def define_METs(process, runOnData=False):
"""Define reconstructed MET.
Configure recalculation of corrected MET and its systematic
uncertainties. Only type-1 corrections are applied. Due to
limitations of MET tools, uncertainties are calculated even when
running over data, while this is not needed. Moreover, they include
uncertainties corresponding to variations in energies of leptons,
taus, and photons, although these variations are not considered in
targeted analyses.
Arguments:
process: The process to which relevant MET producers are added.
runOnData: Flag to distinguish processing of data and
simulation.
Return value:
None.
Among other things, add to the process producer slimmedMETs, which
overrides the namesake collection from MiniAOD. User must use this
new collection.
"""
# Recalculate MET corrections [1]
# [1] https://twiki.cern.ch/twiki/bin/view/CMS/MissingETUncertaintyPrescription?rev=57#Instructions_for_8_0_X_X_20_for
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import \
runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=runOnData,
# electronColl='', muonColl='', photonColl='', tauColl='',
postfix=''
)
def nanoAOD_recalibrateMETs(process,isData):
runMetCorAndUncFromMiniAOD(process,isData=isData)
process.nanoSequenceCommon.insert(process.nanoSequenceCommon.index(jetSequence),cms.Sequence(process.fullPatMetSequence))
# makePuppiesFromMiniAOD(process,True) # call this before in the global customizer otherwise it would reset photon IDs in VID
# runMetCorAndUncFromMiniAOD(process,isData=isData,metType="Puppi",postfix="Puppi",jetFlavor="AK4PFPuppi")
# process.puppiNoLep.useExistingWeights = False
# process.puppi.useExistingWeights = False
# process.nanoSequenceCommon.insert(process.nanoSequenceCommon.index(jetSequence),cms.Sequence(process.puppiMETSequence+process.fullPatMetSequencePuppi))
return process
def makeAnalysisStep(self, stepName, **inputs):
step = super(RecomputeMetUncertainties, self).makeAnalysisStep(stepName, **inputs)
if stepName == 'preliminary':
# Recompute MET uncertainties with new JEC
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(self.process,
isData=not self.isMC,
)
step.addModule('fullPatMetSequence', self.process.fullPatMetSequence,
'met_fromUncertaintyTool', met_fromUncertaintyTool = ':Ntuple')
return step
def setup_MET(process, cms, options, postfix="PFlow"):
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
print '=' * 60
print "Re-running MET on MiniAOD"
print '=' * 60
runOnData = options.isData
# Running post Jet_Setup so GT should already be overwritten if needed?
# recalculate MET with JEC
runMetCorAndUncFromMiniAOD(
process,
isData=runOnData,
electronColl = cms.InputTag('calibratedPatElectrons'),
)
def setup_MET(process, cms, options, postfix="PFlow"):
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
print '=' * 60
print "Re-running MET on MiniAOD"
print '=' * 60
usePrivateSQlite = options.useJECFromFile
runOnData = options.isData
'''
application of residual corrections. Have to be set to True once the 13 TeV
residual corrections are available. False to be kept meanwhile. Can be kept
to False
'''
applyResiduals = options.applyResiduals
if usePrivateSQlite:
from CondCore.DBCommon.CondDBSetup_cfi import *
import os
era = "Fall15_25nsV2_"
if runOnData:
era += 'DATA'
else:
era += 'MC'
dBFile = os.path.expandvars(
era + ".db")
# "$CMSSW_BASE/src/BristolAnalysis/NTupleTools/data/JEC/" + era + ".db")
process.jec = cms.ESSource( "PoolDBESSource",CondDBSetup,
connect = cms.string( "sqlite_file:"+dBFile ),
toGet = cms.VPSet(
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+era+"_AK4PF"),
label= cms.untracked.string("AK4PF")
),
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+era+"_AK4PFchs"),
label= cms.untracked.string("AK4PFchs")
),
)
)
process.es_prefer_jec = cms.ESPrefer("PoolDBESSource",'jec')
# recalculate MET with JEC
runMetCorAndUncFromMiniAOD(
process,
isData=runOnData,
electronColl = cms.InputTag('calibratedPatElectrons'),
)
def configurePFMetForMiniAOD(process, data=False):
# do produce pfMet and No-HF pfMet, both raw and T1 corrected
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
jecUncertaintyFile="PhysicsTools/PatUtils/data/Summer15_50nsV4_DATA_UncertaintySources_AK4PFchs.txt"
runMetCorAndUncFromMiniAOD(process, isData=data, jecUncFile=jecUncertaintyFile )
process.noHFCands = cms.EDFilter("CandPtrSelector", src=cms.InputTag("packedPFCandidates"), cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0") )
runMetCorAndUncFromMiniAOD(process, isData=data, pfCandColl=cms.InputTag("noHFCands"), jecUncFile=jecUncertaintyFile, postfix="NoHF" )
process.patPFMet.computeMETSignificance = cms.bool(True)
process.patPFMet.srcLeptons = cms.VInputTag("slimmedTaus", "slimmedElectrons", "slimmedMuons")
process.patPFMetNoHF.computeMETSignificance = cms.bool(True)
process.patPFMetNoHF.srcLeptons = cms.VInputTag("slimmedTaus", "slimmedElectrons", "slimmedMuons")
process.pfMet.calculateSignificance = cms.bool(True)
process.pfMetNoHF.calculateSignificance = cms.bool(True)
from RecoMET.METProducers.METSignificanceParams_cfi import METSignificanceParams
process.pfMet.parameters = METSignificanceParams
process.pfMet.srcMet = cms.InputTag("pfMet")
process.pfMet.srcJets = cms.InputTag("slimmedJets")
process.pfMet.srcLeptons = cms.VInputTag("slimmedTaus", "slimmedElectrons", "slimmedMuons")
process.pfMetNoHF.parameters = METSignificanceParams
process.pfMetNoHF.srcMet = cms.InputTag("pfMetNoHF")
process.pfMetNoHF.srcJets = cms.InputTag("slimmedJets")
process.pfMetNoHF.srcLeptons = cms.VInputTag("slimmedTaus", "slimmedElectrons", "slimmedMuons")
process.pfMetNoHF.srcCandidates = cms.InputTag("noHFCands")
# temporary fix from Missing ET mailing list
process.patMETs.addGenMET = cms.bool(False)
process.patJets.addGenJetMatch = cms.bool(False)
process.patJets.addGenPartonMatch = cms.bool(False)
process.patJets.addPartonJetMatch = cms.bool(False)
process.makePFMET = cms.Sequence()
if not data:
process.makePFMET = cms.Sequence( process.genMetExtractor )
process.makePFMET *= cms.Sequence(
process.ak4PFJets *
process.pfMet *
process.patJetCorrFactors *
process.patJets *
process.patPFMetT1T2Corr
)
def runMETs(process,isMC):
#================================ Get the most recent JEC ==================================================================#
# Setup the private SQLite -- Ripped from PhysicsTools/PatAlgos/test/corMETFromMiniAOD.py
era = "Spring16_25nsV6"
if isMC :
era += "_MC"
else :
era += "_DATA"
dBFile = os.path.expandvars(era+".db")
print dBFile
if usePrivateSQlite:
process.jec = cms.ESSource("PoolDBESSource",
CondDBSetup,
connect = cms.string("sqlite_file:"+dBFile),
toGet = cms.VPSet(
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+era+"_AK4PF"),
label= cms.untracked.string("AK4PF")
),
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+era+"_AK4PFchs"),
label= cms.untracked.string("AK4PFchs")
),
)
)
process.es_prefer_jec = cms.ESPrefer("PoolDBESSource",'jec')
#===========================================================================================================================#
runMetCorAndUncFromMiniAOD(process, metType="PF",
jetCollUnskimmed="slimmedJets",
electronColl="slimmedElectrons",
photonColl="slimmedPhotons",
muonColl="slimmedMuons",
tauColl="slimmedTaus",
reclusterJets = False,
fixEE2017 = True,
pfCandColl = "packedPFCandidates",
# will produce new MET collection: slimmedMETsModifiedMET
postfix="ModifiedMET",
isData=(not isMC),
)
def nanoAOD_recalibrateMETs(process,isData):
runMetCorAndUncFromMiniAOD(process,isData=isData)
process.nanoSequenceCommon.insert(process.nanoSequenceCommon.index(process.jetSequence),cms.Sequence(process.fullPatMetSequence))
process.basicJetsForMetForT1METNano = process.basicJetsForMet.clone(
src = process.updatedJetsWithUserData.src,
skipEM = False,
type1JetPtThreshold = 0.0,
calcMuonSubtrRawPtAsValueMap = cms.bool(True),
)
process.jetSequence.insert(process.jetSequence.index(process.updatedJetsWithUserData),cms.Sequence(process.basicJetsForMetForT1METNano))
process.updatedJetsWithUserData.userFloats.muonSubtrRawPt = cms.InputTag("basicJetsForMetForT1METNano:MuonSubtrRawPt")
process.corrT1METJetTable.src = process.finalJets.src
process.corrT1METJetTable.cut = "pt<15 && abs(eta)<9.9"
for table in process.jetTable, process.corrT1METJetTable:
table.variables.muonSubtrFactor = Var("1-userFloat('muonSubtrRawPt')/(pt()*jecFactor('Uncorrected'))",float,doc="1-(muon-subtracted raw pt)/(raw pt)",precision=6)
process.metTables += process.corrT1METJetTable
# makePuppiesFromMiniAOD(process,True) # call this before in the global customizer otherwise it would reset photon IDs in VID
# runMetCorAndUncFromMiniAOD(process,isData=isData,metType="Puppi",postfix="Puppi",jetFlavor="AK4PFPuppi")
# process.puppiNoLep.useExistingWeights = False
# process.puppi.useExistingWeights = False
# process.nanoSequenceCommon.insert(process.nanoSequenceCommon.index(jetSequence),cms.Sequence(process.puppiMETSequence+process.fullPatMetSequencePuppi))
return process
def nanoAOD_runMETfixEE2017(process,isData):
runMetCorAndUncFromMiniAOD(process,isData=isData,
fixEE2017 = True,
fixEE2017Params = {'userawPt': True, 'ptThreshold':50.0, 'minEtaThreshold':2.65, 'maxEtaThreshold': 3.139},
postfix = "FixEE2017")
process.nanoSequenceCommon.insert(2,process.fullPatMetSequenceFixEE2017)
process.kappaTuple.PileupDensity.rename = cms.vstring(
"fixedGridRhoFastjetAll => pileupDensity")
#################
# Configure MET #
#################
# official Prescription for calculating corrections and uncertainties on Missing Transverse Energy (MET):
# https://twiki.cern.ch/twiki/bin/view/CMS/MissingETUncertaintyPrescription#Instructions_for_8_0_X_X_26_patc
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
# re-correct MET for JEC and get the proper uncertainties
# Note: this only affects the default (i.e. Type1-corrected) MET.
# Since we only write out the raw MET, this line likely has no effect.
runMetCorAndUncFromMiniAOD(process, isData=options.isData)
# -- end of MET recipe
# wire miniAOD METs to collection from the "KAPPA" process
process.kappaTuple.PatMET.metPF = cms.PSet(src=cms.InputTag("slimmedMETs"),
correctionLevel=cms.string('Raw'))
process.kappaTuple.PatMET.metCHS = cms.PSet(
src=cms.InputTag("slimmedMETs"), correctionLevel=cms.string('RawChs'))
process.kappaTuple.PatMET.metPuppi = cms.PSet(
src=cms.InputTag("slimmedMETsPuppi"), correctionLevel=cms.string('Raw'))
# -- activate KAPPA producers
process.kappaTuple.active += cms.vstring('PatMET')
##############
if not useHFCandidates:
process.noHFCands = cms.EDFilter(
"CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0"))
patAlgosToolsTask.add(process.noHFCands)
#jets are rebuilt from those candidates by the tools, no need to do anything else
### =================================================================================
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#default configuration for miniAOD reprocessing, change the isData flag to run on data
#for a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(
process,
isData=runOnData,
)
if not useHFCandidates:
runMetCorAndUncFromMiniAOD(
process,
isData=runOnData,
pfCandColl=cms.InputTag("noHFCands"),
reclusterJets=True, #needed for NoHF
recoMetFromPFCs=True, #needed for NoHF
postfix="NoHF")
if redoPuppi:
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
makePuppiesFromMiniAOD(process)
def reproduceMET(process, isdata):
from CondCore.DBCommon.CondDBSetup_cfi import *
import os
if isdata:
era = "Spring16_25nsV6_DATA"
else:
era = "Spring16_25nsV6_MC"
jerera = "Spring16_25nsV6"
##___________________________External JEC file________________________________||
process.jec = cms.ESSource(
"PoolDBESSource",
CondDBSetup,
# connect = cms.string("sqlite:PhysicsTools/PatUtils/data/"+era+".db"),
connect=cms.string("sqlite:" + era + "_JEC.db"),
toGet=cms.VPSet(
cms.PSet(record=cms.string("JetCorrectionsRecord"),
tag=cms.string("JetCorrectorParametersCollection_" + era +
"_AK4PF"),
label=cms.untracked.string("AK4PF")),
cms.PSet(record=cms.string("JetCorrectionsRecord"),
tag=cms.string("JetCorrectorParametersCollection_" + era +
"_AK4PFchs"),
label=cms.untracked.string("AK4PFchs")),
cms.PSet(record=cms.string("JetCorrectionsRecord"),
tag=cms.string("JetCorrectorParametersCollection_" + era +
"_AK4PFPuppi"),
label=cms.untracked.string("AK4PFPuppi")),
))
process.es_prefer_jec = cms.ESPrefer("PoolDBESSource", 'jec')
##___________________________External JER file________________________________||
process.jer = cms.ESSource(
"PoolDBESSource",
CondDBSetup,
# connect = cms.string("sqlite:PhysicsTools/PatUtils/data/JER/"+jerera+"_MC.db"),
connect=cms.string("sqlite:" + jerera + "_MC_JER.db"),
toGet=cms.VPSet(
#######
### read the PFchs
cms.PSet(record=cms.string('JetResolutionRcd'),
tag=cms.string('JR_' + jerera +
'_MC_PtResolution_AK4PFchs'),
label=cms.untracked.string('AK4PFchs_pt')),
cms.PSet(record=cms.string("JetResolutionRcd"),
tag=cms.string('JR_' + jerera +
'_MC_PhiResolution_AK4PFchs'),
label=cms.untracked.string("AK4PFchs_phi")),
cms.PSet(record=cms.string('JetResolutionScaleFactorRcd'),
tag=cms.string('JR_' + jerera + '_MC_SF_AK4PFchs'),
label=cms.untracked.string('AK4PFchs')),
#######
### read the Puppi JER
cms.PSet(record=cms.string('JetResolutionRcd'),
tag=cms.string('JR_' + jerera +
'_MC_PtResolution_AK4PFPuppi'),
label=cms.untracked.string('AK4PFPuppi_pt')),
cms.PSet(record=cms.string("JetResolutionRcd"),
tag=cms.string('JR_' + jerera +
'_MC_PhiResolution_AK4PFPuppi'),
label=cms.untracked.string("AK4PFPuppi_phi")),
cms.PSet(record=cms.string('JetResolutionScaleFactorRcd'),
tag=cms.string('JR_' + jerera + '_MC_SF_AK4PFPuppi'),
label=cms.untracked.string('AK4PFPuppi')),
))
process.es_prefer_jer = cms.ESPrefer("PoolDBESSource", 'jer')
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#default configuration for miniAOD reprocessing, change the isData flag to run on data
#for a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(
process,
isData=isdata,
)
# process.selectedPatJetsForMetT1T2Corr.src = cms.InputTag("cleanedPatJets")
# process.patPFMetT1.src = cms.InputTag("slimmedMETs")
#
# process.CustomisationsSequence += process.patJetCorrFactorsReapplyJEC
# process.CustomisationsSequence += process.patJetsReapplyJEC
# process.CustomisationsSequence += process.basicJetsForMet
# process.CustomisationsSequence += process.jetSelectorForMet
# process.CustomisationsSequence += process.cleanedPatJets
# process.CustomisationsSequence += process.metrawCalo
# process.CustomisationsSequence += process.selectedPatJetsForMetT1T2Corr
# process.CustomisationsSequence += process.patPFMetT1T2Corr
# process.CustomisationsSequence += process.patPFMetT1
# process.CustomisationsSequence += process.patMetCorrectionSequence
if isdata:
return
# process.CustomisationsSequence += process.patMetUncertaintySequence #only for MC
# process.CustomisationsSequence += process.patShiftedModuleSequence #only for MC
"""
labelName='UpdatedJEC',
jetCorrections=('AK4PFchs',
cms.vstring(['L1FastJet', 'L2Relative',
'L3Absolute']), 'None'))
process.jecSequence = cms.Sequence(process.patJetCorrFactorsUpdatedJEC *
process.updatedPatJetsUpdatedJEC)
#///////////////////////////////////////////////////////////
#Reham to update the MET after updating the JEC
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=False, #(or False),
postfix="TEST")
#/////////////////////////////////////////////////////
#Reham to add new instructiond for electron energy correction and smearing PLUS electron ID
from RecoEgamma.EgammaTools.EgammaPostRecoTools import setupEgammaPostRecoSeq
setupEgammaPostRecoSeq(
process,
runVID=True,
eleIDModules=[
'RecoEgamma.ElectronIdentification.Identification.mvaElectronID_Fall17_iso_V2_cff',
'RecoEgamma.ElectronIdentification.Identification.heepElectronID_HEEPV70_cff'
],
# runVID=True, #saves CPU time by not needlessly re-running VID
process.load('RecoMET.METFilters.BadChargedCandidateFilter_cfi')
process.BadChargedCandidateFilter.muons = cms.InputTag("slimmedMuons")
process.BadChargedCandidateFilter.PFCandidates = cms.InputTag(
"packedPFCandidates")
process.BadChargedCandidateFilter.taggingMode = cms.bool(True)
process.metfilterSequence = cms.Sequence(process.BadPFMuonFilter *
process.BadChargedCandidateFilter)
if not options.isData:
process.PandaNtupler.metfilter = cms.InputTag('TriggerResults', '', 'PAT')
############ RECOMPUTE PUPPI/MET #######################
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process, ## PF MET
isData=isData)
process.PandaNtupler.pfmet = cms.InputTag('slimmedMETs', '', 'PandaNtupler')
process.MonoXFilter.met = cms.InputTag('slimmedMETs', '', 'PandaNtupler')
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
makePuppiesFromMiniAOD(process, True)
process.puppi.useExistingWeights = False # I still don't trust miniaod...
