EmDQM Class Reference

#include <EmDQM.h>

Inheritance diagram for EmDQM:

Public Member Functions
void	analyze (const edm::Event &event, const edm::EventSetup &) override
void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
void	dqmBeginRun (edm::Run const &, edm::EventSetup const &) override
	EmDQM (const edm::ParameterSet &pset)
	Constructor. More...
void	endRun (edm::Run const &, edm::EventSetup const &) override
	~EmDQM () override
	Destructor. More...
Public Member Functions inherited from one::DQMEDAnalyzer< T >
	DQMEDAnalyzer ()=default
	DQMEDAnalyzer (DQMEDAnalyzer< T... > const &)=delete
	DQMEDAnalyzer (DQMEDAnalyzer< T... > &&)=delete
	~DQMEDAnalyzer () override=default

Private Member Functions
bool	checkGeneratedParticlesRequirement (const edm::Event &event)
bool	checkRecoParticlesRequirement (const edm::Event &event)
int	countSubstring (const std::string &, const std::string &)
std::vector< std::vector< std::string > >	findEgammaPaths ()
std::vector< std::string >	getFilterModules (const std::string &)
double	getPrimaryEtCut (const std::string &)
edm::ParameterSet	makePSetForEgammaDoubleEtDeltaPhiFilter (const std::string &)
edm::ParameterSet	makePSetForEgammaGenericFilter (const std::string &)
edm::ParameterSet	makePSetForEgammaGenericQuadraticFilter (const std::string &)
edm::ParameterSet	makePSetForElectronGenericFilter (const std::string &)
edm::ParameterSet	makePSetForEtFilter (const std::string &)
edm::ParameterSet	makePSetForL1SeedFilter (const std::string &)
edm::ParameterSet	makePSetForL1SeedToSuperClusterMatchFilter (const std::string &)
edm::ParameterSet	makePSetForOneOEMinusOneOPFilter (const std::string &)
edm::ParameterSet	makePSetForPixelMatchFilter (const std::string &)
void	SetVarsFromPSet (std::vector< edm::ParameterSet >::iterator)

Private Attributes
bool	autoConfMode_
std::string	dirname_
double	eta2DMax_
std::vector< MonitorElement * >	etagens
std::vector< std::vector< MonitorElement * > >	etahistmatchs
std::vector< std::vector< MonitorElement * > >	etahists
double	etaMax_
std::vector< MonitorElement * >	etaphigens
std::vector< std::vector< MonitorElement * > >	etaphihistmatchs
std::vector< std::vector< MonitorElement * > >	etaphihists
std::vector< MonitorElement * >	etgens
std::vector< std::vector< MonitorElement * > >	ethistmatchs
std::vector< std::vector< MonitorElement * > >	ethists
unsigned int	gencut_
edm::EDGetTokenT< edm::View< reco::Candidate > >	gencutColl_fidDiGamma_token
edm::EDGetTokenT< edm::View< reco::Candidate > >	gencutColl_fidGammaJet_token
edm::EDGetTokenT< edm::View< reco::Candidate > >	gencutColl_fidTripleEle_token
edm::EDGetTokenT< edm::View< reco::Candidate > >	gencutColl_fidWenu_token
edm::EDGetTokenT< edm::View< reco::Candidate > >	gencutColl_fidZee_token
edm::EDGetTokenT< edm::View< reco::Candidate > >	gencutColl_manualConf_token
edm::InputTag	gencutCollection_
double	genEtaAcc_
double	genEtAcc_
edm::EDGetTokenT< edm::View< reco::Candidate > >	genParticles_token
std::vector< std::vector< MonitorElement * > >	histEtaOfHltObjMatchToGens
std::vector< std::vector< MonitorElement * > >	histEtaPhiOfHltObjMatchToGens
std::vector< std::vector< MonitorElement * > >	histEtOfHltObjMatchToGens
HistoFiller< reco::RecoEcalCandidateCollection > *	histoFillerClu
HistoFiller< reco::ElectronCollection > *	histoFillerEle
HistoFiller< l1extra::L1EmParticleCollection > *	histoFillerL1Iso
HistoFiller< l1extra::L1EmParticleCollection > *	histoFillerL1NonIso
HistoFiller< reco::RecoEcalCandidateCollection > *	histoFillerPho
std::vector< std::vector< MonitorElement * > >	histPhiOfHltObjMatchToGens
std::set< std::string >	hltCollectionLabelsFound
std::vector< std::set< std::string > >	hltCollectionLabelsFoundPerPath
std::set< std::string >	hltCollectionLabelsMissed
std::vector< std::set< std::string > >	hltCollectionLabelsMissedPerPath
HLTConfigProvider	hltConfig_
	The instance of the HLTConfigProvider as a data member. More...
edm::EDGetTokenT< edm::TriggerResults >	hltResults_token
bool	isData_
std::vector< std::vector< edm::InputTag > >	isoNames
bool	mcMatchedOnly_
unsigned int	minEtForEtaEffPlot_
unsigned int	nbins2D_
unsigned int	nbins_
std::vector< unsigned int >	nCandCuts
bool	noIsolationPlots_
bool	noPhiPlots_
unsigned int	numOfHLTCollectionLabels
std::vector< edm::ParameterSet >	paramSets
unsigned int	pathIndex
int	pdgGen
double	phi2DMax_
std::vector< MonitorElement * >	phigens
std::vector< std::vector< MonitorElement * > >	phihistmatchs
std::vector< std::vector< MonitorElement * > >	phihists
double	phiMax_
std::vector< std::pair< double, double > >	plotBounds
double	plotEtMin
std::vector< bool >	plotiso
double	plotPtMax
double	plotPtMin
const edm::ParameterSet &	pset
GreaterByPt< reco::Particle >	pTComparator_
GreaterByPt< reco::GenParticle >	pTGenComparator_
double	ptMax_
double	ptMin_
unsigned int	reqNum
std::vector< std::string >	theHLTCollectionHumanNames
std::vector< edm::InputTag >	theHLTCollectionLabels
std::vector< int >	theHLTOutputTypes
edm::InputTag	theL1Seed
std::vector< MonitorElement * >	totalmatchs
std::vector< MonitorElement * >	totals
edm::InputTag	triggerObject_
edm::EDGetTokenT< trigger::TriggerEventWithRefs >	triggerObject_token
bool	useHumanReadableHistTitles_
unsigned int	verbosity_

Static Private Attributes
static const unsigned	OUTPUT_ALL = 3
static const unsigned	OUTPUT_ERRORS = 1
static const unsigned	OUTPUT_SILENT = 0
static const unsigned	OUTPUT_WARNINGS = 2
static const unsigned	TYPE_DOUBLE_ELE = 1
static const unsigned	TYPE_DOUBLE_PHOTON = 3
static const unsigned	TYPE_SINGLE_ELE = 0
static const unsigned	TYPE_SINGLE_PHOTON = 2
static const unsigned	TYPE_TRIPLE_ELE = 4

Friends
class	HistoFiller< l1extra::L1EmParticleCollection >
class	HistoFiller< reco::ElectronCollection >
class	HistoFiller< reco::RecoEcalCandidateCollection >

Detailed Description

Definition at line 63 of file EmDQM.h.

Constructor & Destructor Documentation

EmDQM::EmDQM ( const edm::ParameterSet &  pset )

explicit

Constructor.

Definition at line 12 of file EmDQM.cc.

References autoConfMode_, eta2DMax_, etaMax_, gencutColl_fidDiGamma_token, gencutColl_fidGammaJet_token, gencutColl_fidTripleEle_token, gencutColl_fidWenu_token, gencutColl_fidZee_token, gencutColl_manualConf_token, genEtaAcc_, genEtAcc_, genParticles_token, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), histoFillerClu, histoFillerEle, histoFillerL1Iso, histoFillerL1NonIso, histoFillerPho, hltResults_token, isData_, mcMatchedOnly_, minEtForEtaEffPlot_, nbins2D_, nbins_, noIsolationPlots_, noPhiPlots_, paramSets, phi2DMax_, phiMax_, pset, ptMax_, ptMin_, triggerObject_, triggerObject_token, useHumanReadableHistTitles_, and verbosity_.

                                         : pset(pset_) 
{
  // are we running in automatic configuration mode with the HLTConfigProvider
  // or with a per path python config file
  autoConfMode_ = pset.getUntrackedParameter<bool>("autoConfMode", false);

  // set global parameters
  triggerObject_ = pset_.getParameter<edm::InputTag>("triggerobject");
  verbosity_ = pset_.getUntrackedParameter<unsigned int>("verbosity",0);
  genEtaAcc_ = pset.getParameter<double>("genEtaAcc");
  genEtAcc_ = pset.getParameter<double>("genEtAcc");
  ptMax_ = pset.getUntrackedParameter<double>("PtMax",1000.);
  ptMin_ = pset.getUntrackedParameter<double>("PtMin",0.);
  etaMax_ = pset.getUntrackedParameter<double>("EtaMax", 2.7);
  phiMax_ = pset.getUntrackedParameter<double>("PhiMax", 3.15);
  nbins_ = pset.getUntrackedParameter<unsigned int>("Nbins",40);
  eta2DMax_ = pset.getUntrackedParameter<double>("Eta2DMax", 2.8);
  phi2DMax_ = pset.getUntrackedParameter<double>("Phi2DMax", 3.2);
  nbins2D_ = pset.getUntrackedParameter<unsigned int>("Nbins2D",16);
  minEtForEtaEffPlot_ = pset.getUntrackedParameter<unsigned int>("minEtForEtaEffPlot", 15);
  useHumanReadableHistTitles_ = pset.getUntrackedParameter<bool>("useHumanReadableHistTitles", false);
  mcMatchedOnly_ = pset.getUntrackedParameter<bool>("mcMatchedOnly", true);
  noPhiPlots_ = pset.getUntrackedParameter<bool>("noPhiPlots", true);
  noIsolationPlots_ = pset.getUntrackedParameter<bool>("noIsolationPlots", true);

  if (!autoConfMode_) {
    paramSets.push_back(pset);
    isData_ = false;
  } else {
    isData_ = pset.getParameter<bool>("isData");
  }

  histoFillerEle      = new HistoFiller<reco::ElectronCollection>(this);
  histoFillerPho      = new HistoFiller<reco::RecoEcalCandidateCollection>(this);
  histoFillerClu      = new HistoFiller<reco::RecoEcalCandidateCollection>(this);
  histoFillerL1Iso    = new HistoFiller<l1extra::L1EmParticleCollection>(this);
  histoFillerL1NonIso = new HistoFiller<l1extra::L1EmParticleCollection>(this);

  // consumes
  genParticles_token = consumes<edm::View<reco::Candidate> >(edm::InputTag("genParticles"));
  triggerObject_token = consumes<trigger::TriggerEventWithRefs>(triggerObject_);
  hltResults_token = consumes<edm::TriggerResults>(edm::InputTag("TriggerResults", "", triggerObject_.process()));
  if (autoConfMode_) {
    gencutColl_fidWenu_token = mayConsume<edm::View<reco::Candidate> >(edm::InputTag("fiducialWenu"));
    gencutColl_fidZee_token = mayConsume<edm::View<reco::Candidate> >(edm::InputTag("fiducialZee"));
    gencutColl_fidTripleEle_token = mayConsume<edm::View<reco::Candidate> >(edm::InputTag("fiducialTripleEle"));
    gencutColl_fidGammaJet_token = mayConsume<edm::View<reco::Candidate> >(edm::InputTag("fiducialGammaJet"));
    gencutColl_fidDiGamma_token = mayConsume<edm::View<reco::Candidate> >(edm::InputTag("fiducialDiGamma"));
  } else {
    gencutColl_manualConf_token = consumes<edm::View<reco::Candidate> >(pset.getParameter<edm::InputTag>("cutcollection"));
  }
}

EmDQM::~EmDQM ( )

override

Destructor.

Definition at line 607 of file EmDQM.cc.

             {
}

Member Function Documentation

void EmDQM::analyze ( const edm::Event &  event, const edm::EventSetup &  setup  )

override

Definition at line 729 of file EmDQM.cc.

