfix('pfPileUpIso').checkClosestZVertex = False
    
    processpostfix('pfMuonsFromVertex').d0Cut = processpostfix('pfElectronsFromVertex').d0Cut = 2
    processpostfix('pfMuonsFromVertex').dzCut = processpostfix('pfElectronsFromVertex').dzCut = 2
    
    processpostfix('pfSelectedMuons').cut = 'pt > 5.'
    #processpostfix('pfSelectedMuons').cut += process.jtupleParams.muonCut
    processpostfix('pfIsolatedMuons').isolationCut = 0.2
    
    if False: # pfMuonIsoConeR03
        processpostfix('pfIsolatedMuons').isolationValueMapsCharged  = cms.VInputTag(InputTagPostFix('muPFIsoValueCharged03'))
        processpostfix('pfIsolatedMuons').deltaBetaIsolationValueMap = InputTagPostFix('muPFIsoValuePU03')
        processpostfix('pfIsolatedMuons').isolationValueMapsNeutral  = cms.VInputTag(InputTagPostFix('muPFIsoValueNeutral03'), InputTagPostFix('muPFIsoValueGamma03'))
        processpostfix('pfMuons').isolationValueMapsCharged  = cms.VInputTag(InputTagPostFix('muPFIsoValueCharged03'))
        processpostfix('pfMuons').deltaBetaIsolationValueMap = InputTagPostFix('muPFIsoValuePU03')
        processpostfix('pfMuons').isolationValueMapsNeutral  = cms.VInputTag(InputTagPostFix('muPFIsoValueNeutral03'), InputTagPostFix('muPFIsoValueGamma03'))
        processpostfix('patMuons').isolationValues.pfNeutralHadrons   = InputTagPostFix('muPFIsoValueNeutral03')
        processpostfix('patMuons').isolationValues.pfChargedAll       = InputTagPostFix('muPFIsoValueChargedAll03')
        processpostfix('patMuons').isolationValues.pfPUChargedHadrons = InputTagPostFix('muPFIsoValuePU03')
        processpostfix('patMuons').isolationValues.pfPhotons          = InputTagPostFix('muPFIsoValueGamma03')
        processpostfix('patMuons').isolationValues.pfChargedHadrons   = InputTagPostFix('muPFIsoValueCharged03')
    
    processpostfix('pfSelectedElectrons').cut = 'pt > 5. && gsfTrackRef.isNonnull && gsfTrackRef.trackerExpectedHitsInner.numberOfLostHits < 2'
    #processpostfix('pfSelectedElectrons').cut += ' && ' + process.jtupleParams.electronCut # disabled by default, but can use minimal (veto) electron selection cut on top of pfElectronSelectionCut
    processpostfix('pfIsolatedElectrons').isolationCut = 0.2
    
    if True: # pfElectronIsoConeR03
        processpostfix('pfIsolatedElectrons').isolationValueMapsCharged  = cms.VInputTag(InputTagPostFix('elPFIsoValueCharged03PFId'))
        processpostfix('pfIsolatedElectrons').deltaBetaIsolationValueMap = InputTagPostFix('elPFIsoValuePU03PFId')
        processpostfix('pfIsolatedElectrons').isolationValueMapsNeutral  = cms.VInputTag(InputTagPostFix('elPFIsoValueNeutral03PFId'), InputTagPostFix('elPFIsoValueGamma03PFId'))
        processpostfix('pfElectrons').isolationValueMapsCharged  = cms.VInputTag(InputTagPostFix('elPFIsoValueCharged03PFId'))
        processpostfix('pfElectrons').deltaBetaIsolationValueMap = InputTagPostFix('elPFIsoValuePU03PFId')
        processpostfix('pfElectrons').isolationValueMapsNeutral  = cms.VInputTag(InputTagPostFix('elPFIsoValueNeutral03PFId'), InputTagPostFix('elPFIsoValueGamma03PFId'))
        processpostfix('patElectrons').isolationValues.pfNeutralHadrons   = InputTagPostFix('elPFIsoValueNeutral03PFId')
        processpostfix('patElectrons').isolationValues.pfChargedAll       = InputTagPostFix('elPFIsoValueChargedAll03PFId')
        processpostfix('patElectrons').isolationValues.pfPUChargedHadrons = InputTagPostFix('elPFIsoValuePU03PFId')
        processpostfix('patElectrons').isolationValues.pfPhotons          = InputTagPostFix('elPFIsoValueGamma03PFId')
        processpostfix('patElectrons').isolationValues.pfChargedHadrons   = InputTagPostFix('elPFIsoValueCharged03PFId')
    