process.puppiNoLep.useExistingWeights = False
runMetCorAndUncFromMiniAOD(
process, ## Puppi MET
isData=options.isData,
metType="Puppi",
def nanoAOD_recalibrateMETs(process, isData):
# add DeepMETs
nanoAOD_DeepMET_switch = cms.PSet(
nanoAOD_addDeepMET_switch=cms.untracked.bool(
True), # decide if DeeMET should be included in Nano
nanoAOD_produceDeepMET_switch=cms.untracked.bool(
False), # decide if DeepMET should be computed on the fly
ResponseTune_Graph=cms.untracked.string(
'RecoMET/METPUSubtraction/data/deepmet/deepmet_resp_v1_2018.pb'))
for modifier in run2_miniAOD_80XLegacy, run2_nanoAOD_94X2016, run2_nanoAOD_94XMiniAODv1, run2_nanoAOD_94XMiniAODv2, run2_nanoAOD_102Xv1, run2_nanoAOD_106Xv1:
# compute DeepMETs in these eras (before 111X)
modifier.toModify(
nanoAOD_DeepMET_switch,
nanoAOD_produceDeepMET_switch=cms.untracked.bool(True))
for modifier in run2_miniAOD_80XLegacy, run2_nanoAOD_94X2016:
modifier.toModify(
nanoAOD_DeepMET_switch,
ResponseTune_Graph=cms.untracked.string(
"RecoMET/METPUSubtraction/data/deepmet/deepmet_resp_v1_2016.pb"
))
if nanoAOD_DeepMET_switch.nanoAOD_addDeepMET_switch:
process = nanoAOD_addDeepMET(
process,
addDeepMETProducer=nanoAOD_DeepMET_switch.
nanoAOD_produceDeepMET_switch,
ResponseTune_Graph=nanoAOD_DeepMET_switch.ResponseTune_Graph)
# if included in Nano, and not computed in the fly, then it should be extracted from minAOD
extractDeepMETs = nanoAOD_DeepMET_switch.nanoAOD_addDeepMET_switch and not nanoAOD_DeepMET_switch.nanoAOD_produceDeepMET_switch
runMetCorAndUncFromMiniAOD(process,
isData=isData,
extractDeepMETs=extractDeepMETs)
process.nanoSequenceCommon.insert(
process.nanoSequenceCommon.index(process.jetSequence),
cms.Sequence(process.fullPatMetSequence))
process.basicJetsForMetForT1METNano = process.basicJetsForMet.clone(
src=process.updatedJetsWithUserData.src,
skipEM=False,
type1JetPtThreshold=0.0,
calcMuonSubtrRawPtAsValueMap=cms.bool(True),
)
process.jetSequence.insert(
process.jetSequence.index(process.updatedJetsWithUserData),
cms.Sequence(process.basicJetsForMetForT1METNano))
process.updatedJetsWithUserData.userFloats.muonSubtrRawPt = cms.InputTag(
"basicJetsForMetForT1METNano:MuonSubtrRawPt")
process.corrT1METJetTable.src = process.finalJets.src
process.corrT1METJetTable.cut = "pt<15 && abs(eta)<9.9"
for table in process.jetTable, process.corrT1METJetTable:
table.variables.muonSubtrFactor = Var(
"1-userFloat('muonSubtrRawPt')/(pt()*jecFactor('Uncorrected'))",
float,
doc="1-(muon-subtracted raw pt)/(raw pt)",
precision=6)
process.metTables += process.corrT1METJetTable
# makePuppiesFromMiniAOD(process,True) # call this before in the global customizer otherwise it would reset photon IDs in VID
# runMetCorAndUncFromMiniAOD(process,isData=isData,metType="Puppi",postfix="Puppi",jetFlavor="AK4PFPuppi")
# process.puppiNoLep.useExistingWeights = False
# process.puppi.useExistingWeights = False
# process.nanoSequenceCommon.insert(process.nanoSequenceCommon.index(jetSequence),cms.Sequence(process.puppiMETSequence+process.fullPatMetSequencePuppi))
return process
if isData:
jecFile = cms.string('%s/src/Analysis/ALPHA/data/%s/%s_Uncertainty_AK4PFchs.txt' % (os.environ['CMSSW_BASE'], JECstring, JECstring))
else:
jecFile = cms.string('%s/src/Analysis/ALPHA/data/Summer16_23Sep2016V3_MC/Summer16_23Sep2016V3_MC_Uncertainty_AK4PFchs.txt' % os.environ['CMSSW_BASE'])
runMetCorAndUncFromMiniAOD(process,
#metType="PF",
#correctionLevel=["T1","Smear"],
#computeUncertainties=True,
#produceIntermediateCorrections=False,
#addToPatDefaultSequence=False,
isData=isData,
#onMiniAOD=True,
#reapplyJEC=reapplyJEC,
#reclusterJets=reclusterJets,
#jetSelection=jetSelection,
#recoMetFromPFCs=recoMetFromPFCs,
#autoJetCleaning=jetCleaning,
#manualJetConfig=manualJetConfig,
#jetFlavor=jetFlavor,
#jetCorLabelUpToL3=jetCorLabelL3,
#jetCorLabelL3Res=jetCorLabelRes,
#jecUnFile=jecFile,
#CHS=CHS,
#postfix=postfix,
)
if isData:
filterString = "RECO"
else:
filterString = "PAT"
from RecoEgamma.EgammaTools.EgammaPostRecoTools import setupEgammaPostRecoSeq
setupEgammaPostRecoSeq(process, era='2018-Prompt')
######################################################
################ MET Re-correct ##################
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
process.noHFCands = cms.EDFilter(
"CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string(
"abs(pdgId)!=1 && abs(pdgId)!=2 && !(eta> -3.14 && eta <1.4 && phi >-1.57 && phi < 0.87) "
))
runMetCorAndUncFromMiniAOD(
process,
isData=True, # false for MC
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True,
reclusterJets=True,
postfix="NoHF")
######################################################
################# MET FILTERS ####################
process.load('RecoMET.METFilters.ecalBadCalibFilter_cfi')
baddetEcallist = cms.vuint32([
872439604, 872422825, 872420274, 872423218, 872423215, 872416066,
872435036, 872439336, 872420273, 872436907, 872420147, 872439731,
872436657, 872420397, 872439732, 872439339, 872439603, 872422436,
872439861, 872437051, 872437052, 872420649, 872422436, 872421950,
872437185, 872422564, 872421566, 872421695, 872421955, 872421567,
872437184, 872421951, 872421694, 872437056, 872437057, 872437313
])
### Removing the HF from the MET computation as from 7 Aug 2015 recommendations
### ---------------------------------------------------------------------------
if options.useNoHFMET:
process.noHFCands = cms.EDFilter(
"CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0"))
#jets are rebuilt from those candidates by the tools, no need to do anything else
### =================================================================================
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#For a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(
process,
isData=("Data" in options.DataProcessing),
)
if options.useNoHFMET:
runMetCorAndUncFromMiniAOD(process,
isData=("Data" in options.DataProcessing),
pfCandColl=cms.InputTag("noHFCands"),
postfix="NoHF")
jLabelNoHF = 'patJetsNoHF'
### -------------------------------------------------------------------
### the lines below remove the L2L3 residual corrections when processing data
### -------------------------------------------------------------------
if ("Data" in options.DataProcessing and options.forceResiduals):
#Take new pat jets as input of the entuples
########################################
from PhysicsTools.PatAlgos.tools.jetTools import updateJetCollection
updateJetCollection(
process,
jetSource = cms.InputTag('slimmedJets'),
labelName = 'UpdatedJEC',
jetCorrections = ('AK4PFchs', cms.vstring(['L1FastJet', 'L2Relative', 'L3Absolute','L2L3Residual']), 'None') # Do not forget 'L2L3Residual' on data!
)
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(process,
isData=runOnData,
metType = 'PF',
postfix=''
)
process.load('Configuration.StandardSequences.Services_cff')
process.load("JetMETCorrections.Modules.JetResolutionESProducer_cfi")
from CondCore.DBCommon.CondDBSetup_cfi import *
import os
process.jer = cms.ESSource("PoolDBESSource",
CondDBSetup,
toGet = cms.VPSet(
# Resolution
cms.PSet(
record = cms.string('JetResolutionRcd'),
# MET correction
# https://twiki.cern.ch/twiki/bin/viewauth/CMS/MissingETUncertaintyPrescription
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
params = {
"isData" : options.isData,
"jecUncFile" : os.path.basename(options.jesUncFiles[0]),
"electronColl" : electronCollection.value(),
"muonColl" : muonCollection.value(),
"jetCollUnskimmed" : jetCollection.value(),
}
if options.campaign == "Run2_pp_13TeV_Legacy17":
params["fixEE2017"] = True
params["fixEE2017Params"] = {"userawPt": True, "ptThreshold": 50.0, "minEtaThreshold": 2.65, "maxEtaThreshold": 3.139}
runMetCorAndUncFromMiniAOD(process, **params)
seq += process.fullPatMetSequence
metCollection = cms.InputTag("slimmedMETs", "", process.name_())
# add DeepJet discriminators
from PhysicsTools.PatAlgos.tools.jetTools import updateJetCollection
if options.campaign != "Run2_pp_13TeV_Legacy18":
updateJetCollection(
process,
jetSource = jetCollection,
pvSource = cms.InputTag('offlineSlimmedPrimaryVertices'),
svSource = cms.InputTag('slimmedSecondaryVertices'),
# Safe to always add 'L2L3Residual' as MC contains dummy L2L3Residual corrections (always set to 1)
jetCorrections = ('AK4PFchs', cms.vstring(['L1FastJet', 'L2Relative', 'L3Absolute', 'L2L3Residual']), 'None'),
btagDiscriminators = [
)
process.jecSequence = cms.Sequence(process.patJetCorrFactorsUpdatedJEC *
process.updatedPatJetsUpdatedJEC)
### END JECs ==========================================================================================
### MET ===============================================================================================
# from : https://twiki.cern.ch/twiki/bin/view/CMS/MissingETUncertaintyPrescription#We_have_a_tool_to_help_you_to_ap
# PFMET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
# If you only want to re-correct and get the proper uncertainties
runMetCorAndUncFromMiniAOD(
process,
isData=runOnData,
#fixEE2017 = False,
#fixEE2017Params = {'userawPt': True, 'PtThreshold':50.0, 'MinEtaThreshold':2.65, 'MaxEtaThreshold': 3.139} ,
postfix="ModifiedMET")
# PuppiMET
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
makePuppiesFromMiniAOD(process, True)
# If you only want to re-correct and get the proper uncertainties
runMetCorAndUncFromMiniAOD(
process,
isData=runOnData,
metType="Puppi",
postfix="Puppi",
jetFlavor="AK4PFPuppi",
)
from PhysicsTools.PatAlgos.producersLayer1.jetUpdater_cff import updatedPatJets
process.patJetsReapplyJEC = updatedPatJets.clone(
jetSource=cms.InputTag("slimmedJets"),
jetCorrFactorsSource=cms.VInputTag(
cms.InputTag("patJetCorrFactorsReapplyJEC")))
#PFMET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
# If you only want to re-correct and get the proper uncertainties
runMetCorAndUncFromMiniAOD(process,
isData=runOnData,
fixEE2017=True,
fixEE2017Params={
'userawPt': True,
'PtThreshold': 50.0,
'MinEtaThreshold': 2.65,
'MaxEtaThreshold': 3.139
},
postfix="ModifiedMET")
#PuppiMET
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
makePuppiesFromMiniAOD(process, True)
# If you only want to re-cluster and get the proper uncertainties
runMetCorAndUncFromMiniAOD(process,
isData=runOnData,
metType="Puppi",
pfCandColl=cms.InputTag("puppiForMET"),
recoMetFromPFCs=True,
)
process.path *= (process.packedPFCandidatesCHSNotFromPV)
process.packedPFCandidatesCHS = cms.EDFilter(
'CandPtrSelector',
src=cms.InputTag('packedPFCandidates'),
cut=cms.string('fromPV() > 0') # only loose selection (0)
)
process.path *= (process.packedPFCandidatesCHS)
# -- start of MET recipe
# the following lines are for default MET for Type1 corrections
# If you only want to re-correct for JEC and get the proper uncertainties for the default MET
runMetCorAndUncFromMiniAOD(process,
isData=options.isData,
pfCandColl='packedPFCandidatesCHS',
recoMetFromPFCs=True)
## If you would like to re-cluster both jets and met and get the proper uncertainties
#runMetCorAndUncFromMiniAOD(process,
# isData=options.isData,
# pfCandColl=cms.InputTag("packedPFCandidates"),
# recoMetFromPFCs=True,
# CHS = True, # this is an important step and determines what type of jets to be reclustered
# reclusterJets = True
# )
# wire CHS MET to new collection from the "KAPPA" process
process.kappaTuple.PatMET.metCHS = cms.PSet(src=cms.InputTag("slimmedMETs"),
uncorrected=cms.bool(True))
if not options.isData:
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
# create collection of PF candidates likely coming from the primary vertex
process.packedPFCandidatesCHS = cms.EDFilter('CandPtrSelector',
src = cms.InputTag('packedPFCandidates'),
cut = cms.string('fromPV() > 0') # only loose selection (0)
)
process.path *= (process.packedPFCandidatesCHS)
# -- start of MET recipe
# the following lines are for default MET for Type1 corrections
# If you only want to re-correct for JEC and get the proper uncertainties for the default MET
runMetCorAndUncFromMiniAOD(process,
isData=options.isData,
pfCandColl='packedPFCandidatesCHS', # TODO: use 'packedPFCandidatesCHS'?