References autoConfMode_, checkGeneratedParticlesRequirement(), checkRecoParticlesRequirement(), stringResolutionProvider_cfi::et, PVValHelper::eta, etagens, etaphigens, etgens, HistoFiller< T >::fillHistos(), gencut_, gencutColl_fidDiGamma_token, gencutColl_fidGammaJet_token, gencutColl_fidTripleEle_token, gencutColl_fidWenu_token, gencutColl_fidZee_token, gencutColl_manualConf_token, histoFillerClu, histoFillerEle, histoFillerL1Iso, histoFillerL1NonIso, histoFillerPho, hltCollectionLabelsFound, hltCollectionLabelsFoundPerPath, hltCollectionLabelsMissed, hltCollectionLabelsMissedPerPath, hltConfig_, SelectingProcedure_cff::hltResults, hltResults_token, mps_fire::i, edm::HLTGlobalStatus::index(), createfilelist::int, edm::EventBase::isRealData(), edm::HandleBase::isValid(), mcMatchedOnly_, minEtForEtaEffPlot_, HLTConfigProvider::moduleIndex(), gen::n, nCandCuts, noPhiPlots_, numOfHLTCollectionLabels, OUTPUT_ERRORS, OUTPUT_WARNINGS, paramSets, pathIndex, pdgGen, phi, phigens, plotEtMin, pTComparator_, reqNum, SetVarsFromPSet(), theHLTCollectionLabels, theHLTOutputTypes, totalmatchs, totals, trigger::TriggerCluster, trigger::TriggerElectron, trigger::TriggerL1IsoEG, trigger::TriggerL1NoIsoEG, triggerObject_, triggerObject_token, trigger::TriggerPhoton, and verbosity_.

{
  // loop over all the trigger path parameter sets
  unsigned int vPos = 0;
  for (std::vector<edm::ParameterSet>::iterator psetIt = paramSets.begin(); psetIt != paramSets.end(); ++psetIt, ++vPos) {
    SetVarsFromPSet(psetIt);
    // get the set forthe current path
    hltCollectionLabelsFound = hltCollectionLabelsFoundPerPath.at(vPos);
    hltCollectionLabelsMissed = hltCollectionLabelsMissedPerPath.at(vPos);

    //           Check if there's enough gen particles        //
    //             of interest                                //
    // get the right data according to the trigger path currently looked at
    edm::Handle< edm::View<reco::Candidate> > cutCounter;
    if (autoConfMode_) {
      switch(reqNum) {
         case 1:
            if (pdgGen == 11) event.getByToken(gencutColl_fidWenu_token, cutCounter);
            else event.getByToken(gencutColl_fidGammaJet_token, cutCounter);
            break;
         case 2:
            if (pdgGen == 11) event.getByToken(gencutColl_fidZee_token, cutCounter);
            else event.getByToken(gencutColl_fidDiGamma_token, cutCounter);
            break;
         case 3:
            event.getByToken(gencutColl_fidTripleEle_token, cutCounter);
            break;
      }
    } else {
      event.getByToken(gencutColl_manualConf_token, cutCounter);
    }
    if (cutCounter->size() < (unsigned int)gencut_) {
      //edm::LogWarning("EmDQM") << "Less than "<< gencut_ <<" gen particles with pdgId=" << pdgGen;
      continue;
    }

    // fill L1 and HLT info
    // get objects possed by each filter
    edm::Handle<trigger::TriggerEventWithRefs> triggerObj;
    event.getByToken(triggerObject_token,triggerObj);
    if(!triggerObj.isValid()) {
      if (verbosity_ >= OUTPUT_WARNINGS)
         edm::LogWarning("EmDQM") << "parameter triggerobject (" << triggerObject_ << ") does not corresond to a valid TriggerEventWithRefs product. Please check especially the process name (e.g. when running over reprocessed datasets)";
      continue;
    }

    // Were enough high energy gen particles found?
    if (event.isRealData()) {
      // running validation on data.
      // TODO: we should check that the entire
      //       run is on the same type (all data or
      //       all MC). Otherwise one gets
      //       uninterpretable results...
      if (!checkRecoParticlesRequirement(event))
        continue;
    }
    else { // MC
      // if no, throw event away
      if (!checkGeneratedParticlesRequirement(event))
        continue;
    }

    // It was an event worth keeping. Continue.

    //  Fill the bin labeled "Total"                          //
    //   This will be the number of events looked at.         //
    if (!mcMatchedOnly_) totals.at(vPos)->Fill(numOfHLTCollectionLabels+0.5);
    totalmatchs.at(vPos)->Fill(numOfHLTCollectionLabels+0.5);

    //               Fill generator info                      //
    // the gencut_ highest Et generator objects of the preselected type are our matches

    std::vector<reco::Particle> sortedGen;
    for(edm::View<reco::Candidate>::const_iterator genpart = cutCounter->begin(); genpart != cutCounter->end();genpart++){
      reco::Particle tmpcand(  genpart->charge(), genpart->p4(), genpart->vertex(),genpart->pdgId(),genpart->status() );
      if (tmpcand.et() >= plotEtMin) {
        sortedGen.push_back(tmpcand);
      }
    }
    std::sort(sortedGen.begin(),sortedGen.end(),pTComparator_ );

    // Now the collection of gen particles is sorted by pt.
    // So, remove all particles from the collection so that we 
    // only have the top "1 thru gencut_" particles in it
    if (sortedGen.size() < gencut_){
      continue;
    }
    sortedGen.erase(sortedGen.begin()+gencut_,sortedGen.end());

    for (unsigned int i = 0 ; i < gencut_ ; i++ ) {
      etgens.at(vPos)->Fill( sortedGen[i].et()  ); //validity has been implicitily checked by the cut on gencut_ above
      if (sortedGen[i].et() > minEtForEtaEffPlot_) {
        etagens.at(vPos)->Fill( sortedGen[i].eta() );
        if (!noPhiPlots_) phigens.at(vPos)->Fill( sortedGen[i].phi() );
         etaphigens.at(vPos)->Fill( sortedGen[i].eta(),sortedGen[i].phi() );
      }
    } // END of loop over Generated particles
    if (gencut_ >= reqNum && !mcMatchedOnly_) totals.at(vPos)->Fill(numOfHLTCollectionLabels+1.5); // this isn't really needed anymore keep for backward comp.
    if (gencut_ >= reqNum) totalmatchs.at(vPos)->Fill(numOfHLTCollectionLabels+1.5); // this isn't really needed anymore keep for backward comp.
            
    bool accepted = true;  // flags that the event has been accepted by all filters before
    edm::Handle<edm::TriggerResults> hltResults;
    event.getByToken(hltResults_token, hltResults);
    //            Loop over filter modules                    //
    for(unsigned int n=0; n < numOfHLTCollectionLabels ; n++) {
      // check that there are not less sortedGen particles than nCandCut requires for this filter
      if (sortedGen.size() < nCandCuts.at(n)) {
         if (verbosity_ >= OUTPUT_ERRORS)
            edm::LogError("EmDQM") << "There are less generated particles than the module '" << theHLTCollectionLabels[n].label() << "' requires.";
         continue;
      }
      std::vector<reco::Particle> sortedGenForFilter(sortedGen);
      sortedGenForFilter.erase(sortedGenForFilter.begin() + nCandCuts.at(n), sortedGenForFilter.end());

      // Fill only if this filter was run.
      if (pathIndex != 0 && hltConfig_.moduleIndex(pathIndex, theHLTCollectionLabels[n].label()) > hltResults->index(pathIndex)) break;
      // These numbers are from the Parameter Set, such as:
      //   theHLTOutputTypes = cms.uint32(100)
      switch(theHLTOutputTypes[n]) 
      {
        case trigger::TriggerL1NoIsoEG: // Non-isolated Level 1
          histoFillerL1NonIso->fillHistos(triggerObj,event,vPos,n,sortedGenForFilter,accepted);
          break;
        case trigger::TriggerL1IsoEG: // Isolated Level 1
          histoFillerL1Iso->fillHistos(triggerObj,event,vPos,n,sortedGenForFilter,accepted);
          break;
        case trigger::TriggerPhoton: // Photon 
          histoFillerPho->fillHistos(triggerObj,event,vPos,n,sortedGenForFilter,accepted);
          break;
        case trigger::TriggerElectron: // Electron 
          histoFillerEle->fillHistos(triggerObj,event,vPos,n,sortedGenForFilter,accepted);
          break;
        case trigger::TriggerCluster: // TriggerCluster
          histoFillerClu->fillHistos(triggerObj,event,vPos,n,sortedGenForFilter,accepted);
          break;
        default: 
          throw(cms::Exception("Release Validation Error") << "HLT output type not implemented: theHLTOutputTypes[n]" );
      }
    } // END of loop over filter modules

    // earse the dummy and fill with real set
    hltCollectionLabelsFoundPerPath.at(vPos) = hltCollectionLabelsFound;
    hltCollectionLabelsMissedPerPath.at(vPos) = hltCollectionLabelsMissed;
  }
}

void EmDQM::bookHistograms ( DQMStore::IBooker &  iBooker, edm::Run const &  iRun, edm::EventSetup const &  iSetup  )

override

Definition at line 390 of file EmDQM.cc.

References DQMStore::IBooker::book1D(), DQMStore::IBooker::book2D(), dirname_, eta2DMax_, etagens, etahistmatchs, etahists, etaMax_, etaphigens, etaphihistmatchs, etaphihists, etgens, ethistmatchs, ethists, histEtaOfHltObjMatchToGens, histEtaPhiOfHltObjMatchToGens, histEtOfHltObjMatchToGens, histPhiOfHltObjMatchToGens, mps_fire::i, label, mcMatchedOnly_, nbins2D_, nbins_, noPhiPlots_, numOfHLTCollectionLabels, paramSets, pdgGen, phi2DMax_, phigens, phihistmatchs, phihists, phiMax_, plotPtMax, plotPtMin, MonitorElement::setBinLabel(), DQMStore::IBooker::setCurrentFolder(), SetVarsFromPSet(), AlCaHLTBitMon_QueryRunRegistry::string, theHLTCollectionHumanNames, theHLTCollectionLabels, pileupDistInMC::total, totalmatchs, totals, and useHumanReadableHistTitles_.

{
   // loop over all the trigger path parameter sets
   for (std::vector<edm::ParameterSet>::iterator psetIt = paramSets.begin(); psetIt != paramSets.end(); ++psetIt) {
      SetVarsFromPSet(psetIt);

      iBooker.setCurrentFolder(dirname_);
    
      //  Set up Histogram of Effiency vs Step.                 //
      //   theHLTCollectionLabels is a vector of InputTags      //
      //    from the configuration file.                        //
      // Et & eta distributions
      std::vector<MonitorElement*> etahist;
      std::vector<MonitorElement*> phihist;
      std::vector<MonitorElement*> ethist;
      std::vector<MonitorElement*> etahistmatch;
      std::vector<MonitorElement*> phihistmatch;
      std::vector<MonitorElement*> ethistmatch;
      std::vector<MonitorElement*> histEtOfHltObjMatchToGen;
      std::vector<MonitorElement*> histEtaOfHltObjMatchToGen;
      std::vector<MonitorElement*> histPhiOfHltObjMatchToGen;
      std::vector<MonitorElement*> etaphihist;
      std::vector<MonitorElement*> etaphihistmatch;
      std::vector<MonitorElement*> histEtaPhiOfHltObjMatchToGen; 
      // Plots of efficiency per step
      MonitorElement* total;
      MonitorElement* totalmatch;
      //generator histograms
      MonitorElement* etgen;
      MonitorElement* etagen;
      MonitorElement* phigen;
      MonitorElement* etaphigen;
 
      std::string histName="total_eff";
      std::string histTitle = "total events passing";
      if (!mcMatchedOnly_) {
         // This plot will have bins equal to 2+(number of
         //        HLTCollectionLabels in the config file)
         total = iBooker.book1D(histName.c_str(),histTitle.c_str(),numOfHLTCollectionLabels+2,0,numOfHLTCollectionLabels+2);
         total->setBinLabel(numOfHLTCollectionLabels+1,"Total");
         total->setBinLabel(numOfHLTCollectionLabels+2,"Gen");
         for (unsigned int u=0; u<numOfHLTCollectionLabels; u++) {
            total->setBinLabel(u+1,theHLTCollectionLabels[u].label());
         }
      }
    
      histName="total_eff_MC_matched";
      histTitle="total events passing (mc matched)";
      totalmatch = iBooker.book1D(histName.c_str(),histTitle.c_str(),numOfHLTCollectionLabels+2,0,numOfHLTCollectionLabels+2);
      totalmatch->setBinLabel(numOfHLTCollectionLabels+1,"Total");
      totalmatch->setBinLabel(numOfHLTCollectionLabels+2,"Gen");
      for (unsigned int u=0; u<numOfHLTCollectionLabels; u++) {
         totalmatch->setBinLabel(u+1,theHLTCollectionLabels[u].label());
      }
    
      MonitorElement* tmphisto;
      //MonitorElement* tmpiso;
    
