def setupEleTrigger(process, hltProcessName ):
process.load("PhysicsTools.PatAlgos.triggerLayer1.triggerProducer_cff")
process.patTrigger.processName = hltProcessName
process.load("PhysicsTools.PatAlgos.triggerLayer1.triggerMatcher_cfi")
process.electronTriggerMatchHLTEle15LWL1R.src = "selectedPatElectrons"
process.electronTriggerMatchHLTEle15LWL1R.pathNames = cms.vstring()
process.electronTriggerMatchHLTEle15LWL1R.pathNames.append('HLT_Photon15_Cleaned_L1R' )
process.electronTriggerMatchHLTEle15LWL1R.pathNames.append('HLT_Photon10_L1R' )
process.electronTriggerMatchHLTEle15LWL1R.pathNames.append('HLT_Photon10_Cleaned_L1R' )
process.electronTriggerMatchHLTEle15LWL1R.pathNames.append('HLT_Ele10_LW_EleId_L1R' )
process.electronTriggerMatchHLTEle15LWL1R.pathNames.append('HLT_Ele10_SW_EleId_L1R' )
process.electronTriggerMatchHLTEle15LWL1R.pathNames.append('HLT_Ele12_SW_TightEleIdIsol_L1R' )
process.electronTriggerMatchHLTEle15LWL1R.pathNames.append('HLT_Ele12_SW_TighterEleIdIsol_L1R_v1' )
process.electronTriggerMatchHLTEle15LWL1R.pathNames.append('HLT_Ele17_SW_CaloEleId_L1R')
process.electronTriggerMatchHLTEle15LWL1R.maxDeltaR = 0.5
process.electronTriggerMatchHLTEle15LWL1R.maxDPtRel = 999.
process.patTriggerMatcher += process.electronTriggerMatchHLTEle15LWL1R
process.patTriggerMatcher.remove( process.patTriggerMatcherElectron )
process.patTriggerMatcher.remove( process.patTriggerMatcherMuon )
process.patTriggerMatcher.remove( process.patTriggerMatcherTau )
process.patElectronsTriggerMatchEmbedder = cms.EDProducer("PATTriggerMatchElectronEmbedder",
src = cms.InputTag( "selectedPatElectrons" ),
matches = cms.VInputTag( "electronTriggerMatchHLTEle15LWL1R" )
)
process.patTriggerSequence += process.patElectronsTriggerMatchEmbedder
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process )
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
process.patMuons.addPuppiIsolation = cms.bool(True)
process.patMuons.puppiIsolationChargedHadrons = cms.InputTag(
"muonPUPPIIsolation", "h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiIsolationNeutralHadrons = cms.InputTag(
"muonPUPPIIsolation", "h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiIsolationPhotons = cms.InputTag(
"muonPUPPIIsolation", "gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag(
"muonPUPPINoLeptonsIsolation", "h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag(
"muonPUPPINoLeptonsIsolation", "h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationPhotons = cms.InputTag(
"muonPUPPINoLeptonsIsolation",
"gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.computeMiniIso = cms.bool(True)
process.patMuons.computeMuonMVA = cms.bool(True)
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.patElectrons.usePfCandidateMultiMap = True
process.patElectrons.pfCandidateMultiMap = cms.InputTag(
"reducedEgamma", "reducedGsfElectronPfCandMap")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose=cms.InputTag("reducedEgamma", "eidRobustLoose"),
eidRobustTight=cms.InputTag("reducedEgamma", "eidRobustTight"),
eidLoose=cms.InputTag("reducedEgamma", "eidLoose"),
eidTight=cms.InputTag("reducedEgamma", "eidTight"),
eidRobustHighEnergy=cms.InputTag("reducedEgamma",
"eidRobustHighEnergy"),
)
process.patElectrons.addPFClusterIso = cms.bool(True)
#add puppi isolation in miniAOD
process.patElectrons.addPuppiIsolation = cms.bool(True)
process.patElectrons.puppiIsolationChargedHadrons = cms.InputTag(
"egmElectronPUPPIIsolation", "h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiIsolationNeutralHadrons = cms.InputTag(
"egmElectronPUPPIIsolation", "h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiIsolationPhotons = cms.InputTag(
"egmElectronPUPPIIsolation", "gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation", "h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation", "h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiNoLeptonsIsolationPhotons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation",
"gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.computeMiniIso = cms.bool(True)
process.patElectrons.ecalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "eleEcalPFClusIso")
process.patElectrons.hcalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "eleHcalPFClusIso")
process.elPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.addPFClusterIso = cms.bool(True)
#add puppi isolation in miniAOD
process.patPhotons.addPuppiIsolation = cms.bool(True)
process.patPhotons.puppiIsolationChargedHadrons = cms.InputTag(
"egmPhotonPUPPIIsolation", "h+-DR030-")
process.patPhotons.puppiIsolationNeutralHadrons = cms.InputTag(
"egmPhotonPUPPIIsolation", "h0-DR030-")
process.patPhotons.puppiIsolationPhotons = cms.InputTag(
"egmPhotonPUPPIIsolation", "gamma-DR030-")
process.patPhotons.ecalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "phoEcalPFClusIso")
process.patPhotons.hcalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "phoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight'))
process.phPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
#
process.patOOTPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedOOTPhotons")
process.patOOTPhotons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string(
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))"
)
from Configuration.Eras.Modifier_phase2_muon_cff import phase2_muon
phase2_muon.toModify(
process.selectedPatMuons,
cut=
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose') || muonID('ME0MuonArbitrated') || muonID('GEMMuonArbitrated')) )"
)
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string(
"pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure(process)
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone(process, outputModule='')
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I + other PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncForMiniAODProduction
runMetCorAndUncForMiniAODProduction(process,
metType="PF",
jetCollUnskimmed="patJets")
#caloMET computation
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process, labelName="patCaloMet", metSource="caloMetM")
#noHF pfMET =========
task = getPatAlgosToolsTask(process)
process.noHFCands = cms.EDFilter(
"GenericPFCandidateSelector",
src=cms.InputTag("particleFlow"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0"))
task.add(process.noHFCands)
runMetCorAndUncForMiniAODProduction(
process,
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True, #needed for HF removal
jetSelection="pt>15 && abs(eta)<3.",
postfix="NoHF")
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsNoHF', process.slimmedMETs.clone(),
process, task)
process.slimmedMETsNoHF.src = cms.InputTag("patMETsNoHF")
process.slimmedMETsNoHF.rawVariation = cms.InputTag("patPFMetNoHF")
process.slimmedMETsNoHF.t1Uncertainties = cms.InputTag("patPFMetT1%sNoHF")
process.slimmedMETsNoHF.t01Variation = cms.InputTag("patPFMetT0pcT1NoHF")
process.slimmedMETsNoHF.t1SmearedVarsAndUncs = cms.InputTag(
"patPFMetT1Smear%sNoHF")
process.slimmedMETsNoHF.tXYUncForRaw = cms.InputTag("patPFMetTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1 = cms.InputTag("patPFMetT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01 = cms.InputTag(
"patPFMetT0pcT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1Smear = cms.InputTag(
"patPFMetT1SmearTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01Smear = cms.InputTag(
"patPFMetT0pcT1SmearTxyNoHF")
del process.slimmedMETsNoHF.caloMET
# ================== NoHF pfMET
# ================== CHSMET
process.CHSCands = cms.EDFilter("CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("fromPV(0) > 0"))
task.add(process.CHSCands)
process.pfMetCHS = cms.EDProducer(
"PFMETProducer",
src=cms.InputTag("CHSCands"),
alias=cms.string('pfMet'),
globalThreshold=cms.double(0.0),
calculateSignificance=cms.bool(False),
)
task.add(process.pfMetCHS)
addMETCollection(process, labelName="patCHSMet", metSource="pfMetCHS")
process.patCHSMet.computeMETSignificance = cms.bool(False)
# ================== CHSMET
# ================== TrkMET
process.TrkCands = cms.EDFilter(
"CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string(
"charge()!=0 && pvAssociationQuality()>=4 && vertexRef().key()==0")
)
task.add(process.TrkCands)
process.pfMetTrk = cms.EDProducer(
"PFMETProducer",
src=cms.InputTag("TrkCands"),
alias=cms.string('pfMet'),
globalThreshold=cms.double(0.0),
calculateSignificance=cms.bool(False),
)
task.add(process.pfMetTrk)
addMETCollection(process, labelName="patTrkMet", metSource="pfMetTrk")
process.patTrkMet.computeMETSignificance = cms.bool(False)
# ================== TrkMET
## PU JetID
process.load("RecoJets.JetProducers.PileupJetID_cfi")
task.add(process.pileUpJetIDTask)
process.patJets.userData.userFloats.src = [
cms.InputTag("pileupJetId:fullDiscriminant"),
]
process.patJets.userData.userInts.src = [
cms.InputTag("pileupJetId:fullId"),
]
## Quark Gluon Likelihood
process.load('RecoJets.JetProducers.QGTagger_cfi')
task.add(process.QGTaggerTask)
process.patJets.userData.userFloats.src += [
cms.InputTag('QGTagger:qgLikelihood'),
]
## DeepCSV meta discriminators (simple arithmethic on output probabilities)
process.load('RecoBTag.Combined.deepFlavour_cff')
task.add(process.pfDeepCSVDiscriminatorsJetTags)
process.patJets.discriminatorSources.extend([
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:BvsAll'),
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:CvsB'),
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:CvsL'),
])
## CaloJets
process.caloJetMap = cms.EDProducer(
"RecoJetDeltaRValueMapProducer",
src=process.patJets.jetSource,
matched=cms.InputTag("ak4CaloJets"),
distMax=cms.double(0.4),
values=cms.vstring('pt', 'emEnergyFraction'),
valueLabels=cms.vstring('pt', 'emEnergyFraction'),
lazyParser=cms.bool(True))
task.add(process.caloJetMap)
process.patJets.userData.userFloats.src += [
cms.InputTag("caloJetMap:pt"),
cms.InputTag("caloJetMap:emEnergyFraction")
]
#Muon object modifications
from PhysicsTools.PatAlgos.slimming.muonIsolationsPUPPI_cfi import makeInputForPUPPIIsolationMuon
makeInputForPUPPIIsolationMuon(process)
#EGM object modifications
from PhysicsTools.PatAlgos.slimming.egmIsolationsPUPPI_cfi import makeInputForPUPPIIsolationEgm
makeInputForPUPPIIsolationEgm(process)
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
electron_ids = [
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_PHYS14_PU20bx25_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_25ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_50ns_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV60_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_nonTrig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_Trig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_50ns_Trig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV70_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Fall17_94X_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_noIso_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_iso_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Summer16_80X_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring16_GeneralPurpose_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring16_HZZ_V1_cff',
]
switchOnVIDElectronIdProducer(process, DataFormat.MiniAOD, task)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
process.electronRegressionValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
for idmod in electron_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDElectronSelection, None,
False, task)
#heepIDVarValueMaps only exists if HEEP V6.1 or HEEP 7.0 ID has already been loaded
if hasattr(process, 'heepIDVarValueMaps'):
process.heepIDVarValueMaps.elesMiniAOD = cms.InputTag(
'reducedEgamma', 'reducedGedGsfElectrons')
#force HEEP to use miniAOD (otherwise it'll detect the AOD)
process.heepIDVarValueMaps.dataFormat = cms.int32(2)
#add the HEEP trk isol to the slimmed electron, add it to the first FromFloatValMap modifier
for pset in process.slimmedElectrons.modifierConfig.modifications:
if pset.hasParameter(
"modifierName") and pset.modifierName == cms.string(
'EGExtraInfoModifierFromFloatValueMaps'):
pset.electron_config.heepTrkPtIso = cms.InputTag(
"heepIDVarValueMaps", "eleTrkPtIso")
break
#VID Photon IDs
photon_ids = [
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_25ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_50ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_25ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_50ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Fall17_94X_V1_TrueVtx_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Fall17_94X_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Fall17_94X_V1p1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring16_V2p2_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring16_nonTrig_V1_cff'
]
switchOnVIDPhotonIdProducer(process, DataFormat.AOD, task)
process.egmPhotonIsolation.srcToIsolate = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
for iPSet in process.egmPhotonIsolation.isolationConeDefinitions:
iPSet.particleBasedIsolation = cms.InputTag("reducedEgamma",
"reducedPhotonPfCandMap")
process.egmPhotonIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonRegressionValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.particleBasedIsolation = \
cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.photonMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDPhotonSelection, None,
False, task)
#add the cut base IDs bitmaps of which cuts passed
from RecoEgamma.EgammaTools.egammaObjectModifications_tools import makeVIDBitsModifier
egamma_modifications.append(
makeVIDBitsModifier(process, "egmGsfElectronIDs", "egmPhotonIDs"))
#-- Adding boosted taus
from RecoTauTag.Configuration.boostedHPSPFTaus_cfi import addBoostedTaus
addBoostedTaus(process)
process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
process.load("RecoTauTag.Configuration.HPSPFTaus_cff")
#-- Adding customization for 94X 2017 legacy reMniAOD
from Configuration.Eras.Modifier_run2_miniAOD_94XFall17_cff import run2_miniAOD_94XFall17
_makePatTausTaskWithRetrainedMVATauID = process.makePatTausTask.copy()
_makePatTausTaskWithRetrainedMVATauID.add(
process.hpsPFTauDiscriminationByIsolationMVArun2v1DBoldDMwLTTask)
run2_miniAOD_94XFall17.toReplaceWith(
process.makePatTausTask, _makePatTausTaskWithRetrainedMVATauID)
#-- Adding custimization for 80X 2016 legacy reMiniAOD
from Configuration.Eras.Modifier_run2_miniAOD_80XLegacy_cff import run2_miniAOD_80XLegacy
_makePatTausTaskWithTauReReco = process.makePatTausTask.copy()
_makePatTausTaskWithTauReReco.add(process.PFTauTask)
run2_miniAOD_80XLegacy.toReplaceWith(process.makePatTausTask,
_makePatTausTaskWithTauReReco)
#-- Adding LowPt taus
from RecoTauTag.Configuration.LowPtHPSPFTaus_cfi import addLowPtTaus
addLowPtTaus(process)
process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
process.load("RecoTauTag.Configuration.HPSPFTaus_cff")
# Adding puppi jets
if not hasattr(
process,
'ak4PFJetsPuppi'): #MM: avoid confilct with substructure call
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
task.add(process.ak4PFJets)
task.add(process.ak4PFJetsPuppi)
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer(
"JetTracksAssociatorAtVertex",
j2tParametersVX,
jets=cms.InputTag("ak4PFJetsPuppi"))
task.add(process.ak4PFJetsPuppiTracksAssociatorAtVertex)
process.patJetPuppiCharge = cms.EDProducer(
"JetChargeProducer",
src=cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var=cms.string('Pt'),
exp=cms.double(1.0))
task.add(process.patJetPuppiCharge)
noDeepFlavourDiscriminators = [
x.value() for x in process.patJets.discriminatorSources
if not "DeepFlavour" in x.value()
]
addJetCollection(
process,
postfix="",
labelName='Puppi',
jetSource=cms.InputTag('ak4PFJetsPuppi'),
jetCorrections=('AK4PFPuppi', ['L2Relative', 'L3Absolute'], ''),
pfCandidates=cms.InputTag(
'puppi'
), # using Puppi candidates as input for b tagging of Puppi jets
algo='AK',
rParam=0.4,
btagDiscriminators=noDeepFlavourDiscriminators)
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 15")
process.load('PhysicsTools.PatAlgos.slimming.slimmedJets_cfi')
# update slimmed jets to include DeepFlavour (keep same name)
from PhysicsTools.PatAlgos.tools.jetTools import updateJetCollection
# make clone for DeepFlavour-less slimmed jets, so output name is preserved
process.slimmedJetsNoDeepFlavour = process.slimmedJets.clone()
task.add(process.slimmedJetsNoDeepFlavour)
updateJetCollection(
process,
jetSource=cms.InputTag('slimmedJetsNoDeepFlavour'),
# updateJetCollection defaults to MiniAOD inputs but
# here it is made explicit (as in training or MINIAOD redoing)
pvSource=cms.InputTag('offlineSlimmedPrimaryVertices'),
pfCandidates=cms.InputTag('packedPFCandidates'),
svSource=cms.InputTag('slimmedSecondaryVertices'),
muSource=cms.InputTag('slimmedMuons'),
elSource=cms.InputTag('slimmedElectrons'),
jetCorrections=('AK4PFchs',
cms.vstring(['L1FastJet', 'L2Relative',
'L3Absolute']), 'None'),
btagDiscriminators=[
'pfDeepFlavourJetTags:probb',
'pfDeepFlavourJetTags:probbb',
'pfDeepFlavourJetTags:problepb',
'pfDeepFlavourJetTags:probc',
'pfDeepFlavourJetTags:probuds',
'pfDeepFlavourJetTags:probg',
],
postfix='SlimmedDeepFlavour',
printWarning=False)
# slimmedJets with DeepFlavour (remove DeepFlavour-less)
delattr(process, 'slimmedJets')
process.slimmedJets = process.selectedUpdatedPatJetsSlimmedDeepFlavour.clone(
)
# delete module not used anymore (slimmedJets substitutes)
delattr(process, 'selectedUpdatedPatJetsSlimmedDeepFlavour')
task.add(process.slimmedJets)
task.add(process.slimmedJetsAK8)
addToProcessAndTask('slimmedJetsPuppiNoMultiplicities',
process.slimmedJetsNoDeepFlavour.clone(), process,
task)
process.slimmedJetsPuppiNoMultiplicities.src = cms.InputTag(
"selectedPatJetsPuppi")
process.slimmedJetsPuppiNoMultiplicities.packedPFCandidates = cms.InputTag(
"packedPFCandidates")
from PhysicsTools.PatAlgos.patPuppiJetSpecificProducer_cfi import patPuppiJetSpecificProducer
process.patPuppiJetSpecificProducer = patPuppiJetSpecificProducer.clone(
src=cms.InputTag("slimmedJetsPuppiNoMultiplicities"), )
task.add(process.patPuppiJetSpecificProducer)
updateJetCollection(
process,
labelName='PuppiJetSpecific',
jetSource=cms.InputTag('slimmedJetsPuppiNoMultiplicities'),
)
process.updatedPatJetsPuppiJetSpecific.userData.userFloats.src = [
'patPuppiJetSpecificProducer:puppiMultiplicity',
'patPuppiJetSpecificProducer:neutralPuppiMultiplicity',
'patPuppiJetSpecificProducer:neutralHadronPuppiMultiplicity',
'patPuppiJetSpecificProducer:photonPuppiMultiplicity',
'patPuppiJetSpecificProducer:HFHadronPuppiMultiplicity',
'patPuppiJetSpecificProducer:HFEMPuppiMultiplicity'
]
process.slimmedJetsPuppi = process.selectedUpdatedPatJetsPuppiJetSpecific.clone(
)
delattr(process, 'selectedUpdatedPatJetsPuppiJetSpecific')
task.add(process.slimmedJetsPuppi)
## puppi met
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppies
makePuppies(process)
runMetCorAndUncForMiniAODProduction(process,
metType="Puppi",
pfCandColl=cms.InputTag("puppiForMET"),
jetCollUnskimmed="slimmedJetsPuppi",
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
postfix="Puppi")
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsPuppi', process.slimmedMETs.clone(),
process, task)
process.slimmedMETsPuppi.src = cms.InputTag("patMETsPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi")
process.slimmedMETsPuppi.t1Uncertainties = cms.InputTag(
"patPFMetT1%sPuppi")
process.slimmedMETsPuppi.t01Variation = cms.InputTag("patPFMetT0pcT1Puppi")
process.slimmedMETsPuppi.t1SmearedVarsAndUncs = cms.InputTag(
"patPFMetT1Smear%sPuppi")
process.slimmedMETsPuppi.tXYUncForRaw = cms.InputTag("patPFMetTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1 = cms.InputTag("patPFMetT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01 = cms.InputTag(
"patPFMetT0pcT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1Smear = cms.InputTag(
"patPFMetT1SmearTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01Smear = cms.InputTag(
"patPFMetT0pcT1SmearTxyPuppi")
del process.slimmedMETsPuppi.caloMET
# add DetIdAssociatorRecords to EventSetup (for isolatedTracks)
process.load("TrackingTools.TrackAssociator.DetIdAssociatorESProducer_cff")
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
process.patMuons.addPuppiIsolation = cms.bool(True)
process.patMuons.puppiIsolationChargedHadrons = cms.InputTag("muonPUPPIIsolation","h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiIsolationNeutralHadrons = cms.InputTag("muonPUPPIIsolation","h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiIsolationPhotons = cms.InputTag("muonPUPPIIsolation","gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag("muonPUPPINoLeptonsIsolation","h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag("muonPUPPINoLeptonsIsolation","h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationPhotons = cms.InputTag("muonPUPPINoLeptonsIsolation","gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.computeMiniIso = cms.bool(True)