recoMetFromPFCs=True)
## If you would like to re-cluster both jets and met and get the proper uncertainties
#runMetCorAndUncFromMiniAOD(process,
# isData=options.isData,
# pfCandColl=cms.InputTag("packedPFCandidates"),
# recoMetFromPFCs=True,
# CHS = True, # this is an important step and determines what type of jets to be reclustered
# reclusterJets = True
# )
# -- apply E/Gamma gain switch fix
if options.isData:
def getBaseConfig(
nickname,
testfile=False, # false if not given, string otherwise
maxevents=-1,
outputfilename='kappaTuple.root'):
from Kappa.Skimming.KSkimming_template_cfg import process
## ------------------------------------------------------------------------
# count number of events before doing anything else
process.p *= process.nEventsTotal
process.p *= process.nNegEventsTotal
muons = "slimmedMuons"
electrons = "slimmedElectrons"
# new tau id only available for 8_0_20 (I believe) and above
if tools.is_above_cmssw_version([8, 0, 20]):
taus = "NewTauIDsEmbedded"
else:
taus = "slimmedTaus"
isSignal = datasetsHelper.isSignal(nickname)
# produce selected collections and filter events with not even one Lepton
if options.preselect and not isSignal:
from Kappa.Skimming.KSkimming_preselection import do_preselection
do_preselection(process)
process.p *= process.goodEventFilter
process.selectedKappaTaus.cut = cms.string('pt > 15 && abs(eta) < 2.5')
process.selectedKappaMuons.cut = cms.string('pt > 8 && abs(eta) < 2.6')
process.selectedKappaElectrons.cut = cms.string(
'pt > 8 && abs(eta) < 2.7')
muons = "selectedKappaMuons"
electrons = "selectedKappaElectrons"
taus = "selectedKappaTaus"
process.goodEventFilter.minNumber = cms.uint32(2)
## ------------------------------------------------------------------------
# possibility to write out edmDump. Be careful when using unsceduled mode
process.load("Kappa.Skimming.edmOut")
process.ep = cms.EndPath()
#process.ep *= process.edmOut
## ------------------------------------------------------------------------
# Configure Kappa
if testfile:
process.source.fileNames = cms.untracked.vstring("%s" % testfile)
else:
process.source = cms.Source('PoolSource',
fileNames=cms.untracked.vstring())
process.maxEvents.input = maxevents
process.kappaTuple.verbose = cms.int32(0)
# uncomment the following option to select only running on certain luminosity blocks. Use only for debugging
# process.source.lumisToProcess = cms.untracked.VLuminosityBlockRange("1:500-1:1000")
# process.source.eventsToProcess = cms.untracked.VEventRange("299368:56418140-299368:56418140")
process.kappaTuple.profile = cms.bool(True)
globaltag = datasetsHelper.getGlobalTag(nickname)
print "Global Tag:", globaltag
process.GlobalTag.globaltag = globaltag
## ------------------------------------------------------------------------
# Configure Metadata describing the file
# Important to be evaluated correctly for the following steps
# data, isEmbedded, miniaod, process.kappaTuple.TreeInfo.parameters = datasetsHelper.getTreeInfo(nickname, globaltag, kappaTag)
process.kappaTuple.active = cms.vstring('TreeInfo')
data = datasetsHelper.isData(nickname)
isEmbedded = datasetsHelper.isEmbedded(nickname)
print "nickname:", nickname
#####miniaod = datasetsHelper.isMiniaod(nickname) not used anymore, since everything is MiniAOD now
process.kappaTuple.TreeInfo.parameters = datasetsHelper.getTreeInfo(
nickname)
## ------------------------------------------------------------------------
# General configuration
if tools.is_above_cmssw_version([7, 4]) and not data and not isEmbedded:
process.kappaTuple.Info.pileUpInfoSource = cms.InputTag(
"slimmedAddPileupInfo", "", "PAT")
if not tools.is_above_cmssw_version([9]):
if isSignal:
process.kappaTuple.Info.lheSource = cms.InputTag("source")
# save primary vertex
process.kappaTuple.active += cms.vstring(
'VertexSummary') # save VertexSummary
process.kappaTuple.VertexSummary.whitelist = cms.vstring(
'offlineSlimmedPrimaryVertices') # save VertexSummary
process.kappaTuple.VertexSummary.rename = cms.vstring(
'offlineSlimmedPrimaryVertices => goodOfflinePrimaryVerticesSummary')
if tools.is_above_cmssw_version([7, 6]):
process.kappaTuple.VertexSummary.goodOfflinePrimaryVerticesSummary = cms.PSet(
src=cms.InputTag("offlineSlimmedPrimaryVertices"))
process.kappaTuple.active += cms.vstring('TriggerObjectStandalone')
# setup BadPFMuonFilter and BadChargedCandidateFilter
if tools.is_above_cmssw_version(
[8]) and not tools.is_above_cmssw_version([9]):
process.load('RecoMET.METFilters.BadPFMuonFilter_cfi')
process.BadPFMuonFilter.muons = cms.InputTag("slimmedMuons")
process.BadPFMuonFilter.PFCandidates = cms.InputTag(
"packedPFCandidates")
process.BadPFMuonFilter.taggingMode = cms.bool(True)
process.load('RecoMET.METFilters.BadChargedCandidateFilter_cfi')
process.BadChargedCandidateFilter.muons = cms.InputTag("slimmedMuons")
process.BadChargedCandidateFilter.PFCandidates = cms.InputTag(
"packedPFCandidates")
process.BadChargedCandidateFilter.taggingMode = cms.bool(True)
# in reMiniAOD data these filters are already present; only need to run the dedicated module for MC and older data
if not "03Feb2017" in str(
process.kappaTuple.TreeInfo.parameters.scenario):
process.load('RecoMET.METFilters.badGlobalMuonTaggersMiniAOD_cff')
#switch on tagging mode:
process.badGlobalMuonTaggerMAOD.taggingMode = cms.bool(True)
process.cloneGlobalMuonTaggerMAOD.taggingMode = cms.bool(True)
process.kappaTuple.TriggerObjectStandalone.metfilterbitslist = cms.vstring(
"BadChargedCandidateFilter", "BadPFMuonFilter",
"badGlobalMuonTaggerMAOD", "cloneGlobalMuonTaggerMAOD")
else:
process.kappaTuple.TriggerObjectStandalone.metfilterbitslist = cms.vstring(
"BadChargedCandidateFilter", "BadPFMuonFilter")
process.kappaTuple.Info.hltSource = cms.InputTag("TriggerResults", "",
"HLT")
if isEmbedded:
process.kappaTuple.TriggerObjectStandalone.bits = cms.InputTag(
"TriggerResults", "", "SIMembedding")
process.kappaTuple.TriggerObjectStandalone.metfilterbits = cms.InputTag(
"TriggerResults", "", "MERGE")
process.kappaTuple.Info.hltSource = cms.InputTag(
"TriggerResults", "", "SIMembedding")
elif data:
if tools.is_above_cmssw_version([9]):
process.kappaTuple.Info.hltSource = cms.InputTag(
"TriggerResults", "", "HLT")
process.kappaTuple.TriggerObjectStandalone.metfilterbits = cms.InputTag(
"TriggerResults", "",
"RECO") # take last process used in production for data
elif "03Feb2017" in str(
process.kappaTuple.TreeInfo.parameters.scenario):
process.kappaTuple.TriggerObjectStandalone.metfilterbits = cms.InputTag(
"TriggerResults", "", "PAT")
else:
process.kappaTuple.TriggerObjectStandalone.metfilterbits = cms.InputTag(
"TriggerResults", "", "RECO")
process.kappaTuple.Info.hltSource = cms.InputTag(
"TriggerResults", "", "RECO")
else:
process.kappaTuple.TriggerObjectStandalone.metfilterbits = cms.InputTag(
"TriggerResults", "",
"PAT") # take last process used in production for mc
if not isEmbedded and "Spring16" in str(
process.kappaTuple.TreeInfo.parameters.campaign):
# adds for each HLT Trigger wich contains "Tau" or "tau" in the name a Filter object named "l1extratauccolltection"
process.kappaTuple.TriggerObjectStandalone.l1extratauJetSource = cms.untracked.InputTag(
"l1extraParticles", "IsoTau", "RECO")
if not tools.is_above_cmssw_version([9]):
process.kappaTuple.TriggerObjectStandalone.triggerObjects = cms.PSet(
src=cms.InputTag("selectedPatTrigger"))
process.kappaTuple.TriggerObjectStandalone.bits = cms.InputTag(
"TriggerResults", "", "HLT")
process.kappaTuple.active += cms.vstring('BeamSpot')
if tools.is_above_cmssw_version([7, 6]):
process.kappaTuple.BeamSpot.offlineBeamSpot = cms.PSet(
src=cms.InputTag("offlineBeamSpot"))
if not isEmbedded and data:
process.kappaTuple.active += cms.vstring(
'DataInfo') # produce Metadata for data,
if not isEmbedded and not data:
process.kappaTuple.active += cms.vstring(
'GenInfo') # produce Metadata for MC,
process.kappaTuple.active += cms.vstring(
'GenParticles') # save GenParticles,
process.kappaTuple.active += cms.vstring(
'GenTaus') # save GenParticles,
process.kappaTuple.GenParticles.genParticles.src = cms.InputTag(
"prunedGenParticles")
process.kappaTuple.GenTaus.genTaus.src = cms.InputTag(
"prunedGenParticles")
# write out for all processes where available
process.kappaTuple.Info.lheWeightNames = cms.vstring(".*")
# save Flag
process.kappaTuple.Info.isEmbedded = cms.bool(isEmbedded)
if isEmbedded:
#process.load('RecoBTag/Configuration/RecoBTag_cff')
#process.load('RecoJets/JetAssociationProducers/ak5JTA_cff')
#process.ak5PFJetNewTracksAssociatorAtVertex.tracks = "tmfTracks"
#process.ak5PFCHSNewJetTracksAssociatorAtVertex.tracks = "tmfTracks"
#process.p *= process.btagging
# disable overrideHLTCheck for embedded samples, since it triggers an Kappa error
process.kappaTuple.Info.overrideHLTCheck = cms.untracked.bool(True)
process.kappaTuple.active += cms.vstring('GenInfo')
process.kappaTuple.active += cms.vstring(
'GenParticles') # save GenParticles,
process.kappaTuple.GenParticles.genParticles.src = cms.InputTag(
"prunedGenParticles")
process.kappaTuple.active += cms.vstring('GenTaus')
process.kappaTuple.GenTaus.genTaus.src = cms.InputTag(
"prunedGenParticles")
#process.kappaTuple.active += cms.vstring('GenTaus') # save GenParticles,
#process.kappaTuple.GenParticles.genParticles.src = cms.InputTag("genParticles","","EmbeddedRECO")
## ------------------------------------------------------------------------
# Trigger
from Kappa.Skimming.hlt_run2 import hltBlacklist, hltWhitelist
process.kappaTuple.Info.hltWhitelist = hltWhitelist
process.kappaTuple.Info.hltBlacklist = hltBlacklist
## ------------------------------------------------------------------------
# should not be the default, it blows up the skim a lot
#process.kappaTuple.active += cms.vstring('packedPFCandidates')
#process.kappaTuple.packedPFCandidates.packedPFCandidates = cms.PSet(src = cms.InputTag("packedPFCandidates"))
jetCollectionPuppi = "slimmedJetsPuppi"
if tools.is_above_cmssw_version([9]):
jetCollection = "slimmedJets"
elif tools.is_above_cmssw_version([8]):
from RecoMET.METPUSubtraction.jet_recorrections import recorrectJets
#from RecoMET.METPUSubtraction.jet_recorrections import loadLocalSqlite
#loadLocalSqlite(process, sqliteFilename = "Spring16_25nsV6_DATA.db" if data else "Spring16_25nsV6_MC.db",
# tag = 'JetCorrectorParametersCollection_Spring16_25nsV6_DATA_AK4PF' if data else 'JetCorrectorParametersCollection_Spring16_25nsV6_MC_AK4PF')
recorrectJets(process, isData=data)
jetCollection = "patJetsReapplyJEC"
else:
from RecoMET.METPUSubtraction.localSqlite import recorrectJets
recorrectJets(process, isData=data)
jetCollection = "patJetsReapplyJEC"
## ------------------------------------------------------------------------
# Configure Muons
process.load("Kappa.Skimming.KMuons_miniAOD_cff")
process.kappaTuple.Muons.muons.src = cms.InputTag(muons)
process.kappaTuple.Muons.muons.vertexcollection = cms.InputTag(
"offlineSlimmedPrimaryVertices")
process.kappaTuple.Muons.use03ConeForPfIso = cms.bool(True)
process.kappaTuple.Muons.doPfIsolation = cms.bool(False)
for src in [
"muPFIsoDepositCharged", "muPFIsoDepositChargedAll",
"muPFIsoDepositNeutral", "muPFIsoDepositGamma", "muPFIsoDepositPU"
]:
setattr(getattr(process, src), "src", cms.InputTag(muons))
process.kappaTuple.active += cms.vstring('Muons')
process.kappaTuple.Muons.noPropagation = cms.bool(True)
process.p *= (process.makeKappaMuons)
## ------------------------------------------------------------------------
# Configure Electrons
process.kappaTuple.active += cms.vstring('Electrons')
process.load("Kappa.Skimming.KElectrons_miniAOD_cff")
process.kappaTuple.Electrons.electrons.src = cms.InputTag(
"slimmedElectrons")
process.kappaTuple.Electrons.electrons.vertexcollection = cms.InputTag(
"offlineSlimmedPrimaryVertices")
process.kappaTuple.Electrons.electrons.rhoIsoInputTag = cms.InputTag(
"slimmedJets", "rho")
process.kappaTuple.Electrons.electrons.allConversions = cms.InputTag(
"reducedEgamma", "reducedConversions")
from Kappa.Skimming.KElectrons_miniAOD_cff import setupElectrons
process.kappaTuple.Electrons.srcIds = cms.string("standalone")
if tools.is_above_cmssw_version([9, 4]):
process.kappaTuple.Electrons.ids = cms.VInputTag(
"egmGsfElectronIDs:cutBasedElectronID-Fall17-94X-V1-veto",
"egmGsfElectronIDs:cutBasedElectronID-Fall17-94X-V1-loose",
"egmGsfElectronIDs:cutBasedElectronID-Fall17-94X-V1-medium",
"egmGsfElectronIDs:cutBasedElectronID-Fall17-94X-V1-tight",
"egmGsfElectronIDs:mvaEleID-Fall17-noIso-V1-wp90",
"egmGsfElectronIDs:mvaEleID-Fall17-noIso-V1-wp80",
"egmGsfElectronIDs:mvaEleID-Fall17-noIso-V1-wpLoose",
"egmGsfElectronIDs:mvaEleID-Fall17-iso-V1-wp90",
"egmGsfElectronIDs:mvaEleID-Fall17-iso-V1-wp80",
"egmGsfElectronIDs:mvaEleID-Fall17-iso-V1-wpLoose",
"electronMVAValueMapProducer:ElectronMVAEstimatorRun2Fall17NoIsoV1Values",
"electronMVAValueMapProducer:ElectronMVAEstimatorRun2Fall17IsoV1Values",
"egmGsfElectronIDs:cutBasedElectronID-Summer16-80X-V1-veto",
"egmGsfElectronIDs:cutBasedElectronID-Summer16-80X-V1-loose",
"egmGsfElectronIDs:cutBasedElectronID-Summer16-80X-V1-medium",
"egmGsfElectronIDs:cutBasedElectronID-Summer16-80X-V1-tight",
"electronMVAValueMapProducer:ElectronMVAEstimatorRun2Spring16GeneralPurposeV1Values"
)
elif tools.is_above_cmssw_version([8]):
process.kappaTuple.Electrons.ids = cms.VInputTag(
"egmGsfElectronIDs:cutBasedElectronID-Summer16-80X-V1-veto",
"egmGsfElectronIDs:cutBasedElectronID-Summer16-80X-V1-loose",
"egmGsfElectronIDs:cutBasedElectronID-Summer16-80X-V1-medium",
"egmGsfElectronIDs:cutBasedElectronID-Summer16-80X-V1-tight",
"electronMVAValueMapProducer:ElectronMVAEstimatorRun2Spring16GeneralPurposeV1Values"
)
else:
process.kappaTuple.Electrons.ids = cms.VInputTag(
"egmGsfElectronIDs:cutBasedElectronID-Spring15-25ns-V1-standalone-veto",
"egmGsfElectronIDs:cutBasedElectronID-Spring15-25ns-V1-standalone-loose",
"egmGsfElectronIDs:cutBasedElectronID-Spring15-25ns-V1-standalone-medium",
"egmGsfElectronIDs:cutBasedElectronID-Spring15-25ns-V1-standalone-tight",
"electronMVAValueMapProducer:ElectronMVAEstimatorRun2Spring15NonTrig25nsV1Values"
)
setupElectrons(process, electrons)
process.p *= (process.makeKappaElectrons)
## ------------------------------------------------------------------------
# new tau id only available for 8_0_20 (I believe) and above
if tools.is_above_cmssw_version([8, 0, 20]):
process.load(
'RecoTauTag.Configuration.loadRecoTauTagMVAsFromPrepDB_cfi')
process.load("Kappa.Skimming.KPatTaus_run2_cff")
process.p *= (process.makeKappaTaus)
# embed new id's into new tau collection
embedID = cms.EDProducer(
"PATTauIDEmbedder",
src=cms.InputTag('slimmedTaus'),
tauIDSources=cms.PSet(
rerunDiscriminationByIsolationMVAOldDMrun2v1raw=cms.InputTag(
'rerunDiscriminationByIsolationMVAOldDMrun2v1raw'),
rerunDiscriminationByIsolationMVAOldDMrun2v1VLoose=cms.
