def listOfSteps(self,params) : _jet = params["objects"]["jet"] _muon = params["objects"]["muon"] _photon = params["objects"]["photon"] stepList = [ steps.progressPrinter(), steps.jetPtSelector(_jet,100.0,0), steps.leadingUnCorrJetPtSelector( [_jet],100.0 ), steps.hltFilter("HLT_Jet50U"), steps.vertexRequirementFilter(5.0,24.0), steps.techBitFilter([0],True), steps.physicsDeclared(), steps.monsterEventFilter(10,0.25), steps.hbheNoiseFilter(), steps.multiplicityFilter("%sIndices%s"%_jet, nMin = params["nJetsMinMax"][0], nMax = params["nJetsMinMax"][1]), steps.multiplicityFilter("%sIndicesOther%s"%_jet, nMax = 0), steps.variableGreaterFilter(350.0,"%sSumPt%s"%_jet), #steps.multiplicityFilter("%sIndices%s"%_photon, nMax = 0), steps.multiplicityFilter("%sIndices%s"%_muon, nMax = 0), steps.alphaTetaDependence(_jet) # signal distributions for {g,Z}x{forward,mid,central} ] return stepList
def listOfSteps(self,params) : _jet = params["objects"]["jet"] _electron = params["objects"]["electron"] _muon = params["objects"]["muon"] _photon = params["objects"]["photon"] _met = params["objects"]["met"] outList=[ steps.progressPrinter(), steps.histogrammer("genpthat",200,0,1000,title=";#hat{p_{T}} (GeV);events / bin"), steps.preIdJetPtSelector(_jet,100.0,0), steps.preIdJetPtSelector(_jet, 80.0,1), steps.leadingUnCorrJetPtSelector( [_jet],100.0 ), steps.hltFilter("HLT_Jet50U"), steps.vertexRequirementFilter(), steps.techBitFilter([0],True), steps.physicsDeclared(), steps.monsterEventFilter(), steps.hbheNoiseFilter(), steps.multiplicityFilter("%sIndices%s"%_photon, nMax = 0), steps.multiplicityFilter("%sIndices%s"%_electron, nMax = 0), steps.multiplicityFilter("%sIndices%s"%_muon, nMax = 0), steps.multiplicityFilter("%sIndicesUnmatched%s"%_electron, nMax = 0), steps.multiplicityFilter("%sIndicesUnmatched%s"%_photon, nMax = 0), steps.multiplicityFilter("%sIndicesOther%s"%_muon, nMax = 0), steps.uniquelyMatchedNonisoMuons(_jet), steps.singleJetHistogrammer(_jet), steps.histogrammer(_met,100,0.0,500.0,title=";"+_met+" (GeV);events / bin", funcString = "lambda x: x.pt()"), steps.histogrammer("%sSumP4%s"%_jet,100,0.0,500.0,title=";MHT (GeV);events / bin", funcString = "lambda x: x.pt()"), steps.multiplicityFilter("%sIndices%s"%_jet, nMin = params["nJetsMinMax"][0], nMax = params["nJetsMinMax"][1]), steps.multiplicityFilter("%sIndicesOther%s"%_jet, nMax = 0), steps.jetPtSelector(_jet,100.0,0), steps.jetEtaSelector(_jet,2.5,0), steps.jetPtSelector(_jet,80.0,1), steps.singleJetHistogrammer(_jet), steps.histogrammer(_met,100,0.0,500.0,title=";"+_met+" (GeV);events / bin", funcString = "lambda x: x.pt()"), steps.histogrammer("%sSumP4%s"%_jet,100,0.0,500.0,title=";MHT (GeV);events / bin", funcString = "lambda x: x.pt()"), steps.variableGreaterFilter(350.0,"%sSumEt%s"%_jet, suffix = "GeV"), steps.singleJetHistogrammer(_jet), steps.histogrammer(_met,100,0.0,500.0,title=";"+_met+" (GeV);events / bin", funcString = "lambda x: x.pt()"), steps.histogrammer("%sSumP4%s"%_jet,100,0.0,500.0,title=";MHT (GeV);events / bin", funcString = "lambda x: x.pt()"), steps.variablePtGreaterFilter(140.0,"%sSumP4%s"%_jet,"GeV"), steps.variableGreaterFilter(0.55,"%sAlphaT%s"%_jet), steps.singleJetHistogrammer(_jet), steps.histogrammer(_met,100,0.0,500.0,title=";"+_met+" (GeV);events / bin", funcString = "lambda x: x.pt()"), steps.histogrammer("%sSumP4%s"%_jet,100,0.0,500.0,title=";MHT (GeV);events / bin", funcString = "lambda x: x.pt()"), ] return outList