      // Set up generator-level histograms                      //
      std::string pdgIdString;
      switch(pdgGen) {
      case 11:
        pdgIdString="Electron";break;
      case 22:
        pdgIdString="Photon";break;
      default:
        pdgIdString="Particle";
      }
    
      histName = "gen_et";
      histTitle= "E_{T} of " + pdgIdString + "s" ;
      etgen =  iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,plotPtMin,plotPtMax);
      histName = "gen_eta";
      histTitle= "#eta of "+ pdgIdString +"s " ;
      etagen = iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,-etaMax_, etaMax_);
      histName = "gen_phi";
      histTitle= "#phi of "+ pdgIdString +"s " ;
      if (!noPhiPlots_) phigen = iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,-phiMax_, phiMax_);
      histName = "gen_etaphi";
      histTitle= "#eta-#phi of "+ pdgIdString +"s " ;
      etaphigen = iBooker.book2D(histName.c_str(),histTitle.c_str(), nbins2D_-2,-eta2DMax_, eta2DMax_,nbins2D_,-phi2DMax_, phi2DMax_); 
      //  Set up histograms of HLT objects                      //
      // Determine what strings to use for histogram titles
      std::vector<std::string> HltHistTitle;
      if ( theHLTCollectionHumanNames.size() == numOfHLTCollectionLabels && useHumanReadableHistTitles_ ) {
        HltHistTitle = theHLTCollectionHumanNames;
      } else {
        for (unsigned int i =0; i < numOfHLTCollectionLabels; i++) {
          HltHistTitle.push_back(theHLTCollectionLabels[i].label());
        }
      }
     
      for(unsigned int i = 0; i< numOfHLTCollectionLabels ; i++){
        if (!mcMatchedOnly_) {
           // Et distribution of HLT objects passing filter i
           histName = theHLTCollectionLabels[i].label()+"et_all";
           histTitle = HltHistTitle[i]+" Et (ALL)";
           tmphisto =  iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,plotPtMin,plotPtMax);
           ethist.push_back(tmphisto);
           
           // Eta distribution of HLT objects passing filter i
           histName = theHLTCollectionLabels[i].label()+"eta_all";
           histTitle = HltHistTitle[i]+" #eta (ALL)";
           tmphisto =  iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,-etaMax_, etaMax_);
           etahist.push_back(tmphisto);          

           if (!noPhiPlots_) {
             // Phi distribution of HLT objects passing filter i
             histName = theHLTCollectionLabels[i].label()+"phi_all";
             histTitle = HltHistTitle[i]+" #phi (ALL)";
             tmphisto =  iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,-phiMax_, phiMax_);
             phihist.push_back(tmphisto);
           }
    
           histName = theHLTCollectionLabels[i].label()+"etaphi_all";
           histTitle = HltHistTitle[i]+" #eta-#phi (ALL)";
           tmphisto =  iBooker.book2D(histName.c_str(),histTitle.c_str(),nbins2D_-2,-eta2DMax_, eta2DMax_,nbins2D_,-phi2DMax_, phi2DMax_);
           etaphihist.push_back(tmphisto);

   
           // Et distribution of HLT object that is closest delta-R match to sorted gen particle(s)
           histName  = theHLTCollectionLabels[i].label()+"et";
           histTitle = HltHistTitle[i]+" Et";
           tmphisto  = iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,plotPtMin,plotPtMax);
           histEtOfHltObjMatchToGen.push_back(tmphisto);
    
           // eta distribution of HLT object that is closest delta-R match to sorted gen particle(s)
           histName  = theHLTCollectionLabels[i].label()+"eta";
           histTitle = HltHistTitle[i]+" eta";
           tmphisto  = iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,-etaMax_, etaMax_);
           histEtaOfHltObjMatchToGen.push_back(tmphisto);
    
           if (!noPhiPlots_) {
             // phi distribution of HLT object that is closest delta-R match to sorted gen particle(s)
             histName  = theHLTCollectionLabels[i].label()+"phi";
             histTitle = HltHistTitle[i]+" phi";
             tmphisto  = iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,-phiMax_, phiMax_);
             histPhiOfHltObjMatchToGen.push_back(tmphisto);
           }

           histName  = theHLTCollectionLabels[i].label()+"etaphi";
           histTitle = HltHistTitle[i]+" eta-phi";
           tmphisto  = iBooker.book2D(histName.c_str(),histTitle.c_str(),nbins2D_-2,-eta2DMax_, eta2DMax_,nbins2D_,-phi2DMax_, phi2DMax_);
           histEtaPhiOfHltObjMatchToGen.push_back(tmphisto);
       }
    
        // Et distribution of gen object matching HLT object passing filter i
        histName = theHLTCollectionLabels[i].label()+"et_MC_matched";
        histTitle = HltHistTitle[i]+" Et (MC matched)";
        tmphisto =  iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,plotPtMin,plotPtMax);
        ethistmatch.push_back(tmphisto);
        
        // Eta distribution of gen object matching HLT object passing filter i
        histName = theHLTCollectionLabels[i].label()+"eta_MC_matched";
        histTitle = HltHistTitle[i]+" #eta (MC matched)";
        tmphisto =  iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,-etaMax_, etaMax_);
        etahistmatch.push_back(tmphisto);
    
        if (!noPhiPlots_) {
          // Phi distribution of gen object matching HLT object passing filter i
          histName = theHLTCollectionLabels[i].label()+"phi_MC_matched";
          histTitle = HltHistTitle[i]+" #phi (MC matched)";
          tmphisto =  iBooker.book1D(histName.c_str(),histTitle.c_str(),nbins_,-phiMax_, phiMax_);
          phihistmatch.push_back(tmphisto);
        }

        histName = theHLTCollectionLabels[i].label()+"etaphi_MC_matched";
        histTitle = HltHistTitle[i]+" #eta-#phi (MC matched)";
        tmphisto =  iBooker.book2D(histName.c_str(),histTitle.c_str(),nbins2D_-2,-eta2DMax_, eta2DMax_,nbins2D_,-phi2DMax_, phi2DMax_);
        etaphihistmatch.push_back(tmphisto);
      }

      // Et & eta distributions
      etahists.push_back(etahist);
      phihists.push_back(phihist);
      ethists.push_back(ethist);
      etahistmatchs.push_back(etahistmatch);
      phihistmatchs.push_back(phihistmatch);
      ethistmatchs.push_back(ethistmatch);
      histEtOfHltObjMatchToGens.push_back(histEtOfHltObjMatchToGen);
      histEtaOfHltObjMatchToGens.push_back(histEtaOfHltObjMatchToGen);
      histPhiOfHltObjMatchToGens.push_back(histPhiOfHltObjMatchToGen);
      etaphihists.push_back(etaphihist);
      etaphihistmatchs.push_back(etaphihistmatch);
      histEtaPhiOfHltObjMatchToGens.push_back(histEtaPhiOfHltObjMatchToGen);
      // commented out because uses data not included in HTLDEBUG and uses
      // Isolation distributions
      //etahistisos.push_back(etahistiso);
      //phihistisos.push_back(phihistiso);
      //ethistisos.push_back(ethistiso);
      //etahistisomatchs.push_back(etahistisomatch);
      //phihistisomatchs.push_back(phihistisomatch);
      //ethistisomatchs.push_back(ethistisomatch);
      //histEtIsoOfHltObjMatchToGens.push_back(histEtIsoOfHltObjMatchToGen); 
      //histEtaIsoOfHltObjMatchToGens.push_back(histEtaIsoOfHltObjMatchToGen);
      //histPhiIsoOfHltObjMatchToGens.push_back(histPhiIsoOfHltObjMatchToGen);

      totals.push_back(total);
      totalmatchs.push_back(totalmatch);
      etgens.push_back(etgen);
      etagens.push_back(etagen);
      phigens.push_back(phigen);
     etaphigens.push_back(etaphigen);
   }
}

bool EmDQM::checkGeneratedParticlesRequirement ( const edm::Event &  event )

private

helper to check whether there were enough generator level electrons/photons (MC) or enough reco level electrons/photons to analyze this event.

Returns

if the event has enough of these candidates.

Definition at line 611 of file EmDQM.cc.

References funct::abs(), reco::LeafCandidate::et(), PVValHelper::eta, gencut_, genEtaAcc_, GenHFHadronMatcher_cfi::genParticles, genParticles_token, mps_fire::i, edm::HandleBase::isValid(), OUTPUT_WARNINGS, pdgGen, plotEtMin, pTGenComparator_, and verbosity_.

Referenced by analyze().

{
   // Decide if this was an event of interest.               //
   //  Did the highest energy particles happen               //
   //  to have |eta| < 2.5 ?  Then continue.                 //
   edm::Handle< edm::View<reco::Candidate> > genParticles;
   event.getByToken(genParticles_token, genParticles);
   if(!genParticles.isValid()) {
     if (verbosity_ >= OUTPUT_WARNINGS)
        edm::LogWarning("EmDQM") << "genParticles invalid.";
     return false;
   }

   std::vector<reco::LeafCandidate> allSortedGenParticles;

   for(edm::View<reco::Candidate>::const_iterator currentGenParticle = genParticles->begin(); currentGenParticle != genParticles->end(); currentGenParticle++){

     // TODO: do we need to check the states here again ?
     // in principle, there should collections produced with the python configuration
     // (other than 'genParticles') which fulfill these criteria
     if (  !( abs((*currentGenParticle).pdgId())==pdgGen  && (*currentGenParticle).status()==1 && (*currentGenParticle).et() > 2.0)  )  continue;

     reco::LeafCandidate tmpcand( *(currentGenParticle) );

     if (tmpcand.et() < plotEtMin) continue;

     allSortedGenParticles.push_back(tmpcand);
   }

   std::sort(allSortedGenParticles.begin(), allSortedGenParticles.end(),pTGenComparator_);

   // return false if not enough particles found
   if (allSortedGenParticles.size() < gencut_)
     return false;

   // additional check (this might be legacy code and we need to check
   // whether this should not be removed ?)

   // We now have a sorted collection of all generated particles
   // with pdgId = pdgGen.
   // Loop over them to see if the top gen particles have eta within acceptance
  // bool keepEvent = true;
   for (unsigned int i = 0 ; i < gencut_ ; i++ ) {
     bool inECALgap = fabs(allSortedGenParticles[i].eta()) > 1.4442 && fabs(allSortedGenParticles[i].eta()) < 1.556;
     if ( (fabs(allSortedGenParticles[i].eta()) > genEtaAcc_) || inECALgap ) {
       //edm::LogWarning("EmDQM") << "Throwing event away. Gen particle with pdgId="<< allSortedGenParticles[i].pdgId() <<"; et="<< allSortedGenParticles[i].et() <<"; and eta="<< allSortedGenParticles[i].eta() <<" beyond acceptance.";
       return false;
     }
   }

   // all tests passed
   return true;
}

bool EmDQM::checkRecoParticlesRequirement ( const edm::Event &  event )

private

similar to checkGeneratedParticlesRequirement(..) but for reconstructed particles. For the moment, there are some additional requirements in the MC version so we can't use the same code for both cases.

Definition at line 668 of file EmDQM.cc.

References autoConfMode_, gencut_, gencutColl_fidDiGamma_token, gencutColl_fidGammaJet_token, gencutColl_fidTripleEle_token, gencutColl_fidWenu_token, gencutColl_fidZee_token, gencutColl_manualConf_token, edm::HandleBase::isValid(), OUTPUT_WARNINGS, pdgGen, plotEtMin, reqNum, and verbosity_.

Referenced by analyze().

{
  // note that this code is very similar to the one in checkGeneratedParticlesRequirement(..)
  // and hopefully can be merged with it at some point in the future

  edm::Handle< edm::View<reco::Candidate> > referenceParticles;
  // get the right data according to the trigger path currently looked at
  if (autoConfMode_) {
    switch(reqNum) {
       case 1:
          if (pdgGen == 11) event.getByToken(gencutColl_fidWenu_token, referenceParticles);
          else event.getByToken(gencutColl_fidGammaJet_token, referenceParticles);
          break;
       case 2:
          if (pdgGen == 11) event.getByToken(gencutColl_fidZee_token, referenceParticles);
          else event.getByToken(gencutColl_fidDiGamma_token, referenceParticles);
          break;
       case 3:
          event.getByToken(gencutColl_fidTripleEle_token, referenceParticles);
          break;
    }
  } else {
    event.getByToken(gencutColl_manualConf_token, referenceParticles);
  }
  if(!referenceParticles.isValid()) {
     if (verbosity_ >= OUTPUT_WARNINGS)
        edm::LogWarning("EmDQM") << "referenceParticles invalid.";
     return false;
  }

  std::vector<const reco::Candidate *> allSortedReferenceParticles;

  for(edm::View<reco::Candidate>::const_iterator currentReferenceParticle = referenceParticles->begin();
      currentReferenceParticle != referenceParticles->end();
      currentReferenceParticle++)
  {
     if ( currentReferenceParticle->et() <= 2.0)
       continue;

     // Note that for determining the overall efficiency,
     // we should only allow
     //
     // HOWEVER: for turn-on curves, we need to let
     //          more electrons pass
     if (currentReferenceParticle->et() < plotEtMin)
       continue;

     // TODO: instead of filling a new vector we could simply count here...
     allSortedReferenceParticles.push_back(&(*currentReferenceParticle));
  }

   // std::sort(allSortedReferenceParticles.begin(), allSortedReferenceParticles.end(),pTComparator_);

   // return false if not enough particles found
   return allSortedReferenceParticles.size() >= gencut_;
}

int EmDQM::countSubstring ( const std::string &  str, const std::string &  sub  )

private

Definition at line 1083 of file EmDQM.cc.