InputTag('rerunDiscriminationByIsolationMVAOldDMrun2v1VLoose'),
rerunDiscriminationByIsolationMVAOldDMrun2v1Loose=cms.InputTag(
'rerunDiscriminationByIsolationMVAOldDMrun2v1Loose'),
rerunDiscriminationByIsolationMVAOldDMrun2v1Medium=cms.
InputTag('rerunDiscriminationByIsolationMVAOldDMrun2v1Medium'),
rerunDiscriminationByIsolationMVAOldDMrun2v1Tight=cms.InputTag(
'rerunDiscriminationByIsolationMVAOldDMrun2v1Tight'),
rerunDiscriminationByIsolationMVAOldDMrun2v1VTight=cms.
InputTag('rerunDiscriminationByIsolationMVAOldDMrun2v1VTight'),
rerunDiscriminationByIsolationMVAOldDMrun2v1VVTight=cms.
InputTag(
'rerunDiscriminationByIsolationMVAOldDMrun2v1VVTight'),
rerunDiscriminationByIsolationMVANewDMrun2v1raw=cms.InputTag(
'rerunDiscriminationByIsolationMVANewDMrun2v1raw'),
rerunDiscriminationByIsolationMVANewDMrun2v1VLoose=cms.
InputTag('rerunDiscriminationByIsolationMVANewDMrun2v1VLoose'),
rerunDiscriminationByIsolationMVANewDMrun2v1Loose=cms.InputTag(
'rerunDiscriminationByIsolationMVANewDMrun2v1Loose'),
rerunDiscriminationByIsolationMVANewDMrun2v1Medium=cms.
InputTag('rerunDiscriminationByIsolationMVANewDMrun2v1Medium'),
rerunDiscriminationByIsolationMVANewDMrun2v1Tight=cms.InputTag(
'rerunDiscriminationByIsolationMVANewDMrun2v1Tight'),
rerunDiscriminationByIsolationMVANewDMrun2v1VTight=cms.
InputTag('rerunDiscriminationByIsolationMVANewDMrun2v1VTight'),
rerunDiscriminationByIsolationMVANewDMrun2v1VVTight=cms.
InputTag(
'rerunDiscriminationByIsolationMVANewDMrun2v1VVTight')),
)
setattr(process, taus, embedID)
process.p *= getattr(process, taus)
process.kappaTuple.active += cms.vstring('PatTaus')
process.kappaTuple.PatTaus.taus.binaryDiscrBlacklist = cms.vstring()
process.kappaTuple.PatTaus.taus.src = cms.InputTag(taus)
process.kappaTuple.PatTaus.taus.floatDiscrBlacklist = cms.vstring()
# just took everything from https://twiki.cern.ch/twiki/bin/viewauth/CMS/TauIDRecommendation13TeV
process.kappaTuple.PatTaus.taus.preselectOnDiscriminators = cms.vstring()
process.kappaTuple.PatTaus.taus.binaryDiscrWhitelist = cms.vstring(
"decayModeFinding",
"decayModeFindingNewDMs",
"byLooseCombinedIsolationDeltaBetaCorr3Hits",
"byMediumCombinedIsolationDeltaBetaCorr3Hits",
"byTightCombinedIsolationDeltaBetaCorr3Hits",
"byCombinedIsolationDeltaBetaCorrRaw3Hits",
"chargedIsoPtSum",
"neutralIsoPtSum",
"neutralIsoPtSumWeight",
"puCorrPtSum",
"footprintCorrection",
"photonPtSumOutsideSignalCone",
"byIsolationMVArun2v1DBoldDMwLTraw",
"byVLooseIsolationMVArun2v1DBoldDMwLT",
"byLooseIsolationMVArun2v1DBoldDMwLT",
"byMediumIsolationMVArun2v1DBoldDMwLT",
"byTightIsolationMVArun2v1DBoldDMwLT",
"byVTightIsolationMVArun2v1DBoldDMwLT",
"byVVTightIsolationMVArun2v1DBoldDMwLT",
#"byIsolationMVArun2v1DBnewDMwLTraw",
#"byVLooseIsolationMVArun2v1DBnewDMwLT",
#"byLooseIsolationMVArun2v1DBnewDMwLT",
#"byMediumIsolationMVArun2v1DBnewDMwLT",
#"byTightIsolationMVArun2v1DBnewDMwLT",
#"byVTightIsolationMVArun2v1DBnewDMwLT",
#"byVVTightIsolationMVArun2v1DBnewDMwLT",
"againstMuonLoose3",
"againstMuonTight3",
"againstElectronMVA6category",
"againstElectronMVA6raw",
"againstElectronVLooseMVA6",
"againstElectronLooseMVA6",
"againstElectronMediumMVA6",
"againstElectronTightMVA6",
"againstElectronVTightMVA6" #,
#"chargedIsoPtSumdR03",
#"neutralIsoPtSumdR03",
#"neutralIsoPtSumWeightdR03",
#"footprintCorrectiondR03",
#"photonPtSumOutsideSignalConedR03",
#"byLooseCombinedIsolationDeltaBetaCorr3HitsdR03",
#"byMediumCombinedIsolationDeltaBetaCorr3HitsdR03",
#"byTightCombinedIsolationDeltaBetaCorr3HitsdR03",
#"byIsolationMVArun2v1DBdR03oldDMwLTraw",
#"byVLooseIsolationMVArun2v1DBdR03oldDMwLT",
#"byLooseIsolationMVArun2v1DBdR03oldDMwLT",
#"byMediumIsolationMVArun2v1DBdR03oldDMwLT",
#"byTightIsolationMVArun2v1DBdR03oldDMwLT",
#"byVTightIsolationMVArun2v1DBdR03oldDMwLT",
#"byVVTightIsolationMVArun2v1DBdR03oldDMwLT",
)
if tools.is_above_cmssw_version([8, 0, 20]):
process.kappaTuple.PatTaus.taus.binaryDiscrWhitelist += cms.vstring(
"rerunDiscriminationByIsolationMVAOldDMrun2v1raw",
"rerunDiscriminationByIsolationMVAOldDMrun2v1VLoose",
"rerunDiscriminationByIsolationMVAOldDMrun2v1Loose",
"rerunDiscriminationByIsolationMVAOldDMrun2v1Medium",
"rerunDiscriminationByIsolationMVAOldDMrun2v1Tight",
"rerunDiscriminationByIsolationMVAOldDMrun2v1VTight",
"rerunDiscriminationByIsolationMVAOldDMrun2v1VVTight",
"rerunDiscriminationByIsolationMVANewDMrun2v1raw",
"rerunDiscriminationByIsolationMVANewDMrun2v1VLoose",
"rerunDiscriminationByIsolationMVANewDMrun2v1Loose",
"rerunDiscriminationByIsolationMVANewDMrun2v1Medium",
"rerunDiscriminationByIsolationMVANewDMrun2v1Tight",
"rerunDiscriminationByIsolationMVANewDMrun2v1VTight",
"rerunDiscriminationByIsolationMVANewDMrun2v1VVTight")
## now also possible to save all MVA isolation inputs for taus # turn of per default
process.kappaTuple.PatTaus.taus.extrafloatDiscrlist = cms.untracked.vstring(
"decayDistX", "decayDistY", "decayDistZ", "decayDistM", "nPhoton",
"ptWeightedDetaStrip", "ptWeightedDphiStrip", "ptWeightedDrSignal",
"ptWeightedDrIsolation", "leadingTrackChi2", "eRatio")
process.kappaTuple.PatTaus.taus.floatDiscrWhitelist = process.kappaTuple.PatTaus.taus.binaryDiscrWhitelist
process.kappaTuple.PatTaus.verbose = cms.int32(1)
## ------------------------------------------------------------------------
## Configure Jets
process.kappaTuple.active += cms.vstring('PileupDensity')
process.kappaTuple.PileupDensity.whitelist = cms.vstring(
"fixedGridRhoFastjetAll")
process.kappaTuple.PileupDensity.rename = cms.vstring(
"fixedGridRhoFastjetAll => pileupDensity")
if tools.is_above_cmssw_version([7, 6]):
process.kappaTuple.PileupDensity.pileupDensity = cms.PSet(
src=cms.InputTag("fixedGridRhoFastjetAll"))
process.kappaTuple.active += cms.vstring('PatJets')
if tools.is_above_cmssw_version([7, 6]):
process.kappaTuple.PatJets.ak4PF = cms.PSet(
src=cms.InputTag(jetCollection))
process.kappaTuple.PatJets.puppiJets = cms.PSet(
src=cms.InputTag(jetCollectionPuppi))
## Standard MET and GenMet from pat::MET
process.kappaTuple.active += cms.vstring('PatMET')
process.kappaTuple.PatMET.met = cms.PSet(src=cms.InputTag("slimmedMETs"))
if tools.is_above_cmssw_version([9]):
pass
elif tools.is_above_cmssw_version([8, 0, 14]):
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(process, isData=data)
process.kappaTuple.PatMET.met = cms.PSet(
src=cms.InputTag("slimmedMETs", "", "KAPPA"))
#process.kappaTuple.PatMET.pfmetT1 = cms.PSet(src=cms.InputTag("patpfMETT1"))
process.kappaTuple.PatMET.metPuppi = cms.PSet(
src=cms.InputTag("slimmedMETsPuppi"))
if not tools.is_above_cmssw_version([9]):
## Write MVA MET to KMETs
process.kappaTuple.active += cms.vstring('PatMETs')
# new MVA MET
from RecoMET.METPUSubtraction.MVAMETConfiguration_cff import runMVAMET
runMVAMET(process, jetCollectionPF=jetCollection)
process.kappaTuple.PatMETs.MVAMET = cms.PSet(
src=cms.InputTag("MVAMET", "MVAMET"))
process.MVAMET.srcLeptons = cms.VInputTag(
muons, electrons, taus) # to produce all possible combinations
process.MVAMET.requireOS = cms.bool(False)
if tools.is_above_cmssw_version([8, 0]) and isEmbedded:
process.MVAMET.srcMETs = cms.VInputTag(
cms.InputTag("slimmedMETs", "", "MERGE"),
cms.InputTag("patpfTrackMET"), cms.InputTag("patpfNoPUMET"),
cms.InputTag("patpfPUCorrectedMET"),
cms.InputTag("patpfPUMET"),
cms.InputTag("slimmedMETsPuppi", "", "MERGE"))
## ------------------------------------------------------------------------
## GenJets
if not data or isEmbedded:
process.load('PhysicsTools/JetMCAlgos/TauGenJets_cfi')
process.load(
'PhysicsTools/JetMCAlgos/TauGenJetsDecayModeSelectorAllHadrons_cfi'
)
process.tauGenJets.GenParticles = cms.InputTag("prunedGenParticles")
process.p *= (process.tauGenJets +
process.tauGenJetsSelectorAllHadrons)
if isSignal:
process.kappaTuple.GenJets.whitelist = cms.vstring(
"tauGenJets", "slimmedGenJets")
else:
process.kappaTuple.GenJets.whitelist = cms.vstring("tauGenJets")
process.kappaTuple.active += cms.vstring('GenJets')
if tools.is_above_cmssw_version([7, 6]):
if isSignal:
process.kappaTuple.GenJets.genJets = cms.PSet(
src=cms.InputTag("slimmedGenJets"))
process.kappaTuple.GenJets.tauGenJets = cms.PSet(
src=cms.InputTag("tauGenJets"))
process.kappaTuple.GenJets.tauGenJetsSelectorAllHadrons = cms.PSet(
src=cms.InputTag("tauGenJetsSelectorAllHadrons"))
# add repository revisions to TreeInfo
for repo, rev in tools.get_repository_revisions().iteritems():
setattr(process.kappaTuple.TreeInfo.parameters, repo, cms.string(rev))
## ------------------------------------------------------------------------
## Count Events after running all filters
if not data:
process.nEventsTotal.isMC = cms.bool(True)
process.nNegEventsTotal.isMC = cms.bool(True)
process.nEventsFiltered.isMC = cms.bool(True)
process.nNegEventsFiltered.isMC = cms.bool(True)
process.p *= process.nEventsFiltered
process.p *= process.nNegEventsFiltered
process.kappaTuple.active += cms.vstring('FilterSummary')
## ------------------------------------------------------------------------
## if needed adapt output filename
process.ep *= process.kappaOut
if outputfilename != '':
process.kappaTuple.outputFile = cms.string('%s' % outputfilename)
## ------------------------------------------------------------------------
## Further information saved to Kappa output
if options.dumpPython:
f = open("dumpPython.py", "w")
f.write(process.dumpPython())
f.close()
# add python config to TreeInfo
process.kappaTuple.TreeInfo.parameters.config = cms.string(
process.dumpPython())
return process
fillpfjetInfo_=cms.untracked.bool(True),
pfjetLabel_=cms.untracked.InputTag("selectedUpdatedPatJetsUpdatedJEC"),
filltauInfo_=cms.untracked.bool(False),
tauLabel_=cms.untracked.InputTag("slimmedTaus"),
)
process.TFileService = cms.Service("TFileService",
fileName=cms.string("histo.root"),
closeFileFast=cms.untracked.bool(True))
from RecoEgamma.EgammaTools.EgammaPostRecoTools import setupEgammaPostRecoSeq
setupEgammaPostRecoSeq(process, runVID=False, era='2018-Prompt')
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=False,
)
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
makePuppiesFromMiniAOD(process, True)
runMetCorAndUncFromMiniAOD(
process,
isData=False,
metType="Puppi",
postfix="Puppi",
jetFlavor="AK4PFPuppi",
)
process.puppi.useExistingWeights = True
#All paths are here
process.p = cms.Path(
jetCorrections=('AK4PFchs', [
'L1FastJet', 'L2Relative', 'L3Absolute', 'L2L3Residual'
], ''),
genParticles=cms.InputTag('prunedGenParticles'),
pvSource=cms.InputTag('offlineSlimmedPrimaryVertices'))
process.patJets.addGenJetMatch = cms.bool(False)
process.patJets.addGenPartonMatch = cms.bool(False)
process.patJets.addPartonJetMatch = cms.bool(False)
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#default configuration for miniAOD reprocessing, change the isData flag to run on data
#for a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(
process,
isData=not (config["RUNONMC"]),
)
process.patPFMetT1T2Corr.type1JetPtThreshold = cms.double(15.0)
process.patPFMetT2Corr.type1JetPtThreshold = cms.double(15.0)
process.slimmedMETs.t01Variation = cms.InputTag("slimmedMETs", "", "RECO")
if config["RUNONMC"]:
process.patPFMetT1T2Corr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT1T2SmearCorr.jetCorrLabelRes = cms.InputTag(
"L3Absolute")
process.patPFMetT2Corr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT2SmearCorr.jetCorrLabelRes = cms.InputTag(
"L3Absolute")
process.shiftedPatJetEnDown.jetCorrLabelUpToL3Res = cms.InputTag(
"ak4PFCHSL1FastL2L3Corrector")
process.shiftedPatJetEnUp.jetCorrLabelUpToL3Res = cms.InputTag(
def reproduceMET(process,isdata):
from CondCore.DBCommon.CondDBSetup_cfi import *
import os
if isdata:
era="Spring16_25nsV6_DATA"
else:
era="Spring16_25nsV6_MC"
jerera="Spring16_25nsV6"
##___________________________External JEC file________________________________||
process.jec = cms.ESSource("PoolDBESSource",CondDBSetup,
# connect = cms.string("sqlite:PhysicsTools/PatUtils/data/"+era+".db"),
connect = cms.string("sqlite:"+era+"_JEC.db"),
toGet = cms.VPSet(
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+era+"_AK4PF"),
label= cms.untracked.string("AK4PF")
),
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+era+"_AK4PFchs"),
label= cms.untracked.string("AK4PFchs")
),
cms.PSet(record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+era+"_AK4PFPuppi"),
label = cms.untracked.string("AK4PFPuppi")
),
)
)
process.es_prefer_jec = cms.ESPrefer("PoolDBESSource",'jec')
##___________________________External JER file________________________________||
process.jer = cms.ESSource("PoolDBESSource",CondDBSetup,
# connect = cms.string("sqlite:PhysicsTools/PatUtils/data/JER/"+jerera+"_MC.db"),
connect = cms.string("sqlite:"+jerera+"_MC_JER.db"),
toGet = cms.VPSet(
#######
### read the PFchs
cms.PSet(
record = cms.string('JetResolutionRcd'),
tag = cms.string('JR_'+jerera+'_MC_PtResolution_AK4PFchs'),
label = cms.untracked.string('AK4PFchs_pt')
),
cms.PSet(
record = cms.string("JetResolutionRcd"),
tag = cms.string('JR_'+jerera+'_MC_PhiResolution_AK4PFchs'),
label = cms.untracked.string("AK4PFchs_phi")
),
cms.PSet(
record = cms.string('JetResolutionScaleFactorRcd'),
tag = cms.string('JR_'+jerera+'_MC_SF_AK4PFchs'),
label = cms.untracked.string('AK4PFchs')
),
#######
### read the Puppi JER
cms.PSet(
record = cms.string('JetResolutionRcd'),
tag = cms.string('JR_'+jerera+'_MC_PtResolution_AK4PFPuppi'),
label = cms.untracked.string('AK4PFPuppi_pt')
),