def listOfSteps(self,params) : _jet = params["objects"]["jet"] _electron = params["objects"]["electron"] _muon = params["objects"]["muon"] _photon = params["objects"]["photon"] _met = params["objects"]["met"] _etRatherThanPt = params["etRatherThanPt"] outList=[ steps.progressPrinter(), steps.hbheNoiseFilter(), steps.vertexRequirementFilter(), steps.techBitFilter([0],True), steps.physicsDeclared(), steps.monsterEventFilter(), steps.hltFilter("HLT_HT100U"), steps.histogrammer("%sIndicesOther%s"%_jet,10,-0.5,9.5, title=";number of %s%s above p_{T}#semicolon failing ID or #eta;events / bin"%_jet, funcString="lambda x:len(x)"), steps.multiplicityFilter("%sIndicesOther%s"%_jet, nMax = 0), steps.histogrammer("%sIndices%s"%_jet,10,-0.5,9.5, title=";number of %s%s passing ID#semicolon p_{T}#semicolon #eta cuts;events / bin"%_jet, funcString="lambda x:len(x)"), steps.multiplicityFilter("%sIndices%s"%_jet, nMin = params["nJetsMinMax"][0], nMax = params["nJetsMinMax"][1]), steps.preIdJetPtSelector(_jet,100.0,0), steps.jetEtaSelector(_jet,2.5,0), steps.preIdJetPtSelector(_jet,100.0,1), steps.variableGreaterFilter(350.0,"%sSumEt%s"%_jet, suffix = "GeV"), #steps.runLsEventFilter("tanjasEvents.txt"), #electron, muon, photon vetoes steps.multiplicityFilter("%sIndices%s"%_muon, nMax = 0), #steps.multiplicityFilter("%sIndicesOther%s"%_muon, nMax = 0), steps.multiplicityFilter("%sIndicesNonIso%s"%_muon, nMax = 0), steps.multiplicityFilter("%sIndices%s"%_electron, nMax = 0), #steps.multiplicityFilter("%sIndices%s"%_photon, nMax = 0), #steps.multiplicityFilter("%sIndicesUnmatched%s"%_electron, nMax = 0), #steps.multiplicityFilter("%sIndicesUnmatched%s"%_photon, nMax = 0), #steps.uniquelyMatchedNonisoMuons(_jet), ####many plots ###steps.passFilter("singleJetPlots1"), ###steps.singleJetHistogrammer(_jet), ###steps.passFilter("jetSumPlots1"), ###steps.cleanJetHtMhtHistogrammer(_jet,_etRatherThanPt), ###steps.histogrammer(_met,100,0.0,500.0,title=";"+_met+" (GeV);events / bin", funcString = "lambda x: x.pt()"), ###steps.passFilter("kinematicPlots1"), ###steps.alphaHistogrammer(_jet, _etRatherThanPt), ###steps.alphaMetHistogrammer(_jet, _etRatherThanPt, _met), ### ####signal selection ###steps.variablePtGreaterFilter(140.0,"%sSumP4%s"%_jet,"GeV"), steps.variableGreaterFilter(0.55,"%sAlphaT%s"%_jet), ###steps.histogrammer("mhtMinusMetOverMeff", 100, -1.0, 1.0, title = ";(MHT - PFMET)/(MHT+HT);events / bin"), ###steps.variableLessFilter(0.15,"mhtMinusMetOverMeff"), ###steps.deadEcalFilter(jets = _jet, dR = 0.3, dPhiStarCut = 0.5, nXtalThreshold = 5), #####steps.variableGreaterFilter(0.53,"%sAlphaTMet%s"%_jet), ### ####steps.skimmer(), ####steps.eventPrinter(), ####steps.jetPrinter(_jet), ####steps.particleP4Printer(_muon), ####steps.particleP4Printer(_photon), ####steps.recHitPrinter("clusterPF","Ecal"), ####steps.htMhtPrinter(_jet), ####steps.alphaTPrinter(_jet,_etRatherThanPt), ####steps.genParticlePrinter(minPt=10.0,minStatus=3), #### ####steps.displayer(jets = _jet, #### muons = _muon, #### met = params["objects"]["met"], #### electrons = params["objects"]["electron"], #### photons = params["objects"]["photon"], #### recHits = params["objects"]["rechit"],recHitPtThreshold=1.0,#GeV #### scale = 400.0,#GeV #### etRatherThanPt = _etRatherThanPt, #### ), ] return outList