References KineDebug3::count(), and PFRecoTauDiscriminationByIsolation_cfi::offset.

Referenced by findEgammaPaths(), and makePSetForL1SeedFilter().

{
    if (sub.length() == 0) return 0;
    int count = 0;
    for (size_t offset = str.find(sub); offset != std::string::npos;
     offset = str.find(sub, offset + sub.length()))
    {
        ++count;
    }
    return count;
}

void EmDQM::dqmBeginRun ( edm::Run const &  iRun, edm::EventSetup const &  iSetup  )

override

Definition at line 67 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::ParameterSet::addUntrackedParameter(), autoConfMode_, HLTConfigProvider::changed(), edm::ParameterSet::empty(), edm::ParameterSet::exists(), ALCARECOTkAlBeamHalo_cff::filter, findEgammaPaths(), getFilterModules(), edm::ParameterSet::getParameter(), getPrimaryEtCut(), hltCollectionLabelsFound, hltCollectionLabelsFoundPerPath, hltCollectionLabelsMissed, hltCollectionLabelsMissedPerPath, hltConfig_, mps_fire::i, HLTConfigProvider::init(), HLTConfigProvider::inited(), isData_, label, makePSetForEgammaDoubleEtDeltaPhiFilter(), makePSetForEgammaGenericFilter(), makePSetForEgammaGenericQuadraticFilter(), makePSetForElectronGenericFilter(), makePSetForEtFilter(), makePSetForL1SeedFilter(), makePSetForL1SeedToSuperClusterMatchFilter(), makePSetForOneOEMinusOneOPFilter(), makePSetForPixelMatchFilter(), HLTConfigProvider::modulePSet(), OUTPUT_ALL, OUTPUT_ERRORS, OUTPUT_WARNINGS, paramSets, edm::InputTag::process(), HLTConfigProvider::processName(), AlignmentTrackSelector_cfi::ptMax, ptMax_, ptMin, ptMin_, HLTConfigProvider::removeVersion(), HLTConfigProvider::size(), AlCaHLTBitMon_QueryRunRegistry::string, HLTConfigProvider::tableName(), HLTConfigProvider::triggerIndex(), triggerObject_, trigger::TriggerPhoton, TYPE_DOUBLE_ELE, TYPE_DOUBLE_PHOTON, TYPE_SINGLE_ELE, TYPE_SINGLE_PHOTON, TYPE_TRIPLE_ELE, and verbosity_.

{
   bool changed(true);
   if (hltConfig_.init(iRun, iSetup, triggerObject_.process(), changed)) {

      // if init returns TRUE, initialisation has succeeded!

      if (autoConfMode_) {
        if (verbosity_ >= OUTPUT_ALL) {
           // Output general information on the menu
           edm::LogPrint("EmDQM") << "inited=" << hltConfig_.inited();
           edm::LogPrint("EmDQM") << "changed=" << hltConfig_.changed();
           edm::LogPrint("EmDQM") << "processName=" << hltConfig_.processName();
           edm::LogPrint("EmDQM") << "tableName=" << hltConfig_.tableName();
           edm::LogPrint("EmDQM") << "size=" << hltConfig_.size();
           edm::LogInfo("EmDQM") << "The following filter types are not analyzed: \n" 
                                  << "\tHLTGlobalSumsMET\n"
                                  << "\tHLTHtMhtFilter\n"
                                  << "\tHLTMhtFilter\n"
                                  << "\tHLTJetTag\n"
                                  << "\tHLT1CaloJet\n"
                                  << "\tHLT1CaloMET\n"
                                  << "\tHLT1CaloBJet\n"
                                  << "\tHLT1Tau\n"
                                  << "\tHLT1PFTau\n"
                                  << "\tPFTauSelector\n"
                                  << "\tHLT1PFJet\n"
                                  << "\tHLTPFJetCollectionsFilter\n"
                                  << "\tHLTPFJetCollectionsVBFFilter\n"
                                  << "\tHLTPFJetTag\n"
                                  << "\tEtMinCaloJetSelector\n"
                                  << "\tEtMinPFJetSelector\n"
                                  << "\tLargestEtCaloJetSelector\n"
                                  << "\tLargestEtPFJetSelector\n"
                                  << "\tHLTEgammaTriggerFilterObjectWrapper\n"
                                  << "\tHLTEgammaDoubleLegCombFilter\n"
                                  << "\tHLT2ElectronTau\n"
                                  << "\tHLT2ElectronMET\n"
                                  << "\tHLT2ElectronPFTau\n"
                                  << "\tHLTPMMassFilter\n"
                                  << "\tHLTHcalTowerFilter\n"
                                  << "\tHLT1Photon\n"
                                  << "\tHLTRFilter\n"
                                  << "\tHLTRHemisphere\n"
                                  << "\tHLTElectronPFMTFilter\n"
                                  << "\tPrimaryVertexObjectFilter\n"
                                  << "\tHLTEgammaAllCombMassFilter\n"
                                  << "\tHLTMuon*\n"
                                  ;
        }


        // All electron and photon paths
        std::vector<std::vector<std::string> > egammaPaths = findEgammaPaths();
        //std::cout << "Found " << egammaPaths[TYPE_SINGLE_ELE].size() << " single electron paths" << std::endl;
        //std::cout << "Found " << egammaPaths[TYPE_DOUBLE_ELE].size() << " double electron paths" << std::endl;
        //std::cout << "Found " << egammaPaths[TYPE_TRIPLE_ELE].size() << " triple electron paths" << std::endl;
        //std::cout << "Found " << egammaPaths[TYPE_SINGLE_PHOTON].size() << " single photon paths" << std::endl;
        //std::cout << "Found " << egammaPaths[TYPE_DOUBLE_PHOTON].size() << " double photon paths" << std::endl;

        std::vector<std::string> filterModules;

        for (unsigned int j=0; j < egammaPaths.size() ; j++) {
           if (verbosity_ >= OUTPUT_ALL) {
              switch(j) {
                 case TYPE_SINGLE_ELE:
                    edm::LogPrint("EmDQM") << "/////////////////////////////////////////\nSingle electron paths: ";
                    break;
                 case TYPE_DOUBLE_ELE:
                    edm::LogPrint("EmDQM") << "/////////////////////////////////////////\nDouble electron paths: ";
                    break;
                 case TYPE_TRIPLE_ELE:
                    edm::LogPrint("EmDQM") << "/////////////////////////////////////////\nTriple electron paths: ";
                    break;
                 case TYPE_SINGLE_PHOTON:
                    edm::LogPrint("EmDQM") << "/////////////////////////////////////////\nSingle photon paths: ";
                    break;
                 case TYPE_DOUBLE_PHOTON:
                    edm::LogPrint("EmDQM") << "/////////////////////////////////////////\nDouble photon paths: ";
                    break;
              }
           }

           for (unsigned int i=0; i < egammaPaths.at(j).size() ; i++) {
              // get pathname of this trigger 
              const std::string pathName = egammaPaths.at(j).at(i);
              if (verbosity_ >= OUTPUT_ALL)
                 edm::LogPrint("EmDQM") << "Path: " << pathName;

              // get filters of the current path
              filterModules = getFilterModules(pathName);

              //--------------------       
              edm::ParameterSet paramSet;

              paramSet.addUntrackedParameter("pathIndex", hltConfig_.triggerIndex(pathName));
              paramSet.addParameter("@module_label", hltConfig_.removeVersion(pathName) + "_DQM");
              //paramSet.addParameter("@module_label", pathName + "_DQM");

              // plotting parameters (untracked because they don't affect the physics)
              double genEtMin = getPrimaryEtCut(pathName);
              if (genEtMin >= 0) {
                 paramSet.addUntrackedParameter("genEtMin", genEtMin);
              } else {
                 if (verbosity_ >= OUTPUT_WARNINGS)
                    edm::LogWarning("EmDQM") << "Pathname: '" << pathName << "':  Unable to determine a minimum Et. Will not include this path in the validation.";
                 continue;
              }

              // set the x axis of the et plots to some reasonable value based
              // on the primary et cut determined from the path name
              double ptMax = ptMax_;
              double ptMin = ptMin_;
              if (ptMax < (1.2*genEtMin)) {
                 paramSet.addUntrackedParameter<double>("PtMax", (10*ceil(0.12 * genEtMin)));
                 paramSet.addUntrackedParameter<double>("PtMin", (10*ceil(0.12 * genEtMin) - ptMax + ptMin));
              }
              else {
                 paramSet.addUntrackedParameter<double>("PtMax", ptMax);
                 paramSet.addUntrackedParameter<double>("PtMin", ptMin);
              }

              //preselction cuts 
              switch (j) {
                 case TYPE_SINGLE_ELE:
                    paramSet.addParameter<unsigned>("reqNum", 1);
                    paramSet.addParameter<int>("pdgGen", 11);
                    paramSet.addParameter<edm::InputTag>("cutcollection", edm::InputTag("fiducialWenu"));
                    paramSet.addParameter<int>("cutnum", 1);
                    break;
                 case TYPE_DOUBLE_ELE:
                    paramSet.addParameter<unsigned>("reqNum", 2);
                    paramSet.addParameter<int>("pdgGen", 11);
                    paramSet.addParameter<edm::InputTag>("cutcollection", edm::InputTag("fiducialZee"));
                    paramSet.addParameter<int>("cutnum", 2);
                    break;
                 case TYPE_TRIPLE_ELE:
                    paramSet.addParameter<unsigned>("reqNum", 3);
                    paramSet.addParameter<int>("pdgGen", 11);
                    paramSet.addParameter<edm::InputTag>("cutcollection", edm::InputTag("fiducialTripleEle"));
                    paramSet.addParameter<int>("cutnum", 3);
                    break;
                 case TYPE_SINGLE_PHOTON:
                    paramSet.addParameter<unsigned>("reqNum", 1);
                    paramSet.addParameter<int>("pdgGen", 22);
                    paramSet.addParameter<edm::InputTag>("cutcollection", edm::InputTag("fiducialGammaJet"));
                    paramSet.addParameter<int>("cutnum", 1);
                    break;
                 case TYPE_DOUBLE_PHOTON:
                    paramSet.addParameter<unsigned>("reqNum", 2);
                    paramSet.addParameter<int>("pdgGen", 22);
                    paramSet.addParameter<edm::InputTag>("cutcollection", edm::InputTag("fiducialDiGamma"));
                    paramSet.addParameter<int>("cutnum", 2);
              }
              //--------------------

              // TODO: extend this
              if (isData_) paramSet.addParameter<edm::InputTag>("cutcollection", edm::InputTag("gsfElectrons"));

              std::vector<edm::ParameterSet> filterVPSet;
              edm::ParameterSet filterPSet;
              std::string moduleLabel;

              // loop over filtermodules of current trigger path
              for (std::vector<std::string>::iterator filter = filterModules.begin(); filter != filterModules.end(); ++filter) {
                 std::string moduleType = hltConfig_.modulePSet(*filter).getParameter<std::string>("@module_type");
                 moduleLabel = hltConfig_.modulePSet(*filter).getParameter<std::string>("@module_label");

                 // first check if it is a filter we are not interrested in
                 if (moduleType == "Pythia6GeneratorFilter" ||
                     moduleType == "HLTTriggerTypeFilter" ||
                     moduleType == "HLTLevel1Activity" ||
                     moduleType == "HLTPrescaler" ||
                     moduleType == "HLTBool")
                    continue;