cms.PSet(
record = cms.string("JetResolutionRcd"),
tag = cms.string('JR_'+jerera+'_MC_PhiResolution_AK4PFPuppi'),
label= cms.untracked.string("AK4PFPuppi_phi")
),
cms.PSet(
record = cms.string('JetResolutionScaleFactorRcd'),
tag = cms.string('JR_'+jerera+'_MC_SF_AK4PFPuppi'),
label = cms.untracked.string('AK4PFPuppi')
),
) )
process.es_prefer_jer = cms.ESPrefer("PoolDBESSource",'jer')
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#default configuration for miniAOD reprocessing, change the isData flag to run on data
#for a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(process,
isData=isdata,
)
# process.selectedPatJetsForMetT1T2Corr.src = cms.InputTag("cleanedPatJets")
# process.patPFMetT1.src = cms.InputTag("slimmedMETs")
#
# process.CustomisationsSequence += process.patJetCorrFactorsReapplyJEC
# process.CustomisationsSequence += process.patJetsReapplyJEC
# process.CustomisationsSequence += process.basicJetsForMet
# process.CustomisationsSequence += process.jetSelectorForMet
# process.CustomisationsSequence += process.cleanedPatJets
# process.CustomisationsSequence += process.metrawCalo
# process.CustomisationsSequence += process.selectedPatJetsForMetT1T2Corr
# process.CustomisationsSequence += process.patPFMetT1T2Corr
# process.CustomisationsSequence += process.patPFMetT1
# process.CustomisationsSequence += process.patMetCorrectionSequence
if isdata:
return
# process.CustomisationsSequence += process.patMetUncertaintySequence #only for MC
# process.CustomisationsSequence += process.patShiftedModuleSequence #only for MC
"""
process.QGTagger.srcVertexCollection = cms.InputTag("offlinePrimaryVertices")
# compute corrected pruned jet mass
process.corrJets = cms.EDProducer(
"CorrJetsProducer",
jets=cms.InputTag("slimmedJetsAK8JEC"),
vertex=cms.InputTag("offlineSlimmedPrimaryVertices"),
rho=cms.InputTag("fixedGridRhoFastjetAll"),
payload=cms.string("AK8PFchs"),
isData=cms.bool(False),
year=cms.untracked.int32(2016))
# Recompute MET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=True,
)
# STXS
process.load("SimGeneral.HepPDTESSource.pythiapdt_cfi")
process.mergedGenParticles = cms.EDProducer(
"MergedGenParticleProducer",
inputPruned=cms.InputTag("prunedGenParticles"),
inputPacked=cms.InputTag("packedGenParticles"),
)
process.myGenerator = cms.EDProducer(
"GenParticles2HepMCConverter",
genParticles=cms.InputTag("mergedGenParticles"),
genEventInfo=cms.InputTag("generator"),
signalParticlePdgIds=cms.vint32(25))
process.rivetProducerHTXS = cms.EDProducer(
def makeTreeFromMiniAOD(
process,
outfile,
reportfreq=10,
dataset="",
globaltag="",
numevents=-1,
lostlepton=False,
geninfo=False,
tagname="RECO",
jsonfile="",
jecfile="",
residual=False,
jerfile="",
pufile="",
doPDFs=False,
fastsim=False,
signal=False,
):
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## Preamble
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
process.load("Configuration.StandardSequences.FrontierConditions_GlobalTag_condDBv2_cff")
process.GlobalTag.globaltag = globaltag
# log output
process.load("FWCore.MessageService.MessageLogger_cfi")
process.MessageLogger.cerr.FwkReport.reportEvery = reportfreq
process.options = cms.untracked.PSet(
allowUnscheduled = cms.untracked.bool(True),
# wantSummary = cms.untracked.bool(True) # off by default
)
# files to process
import FWCore.PythonUtilities.LumiList as LumiList
process.maxEvents = cms.untracked.PSet(
input = cms.untracked.int32(numevents)
)
process.source = cms.Source("PoolSource",
fileNames = cms.untracked.vstring(dataset)
)
if len(jsonfile)>0: process.source.lumisToProcess = LumiList.LumiList(filename = jsonfile).getVLuminosityBlockRange()
# output file
process.TFileService = cms.Service("TFileService",
fileName = cms.string(outfile+".root")
)
# branches for treemaker
VectorRecoCand = cms.vstring()
VarsDouble = cms.vstring()
VarsInt = cms.vstring()
VarsBool = cms.vstring()
VectorTLorentzVector = cms.vstring()
VectorDouble = cms.vstring()
VectorString = cms.vstring()
VectorInt = cms.vstring()
VectorBool = cms.vstring()
process.Baseline = cms.Sequence()
# configure treemaker
from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.treeMaker import TreeMaker
process.LQTreeMaker2 = TreeMaker.clone(
TreeName = cms.string("SimpleTree"),
VectorRecoCand = VectorRecoCand,
VarsDouble = VarsDouble,
VarsInt = VarsInt,
VarsBool = VarsBool,
VectorTLorentzVector = VectorTLorentzVector,
VectorDouble = VectorDouble,
VectorInt = VectorInt,
VectorString = VectorString,
VectorBool = VectorBool,
)
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## Standard producers
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## SUSY scan info
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## WeightProducer
## ----------------------------------------------------------------------------------------------
if geninfo:
from LeptoQuarkTreeMaker.WeightProducer.getWeightProducer_cff import getWeightProducer
process.WeightProducer = getWeightProducer(process.source.fileNames[0],fastsim and signal)
process.WeightProducer.Lumi = cms.double(1) #default: 1 pb-1 (unit value)
process.WeightProducer.FileNamePUDataDistribution = cms.string(pufile)
VarsDouble.extend(['WeightProducer:weight(Weight)','WeightProducer:xsec(CrossSection)','WeightProducer:nevents(NumEvents)',
'WeightProducer:TrueNumInteractions','WeightProducer:PUweight(puWeight)','WeightProducer:PUSysUp(puSysUp)','WeightProducer:PUSysDown(puSysDown)'])
VarsInt.extend(['WeightProducer:NumInteractions'])
## ----------------------------------------------------------------------------------------------
## PDF weights for PDF systematics
## ----------------------------------------------------------------------------------------------
if geninfo and doPDFs:
process.PDFWeights = cms.EDProducer('PDFWeightProducer')
VectorDouble.extend(['PDFWeights:PDFweights','PDFWeights:ScaleWeights'])
VectorInt.extend(['PDFWeights:PDFids'])
## ----------------------------------------------------------------------------------------------
## GenHT for stitching together MC samples
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## PrimaryVertices
## ----------------------------------------------------------------------------------------------
process.goodVertices = cms.EDFilter("VertexSelector",
src = cms.InputTag("offlineSlimmedPrimaryVertices"),
cut = cms.string("!isFake && ndof > 4 && abs(z) < 24 && position.Rho < 2"),
filter = cms.bool(False)
)
from LeptoQuarkTreeMaker.Utils.primaryvertices_cfi import primaryvertices
process.NVtx = primaryvertices.clone(
VertexCollection = cms.InputTag('goodVertices'),
)
VarsInt.extend(['NVtx'])
# also store total number of vertices without quality checks
process.nAllVertices = primaryvertices.clone(
VertexCollection = cms.InputTag('offlineSlimmedPrimaryVertices'),
)
VarsInt.extend(['nAllVertices'])
## ----------------------------------------------------------------------------------------------
## GenParticles
## ----------------------------------------------------------------------------------------------
## JECs
## ----------------------------------------------------------------------------------------------
process.load("CondCore.DBCommon.CondDBCommon_cfi")
from CondCore.DBCommon.CondDBSetup_cfi import CondDBSetup
# default miniAOD tags
JetTag = cms.InputTag('slimmedJets')
JetAK8Tag = cms.InputTag('slimmedJetsAK8')
METTag = cms.InputTag('slimmedMETs')
# get the JECs (disabled by default)
# this requires the user to download the .db file from this twiki
# https://twiki.cern.ch/twiki/bin/viewauth/CMS/JECDataMC
if len(jecfile)>0:
#get name of JECs without any directories
JECera = jecfile.split('/')[-1]
JECPatch = cms.string('sqlite_file:'+jecfile+'.db')
if os.getenv('GC_CONF'):
JECPatch = cms.string('sqlite_file:../src/'+jecfile+'.db')
process.jec = cms.ESSource("PoolDBESSource",CondDBSetup,
connect = JECPatch,
toGet = cms.VPSet(
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+JECera+"_AK4PFchs"),
label = cms.untracked.string("AK4PFchs")
),
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+JECera+"_AK4PF"),
label = cms.untracked.string("AK4PF")
),
cms.PSet(
record = cms.string("JetCorrectionsRecord"),
tag = cms.string("JetCorrectorParametersCollection_"+JECera+"_AK8PFchs"),
label = cms.untracked.string("AK8PFchs")
),
)
)
process.es_prefer_jec = cms.ESPrefer("PoolDBESSource","jec")
levels = ['L1FastJet','L2Relative','L3Absolute']
if residual: levels.append('L2L3Residual')
from PhysicsTools.PatAlgos.tools.jetTools import updateJetCollection
updateJetCollection(
process,
jetSource = cms.InputTag('slimmedJets'),
postfix = 'UpdatedJEC',
jetCorrections = ('AK4PFchs', levels, 'None')
)
JetTag = cms.InputTag('updatedPatJetsUpdatedJEC')
# also update the corrections for AK8 jets
updateJetCollection(
process,
jetSource = cms.InputTag('slimmedJetsAK8'),
labelName = 'AK8',
postfix = 'UpdatedJEC',
jetCorrections = ('AK8PFchs', levels, 'None')
)
JetAK8Tag = cms.InputTag('updatedPatJetsAK8UpdatedJEC')
# update the MET to account for the new JECs
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=not geninfo, # controls gen met
)
METTag = cms.InputTag('slimmedMETs','',process.name_())
else:
# pointless run of MET tool because it is barely functional
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=not geninfo, # controls gen met
)
# keep jets before any further modifications for hadtau
JetTagBeforeSmearing = JetTag
# JEC uncertainty - after JECs are updated
from LeptoQuarkTreeMaker.Utils.jetuncertainty_cfi import JetUncertaintyProducer
process.jecUnc = JetUncertaintyProducer.clone(
JetTag = JetTag,
jecUncDir = cms.int32(0)
)
# JER factors - central, up, dow
from LeptoQuarkTreeMaker.Utils.smearedpatjet_cfi import SmearedPATJetProducer
process.jerFactor = SmearedPATJetProducer.clone(
src = JetTag,
variation = cms.int32(0),
store_factor = cms.bool(True)
)
process.jerFactorUp = SmearedPATJetProducer.clone(
src = JetTag,
variation = cms.int32(1),
store_factor = cms.bool(True)
)
process.jerFactorDown = SmearedPATJetProducer.clone(
src = JetTag,
variation = cms.int32(-1),
store_factor = cms.bool(True)
)
# add userfloat & update tag
from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.addJetInfo import addJetInfo
process, JetTag = addJetInfo(process, JetTag, ['jecUnc','jerFactor','jerFactorUp','jerFactorDown'], [])
## ----------------------------------------------------------------------------------------------
## IsoTracks
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## Electrons/Muons
## ----------------------------------------------------------------------------------------------
# The decision was made to include the filter decision flags
# as individual branches in the tree
if not fastsim: # MET filters are not run for fastsim samples
from LeptoQuarkTreeMaker.Utils.filterdecisionproducer_cfi import filterDecisionProducer
process.CSCTightHaloFilter = filterDecisionProducer.clone(
trigTagArg1 = cms.string('TriggerResults'),
trigTagArg2 = cms.string(''),
trigTagArg3 = cms.string(tagname),
filterName = cms.string("Flag_CSCTightHalo2015Filter"),
)
VarsInt.extend(['CSCTightHaloFilter'])
process.globalTightHalo2016Filter = filterDecisionProducer.clone(
trigTagArg1 = cms.string('TriggerResults'),
trigTagArg2 = cms.string(''),
trigTagArg3 = cms.string(tagname),
filterName = cms.string("Flag_globalTightHalo2016Filter"),
)
VarsInt.extend(['globalTightHalo2016Filter'])
process.HBHENoiseFilter = filterDecisionProducer.clone(
trigTagArg1 = cms.string('TriggerResults'),
trigTagArg2 = cms.string(''),
trigTagArg3 = cms.string(tagname),
filterName = cms.string("Flag_HBHENoiseFilter"),
)
VarsInt.extend(['HBHENoiseFilter'])
process.HBHEIsoNoiseFilter = filterDecisionProducer.clone(
trigTagArg1 = cms.string('TriggerResults'),
trigTagArg2 = cms.string(''),
trigTagArg3 = cms.string(tagname),
filterName = cms.string("Flag_HBHENoiseIsoFilter"),
)
VarsInt.extend(['HBHEIsoNoiseFilter'])
process.EcalDeadCellTriggerPrimitiveFilter = filterDecisionProducer.clone(
trigTagArg1 = cms.string('TriggerResults'),
trigTagArg2 = cms.string(''),
trigTagArg3 = cms.string(tagname),
filterName = cms.string("Flag_EcalDeadCellTriggerPrimitiveFilter"),
)
VarsInt.extend(['EcalDeadCellTriggerPrimitiveFilter'])
process.eeBadScFilter = filterDecisionProducer.clone(
trigTagArg1 = cms.string('TriggerResults'),
trigTagArg2 = cms.string(''),
trigTagArg3 = cms.string(tagname),
filterName = cms.string("Flag_eeBadScFilter"),
)
VarsInt.extend(['eeBadScFilter'])
# some filters need to be rerun
process.load('RecoMET.METFilters.BadChargedCandidateFilter_cfi')
process.BadChargedCandidateFilter.muons = cms.InputTag("slimmedMuons")
process.BadChargedCandidateFilter.PFCandidates = cms.InputTag("packedPFCandidates")
process.BadChargedCandidateFilter.taggingMode = True
VarsBool.extend(['BadChargedCandidateFilter'])
process.load('RecoMET.METFilters.BadPFMuonFilter_cfi')
process.BadPFMuonFilter.muons = cms.InputTag("slimmedMuons")
process.BadPFMuonFilter.PFCandidates = cms.InputTag("packedPFCandidates")
process.BadPFMuonFilter.taggingMode = True
VarsBool.extend(['BadPFMuonFilter'])
'''
process.load('Configuration.StandardSequences.Services_cff')
process.RandomNumberGeneratorService = cms.Service("RandomNumberGeneratorService",
calibratedPatElectrons = cms.PSet(
initialSeed = cms.untracked.uint32(81),
engineName = cms.untracked.string('TRandom3'),
),
calibratedPatPhotons = cms.PSet(
initialSeed = cms.untracked.uint32(81),