def listOfSteps(self,params) : _jet = params["objects"]["jet"] _electron = params["objects"]["electron"] _muon = params["objects"]["muon"] _photon = params["objects"]["photon"] _met = params["objects"]["met"] _etRatherThanPt = params["etRatherThanPt"] outList=[ steps.progressPrinter(), steps.histogrammer("genpthat",200,0,1000,title=";#hat{p_{T}} (GeV);events / bin"), steps.preIdJetPtSelector(_jet,100.0,0), steps.preIdJetPtSelector(_jet, 80.0,1), steps.leadingUnCorrJetPtSelector( [_jet],100.0 ), steps.hltFilter("HLT_Jet50U"), steps.vertexRequirementFilter(), steps.techBitFilter([0],True), steps.physicsDeclared(), steps.monsterEventFilter(), steps.hbheNoiseFilter(), steps.hltPrescaleHistogrammer(["HLT_Jet50U","HLT_HT100U","HLT_MET45"]), steps.histogrammer("%sIndices%s"%_jet,10,-0.5,9.5, title=";number of %s%s passing ID#semicolon p_{T}#semicolon #eta cuts;events / bin"%_jet, funcString="lambda x:len(x)"), steps.multiplicityFilter("%sIndices%s"%_jet, nMin = params["nJetsMinMax"][0], nMax = params["nJetsMinMax"][1]), steps.histogrammer("%sIndicesOther%s"%_jet,10,-0.5,9.5, title=";number of %s%s above p_{T}#semicolon failing ID or #eta;events / bin"%_jet, funcString="lambda x:len(x)"), steps.multiplicityFilter("%sIndicesOther%s"%_jet, nMax = 0), #electron, muon, photon vetoes steps.histogrammer("%sIndices%s"%_electron,10,-0.5,9.5,title="; N electrons ;events / bin", funcString = "lambda x: len(x)"), steps.multiplicityFilter("%sIndices%s"%_electron, nMax = 0), steps.histogrammer("%sIndices%s"%_muon,10,-0.5,9.5,title="; N muons ;events / bin", funcString = "lambda x: len(x)"), steps.multiplicityFilter("%sIndices%s"%_muon, nMax = 0), steps.histogrammer("%sIndices%s"%_photon,10,-0.5,9.5,title="; N photons ;events / bin", funcString = "lambda x: len(x)"), steps.multiplicityFilter("%sIndices%s"%_photon, nMax = 0), #steps.histogrammer("%sIndicesUnmatched%s"%_electron,10,-0.5,9.5,title="; N electrons unmatched;events / bin", funcString = "lambda x: len(x)"), #steps.multiplicityFilter("%sIndicesUnmatched%s"%_electron, nMax = 0), #steps.histogrammer("%sIndicesUnmatched%s"%_photon,10,-0.5,9.5,title="; N photons unmatched;events / bin", funcString = "lambda x: len(x)"), #steps.multiplicityFilter("%sIndicesUnmatched%s"%_photon, nMax = 0), #steps.uniquelyMatchedNonisoMuons(_jet), steps.histogrammer("%sSumEt%s"%_jet,50,0,1500, title = ";H_{T} (GeV) from %s%s %s_{T}s;events / bin"%(_jet[0],_jet[1],"p" if not _etRatherThanPt else "E")), steps.variableGreaterFilter(350.0,"%sSumEt%s"%_jet, suffix = "GeV"), #many plots steps.passFilter("singleJetPlots1"), steps.singleJetHistogrammer(_jet), steps.passFilter("jetSumPlots1"), steps.cleanJetHtMhtHistogrammer(_jet,_etRatherThanPt), steps.histogrammer(_met,100,0.0,500.0,title=";"+_met+" (GeV);events / bin", funcString = "lambda x: x.pt()"), steps.passFilter("kinematicPlots1"), steps.alphaHistogrammer(_jet, _etRatherThanPt), ###extrapolation region ##steps.variableGreaterFilter(0.50,"%sAlphaT%s"%_jet), ## ###many plots (again) ##steps.passFilter("singleJetPlots2"), ##steps.cleanJetPtHistogrammer(_jet), ##steps.passFilter("jetSumPlots2"), ##steps.cleanJetHtMhtHistogrammer(_jet), ###steps.passFilter("kinematicPlots2"), ###steps.alphaHistogrammer(_jet), #signal