process.patMuons.computeMuonMVA = cms.bool(True)
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.usePfCandidateMultiMap = True
process.patElectrons.pfCandidateMultiMap = cms.InputTag("reducedEgamma","reducedGsfElectronPfCandMap")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose = cms.InputTag("reducedEgamma","eidRobustLoose"),
eidRobustTight = cms.InputTag("reducedEgamma","eidRobustTight"),
eidLoose = cms.InputTag("reducedEgamma","eidLoose"),
eidTight = cms.InputTag("reducedEgamma","eidTight"),
eidRobustHighEnergy = cms.InputTag("reducedEgamma","eidRobustHighEnergy"),
)
process.patElectrons.addPFClusterIso = cms.bool(True)
#add puppi isolation in miniAOD
process.patElectrons.addPuppiIsolation = cms.bool(True)
process.patElectrons.puppiIsolationChargedHadrons = cms.InputTag("egmElectronPUPPIIsolation","h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiIsolationNeutralHadrons = cms.InputTag("egmElectronPUPPIIsolation","h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiIsolationPhotons = cms.InputTag("egmElectronPUPPIIsolation","gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiNoLeptonsIsolationPhotons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.computeMiniIso = cms.bool(True)
process.patElectrons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleEcalPFClusIso")
process.patElectrons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleHcalPFClusIso")
process.elPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.addPFClusterIso = cms.bool(True)
#add puppi isolation in miniAOD
process.patPhotons.addPuppiIsolation = cms.bool(True)
process.patPhotons.puppiIsolationChargedHadrons = cms.InputTag("egmPhotonPUPPIIsolation","h+-DR030-")
process.patPhotons.puppiIsolationNeutralHadrons = cms.InputTag("egmPhotonPUPPIIsolation","h0-DR030-")
process.patPhotons.puppiIsolationPhotons = cms.InputTag("egmPhotonPUPPIIsolation","gamma-DR030-")
process.patPhotons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoEcalPFClusIso")
process.patPhotons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight')
)
process.phPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.patOOTPhotons.photonSource = cms.InputTag("reducedEgamma","reducedOOTPhotons")
process.patOOTPhotons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
from Configuration.Eras.Modifier_phase2_muon_cff import phase2_muon
phase2_muon.toModify(process.selectedPatMuons, cut = "pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose') || muonID('ME0MuonArbitrated') || muonID('GEMMuonArbitrated')) )")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure( process )
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I + other PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncForMiniAODProduction
runMetCorAndUncForMiniAODProduction(process, metType="PF",
jetCollUnskimmed="patJets")
#caloMET computation
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process,
labelName = "patCaloMet",
metSource = "caloMetM"
)
#noHF pfMET =========
task = getPatAlgosToolsTask(process)
process.noHFCands = cms.EDFilter("GenericPFCandidateSelector",
src=cms.InputTag("particleFlow"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0")
)
task.add(process.noHFCands)
runMetCorAndUncForMiniAODProduction(process,
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True, #needed for HF removal
jetSelection="pt>15 && abs(eta)<3.",
postfix="NoHF"
)
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsNoHF', process.slimmedMETs.clone(), process, task)
process.slimmedMETsNoHF.src = cms.InputTag("patMETsNoHF")
process.slimmedMETsNoHF.rawVariation = cms.InputTag("patPFMetNoHF")
process.slimmedMETsNoHF.t1Uncertainties = cms.InputTag("patPFMetT1%sNoHF")
process.slimmedMETsNoHF.t01Variation = cms.InputTag("patPFMetT0pcT1NoHF")
process.slimmedMETsNoHF.t1SmearedVarsAndUncs = cms.InputTag("patPFMetT1Smear%sNoHF")
process.slimmedMETsNoHF.tXYUncForRaw = cms.InputTag("patPFMetTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1 = cms.InputTag("patPFMetT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01 = cms.InputTag("patPFMetT0pcT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1Smear = cms.InputTag("patPFMetT1SmearTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01Smear = cms.InputTag("patPFMetT0pcT1SmearTxyNoHF")
del process.slimmedMETsNoHF.caloMET
# ================== NoHF pfMET
# ================== CHSMET
process.CHSCands = cms.EDFilter("CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("fromPV(0) > 0")
)
task.add(process.CHSCands)
process.pfMetCHS = cms.EDProducer("PFMETProducer",
src = cms.InputTag("CHSCands"),
alias = cms.string('pfMet'),
globalThreshold = cms.double(0.0),
calculateSignificance = cms.bool(False),
)
task.add(process.pfMetCHS)
addMETCollection(process,
labelName = "patCHSMet",
metSource = "pfMetCHS"
)
process.patCHSMet.computeMETSignificance = cms.bool(False)
# ================== CHSMET
# ================== TrkMET
process.TrkCands = cms.EDFilter("CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("charge()!=0 && pvAssociationQuality()>=4 && vertexRef().key()==0")
)
task.add(process.TrkCands)
process.pfMetTrk = cms.EDProducer("PFMETProducer",
src = cms.InputTag("TrkCands"),
alias = cms.string('pfMet'),
globalThreshold = cms.double(0.0),
calculateSignificance = cms.bool(False),
)
task.add(process.pfMetTrk)
addMETCollection(process,
labelName = "patTrkMet",
metSource = "pfMetTrk"
)
process.patTrkMet.computeMETSignificance = cms.bool(False)
# ================== TrkMET
## PU JetID
process.load("RecoJets.JetProducers.PileupJetID_cfi")
task.add(process.pileUpJetIDTask)
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
process.patJets.userData.userInts.src = [ cms.InputTag("pileupJetId:fullId"), ]
## Quark Gluon Likelihood
process.load('RecoJets.JetProducers.QGTagger_cfi')
task.add(process.QGTaggerTask)
process.patJets.userData.userFloats.src += [ cms.InputTag('QGTagger:qgLikelihood'), ]
## CaloJets
process.caloJetMap = cms.EDProducer("RecoJetDeltaRValueMapProducer",
src = process.patJets.jetSource,
matched = cms.InputTag("ak4CaloJets"),
distMax = cms.double(0.4),
values = cms.vstring('pt','emEnergyFraction'),
valueLabels = cms.vstring('pt','emEnergyFraction'),
lazyParser = cms.bool(True) )
task.add(process.caloJetMap)
process.patJets.userData.userFloats.src += [ cms.InputTag("caloJetMap:pt"), cms.InputTag("caloJetMap:emEnergyFraction") ]
#Muon object modifications
from PhysicsTools.PatAlgos.slimming.muonIsolationsPUPPI_cfi import makeInputForPUPPIIsolationMuon
makeInputForPUPPIIsolationMuon(process)
#EGM object modifications
from PhysicsTools.PatAlgos.slimming.egmIsolationsPUPPI_cfi import makeInputForPUPPIIsolationEgm
makeInputForPUPPIIsolationEgm(process)
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
electron_ids = ['RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_PHYS14_PU20bx25_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_25ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_50ns_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV60_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_nonTrig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_Trig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_50ns_Trig_V1_cff']
switchOnVIDElectronIdProducer(process,DataFormat.MiniAOD, task)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
process.electronRegressionValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
for idmod in electron_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDElectronSelection,None,False,task)
#heepIDVarValueMaps only exists if HEEP V6.1 or HEEP 7.0 ID has already been loaded
if hasattr(process,'heepIDVarValueMaps'):
process.heepIDVarValueMaps.elesMiniAOD = cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
#force HEEP to use miniAOD (otherwise it'll detect the AOD)
process.heepIDVarValueMaps.dataFormat = cms.int32(2)
#VID Photon IDs
photon_ids = ['RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_25ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_50ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_25ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_50ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring16_V2p2_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring16_nonTrig_V1_cff']
switchOnVIDPhotonIdProducer(process,DataFormat.AOD, task)
process.egmPhotonIsolation.srcToIsolate = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
for iPSet in process.egmPhotonIsolation.isolationConeDefinitions:
iPSet.particleBasedIsolation = cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.egmPhotonIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonRegressionValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.particleBasedIsolation = \
cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.photonMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDPhotonSelection,None,False,task)
#---------------------------------------------------------------------------
#Adding Boosted Subjets taus
from RecoTauTag.Configuration.boostedHPSPFTaus_cfi import addBoostedTaus
addBoostedTaus(process)
#---------------------------------------------------------------------------
#Adding tau reco for 80X legacy reMiniAOD
#make a copy of makePatTauTask to avoid labels and substitution problems
_makePatTausTaskWithTauReReco = process.makePatTausTask.copy()
#add PFTau reco modules to cloned makePatTauTask
process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
_makePatTausTaskWithTauReReco.add(process.PFTauTask)
#replace original task by extended one for the miniAOD_80XLegacy era
from Configuration.Eras.Modifier_run2_miniAOD_80XLegacy_cff import run2_miniAOD_80XLegacy
run2_miniAOD_80XLegacy.toReplaceWith(
process.makePatTausTask, _makePatTausTaskWithTauReReco)
#---------------------------------------------------------------------------
# Adding puppi jets
if not hasattr(process, 'ak4PFJetsPuppi'): #MM: avoid confilct with substructure call
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
task.add(process.ak4PFJets)
task.add(process.ak4PFJetsPuppi)
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer("JetTracksAssociatorAtVertex",
j2tParametersVX,
jets = cms.InputTag("ak4PFJetsPuppi")
)
task.add(process.ak4PFJetsPuppiTracksAssociatorAtVertex)
process.patJetPuppiCharge = cms.EDProducer("JetChargeProducer",
src = cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var = cms.string('Pt'),
exp = cms.double(1.0)
)
task.add(process.patJetPuppiCharge)
addJetCollection(process, postfix = "", labelName = 'Puppi', jetSource = cms.InputTag('ak4PFJetsPuppi'),
jetCorrections = ('AK4PFPuppi', ['L2Relative', 'L3Absolute'], ''),
pfCandidates = cms.InputTag('puppi'), # using Puppi candidates as input for b tagging of Puppi jets
algo= 'AK', rParam = 0.4, btagDiscriminators = map(lambda x: x.value() ,process.patJets.discriminatorSources)
)
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 15")
process.load('PhysicsTools.PatAlgos.slimming.slimmedJets_cfi')
task.add(process.slimmedJets)
task.add(process.slimmedJetsAK8)
addToProcessAndTask('slimmedJetsPuppi', process.slimmedJets.clone(), process, task)
process.slimmedJetsPuppi.src = cms.InputTag("selectedPatJetsPuppi")
process.slimmedJetsPuppi.packedPFCandidates = cms.InputTag("packedPFCandidates")
## puppi met
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppies
makePuppies( process );
runMetCorAndUncForMiniAODProduction(process, metType="Puppi",
pfCandColl=cms.InputTag("puppiForMET"),
jetCollUnskimmed="slimmedJetsPuppi",
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
postfix="Puppi"
)
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsPuppi', process.slimmedMETs.clone(), process, task)
process.slimmedMETsPuppi.src = cms.InputTag("patMETsPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi")
process.slimmedMETsPuppi.t1Uncertainties = cms.InputTag("patPFMetT1%sPuppi")
process.slimmedMETsPuppi.t01Variation = cms.InputTag("patPFMetT0pcT1Puppi")
process.slimmedMETsPuppi.t1SmearedVarsAndUncs = cms.InputTag("patPFMetT1Smear%sPuppi")
process.slimmedMETsPuppi.tXYUncForRaw = cms.InputTag("patPFMetTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1 = cms.InputTag("patPFMetT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01 = cms.InputTag("patPFMetT0pcT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1Smear = cms.InputTag("patPFMetT1SmearTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01Smear = cms.InputTag("patPFMetT0pcT1SmearTxyPuppi")
del process.slimmedMETsPuppi.caloMET
# add DetIdAssociatorRecords to EventSetup (for isolatedTracks)
process.load("TrackingTools.TrackAssociator.DetIdAssociatorESProducer_cff")
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose = cms.InputTag("reducedEgamma","eidRobustLoose"),
eidRobustTight = cms.InputTag("reducedEgamma","eidRobustTight"),
eidLoose = cms.InputTag("reducedEgamma","eidLoose"),
eidTight = cms.InputTag("reducedEgamma","eidTight"),
eidRobustHighEnergy = cms.InputTag("reducedEgamma","eidRobustHighEnergy"),
)
process.elPFIsoDepositCharged.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAll.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutral.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGamma.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPU.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight')
)
process.phPFIsoDepositCharged.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAll.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutral.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGamma.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPU.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 18. && tauID('decayModeFinding')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
# add CMS top tagger
from RecoJets.JetProducers.caTopTaggers_cff import caTopTagInfos as toptag
process.cmsttRaw = toptag.clone()
process.caTopTagInfos = cms.EDProducer("RecoJetDeltaRTagInfoValueMapProducer",
src = cms.InputTag("ak8PFJetsCHS"),
matched = cms.InputTag("cmsTopTagPFJetsCHS"),
matchedTagInfos = cms.InputTag("cmsttRaw"),
distMax = cms.double(0.8)
)
#add AK8
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
addJetCollection(process, labelName = 'AK8',
jetSource = cms.InputTag('ak8PFJetsCHS'),
algo= 'AK', rParam = 0.8,
jetCorrections = ('AK8PFchs', cms.vstring(['L1FastJet', 'L2Relative', 'L3Absolute']), 'None'),
btagInfos = ['caTopTagInfos']
)
process.patJetsAK8.userData.userFloats.src = [] # start with empty list of user floats
process.selectedPatJetsAK8.cut = cms.string("pt > 100")
process.patJetGenJetMatchAK8.matched = 'slimmedGenJets'
## AK8 groomed masses
from RecoJets.Configuration.RecoPFJets_cff import ak8PFJetsCHSPruned, ak8PFJetsCHSFiltered, ak8PFJetsCHSTrimmed
process.ak8PFJetsCHSPruned = ak8PFJetsCHSPruned.clone()
process.ak8PFJetsCHSTrimmed = ak8PFJetsCHSTrimmed.clone()
process.ak8PFJetsCHSFiltered = ak8PFJetsCHSFiltered.clone()
process.load("RecoJets.JetProducers.ak8PFJetsCHS_groomingValueMaps_cfi")
process.patJetsAK8.userData.userFloats.src += ['ak8PFJetsCHSPrunedLinks','ak8PFJetsCHSTrimmedLinks','ak8PFJetsCHSFilteredLinks']
# Add AK8 top tagging variables
process.patJetsAK8.tagInfoSources = cms.VInputTag(cms.InputTag("caTopTagInfos"))
process.patJetsAK8.addTagInfos = cms.bool(True)
# add Njetiness
process.load('RecoJets.JetProducers.nJettinessAdder_cfi')
process.NjettinessAK8 = process.Njettiness.clone()
process.NjettinessAK8.src = cms.InputTag("ak8PFJetsCHS")
process.NjettinessAK8.cone = cms.double(0.8)
process.patJetsAK8.userData.userFloats.src += ['NjettinessAK8:tau1','NjettinessAK8:tau2','NjettinessAK8:tau3']
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
# FIXME: this and the typeI MET should become AK4 once we have the proper JEC?
from PhysicsTools.PatUtils.tools.runType1PFMEtUncertainties import runType1PFMEtUncertainties
addJetCollection(process, postfix = "ForMetUnc", labelName = 'AK4PF', jetSource = cms.InputTag('ak4PFJets'), jetCorrections = ('AK4PF', ['L1FastJet', 'L2Relative', 'L3Absolute'], ''))
process.patJetsAK4PFForMetUnc.getJetMCFlavour = False
runType1PFMEtUncertainties(process,
addToPatDefaultSequence=False,
jetCollection="selectedPatJetsAK4PFForMetUnc",
electronCollection="selectedPatElectrons",
muonCollection="selectedPatMuons",
tauCollection="selectedPatTaus",
makeType1p2corrPFMEt=True,
outputModule=None)
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).p4.M):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).nTracks):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).value):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).significance):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).p4.x):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).p4.y):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).p4.z):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).position.x):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).position.y):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).position.z):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring('vtxMass','vtxNtracks','vtx3DVal','vtx3DSig','vtxPx','vtxPy','vtxPz','vtxPosX','vtxPosY','vtxPosZ')
process.patJets.tagInfoSources = cms.VInputTag(cms.InputTag("secondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("PhysicsTools.PatAlgos.slimming.pileupJetId_cfi")
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
#VID Electron IDs
electron_ids = ['RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_CSA14_50ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_CSA14_PU20bx25_V0_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV50_CSA14_25ns_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV50_CSA14_startup_cff']
switchOnVIDElectronIdProducer(process)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronIDValueMapProducer.ebReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedEBRecHits")
process.electronIDValueMapProducer.eeReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedEERecHits")
process.electronIDValueMapProducer.esReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedESRecHits")
for idmod in electron_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDElectronSelection)
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose=cms.InputTag("reducedEgamma", "eidRobustLoose"),
eidRobustTight=cms.InputTag("reducedEgamma", "eidRobustTight"),
eidLoose=cms.InputTag("reducedEgamma", "eidLoose"),
eidTight=cms.InputTag("reducedEgamma", "eidTight"),
eidRobustHighEnergy=cms.InputTag("reducedEgamma",
"eidRobustHighEnergy"),
)
process.elPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight'))
process.phPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string(
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))"
)
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string(
"pt > 18. && tauID('decayModeFinding')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
# add CMS top tagger
from RecoJets.JetProducers.caTopTaggers_cff import caTopTagInfos
process.caTopTagInfos = caTopTagInfos.clone()
process.caTopTagInfosPAT = cms.EDProducer(
"RecoJetDeltaRTagInfoValueMapProducer",
src=cms.InputTag("ak8PFJetsCHS"),
matched=cms.InputTag("cmsTopTagPFJetsCHS"),
matchedTagInfos=cms.InputTag("caTopTagInfos"),
distMax=cms.double(0.8))
#add AK8
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
addJetCollection(
process,
labelName='AK8',
jetSource=cms.InputTag('ak8PFJetsCHS'),
algo='AK',
rParam=0.8,
jetCorrections=('AK8PFchs',
cms.vstring(['L1FastJet', 'L2Relative',
'L3Absolute']), 'None'),
btagInfos=['caTopTagInfosPAT'])
process.patJetsAK8.userData.userFloats.src = [
] # start with empty list of user floats
process.selectedPatJetsAK8.cut = cms.string("pt > 100")
process.patJetGenJetMatchAK8.matched = 'slimmedGenJets'
## AK8 groomed masses
from RecoJets.Configuration.RecoPFJets_cff import ak8PFJetsCHSPruned, ak8PFJetsCHSSoftDrop, ak8PFJetsCHSFiltered, ak8PFJetsCHSTrimmed
process.ak8PFJetsCHSPruned = ak8PFJetsCHSPruned.clone()
process.ak8PFJetsCHSSoftDrop = ak8PFJetsCHSSoftDrop.clone()
process.ak8PFJetsCHSTrimmed = ak8PFJetsCHSTrimmed.clone()
process.ak8PFJetsCHSFiltered = ak8PFJetsCHSFiltered.clone()
process.load("RecoJets.JetProducers.ak8PFJetsCHS_groomingValueMaps_cfi")
process.patJetsAK8.userData.userFloats.src += [
'ak8PFJetsCHSPrunedMass', 'ak8PFJetsCHSSoftDropMass',
'ak8PFJetsCHSTrimmedMass', 'ak8PFJetsCHSFilteredMass'
]
# Add AK8 top tagging variables
process.patJetsAK8.tagInfoSources = cms.VInputTag(
cms.InputTag("caTopTagInfosPAT"))
process.patJetsAK8.addTagInfos = cms.bool(True)
# add Njetiness
process.load('RecoJets.JetProducers.nJettinessAdder_cfi')
process.NjettinessAK8 = process.Njettiness.clone()
process.NjettinessAK8.src = cms.InputTag("ak8PFJetsCHS")
process.NjettinessAK8.cone = cms.double(0.8)
process.patJetsAK8.userData.userFloats.src += [
'NjettinessAK8:tau1', 'NjettinessAK8:tau2', 'NjettinessAK8:tau3'
]
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone(process, outputModule='')