                 // now check for the known filter types
                 if (moduleType == "HLTLevel1GTSeed") {
                    filterPSet = makePSetForL1SeedFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTEgammaL1MatchFilterRegional") {
                    filterPSet = makePSetForL1SeedToSuperClusterMatchFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTEgammaEtFilter") {
                    filterPSet = makePSetForEtFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTElectronOneOEMinusOneOPFilterRegional") {
                    filterPSet = makePSetForOneOEMinusOneOPFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTElectronPixelMatchFilter") {
                    filterPSet = makePSetForPixelMatchFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTEgammaGenericFilter") {
                    filterPSet = makePSetForEgammaGenericFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTEgammaGenericQuadraticFilter") {
                    filterPSet = makePSetForEgammaGenericQuadraticFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTElectronGenericFilter") {
                    filterPSet = makePSetForElectronGenericFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTEgammaDoubleEtDeltaPhiFilter") {
                    filterPSet = makePSetForEgammaDoubleEtDeltaPhiFilter(moduleLabel);
                 }
                 else if (moduleType == "HLTGlobalSumsMET"
                          || moduleType == "HLTHtMhtFilter"
                          || moduleType == "HLTMhtFilter"
                          || moduleType == "HLTJetTag"
                          || moduleType == "HLT1CaloJet"
                          || moduleType == "HLT1CaloMET"
                          || moduleType == "HLT1CaloBJet"
                          || moduleType == "HLT1Tau"
                          || moduleType == "HLT1PFTau"
                          || moduleType == "PFTauSelector"
                          || moduleType == "HLT1PFJet"
                          || moduleType == "HLTPFJetCollectionsFilter"
                          || moduleType == "HLTPFJetCollectionsVBFFilter"
                          || moduleType == "HLTPFJetTag"
                          || moduleType == "EtMinCaloJetSelector"
                          || moduleType == "EtMinPFJetSelector"
                          || moduleType == "LargestEtCaloJetSelector"
                          || moduleType == "LargestEtPFJetSelector"
                          || moduleType == "HLTEgammaTriggerFilterObjectWrapper"  // 'fake' filter
                          || moduleType == "HLTEgammaDoubleLegCombFilter" // filter does not put anything in TriggerEventWithRefs
                          || moduleType == "HLT2ElectronMET"
                          || moduleType == "HLT2ElectronTau"
                          || moduleType == "HLT2ElectronPFTau"
                          || moduleType == "HLTPMMassFilter"
                          || moduleType == "HLTHcalTowerFilter"
                          || moduleType == "HLT1Photon"
                          || moduleType == "HLTRFilter"
                          || moduleType == "HLTRHemisphere"
                          || moduleType == "HLTElectronPFMTFilter"
                          || moduleType == "PrimaryVertexObjectFilter"
                          || moduleType == "HLTEgammaAllCombMassFilter"
                          || moduleType.find("HLTMuon") != std::string::npos
                         )
                    continue;
                 else {
                    if (verbosity_ >= OUTPUT_WARNINGS)
                       edm::LogWarning("EmDQM")  << "No parameter set for filter '" << moduleLabel << "' with filter type '" << moduleType << "' added. Module will not be analyzed.";
                    continue;
                 }

                 // something went wrong when the parameter set is empty. 
                 if (!filterPSet.empty()) {
                    if (!hltConfig_.modulePSet(moduleLabel).exists("saveTags")) {
                       // make sure that 'theHLTOutputTypes' before an unseeded filter in a photon path is set to trigger::TriggerPhoton
                       // this is coupled to the parameter 'saveTag = true'
                       if (moduleLabel.find("Unseeded") != std::string::npos && (j == TYPE_DOUBLE_PHOTON || j == TYPE_SINGLE_PHOTON)) {
                          filterVPSet.back().addParameter<int>("theHLTOutputTypes", trigger::TriggerPhoton);
                       }
                    }
                    // if ncandcut is -1 (when parsing for the number of particles in the name of the L1seed filter fails),
                    // fall back to setting ncandcut to the number of particles needed for the given path.
                    if (filterPSet.getParameter<int>("ncandcut") < 0) {
                      edm::LogPrint("EmDQM") << "No number of candidates for filter " << moduleLabel << " found. Set to " << paramSet.getParameter<int>("cutnum") << ", determined from path name.";
                      filterPSet.addParameter<int>("ncandcut", paramSet.getParameter<int>("cutnum"));
                    } else if (filterPSet.getParameter<int>("ncandcut") > paramSet.getParameter<int>("cutnum")) {
                      edm::LogInfo("EmDQM") << "Changed required number of candidates from " << paramSet.getParameter<int>("cutnum") << " to " << filterPSet.getParameter<int>("ncandcut") << " for filter " << moduleLabel;
                      paramSet.addParameter<int>("cutnum", filterPSet.getParameter<int>("ncandcut"));
                      paramSet.addParameter<unsigned>("reqNum", (unsigned)filterPSet.getParameter<int>("ncandcut"));
                    }

                    filterVPSet.push_back(filterPSet);
                 }
                 else
                    break;

              } // end loop over filter modules of current trigger path

              // do not include this path when an empty filterPSet is detected.
              if (!filterPSet.empty()) {
                 std::string lastModuleName = filterPSet.getParameter<edm::InputTag>("HLTCollectionLabels").label();
                 if (!hltConfig_.modulePSet(lastModuleName).exists("saveTags")) {
                    // make sure that 'theHLTOutputTypes' of the last filter of a photon path is set to trigger::TriggerPhoton
                    // this is coupled to the parameter 'saveTag = true'
                    if ((j == TYPE_SINGLE_PHOTON || j == TYPE_DOUBLE_PHOTON) && pathName.rfind("Ele") == std::string::npos) {
                       filterVPSet.back().addParameter<int>("theHLTOutputTypes", trigger::TriggerPhoton);
                    }
                 }
                 paramSet.addParameter<std::vector<edm::ParameterSet> >("filters", filterVPSet);
              }
              else {
                 if (verbosity_ >= OUTPUT_ALL)
                    edm::LogPrint("EmDQM") << "Will not include this path in the validation due to errors while generating the parameter set.";
                 continue;
              }

              // dump generated parameter set
              //std::cout << paramSet.dump() << std::endl;

              paramSets.push_back(paramSet);
           } // loop over all paths of this analysis type

        } // loop over analysis types (single ele etc.)
      }

      hltCollectionLabelsFoundPerPath.reserve(paramSets.size());
      hltCollectionLabelsMissedPerPath.reserve(paramSets.size());

      // loop over all the trigger path parameter sets
      for (std::vector<edm::ParameterSet>::iterator psetIt = paramSets.begin(); psetIt != paramSets.end(); ++psetIt) {
         hltCollectionLabelsFoundPerPath.push_back(hltCollectionLabelsFound);
         hltCollectionLabelsMissedPerPath.push_back(hltCollectionLabelsMissed);
      }

      if (changed) {
         // The HLT config has actually changed wrt the previous Run, hence rebook your
         // histograms or do anything else dependent on the revised HLT config
      }
   } else {
      // if init returns FALSE, initialisation has NOT succeeded, which indicates a problem
      // with the file and/or code and needs to be investigated!
      if (verbosity_ >= OUTPUT_ERRORS)
         edm::LogError("EmDQM") << " HLT config extraction failure with process name '" << triggerObject_.process() << "'.";
      // In this case, all access methods will return empty values!
   }
}

void EmDQM::endRun ( edm::Run const &  iRun, edm::EventSetup const &  iSetup  )

override

Definition at line 1041 of file EmDQM.cc.

References KineDebug3::count(), edm::InputTag::encode(), hltCollectionLabelsFoundPerPath, hltCollectionLabelsMissedPerPath, OUTPUT_ALL, OUTPUT_WARNINGS, paramSets, SetVarsFromPSet(), GlobalPosition_Frontier_DevDB_cff::tag, and verbosity_.

{
   // loop over all the trigger path parameter sets
   unsigned int vPos = 0;
   for (std::vector<edm::ParameterSet>::iterator psetIt = paramSets.begin(); psetIt != paramSets.end(); ++psetIt, ++vPos) {
      SetVarsFromPSet(psetIt);

      // print information about hltCollectionLabels which were not found
      // (but only those which were never found)

      // check which ones were never found
      std::vector<std::string> labelsNeverFound;
      
      BOOST_FOREACH(const edm::InputTag &tag, hltCollectionLabelsMissedPerPath.at(vPos))
      {
        if ((hltCollectionLabelsFoundPerPath.at(vPos)).count(tag.encode()) == 0)
          // never found
          labelsNeverFound.push_back(tag.encode());

      } // loop over all tags which were missed at least once

      if (labelsNeverFound.empty())
        continue;

      std::sort(labelsNeverFound.begin(), labelsNeverFound.end());

      // there was at least one label which was never found
      // (note that this could also be because the corresponding
      // trigger path slowly fades out to zero efficiency)
      if (verbosity_ >= OUTPUT_WARNINGS)
         edm::LogWarning("EmDQM") << "There were some HLTCollectionLabels which were never found:";

      BOOST_FOREACH(const edm::InputTag &tag, labelsNeverFound)
      {
        if (verbosity_ >= OUTPUT_ALL)
           edm::LogPrint("EmDQM") << "  " << tag;
      }
   }
}

std::vector< std::vector< std::string > > EmDQM::findEgammaPaths ( )

private

Definition at line 1098 of file EmDQM.cc.

References countSubstring(), hltConfig_, mps_fire::i, callgraph::path, HLTConfigProvider::size(), AlCaHLTBitMon_QueryRunRegistry::string, HLTConfigProvider::triggerName(), TYPE_DOUBLE_ELE, TYPE_DOUBLE_PHOTON, TYPE_SINGLE_ELE, TYPE_SINGLE_PHOTON, and TYPE_TRIPLE_ELE.

Referenced by dqmBeginRun().

{
   std::vector<std::vector<std::string> > Paths(5);
   // Loop over all paths in the menu
   for (unsigned int i=0; i<hltConfig_.size(); i++) {

      std::string path = hltConfig_.triggerName(i);

      // Find electron and photon paths and classify them
      if (int(path.find("HLT_")) == 0) {    // Path should start with 'HLT_'

         int scCount = countSubstring(path, "_SC");
         int eleCount = countSubstring(path, "Ele");
         int doubleEleCount = countSubstring(path, "DoubleEle");
         int doubleSCCount = countSubstring(path, "DiSC");
         int tripleEleCount = countSubstring(path, "TripleEle");
         int photonCount = countSubstring(path, "hoton");
         int doublePhotonCount = countSubstring(path, "DoublePhoton") + countSubstring(path, "Diphoton");

         int totEleCount = 2*tripleEleCount + doubleEleCount + eleCount + scCount + 2*doubleSCCount;
         int totPhotonCount = doublePhotonCount + photonCount;

         if (totEleCount + totPhotonCount < 1) continue;
         switch (totEleCount) {
            case 1:
               Paths[TYPE_SINGLE_ELE].push_back(path);
               //std::cout << "Electron \t" << path << std::endl;
               break;
            case 2:
               Paths[TYPE_DOUBLE_ELE].push_back(path);
               //std::cout << "DoubleElectron \t" << path << std::endl;
               break;
            case 3:
               Paths[TYPE_TRIPLE_ELE].push_back(path);
               //std::cout << "TripleElectron \t" << path << std::endl;
               break;
         }

         switch (totPhotonCount) {
            case 1:
               Paths[TYPE_SINGLE_PHOTON].push_back(path);
               //std::cout << "Photon \t\t" << path << std::endl;
               break;
            case 2:
               Paths[TYPE_DOUBLE_PHOTON].push_back(path);
               //std::cout << "DoublePhoton \t" << path << std::endl;
               break;
         }
      }
      //std::cout << i << " triggerName: " << path << " containing " << hltConfig_.size(i) << " modules."<< std::endl;
   }
   return Paths;
}

std::vector< std::string > EmDQM::getFilterModules ( const std::string &  path )

private

Definition at line 1155 of file EmDQM.cc.

References filters, hltConfig_, mps_fire::i, HLTConfigProvider::moduleEDMType(), HLTConfigProvider::moduleLabel(), HLTConfigProvider::moduleType(), HLTConfigProvider::size(), and AlCaHLTBitMon_QueryRunRegistry::string.

Referenced by dqmBeginRun().

{
   std::vector<std::string> filters;

   //std::cout << "Pathname: " << path << std::endl;

   // Loop over all modules in the path
   for (unsigned int i=0; i<hltConfig_.size(path); i++) {

      std::string module = hltConfig_.moduleLabel(path, i);
      std::string moduleType = hltConfig_.moduleType(module);
      std::string moduleEDMType = hltConfig_.moduleEDMType(module);

      // Find filters
      if (moduleEDMType == "EDFilter" || moduleType.find("Filter") != std::string::npos) {  // older samples may not have EDMType data included
         filters.push_back(module);
         //std::cout << i << "    moduleLabel: " << module << "    moduleType: " << moduleType << "    moduleEDMType: " << moduleEDMType << std::endl;
      }
   }
   return filters;
}

double EmDQM::getPrimaryEtCut ( const std::string &  path )

private

Definition at line 1180 of file EmDQM.cc.

Referenced by dqmBeginRun().