engineName = cms.untracked.string('TRandom3'),
),
)
process.load('EgammaAnalysis.ElectronTools.calibratedElectronsRun2_cfi')
correctionType = "80Xapproval"
calibratedPatElectrons = cms.EDProducer("CalibratedPatElectronProducerRun2",
# input collections
electrons = cms.InputTag('slimmedElectrons'),
gbrForestName = cms.string("gedelectron_p4combination_25ns"),
# data or MC corrections
# if isMC is false, data corrections are applied
isMC = cms.bool(False),
# set to True to get special "fake" smearing for synchronization. Use JUST in case of synchronization
isSynchronization = cms.bool(False),
correctionFile = cms.string("80Xapproval")
)
process.Baseline += process.calibratedPatElectrons
from LeptoQuarkTreeMaker.Utils.HEEPProducer_cfi import HEEPProducer
process.HEEPProducer = HEEPProducer.clone(
eletag = cms.InputTag('slimmedElectrons')
)
process.Baseline += process.HEEPProducer
VectorDouble.extend(['HEEPProducer:trackiso(Electron_trackiso)'])
VectorDouble.extend(['HEEPProducer:Eta(Electron_Eta)'])
VectorDouble.extend(['HEEPProducer:Et(Electron_Et)'])
VectorDouble.extend(['HEEPProducer:DeltaEtain(Electron_DeltaEtain)'])
VectorDouble.extend(['HEEPProducer:DeltaPhiin(Electron_DeltaPhiin)'])
VectorDouble.extend(['HEEPProducer:HbE(Electron_HOverE)'])
VectorDouble.extend(['HEEPProducer:SiEtaiEta(Electron_SiEtaiEta)'])
VectorDouble.extend(['HEEPProducer:Ecaliso(Electron_Ecaliso)'])
VectorDouble.extend(['HEEPProducer:HD1iso(Electron_HD1iso)'])
VectorDouble.extend(['HEEPProducer:HD2iso(Electron_HD2iso)'])
VectorBool.extend(['HEEPProducer:ecalDriven(Electron_ecalDriven)'])
VectorDouble.extend(['HEEPProducer:e25max(Electron_e25max)'])
VectorDouble.extend(['HEEPProducer:e55(Electron_e55)'])
VectorDouble.extend(['HEEPProducer:e25bye55(Electron_e25bye55)'])
VectorDouble.extend(['HEEPProducer:Fullsce25bye55(Electron_Fullsce25bye55)'])
VectorDouble.extend(['HEEPProducer:Fulle15bye55(Electron_Fulle15bye55)'])
VectorDouble.extend(['HEEPProducer:scEnergy(Electron_scEnergy)'])
VectorDouble.extend(['HEEPProducer:DeltaEtaSeed(Electron_DeltaEtaSeed)'])
VectorDouble.extend(['HEEPProducer:rho(rho)'])
VectorInt.extend(['HEEPProducer:Charge(Electron_Charge)'])
VectorDouble.extend(['HEEPProducer:ePt(Electron_Pt)'])
VectorDouble.extend(['HEEPProducer:e15(Electron_e15)'])
VectorDouble.extend(['HEEPProducer:ecalEnergy(Electron_ecalEnergy)'])
VectorDouble.extend(['HEEPProducer:full55SiEtaiEta(Electron_full55SiEtaiEta)'])
VectorDouble.extend(['HEEPProducer:sce25max(Electron_sce25max)'])
VectorDouble.extend(['HEEPProducer:sce55(Electron_sce55)'])
VectorDouble.extend(['HEEPProducer:sce25bye55(Electron_sce25bye55)'])
VectorDouble.extend(['HEEPProducer:e15bye55(Electron_e15bye55)'])
VectorDouble.extend(['HEEPProducer:DeltaEtaSeedscandTrack(Electron_DeltaEtaSeedscandTrack)'])
VectorDouble.extend(['HEEPProducer:Phi(Electron_Phi)'])
VectorDouble.extend(['HEEPProducer:eEnergy(Electron_Energy)'])
VectorDouble.extend(['HEEPProducer:dxy(dxy)'])
VectorInt.extend(['HEEPProducer:losthits(Electron_losthits)'])
VectorDouble.extend(['HEEPProducer:ePz(Electron_Pz)'])
VectorDouble.extend(['HEEPProducer:eTheta(Electron_Theta)'])
VectorDouble.extend(['HEEPProducer:ePx(Electron_Px)'])
VectorDouble.extend(['HEEPProducer:ePy(Electron_Py)'])
VectorDouble.extend(['HEEPProducer:normalizedChi2(Electron_normalizedChi2)'])
VectorInt.extend(['HEEPProducer:PDGID(PDGID)'])
VectorInt.extend(['HEEPProducer:gencharge(gencharge)'])
VectorDouble.extend(['HEEPProducer:genPt(genPt)'])
VectorDouble.extend(['HEEPProducer:genEta(genEta)'])
VectorDouble.extend(['HEEPProducer:genPhi(genPhi)'])
VectorDouble.extend(['HEEPProducer:genEnergy(genEnergy)'])
VectorInt.extend(['HEEPProducer:motherPDGID(motherPDGID)'])
VectorInt.extend(['HEEPProducer:elstatus(elstatus)'])
VectorDouble.extend(['HEEPProducer:PtHEEP(Electron_PtHEEP)'])
VectorDouble.extend(['HEEPProducer:scEtaa(Electron_scEtaa)'])
VectorDouble.extend(['HEEPProducer:scEta(Electron_scEta)'])
## ----------------------------------------------------------------------------------------------
## Muons
## ----------------------------------------------------------------------------------------------
from LeptoQuarkTreeMaker.Utils.MuonProducer_cfi import MuonProducer
process.MuonProducer = MuonProducer.clone(
muontag = cms.InputTag('slimmedMuons')
)
process.Baseline += process.MuonProducer
VectorBool.extend(['MuonProducer:MuonisTightMuon(MuonisTightMuon)'])
VectorBool.extend(['MuonProducer:MuonisHighPtMuon(MuonisHighPtMuon)'])
VectorDouble.extend(['MuonProducer:MuonEta(MuonEta)'])
VectorDouble.extend(['MuonProducer:MuonPhi(MuonPhi)'])
VectorDouble.extend(['MuonProducer:MuonPt(MuonPt)'])
VectorDouble.extend(['MuonProducer:MuonEnergy(MuonEnergy)'])
VectorDouble.extend(['MuonProducer:MuonPtError(MuonPtError)'])
VectorDouble.extend(['MuonProducer:MuonGlobalChi2(MuonGlobalChi2)'])
VectorDouble.extend(['MuonProducer:MuonTrkPtError(MuonTrkPtError)'])
VectorInt.extend(['MuonProducer:MuonIsPF(MuonIsPF)'])
VectorInt.extend(['MuonProducer:MuonCharge(MuonCharge)'])
VectorInt.extend(['MuonProducer:MuonGlobalTrkValidHits(MuonGlobalTrkValidHits)'])
VectorInt.extend(['MuonProducer:MuonTrkPixelHits(MuonTrkPixelHits)'])
VectorInt.extend(['MuonProducer:MuonStationMatches(MuonStationMatches)'])
VectorDouble.extend(['MuonProducer:MuonPFIsoR04Photon(MuonPFIsoR04Photon)'])
VectorDouble.extend(['MuonProducer:MuonPFIsoR04NeutralHadron(MuonPFIsoR04NeutralHadron)'])
VectorDouble.extend(['MuonProducer:MuonPFIsoR04PU(MuonPFIsoR04PU)'])
VectorDouble.extend(['MuonProducer:MuonTrackerIsoSumPT(MuonTrackerIsoSumPT)'])
VectorDouble.extend(['MuonProducer:MuonPFIsoR04ChargedHadron(MuonPFIsoR04ChargedHadron)'])
VectorInt.extend(['MuonProducer:MuonPassID(MuonPassID)'])
VectorInt.extend(['MuonProducer:MuonIsGlobal(MuonIsGlobal)'])
VectorInt.extend(['MuonProducer:MuonTrackLayersWithMeasurement(MuonTrackLayersWithMeasurement)'])
VectorDouble.extend(['MuonProducer:CocktailEta(CocktailPtError)'])
VectorDouble.extend(['MuonProducer:CocktailPt(CocktailPt)'])
VectorDouble.extend(['MuonProducer:MuonBestTrackVtxDistXY(MuonBestTrackVtxDistXY)'])
VectorDouble.extend(['MuonProducer:MuonBestTrackVtxDistZ(MuonBestTrackVtxDistZ)'])
## ----------------------------------------------------------------------------------------------
## Taus
## ----------------------------------------------------------------------------------------------
from LeptoQuarkTreeMaker.Utils.TauProducer_cfi import TauProducer
process.TauProducer = TauProducer.clone(
tautag = cms.InputTag('slimmedTaus')
)
process.Baseline += process.TauProducer
VectorDouble.extend(['TauProducer:tEta(TauEta)'])
VectorDouble.extend(['TauProducer:tPhi(TauPhi)'])
VectorDouble.extend(['TauProducer:tPt(TauPt)'])
'''
## ----------------------------------------------------------------------------------------------
## Triggers
## ----------------------------------------------------------------------------------------------
# The trigger results are saved to the tree as a vector
# Three vectors are saved:
# 1) names of the triggers
# 2) trigger results
# 3) trigger prescales
# the indexing of these vectors must match
# If the version number of the input trigger name is omitted,
# any matching trigger will be included (default behavior)
from LeptoQuarkTreeMaker.Utils.triggerproducer_cfi import triggerProducer
from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.triggerNameList import triggerNameList as _triggerNameList
process.TriggerProducer = triggerProducer.clone(
trigTagArg1 = cms.string('TriggerResults'),
trigTagArg2 = cms.string(''),
trigTagArg3 = cms.string('HLT'),
prescaleTagArg1 = cms.string('patTrigger'),
prescaleTagArg2 = cms.string(''),
prescaleTagArg3 = cms.string(''),
triggerNameList = _triggerNameList
)
VectorInt.extend(['TriggerProducer:TriggerPass','TriggerProducer:TriggerPrescales'])
VectorString.extend(['TriggerProducer:TriggerNames'])
VectorDouble.extend(['TriggerProducer:objectPt'])
VectorDouble.extend(['TriggerProducer:objecteta'])
VectorDouble.extend(['TriggerProducer:objectphi'])
VectorDouble.extend(['TriggerProducer:objectE'])
'''
if not geninfo:
from LeptoQuarkTreeMaker.Utils.prescaleweightproducer_cfi import prescaleweightProducer
process.PrescaleWeightProducer = prescaleweightProducer.clone()
VarsDouble.extend(['PrescaleWeightProducer:weight(PrescaleWeightHT)'])
VarsDouble.extend(['PrescaleWeightProducer:ht(HTOnline)'])
VarsDouble.extend(['PrescaleWeightProducer:mht(MHTOnline)'])
'''
## ----------------------------------------------------------------------------------------------
## JER smearing, various uncertainties
## ----------------------------------------------------------------------------------------------
# list of clean tags - ignore jet ID for jets matching these objects
SkipTag = cms.VInputTag(
# cms.InputTag('LeptonsNew:IdIsoMuon'),
# cms.InputTag('LeptonsNew:IdIsoElectron'),
# cms.InputTag('IsolatedElectronTracksVeto'),
# cms.InputTag('IsolatedMuonTracksVeto'),
# cms.InputTag('IsolatedPionTracksVeto'),
)
# get the JERs (disabled by default)
# this requires the user to download the .db file from this github
# https://github.com/cms-jet/JRDatabase
'''
if len(jerfile)>0:
#get name of JERs without any directories
JERera = jerfile.split('/')[-1]
JERPatch = cms.string('sqlite_file:'+jerfile+'.db')
if os.getenv('GC_CONF'):
JERPatch = cms.string('sqlite_file:../src/'+jerfile+'.db')
process.jer = cms.ESSource("PoolDBESSource",CondDBSetup,
connect = JERPatch,
toGet = cms.VPSet(
cms.PSet(
record = cms.string('JetResolutionRcd'),
tag = cms.string('JR_'+JERera+'_PtResolution_AK4PFchs'),
label = cms.untracked.string('AK4PFchs_pt')
),
cms.PSet(
record = cms.string('JetResolutionScaleFactorRcd'),
tag = cms.string('JR_'+JERera+'_SF_AK4PFchs'),
label = cms.untracked.string('AK4PFchs')
),
),
)
process.es_prefer_jer = cms.ESPrefer('PoolDBESSource', 'jer')
'''
# skip all jet smearing and uncertainties for data
# from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.JetDepot import JetDepot
from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.makeJetVars import makeJetVars
process = makeJetVars(process,
JetTag=JetTag,
suff='',
skipGoodJets=False,
storeProperties=2,
geninfo=geninfo,
fastsim=fastsim,
SkipTag=SkipTag
)
if geninfo:
from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.JetDepot import JetDepot
# JEC unc up
process, JetTagJECup = JetDepot(process,
JetTag=JetTag,
jecUncDir=1,
doSmear=True,
jerUncDir=0
)
process = makeJetVars(process,
JetTag=JetTagJECup,
suff='JECup',
skipGoodJets=False,
storeProperties=1,
geninfo=geninfo,
fastsim=fastsim,
SkipTag=SkipTag
)
# JEC unc down
process, JetTagJECdown = JetDepot(process,
JetTag=JetTag,
jecUncDir=-1,
doSmear=True,
jerUncDir=0
)
process = makeJetVars(process,
JetTag=JetTagJECdown,
suff='JECdown',
skipGoodJets=False,
storeProperties=1,
geninfo=geninfo,
fastsim=fastsim,
SkipTag=SkipTag
)
# JER unc up
process, JetTagJERup = JetDepot(process,
JetTag=JetTag,
jecUncDir=0,
doSmear=True,
jerUncDir=1
)
process = makeJetVars(process,
JetTag=JetTagJERup,
suff='JERup',
skipGoodJets=False,
storeProperties=1,
geninfo=geninfo,
fastsim=fastsim,
SkipTag=SkipTag
)
# JER unc down
process, JetTagJERdown = JetDepot(process,
JetTag=JetTag,
jecUncDir=0,
doSmear=True,
jerUncDir=-1
)
process = makeJetVars(process,
JetTag=JetTagJERdown,
suff='JERdown',
skipGoodJets=False,
storeProperties=1,
geninfo=geninfo,
fastsim=fastsim,
SkipTag=SkipTag
)
# finally, do central smearing and replace jet tag
process, JetTag = JetDepot(process,
JetTag=JetTag,
jecUncDir=0,
doSmear=True,
jerUncDir=0
)
## ----------------------------------------------------------------------------------------------
## Jet variables
## ----------------------------------------------------------------------------------------------
'''
# get updated QG training
QGPatch = cms.string('sqlite_file:data/QGL_80X.db')
if os.getenv('GC_CONF'):
QGPatch = cms.string('sqlite_file:../src/data/QGL_80X.db')
process.qgdb = cms.ESSource("PoolDBESSource",CondDBSetup,
connect = QGPatch,
toGet = cms.VPSet(
cms.PSet(
record = cms.string('QGLikelihoodRcd'),
tag = cms.string('QGLikelihoodObject_80X_AK4PFchs'),
label = cms.untracked.string('QGL_AK4PFchs')
),
cms.PSet(
record = cms.string('QGLikelihoodRcd'),
tag = cms.string('QGLikelihoodObject_80X_AK4PFchs_antib'),
label = cms.untracked.string('QGL_AK4PFchs_antib')
),
)
)
process.es_prefer_qg = cms.ESPrefer("PoolDBESSource","qgdb")
# get QG tagging discriminant
process.QGTagger = cms.EDProducer('QGTagger',
srcJets = JetTag,
jetsLabel = cms.string('QGL_AK4PFchs'),
srcRho = cms.InputTag('fixedGridRhoFastjetAll'),
srcVertexCollection = cms.InputTag('offlinePrimaryVerticesWithBS'),
useQualityCuts = cms.bool(False)
)
# add userfloats & update tag
process, JetTag = addJetInfo(process, JetTag, ['QGTagger:qgLikelihood','QGTagger:ptD', 'QGTagger:axis2'], ['QGTagger:mult'])
process = makeJetVars(process,
JetTag=JetTag,
suff='',
skipGoodJets=False,
storeProperties=2,
geninfo=geninfo,
fastsim=fastsim,
SkipTag=SkipTag
)
# get double b-tagger (w/ miniAOD customizations)
process.load("RecoBTag.ImpactParameter.pfImpactParameterAK8TagInfos_cfi")
process.pfImpactParameterAK8TagInfos.primaryVertex = cms.InputTag("offlineSlimmedPrimaryVertices")
process.pfImpactParameterAK8TagInfos.candidates = cms.InputTag("packedPFCandidates")
process.pfImpactParameterAK8TagInfos.jets = JetAK8Tag
process.load("RecoBTag.SecondaryVertex.pfInclusiveSecondaryVertexFinderAK8TagInfos_cfi")