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
# FIXME: this and the typeI MET should become AK4 once we have the proper JEC?
from PhysicsTools.PatUtils.tools.runType1PFMEtUncertainties import runType1PFMEtUncertainties
addJetCollection(process,
postfix="ForMetUnc",
labelName='AK4PF',
jetSource=cms.InputTag('ak4PFJets'),
jetCorrections=('AK4PF',
['L1FastJet', 'L2Relative',
'L3Absolute'], ''))
process.patJetsAK4PFForMetUnc.getJetMCFlavour = False
runType1PFMEtUncertainties(process,
addToPatDefaultSequence=False,
jetCollection="selectedPatJetsAK4PFForMetUnc",
electronCollection="selectedPatElectrons",
muonCollection="selectedPatMuons",
tauCollection="selectedPatTaus",
makeType1p2corrPFMEt=True,
outputModule=None)
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.M):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).numberOfSourceCandidatePtrs):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).value):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).significance):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.z):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.z):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring(
'vtxMass', 'vtxNtracks', 'vtx3DVal', 'vtx3DSig', 'vtxPx', 'vtxPy',
'vtxPz', 'vtxPosX', 'vtxPosY', 'vtxPosZ')
process.patJets.tagInfoSources = cms.VInputTag(
cms.InputTag("pfSecondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("PhysicsTools.PatAlgos.slimming.pileupJetId_cfi")
process.patJets.userData.userFloats.src = [
cms.InputTag("pileupJetId:fullDiscriminant"),
]
#VID Electron IDs
electron_ids = [
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_CSA14_50ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_CSA14_PU20bx25_V0_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV50_CSA14_25ns_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV50_CSA14_startup_cff'
]
switchOnVIDElectronIdProducer(process)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronIDValueMapProducer.ebReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedEBRecHits")
process.electronIDValueMapProducer.eeReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedEERecHits")
process.electronIDValueMapProducer.esReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedESRecHits")
for idmod in electron_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDElectronSelection)
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose = cms.InputTag("reducedEgamma","eidRobustLoose"),
eidRobustTight = cms.InputTag("reducedEgamma","eidRobustTight"),
eidLoose = cms.InputTag("reducedEgamma","eidLoose"),
eidTight = cms.InputTag("reducedEgamma","eidTight"),
eidRobustHighEnergy = cms.InputTag("reducedEgamma","eidRobustHighEnergy"),
)
process.patElectrons.addPFClusterIso = cms.bool(True)
process.patElectrons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleEcalPFClusIso")
process.patElectrons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleHcalPFClusIso")
process.elPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.addPFClusterIso = cms.bool(True)
process.patPhotons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoEcalPFClusIso")
process.patPhotons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight')
)
process.phPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure( process )
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I + other PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncForMiniAODProduction
runMetCorAndUncForMiniAODProduction(process, metType="PF",
jetCollUnskimmed="patJets",
jetColl="selectedPatJets")
#caloMET computation
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process,
labelName = "patCaloMet",
metSource = "caloMetM"
)
#noHF pfMET =========
process.noHFCands = cms.EDFilter("GenericPFCandidateSelector",
src=cms.InputTag("particleFlow"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0")
)
runMetCorAndUncForMiniAODProduction(process,
pfCandColl=cms.InputTag("noHFCands"),
recomputeMET=True, #needed for HF removal
postfix="NoHF"
)
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
process.slimmedMETsNoHF = process.slimmedMETs.clone()
process.slimmedMETsNoHF.src = cms.InputTag("patMETsNoHF")
process.slimmedMETsNoHF.rawVariation = cms.InputTag("patPFMetNoHF")
process.slimmedMETsNoHF.t1Uncertainties = cms.InputTag("patPFMetT1%sNoHF")
process.slimmedMETsNoHF.t01Variation = cms.InputTag("patPFMetT0pcT1NoHF")
process.slimmedMETsNoHF.t1SmearedVarsAndUncs = cms.InputTag("patPFMetT1Smear%sNoHF")
process.slimmedMETsNoHF.tXYUncForRaw = cms.InputTag("patPFMetTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1 = cms.InputTag("patPFMetT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01 = cms.InputTag("patPFMetT0pcT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1Smear = cms.InputTag("patPFMetT1SmearTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01Smear = cms.InputTag("patPFMetT0pcT1SmearTxyNoHF")
del process.slimmedMETsNoHF.caloMET
# ================== NoHF pfMET
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.M):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).numberOfSourceCandidatePtrs):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).value):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).significance):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.z):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.z):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring('vtxMass','vtxNtracks','vtx3DVal','vtx3DSig','vtxPx','vtxPy','vtxPz','vtxPosX','vtxPosY','vtxPosZ')
process.patJets.tagInfoSources = cms.VInputTag(cms.InputTag("pfSecondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("RecoJets.JetProducers.PileupJetID_cfi")
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
## CaloJets
process.caloJetMap = cms.EDProducer("RecoJetDeltaRValueMapProducer",
src = process.patJets.jetSource,
matched = cms.InputTag("ak4CaloJets"),
distMax = cms.double(0.4),
values = cms.vstring('pt','emEnergyFraction'),
valueLabels = cms.vstring('pt','emEnergyFraction'),
lazyParser = cms.bool(True) )
process.patJets.userData.userFloats.src += [ cms.InputTag("caloJetMap:pt"), cms.InputTag("caloJetMap:emEnergyFraction") ]
#EGM object modifications
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
electron_ids = ['RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_PHYS14_PU20bx25_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_25ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_50ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV60_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_nonTrig_V1_cff']
switchOnVIDElectronIdProducer(process,DataFormat.MiniAOD)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
process.electronRegressionValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
for idmod in electron_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDElectronSelection,None,False)
#VID Photon IDs
photon_ids = ['RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_PHYS14_PU20bx25_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_50ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_25ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_50ns_nonTrig_V2p1_cff']
switchOnVIDPhotonIdProducer(process,DataFormat.MiniAOD)
process.egmPhotonIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonRegressionValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.particleBasedIsolation = \
cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.photonMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDPhotonSelection,None,False)
# Adding puppi jets
process.load('CommonTools.PileupAlgos.Puppi_cff')
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
#process.puppi.candName = cms.InputTag('packedPFCandidates')
#process.puppi.vertexName = cms.InputTag('offlineSlimmedPrimaryVertices')
# kind of ugly, is there a better way to do this?
process.pfNoLepPUPPI = cms.EDFilter("PdgIdCandViewSelector",
src = cms.InputTag("particleFlow"),
pdgId = cms.vint32( 1,2,22,111,130,310,2112,211,-211,321,-321,999211,2212,-2212 )
)
process.pfLeptonsPUPPET = cms.EDFilter("PdgIdCandViewSelector",
src = cms.InputTag("particleFlow"),
pdgId = cms.vint32(-11,11,-13,13),
)
process.puppiNoLep = process.puppi.clone()
process.puppiNoLep.candName = cms.InputTag('pfNoLepPUPPI')
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer("JetTracksAssociatorAtVertex",
j2tParametersVX,
jets = cms.InputTag("ak4PFJetsPuppi")
)
process.patJetPuppiCharge = cms.EDProducer("JetChargeProducer",
src = cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var = cms.string('Pt'),
exp = cms.double(1.0)
)
addJetCollection(process, postfix = "", labelName = 'Puppi', jetSource = cms.InputTag('ak4PFJetsPuppi'),
jetCorrections = ('AK4PFchs', ['L2Relative', 'L3Absolute'], ''),
algo= 'AK', rParam = 0.4, btagDiscriminators = map(lambda x: x.value() ,process.patJets.discriminatorSources)
)
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.userData.userFloats.src = cms.VInputTag(cms.InputTag(""))
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 20")
process.load('PhysicsTools.PatAlgos.slimming.slimmedJets_cfi')
process.slimmedJetsPuppi = process.slimmedJets.clone()
process.slimmedJetsPuppi.src = cms.InputTag("selectedPatJetsPuppi")
process.slimmedJetsPuppi.packedPFCandidates = cms.InputTag("packedPFCandidates")
## puppi met
process.load('RecoMET.METProducers.PFMET_cfi')
process.puppiForMET = cms.EDProducer("CandViewMerger",
src = cms.VInputTag( "pfLeptonsPUPPET", "puppiNoLep")
)
process.pfMetPuppi = process.pfMet.clone()
process.pfMetPuppi.src = cms.InputTag("puppiForMET")
process.pfMetPuppi.alias = cms.string('pfMetPuppi')
# type1 correction, from puppi jets
process.corrPfMetType1Puppi = process.corrPfMetType1.clone(
src = 'ak4PFJetsPuppi',
jetCorrLabel = 'ak4PFCHSL2L3Corrector',
)
del process.corrPfMetType1Puppi.offsetCorrLabel # no L1 for PUPPI jets
process.pfMetT1Puppi = process.pfMetT1.clone(
src = 'pfMetPuppi',
srcCorrections = [ cms.InputTag("corrPfMetType1Puppi","type1") ]
)
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process, labelName='patMETPuppi', metSource='pfMetT1Puppi') # T1
addMETCollection(process, labelName='patPFMetPuppi', metSource='pfMetPuppi') # RAW
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
process.slimmedMETsPuppi = process.slimmedMETs.clone()
process.slimmedMETsPuppi.src = cms.InputTag("patMETPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi") # only central value
# only central values for puppi met
del process.slimmedMETsPuppi.t01Variation
del process.slimmedMETsPuppi.t1SmearedVarsAndUncs
del process.slimmedMETsPuppi.tXYUncForRaw
del process.slimmedMETsPuppi.tXYUncForT1
del process.slimmedMETsPuppi.tXYUncForT01
del process.slimmedMETsPuppi.tXYUncForT1Smear
del process.slimmedMETsPuppi.tXYUncForT01Smear
del process.slimmedMETsPuppi.caloMET
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose = cms.InputTag("reducedEgamma","eidRobustLoose"),
eidRobustTight = cms.InputTag("reducedEgamma","eidRobustTight"),
eidLoose = cms.InputTag("reducedEgamma","eidLoose"),
eidTight = cms.InputTag("reducedEgamma","eidTight"),
eidRobustHighEnergy = cms.InputTag("reducedEgamma","eidRobustHighEnergy"),
)
process.elPFIsoDepositCharged.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAll.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutral.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGamma.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPU.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight')
)
process.phPFIsoDepositCharged.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAll.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutral.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGamma.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPU.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 20 && tauID('decayModeFinding')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
#
from PhysicsTools.PatAlgos.tools.jetTools import switchJetCollection
#switch to AK4 (though it should soon be unnecessary as ak4 should become the 71X default)
#FIXME: still using AK5PFchs for jet energy corrections, while waiting for a new globalTag
switchJetCollection(process, jetSource = cms.InputTag('ak4PFJetsCHS'),
jetCorrections = ('AK5PFchs', cms.vstring(['L1FastJet', 'L2Relative', 'L3Absolute']), ''),
btagDiscriminators = ['jetBProbabilityBJetTags', 'jetProbabilityBJetTags', 'trackCountingHighPurBJetTags', 'trackCountingHighEffBJetTags', 'simpleSecondaryVertexHighEffBJetTags',
'simpleSecondaryVertexHighPurBJetTags', 'combinedSecondaryVertexBJetTags' , 'combinedInclusiveSecondaryVertexBJetTags' ],
)
#add CA8
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
#
addJetCollection(process, labelName = 'CA8', jetSource = cms.InputTag('ca8PFJetsCHS'),algo= 'CA', rParam = 0.8)
process.selectedPatJetsCA8.cut = cms.string("pt > 100")
process.patJetGenJetMatchCA8.matched = 'slimmedGenJets'
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
# FIXME: this and the typeI MET should become AK4 once we have the proper JEC?
from PhysicsTools.PatUtils.tools.metUncertaintyTools import runMEtUncertainties
addJetCollection(process, postfix = "ForMetUnc", labelName = 'AK5PF', jetSource = cms.InputTag('ak5PFJets'), jetCorrections = ('AK5PF', ['L1FastJet', 'L2Relative', 'L3Absolute'], ''))
process.patJetsAK5PFForMetUnc.getJetMCFlavour = False
runMEtUncertainties(process,jetCollection="selectedPatJetsAK5PFForMetUnc", outputModule=None)
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).p4.M):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).nTracks):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).value):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).significance):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring('vtxMass','vtxNtracks','vtx3DVal','vtx3DSig')
process.patJets.tagInfoSources = cms.VInputTag(cms.InputTag("secondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("PhysicsTools.PatAlgos.slimming.pileupJetId_cfi")
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose = cms.InputTag("reducedEgamma","eidRobustLoose"),
eidRobustTight = cms.InputTag("reducedEgamma","eidRobustTight"),
eidLoose = cms.InputTag("reducedEgamma","eidLoose"),
eidTight = cms.InputTag("reducedEgamma","eidTight"),
eidRobustHighEnergy = cms.InputTag("reducedEgamma","eidRobustHighEnergy"),
)
process.patElectrons.addPFClusterIso = cms.bool(True)
process.patElectrons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleEcalPFClusIso")
process.patElectrons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleHcalPFClusIso")
process.elPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.addPFClusterIso = cms.bool(True)
process.patPhotons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoEcalPFClusIso")
process.patPhotons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight')
)
process.phPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure( process )
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
# FIXME: are we 100% sure this should still be PF and not PFchs? -> MM: Yes for <=75X
addJetCollection(process, postfix = "ForMetUnc", labelName = 'AK4PF', jetSource = cms.InputTag('ak4PFJets'), jetCorrections = ('AK4PF', ['L1FastJet', 'L2Relative', 'L3Absolute'], ''))
process.patJetsAK4PFForMetUnc.getJetMCFlavour = False
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMETCorrectionsAndUncertainties
#MET flavors
runMETCorrectionsAndUncertainties(process, metType="PF",
correctionLevel=["T0","T1","T2","Smear","Txy"],
computeUncertainties=False,
produceIntermediateCorrections=True,
addToPatDefaultSequence=False,
jetCollectionUnskimmed="patJetsAK4PFForMetUnc",
jetCollection="selectedPatJetsAK4PFForMetUnc",
postfix="",
)
#MET T1 uncertainties
runMETCorrectionsAndUncertainties(process, metType="PF",
correctionLevel=["T1"],
computeUncertainties=True,
produceIntermediateCorrections=False,
addToPatDefaultSequence=False,
jetCollectionUnskimmed="patJetsAK4PFForMetUnc",
jetCollection="selectedPatJetsAK4PFForMetUnc",
postfix="",
)
#MET T1 Smeared JER uncertainties
runMETCorrectionsAndUncertainties(process, metType="PF",
correctionLevel=["T1","Smear"],
computeUncertainties=True,
produceIntermediateCorrections=False,
addToPatDefaultSequence=False,
jetCollectionUnskimmed="patJetsAK4PFForMetUnc",
jetCollection="selectedPatJetsAK4PFForMetUnc",
postfix="",
)
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process,
labelName = "patCaloMet",
metSource = "caloMetM"
)
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.M):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).numberOfSourceCandidatePtrs):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).value):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).significance):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.z):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.z):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring('vtxMass','vtxNtracks','vtx3DVal','vtx3DSig','vtxPx','vtxPy','vtxPz','vtxPosX','vtxPosY','vtxPosZ')
process.patJets.tagInfoSources = cms.VInputTag(cms.InputTag("pfSecondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("PhysicsTools.PatAlgos.slimming.pileupJetId_cfi")
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
## CaloJets
process.caloJetMap = cms.EDProducer("RecoJetDeltaRValueMapProducer",
src = process.patJets.jetSource,
matched = cms.InputTag("ak4CaloJets"),
distMax = cms.double(0.4),
values = cms.vstring('pt','emEnergyFraction'),
valueLabels = cms.vstring('pt','emEnergyFraction'),
lazyParser = cms.bool(True) )
process.patJets.userData.userFloats.src += [ cms.InputTag("caloJetMap:pt"), cms.InputTag("caloJetMap:emEnergyFraction") ]
#EGM object modifications
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
electron_ids = ['RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_PHYS14_PU20bx25_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV51_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV60_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_PHYS14_PU20bx25_nonTrig_V1_cff']
switchOnVIDElectronIdProducer(process,DataFormat.MiniAOD)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
for idmod in electron_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDElectronSelection)
#VID Photon IDs
photon_ids = ['RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_PHYS14_PU20bx25_V2_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_PHYS14_PU20bx25_nonTrig_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_50ns_nonTrig_V0_cff']
switchOnVIDPhotonIdProducer(process,DataFormat.MiniAOD)
process.egmPhotonIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.particleBasedIsolation = \
cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.photonMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDPhotonSelection)
# Adding puppi jets
process.load('CommonTools.PileupAlgos.Puppi_cff')
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
#process.puppi.candName = cms.InputTag('packedPFCandidates')
#process.puppi.vertexName = cms.InputTag('offlineSlimmedPrimaryVertices')
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer("JetTracksAssociatorAtVertex",
j2tParametersVX,
jets = cms.InputTag("ak4PFJetsPuppi")
)
process.patJetPuppiCharge = cms.EDProducer("JetChargeProducer",
src = cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var = cms.string('Pt'),
exp = cms.double(1.0)
)
addJetCollection(process, postfix = "", labelName = 'Puppi', jetSource = cms.InputTag('ak4PFJetsPuppi'),
jetCorrections = ('AK4PFchs', ['L2Relative', 'L3Absolute'], ''),
algo= 'AK', rParam = 0.4, btagDiscriminators = map(lambda x: x.value() ,process.patJets.discriminatorSources)
)
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.userData.userFloats.src = cms.VInputTag(cms.InputTag(""))
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 20")
process.load('PhysicsTools.PatAlgos.slimming.slimmedJets_cfi')
process.slimmedJetsPuppi = process.slimmedJets.clone()
process.slimmedJetsPuppi.src = cms.InputTag("selectedPatJetsPuppi")
process.slimmedJetsPuppi.packedPFCandidates = cms.InputTag("packedPFCandidates")
## puppi met
process.load('RecoMET.METProducers.PFMET_cfi')
process.pfMetPuppi = process.pfMet.clone()
process.pfMetPuppi.src = cms.InputTag("puppi")
process.pfMetPuppi.alias = cms.string('pfMetPuppi')
# type1 correction, from puppi jets
process.corrPfMetType1Puppi = process.corrPfMetType1.clone(
src = 'ak4PFJetsPuppi',
jetCorrLabel = 'ak4PFCHSL2L3Corrector',
)
del process.corrPfMetType1Puppi.offsetCorrLabel # no L1 for PUPPI jets
process.pfMetT1Puppi = process.pfMetT1.clone(
src = 'pfMetPuppi',
srcCorrections = [ cms.InputTag("corrPfMetType1Puppi","type1") ]
)
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process, labelName='patMETPuppi', metSource='pfMetT1Puppi') # T1
addMETCollection(process, labelName='patPFMetPuppi', metSource='pfMetPuppi') # RAW
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
process.slimmedMETsPuppi = process.slimmedMETs.clone()
process.slimmedMETsPuppi.src = cms.InputTag("patMETPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi") # only central value
# only central values for puppi met
del process.slimmedMETsPuppi.t01Variation
del process.slimmedMETsPuppi.t1SmearedVarsAndUncs
del process.slimmedMETsPuppi.tXYUncForRaw
del process.slimmedMETsPuppi.tXYUncForT1
del process.slimmedMETsPuppi.tXYUncForT01
del process.slimmedMETsPuppi.tXYUncForT1Smear
del process.slimmedMETsPuppi.tXYUncForT01Smear
del process.slimmedMETsPuppi.caloMET
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose = cms.InputTag("reducedEgamma","eidRobustLoose"),
eidRobustTight = cms.InputTag("reducedEgamma","eidRobustTight"),
eidLoose = cms.InputTag("reducedEgamma","eidLoose"),
eidTight = cms.InputTag("reducedEgamma","eidTight"),
eidRobustHighEnergy = cms.InputTag("reducedEgamma","eidRobustHighEnergy"),
)
process.patElectrons.addPFClusterIso = cms.bool(True)
process.patElectrons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleEcalPFClusIso")
process.patElectrons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleHcalPFClusIso")
process.elPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.addPFClusterIso = cms.bool(True)
process.patPhotons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoEcalPFClusIso")
process.patPhotons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight')
)
process.phPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure( process )