{
   double minEt = -1;

   boost::regex reg("^HLT_.*?(Ele|hoton|EG|SC)([[:digit:]]+).*");

   boost::smatch what;
   if (boost::regex_match(path, what, reg, boost::match_extra))
   {
     minEt = boost::lexical_cast<double>(what[2]); 
   }

   return minEt;
}

edm::ParameterSet EmDQM::makePSetForEgammaDoubleEtDeltaPhiFilter ( const std::string &  moduleName )

private

Definition at line 1325 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::InputTag::process(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerCluster, and triggerObject_.

Referenced by dqmBeginRun().

{
  edm::ParameterSet retPSet;
 
  retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
  //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
  retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
  retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", std::vector<edm::InputTag>(1, std::string("none")));
  retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerCluster);
  retPSet.addParameter<int>("ncandcut", 2);

  return retPSet;
}

edm::ParameterSet EmDQM::makePSetForEgammaGenericFilter ( const std::string &  moduleName )

private

Definition at line 1342 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::ParameterSet::getParameter(), hltConfig_, edm::InputTag::label(), HLTConfigProvider::modulePSet(), HLTConfigProvider::moduleType(), OUTPUT_ERRORS, edm::InputTag::process(), HLTConfigProvider::saveTags(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerCluster, triggerObject_, trigger::TriggerPhoton, and verbosity_.

Referenced by dqmBeginRun().

{
  edm::ParameterSet retPSet;

  // example usages of HLTEgammaGenericFilter are:
  //   R9 shape filter                        hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolR9ShapeFilter 
  //   cluster shape filter                   hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolClusterShapeFilter 
  //   Ecal isolation filter                  hltL1NonIsoHLTNonIsoSingleElectronEt17TIghterEleIdIsolEcalIsolFilter
  //   H/E filter                             hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolHEFilter
  //   HCAL isolation filter                  hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolHcalIsolFilter

  // infer the type of filter by the type of the producer which
  // generates the collection used to cut on this
  edm::InputTag varTag = hltConfig_.modulePSet(moduleName).getParameter<edm::InputTag>("varTag");
  //edm::InputTag nonIsoTag = hltConfig_.modulePSet(moduleName).getParameter<edm::InputTag>("");
  //std::cout << "varTag.label " << varTag.label() << " nonIsoTag.label " << nonIsoTag.label() << std::endl;

  std::string inputType = hltConfig_.moduleType(varTag.label());
  //std::cout << "inputType " << inputType << " moduleName " << moduleName << std::endl;

  //--------------------
  // sanity check: non-isolated path should be produced by the
  // same type of module

  // first check that the non-iso tag is non-empty
  //if (nonIsoTag.label().empty()) {
  //  edm::LogError("EmDQM") << "nonIsoTag of HLTEgammaGenericFilter '" << moduleName <<  "' is empty.";
  //  return retPSet;
  //}
  //if (inputType != hltConfig_.moduleType(nonIsoTag.label())) {
  //  edm::LogError("EmDQM") << "C++ Type of varTag '" << inputType << "' and nonIsoTag '" << hltConfig_.moduleType(nonIsoTag.label()) << "' are not the same for HLTEgammaGenericFilter '" << moduleName <<  "'.";
  //  return retPSet;
  //}
  //--------------------

  // parameter saveTag determines the output type
  if (hltConfig_.saveTags(moduleName))
     retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerPhoton);  
  else
     retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerCluster);

  std::vector<edm::InputTag> isoCollections;
  isoCollections.push_back(varTag);
  //if (!nonIsoTag.label().empty())
  //   isoCollections.push_back(nonIsoTag);

  //--------------------
  // the following cases seem to have identical PSets ?
  //--------------------

  if (inputType == "EgammaHLTR9Producer" ||                       // R9 shape
      inputType == "EgammaHLTR9IDProducer" ||                     // R9 ID
      inputType == "EgammaHLTClusterShapeProducer" ||             // cluster shape
      inputType == "EgammaHLTEcalRecIsolationProducer" ||         // ecal isolation
      inputType == "EgammaHLTHcalIsolationProducersRegional" ||   // HCAL isolation and HE
      inputType == "EgammaHLTGsfTrackVarProducer" ||              // GSF track deta and dphi filter
      inputType == "EgammaHLTBcHcalIsolationProducersRegional" || // HCAL isolation and HE
      inputType == "EgammaHLTEcalPFClusterIsolationProducer" ||   // ECAL PF isolation filter
      inputType == "EgammaHLTHcalPFClusterIsolationProducer" ||   // HCAL PF isolation filter
      inputType == "EgammaHLTElectronTrackIsolationProducers"     // Track isolation filter
     ) {
    retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
    //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
    retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
    retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", isoCollections);
    retPSet.addParameter<int>("ncandcut", hltConfig_.modulePSet(moduleName).getParameter<int>("ncandcut"));

    return retPSet;
  }

  if (verbosity_ >= OUTPUT_ERRORS)
     edm::LogError("EmDQM") << "Can't determine what the HLTEgammaGenericFilter '" << moduleName <<  "' should do: uses a collection produced by a module of C++ type '" << inputType << "'.";
  return edm::ParameterSet();
}

edm::ParameterSet EmDQM::makePSetForEgammaGenericQuadraticFilter ( const std::string &  moduleName )

private

Definition at line 1420 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::ParameterSet::getParameter(), hltConfig_, edm::InputTag::label(), HLTConfigProvider::modulePSet(), HLTConfigProvider::moduleType(), OUTPUT_ERRORS, edm::InputTag::process(), HLTConfigProvider::saveTags(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerCluster, triggerObject_, trigger::TriggerPhoton, and verbosity_.

Referenced by dqmBeginRun().

{
  edm::ParameterSet retPSet;

  // example usages of HLTEgammaGenericFilter are:
  //   R9 shape filter                        hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolR9ShapeFilter 
  //   cluster shape filter                   hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolClusterShapeFilter 
  //   Ecal isolation filter                  hltL1NonIsoHLTNonIsoSingleElectronEt17TIghterEleIdIsolEcalIsolFilter
  //   H/E filter                             hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolHEFilter
  //   HCAL isolation filter                  hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolHcalIsolFilter

  // infer the type of filter by the type of the producer which
  // generates the collection used to cut on this
  edm::InputTag varTag = hltConfig_.modulePSet(moduleName).getParameter<edm::InputTag>("varTag");
  //edm::InputTag nonIsoTag = hltConfig_.modulePSet(moduleName).getParameter<edm::InputTag>("nonIsoTag");
  //std::cout << "varTag.label " << varTag.label() << " nonIsoTag.label " << nonIsoTag.label() << std::endl;

  std::string inputType = hltConfig_.moduleType(varTag.label());
  //std::cout << "inputType " << inputType << " moduleName " << moduleName << std::endl;

  //--------------------
  // sanity check: non-isolated path should be produced by the
  // same type of module

  // first check that the non-iso tag is non-empty
  //if (nonIsoTag.label().empty()) {
  //  edm::LogError("EmDQM") << "nonIsoTag of HLTEgammaGenericFilter '" << moduleName <<  "' is empty.";
  //  return retPSet;
  //}
  //if (inputType != hltConfig_.moduleType(nonIsoTag.label())) {
  //  edm::LogError("EmDQM") << "C++ Type of varTag '" << inputType << "' and nonIsoTag '" << hltConfig_.moduleType(nonIsoTag.label()) << "' are not the same for HLTEgammaGenericFilter '" << moduleName <<  "'.";
  //  return retPSet;
  //}
  //--------------------

  // parameter saveTag determines the output type
  if (hltConfig_.saveTags(moduleName))
     retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerPhoton);  
  else
     retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerCluster);

  std::vector<edm::InputTag> isoCollections;
  isoCollections.push_back(varTag);
  //if (!nonIsoTag.label().empty())
  //   isoCollections.push_back(nonIsoTag);

  //--------------------
  // the following cases seem to have identical PSets ?
  //--------------------

  if (inputType == "EgammaHLTR9Producer" ||                            // R9 shape
      inputType == "EgammaHLTR9IDProducer" ||                          // R9 ID
      inputType == "EgammaHLTClusterShapeProducer" ||                  // cluster shape
      inputType == "EgammaHLTEcalRecIsolationProducer" ||              // ecal isolation
      inputType == "EgammaHLTHcalIsolationProducersRegional" ||        // HCAL isolation and HE
      inputType == "EgammaHLTBcHcalIsolationProducersRegional" ||      // HCAL isolation and HE
      inputType == "EgammaHLTEcalPFClusterIsolationProducer" ||        // ECAL PF isolation filter
      inputType == "EgammaHLTHcalPFClusterIsolationProducer" ||        // HCAL PF isolation filter
      inputType == "EgammaHLTPhotonTrackIsolationProducersRegional"    // Photon track isolation
     ) {
    retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
    //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
    retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
    retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", isoCollections);
    retPSet.addParameter<int>("ncandcut", hltConfig_.modulePSet(moduleName).getParameter<int>("ncandcut"));

    return retPSet;
  }
 
  if (verbosity_ >= OUTPUT_ERRORS)
     edm::LogError("EmDQM") << "Can't determine what the HLTEgammaGenericQuadraticFilter '" << moduleName <<  "' should do: uses a collection produced by a module of C++ type '" << inputType << "'.";
  return edm::ParameterSet();
}

edm::ParameterSet EmDQM::makePSetForElectronGenericFilter ( const std::string &  moduleName )

private

Definition at line 1497 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::ParameterSet::getParameter(), hltConfig_, edm::InputTag::label(), HLTConfigProvider::modulePSet(), HLTConfigProvider::moduleType(), OUTPUT_ERRORS, edm::InputTag::process(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerElectron, triggerObject_, and verbosity_.

Referenced by dqmBeginRun().

{
  edm::ParameterSet retPSet;

  // example usages of HLTElectronGenericFilter are:
  //
  // deta filter      hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolDetaFilter
  // dphi filter      hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolDphiFilter
  // track isolation  hltL1NonIsoHLTNonIsoSingleElectronEt17TighterEleIdIsolTrackIsolFilter

  // infer the type of filter by the type of the producer which
  // generates the collection used to cut on this
  edm::InputTag varTag = hltConfig_.modulePSet(moduleName).getParameter<edm::InputTag>("varTag");
  //edm::InputTag nonIsoTag = hltConfig_.modulePSet(moduleName).getParameter<edm::InputTag>("nonIsoTag");
  //std::cout << "varTag.label " << varTag.label() << " nonIsoTag.label " << nonIsoTag.label() << std::endl;

  std::string inputType = hltConfig_.moduleType(varTag.label());
  //std::cout << "inputType iso " << inputType << " inputType noniso " << hltConfig_.moduleType(nonIsoTag.label()) << " moduleName " << moduleName << std::endl;

  //--------------------
  // sanity check: non-isolated path should be produced by the
  // same type of module
  //if (nonIsoTag.label().empty()) {
  //  edm::LogError("EmDQM") << "nonIsoTag of HLTElectronGenericFilter '" << moduleName <<  "' is empty.";
  //  return retPSet;
  //}
  //if (inputType != hltConfig_.moduleType(nonIsoTag.label())) {
  //  edm::LogError("EmDQM") << "C++ Type of varTag '" << inputType << "' and nonIsoTag '" << hltConfig_.moduleType(nonIsoTag.label()) << "' are not the same for HLTElectronGenericFilter '" << moduleName <<  "'.";
  //  return retPSet;
  //}
  //--------------------

  // the type of object to look for seems to be the
  // same for all uses of HLTEgammaGenericFilter
  retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerElectron);

  std::vector<edm::InputTag> isoCollections;
  isoCollections.push_back(varTag);
  //if (!nonIsoTag.label().empty())
  //   isoCollections.push_back(nonIsoTag);

  //--------------------
  // the following cases seem to have identical PSets ?
  //--------------------

  // note that whether deta or dphi is used is determined from
  // the product instance (not the module label)
  if (inputType == "EgammaHLTElectronDetaDphiProducer" ||           // deta and dphi filter
      inputType == "EgammaHLTElectronTrackIsolationProducers"       // track isolation
     ) {
    retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
    //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
    retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
    retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", isoCollections);
    retPSet.addParameter<int>("ncandcut", hltConfig_.modulePSet(moduleName).getParameter<int>("ncandcut"));

    return retPSet;
  }

  if (verbosity_ >= OUTPUT_ERRORS)
     edm::LogError("EmDQM") << "Can't determine what the HLTElectronGenericFilter '" << moduleName <<  "' should do: uses a collection produced by a module of C++ type '" << inputType << "'.";
  return edm::ParameterSet();
}

edm::ParameterSet EmDQM::makePSetForEtFilter ( const std::string &  moduleName )

private

Definition at line 1274 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::ParameterSet::getParameter(), hltConfig_, HLTConfigProvider::modulePSet(), edm::InputTag::process(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerCluster, and triggerObject_.