selection steps.variablePtGreaterFilter(140.0,"%sSumP4%s"%_jet,"GeV"), steps.variableGreaterFilter(0.55,"%sAlphaT%s"%_jet), steps.ptRatioLessThanSelector(numVar = "%sSumP4%s"%_jet, denVar = "%sSumP4Low%s"%_jet, threshold = 1.25), steps.ptRatioHistogrammer(numVar = "%sSumP4%s"%_jet, denVar = "%sSumP4Low%s"%_jet), #steps.skimmer(), #steps.eventPrinter(), #steps.jetPrinter(_jet), #steps.htMhtPrinter(_jet), #steps.alphaTPrinter(_jet,_etRatherThanPt), #steps.genParticlePrinter(minPt=10.0,minStatus=3), #steps.displayer(jets = _jet, # muons = _muon, # met = params["objects"]["met"], # electrons = params["objects"]["electron"], # photons = params["objects"]["photon"], # recHits = params["objects"]["rechit"],recHitPtThreshold=1.0,#GeV # scale = 200.0),#GeV ] return outList
def listOfSteps(self,params) : _jet = params["objects"]["jet"] _electron = params["objects"]["electron"] _muon = params["objects"]["muon"] _photon = params["objects"]["photon"] _met = params["objects"]["met"] _etRatherThanPt = params["etRatherThanPt"] outList=[ supy.steps.printer.progressPrinter(), steps.histogrammer("genpthat",200,0,1000,title=";#hat{p_{T}} (GeV);events / bin"), steps.preIdJetPtSelector(_jet,100.0,0), steps.preIdJetPtSelector(_jet,100.0,1), steps.jetEtaSelector(_jet,2.5,0), steps.hltFilter("HLT_HT100U"), #steps.vertexRequirementFilter(), steps.techBitFilter([0],True), steps.physicsDeclared(), steps.monsterEventFilter(), steps.hbheNoiseFilter(), steps.histogrammer("vertexIndices", 10,-0.5,9.5, title = ";N good vertices;events / bin", funcString="lambda x:len(x)"), steps.multiplicityFilter("vertexIndices", nMin = 1), steps.histogrammer("vertexIndicesOther", 10,-0.5,9.5, title = ";N bad vertices;events / bin", funcString="lambda x:len(x)"), steps.multiplicityFilter("vertexIndicesOther", nMax = 0), steps.histogrammer("vertexIndices", 10,-0.5,9.5, title = ";N good vertices;events / bin", funcString="lambda x:len(x)"), steps.vertexHistogrammer(), #steps.hltPrescaleHistogrammer(["HLT_Jet50U","HLT_Jet70U","HLT_Jet100U","HLT_HT100U","HLT_HT120U","HLT_HT140U"]), #steps.iterHistogrammer("ecalDeadTowerTrigPrimP4", 256, 0.0, 128.0, title=";E_{T} of ECAL TP in each dead region (GeV);TPs / bin", # funcString="lambda x:x.Et()"), #steps.histogrammer("%sIndices%s"%_jet,10,-0.5,9.5, title=";number of %s%s passing ID#semicolon p_{T}#semicolon #eta cuts;events / bin"%_jet, funcString="lambda x:len(x)"), steps.multiplicityFilter("%sIndices%s"%_jet, nMin = params["nJetsMinMax"][0], nMax = params["nJetsMinMax"][1]), #steps.histogrammer("%sIndicesOther%s"%_jet,10,-0.5,9.5, title=";number of %s%s above p_{T}#semicolon failing ID or #eta;events / bin"%_jet, funcString="lambda x:len(x)"), steps.multiplicityFilter("%sIndicesOther%s"%_jet, nMax = 0), #electron, muon, photon vetoes #steps.histogrammer("%sIndices%s"%_electron,10,-0.5,9.5,title="; N electrons ;events / bin", funcString = "lambda x: len(x)"), steps.multiplicityFilter("%sIndices%s"%_electron, nMax = 0), #steps.histogrammer("%sIndices%s"%_muon,10,-0.5,9.5,title="; N muons ;events / bin", funcString = "lambda x: len(x)"), steps.multiplicityFilter("%sIndices%s"%_muon, nMax = 0), #steps.histogrammer("%sIndicesOther%s"%_muon,10,-0.5,9.5, title=";number of %s%s above p_{T}#semicolon failing