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
# FIXME: are we 100% sure this should still be PF and not PFchs?
from PhysicsTools.PatUtils.tools.runType1PFMEtUncertainties import runType1PFMEtUncertainties
addJetCollection(process, postfix = "ForMetUnc", labelName = 'AK4PF', jetSource = cms.InputTag('ak4PFJets'), jetCorrections = ('AK4PF', ['L1FastJet', 'L2Relative', 'L3Absolute'], ''))
process.patJetsAK4PFForMetUnc.getJetMCFlavour = False
runType1PFMEtUncertainties(process,
addToPatDefaultSequence=False,
jetCollectionUnskimmed="patJetsAK4PFForMetUnc",
jetCollection="selectedPatJetsAK4PFForMetUnc",
electronCollection="selectedPatElectrons",
muonCollection="selectedPatMuons",
tauCollection="selectedPatTaus",
makeType1p2corrPFMEt=True,
doSmearJets=False,
outputModule=None)
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process,
labelName = "patCaloMet",
metSource = "caloMetM"
)
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.M):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).numberOfSourceCandidatePtrs):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).value):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).significance):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.z):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.z):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring('vtxMass','vtxNtracks','vtx3DVal','vtx3DSig','vtxPx','vtxPy','vtxPz','vtxPosX','vtxPosY','vtxPosZ')
process.patJets.tagInfoSources = cms.VInputTag(cms.InputTag("pfSecondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("PhysicsTools.PatAlgos.slimming.pileupJetId_cfi")
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
## CaloJets
process.caloJetMap = cms.EDProducer("RecoJetDeltaRValueMapProducer",
src = process.patJets.jetSource,
matched = cms.InputTag("ak4CaloJets"),
distMax = cms.double(0.4),
values = cms.vstring('pt','emEnergyFraction'),
valueLabels = cms.vstring('pt','emEnergyFraction'),
lazyParser = cms.bool(True) )
process.patJets.userData.userFloats.src += [ cms.InputTag("caloJetMap:pt"), cms.InputTag("caloJetMap:emEnergyFraction") ]
#VID Electron IDs
electron_ids = ['RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_CSA14_50ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_CSA14_PU20bx25_V0_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV50_CSA14_25ns_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV50_CSA14_startup_cff']
switchOnVIDElectronIdProducer(process, DataFormat.MiniAOD)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronIDValueMapProducer.ebReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedEBRecHits")
process.electronIDValueMapProducer.eeReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedEERecHits")
process.electronIDValueMapProducer.esReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedESRecHits")
for idmod in electron_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDElectronSelection)
# Adding puppi jets
process.load('CommonTools.PileupAlgos.Puppi_cff')
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
#process.puppi.candName = cms.InputTag('packedPFCandidates')
#process.puppi.vertexName = cms.InputTag('offlineSlimmedPrimaryVertices')
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer("JetTracksAssociatorAtVertex",
j2tParametersVX,
jets = cms.InputTag("ak4PFJetsPuppi")
)
process.patJetPuppiCharge = cms.EDProducer("JetChargeProducer",
src = cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var = cms.string('Pt'),
exp = cms.double(1.0)
)
addJetCollection(process, postfix = "", labelName = 'Puppi', jetSource = cms.InputTag('ak4PFJetsPuppi'),
jetCorrections = ('AK4PFchs', ['L2Relative', 'L3Absolute'], ''),
algo= 'AK', rParam = 0.4, btagDiscriminators = map(lambda x: x.value() ,process.patJets.discriminatorSources)
)
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.userData.userFloats.src = cms.VInputTag(cms.InputTag(""))
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 20")
process.load('PhysicsTools.PatAlgos.slimming.slimmedJets_cfi')
process.slimmedJetsPuppi = process.slimmedJets.clone()
process.slimmedJetsPuppi.src = cms.InputTag("selectedPatJetsPuppi")
process.slimmedJetsPuppi.packedPFCandidates = cms.InputTag("packedPFCandidates")
## puppi met
process.load('RecoMET.METProducers.PFMET_cfi')
process.pfMetPuppi = process.pfMet.clone()
process.pfMetPuppi.src = cms.InputTag("puppi")
process.pfMetPuppi.alias = cms.string('pfMetPuppi')
## type1 correction, from puppi jets
process.corrPfMetType1Puppi = process.corrPfMetType1.clone(
src = 'ak4PFJetsPuppi',
jetCorrLabel = 'ak4PFCHSL2L3Corrector',
)
del process.corrPfMetType1Puppi.offsetCorrLabel # no L1 for PUPPI jets
process.pfMetT1Puppi = process.pfMetT1.clone(
src = 'pfMetPuppi',
srcCorrections = [ cms.InputTag("corrPfMetType1Puppi","type1") ]
)
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process, labelName='patMETPuppi', metSource='pfMetT1Puppi') # T1
addMETCollection(process, labelName='patPFMetPuppi', metSource='pfMetPuppi') # RAW
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
process.slimmedMETsPuppi = process.slimmedMETs.clone()
process.slimmedMETsPuppi.src = cms.InputTag("patMETPuppi")
process.slimmedMETsPuppi.rawUncertainties = cms.InputTag("patPFMetPuppi") # only central value
process.slimmedMETsPuppi.type1Uncertainties = cms.InputTag("patPFMetT1") # only central value for now
del process.slimmedMETsPuppi.type1p2Uncertainties # not available
#Jen additions
from PhysicsTools.PatAlgos.slimming.metFilterPaths_cff import miniAOD_insertMETFiltersInSchedule
miniAOD_insertMETFiltersInSchedule(process)
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 3")
process.selectedPatElectrons.cut = cms.string("pt > 5")
process.selectedPatTaus.cut = cms.string("pt > 20")
process.slimmedJets.clearDaughters = False
#process.slimmedElectrons.dropRecHits = True
#process.slimmedElectrons.dropBasicClusters = True
#process.slimmedElectrons.dropPFlowClusters = True
#process.slimmedElectrons.dropPreshowerClusters = True
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process )
process.patTrigger.packTriggerPathNames = cms.bool(True)
# ##
# process.options.wantSummary = False ## (to suppress the long output at the end of the job)
# ##
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatUtils.tools.metUncertaintyTools import runMEtUncertainties
addJetCollection(process, postfix = "ForMetUnc", labelName = 'AK5PF', jetSource = cms.InputTag('ak5PFJets'), jetCorrections = ('AK5PF', ['L1FastJet', 'L2Relative', 'L3Absolute'], ''), btagDiscriminators = ['combinedSecondaryVertexBJetTags' ] )
runMEtUncertainties(process,jetCollection="selectedPatJetsAK5PFForMetUnc", outputModule=None)
# process.out.outputCommands = [ ... ] ## (e.g. taken from PhysicsTools/PatAlgos/python/patEventContent_cff.py)
# ##
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose = cms.InputTag("reducedEgamma","eidRobustLoose"),
eidRobustTight = cms.InputTag("reducedEgamma","eidRobustTight"),
eidLoose = cms.InputTag("reducedEgamma","eidLoose"),
eidTight = cms.InputTag("reducedEgamma","eidTight"),
eidRobustHighEnergy = cms.InputTag("reducedEgamma","eidRobustHighEnergy"),
)
process.patElectrons.addPFClusterIso = cms.bool(True)
#add puppi isolation in miniAOD
process.patElectrons.addPuppiIsolation = cms.bool(True)
process.patElectrons.puppiIsolationChargedHadrons = cms.InputTag("egmElectronPUPPIIsolation","h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiIsolationNeutralHadrons = cms.InputTag("egmElectronPUPPIIsolation","h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiIsolationPhotons = cms.InputTag("egmElectronPUPPIIsolation","gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiNoLeptonsIsolationPhotons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleEcalPFClusIso")
process.patElectrons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleHcalPFClusIso")
process.elPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.addPFClusterIso = cms.bool(True)
#add puppi isolation in miniAOD
process.patPhotons.addPuppiIsolation = cms.bool(True)
process.patPhotons.puppiIsolationChargedHadrons = cms.InputTag("egmPhotonPUPPIIsolation","h+-DR030-")
process.patPhotons.puppiIsolationNeutralHadrons = cms.InputTag("egmPhotonPUPPIIsolation","h0-DR030-")
process.patPhotons.puppiIsolationPhotons = cms.InputTag("egmPhotonPUPPIIsolation","gamma-DR030-")
process.patPhotons.ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoEcalPFClusIso")
process.patPhotons.hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight')
)
process.phPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure( process )
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I + other PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncForMiniAODProduction
runMetCorAndUncForMiniAODProduction(process, metType="PF",
jetCollUnskimmed="patJets")
#caloMET computation
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process,
labelName = "patCaloMet",
metSource = "caloMetM"
)
#noHF pfMET =========
task = getPatAlgosToolsTask(process)
process.noHFCands = cms.EDFilter("GenericPFCandidateSelector",
src=cms.InputTag("particleFlow"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0")
)
task.add(process.noHFCands)
runMetCorAndUncForMiniAODProduction(process,
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True, #needed for HF removal
jetSelection="pt>15 && abs(eta)<3.",
postfix="NoHF"
)
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsNoHF', process.slimmedMETs.clone(), process, task)
process.slimmedMETsNoHF.src = cms.InputTag("patMETsNoHF")
process.slimmedMETsNoHF.rawVariation = cms.InputTag("patPFMetNoHF")
process.slimmedMETsNoHF.t1Uncertainties = cms.InputTag("patPFMetT1%sNoHF")
process.slimmedMETsNoHF.t01Variation = cms.InputTag("patPFMetT0pcT1NoHF")
process.slimmedMETsNoHF.t1SmearedVarsAndUncs = cms.InputTag("patPFMetT1Smear%sNoHF")
process.slimmedMETsNoHF.tXYUncForRaw = cms.InputTag("patPFMetTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1 = cms.InputTag("patPFMetT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01 = cms.InputTag("patPFMetT0pcT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1Smear = cms.InputTag("patPFMetT1SmearTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01Smear = cms.InputTag("patPFMetT0pcT1SmearTxyNoHF")
del process.slimmedMETsNoHF.caloMET
# ================== NoHF pfMET
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
if not hasattr( process, 'pfImpactParameterTagInfos' ):
process.load('RecoBTag.ImpactParameter.pfImpactParameterTagInfos_cfi')
task.add(process.pfImpactParameterTagInfos)
if not hasattr( process, 'pfSecondaryVertexTagInfos' ):
process.load('RecoBTag.SecondaryVertex.pfSecondaryVertexTagInfos_cfi')
task.add(process.pfSecondaryVertexTagInfos)
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.M):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).numberOfSourceCandidatePtrs):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).value):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).significance):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.z):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.z):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring('vtxMass','vtxNtracks','vtx3DVal','vtx3DSig','vtxPx','vtxPy','vtxPz','vtxPosX','vtxPosY','vtxPosZ')
process.patJets.tagInfoSources = cms.VInputTag(cms.InputTag("pfSecondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
## Legacy tight b-tag track selection
## (this will run below-specified taggers with the tight b-tag track selection enabled
## and will add an extra set of b-tag discriminators to 'selectedPatJets'
## with the 'tight' prefix added to the usual discriminator names)
from PhysicsTools.PatAlgos.tools.jetTools import updateJetCollection
updateJetCollection(
process,
jetSource = cms.InputTag('selectedPatJets'),
## updateJetCollection defaults to MiniAOD inputs. Here, this needs to be changed to RECO/AOD inputs
pvSource = cms.InputTag('offlinePrimaryVertices'),
pfCandidates = cms.InputTag('particleFlow'),
svSource = cms.InputTag('inclusiveCandidateSecondaryVertices'),
muSource = cms.InputTag('muons'),
elSource = cms.InputTag('gedGsfElectrons'),
##
jetCorrections = ('AK4PFchs', ['L1FastJet', 'L2Relative', 'L3Absolute'], ''),
btagDiscriminators = ["pfCombinedSecondaryVertexV2BJetTags", "pfCombinedInclusiveSecondaryVertexV2BJetTags",
"pfCombinedCvsLJetTags", "pfCombinedCvsBJetTags"],
runIVF = True,
tightBTagNTkHits = True,
btagPrefix = 'tight',
postfix = 'BTAG' # added to avoid problems with unrunnable schedule
)
#
## PU JetID
process.load("RecoJets.JetProducers.PileupJetID_cfi")
task.add(process.pileupJetId)
task.add(process.pileupJetIdCalculator)
task.add(process.pileupJetIdEvaluator)
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
process.patJets.userData.userInts.src = [ cms.InputTag("pileupJetId:fullId"), ]
## CaloJets
process.caloJetMap = cms.EDProducer("RecoJetDeltaRValueMapProducer",
src = process.patJets.jetSource,
matched = cms.InputTag("ak4CaloJets"),
distMax = cms.double(0.4),
values = cms.vstring('pt','emEnergyFraction'),
valueLabels = cms.vstring('pt','emEnergyFraction'),
lazyParser = cms.bool(True) )
task.add(process.caloJetMap)
process.patJets.userData.userFloats.src += [ cms.InputTag("caloJetMap:pt"), cms.InputTag("caloJetMap:emEnergyFraction") ]
#EGM object modifications
from PhysicsTools.PatAlgos.slimming.egmIsolationsPUPPI_cfi import makeInputForPUPPIIsolationEgm
makeInputForPUPPIIsolationEgm(process)
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
electron_ids = ['RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_PHYS14_PU20bx25_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_25ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_50ns_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV60_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_nonTrig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_Trig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_50ns_Trig_V1_cff']
switchOnVIDElectronIdProducer(process,DataFormat.MiniAOD, task)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
process.electronRegressionValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
for idmod in electron_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDElectronSelection,None,False,task)
#heepIDVarValueMaps only exists if HEEP V6.1 or HEEP 7.0 ID has already been loaded
if hasattr(process,'heepIDVarValueMaps'):
process.heepIDVarValueMaps.elesMiniAOD = cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
#force HEEP to use miniAOD (otherwise it'll detect the AOD)
process.heepIDVarValueMaps.dataFormat = cms.int32(2)
#VID Photon IDs
photon_ids = ['RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_25ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_50ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_25ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_50ns_nonTrig_V2p1_cff']
switchOnVIDPhotonIdProducer(process,DataFormat.MiniAOD, task)
process.egmPhotonIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonRegressionValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.particleBasedIsolation = \
cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.photonMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDPhotonSelection,None,False,task)
#---------------------------------------------------------------------------
#Adding Boosted Subjets taus
from RecoTauTag.Configuration.boostedHPSPFTaus_cfi import addBoostedTaus
addBoostedTaus(process)
#---------------------------------------------------------------------------
# Adding puppi jets
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
task.add(process.ak4PFJets)
task.add(process.ak4PFJetsPuppi)
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer("JetTracksAssociatorAtVertex",
j2tParametersVX,
jets = cms.InputTag("ak4PFJetsPuppi")
)
task.add(process.ak4PFJetsPuppiTracksAssociatorAtVertex)
process.patJetPuppiCharge = cms.EDProducer("JetChargeProducer",
src = cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var = cms.string('Pt'),
exp = cms.double(1.0)
)
task.add(process.patJetPuppiCharge)
addJetCollection(process, postfix = "", labelName = 'Puppi', jetSource = cms.InputTag('ak4PFJetsPuppi'),
jetCorrections = ('AK4PFPuppi', ['L2Relative', 'L3Absolute'], ''),
algo= 'AK', rParam = 0.4, btagDiscriminators = map(lambda x: x.value() ,process.patJets.discriminatorSources)
)
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 15")
process.load('PhysicsTools.PatAlgos.slimming.slimmedJets_cfi')
task.add(process.slimmedJets)
task.add(process.slimmedJetsAK8)
addToProcessAndTask('slimmedJetsPuppi', process.slimmedJets.clone(), process, task)
process.slimmedJetsPuppi.src = cms.InputTag("selectedPatJetsPuppi")
process.slimmedJetsPuppi.packedPFCandidates = cms.InputTag("packedPFCandidates")
## puppi met
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppies
makePuppies( process );
runMetCorAndUncForMiniAODProduction(process, metType="Puppi",
pfCandColl=cms.InputTag("puppiForMET"),
jetCollUnskimmed="slimmedJetsPuppi",
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
postfix="Puppi"
)
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsPuppi', process.slimmedMETs.clone(), process, task)
process.slimmedMETsPuppi.src = cms.InputTag("patMETsPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi")
process.slimmedMETsPuppi.t1Uncertainties = cms.InputTag("patPFMetT1%sPuppi")
process.slimmedMETsPuppi.t01Variation = cms.InputTag("patPFMetT0pcT1Puppi")
process.slimmedMETsPuppi.t1SmearedVarsAndUncs = cms.InputTag("patPFMetT1Smear%sPuppi")
process.slimmedMETsPuppi.tXYUncForRaw = cms.InputTag("patPFMetTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1 = cms.InputTag("patPFMetT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01 = cms.InputTag("patPFMetT0pcT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1Smear = cms.InputTag("patPFMetT1SmearTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01Smear = cms.InputTag("patPFMetT0pcT1SmearTxyPuppi")
del process.slimmedMETsPuppi.caloMET
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
process.patElectrons.embedPflowSuperCluster = False
process.patElectrons.embedPflowBasicClusters = False
process.patElectrons.embedPflowPreshowerClusters = False
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string(
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))"
)
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string(
"pt > 20 && tauID('decayModeFinding')> 0.5")
process.selectedPatPhotons.cut = cms.string(
"pt > 15 && hadTowOverEm()<0.15 ")
#
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
#
addJetCollection(process,
labelName='CA8',
jetSource=cms.InputTag('ca8PFJetsCHS'),
algo='CA',
rParam=0.8)
process.selectedPatJetsCA8.cut = cms.string("pt > 100")
process.patJetGenJetMatchCA8.matched = 'slimmedGenJets'
#
## PU JetID
process.load("PhysicsTools.PatAlgos.slimming.pileupJetId_cfi")
process.patJets.userData.userFloats.src = [
cms.InputTag("pileupJetId:fullDiscriminant"),
]
#
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).p4.M):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).nTracks):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).value):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).significance):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring(
'vtxMass', 'vtxNtracks', 'vtx3DVal', 'vtx3DSig')
process.patJets.tagInfoSources = cms.VInputTag(
cms.InputTag("secondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone(process)
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.metUncertaintyTools import runMEtUncertainties
addJetCollection(process,
postfix="ForMetUnc",
labelName='AK5PF',
jetSource=cms.InputTag('ak5PFJets'),
jetCorrections=('AK5PF',
['L1FastJet', 'L2Relative',
'L3Absolute'], ''),
btagDiscriminators=['combinedSecondaryVertexBJetTags'])
runMEtUncertainties(process,
jetCollection="selectedPatJetsAK5PFForMetUnc",