Referenced by dqmBeginRun().

{
  edm::ParameterSet retPSet;
  
  retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
  //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
  retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
  retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", std::vector<edm::InputTag>(1, std::string("none")));
  retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerCluster);
  retPSet.addParameter<int>("ncandcut", hltConfig_.modulePSet(moduleName).getParameter<int>("ncandcut"));

  return retPSet;
}

edm::ParameterSet EmDQM::makePSetForL1SeedFilter ( const std::string &  moduleName )

private

Definition at line 1198 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), countSubstring(), edm::InputTag::process(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerL1NoIsoEG, and triggerObject_.

Referenced by dqmBeginRun().

{
  // generates a PSet to analyze the behaviour of an L1 seed.
  //
  // moduleName is the name of the HLT module which filters
  // on the L1 seed.
  edm::ParameterSet retPSet;
  
  retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
  //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
  retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
  retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", std::vector<edm::InputTag>(1, std::string("none")));
  retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerL1NoIsoEG);
  
  // as HLTLevel1GTSeed has no parameter ncandcut we determine the value from the name of the filter

  int orCount = countSubstring(moduleName, "OR") + countSubstring(moduleName, "Or");
  int egCount = countSubstring(moduleName, "EG");
  int dEgCount = countSubstring(moduleName, "DoubleEG");
  int tEgCount = countSubstring(moduleName, "TripleEG");

  int candCount = 2*tEgCount + dEgCount + egCount;
  // if L1 is and OR of triggers try the assumption that all of them are similar first and if not take the lowest number. If this is not successful, let the path name decide
  if (orCount > 0 && candCount > 0) {
     if (egCount % (orCount+1) == 0 && dEgCount % (orCount+1) == 0 && tEgCount % (orCount+1) == 0) candCount /= (orCount+1);
     else if (egCount-dEgCount-tEgCount > 0) candCount = 1; // at least one singleEG present
     else if (dEgCount > 0) candCount = 2; // at least one doubleEG and no singleEG present
     else if (tEgCount > 0) candCount = 3; // only tripleEG present
     else candCount = -1;
  }

  switch (candCount) {
     case 0:
        retPSet.addParameter<int>("ncandcut", 0);
        break;
     case 1:
        retPSet.addParameter<int>("ncandcut", 1);
        break;
     case 2:
        retPSet.addParameter<int>("ncandcut", 2);
        break;
     case 3:
        retPSet.addParameter<int>("ncandcut", 3);
        break;
     default:
        retPSet.addParameter<int>("ncandcut", -1);
  }

  return retPSet;
}

edm::ParameterSet EmDQM::makePSetForL1SeedToSuperClusterMatchFilter ( const std::string &  moduleName )

private

Definition at line 1252 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::ParameterSet::getParameter(), hltConfig_, HLTConfigProvider::modulePSet(), edm::InputTag::process(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerCluster, and triggerObject_.

Referenced by dqmBeginRun().

{
  // generates a PSet to analyze the behaviour of L1 to supercluster match filter.
  //
  // moduleName is the name of the HLT module which requires the match
  // between supercluster and L1 seed.
  //
  edm::ParameterSet retPSet;
  
  retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
  //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
  retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
  retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", std::vector<edm::InputTag>(1, std::string("none")));
  retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerCluster);
  retPSet.addParameter<int>("ncandcut", hltConfig_.modulePSet(moduleName).getParameter<int>("ncandcut"));

  return retPSet;
}

edm::ParameterSet EmDQM::makePSetForOneOEMinusOneOPFilter ( const std::string &  moduleName )

private

Definition at line 1291 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::ParameterSet::getParameter(), hltConfig_, HLTConfigProvider::modulePSet(), edm::InputTag::process(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerElectron, and triggerObject_.

Referenced by dqmBeginRun().

{
  edm::ParameterSet retPSet;
  
  retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
  //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
  retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
  retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", std::vector<edm::InputTag>(1, std::string("none")));
  retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerElectron);
  retPSet.addParameter<int>("ncandcut", hltConfig_.modulePSet(moduleName).getParameter<int>("ncandcut"));

  return retPSet;
}

edm::ParameterSet EmDQM::makePSetForPixelMatchFilter ( const std::string &  moduleName )

private

Definition at line 1308 of file EmDQM.cc.

References edm::ParameterSet::addParameter(), edm::ParameterSet::getParameter(), hltConfig_, HLTConfigProvider::modulePSet(), edm::InputTag::process(), AlCaHLTBitMon_QueryRunRegistry::string, trigger::TriggerCluster, and triggerObject_.

Referenced by dqmBeginRun().

{
  edm::ParameterSet retPSet;
 
  retPSet.addParameter<std::vector<double> >("PlotBounds", std::vector<double>(2, 0.0));
  //retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", processName_));
  retPSet.addParameter<edm::InputTag>("HLTCollectionLabels", edm::InputTag(moduleName, "", triggerObject_.process()));
  retPSet.addParameter<std::vector<edm::InputTag> >("IsoCollections", std::vector<edm::InputTag>(1, std::string("none")));
  retPSet.addParameter<int>("theHLTOutputTypes", trigger::TriggerCluster);
  retPSet.addParameter<int>("ncandcut", hltConfig_.modulePSet(moduleName).getParameter<int>("ncandcut"));

  return retPSet;
}

void EmDQM::SetVarsFromPSet ( std::vector< edm::ParameterSet >::iterator  psetIt )

private

Definition at line 1563 of file EmDQM.cc.

References DEFINE_FWK_MODULE, dirname_, filters, gencut_, gencutCollection_, mps_fire::i, isoNames, nCandCuts, noIsolationPlots_, numOfHLTCollectionLabels, pathIndex, pdgGen, plotBounds, plotEtMin, plotiso, plotPtMax, plotPtMin, reqNum, AlCaHLTBitMon_QueryRunRegistry::string, theHLTCollectionHumanNames, theHLTCollectionLabels, and theHLTOutputTypes.

Referenced by analyze(), bookHistograms(), and endRun().

{
  dirname_="HLT/HLTEgammaValidation/"+psetIt->getParameter<std::string>("@module_label");
 
  pathIndex = psetIt->getUntrackedParameter<unsigned int>("pathIndex", 0);
  // parameters for generator study
  reqNum    = psetIt->getParameter<unsigned int>("reqNum");
  pdgGen    = psetIt->getParameter<int>("pdgGen");
  // plotting parameters (untracked because they don't affect the physics)
  plotEtMin  = psetIt->getUntrackedParameter<double>("genEtMin",0.);
  plotPtMin  = psetIt->getUntrackedParameter<double>("PtMin",0.);
  plotPtMax  = psetIt->getUntrackedParameter<double>("PtMax",1000.);
 
  //preselction cuts 
  gencutCollection_= psetIt->getParameter<edm::InputTag>("cutcollection");
  gencut_          = psetIt->getParameter<int>("cutnum");
 
  //         Read in the Vector of Parameter Sets.          //
  //           Information for each filter-step             //
  std::vector<edm::ParameterSet> filters = 
       psetIt->getParameter<std::vector<edm::ParameterSet> >("filters");
 
  // empty vectors of parameters from previous paths
  theHLTCollectionLabels.clear();
  theHLTOutputTypes.clear();
  theHLTCollectionHumanNames.clear();
  plotBounds.clear();
  isoNames.clear();
  plotiso.clear();
  nCandCuts.clear();

  int i = 0;
  for(std::vector<edm::ParameterSet>::iterator filterconf = filters.begin() ; filterconf != filters.end() ; filterconf++)
  {
 
    theHLTCollectionLabels.push_back(filterconf->getParameter<edm::InputTag>("HLTCollectionLabels"));
    theHLTOutputTypes.push_back(filterconf->getParameter<int>("theHLTOutputTypes"));
    // Grab the human-readable name, if it is not specified, use the Collection Label
    theHLTCollectionHumanNames.push_back(filterconf->getUntrackedParameter<std::string>("HLTCollectionHumanName",theHLTCollectionLabels[i].label()));
 
    std::vector<double> bounds = filterconf->getParameter<std::vector<double> >("PlotBounds");
    // If the size of plot "bounds" vector != 2, abort
    assert(bounds.size() == 2);
    plotBounds.push_back(std::pair<double,double>(bounds[0],bounds[1]));
    isoNames.push_back(filterconf->getParameter<std::vector<edm::InputTag> >("IsoCollections"));

    //for (unsigned int i=0; i<isoNames.back().size(); i++) {
    //  switch(theHLTOutputTypes.back())  {
    //  case trigger::TriggerL1NoIsoEG:
    //    histoFillerL1NonIso->isoNameTokens_.push_back(consumes<edm::AssociationMap<edm::OneToValue<l1extra::L1EmParticleCollection , float>>>(isoNames.back()[i]));
    //    break;
    //  case trigger::TriggerL1IsoEG: // Isolated Level 1
    //    histoFillerL1Iso->isoNameTokens_.push_back(consumes<edm::AssociationMap<edm::OneToValue<l1extra::L1EmParticleCollection , float>>>(isoNames.back()[i]));
    //    break;
    //  case trigger::TriggerPhoton: // Photon 
    //    histoFillerPho->isoNameTokens_.push_back(consumes<edm::AssociationMap<edm::OneToValue<reco::RecoEcalCandidateCollection , float>>>(isoNames.back()[i]));
    //    break;
    //  case trigger::TriggerElectron: // Electron 
    //    histoFillerEle->isoNameTokens_.push_back(consumes<edm::AssociationMap<edm::OneToValue<reco::ElectronCollection , float>>>(isoNames.back()[i]));
    //    break;
    //  case trigger::TriggerCluster: // TriggerCluster
    //    histoFillerClu->isoNameTokens_.push_back(consumes<edm::AssociationMap<edm::OneToValue<reco::RecoEcalCandidateCollection , float>>>(isoNames.back()[i]));
    //    break;
    //  default:
    //    throw(cms::Exception("Release Validation Error") << "HLT output type not implemented: theHLTOutputTypes[n]" );
    //  }
    //}

    // If the size of the isoNames vector is not greater than zero, abort
    assert(!isoNames.back().empty());
    if (isoNames.back().at(0).label()=="none") {
      plotiso.push_back(false);
    } else {
      if (!noIsolationPlots_) plotiso.push_back(true);
      else plotiso.push_back(false);
    }
    nCandCuts.push_back(filterconf->getParameter<int>("ncandcut"));
    i++;
  } // END of loop over parameter sets
 
  // Record number of HLTCollectionLabels
  numOfHLTCollectionLabels = theHLTCollectionLabels.size();
}

Friends And Related Function Documentation

friend class HistoFiller< l1extra::L1EmParticleCollection >

friend

Definition at line 68 of file EmDQM.h.

friend class HistoFiller< reco::ElectronCollection >

friend

Definition at line 66 of file EmDQM.h.

friend class HistoFiller< reco::RecoEcalCandidateCollection >

friend

Definition at line 67 of file EmDQM.h.

Member Data Documentation

bool EmDQM::autoConfMode_

private

Definition at line 95 of file EmDQM.h.

Referenced by analyze(), checkRecoParticlesRequirement(), dqmBeginRun(), and EmDQM().

std::string EmDQM::dirname_

private

Definition at line 86 of file EmDQM.h.

Referenced by bookHistograms(), and SetVarsFromPSet().

double EmDQM::eta2DMax_

private

Definition at line 109 of file EmDQM.h.

Referenced by bookHistograms(), and EmDQM().

std::vector<MonitorElement*> EmDQM::etagens

private

Definition at line 215 of file EmDQM.h.

Referenced by analyze(), and bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::etahistmatchs

private

Definition at line 201 of file EmDQM.h.

Referenced by bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::etahists

private

Definition at line 198 of file EmDQM.h.

Referenced by bookHistograms().

double EmDQM::etaMax_

private

Definition at line 106 of file EmDQM.h.

Referenced by bookHistograms(), and EmDQM().

std::vector<MonitorElement*> EmDQM::etaphigens

private

Definition at line 217 of file EmDQM.h.

Referenced by analyze(), and bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::etaphihistmatchs

private

Definition at line 208 of file EmDQM.h.

Referenced by bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::etaphihists

private

Definition at line 207 of file EmDQM.h.

Referenced by bookHistograms().

std::vector<MonitorElement*> EmDQM::etgens

private

Definition at line 214 of file EmDQM.h.

Referenced by analyze(), and bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::ethistmatchs

private

Definition at line 203 of file EmDQM.h.