ID or #eta;events / bin"%_muon,funcString="lambda x:len(x)"), steps.multiplicityFilter("%sIndicesOther%s"%_muon, nMax = 0), #steps.histogrammer("%sIndices%s"%_photon,10,-0.5,9.5,title="; N photons ;events / bin", funcString = "lambda x: len(x)"), steps.multiplicityFilter("%sIndices%s"%_photon, nMax = 0), #steps.histogrammer("%sIndicesUnmatched%s"%_electron,10,-0.5,9.5,title="; N electrons unmatched;events / bin", funcString = "lambda x: len(x)"), steps.multiplicityFilter("%sIndicesUnmatched%s"%_electron, nMax = 0), #steps.histogrammer("%sIndicesUnmatched%s"%_photon,10,-0.5,9.5,title="; N photons unmatched;events / bin", funcString = "lambda x: len(x)"), steps.multiplicityFilter("%sIndicesUnmatched%s"%_photon, nMax = 0), steps.uniquelyMatchedNonisoMuons(_jet), steps.histogrammer("%sSumEt%s"%_jet,50,0,1500, title = ";H_{T} (GeV) from %s%s %s_{T}s;events / bin"%(_jet[0],_jet[1],"p" if not _etRatherThanPt else "E")), steps.variableGreaterFilter(350.0,"%sSumEt%s"%_jet, suffix = "GeV"), steps.histogrammer("vertexIndices", 10,-0.5,9.5, title = ";N good vertices;events / bin", funcString="lambda x:len(x)"), steps.vertexHistogrammer(), #many plots #steps.passFilter("singleJetPlots1"), #steps.singleJetHistogrammer(_jet), #steps.passFilter("jetSumPlots1"), #steps.cleanJetHtMhtHistogrammer(_jet,_etRatherThanPt), #steps.histogrammer(_met,100,0.0,500.0,title=";"+_met+" (GeV);events / bin", funcString = "lambda x: x.pt()"), #steps.passFilter("kinematicPlots1"), #steps.alphaHistogrammer(_jet, _etRatherThanPt), #steps.alphaMetHistogrammer(_jet, _etRatherThanPt, _met), ###extrapolation region ##steps.variableGreaterFilter(0.50,"%sAlphaT%s"%_jet), ## ###many plots (again) ##steps.passFilter("singleJetPlots2"), ##steps.cleanJetPtHistogrammer(_jet), ##steps.passFilter("jetSumPlots2"), ##steps.cleanJetHtMhtHistogrammer(_jet), ###steps.passFilter("kinematicPlots2"), ###steps.alphaHistogrammer(_jet), #signal selection steps.variablePtGreaterFilter(140.0,"%sSumP4%s"%_jet,"GeV"), steps.variableGreaterFilter(0.5,"%sAlphaT%s"%_jet), steps.histogrammer("vertexIndices", 10,-0.5,9.5, title = ";N good vertices;events / bin", funcString="lambda x:len(x)"), steps.vertexHistogrammer(), steps.variableGreaterFilter(0.55,"%sAlphaT%s"%_jet), steps.histogrammer("vertexIndices", 10,-0.5,9.5, title = ";N good vertices;events / bin", funcString="lambda x:len(x)"), steps.vertexHistogrammer(), #steps.histogrammer("mhtMinusMetOverMeff", 100, -1.0, 1.0, title = ";(MHT - PFMET)/(MHT+HT);events / bin"), #steps.variableLessFilter(0.15,"mhtMinusMetOverMeff"), #steps.deadEcalFilter(jets = _jet, dR = 0.3, dPhiStarCut = 0.5, nXtalThreshold = 5), ##steps.variableGreaterFilter(0.53,"%sAlphaTMet%s"%_jet), #steps.skimmer(), #steps.eventPrinter(), #steps.jetPrinter(_jet), #steps.particleP4Printer(_muon), #steps.particleP4Printer(_photon), #steps.recHitPrinter("clusterPF","Ecal"), #steps.htMhtPrinter(_jet), #steps.alphaTPrinter(_jet,_etRatherThanPt), #steps.genParticlePrinter(minPt=10.0,minStatus=3), # #steps.displayer(jets = _jet, # muons = _muon, # met = params["objects"]["met"], # electrons = params["objects"]["electron"], # photons = params["objects"]["photon"], # recHits = params["objects"]["rechit"],recHitPtThreshold=1.0,#GeV # scale = 400.0,#GeV # etRatherThanPt = _etRatherThanPt, # ), ] return outList