outputModule=None)
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose = cms.InputTag("reducedEgamma","eidRobustLoose"),
eidRobustTight = cms.InputTag("reducedEgamma","eidRobustTight"),
eidLoose = cms.InputTag("reducedEgamma","eidLoose"),
eidTight = cms.InputTag("reducedEgamma","eidTight"),
eidRobustHighEnergy = cms.InputTag("reducedEgamma","eidRobustHighEnergy"),
)
process.elPFIsoDepositCharged.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAll.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutral.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGamma.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPU.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight = cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight')
)
process.phPFIsoDepositCharged.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAll.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutral.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGamma.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPU.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 18. && tauID('decayModeFinding')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
#
from PhysicsTools.PatAlgos.tools.jetTools import switchJetCollection
#switch to AK4 for CSA14/70X release (should be default in 71X)
switchJetCollection(process, jetSource = cms.InputTag('ak4PFJetsCHS'),
jetCorrections = ('AK4PFchs', cms.vstring(['L1FastJet', 'L2Relative', 'L3Absolute']), ''),
btagDiscriminators = ['jetBProbabilityBJetTags', 'jetProbabilityBJetTags', 'trackCountingHighPurBJetTags', 'trackCountingHighEffBJetTags', 'simpleSecondaryVertexHighEffBJetTags',
'simpleSecondaryVertexHighPurBJetTags', 'combinedSecondaryVertexBJetTags' , 'combinedInclusiveSecondaryVertexBJetTags' ],
)
#add CA8
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
addJetCollection(process, labelName = 'AK8', jetSource = cms.InputTag('ak8PFJetsCHS'),algo= 'AK', rParam = 0.8, jetCorrections = ('AK7PFchs', cms.vstring(['L1FastJet', 'L2Relative', 'L3Absolute']), 'None') )
process.patJetsAK8.userData.userFloats.src = [] # start with empty list of user floats
process.selectedPatJetsAK8.cut = cms.string("pt > 100")
process.patJetGenJetMatchAK8.matched = 'slimmedGenJets'
## AK8 groomed masses
from RecoJets.Configuration.RecoPFJets_cff import ak8PFJetsCHSPruned, ak8PFJetsCHSFiltered, ak8PFJetsCHSTrimmed
process.ak8PFJetsCHSPruned = ak8PFJetsCHSPruned.clone()
process.ak8PFJetsCHSTrimmed = ak8PFJetsCHSTrimmed.clone()
process.ak8PFJetsCHSFiltered = ak8PFJetsCHSFiltered.clone()
process.load("RecoJets.JetProducers.ak8PFJetsCHS_groomingValueMaps_cfi")
process.patJetsAK8.userData.userFloats.src += ['ak8PFJetsCHSPrunedLinks','ak8PFJetsCHSTrimmedLinks','ak8PFJetsCHSFilteredLinks']
### CA8 groomed masses (for the matched jet): doesn't seem to work, it produces tons of warnings "Matched jets separated by dR greater than distMax=0.8"
# from RecoJets.Configuration.RecoPFJets_cff import ca8PFJetsCHSFiltered, ca8PFJetsCHSTrimmed # ca8PFJetsCHSPruned is already in AOD
# process.ca8PFJetsCHSTrimmed = ca8PFJetsCHSTrimmed.clone()
# process.ca8PFJetsCHSFiltered = ca8PFJetsCHSFiltered.clone()
# process.load("RecoJets.JetProducers.ca8PFJetsCHS_groomingValueMaps_cfi")
# process.ca8PFJetsCHSPrunedLinks.src = cms.InputTag("ak8PFJetsCHS")
# process.ca8PFJetsCHSTrimmedLinks.src = cms.InputTag("ak8PFJetsCHS")
# process.ca8PFJetsCHSFilteredLinks.src = cms.InputTag("ak8PFJetsCHS")
# process.patJetsAK8.userData.userFloats.src += ['ca8PFJetsCHSPrunedLinks','ca8PFJetsCHSTrimmedLinks','ca8PFJetsCHSFilteredLinks']
## cmsTopTagger (note: it is already run in RECO, we just add the value)
process.cmsTopTagPFJetsCHSLinksAK8 = process.ak8PFJetsCHSPrunedLinks.clone()
process.cmsTopTagPFJetsCHSLinksAK8.src = cms.InputTag("ak8PFJetsCHS")
process.cmsTopTagPFJetsCHSLinksAK8.matched = cms.InputTag("cmsTopTagPFJetsCHS")
process.patJetsAK8.userData.userFloats.src += ['cmsTopTagPFJetsCHSLinksAK8']
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.metUncertaintyTools import runMEtUncertainties
addJetCollection(process, postfix = "ForMetUnc", labelName = 'AK5PF', jetSource = cms.InputTag('ak5PFJets'), jetCorrections = ('AK5PF', ['L1FastJet', 'L2Relative', 'L3Absolute'], ''))
runMEtUncertainties(process,jetCollection="selectedPatJetsAK5PFForMetUnc", outputModule=None)
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).p4.M):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).nTracks):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).value):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).significance):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring('vtxMass','vtxNtracks','vtx3DVal','vtx3DSig')
process.patJets.tagInfoSources = cms.VInputTag(cms.InputTag("secondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("PhysicsTools.PatAlgos.slimming.pileupJetId_cfi")
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
def applyTriggerMatching(process):
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone, switchOnTriggerMatchEmbedding
switchOnTriggerStandAlone(process, outputModule='')
#process.patTrigger.packTriggerPathNames = cms.bool(True)
# Trigger Matching for HLT
process.triggerMatchDRDPt = cms.EDProducer(
"PATTriggerMatcherDRDPtLessByR",
src=cms.InputTag(""),
matched=cms.InputTag('selectedPatTrigger'),
matchedCuts=cms.string(""),
maxDPtRel=cms.double(0.5),
maxDeltaR=cms.double(0.5),
resolveAmbiguities=cms.bool(False),
resolveByMatchQuality=cms.bool(True))
process.triggerMatchDR = cms.EDProducer(
"PATTriggerMatcherDRLessByR",
src=cms.InputTag(""),
matched=cms.InputTag('selectedPatTrigger'),
matchedCuts=cms.string(""),
maxDeltaR=cms.double(0.5),
resolveAmbiguities=cms.bool(False),
resolveByMatchQuality=cms.bool(True))
# Muon HLT Trigger Matching
process.muonMatchHLTL2 = process.triggerMatchDRDPt.clone(
src=cms.InputTag("patMuons"),
matchedCuts=cms.string('coll("hltL2MuonCandidates")'),
maxDeltaR=0.3,
maxDPtRel=10.0)
process.muonMatchHLTL3 = process.triggerMatchDRDPt.clone(
src=cms.InputTag("patMuons"),
matchedCuts=cms.string('coll("hltL3MuonCandidates")'),
maxDeltaR=0.1,
maxDPtRel=10.0)
process.muonMatchHLTHIL3 = process.triggerMatchDRDPt.clone(
src=cms.InputTag("patMuons"),
matchedCuts=cms.string('coll("hltHIL3MuonCandidates")'),
maxDeltaR=0.1,
maxDPtRel=10.0)
process.patMuonsWithTriggers = cms.EDProducer(
"PATTriggerMatchMuonEmbedder",
src=cms.InputTag("patMuons"),
matches=cms.VInputTag('muonMatchHLTL2', 'muonMatchHLTL3',
'muonMatchHLTHIL3'))
# Electron HLT Trigger Matching
#process.electronMatchHLT = process.triggerMatchDRDPt.clone(src = cms.InputTag( "patElectrons" ), matchedCuts = cms.string('coll("hltEgammaCandidates")'), maxDeltaR = 0.3, maxDPtRel = 10.0) #FIXME
#process.patElectronsWithTriggers = cms.EDProducer("PATTriggerMatchElectronEmbedder", src = cms.InputTag( "patElectrons" ), matches = cms.VInputTag('electronMatchHLT') )
# Photon HLT Trigger Matching
#process.photonMatchHLT = process.triggerMatchDRDPt.clone(src = cms.InputTag( "patPhotons" ), matchedCuts = cms.string('coll("hltEgammaCandidates")'), maxDeltaR = 0.3, maxDPtRel = 10.0) #FIXME
#process.photonMatchHIHLT = process.triggerMatchDRDPt.clone(src = cms.InputTag( "patPhotons" ), matchedCuts = cms.string('coll("hltRecoHIEcalWithCleaningCandidate")'), maxDeltaR = 0.3, maxDPtRel = 10.0) #FIXME
#process.patPhotonsWithTriggers = cms.EDProducer("PATTriggerMatchPhotonEmbedder", src = cms.InputTag( "patPhotons" ), matches = cms.VInputTag('photonMatchHLT' , 'photonMatchHIHLT') )
# Jet HLT Trigger Matching
#process.jetMatchHLTPFJets = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltPAAK4PFJetsCorrected")'), maxDeltaR = 0.4)
#process.jetMatchHLTPFBJets = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltPACombinedSecondaryVertexBJetTagsPF")'), maxDeltaR = 0.4)
#process.jetMatchHLTPFBjetsCommTrack = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltBTagPFCSVp016SingleWithMatching40CommonTracking")'), maxDeltaR = 0.4)
#process.jetMatchHLTCaloJets = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltPAAK4CaloJetsCorrectedIDPassed")'), maxDeltaR = 0.4)
#process.jetMatchHLTPFCaloJets30Eta2p1 = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltPAAK4PFJetsCorrectedMatchedToCaloJets30Eta2p1")'), maxDeltaR = 0.4)
#process.jetMatchHLTPFCaloJets15Eta5p1 = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltPAAK4PFJetsCorrectedMatchedToCaloJets15Eta5p1")'), maxDeltaR = 0.4)
#process.jetMatchHLTPFCaloJets30Eta5p1 = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltPAAK4PFJetsCorrectedMatchedToCaloJets30Eta5p1")'), maxDeltaR = 0.4)
#process.jetMatchHLTPFCaloJets50Eta5p1 = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltPAAK4PFJetsCorrectedMatchedToCaloJets50Eta5p1")'), maxDeltaR = 0.4)
#process.jetMatchHLTCaloBJets = process.triggerMatchDR.clone(src = cms.InputTag( "patJets" ), matchedCuts = cms.string('coll("hltPABLifetimeL3FilterCSVCaloJet40Eta2p1")'), maxDeltaR = 0.4)
#process.patJetsWithTriggers = cms.EDProducer("PATTriggerMatchJetEmbedder", src = cms.InputTag( "patJets" ), matches = cms.VInputTag('jetMatchHLTPFJets', 'jetMatchHLTCaloJets', 'jetMatchHLTPFCaloJets30Eta2p1', 'jetMatchHLTPFCaloJets15Eta5p1', 'jetMatchHLTPFCaloJets30Eta5p1', 'jetMatchHLTPFCaloJets50Eta5p1', 'jetMatchHLTCaloBJets', 'jetMatchHLTPFBJets', 'jetMatchHLTPFBjetsCommTrack') )
# Keep HLT Trigger Matching Objects
process.MicroEventContent.outputCommands.append('keep *_*WithTriggers_*_*')
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
process.patMuons.addPuppiIsolation = cms.bool(True)
process.patMuons.puppiIsolationChargedHadrons = cms.InputTag(
"muonPUPPIIsolation", "h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiIsolationNeutralHadrons = cms.InputTag(
"muonPUPPIIsolation", "h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiIsolationPhotons = cms.InputTag(
"muonPUPPIIsolation", "gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag(
"muonPUPPINoLeptonsIsolation", "h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag(
"muonPUPPINoLeptonsIsolation", "h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationPhotons = cms.InputTag(
"muonPUPPINoLeptonsIsolation",
"gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.computeMiniIso = True
process.patMuons.computeMuonMVA = True
process.patMuons.computeSoftMuonMVA = True
process.patMuons.addTriggerMatching = True
from Configuration.Eras.Modifier_run2_muon_2016_cff import run2_muon_2016
from Configuration.Eras.Modifier_run2_muon_2017_cff import run2_muon_2017
from Configuration.Eras.Modifier_run2_muon_2018_cff import run2_muon_2018
run2_muon_2016.toModify(
process.patMuons,
effectiveAreaVec=[0.0735, 0.0619, 0.0465, 0.0433, 0.0577])
run2_muon_2017.toModify(
process.patMuons,
effectiveAreaVec=[0.0566, 0.0562, 0.0363, 0.0119, 0.0064])
run2_muon_2018.toModify(
process.patMuons,
effectiveAreaVec=[0.0566, 0.0562, 0.0363, 0.0119, 0.0064])
run2_muon_2016.toModify(
process.patMuons,
mvaTrainingFile=
"RecoMuon/MuonIdentification/data/mu_2016_BDTG.weights.xml")
process.patMuons.computePuppiCombinedIso = True
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.patElectrons.usePfCandidateMultiMap = True
process.patElectrons.pfCandidateMultiMap = cms.InputTag(
"reducedEgamma", "reducedGsfElectronPfCandMap")
process.patElectrons.electronIDSources = cms.PSet()
from Configuration.Eras.Modifier_run2_miniAOD_80XLegacy_cff import run2_miniAOD_80XLegacy
from Configuration.Eras.Modifier_run2_miniAOD_94XFall17_cff import run2_miniAOD_94XFall17
(run2_miniAOD_80XLegacy | run2_miniAOD_94XFall17).toModify(
process.patElectrons,
addPFClusterIso=True,
ecalPFClusterIsoMap="reducedEgamma:eleEcalPFClusIso",
hcalPFClusterIsoMap="reducedEgamma:eleHcalPFClusIso")
#add puppi isolation in miniAOD
process.patElectrons.addPuppiIsolation = cms.bool(True)
process.patElectrons.puppiIsolationChargedHadrons = cms.InputTag(
"egmElectronPUPPIIsolation", "h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiIsolationNeutralHadrons = cms.InputTag(
"egmElectronPUPPIIsolation", "h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiIsolationPhotons = cms.InputTag(
"egmElectronPUPPIIsolation", "gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation", "h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation", "h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiNoLeptonsIsolationPhotons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation",
"gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.computeMiniIso = cms.bool(True)
process.elPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
#add puppi isolation in miniAOD
process.patPhotons.addPuppiIsolation = cms.bool(True)
process.patPhotons.puppiIsolationChargedHadrons = cms.InputTag(
"egmPhotonPUPPIIsolation", "h+-DR030-")
process.patPhotons.puppiIsolationNeutralHadrons = cms.InputTag(
"egmPhotonPUPPIIsolation", "h0-DR030-")
process.patPhotons.puppiIsolationPhotons = cms.InputTag(
"egmPhotonPUPPIIsolation", "gamma-DR030-")
(run2_miniAOD_80XLegacy | run2_miniAOD_94XFall17).toModify(
process.patPhotons,
addPFClusterIso=True,
ecalPFClusterIsoMap="reducedEgamma:phoEcalPFClusIso",
hcalPFClusterIsoMap="reducedEgamma:phoHcalPFClusIso")
#the 80X legacy customsations are done in ootPhotonProducer for OOT photons
run2_miniAOD_94XFall17.toModify(
process.patOOTPhotons,
addPFClusterIso=True,
ecalPFClusterIsoMap="reducedEgamma:ootPhoEcalPFClusIso",
hcalPFClusterIsoMap="reducedEgamma:ootPhoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
process.phPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
#
process.patOOTPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedOOTPhotons")
process.patOOTPhotons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string(
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))"
)
from Configuration.Eras.Modifier_phase2_muon_cff import phase2_muon
phase2_muon.toModify(
process.selectedPatMuons,
cut=
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose') || muonID('ME0MuonArbitrated') || muonID('GEMMuonArbitrated')) )"
)
from Configuration.Eras.Modifier_pp_on_AA_2018_cff import pp_on_AA_2018
from Configuration.Eras.Modifier_pp_on_PbPb_run3_cff import pp_on_PbPb_run3
(pp_on_AA_2018 | pp_on_PbPb_run3).toModify(
process.selectedPatMuons,
cut=
"pt > 5 || isPFMuon || (pt > 1.2 && (isGlobalMuon || isStandAloneMuon) )"
)
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string(
"pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure(process)
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone(process, outputModule='')
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I + other PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncForMiniAODProduction
runMetCorAndUncForMiniAODProduction(process,
metType="PF",
jetCollUnskimmed="patJets")
#caloMET computation
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process, labelName="patCaloMet", metSource="caloMetM")
#noHF pfMET =========
task = getPatAlgosToolsTask(process)
process.noHFCands = cms.EDFilter(
"GenericPFCandidateSelector",
src=cms.InputTag("particleFlow"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0"))
task.add(process.noHFCands)
runMetCorAndUncForMiniAODProduction(
process,
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True, #needed for HF removal
jetSelection="pt>15 && abs(eta)<3.",
postfix="NoHF")
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
process.slimmedMETs.addDeepMETs = True
addToProcessAndTask('slimmedMETsNoHF', process.slimmedMETs.clone(),
process, task)
process.slimmedMETsNoHF.src = cms.InputTag("patMETsNoHF")
process.slimmedMETsNoHF.rawVariation = cms.InputTag("patPFMetNoHF")
process.slimmedMETsNoHF.t1Uncertainties = cms.InputTag("patPFMetT1%sNoHF")
process.slimmedMETsNoHF.t01Variation = cms.InputTag("patPFMetT0pcT1NoHF")
process.slimmedMETsNoHF.t1SmearedVarsAndUncs = cms.InputTag(
"patPFMetT1Smear%sNoHF")
process.slimmedMETsNoHF.tXYUncForRaw = cms.InputTag("patPFMetTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1 = cms.InputTag("patPFMetT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01 = cms.InputTag(
"patPFMetT0pcT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1Smear = cms.InputTag(
"patPFMetT1SmearTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01Smear = cms.InputTag(
"patPFMetT0pcT1SmearTxyNoHF")
del process.slimmedMETsNoHF.caloMET
# ================== NoHF pfMET
# ================== CHSMET
process.CHSCands = cms.EDFilter("CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("fromPV(0) > 0"))
task.add(process.CHSCands)
from RecoMET.METProducers.pfMet_cfi import pfMet
process.pfMetCHS = pfMet.clone(src='CHSCands')
task.add(process.pfMetCHS)
addMETCollection(process, labelName="patCHSMet", metSource="pfMetCHS")
process.patCHSMet.computeMETSignificance = cms.bool(False)
# ================== CHSMET
# ================== TrkMET
process.TrkCands = cms.EDFilter(
"CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string(
"charge()!=0 && pvAssociationQuality()>=4 && vertexRef().key()==0")
)
task.add(process.TrkCands)
process.pfMetTrk = pfMet.clone(src='TrkCands')
task.add(process.pfMetTrk)
addMETCollection(process, labelName="patTrkMet", metSource="pfMetTrk")
process.patTrkMet.computeMETSignificance = cms.bool(False)
# ================== TrkMET
## PU JetID
process.load("RecoJets.JetProducers.PileupJetID_cfi")
task.add(process.pileUpJetIDTask)
process.patJets.userData.userFloats.src = [
cms.InputTag("pileupJetId:fullDiscriminant"),
]
process.patJets.userData.userInts.src = [
cms.InputTag("pileupJetId:fullId"),
]
## Quark Gluon Likelihood
process.load('RecoJets.JetProducers.QGTagger_cfi')
task.add(process.QGTaggerTask)
process.patJets.userData.userFloats.src += [
cms.InputTag('QGTagger:qgLikelihood'),
]
## DeepCSV meta discriminators (simple arithmethic on output probabilities)
process.load('RecoBTag.Combined.deepFlavour_cff')
task.add(process.pfDeepCSVDiscriminatorsJetTags)
process.patJets.discriminatorSources.extend([
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:BvsAll'),
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:CvsB'),
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:CvsL'),
])
## CaloJets
process.caloJetMap = cms.EDProducer(
"RecoJetDeltaRValueMapProducer",
src=process.patJets.jetSource,
matched=cms.InputTag("ak4CaloJets"),
distMax=cms.double(0.4),
values=cms.vstring('pt', 'emEnergyFraction'),
valueLabels=cms.vstring('pt', 'emEnergyFraction'),
lazyParser=cms.bool(True))
task.add(process.caloJetMap)
process.patJets.userData.userFloats.src += [
cms.InputTag("caloJetMap:pt"),
cms.InputTag("caloJetMap:emEnergyFraction")
]
#Muon object modifications
from PhysicsTools.PatAlgos.slimming.muonIsolationsPUPPI_cfi import makeInputForPUPPIIsolationMuon
makeInputForPUPPIIsolationMuon(process)
#EGM object modifications
from PhysicsTools.PatAlgos.slimming.egmIsolationsPUPPI_cfi import makeInputForPUPPIIsolationEgm
makeInputForPUPPIIsolationEgm(process)
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
process.patElectrons.addElectronID = cms.bool(True)
electron_ids = [
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV70_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV71_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Fall17_94X_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Fall17_94X_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_noIso_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_iso_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_noIso_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_iso_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Summer16_80X_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring16_GeneralPurpose_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring16_HZZ_V1_cff',
]
switchOnVIDElectronIdProducer(process, DataFormat.MiniAOD, task)
process.egmGsfElectronIDs.physicsObjectSrc = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = cms.InputTag(
'reducedEgamma', 'reducedGedGsfElectrons')