    process.load('EgammaAnalysis.ElectronTools.electronIdMVAProducer_cfi')
    processpostfix('patElectrons').electronIDSources.mvaTrigV0    = cms.InputTag("mvaTrigV0")
    processpostfix('patElectrons').electronIDSources.mvaNonTrigV0 = cms.InputTag("mvaNonTrigV0")
    processpostfix('patMuons').embedTrack = True
    processpostfix('patJets').addTagInfos = True
    processpostfix('selectedPatElectrons').cut = process.jtupleParams.electronCut
    processpostfix('selectedPatMuons').cut = process.jtupleParams.muonCut
    processpostfix('selectedPatJets').cut = process.jtupleParams.jetCut
    
    process.load('CMGTools.External.pujetidsequence_cff')
    for x in (process.puJetId, process.puJetMva, process.puJetIdChs, process.puJetMvaChs):
        x.jets = InputTagPostFix('selectedPatJets')
        # fix bug in V00-03-04 of CMGTools/External
        if hasattr(x, 'algos'):
            bad, good = 'RecoJets/JetProducers', 'CMGTools/External'
            for ps in x.algos:
                if hasattr(ps, 'tmvaWeights'):
                    s = ps.tmvaWeights.value()
                    if s.startswith(bad):
                        ps.tmvaWeights = s.replace(bad, good)
    
    from PhysicsTools.PatAlgos.tools.coreTools import runOnData, removeSpecificPATObjects
    if not runOnMC:
        runOnData(process, names = ['All'], postfix = postfix)
    removeSpecificPATObjects(process, names = ['Photons'], postfix = postfix) # will also remove cleaning
    
    # Make some extra SV producers for MFV studies. JMTBAD postfix junk
    for cut in (1., 1.5, 2., 2.5, 3., 3.5, 4., 4.5, 5., 5.5, 6.):
        cut_name = ('%.1f' % cut).replace('.', 'p')
                     
        tag_info_name = 'secondaryVertexMaxDR%sTagInfosAODPF' % cut_name
        tag_info_obj = process.secondaryVertexTagInfosAODPF.clone()
        tag_info_obj.vertexCuts.maxDeltaRToJetAxis = cut
        setattr(process, tag_info_name, tag_info_obj)
        process.patJetsPF.tagInfoSources.append(cms.InputTag(tag_info_name))
    
        processpostfix('patPF2PATSequence').replace(processpostfix('patJets'), tag_info_obj * processpostfix('patJets'))
    
    from JMTucker.Tools.PATTupleSelection_cfi import makeLeptonProducers
    makeLeptonProducers(process, postfix=postfix, params=process.jtupleParams)
    
    common_seq = cms.ignore(process.goodOfflinePrimaryVertices) + cms.ignore(process.mvaTrigV0) + cms.ignore(process.mvaNonTrigV0) + processpostfix('patPF2PATSequence') + process.puJetIdSqeuenceChs
    
    process.load('JMTucker.MFVNeutralino.Vertexer_cff')
    common_seq *= process.mfvVertices
    