process.pfInclusiveSecondaryVertexFinderAK8TagInfos.extSVCollection = cms.InputTag("slimmedSecondaryVertices")
process.pfInclusiveSecondaryVertexFinderAK8TagInfos.trackIPTagInfos = cms.InputTag("pfImpactParameterAK8TagInfos")
process.load("RecoBTag.SecondaryVertex.pfBoostedDoubleSVAK8TagInfos_cfi")
process.load("RecoBTag.SecondaryVertex.candidateBoostedDoubleSecondaryVertexAK8Computer_cfi")
process.load("RecoBTag.SecondaryVertex.pfBoostedDoubleSecondaryVertexAK8BJetTags_cfi")
# add discriminator and update tag
process, JetAK8Tag = addJetInfo(process, JetAK8Tag, [], [], cms.VInputTag(cms.InputTag("pfBoostedDoubleSecondaryVertexAK8BJetTags")))
# apply jet ID
process = makeJetVars(process,
JetTag=JetAK8Tag,
suff='AK8',
skipGoodJets=False,
storeProperties=1,
geninfo=geninfo,
fastsim=fastsim,
onlyGoodJets=True
)
# AK8 jet variables - separate instance of jet properties producer
from LeptoQuarkTreeMaker.Utils.jetproperties_cfi import jetproperties
process.JetsPropertiesAK8 = jetproperties.clone(
JetTag = JetAK8Tag,
properties = cms.vstring(
"prunedMass" ,
"NsubjettinessTau1" ,
"NsubjettinessTau2" ,
"NsubjettinessTau3" ,
"bDiscriminatorSubjet1",
"bDiscriminatorSubjet2",
"bDiscriminatorCSV" ,
"NumBhadrons" ,
"NumChadrons" ,
)
)
#specify userfloats
process.JetsPropertiesAK8.prunedMass = cms.vstring('ak8PFJetsCHSPrunedMass')
process.JetsPropertiesAK8.NsubjettinessTau1 = cms.vstring('NjettinessAK8:tau1')
process.JetsPropertiesAK8.NsubjettinessTau2 = cms.vstring('NjettinessAK8:tau2')
process.JetsPropertiesAK8.NsubjettinessTau3 = cms.vstring('NjettinessAK8:tau3')
process.JetsPropertiesAK8.bDiscriminatorSubjet1 = cms.vstring('SoftDrop','pfCombinedInclusiveSecondaryVertexV2BJetTags')
process.JetsPropertiesAK8.bDiscriminatorSubjet2 = cms.vstring('SoftDrop','pfCombinedInclusiveSecondaryVertexV2BJetTags')
process.JetsPropertiesAK8.bDiscriminatorCSV = cms.vstring('pfBoostedDoubleSecondaryVertexAK8BJetTags')
#VectorRecoCand.extend([JetAK8Tag.value()+'(JetsAK8)'])
#VectorDouble.extend(['JetsPropertiesAK8:prunedMass(JetsAK8_prunedMass)',
# 'JetsPropertiesAK8:bDiscriminatorSubjet1(JetsAK8_bDiscriminatorSubjet1CSV)',
# 'JetsPropertiesAK8:bDiscriminatorSubjet2(JetsAK8_bDiscriminatorSubjet2CSV)',
# 'JetsPropertiesAK8:bDiscriminatorCSV(JetsAK8_doubleBDiscriminator)',
# 'JetsPropertiesAK8:NsubjettinessTau1(JetsAK8_NsubjettinessTau1)',
# 'JetsPropertiesAK8:NsubjettinessTau2(JetsAK8_NsubjettinessTau2)',
# 'JetsPropertiesAK8:NsubjettinessTau3(JetsAK8_NsubjettinessTau3)'])
#VectorInt.extend(['JetsPropertiesAK8:NumBhadrons(JetsAK8_NumBhadrons)',
# 'JetsPropertiesAK8:NumChadrons(JetsAK8_NumChadrons)'])
'''
## ----------------------------------------------------------------------------------------------
## GenJet variables
## ----------------------------------------------------------------------------------------------
if geninfo:
# store all genjets
VectorRecoCand.extend ( [ 'slimmedGenJets(GenJets)' ] )
from LeptoQuarkTreeMaker.Utils.subJetSelection_cfi import SubGenJetSelection
process.GenHTJets = SubGenJetSelection.clone(
JetTag = cms.InputTag('slimmedGenJets'),
MinPt = cms.double(30),
MaxEta = cms.double(2.4),
)
#VectorBool.extend(['GenHTJets:SubJetMask(GenJets_HTMask)'])
# make gen HT
from LeptoQuarkTreeMaker.Utils.htdouble_cfi import htdouble
process.GenHT = htdouble.clone(
JetTag = cms.InputTag("GenHTJets"),
)
#VarsDouble.extend(['GenHT'])
process.GenMHTJets = SubGenJetSelection.clone(
JetTag = cms.InputTag('slimmedGenJets'),
MinPt = cms.double(30),
MaxEta = cms.double(5.0),
)
#VectorBool.extend(['GenMHTJets:SubJetMask(GenJets_MHTMask)'])
'''
# make gen MHT
from LeptoQuarkTreeMaker.Utils.mhtdouble_cfi import mhtdouble
process.GenMHT = mhtdouble.clone(
JetTag = cms.InputTag('GenMHTJets'),
)
VarsDouble.extend(['GenMHT:Pt(GenMHT)','GenMHT:Phi(GenMHTPhi)'])
'''
## ----------------------------------------------------------------------------------------------
## Baseline filters
## ----------------------------------------------------------------------------------------------
# sequence for baseline filters
process.Baseline = cms.Sequence()
'''
from LeptoQuarkTreeMaker.Utils.doublefilter_cfi import DoubleFilter
process.HTFilter = DoubleFilter.clone(
DoubleTag = cms.InputTag('HT'),
CutValue = cms.double('500'),
)
process.MHTFilter = DoubleFilter.clone(
DoubleTag = cms.InputTag('MHT:Pt'),
CutValue = cms.double('200'),
)
if applybaseline:
process.Baseline += process.HTFilter
#process.Baseline += process.MHTFilter
'''
## ----------------------------------------------------------------------------------------------
## MET
## ----------------------------------------------------------------------------------------------
from LeptoQuarkTreeMaker.Utils.metdouble_cfi import metdouble
process.MET = metdouble.clone(
METTag = METTag,
GenMETTag = cms.InputTag("slimmedMETs","",tagname), #original collection used deliberately here
JetTag = cms.InputTag('HTJets'),
geninfo = cms.untracked.bool(geninfo),
)
VarsDouble.extend(['MET:Pt(MET)','MET:Phi(METPhi)'])
if geninfo:
VarsDouble.extend(['MET:GenPt(GenMET)','MET:GenPhi(GenMETPhi)'])
VectorDouble.extend(['MET:PtUp(METUp)', 'MET:PtDown(METDown)', 'MET:PhiUp(METPhiUp)', 'MET:PhiDown(METPhiDown)'])
'''
from LeptoQuarkTreeMaker.Utils.mt2producer_cfi import mt2Producer
process.Mt2Producer = mt2Producer.clone(
JetTag = cms.InputTag('MHTJets'),
METTag = METTag
)
VarsDouble.extend(['Mt2Producer:mt2(MT2)'])
'''
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## Optional producers (background estimations, control regions)
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## Hadronic Tau Background
## ----------------------------------------------------------------------------------------------
'''
if hadtau:
from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.doHadTauBkg import doHadTauBkg
dorecluster = False
if hadtaurecluster==0: dorecluster = False
elif hadtaurecluster==1: dorecluster = ("TTJets" in process.source.fileNames[0] or "WJets" in process.source.fileNames[0])
elif hadtaurecluster==2: dorecluster = geninfo
elif hadtaurecluster==3: dorecluster = True
process = doHadTauBkg(process,geninfo,residual,JetTagBeforeSmearing,fastsim,dorecluster)
## ----------------------------------------------------------------------------------------------
## Lost Lepton Background
## ----------------------------------------------------------------------------------------------
if lostlepton:
from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.doLostLeptonBkg import doLostLeptonBkg
process = doLostLeptonBkg(process,geninfo,METTag)
## ----------------------------------------------------------------------------------------------
## Zinv Background
## ----------------------------------------------------------------------------------------------
if doZinv:
from LeptoQuarkTreeMaker.LeptoQuarkTreeMaker.doZinvBkg import doZinvBkg
process = doZinvBkg(process,tagname,geninfo,residual,fastsim)
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
## Final steps
## ----------------------------------------------------------------------------------------------
## ----------------------------------------------------------------------------------------------
'''
# create the process path
process.dump = cms.EDAnalyzer("EventContentAnalyzer")
process.WriteTree = cms.Path(
process.Baseline *
process.LQTreeMaker2
)
return process
from PhysicsTools.PatAlgos.tools.jetTools import updateJetCollection
updateJetCollection(process,
jetSource=cms.InputTag('slimmedJetsPuppi'),
postfix='UpdatedJECAK4PFPuppi',
jetCorrections=('AK4PFPuppi', [
'L1FastJet', 'L2Relative', 'L3Absolute'
], 'None'))
process.ntuple.jets = "updatedPatJetsUpdatedJECAK4PFPuppi"
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=False,
metType="Puppi",
postfix="PuppiCorr",
pfCandColl=cms.InputTag("puppiForMET"),
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
)
puppiMetSource = cms.InputTag("slimmedMETsPuppiCorr", "",
"MiniAnalysis")
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
makePuppiesFromMiniAOD(process, True)
process.ntuple.mets = puppiMetSource
process.jetmetsequence = cms.Sequence()
from PhysicsTools.PatAlgos.producersLayer1.jetUpdater_cff import patJetsUpdated
process.patJetsReapplyJEC = patJetsUpdated.clone(
jetSource = cms.InputTag("slimmedJets"),
jetCorrFactorsSource = cms.VInputTag(cms.InputTag("patJetCorrFactorsReapplyJEC"))
)
###### Apply new JECs to MET
## From https://github.com/cms-met/cmssw/blob/METCorUnc74X/PhysicsTools/PatAlgos/test/corMETFromMiniAOD.py
process.options = cms.untracked.PSet(
allowUnscheduled = cms.untracked.bool(True),
wantSummary = cms.untracked.bool(False)
)
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(process,
isData=isData,
pfCandColl=cms.InputTag("packedPFCandidates")
)
if isData:
process.patPFMetT1T2Corr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT1T2SmearCorr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT2Corr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT2SmearCorr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.shiftedPatJetEnDown.jetCorrLabelUpToL3Res = cms.InputTag("ak4PFCHSL1FastL2L3Corrector")
process.shiftedPatJetEnUp.jetCorrLabelUpToL3Res = cms.InputTag("ak4PFCHSL1FastL2L3Corrector")
# Redefine process for data to RECO
process.slimmedMETs.t01Variation = cms.InputTag("slimmedMETs","",processRECO)
###### Path
process.p = cms.Path(process.patJetCorrFactorsReapplyJEC*
process.patJetsReapplyJEC*
#process.HBHENoiseFilterResultProducer* #produces HBHE baseline bools
era='2017-Nov17ReReco',
eleIDModules=myEleID,
phoIDModules=myPhoID,
)
#a sequence egammaPostRecoSeq has now been created and should be added to your path, eg process.p=cms.Path(process.egammaPostRecoSeq)
###########################
#### MET EE Noise
###########################
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD (
process,
isData = (not isMC), # false for MC
fixEE2017 = True,
fixEE2017Params = {'userawPt': True, 'ptThreshold':50.0, 'minEtaThreshold':2.65, 'maxEtaThreshold': 3.139} ,
postfix = "ModifiedMET"
)
process.recoTree.MET = cms.InputTag("slimmedMETsModifiedMET")
#################
### Reapply JEC
### https://twiki.cern.ch/twiki/bin/view/CMSPublic/WorkBookJetEnergyCorrections#CorrPatJets
#################
from PhysicsTools.PatAlgos.tools.jetTools import updateJetCollection
#### AK4
updateJetCollection(
jetSource = cms.InputTag('ak4PFJetsCHS'),
jetCorrections = ('AK4PFchs', ['L1FastJet', 'L2Relative', 'L3Absolute','L2L3Residual'], ''),
genParticles = cms.InputTag('prunedGenParticles'),
pvSource = cms.InputTag('offlineSlimmedPrimaryVertices')
)
process.patJets.addGenJetMatch = cms.bool(False)
process.patJets.addGenPartonMatch = cms.bool(False)
process.patJets.addPartonJetMatch = cms.bool(False)
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#default configuration for miniAOD reprocessing, change the isData flag to run on data
#for a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(process,
isData=not(config["RUNONMC"]),
)
process.patPFMetT1T2Corr.type1JetPtThreshold = cms.double(15.0)
process.patPFMetT2Corr.type1JetPtThreshold = cms.double(15.0)
process.slimmedMETs.t01Variation = cms.InputTag("slimmedMETs","","RECO")
if config["RUNONMC"]:
process.patPFMetT1T2Corr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT1T2SmearCorr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT2Corr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT2SmearCorr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.shiftedPatJetEnDown.jetCorrLabelUpToL3Res = cms.InputTag("ak4PFCHSL1FastL2L3Corrector")
process.shiftedPatJetEnUp.jetCorrLabelUpToL3Res = cms.InputTag("ak4PFCHSL1FastL2L3Corrector")
####### Adding HEEP id ##########
'L3Absolute']), 'None'))
updateJetCollection(
process,
jetSource=cms.InputTag('slimmedJetsAK8'),
labelName='UpdatedJECAK8',
jetCorrections=('AK8PFchs',
cms.vstring(['L1FastJet', 'L2Relative',
'L3Absolute']), 'None'),
btagDiscriminators=['pfBoostedDoubleSecondaryVertexAK8BJetTags'],
btagPrefix=
'newV4' # optional, in case interested in accessing both the old and new discriminator values
)
# MET correction and uncertainties
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(process, isData=False)
process.load("ggAnalysis.ggNtuplizer.ggNtuplizer_miniAOD_cfi")
process.load("ggAnalysis.ggNtuplizer.ggPhotonIso_CITK_PUPPI_cff")
process.load("ggAnalysis.ggNtuplizer.ggMETFilters_cff")
process.ggNtuplizer.dumpSoftDrop = cms.bool(True)
process.ggNtuplizer.jecAK8PayloadNames = cms.vstring(jecLevels)
process.ggNtuplizer.runHFElectrons = cms.bool(True)
process.ggNtuplizer.isAOD = cms.bool(False)
process.ggNtuplizer.doGenParticles = cms.bool(True)
process.ggNtuplizer.dumpSubJets = cms.bool(True)
process.ggNtuplizer.dumpJets = cms.bool(True)
process.ggNtuplizer.dumpTaus = cms.bool(False)
process.ggNtuplizer.patTriggerResults = cms.InputTag("TriggerResults", "",
"PAT")
if runOnData:
process.patJetCorrFactorsReapplyJEC.levels.append("L2L3Residual")
from PhysicsTools.PatAlgos.producersLayer1.jetUpdater_cff import updatedPatJets
process.patJetsReapplyJEC = updatedPatJets.clone(
jetSource = cms.InputTag("slimmedJets"),
jetCorrFactorsSource = cms.VInputTag(cms.InputTag("patJetCorrFactorsReapplyJEC"))
)
#PFMET
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
# If you only want to re-correct and get the proper uncertainties
runMetCorAndUncFromMiniAOD(process,
isData=runOnData,
fixEE2017 = True,
postfix = "ModifiedMET"
)
#PuppiMET