# To use older DataFormats, the electronMVAValueMapProducer MUST take a updated electron collection
# such that the conversion variables are filled correctly.
process.load("RecoEgamma.EgammaTools.gedGsfElectronsTo106X_cff")
run2_miniAOD_80XLegacy.toModify(
task, func=lambda t: t.add(process.gedGsfElectronsFrom80XTo106XTask))
run2_miniAOD_80XLegacy.toModify(
process.electronMVAValueMapProducer,
keysForValueMaps=cms.InputTag('reducedEgamma',
'reducedGedGsfElectrons'),
src=cms.InputTag("gedGsfElectronsFrom80XTo106X"))
run2_miniAOD_94XFall17.toModify(
task, func=lambda t: t.add(process.gedGsfElectronsFrom94XTo106XTask))
run2_miniAOD_94XFall17.toModify(
process.electronMVAValueMapProducer,
keysForValueMaps=cms.InputTag('reducedEgamma',
'reducedGedGsfElectrons'),
src=cms.InputTag("gedGsfElectronsFrom94XTo106X"))
from Configuration.Eras.Modifier_pp_on_AA_2018_cff import pp_on_AA_2018
pp_on_AA_2018.toModify(
task, func=lambda t: t.add(process.gedGsfElectronsFrom94XTo106XTask))
pp_on_AA_2018.toModify(process.electronMVAValueMapProducer,
keysForValueMaps=cms.InputTag(
'reducedEgamma', 'reducedGedGsfElectrons'),
src="gedGsfElectronsFrom94XTo106X")
for idmod in electron_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDElectronSelection, None,
False, task)
#VID Photon IDs
process.patPhotons.addPhotonID = cms.bool(True)
photon_ids = [
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Fall17_94X_V1_TrueVtx_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Fall17_94X_V2_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Fall17_94X_V1p1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Fall17_94X_V2_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring16_V2p2_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring16_nonTrig_V1_cff'
]
switchOnVIDPhotonIdProducer(process, DataFormat.AOD, task)
process.egmPhotonIDs.physicsObjectSrc = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.photonMVAValueMapProducer.src = cms.InputTag(
'reducedEgamma', 'reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDPhotonSelection, None,
False, task)
#add the cut base IDs bitmaps of which cuts passed
from RecoEgamma.EgammaTools.egammaObjectModifications_tools import makeVIDBitsModifier
egamma_modifications.append(
makeVIDBitsModifier(process, "egmGsfElectronIDs", "egmPhotonIDs"))
#-- Adding boosted taus
from RecoTauTag.Configuration.boostedHPSPFTaus_cfi import addBoostedTaus
addBoostedTaus(process)
process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
process.load("RecoTauTag.Configuration.HPSPFTaus_cff")
#-- Adding customization for 94X 2017 legacy reMniAOD
_makePatTausTaskWithRetrainedMVATauID = process.makePatTausTask.copy()
_makePatTausTaskWithRetrainedMVATauID.add(
process.hpsPFTauBasicDiscriminatorsTask,
process.hpsPFTauDiscriminationByIsolationMVArun2v1DBoldDMwLTTask,
process.hpsPFTauDiscriminationByIsolationMVArun2v1DBnewDMwLTTask,
process.hpsPFTauBasicDiscriminatorsdR03Task,
process.hpsPFTauDiscriminationByIsolationMVArun2v1DBdR03oldDMwLTTask,
process.hpsPFTauDiscriminationByMVA6rawElectronRejection,
process.hpsPFTauDiscriminationByMVA6ElectronRejection,
process.hpsPFTauDiscriminationByMuonRejection3)
from Configuration.ProcessModifiers.run2_miniAOD_UL_cff import run2_miniAOD_UL
(run2_miniAOD_94XFall17 | run2_miniAOD_UL).toReplaceWith(
process.makePatTausTask, _makePatTausTaskWithRetrainedMVATauID)
#-- Adding DeepTauID
# deepTau v2p1
_updatedTauName = 'slimmedTausDeepIDsv2p1'
_noUpdatedTauName = 'slimmedTausNoDeepIDs'
import RecoTauTag.RecoTau.tools.runTauIdMVA as tauIdConfig
tauIdEmbedder = tauIdConfig.TauIDEmbedder(process,
debug=False,
updatedTauName=_updatedTauName,
toKeep=['deepTau2017v2p1'])
from Configuration.Eras.Modifier_phase2_common_cff import phase2_common #Phase2 Tau MVA
phase2_common.toModify(
tauIdEmbedder.toKeep,
func=lambda t: t.append('newDMPhase2v1')) #Phase2 Tau MVA
tauIdEmbedder.runTauID()
addToProcessAndTask(_noUpdatedTauName, process.slimmedTaus.clone(),
process, task)
delattr(process, 'slimmedTaus')
process.deepTau2017v2p1.taus = _noUpdatedTauName
process.slimmedTaus = getattr(process,
_updatedTauName).clone(src=_noUpdatedTauName)
process.deepTauIDTask = cms.Task(process.deepTau2017v2p1,
process.slimmedTaus)
task.add(process.deepTauIDTask)
if 'newDMPhase2v1' in tauIdEmbedder.toKeep:
process.rerunDiscriminationByIsolationMVADBnewDMwLTPhase2raw.PATTauProducer = _noUpdatedTauName
process.rerunDiscriminationByIsolationMVADBnewDMwLTPhase2.PATTauProducer = _noUpdatedTauName
task.add(process.rerunIsolationMVADBnewDMwLTPhase2Task)
#-- Rerun tauID against dead ECal towers to taus for the various re-MiniAOD eras
# to enable default behoviour with leading track extrapolation to ECAL
_makePatTausTaskWithDeadECalVeto = process.makePatTausTask.copy()
_makePatTausTaskWithDeadECalVeto.add(
process.hpsPFTauDiscriminationByDeadECALElectronRejection)
_run2_miniAOD_ANY = (run2_miniAOD_80XLegacy | run2_miniAOD_94XFall17
| run2_miniAOD_UL)
_run2_miniAOD_ANY.toReplaceWith(process.makePatTausTask,
_makePatTausTaskWithDeadECalVeto)
#-- Adding customization for 80X 2016 legacy reMiniAOD and 2018 heavy ions
_makePatTausTaskWithTauReReco = process.makePatTausTask.copy()
_makePatTausTaskWithTauReReco.add(process.PFTauTask)
(run2_miniAOD_80XLegacy | pp_on_AA_2018).toReplaceWith(
process.makePatTausTask, _makePatTausTaskWithTauReReco)
# Adding puppi jets
process.load('CommonTools.PileupAlgos.Puppi_cff')
process.load('RecoJets.JetProducers.ak4PFJets_cfi')
from Configuration.Eras.Modifier_pA_2016_cff import pA_2016
_rerun_puppijets_task = task.copy()
_rerun_puppijets_task.add(process.puppi, process.ak4PFJetsPuppi)
(_run2_miniAOD_ANY | pA_2016 | pp_on_AA_2018).toReplaceWith(
task, _rerun_puppijets_task)
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer(
"JetTracksAssociatorAtVertex",
j2tParametersVX,
jets=cms.InputTag("ak4PFJetsPuppi"))
task.add(process.ak4PFJetsPuppiTracksAssociatorAtVertex)
process.patJetPuppiCharge = cms.EDProducer(
"JetChargeProducer",
src=cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var=cms.string('Pt'),
exp=cms.double(1.0))
task.add(process.patJetPuppiCharge)
noDeepFlavourDiscriminators = [
x.value() for x in process.patJets.discriminatorSources
if not "DeepFlavour" in x.value()
]
addJetCollection(process,
postfix="",
labelName='Puppi',
jetSource=cms.InputTag('ak4PFJetsPuppi'),
jetCorrections=('AK4PFPuppi',
['L2Relative', 'L3Absolute'], ''),
pfCandidates=cms.InputTag("particleFlow"),
algo='AK',
rParam=0.4,
btagDiscriminators=noDeepFlavourDiscriminators)
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 15")
from PhysicsTools.PatAlgos.slimming.applyDeepBtagging_cff import applyDeepBtagging
applyDeepBtagging(process)
addToProcessAndTask(
'slimmedJetsPuppi',
process.slimmedJetsNoDeepFlavour.clone(
src="selectedPatJetsPuppi",
packedPFCandidates="packedPFCandidates"), process, task)
task.add(process.slimmedJetsPuppi)
# Embed pixelClusterTagInfos in slimmedJets
process.patJets.addTagInfos = True
process.patJets.tagInfoSources = ["pixelClusterTagInfos"]
process.slimmedJetsNoDeepFlavour.dropTagInfos = '0'
process.updatedPatJetsTransientCorrectedSlimmedDeepFlavour.addTagInfos = True
process.updatedPatJetsTransientCorrectedSlimmedDeepFlavour.tagInfoSources = [
"pixelClusterTagInfos"
]
_run2_miniAOD_ANY.toModify(process.patJets, addTagInfos=False)
_run2_miniAOD_ANY.toModify(
process.updatedPatJetsTransientCorrectedSlimmedDeepFlavour,
addTagInfos=False)
## puppi met
process.load('RecoMET.METProducers.pfMetPuppi_cfi')
_rerun_puppimet_task = task.copy()
_rerun_puppimet_task.add(process.puppiNoLep, process.pfMetPuppi)
(_run2_miniAOD_ANY | pA_2016 | pp_on_AA_2018).toReplaceWith(
task, _rerun_puppimet_task)
runMetCorAndUncForMiniAODProduction(process,
metType="Puppi",
jetCollUnskimmed="slimmedJetsPuppi",
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
postfix="Puppi")
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsPuppi', process.slimmedMETs.clone(),
process, task)
process.slimmedMETsPuppi.src = cms.InputTag("patMETsPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi")
process.slimmedMETsPuppi.t1Uncertainties = cms.InputTag(
"patPFMetT1%sPuppi")
process.slimmedMETsPuppi.t01Variation = cms.InputTag("patPFMetT0pcT1Puppi")
process.slimmedMETsPuppi.t1SmearedVarsAndUncs = cms.InputTag(
"patPFMetT1Smear%sPuppi")
process.slimmedMETsPuppi.tXYUncForRaw = cms.InputTag("patPFMetTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1 = cms.InputTag("patPFMetT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01 = cms.InputTag(
"patPFMetT0pcT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1Smear = cms.InputTag(
"patPFMetT1SmearTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01Smear = cms.InputTag(
"patPFMetT0pcT1SmearTxyPuppi")
del process.slimmedMETsPuppi.caloMET
process.load('RecoMET.METPUSubtraction.deepMETProducer_cfi')
addToProcessAndTask('deepMETsResolutionTune',
process.deepMETProducer.clone(), process, task)
addToProcessAndTask('deepMETsResponseTune',
process.deepMETProducer.clone(), process, task)
process.deepMETsResponseTune.graph_path = 'RecoMET/METPUSubtraction/data/deepmet/deepmet_resp_v1_2018.pb'
from Configuration.Eras.Modifier_phase2_common_cff import phase2_common
phase2_common.toModify(
process.deepMETsResolutionTune,
max_n_pf=12500,
graph_path="RecoMET/METPUSubtraction/data/deepmet/deepmet_v1_phase2.pb"
)
phase2_common.toModify(
process.deepMETsResponseTune,
max_n_pf=12500,
graph_path=
"RecoMET/METPUSubtraction/data/deepmet/deepmet_resp_v1_phase2.pb")
from Configuration.Eras.Modifier_run2_jme_2016_cff import run2_jme_2016
run2_jme_2016.toModify(
process.deepMETsResponseTune,
graph_path=
"RecoMET/METPUSubtraction/data/deepmet/deepmet_resp_v1_2016.pb")
# add DetIdAssociatorRecords to EventSetup (for isolatedTracks)
process.load("TrackingTools.TrackAssociator.DetIdAssociatorESProducer_cff")
# EGamma objects from HGCal are not yet in GED
# so add companion collections for Phase-II MiniAOD production
from Configuration.Eras.Modifier_phase2_hgcal_cff import phase2_hgcal
process.load("RecoEgamma.EgammaTools.slimmedEgammaFromMultiCl_cff")
phase2_hgcal.toModify(
task, func=lambda t: t.add(process.slimmedEgammaFromMultiClTask))
# L1 pre-firing weights for 2016 and 2017
from Configuration.Eras.Modifier_run2_L1prefiring_cff import run2_L1prefiring
from Configuration.Eras.Modifier_stage1L1Trigger_cff import stage1L1Trigger
from Configuration.Eras.Modifier_stage2L1Trigger_2017_cff import stage2L1Trigger_2017
process.load("PhysicsTools.PatUtils.L1ECALPrefiringWeightProducer_cff")
stage1L1Trigger.toModify(process.prefiringweight, DataEra="2016BtoH")
stage2L1Trigger_2017.toModify(process.prefiringweight, DataEra="2017BtoF")
run2_L1prefiring.toModify(task,
func=lambda t: t.add(process.prefiringweight))
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
process.patMuons.addPuppiIsolation = cms.bool(True)
process.patMuons.puppiIsolationChargedHadrons = cms.InputTag("muonPUPPIIsolation","h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiIsolationNeutralHadrons = cms.InputTag("muonPUPPIIsolation","h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiIsolationPhotons = cms.InputTag("muonPUPPIIsolation","gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag("muonPUPPINoLeptonsIsolation","h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag("muonPUPPINoLeptonsIsolation","h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationPhotons = cms.InputTag("muonPUPPINoLeptonsIsolation","gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.computeMiniIso = cms.bool(True)
process.patMuons.computeMuonMVA = cms.bool(True)
process.patMuons.computeSoftMuonMVA = cms.bool(True)
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.patElectrons.usePfCandidateMultiMap = True
process.patElectrons.pfCandidateMultiMap = cms.InputTag("reducedEgamma","reducedGsfElectronPfCandMap")
process.patElectrons.electronIDSources = cms.PSet()
from Configuration.Eras.Modifier_run2_miniAOD_80XLegacy_cff import run2_miniAOD_80XLegacy
run2_miniAOD_80XLegacy.toModify(process.patElectrons,
addPFClusterIso = cms.bool(True),
ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleEcalPFClusIso"),
hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleHcalPFClusIso"))
from Configuration.Eras.Modifier_run2_miniAOD_94XFall17_cff import run2_miniAOD_94XFall17
run2_miniAOD_94XFall17.toModify(process.patElectrons,
addPFClusterIso = cms.bool(True),
ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleEcalPFClusIso"),
hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "eleHcalPFClusIso"))
#add puppi isolation in miniAOD
process.patElectrons.addPuppiIsolation = cms.bool(True)
process.patElectrons.puppiIsolationChargedHadrons = cms.InputTag("egmElectronPUPPIIsolation","h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiIsolationNeutralHadrons = cms.InputTag("egmElectronPUPPIIsolation","h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiIsolationPhotons = cms.InputTag("egmElectronPUPPIIsolation","gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiNoLeptonsIsolationPhotons = cms.InputTag("egmElectronPUPPINoLeptonsIsolation","gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.computeMiniIso = cms.bool(True)
process.elPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
#add puppi isolation in miniAOD
process.patPhotons.addPuppiIsolation = cms.bool(True)
process.patPhotons.puppiIsolationChargedHadrons = cms.InputTag("egmPhotonPUPPIIsolation","h+-DR030-")
process.patPhotons.puppiIsolationNeutralHadrons = cms.InputTag("egmPhotonPUPPIIsolation","h0-DR030-")
process.patPhotons.puppiIsolationPhotons = cms.InputTag("egmPhotonPUPPIIsolation","gamma-DR030-")
from Configuration.Eras.Modifier_run2_miniAOD_80XLegacy_cff import run2_miniAOD_80XLegacy
run2_miniAOD_80XLegacy.toModify(process.patPhotons,
addPFClusterIso = cms.bool(True),
ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoEcalPFClusIso"),
hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoHcalPFClusIso"))
from Configuration.Eras.Modifier_run2_miniAOD_94XFall17_cff import run2_miniAOD_94XFall17
run2_miniAOD_94XFall17.toModify(process.patPhotons,
addPFClusterIso = cms.bool(True),
ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoEcalPFClusIso"),
hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "phoHcalPFClusIso"))
#the 80X legacy customsations are done in ootPhotonProducer for OOT photons
run2_miniAOD_94XFall17.toModify(process.patOOTPhotons,
addPFClusterIso = cms.bool(True),
ecalPFClusterIsoMap = cms.InputTag("reducedEgamma", "ootPhoEcalPFClusIso"),
hcalPFClusterIsoMap = cms.InputTag("reducedEgamma", "ootPhoHcalPFClusIso"))
process.patPhotons.photonSource = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.phPFIsoDepositChargedPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma","reducedGedPhotons")
#
process.patOOTPhotons.photonSource = cms.InputTag("reducedEgamma","reducedOOTPhotons")
process.patOOTPhotons.electronSource = cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string("pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))")
from Configuration.Eras.Modifier_phase2_muon_cff import phase2_muon
phase2_muon.toModify(process.selectedPatMuons, cut = "pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose') || muonID('ME0MuonArbitrated') || muonID('GEMMuonArbitrated')) )")
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string("pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure( process )
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, outputModule = '' )
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I + other PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncForMiniAODProduction
runMetCorAndUncForMiniAODProduction(process, metType="PF",
jetCollUnskimmed="patJets")
#caloMET computation
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process,
labelName = "patCaloMet",
metSource = "caloMetM"
)
#noHF pfMET =========
task = getPatAlgosToolsTask(process)
process.noHFCands = cms.EDFilter("GenericPFCandidateSelector",
src=cms.InputTag("particleFlow"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0")
)
task.add(process.noHFCands)
runMetCorAndUncForMiniAODProduction(process,
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True, #needed for HF removal
jetSelection="pt>15 && abs(eta)<3.",
postfix="NoHF"
)
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsNoHF', process.slimmedMETs.clone(), process, task)
process.slimmedMETsNoHF.src = cms.InputTag("patMETsNoHF")
process.slimmedMETsNoHF.rawVariation = cms.InputTag("patPFMetNoHF")
process.slimmedMETsNoHF.t1Uncertainties = cms.InputTag("patPFMetT1%sNoHF")
process.slimmedMETsNoHF.t01Variation = cms.InputTag("patPFMetT0pcT1NoHF")
process.slimmedMETsNoHF.t1SmearedVarsAndUncs = cms.InputTag("patPFMetT1Smear%sNoHF")
process.slimmedMETsNoHF.tXYUncForRaw = cms.InputTag("patPFMetTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1 = cms.InputTag("patPFMetT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01 = cms.InputTag("patPFMetT0pcT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1Smear = cms.InputTag("patPFMetT1SmearTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01Smear = cms.InputTag("patPFMetT0pcT1SmearTxyNoHF")
del process.slimmedMETsNoHF.caloMET
# ================== NoHF pfMET
# ================== CHSMET
process.CHSCands = cms.EDFilter("CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("fromPV(0) > 0")
)
task.add(process.CHSCands)
process.pfMetCHS = cms.EDProducer("PFMETProducer",
src = cms.InputTag("CHSCands"),
alias = cms.string('pfMet'),
globalThreshold = cms.double(0.0),
calculateSignificance = cms.bool(False),
)
task.add(process.pfMetCHS)
addMETCollection(process,
labelName = "patCHSMet",
metSource = "pfMetCHS"
)
process.patCHSMet.computeMETSignificance = cms.bool(False)
# ================== CHSMET
# ================== TrkMET
process.TrkCands = cms.EDFilter("CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("charge()!=0 && pvAssociationQuality()>=4 && vertexRef().key()==0")
)
task.add(process.TrkCands)
process.pfMetTrk = cms.EDProducer("PFMETProducer",
src = cms.InputTag("TrkCands"),
alias = cms.string('pfMet'),
globalThreshold = cms.double(0.0),
calculateSignificance = cms.bool(False),
)
task.add(process.pfMetTrk)
addMETCollection(process,
labelName = "patTrkMet",
metSource = "pfMetTrk"
)
process.patTrkMet.computeMETSignificance = cms.bool(False)
# ================== TrkMET
## PU JetID
process.load("RecoJets.JetProducers.PileupJetID_cfi")
task.add(process.pileUpJetIDTask)
process.patJets.userData.userFloats.src = [ cms.InputTag("pileupJetId:fullDiscriminant"), ]
process.patJets.userData.userInts.src = [ cms.InputTag("pileupJetId:fullId"), ]
## Quark Gluon Likelihood
process.load('RecoJets.JetProducers.QGTagger_cfi')
task.add(process.QGTaggerTask)
process.patJets.userData.userFloats.src += [ cms.InputTag('QGTagger:qgLikelihood'), ]
## DeepCSV meta discriminators (simple arithmethic on output probabilities)
process.load('RecoBTag.Combined.deepFlavour_cff')
task.add(process.pfDeepCSVDiscriminatorsJetTags)
process.patJets.discriminatorSources.extend([
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:BvsAll' ),
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:CvsB' ),
cms.InputTag('pfDeepCSVDiscriminatorsJetTags:CvsL' ),
])
## CaloJets
process.caloJetMap = cms.EDProducer("RecoJetDeltaRValueMapProducer",
src = process.patJets.jetSource,
matched = cms.InputTag("ak4CaloJets"),
distMax = cms.double(0.4),
values = cms.vstring('pt','emEnergyFraction'),
valueLabels = cms.vstring('pt','emEnergyFraction'),
lazyParser = cms.bool(True) )
task.add(process.caloJetMap)
process.patJets.userData.userFloats.src += [ cms.InputTag("caloJetMap:pt"), cms.InputTag("caloJetMap:emEnergyFraction") ]
#Muon object modifications
from PhysicsTools.PatAlgos.slimming.muonIsolationsPUPPI_cfi import makeInputForPUPPIIsolationMuon
makeInputForPUPPIIsolationMuon(process)
#EGM object modifications
from PhysicsTools.PatAlgos.slimming.egmIsolationsPUPPI_cfi import makeInputForPUPPIIsolationEgm
makeInputForPUPPIIsolationEgm(process)
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
process.patElectrons.addElectronID = cms.bool(True)
electron_ids = ['RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV70_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Fall17_94X_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Fall17_94X_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_noIso_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_iso_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Summer16_80X_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring16_GeneralPurpose_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring16_HZZ_V1_cff',