    # Require numbers of jets based on the trigger: hadronic channel will
    # have at least a 4-jet trigger (maybe 6!), while semileptonic uses a
    # 3-jet trigger. Dileptonic has no jets in trigger, but we'll require
    # at least one b-tag anyway.
    setprocesspostfix('countPatJetsHadronic',     processpostfix('countPatJets').clone(minNumber = 4))
    setprocesspostfix('countPatJetsSemileptonic', processpostfix('countPatJets').clone(minNumber = 3))
    setprocesspostfix('countPatJetsDileptonic',   processpostfix('countPatJets').clone(minNumber = 1))
    
    channels = ('Hadronic', 'Semileptonic', 'Dileptonic')
    for channel in channels:
        setattr(process, 'p' + channel, cms.Path(common_seq))
    
    process.pHadronic     *= processpostfix('countPatJetsHadronic')
    process.pSemileptonic *= processpostfix('countPatJetsSemileptonic') + process.jtupleSemileptonSequence + process.countSemileptons
    process.pDileptonic   *= processpostfix('countPatJetsDileptonic')   + process.jtupleDileptonSequence   + process.countDileptons
    
    process.out.SelectEvents.SelectEvents = ['p' + channel for channel in channels]
    process.out.outputCommands = [
        'drop *',
        'keep *_selectedPatElectrons*_*_*',
        'keep *_selectedPatMuons*_*_*',
        'keep *_selectedPatJets*_*_*',
        'drop *_selectedPatJetsForMETtype1p2CorrPF_*_*',
        'drop *_selectedPatJetsForMETtype2CorrPF_*_*',
        'keep *_mfvVertices*_*_*',
        'drop CaloTowers_*_*_*',
        'keep *_patMETs*_*_*',
        'keep *_goodOfflinePrimaryVertices_*_*',
        'keep edmTriggerResults_TriggerResults__PAT', # for post-tuple filtering on the goodData paths
        'keep *_puJet*_*_*',
        ]
    
    # The normal TrigReport doesn't state how many events are written
    # total to the file in case of OutputModule's SelectEvents having
    # multiple paths. Add a summary to stdout that so that it is easy to
    # see what the total number of events should be (for debugging CRAB
    # jobs). (This means we can kill the normal TrigReport.)
    process.ORTrigReport = cms.EDAnalyzer('ORTrigReport',
                                          results_src = cms.InputTag('TriggerResults', '', process.name_()),
                                          paths = process.out.SelectEvents.SelectEvents
                                          )
    process.pORTrigReport = cms.EndPath(process.ORTrigReport) # Must be on an EndPath.
    
    # As a simple check of the paths' efficiencies, add some lines to the
    # summary showing stats on events with generator-level muons/electrons
    # in acceptance from W decays.
    if runOnMC:
        for name, cut in [('Muon',     'abs(pdgId) == 13 && abs(eta) < 2.4 && abs(mother.pdgId) == 24 && pt > 20'),
                          ('Electron', 'abs(pdgId) == 11 && abs(eta) < 2.5 && abs(mother.pdgId) == 24 && pt > 20'),
                          ('Lepton',   '((abs(pdgId) == 13 && abs(eta) < 2.4) || (abs(pdgId) == 11 && abs(eta) < 2.5)) && abs(mother.pdgId) == 24 && pt > 20'),
                          ]:
            name = 'gen' + name + 's'
            filter = cms.EDFilter('CandViewSelector', src = cms.InputTag('genParticles'), cut = cms.string(cut))
            counter = cms.EDFilter('CandViewCountFilter', src = cms.InputTag(name), minNumber = cms.uint32(1))
            setattr(process, name,           filter)
            setattr(process, name + 'Count', counter)
            setattr(process, 'p' + name + 'Count', cms.Path(filter*counter))
    
    # Check that the stdout spam from PAT was what we expect.
    if suppress_stdout:
        pat_output = buf.getvalue()
        sys.stdout = old_stdout
        buf.close()
        hsh = hash(pat_output)
        #open('pat_spam.txt', 'wt').write(pat_output)
        hsh_expected = 6563257886911239637 if runOnMC else 3125511795667431709
        print 'PAT is done (spam hash %s, expected %s).' % (hsh, hsh_expected)
        if hsh != hsh_expected:
            from JMTucker.Tools.general import big_warn
            big_warn('Unexpected spam hash! Did you change an option?')

    return process, common_seq