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
makePuppiesFromMiniAOD( process, True );
# If you only want to re-cluster and get the proper uncertainties
runMetCorAndUncFromMiniAOD(process,
isData=runOnData,
metType="Puppi",
pfCandColl=cms.InputTag("puppiForMET"),
recoMetFromPFCs=True,
jetFlavor="AK4PFPuppi",
postfix="Puppi"
# setattr(process, UnpackerName, UnpackerModule) #equiv to process.<UnpackerName> = <UnpackerModule>
# process.METSequence += UnpackerModule
# MVAMETName = "patMETMVA%i" % index
# MVAModule = process.MVAMET.clone( srcLeptons = cms.VInputTag (cms.InputTag(UnpackerName) ) )
# setattr(process, MVAMETName, MVAModule)
# process.METSequence += MVAModule
# MVAPairMET.append(cms.InputTag(MVAMETName, "MVAMET"))
else:
print "Using event pfMET (same MET for all pairs)"
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=(not IsMC),
)
# patch to get a standalone MET significance collection
process.METSignificance = cms.EDProducer("ExtractMETSignificance",
srcMET=cms.InputTag(
"slimmedMETs", "", "TEST"))
process.METSequence += process.fullPatMetSequence
process.METSequence += process.METSignificance
# ## always compute met significance
# process.load("RecoMET.METProducers.METSignificance_cfi")
# process.load("RecoMET.METProducers.METSignificanceParams_cfi")
# process.METSequence += cms.Sequence(process.METSignificance)
## ----------------------------------------------------------------------
## Z-recoil correction
def nanoAOD_recalibrateMETs(process,isData):
# add DeepMETs
nanoAOD_DeepMET_switch = cms.PSet(
ResponseTune_Graph = cms.untracked.string('RecoMET/METPUSubtraction/data/models/deepmet/deepmet_resp_v1_2018/model.graphdef')
)
for modifier in run2_miniAOD_80XLegacy, run2_nanoAOD_94X2016:
modifier.toModify(nanoAOD_DeepMET_switch, ResponseTune_Graph="RecoMET/METPUSubtraction/data/models/deepmet/deepmet_resp_v1_2016/model.graphdef")
print("add DeepMET Producers")
process.load('RecoMET.METPUSubtraction.deepMETProducer_cfi')
process.deepMETsResolutionTune = process.deepMETProducer.clone()
process.deepMETsResponseTune = process.deepMETProducer.clone()
process.deepMETsResponseTune.graph_path = nanoAOD_DeepMET_switch.ResponseTune_Graph.value()
runMetCorAndUncFromMiniAOD(process,isData=isData)
process.nanoSequenceCommon.insert(2,cms.Sequence(process.fullPatMetSequence))
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
makePuppiesFromMiniAOD(process,True)
process.puppiNoLep.useExistingWeights = True
process.puppi.useExistingWeights = True
run2_nanoAOD_106Xv1.toModify(process.puppiNoLep, useExistingWeights = False)
run2_nanoAOD_106Xv1.toModify(process.puppi, useExistingWeights = False)
print("will make Puppies on top of MINIAOD")
# makePuppiesFromMiniAOD(process,True) # call this before in the global customizer otherwise it would reset photon IDs in VID
nanoAOD_PuppiV15_switch = cms.PSet(
recoMetFromPFCs = cms.untracked.bool(False),
reclusterJets = cms.untracked.bool(False),
)
run2_nanoAOD_106Xv1.toModify(nanoAOD_PuppiV15_switch,recoMetFromPFCs=True,reclusterJets=True)
if nanoAOD_PuppiV15_switch.reclusterJets:
from RecoJets.JetProducers.ak4PFJets_cfi import ak4PFJets
from PhysicsTools.PatAlgos.tools.helpers import getPatAlgosToolsTask, addToProcessAndTask
task = getPatAlgosToolsTask(process)
addToProcessAndTask('ak4PuppiJets', ak4PFJets.clone (src = 'puppi', doAreaFastjet = True, jetPtMin = 10.), process, task)
from PhysicsTools.PatAlgos.tools.jetTools import addJetCollection
addJetCollection(process,
labelName = 'Puppi',
jetSource = cms.InputTag('ak4PuppiJets'),
algo = 'AK', rParam=0.4,
genJetCollection=cms.InputTag('slimmedGenJets'),
jetCorrections = ('AK4PFPuppi', ['L1FastJet', 'L2Relative', 'L3Absolute','L2L3Residual'], 'None'),
pfCandidates = cms.InputTag('packedPFCandidates'),
pvSource = cms.InputTag('offlineSlimmedPrimaryVertices'),
svSource = cms.InputTag('slimmedSecondaryVertices'),
muSource =cms.InputTag( 'slimmedMuons'),
elSource = cms.InputTag('slimmedElectrons'),
genParticles= cms.InputTag('prunedGenParticles'),
getJetMCFlavour= False
)
process.patJetsPuppi.addGenPartonMatch = cms.bool(False)
process.patJetsPuppi.addGenJetMatch = cms.bool(False)
print("nanoAOD_PuppiV15_switch.reclusterJets is true")
runMetCorAndUncFromMiniAOD(process,isData=isData,metType="Puppi",postfix="Puppi",jetFlavor="AK4PFPuppi", recoMetFromPFCs=bool(nanoAOD_PuppiV15_switch.recoMetFromPFCs), reclusterJets=bool(nanoAOD_PuppiV15_switch.reclusterJets))
process.nanoSequenceCommon.insert(2,cms.Sequence(process.puppiMETSequence+process.fullPatMetSequencePuppi))
return process
### Removing the HF from the MET computation as from 7 Aug 2015 recommendations
### ---------------------------------------------------------------------------
if options.useNoHFMET:
process.noHFCands = cms.EDFilter("CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0")
)
#jets are rebuilt from those candidates by the tools, no need to do anything else
### =================================================================================
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#For a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(process,
isData=("Data" in options.DataProcessing),
)
if options.useNoHFMET:
runMetCorAndUncFromMiniAOD(process,
isData=("Data" in options.DataProcessing),
pfCandColl=cms.InputTag("noHFCands"),
recoMetFromPFCs=True,
reclusterJets=True,
postfix="NoHF"
)
jLabelNoHF = 'patJetsNoHF'
### -------------------------------------------------------------------
### the lines below remove the L2L3 residual corrections when processing data
### -------------------------------------------------------------------
egmCorrectionSequence = cms.Sequence(
process.selectedElectrons +
process.smearedElectrons +
process.smearedPhotons
)
### Vanilla MET
# this is the most basic MET one can find
# even if we override with various types of MET later on, create this so we have a consistent calo MET
# https://twiki.cern.ch/twiki/bin/view/CMS/MissingETUncertaintyPrescription
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData = options.isData,
)
metSequence = cms.Sequence(
process.fullPatMetSequence
)
### PUPPI
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
## Creates process.puppiMETSequence which includes 'puppi' and 'puppiForMET' (= EDProducer('PuppiPhoton'))
## By default, does not use specific photon ID for PuppiPhoton (which was the case in 80X)
makePuppiesFromMiniAOD(process, createScheduledSequence = True)
## Just renaming
puppiSequence = process.puppiMETSequence
process.puppiNoLep.useExistingWeights = False
process.puppi.useExistingWeights = False
)
process.es_prefer_jer = cms.ESPrefer('PoolDBESSource', 'jer')
process.cleanedMu = cms.EDProducer("PATMuonCleanerBySegments",
src = cms.InputTag("slimmedMuons"),
preselection = cms.string("track.isNonnull"),
passthrough = cms.string("isGlobalMuon && numberOfMatches >= 2"),
fractionOfSharedSegments = cms.double(0.499))
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(process,
isData=False,
)
process.load('EgammaAnalysis.ElectronTools.regressionApplication_cff')
from EgammaAnalysis.ElectronTools.regressionWeights_cfi import regressionWeights
process = regressionWeights(process)
process.load('EgammaAnalysis.ElectronTools.calibratedElectronsRun2_cfi')
process.demo = cms.EDAnalyzer('ntuple_maker',
syscalcinfo = cms.untracked.bool (True), #fill the information from syscalc
mgreweightinfo = cms.untracked.bool (False),
vertices = cms.InputTag("offlineSlimmedPrimaryVertices"),
# muons = cms.InputTag("cleanedMu"),
lheevent = cms.InputTag("externalLHEProducer"),
egmCorrectionSequence = cms.Sequence(process.regressionElectrons +
process.regressionPhotons +
process.selectedElectrons +
process.smearedElectrons +
process.smearedPhotons)
### Vanilla MET
# this is the most basic MET one can find
# even if we override with various types of MET later on, create this so we have a consistent calo MET
# https://twiki.cern.ch/twiki/bin/view/CMS/MissingETUncertaintyPrescription
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
runMetCorAndUncFromMiniAOD(
process,
isData=options.isData,
)
metSequence = cms.Sequence(process.fullPatMetSequence)
### PUPPI
# TODO find PUPPI recipes, the following doesn't look right:
# https://twiki.cern.ch/twiki/bin/viewauth/CMS/PUPPI
# From PUPPI MET recipe in
# https://twiki.cern.ch/twiki/bin/view/CMS/MissingETUncertaintyPrescription
# 80X does not contain the latest & greatest PuppiPhoton; need to rerun for all config
from PhysicsTools.PatAlgos.slimming.puppiForMET_cff import makePuppiesFromMiniAOD
# Creates process.puppiMETSequence which includes 'puppi' and 'puppiForMET' (= EDProducer('PuppiPhoton'))
# *UGLY* also runs switchOnVIDPhotonIdProducer and sets up photon id Spring16_V2p2 internally
# which loads photonIDValueMapProducer and egmPhotonIDs
makePuppiesFromMiniAOD(process, createScheduledSequence=True)
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
if isData:
jecFile = cms.string('{0}/src/Analysis/ALPHA/data/{1}_DATA/{1}_DATA_Uncertainty_AK4PFchs.txt'.format(os.environ['CMSSW_BASE'], JECstring))
else:
jecFile = cms.string('{0}/src/Analysis/ALPHA/data/{1}_MC/{1}_MC_Uncertainty_AK4PFchs.txt'.format(os.environ['CMSSW_BASE'], JECstring))
runMetCorAndUncFromMiniAOD(process,
#metType="PF",
#correctionLevel=["T1","Smear"],
#computeUncertainties=True,
#produceIntermediateCorrections=False,
#addToPatDefaultSequence=False,
isData=isData,
#onMiniAOD=True,
#reapplyJEC=reapplyJEC,
#reclusterJets=reclusterJets,
#jetSelection=jetSelection,
#recoMetFromPFCs=recoMetFromPFCs,
#autoJetCleaning=jetCleaning,
#manualJetConfig=manualJetConfig,
#jetFlavor=jetFlavor,
#jetCorLabelUpToL3=jetCorLabelL3,
#jetCorLabelL3Res=jetCorLabelRes,
#jecUnFile=jecFile,
#CHS=CHS,
#postfix=postfix,
)
if isData:
filterString = "RECO"
else:
filterString = "PAT"
process.egmGsfElectronIDs.physicsObjectSrc = electronCollection
process.electronRegressionValueMapProducer.srcMiniAOD = electronCollection
process.electronMVAValueMapProducer.srcMiniAOD = electronCollection
#
# MET corrections and uncertainties
#
if options.recorrectMET:
# use the standard tool
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
# do not use a postfix here!
runMetCorAndUncFromMiniAOD(process,
isData=options.realData,
electronColl=electronCollection.value(),
muonColl=muonCollection.value(),
tauColl=tauCollection.value(),
photonColl=photonCollection.value(),
jetCollUnskimmed=jetCollection.value(),
recoMetFromPFCs=True)
# overwrite output collections
METCollection = cms.InputTag("slimmedMETs", "", process.name_())
# also add MET corrections due to e/g corrections, such as the slew rate fix in reMiniAOD
if options.realData:
from PhysicsTools.PatUtils.tools.corMETFromMuonAndEG import corMETFromMuonAndEG
corMETFromMuonAndEG(process,
pfCandCollection="",
electronCollection="slimmedElectronsBeforeGSFix",
photonCollection="slimmedPhotonsBeforeGSFix",
corElectronCollection=electronCollection.value(),
setupAllVIDIdsInModule(process,idmod,setupVIDPhotonSelection)
process.ggNtuplizer.doNoHFMET=cms.bool(doNoHFMet)
tellMETData = False
if doNoHFMet == True:
process.noHFCands = cms.EDFilter("CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0")
)
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#default configuration for miniAOD reprocessing, change the isData flag to run on data
#for a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(process,
isData=tellMETData,
pfCandColl=cms.InputTag("noHFCands"),
postfix="NoHF"
)
process.patPFMetT1T2CorrNoHF.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT1T2SmearCorrNoHF.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT2CorrNoHF.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT2SmearCorrNoHF.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.shiftedPatJetEnDownNoHF.jetCorrLabelUpToL3Res = cms.InputTag("ak4PFCHSL1FastL2L3Corrector")
process.shiftedPatJetEnUpNoHF.jetCorrLabelUpToL3Res = cms.InputTag("ak4PFCHSL1FastL2L3Corrector")
process.p = cms.Path(
###process.egmGsfElectronIDSequence
# process.mvaTrigV050nsCSA14
# + process.mvaTrigV025nsCSA14
# + process.mvaNonTrigV050nsCSA14
# + process.mvaNonTrigV025nsCSA14
### ---------------------------------------------------------------------------
if not useHFCandidates:
process.noHFCands = cms.EDFilter(
"CandPtrSelector",
src=cms.InputTag("packedPFCandidates"),
cut=cms.string("abs(pdgId)!=1 && abs(pdgId)!=2 && abs(eta)<3.0"))
#jets are rebuilt from those candidates by the tools, no need to do anything else
### =================================================================================
from PhysicsTools.PatUtils.tools.runMETCorrectionsAndUncertainties import runMetCorAndUncFromMiniAOD
#default configuration for miniAOD reprocessing, change the isData flag to run on data
#for a full met computation, remove the pfCandColl input
runMetCorAndUncFromMiniAOD(
process,
isData=runOnData,
)
if not useHFCandidates:
runMetCorAndUncFromMiniAOD(process,
isData=runOnData,
pfCandColl=cms.InputTag("noHFCands"),
postfix="NoHF")
### -------------------------------------------------------------------
### the lines below remove the L2L3 residual corrections when processing data
### -------------------------------------------------------------------
if not applyResiduals:
process.patPFMetT1T2Corr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT1T2SmearCorr.jetCorrLabelRes = cms.InputTag("L3Absolute")
process.patPFMetT2Corr.jetCorrLabelRes = cms.InputTag("L3Absolute")