]
switchOnVIDElectronIdProducer(process,DataFormat.MiniAOD, task)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
process.electronRegressionValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
for idmod in electron_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDElectronSelection,None,False,task)
#heepIDVarValueMaps only exists if HEEP V6.1 or HEEP 7.0 ID has already been loaded
if hasattr(process,'heepIDVarValueMaps'):
process.heepIDVarValueMaps.elesMiniAOD = cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
#force HEEP to use miniAOD (otherwise it'll detect the AOD)
process.heepIDVarValueMaps.dataFormat = cms.int32(2)
#add the HEEP trk isol to the slimmed electron, add it to the first FromFloatValMap modifier
for pset in process.slimmedElectrons.modifierConfig.modifications:
if pset.hasParameter("modifierName") and pset.modifierName == cms.string('EGExtraInfoModifierFromFloatValueMaps'):
pset.electron_config.heepTrkPtIso = cms.InputTag("heepIDVarValueMaps","eleTrkPtIso")
break
#VID Photon IDs
process.patPhotons.addPhotonID = cms.bool(True)
photon_ids = ['RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Fall17_94X_V1_TrueVtx_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Fall17_94X_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Fall17_94X_V1p1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring16_V2p2_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring16_nonTrig_V1_cff']
switchOnVIDPhotonIdProducer(process,DataFormat.AOD, task)
process.egmPhotonIsolation.srcToIsolate = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
for iPSet in process.egmPhotonIsolation.isolationConeDefinitions:
iPSet.particleBasedIsolation = cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.egmPhotonIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonRegressionValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.particleBasedIsolation = \
cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.photonMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process,idmod,setupVIDPhotonSelection,None,False,task)
#add the cut base IDs bitmaps of which cuts passed
from RecoEgamma.EgammaTools.egammaObjectModifications_tools import makeVIDBitsModifier
egamma_modifications.append(makeVIDBitsModifier(process,"egmGsfElectronIDs","egmPhotonIDs"))
#-- Adding boosted taus
from RecoTauTag.Configuration.boostedHPSPFTaus_cfi import addBoostedTaus
addBoostedTaus(process)
process.load("RecoTauTag.Configuration.RecoPFTauTag_cff")
process.load("RecoTauTag.Configuration.HPSPFTaus_cff")
#-- Adding customization for 94X 2017 legacy reMniAOD
from Configuration.Eras.Modifier_run2_miniAOD_94XFall17_cff import run2_miniAOD_94XFall17
_makePatTausTaskWithRetrainedMVATauID = process.makePatTausTask.copy()
_makePatTausTaskWithRetrainedMVATauID.add(process.hpsPFTauDiscriminationByIsolationMVArun2v1DBoldDMwLTTask)
run2_miniAOD_94XFall17.toReplaceWith(
process.makePatTausTask, _makePatTausTaskWithRetrainedMVATauID
)
#-- Adding customization for 80X 2016 legacy reMiniAOD
from Configuration.Eras.Modifier_run2_miniAOD_80XLegacy_cff import run2_miniAOD_80XLegacy
_makePatTausTaskWithTauReReco = process.makePatTausTask.copy()
_makePatTausTaskWithTauReReco.add(process.PFTauTask)
run2_miniAOD_80XLegacy.toReplaceWith(
process.makePatTausTask, _makePatTausTaskWithTauReReco
)
# Adding puppi jets
if not hasattr(process, 'ak4PFJetsPuppi'): #MM: avoid confilct with substructure call
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
task.add(process.ak4PFJets)
task.add(process.ak4PFJetsPuppi)
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer("JetTracksAssociatorAtVertex",
j2tParametersVX,
jets = cms.InputTag("ak4PFJetsPuppi")
)
task.add(process.ak4PFJetsPuppiTracksAssociatorAtVertex)
process.patJetPuppiCharge = cms.EDProducer("JetChargeProducer",
src = cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var = cms.string('Pt'),
exp = cms.double(1.0)
)
task.add(process.patJetPuppiCharge)
noDeepFlavourDiscriminators = [x.value() for x in process.patJets.discriminatorSources if not "DeepFlavour" in x.value()]
addJetCollection(process, postfix = "", labelName = 'Puppi', jetSource = cms.InputTag('ak4PFJetsPuppi'),
jetCorrections = ('AK4PFPuppi', ['L2Relative', 'L3Absolute'], ''),
pfCandidates = cms.InputTag("particleFlow"),
algo= 'AK', rParam = 0.4, btagDiscriminators = noDeepFlavourDiscriminators
)
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 15")
from PhysicsTools.PatAlgos.slimming.applyDeepBtagging_cff import applyDeepBtagging
applyDeepBtagging( process )
addToProcessAndTask('slimmedJetsPuppiNoMultiplicities', process.slimmedJetsNoDeepFlavour.clone(), process, task)
process.slimmedJetsPuppiNoMultiplicities.src = cms.InputTag("selectedPatJetsPuppi")
process.slimmedJetsPuppiNoMultiplicities.packedPFCandidates = cms.InputTag("packedPFCandidates")
from PhysicsTools.PatAlgos.patPuppiJetSpecificProducer_cfi import patPuppiJetSpecificProducer
from PhysicsTools.PatAlgos.tools.jetTools import updateJetCollection
process.patPuppiJetSpecificProducer = patPuppiJetSpecificProducer.clone(
src=cms.InputTag("slimmedJetsPuppiNoMultiplicities"),
)
task.add(process.patPuppiJetSpecificProducer)
updateJetCollection(
process,
labelName = 'PuppiJetSpecific',
jetSource = cms.InputTag('slimmedJetsPuppiNoMultiplicities'),
)
process.updatedPatJetsPuppiJetSpecific.userData.userFloats.src = ['patPuppiJetSpecificProducer:puppiMultiplicity', 'patPuppiJetSpecificProducer:neutralPuppiMultiplicity', 'patPuppiJetSpecificProducer:neutralHadronPuppiMultiplicity', 'patPuppiJetSpecificProducer:photonPuppiMultiplicity', 'patPuppiJetSpecificProducer:HFHadronPuppiMultiplicity', 'patPuppiJetSpecificProducer:HFEMPuppiMultiplicity' ]
process.slimmedJetsPuppi = process.selectedUpdatedPatJetsPuppiJetSpecific.clone()
delattr(process, 'selectedUpdatedPatJetsPuppiJetSpecific')
task.add(process.slimmedJetsPuppi)
## puppi met
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppies
makePuppies( process );
runMetCorAndUncForMiniAODProduction(process, metType="Puppi",
pfCandColl=cms.InputTag("puppiForMET"),
jetCollUnskimmed="slimmedJetsPuppi",
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
postfix="Puppi"
)
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsPuppi', process.slimmedMETs.clone(), process, task)
process.slimmedMETsPuppi.src = cms.InputTag("patMETsPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi")
process.slimmedMETsPuppi.t1Uncertainties = cms.InputTag("patPFMetT1%sPuppi")
process.slimmedMETsPuppi.t01Variation = cms.InputTag("patPFMetT0pcT1Puppi")
process.slimmedMETsPuppi.t1SmearedVarsAndUncs = cms.InputTag("patPFMetT1Smear%sPuppi")
process.slimmedMETsPuppi.tXYUncForRaw = cms.InputTag("patPFMetTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1 = cms.InputTag("patPFMetT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01 = cms.InputTag("patPFMetT0pcT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1Smear = cms.InputTag("patPFMetT1SmearTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01Smear = cms.InputTag("patPFMetT0pcT1SmearTxyPuppi")
del process.slimmedMETsPuppi.caloMET
# add DetIdAssociatorRecords to EventSetup (for isolatedTracks)
process.load("TrackingTools.TrackAssociator.DetIdAssociatorESProducer_cff")
# EGamma objects from HGCal are not yet in GED
# so add companion collections for Phase-II MiniAOD production
from Configuration.Eras.Modifier_phase2_hgcal_cff import phase2_hgcal
process.load("RecoEgamma.EgammaTools.slimmedEgammaFromMultiCl_cff")
phase2_hgcal.toModify(task, func=lambda t: t.add(process.slimmedEgammaFromMultiClTask))
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
process.patMuons.addPuppiIsolation = cms.bool(True)
process.patMuons.puppiIsolationChargedHadrons = cms.InputTag(
"muonPUPPIIsolation", "h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiIsolationNeutralHadrons = cms.InputTag(
"muonPUPPIIsolation", "h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiIsolationPhotons = cms.InputTag(
"muonPUPPIIsolation", "gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag(
"muonPUPPINoLeptonsIsolation", "h+-DR040-ThresholdVeto000-ConeVeto000")
process.patMuons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag(
"muonPUPPINoLeptonsIsolation", "h0-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.puppiNoLeptonsIsolationPhotons = cms.InputTag(
"muonPUPPINoLeptonsIsolation",
"gamma-DR040-ThresholdVeto000-ConeVeto001")
process.patMuons.computeMiniIso = cms.bool(True)
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose=cms.InputTag("reducedEgamma", "eidRobustLoose"),
eidRobustTight=cms.InputTag("reducedEgamma", "eidRobustTight"),
eidLoose=cms.InputTag("reducedEgamma", "eidLoose"),
eidTight=cms.InputTag("reducedEgamma", "eidTight"),
eidRobustHighEnergy=cms.InputTag("reducedEgamma",
"eidRobustHighEnergy"),
)
process.patElectrons.addPFClusterIso = cms.bool(True)
#add puppi isolation in miniAOD
process.patElectrons.addPuppiIsolation = cms.bool(True)
process.patElectrons.puppiIsolationChargedHadrons = cms.InputTag(
"egmElectronPUPPIIsolation", "h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiIsolationNeutralHadrons = cms.InputTag(
"egmElectronPUPPIIsolation", "h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiIsolationPhotons = cms.InputTag(
"egmElectronPUPPIIsolation", "gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.puppiNoLeptonsIsolationChargedHadrons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation", "h+-DR030-BarVeto000-EndVeto001")
process.patElectrons.puppiNoLeptonsIsolationNeutralHadrons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation", "h0-DR030-BarVeto000-EndVeto000")
process.patElectrons.puppiNoLeptonsIsolationPhotons = cms.InputTag(
"egmElectronPUPPINoLeptonsIsolation",
"gamma-DR030-BarVeto000-EndVeto008")
process.patElectrons.computeMiniIso = cms.bool(True)
process.patElectrons.ecalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "eleEcalPFClusIso")
process.patElectrons.hcalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "eleHcalPFClusIso")
process.elPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.addPFClusterIso = cms.bool(True)
#add puppi isolation in miniAOD
process.patPhotons.addPuppiIsolation = cms.bool(True)
process.patPhotons.puppiIsolationChargedHadrons = cms.InputTag(
"egmPhotonPUPPIIsolation", "h+-DR030-")
process.patPhotons.puppiIsolationNeutralHadrons = cms.InputTag(
"egmPhotonPUPPIIsolation", "h0-DR030-")
process.patPhotons.puppiIsolationPhotons = cms.InputTag(
"egmPhotonPUPPIIsolation", "gamma-DR030-")
process.patPhotons.ecalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "phoEcalPFClusIso")
process.patPhotons.hcalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "phoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight'))
process.phPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
#
process.patOOTPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedOOTPhotons")
process.patOOTPhotons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string(
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))"
)
from Configuration.Eras.Modifier_phase2_muon_cff import phase2_muon
phase2_muon.toModify(
process.selectedPatMuons,
cut=
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose') || muonID('ME0MuonArbitrated') || muonID('GEMMuonArbitrated')) )"
)
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string(
"pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure(process)
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone(process, outputModule='')
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I + other PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncForMiniAODProduction
runMetCorAndUncForMiniAODProduction(process,
metType="PF",
jetCollUnskimmed="patJets")
#caloMET computation
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process, labelName="patCaloMet", metSource="caloMetM")
#noHF pfMET =========
task = getPatAlgosToolsTask(process)
process.noHFCands = cms.EDFilter(
"GenericPFCandidateSelector",
src=cms.InputTag("particleFlow"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0"))
task.add(process.noHFCands)
runMetCorAndUncForMiniAODProduction(
process,
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True, #needed for HF removal
jetSelection="pt>15 && abs(eta)<3.",
postfix="NoHF")
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsNoHF', process.slimmedMETs.clone(),
process, task)
process.slimmedMETsNoHF.src = cms.InputTag("patMETsNoHF")
process.slimmedMETsNoHF.rawVariation = cms.InputTag("patPFMetNoHF")
process.slimmedMETsNoHF.t1Uncertainties = cms.InputTag("patPFMetT1%sNoHF")
process.slimmedMETsNoHF.t01Variation = cms.InputTag("patPFMetT0pcT1NoHF")
process.slimmedMETsNoHF.t1SmearedVarsAndUncs = cms.InputTag(
"patPFMetT1Smear%sNoHF")
process.slimmedMETsNoHF.tXYUncForRaw = cms.InputTag("patPFMetTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1 = cms.InputTag("patPFMetT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01 = cms.InputTag(
"patPFMetT0pcT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1Smear = cms.InputTag(
"patPFMetT1SmearTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01Smear = cms.InputTag(
"patPFMetT0pcT1SmearTxyNoHF")
del process.slimmedMETsNoHF.caloMET
# ================== NoHF pfMET
## PU JetID
process.load("RecoJets.JetProducers.PileupJetID_cfi")
task.add(process.pileUpJetIDTask)
process.patJets.userData.userFloats.src = [
cms.InputTag("pileupJetId:fullDiscriminant"),
]
process.patJets.userData.userInts.src = [
cms.InputTag("pileupJetId:fullId"),
]
## Quark Gluon Likelihood
process.load('RecoJets.JetProducers.QGTagger_cfi')
task.add(process.QGTaggerTask)
process.patJets.userData.userFloats.src += [
cms.InputTag('QGTagger:qgLikelihood'),
]
## CaloJets
process.caloJetMap = cms.EDProducer(
"RecoJetDeltaRValueMapProducer",
src=process.patJets.jetSource,
matched=cms.InputTag("ak4CaloJets"),
distMax=cms.double(0.4),
values=cms.vstring('pt', 'emEnergyFraction'),
valueLabels=cms.vstring('pt', 'emEnergyFraction'),
lazyParser=cms.bool(True))
task.add(process.caloJetMap)
process.patJets.userData.userFloats.src += [
cms.InputTag("caloJetMap:pt"),
cms.InputTag("caloJetMap:emEnergyFraction")
]
#Muon object modifications
from PhysicsTools.PatAlgos.slimming.muonIsolationsPUPPI_cfi import makeInputForPUPPIIsolationMuon
makeInputForPUPPIIsolationMuon(process)
#EGM object modifications
from PhysicsTools.PatAlgos.slimming.egmIsolationsPUPPI_cfi import makeInputForPUPPIIsolationEgm
makeInputForPUPPIIsolationEgm(process)
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
electron_ids = [
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_PHYS14_PU20bx25_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_25ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_50ns_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV60_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_nonTrig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_Trig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_50ns_Trig_V1_cff'
]
switchOnVIDElectronIdProducer(process, DataFormat.MiniAOD, task)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
process.electronRegressionValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
for idmod in electron_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDElectronSelection, None,
False, task)
#heepIDVarValueMaps only exists if HEEP V6.1 or HEEP 7.0 ID has already been loaded
if hasattr(process, 'heepIDVarValueMaps'):
process.heepIDVarValueMaps.elesMiniAOD = cms.InputTag(
'reducedEgamma', 'reducedGedGsfElectrons')
#force HEEP to use miniAOD (otherwise it'll detect the AOD)
process.heepIDVarValueMaps.dataFormat = cms.int32(2)
#VID Photon IDs
photon_ids = [
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_25ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_50ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_25ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_50ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring16_V2p2_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring16_nonTrig_V1_cff'
]
switchOnVIDPhotonIdProducer(process, DataFormat.AOD, task)
process.egmPhotonIsolation.srcToIsolate = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
for iPSet in process.egmPhotonIsolation.isolationConeDefinitions:
iPSet.particleBasedIsolation = cms.InputTag("reducedEgamma",
"reducedPhotonPfCandMap")
process.egmPhotonIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonRegressionValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.particleBasedIsolation = \
cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.photonMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDPhotonSelection, None,
False, task)
#---------------------------------------------------------------------------
#Adding Boosted Subjets taus
from RecoTauTag.Configuration.boostedHPSPFTaus_cfi import addBoostedTaus
addBoostedTaus(process)
#---------------------------------------------------------------------------
# Adding puppi jets
if not hasattr(
process,
'ak4PFJetsPuppi'): #MM: avoid confilct with substructure call
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
task.add(process.ak4PFJets)
task.add(process.ak4PFJetsPuppi)
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer(
"JetTracksAssociatorAtVertex",
j2tParametersVX,
jets=cms.InputTag("ak4PFJetsPuppi"))
task.add(process.ak4PFJetsPuppiTracksAssociatorAtVertex)
process.patJetPuppiCharge = cms.EDProducer(
"JetChargeProducer",
src=cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var=cms.string('Pt'),
exp=cms.double(1.0))
task.add(process.patJetPuppiCharge)
addJetCollection(
process,
postfix="",
labelName='Puppi',
jetSource=cms.InputTag('ak4PFJetsPuppi'),
jetCorrections=('AK4PFPuppi', ['L2Relative', 'L3Absolute'], ''),
pfCandidates=cms.InputTag(
'puppi'
), # using Puppi candidates as input for b tagging of Puppi jets
algo='AK',
rParam=0.4,
btagDiscriminators=map(lambda x: x.value(),
process.patJets.discriminatorSources))
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 15")
process.load('PhysicsTools.PatAlgos.slimming.slimmedJets_cfi')
task.add(process.slimmedJets)
task.add(process.slimmedJetsAK8)
addToProcessAndTask('slimmedJetsPuppi', process.slimmedJets.clone(),
process, task)
process.slimmedJetsPuppi.src = cms.InputTag("selectedPatJetsPuppi")
process.slimmedJetsPuppi.packedPFCandidates = cms.InputTag(
"packedPFCandidates")
## puppi met
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppies
makePuppies(process)
runMetCorAndUncForMiniAODProduction(process,
metType="Puppi",
pfCandColl=cms.InputTag("puppiForMET"),
jetCollUnskimmed="slimmedJetsPuppi",
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
postfix="Puppi")
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
task.add(process.slimmedMETs)
addToProcessAndTask('slimmedMETsPuppi', process.slimmedMETs.clone(),
process, task)
process.slimmedMETsPuppi.src = cms.InputTag("patMETsPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi")
process.slimmedMETsPuppi.t1Uncertainties = cms.InputTag(
"patPFMetT1%sPuppi")
process.slimmedMETsPuppi.t01Variation = cms.InputTag("patPFMetT0pcT1Puppi")
process.slimmedMETsPuppi.t1SmearedVarsAndUncs = cms.InputTag(
"patPFMetT1Smear%sPuppi")
process.slimmedMETsPuppi.tXYUncForRaw = cms.InputTag("patPFMetTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1 = cms.InputTag("patPFMetT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01 = cms.InputTag(
"patPFMetT0pcT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1Smear = cms.InputTag(
"patPFMetT1SmearTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01Smear = cms.InputTag(
"patPFMetT0pcT1SmearTxyPuppi")
del process.slimmedMETsPuppi.caloMET
# add DetIdAssociatorRecords to EventSetup (for isolatedTracks)
process.load("TrackingTools.TrackAssociator.DetIdAssociatorESProducer_cff")
process.Tracer = cms.Service( "Tracer" )
## Output
process.out = cms.OutputModule(
"PoolOutputModule"
, SelectEvents = cms.untracked.PSet(
SelectEvents = cms.vstring(
'p'
)
)
, fileName = cms.untracked.string( '%s/output/myPatTuple_addTriggerStandAloneInfoOnly_dataRAW.root'%( os.getenv( "CMSSW_BASE" ) ) )
, outputCommands = cms.untracked.vstring(
'drop *'
, 'keep edmTriggerResults_TriggerResults_*_*'
, 'keep *_hltTriggerSummaryAOD_*_*'
)
)
process.outpath = cms.EndPath(
process.out
)
## RAW to DIGI and RECO pre-requisites
process.load( "Configuration.StandardSequences.RawToDigi_Data_cff" )
process.p = cms.Path(
process.gtDigis
)
## PAT trigger
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone( process, hltProcess = '*' )
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose=cms.InputTag("reducedEgamma", "eidRobustLoose"),
eidRobustTight=cms.InputTag("reducedEgamma", "eidRobustTight"),
eidLoose=cms.InputTag("reducedEgamma", "eidLoose"),
eidTight=cms.InputTag("reducedEgamma", "eidTight"),
eidRobustHighEnergy=cms.InputTag("reducedEgamma",
"eidRobustHighEnergy"),
)
process.patElectrons.addPFClusterIso = cms.bool(True)
process.patElectrons.ecalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "eleEcalPFClusIso")
process.patElectrons.hcalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "eleHcalPFClusIso")
process.elPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositGammaPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.addPFClusterIso = cms.bool(True)
process.patPhotons.ecalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "phoEcalPFClusIso")
process.patPhotons.hcalPFClusterIsoMap = cms.InputTag(
"reducedEgamma", "phoHcalPFClusIso")
process.patPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.patPhotons.electronSource = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight'))
process.phPFIsoDepositChargedPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositChargedAllPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositNeutralPAT.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositGammaPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.phPFIsoDepositPUPAT.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string(
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))"
)
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string(
"pt > 18. && tauID('decayModeFindingNewDMs')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
from PhysicsTools.PatAlgos.slimming.applySubstructure_cff import applySubstructure
applySubstructure(process)
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone(process, outputModule='')
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I + other PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncForMiniAODProduction
runMetCorAndUncForMiniAODProduction(process,
metType="PF",
jetCollUnskimmed="patJets")
#caloMET computation
from PhysicsTools.PatAlgos.tools.metTools import addMETCollection
addMETCollection(process, labelName="patCaloMet", metSource="caloMetM")
#noHF pfMET =========
process.noHFCands = cms.EDFilter(
"GenericPFCandidateSelector",
src=cms.InputTag("particleFlow"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0"))
runMetCorAndUncForMiniAODProduction(
process,
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True, #needed for HF removal
jetSelection="pt>15 && abs(eta)<3.",
postfix="NoHF")
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
process.slimmedMETsNoHF = process.slimmedMETs.clone()
process.slimmedMETsNoHF.src = cms.InputTag("patMETsNoHF")
process.slimmedMETsNoHF.rawVariation = cms.InputTag("patPFMetNoHF")
process.slimmedMETsNoHF.t1Uncertainties = cms.InputTag("patPFMetT1%sNoHF")
process.slimmedMETsNoHF.t01Variation = cms.InputTag("patPFMetT0pcT1NoHF")
process.slimmedMETsNoHF.t1SmearedVarsAndUncs = cms.InputTag(
"patPFMetT1Smear%sNoHF")
process.slimmedMETsNoHF.tXYUncForRaw = cms.InputTag("patPFMetTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1 = cms.InputTag("patPFMetT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01 = cms.InputTag(
"patPFMetT0pcT1TxyNoHF")
process.slimmedMETsNoHF.tXYUncForT1Smear = cms.InputTag(
"patPFMetT1SmearTxyNoHF")
process.slimmedMETsNoHF.tXYUncForT01Smear = cms.InputTag(
"patPFMetT0pcT1SmearTxyNoHF")
del process.slimmedMETsNoHF.caloMET
# ================== NoHF pfMET
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
if not hasattr(process, 'pfImpactParameterTagInfos'):
process.load('RecoBTag.ImpactParameter.pfImpactParameterTagInfos_cfi')
if not hasattr(process, 'pfSecondaryVertexTagInfos'):
process.load('RecoBTag.SecondaryVertex.pfSecondaryVertexTagInfos_cfi')
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.M):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).numberOfSourceCandidatePtrs):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).value):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").flightDistance(0).significance):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).p4.z):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.x):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.y):(0)',
'?(tagInfoCandSecondaryVertex("pfSecondaryVertex").nVertices()>0)?(tagInfoCandSecondaryVertex("pfSecondaryVertex").secondaryVertex(0).vertex.z):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring(
'vtxMass', 'vtxNtracks', 'vtx3DVal', 'vtx3DSig', 'vtxPx', 'vtxPy',
'vtxPz', 'vtxPosX', 'vtxPosY', 'vtxPosZ')
process.patJets.tagInfoSources = cms.VInputTag(
cms.InputTag("pfSecondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("RecoJets.JetProducers.PileupJetID_cfi")
process.patJets.userData.userFloats.src = [
cms.InputTag("pileupJetId:fullDiscriminant"),
]
process.patJets.userData.userInts.src = [
cms.InputTag("pileupJetId:fullId"),
]
## CaloJets
process.caloJetMap = cms.EDProducer(
"RecoJetDeltaRValueMapProducer",
src=process.patJets.jetSource,
matched=cms.InputTag("ak4CaloJets"),
distMax=cms.double(0.4),
values=cms.vstring('pt', 'emEnergyFraction'),
valueLabels=cms.vstring('pt', 'emEnergyFraction'),
lazyParser=cms.bool(True))
process.patJets.userData.userFloats.src += [
cms.InputTag("caloJetMap:pt"),
cms.InputTag("caloJetMap:emEnergyFraction")
]
#EGM object modifications
from PhysicsTools.PatAlgos.slimming.egmIsolationsPUPPI_cfi import makeInputForPUPPIIsolationEgm
makeInputForPUPPIIsolationEgm(process)
from RecoEgamma.EgammaTools.egammaObjectModificationsInMiniAOD_cff import egamma_modifications
process.slimmedElectrons.modifierConfig.modifications = egamma_modifications
process.slimmedPhotons.modifierConfig.modifications = egamma_modifications
#VID Electron IDs
electron_ids = [
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_PHYS14_PU20bx25_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_25ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_Spring15_50ns_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV60_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_nonTrig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_25ns_Trig_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Spring15_50ns_Trig_V1_cff'
]
switchOnVIDElectronIdProducer(process, DataFormat.MiniAOD)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
process.electronRegressionValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedGsfElectrons')
for idmod in electron_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDElectronSelection, None,
False)
#VID Photon IDs
photon_ids = [
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_25ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.cutBasedPhotonID_Spring15_50ns_V1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_25ns_nonTrig_V2p1_cff',
'RecoEgamma.PhotonIdentification.Identification.mvaPhotonID_Spring15_50ns_nonTrig_V2p1_cff'
]
switchOnVIDPhotonIdProducer(process, DataFormat.MiniAOD)
process.egmPhotonIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonRegressionValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedPhotons")
process.photonIDValueMapProducer.particleBasedIsolation = \
cms.InputTag("reducedEgamma","reducedPhotonPfCandMap")
process.photonMVAValueMapProducer.src = \
cms.InputTag('reducedEgamma','reducedGedPhotons')
for idmod in photon_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDPhotonSelection, None,
False)
#---------------------------------------------------------------------------
#Adding Boosted Subjets taus
from RecoTauTag.Configuration.boostedHPSPFTaus_cfi import addBoostedTaus
addBoostedTaus(process)
#---------------------------------------------------------------------------
# Adding puppi jets
process.load('RecoJets.JetProducers.ak4PFJetsPuppi_cfi')
process.ak4PFJetsPuppi.doAreaFastjet = True # even for standard ak4PFJets this is overwritten in RecoJets/Configuration/python/RecoPFJets_cff
from RecoJets.JetAssociationProducers.j2tParametersVX_cfi import j2tParametersVX
process.ak4PFJetsPuppiTracksAssociatorAtVertex = cms.EDProducer(
"JetTracksAssociatorAtVertex",
j2tParametersVX,
jets=cms.InputTag("ak4PFJetsPuppi"))
process.patJetPuppiCharge = cms.EDProducer(
"JetChargeProducer",
src=cms.InputTag("ak4PFJetsPuppiTracksAssociatorAtVertex"),
var=cms.string('Pt'),
exp=cms.double(1.0))
addJetCollection(
process,
postfix="",
labelName='Puppi',
jetSource=cms.InputTag('ak4PFJetsPuppi'),
jetCorrections=('AK4PFPuppi', ['L2Relative', 'L3Absolute'], ''),
algo='AK',
rParam=0.4,
btagDiscriminators=map(lambda x: x.value(),
process.patJets.discriminatorSources))
process.patJetGenJetMatchPuppi.matched = 'slimmedGenJets'
process.patJetsPuppi.jetChargeSource = cms.InputTag("patJetPuppiCharge")
process.selectedPatJetsPuppi.cut = cms.string("pt > 15")
process.load('PhysicsTools.PatAlgos.slimming.slimmedJets_cfi')
process.slimmedJetsPuppi = process.slimmedJets.clone()
process.slimmedJetsPuppi.src = cms.InputTag("selectedPatJetsPuppi")
process.slimmedJetsPuppi.packedPFCandidates = cms.InputTag(
"packedPFCandidates")
## puppi met
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppies
makePuppies(process)
runMetCorAndUncForMiniAODProduction(process,
metType="PF",
pfCandColl=cms.InputTag("puppiForMET"),
jetCollUnskimmed="slimmedJetsPuppi",
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
postfix="Puppi")
process.load('PhysicsTools.PatAlgos.slimming.slimmedMETs_cfi')
process.slimmedMETsPuppi = process.slimmedMETs.clone()
process.slimmedMETsPuppi.src = cms.InputTag("patMETsPuppi")
process.slimmedMETsPuppi.rawVariation = cms.InputTag("patPFMetPuppi")
process.slimmedMETsPuppi.t1Uncertainties = cms.InputTag(
"patPFMetT1%sPuppi")
process.slimmedMETsPuppi.t01Variation = cms.InputTag("patPFMetT0pcT1Puppi")
process.slimmedMETsPuppi.t1SmearedVarsAndUncs = cms.InputTag(
"patPFMetT1Smear%sPuppi")
process.slimmedMETsPuppi.tXYUncForRaw = cms.InputTag("patPFMetTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1 = cms.InputTag("patPFMetT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01 = cms.InputTag(
"patPFMetT0pcT1TxyPuppi")
process.slimmedMETsPuppi.tXYUncForT1Smear = cms.InputTag(
"patPFMetT1SmearTxyPuppi")
process.slimmedMETsPuppi.tXYUncForT01Smear = cms.InputTag(
"patPFMetT0pcT1SmearTxyPuppi")
del process.slimmedMETsPuppi.caloMET
def miniAOD_customizeCommon(process):
process.patMuons.isoDeposits = cms.PSet()
process.patElectrons.isoDeposits = cms.PSet()
process.patTaus.isoDeposits = cms.PSet()
process.patPhotons.isoDeposits = cms.PSet()
#
process.patMuons.embedTrack = True # used for IDs
process.patMuons.embedCombinedMuon = True # used for IDs
process.patMuons.embedMuonBestTrack = True # used for IDs
process.patMuons.embedStandAloneMuon = True # maybe?
process.patMuons.embedPickyMuon = False # no, use best track
process.patMuons.embedTpfmsMuon = False # no, use best track
process.patMuons.embedDytMuon = False # no, use best track
#
# disable embedding of electron and photon associated objects already stored by the ReducedEGProducer
process.patElectrons.embedGsfElectronCore = False ## process.patElectrons.embed in AOD externally stored gsf electron core
process.patElectrons.embedSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedPflowSuperCluster = False ## process.patElectrons.embed in AOD externally stored supercluster
process.patElectrons.embedSeedCluster = False ## process.patElectrons.embed in AOD externally stored the electron's seedcluster
process.patElectrons.embedBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's basic clusters
process.patElectrons.embedPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's preshower clusters
process.patElectrons.embedPflowBasicClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow basic clusters
process.patElectrons.embedPflowPreshowerClusters = False ## process.patElectrons.embed in AOD externally stored the electron's pflow preshower clusters
process.patElectrons.embedRecHits = False ## process.patElectrons.embed in AOD externally stored the RecHits - can be called from the PATElectronProducer
process.patElectrons.electronSource = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.patElectrons.electronIDSources = cms.PSet(
# configure many IDs as InputTag <someName> = <someTag> you
# can comment out those you don't want to save some disk space
eidRobustLoose=cms.InputTag("reducedEgamma", "eidRobustLoose"),
eidRobustTight=cms.InputTag("reducedEgamma", "eidRobustTight"),
eidLoose=cms.InputTag("reducedEgamma", "eidLoose"),
eidTight=cms.InputTag("reducedEgamma", "eidTight"),
eidRobustHighEnergy=cms.InputTag("reducedEgamma",
"eidRobustHighEnergy"),
)
process.elPFIsoDepositCharged.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
process.elPFIsoDepositChargedAll.src = cms.InputTag(
"reducedEgamma", "reducedGedGsfElectrons")
process.elPFIsoDepositNeutral.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
process.elPFIsoDepositGamma.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
process.elPFIsoDepositPU.src = cms.InputTag("reducedEgamma",
"reducedGedGsfElectrons")
#
process.patPhotons.embedSuperCluster = False ## whether to process.patPhotons.embed in AOD externally stored supercluster
process.patPhotons.embedSeedCluster = False ## process.patPhotons.embed in AOD externally stored the photon's seedcluster
process.patPhotons.embedBasicClusters = False ## process.patPhotons.embed in AOD externally stored the photon's basic clusters
process.patPhotons.embedPreshowerClusters = False ## process.patPhotons.embed in AOD externally stored the photon's preshower clusters
process.patPhotons.embedRecHits = False ## process.patPhotons.embed in AOD externally stored the RecHits - can be called from the PATPhotonProducer
process.patPhotons.photonSource = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.patPhotons.photonIDSources = cms.PSet(
PhotonCutBasedIDLoose=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDLoose'),
PhotonCutBasedIDTight=cms.InputTag('reducedEgamma',
'PhotonCutBasedIDTight'))
process.phPFIsoDepositCharged.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.phPFIsoDepositChargedAll.src = cms.InputTag(
"reducedEgamma", "reducedGedPhotons")
process.phPFIsoDepositNeutral.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.phPFIsoDepositGamma.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
process.phPFIsoDepositPU.src = cms.InputTag("reducedEgamma",
"reducedGedPhotons")
#
process.selectedPatJets.cut = cms.string("pt > 10")
process.selectedPatMuons.cut = cms.string(
"pt > 5 || isPFMuon || (pt > 3 && (isGlobalMuon || isStandAloneMuon || numberOfMatches > 0 || muonID('RPCMuLoose')))"
)
process.selectedPatElectrons.cut = cms.string("")
process.selectedPatTaus.cut = cms.string(
"pt > 18. && tauID('decayModeFinding')> 0.5")
process.selectedPatPhotons.cut = cms.string("")
#
from PhysicsTools.PatAlgos.tools.jetTools import switchJetCollection
#switch to AK4 (though it should soon be unnecessary as ak4 should become the 71X default)
#FIXME: still using AK5PFchs for jet energy corrections, while waiting for a new globalTag
switchJetCollection(
process,
jetSource=cms.InputTag('ak4PFJetsCHS'),
jetCorrections=('AK4PFchs',
cms.vstring(['L1FastJet', 'L2Relative',
'L3Absolute']), ''),
btagDiscriminators=[
'jetBProbabilityBJetTags', 'jetProbabilityBJetTags',
'trackCountingHighPurBJetTags', 'trackCountingHighEffBJetTags',
'simpleSecondaryVertexHighEffBJetTags',
'simpleSecondaryVertexHighPurBJetTags',
'combinedSecondaryVertexBJetTags',
'combinedInclusiveSecondaryVertexBJetTags'
],
)
#add CA8
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
addJetCollection(
process,
labelName='AK8',
jetSource=cms.InputTag('ak8PFJetsCHS'),
algo='AK',
rParam=0.8,
jetCorrections=('AK7PFchs',
cms.vstring(['L1FastJet', 'L2Relative',
'L3Absolute']), 'None'))
process.patJetsAK8.userData.userFloats.src = [
] # start with empty list of user floats
process.selectedPatJetsAK8.cut = cms.string("pt > 100")
process.patJetGenJetMatchAK8.matched = 'slimmedGenJets'
## AK8 groomed masses
from RecoJets.Configuration.RecoPFJets_cff import ak8PFJetsCHSPruned, ak8PFJetsCHSFiltered, ak8PFJetsCHSTrimmed
process.ak8PFJetsCHSPruned = ak8PFJetsCHSPruned.clone()
process.ak8PFJetsCHSTrimmed = ak8PFJetsCHSTrimmed.clone()
process.ak8PFJetsCHSFiltered = ak8PFJetsCHSFiltered.clone()
process.load("RecoJets.JetProducers.ak8PFJetsCHS_groomingValueMaps_cfi")
process.patJetsAK8.userData.userFloats.src += [
'ak8PFJetsCHSPrunedLinks', 'ak8PFJetsCHSTrimmedLinks',
'ak8PFJetsCHSFilteredLinks'
]
### CA8 groomed masses (for the matched jet): doesn't seem to work, it produces tons of warnings "Matched jets separated by dR greater than distMax=0.8"
# from RecoJets.Configuration.RecoPFJets_cff import ca8PFJetsCHSFiltered, ca8PFJetsCHSTrimmed # ca8PFJetsCHSPruned is already in AOD
# process.ca8PFJetsCHSTrimmed = ca8PFJetsCHSTrimmed.clone()
# process.ca8PFJetsCHSFiltered = ca8PFJetsCHSFiltered.clone()
# process.load("RecoJets.JetProducers.ca8PFJetsCHS_groomingValueMaps_cfi")
# process.ca8PFJetsCHSPrunedLinks.src = cms.InputTag("ak8PFJetsCHS")
# process.ca8PFJetsCHSTrimmedLinks.src = cms.InputTag("ak8PFJetsCHS")
# process.ca8PFJetsCHSFilteredLinks.src = cms.InputTag("ak8PFJetsCHS")
# process.patJetsAK8.userData.userFloats.src += ['ca8PFJetsCHSPrunedLinks','ca8PFJetsCHSTrimmedLinks','ca8PFJetsCHSFilteredLinks']
## cmsTopTagger (note: it is already run in RECO, we just add the value)
process.cmsTopTagPFJetsCHSLinksAK8 = process.ak8PFJetsCHSPrunedLinks.clone(
)
process.cmsTopTagPFJetsCHSLinksAK8.src = cms.InputTag("ak8PFJetsCHS")
process.cmsTopTagPFJetsCHSLinksAK8.matched = cms.InputTag(
"cmsTopTagPFJetsCHS")
process.patJetsAK8.userData.userFloats.src += [
'cmsTopTagPFJetsCHSLinksAK8'
]
#
from PhysicsTools.PatAlgos.tools.trigTools import switchOnTriggerStandAlone
switchOnTriggerStandAlone(process, outputModule='')
process.patTrigger.packTriggerPathNames = cms.bool(True)
#
# apply type I/type I + II PFMEt corrections to pat::MET object
# and estimate systematic uncertainties on MET
# FIXME: this and the typeI MET should become AK4 once we have the proper JEC?
from PhysicsTools.PatUtils.tools.runType1PFMEtUncertainties import runType1PFMEtUncertainties
addJetCollection(process,
postfix="ForMetUnc",
labelName='AK4PF',
jetSource=cms.InputTag('ak4PFJets'),
jetCorrections=('AK4PF',
['L1FastJet', 'L2Relative',
'L3Absolute'], ''))
process.patJetsAK4PFForMetUnc.getJetMCFlavour = False
runType1PFMEtUncertainties(process,
addToPatDefaultSequence=False,
jetCollection="selectedPatJetsAK4PFForMetUnc",
electronCollection="selectedPatElectrons",
muonCollection="selectedPatMuons",
tauCollection="selectedPatTaus",
makeType1p2corrPFMEt=True,
outputModule=None)
#keep this after all addJetCollections otherwise it will attempt computing them also for stuf with no taginfos
#Some useful BTAG vars
process.patJets.userData.userFunctions = cms.vstring(
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).p4.M):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().secondaryVertex(0).nTracks):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).value):(0)',
'?(tagInfoSecondaryVertex().nVertices()>0)?(tagInfoSecondaryVertex().flightDistance(0).significance):(0)',
)
process.patJets.userData.userFunctionLabels = cms.vstring(
'vtxMass', 'vtxNtracks', 'vtx3DVal', 'vtx3DSig')
process.patJets.tagInfoSources = cms.VInputTag(
cms.InputTag("secondaryVertexTagInfos"))
process.patJets.addTagInfos = cms.bool(True)
#
## PU JetID
process.load("PhysicsTools.PatAlgos.slimming.pileupJetId_cfi")
process.patJets.userData.userFloats.src = [
cms.InputTag("pileupJetId:fullDiscriminant"),
]
#VID Electron IDs
electron_ids = [
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_CSA14_50ns_V1_cff',
'RecoEgamma.ElectronIdentification.Identification.cutBasedElectronID_CSA14_PU20bx25_V0_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV50_CSA14_25ns_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV50_CSA14_startup_cff'
]
switchOnVIDElectronIdProducer(process)
process.egmGsfElectronIDs.physicsObjectSrc = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronIDValueMapProducer.src = \
cms.InputTag("reducedEgamma","reducedGedGsfElectrons")
process.electronIDValueMapProducer.ebReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedEBRecHits")
process.electronIDValueMapProducer.eeReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedEERecHits")
process.electronIDValueMapProducer.esReducedRecHitCollection = \
cms.InputTag("reducedEgamma","reducedESRecHits")
for idmod in electron_ids:
setupAllVIDIdsInModule(process, idmod, setupVIDElectronSelection)