Referenced by bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::ethists

private

Definition at line 200 of file EmDQM.h.

Referenced by bookHistograms().

unsigned int EmDQM::gencut_

private

number of generator level particles (electrons/photons) required (for MC)

Definition at line 183 of file EmDQM.h.

Referenced by analyze(), checkGeneratedParticlesRequirement(), checkRecoParticlesRequirement(), and SetVarsFromPSet().

edm::EDGetTokenT<edm::View<reco::Candidate> > EmDQM::gencutColl_fidDiGamma_token

private

Definition at line 230 of file EmDQM.h.

Referenced by analyze(), checkRecoParticlesRequirement(), and EmDQM().

edm::EDGetTokenT<edm::View<reco::Candidate> > EmDQM::gencutColl_fidGammaJet_token

private

Definition at line 229 of file EmDQM.h.

Referenced by analyze(), checkRecoParticlesRequirement(), and EmDQM().

edm::EDGetTokenT<edm::View<reco::Candidate> > EmDQM::gencutColl_fidTripleEle_token

private

Definition at line 228 of file EmDQM.h.

Referenced by analyze(), checkRecoParticlesRequirement(), and EmDQM().

edm::EDGetTokenT<edm::View<reco::Candidate> > EmDQM::gencutColl_fidWenu_token

private

Definition at line 226 of file EmDQM.h.

Referenced by analyze(), checkRecoParticlesRequirement(), and EmDQM().

edm::EDGetTokenT<edm::View<reco::Candidate> > EmDQM::gencutColl_fidZee_token

private

Definition at line 227 of file EmDQM.h.

Referenced by analyze(), checkRecoParticlesRequirement(), and EmDQM().

edm::EDGetTokenT<edm::View<reco::Candidate> > EmDQM::gencutColl_manualConf_token

private

Definition at line 231 of file EmDQM.h.

Referenced by analyze(), checkRecoParticlesRequirement(), and EmDQM().

edm::InputTag EmDQM::gencutCollection_

private

collection which should be used for generator particles (MC) or reconstructed particles (data).

This collection is used for matching the HLT objects against (e.g. match the HLT object to generated particles or reconstructed electrons/photons).

Definition at line 180 of file EmDQM.h.

Referenced by SetVarsFromPSet().

double EmDQM::genEtaAcc_

private

Definition at line 101 of file EmDQM.h.

Referenced by checkGeneratedParticlesRequirement(), and EmDQM().

double EmDQM::genEtAcc_

private

Definition at line 102 of file EmDQM.h.

Referenced by EmDQM().

edm::EDGetTokenT<edm::View<reco::Candidate> > EmDQM::genParticles_token

private

Definition at line 223 of file EmDQM.h.

Referenced by checkGeneratedParticlesRequirement(), and EmDQM().

std::vector<std::vector<MonitorElement*> > EmDQM::histEtaOfHltObjMatchToGens

private

Definition at line 205 of file EmDQM.h.

Referenced by bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::histEtaPhiOfHltObjMatchToGens

private

Definition at line 209 of file EmDQM.h.

Referenced by bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::histEtOfHltObjMatchToGens

private

Definition at line 204 of file EmDQM.h.

Referenced by bookHistograms().

HistoFiller<reco::RecoEcalCandidateCollection>* EmDQM::histoFillerClu

private

Definition at line 89 of file EmDQM.h.

Referenced by analyze(), and EmDQM().

HistoFiller<reco::ElectronCollection>* EmDQM::histoFillerEle

private

Definition at line 88 of file EmDQM.h.

Referenced by analyze(), and EmDQM().

HistoFiller<l1extra::L1EmParticleCollection>* EmDQM::histoFillerL1Iso

private

Definition at line 92 of file EmDQM.h.

Referenced by analyze(), and EmDQM().

HistoFiller<l1extra::L1EmParticleCollection>* EmDQM::histoFillerL1NonIso

private

Definition at line 90 of file EmDQM.h.

Referenced by analyze(), and EmDQM().

HistoFiller<reco::RecoEcalCandidateCollection>* EmDQM::histoFillerPho

private

Definition at line 91 of file EmDQM.h.

Referenced by analyze(), and EmDQM().

std::vector<std::vector<MonitorElement*> > EmDQM::histPhiOfHltObjMatchToGens

private

Definition at line 206 of file EmDQM.h.

Referenced by bookHistograms().

std::set<std::string> EmDQM::hltCollectionLabelsFound

private

Definition at line 187 of file EmDQM.h.

Referenced by analyze(), and dqmBeginRun().

std::vector<std::set<std::string> > EmDQM::hltCollectionLabelsFoundPerPath

private

which hltCollectionLabels were SEEN at least once

Definition at line 186 of file EmDQM.h.

Referenced by analyze(), dqmBeginRun(), and endRun().

std::set<std::string> EmDQM::hltCollectionLabelsMissed

private

Definition at line 191 of file EmDQM.h.

Referenced by analyze(), and dqmBeginRun().

std::vector<std::set<std::string> > EmDQM::hltCollectionLabelsMissedPerPath

private

which hltCollectionLabels were MISSED at least once

Definition at line 190 of file EmDQM.h.

Referenced by analyze(), dqmBeginRun(), and endRun().

HLTConfigProvider EmDQM::hltConfig_

private

The instance of the HLTConfigProvider as a data member.

Definition at line 133 of file EmDQM.h.

Referenced by analyze(), dqmBeginRun(), findEgammaPaths(), getFilterModules(), makePSetForEgammaGenericFilter(), makePSetForEgammaGenericQuadraticFilter(), makePSetForElectronGenericFilter(), makePSetForEtFilter(), makePSetForL1SeedToSuperClusterMatchFilter(), makePSetForOneOEMinusOneOPFilter(), and makePSetForPixelMatchFilter().

edm::EDGetTokenT<edm::TriggerResults> EmDQM::hltResults_token

private

Definition at line 225 of file EmDQM.h.

Referenced by analyze(), and EmDQM().

bool EmDQM::isData_

private

Definition at line 103 of file EmDQM.h.

Referenced by dqmBeginRun(), and EmDQM().

std::vector<std::vector<edm::InputTag> > EmDQM::isoNames

private

Definition at line 163 of file EmDQM.h.

Referenced by SetVarsFromPSet().

bool EmDQM::mcMatchedOnly_

private

Definition at line 114 of file EmDQM.h.

Referenced by analyze(), bookHistograms(), and EmDQM().

unsigned int EmDQM::minEtForEtaEffPlot_

private

Definition at line 112 of file EmDQM.h.

Referenced by analyze(), and EmDQM().

unsigned int EmDQM::nbins2D_

private

Definition at line 111 of file EmDQM.h.

Referenced by bookHistograms(), and EmDQM().

unsigned int EmDQM::nbins_

private

Definition at line 108 of file EmDQM.h.

Referenced by bookHistograms(), and EmDQM().

std::vector<unsigned int> EmDQM::nCandCuts

private

Definition at line 165 of file EmDQM.h.

Referenced by analyze(), and SetVarsFromPSet().

bool EmDQM::noIsolationPlots_

private

Definition at line 116 of file EmDQM.h.

Referenced by EmDQM(), and SetVarsFromPSet().

bool EmDQM::noPhiPlots_

private

Definition at line 115 of file EmDQM.h.

Referenced by analyze(), bookHistograms(), and EmDQM().

unsigned int EmDQM::numOfHLTCollectionLabels

private

Definition at line 158 of file EmDQM.h.

Referenced by analyze(), bookHistograms(), and SetVarsFromPSet().

const unsigned EmDQM::OUTPUT_ALL = 3

staticprivate

Definition at line 246 of file EmDQM.h.

Referenced by dqmBeginRun(), and endRun().

const unsigned EmDQM::OUTPUT_ERRORS = 1

staticprivate

Definition at line 244 of file EmDQM.h.

Referenced by analyze(), dqmBeginRun(), makePSetForEgammaGenericFilter(), makePSetForEgammaGenericQuadraticFilter(), and makePSetForElectronGenericFilter().

const unsigned EmDQM::OUTPUT_SILENT = 0

staticprivate

Definition at line 243 of file EmDQM.h.

const unsigned EmDQM::OUTPUT_WARNINGS = 2

staticprivate

Definition at line 245 of file EmDQM.h.

Referenced by analyze(), checkGeneratedParticlesRequirement(), checkRecoParticlesRequirement(), dqmBeginRun(), and endRun().

std::vector<edm::ParameterSet> EmDQM::paramSets

private

Definition at line 154 of file EmDQM.h.

Referenced by analyze(), bookHistograms(), dqmBeginRun(), EmDQM(), and endRun().

unsigned int EmDQM::pathIndex

private

Definition at line 156 of file EmDQM.h.

Referenced by analyze(), and SetVarsFromPSet().

int EmDQM::pdgGen

private

Definition at line 168 of file EmDQM.h.

Referenced by analyze(), bookHistograms(), checkGeneratedParticlesRequirement(), checkRecoParticlesRequirement(), and SetVarsFromPSet().

double EmDQM::phi2DMax_

private

Definition at line 110 of file EmDQM.h.

Referenced by bookHistograms(), and EmDQM().

std::vector<MonitorElement*> EmDQM::phigens

private

Definition at line 216 of file EmDQM.h.

Referenced by analyze(), and bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::phihistmatchs

private

Definition at line 202 of file EmDQM.h.

Referenced by bookHistograms().

std::vector<std::vector<MonitorElement*> > EmDQM::phihists

private

Definition at line 199 of file EmDQM.h.

Referenced by bookHistograms().

double EmDQM::phiMax_

private

Definition at line 107 of file EmDQM.h.

Referenced by bookHistograms(), and EmDQM().

std::vector<std::pair<double,double> > EmDQM::plotBounds

private

Definition at line 164 of file EmDQM.h.

Referenced by SetVarsFromPSet().

double EmDQM::plotEtMin

private

Definition at line 170 of file EmDQM.h.

Referenced by analyze(), checkGeneratedParticlesRequirement(), checkRecoParticlesRequirement(), and SetVarsFromPSet().

std::vector<bool> EmDQM::plotiso

private

Definition at line 162 of file EmDQM.h.

Referenced by SetVarsFromPSet().

double EmDQM::plotPtMax

private

Definition at line 172 of file EmDQM.h.

Referenced by bookHistograms(), and SetVarsFromPSet().

double EmDQM::plotPtMin

private

Definition at line 171 of file EmDQM.h.

Referenced by bookHistograms(), and SetVarsFromPSet().

const edm::ParameterSet& EmDQM::pset

private

Definition at line 97 of file EmDQM.h.

Referenced by EmDQM().

GreaterByPt<reco::Particle> EmDQM::pTComparator_

private

Definition at line 219 of file EmDQM.h.

Referenced by analyze().

GreaterByPt<reco::GenParticle> EmDQM::pTGenComparator_

private

Definition at line 220 of file EmDQM.h.

Referenced by checkGeneratedParticlesRequirement().

double EmDQM::ptMax_

private

Definition at line 104 of file EmDQM.h.

Referenced by dqmBeginRun(), and EmDQM().

double EmDQM::ptMin_

private

Definition at line 105 of file EmDQM.h.

Referenced by dqmBeginRun(), and EmDQM().

unsigned int EmDQM::reqNum

private

Definition at line 167 of file EmDQM.h.

Referenced by analyze(), checkRecoParticlesRequirement(), and SetVarsFromPSet().

std::vector<std::string> EmDQM::theHLTCollectionHumanNames

private

Definition at line 159 of file EmDQM.h.

Referenced by bookHistograms(), and SetVarsFromPSet().

std::vector<edm::InputTag> EmDQM::theHLTCollectionLabels

private

Definition at line 157 of file EmDQM.h.

Referenced by analyze(), bookHistograms(), and SetVarsFromPSet().

std::vector<int> EmDQM::theHLTOutputTypes

private

Definition at line 161 of file EmDQM.h.

Referenced by analyze(), and SetVarsFromPSet().

edm::InputTag EmDQM::theL1Seed

private

Definition at line 160 of file EmDQM.h.

std::vector<MonitorElement*> EmDQM::totalmatchs

private

Definition at line 212 of file EmDQM.h.

Referenced by analyze(), and bookHistograms().

std::vector<MonitorElement*> EmDQM::totals

private

Definition at line 211 of file EmDQM.h.

Referenced by analyze(), and bookHistograms().

edm::InputTag EmDQM::triggerObject_

private

Definition at line 99 of file EmDQM.h.

Referenced by analyze(), dqmBeginRun(), EmDQM(), makePSetForEgammaDoubleEtDeltaPhiFilter(), makePSetForEgammaGenericFilter(), makePSetForEgammaGenericQuadraticFilter(), makePSetForElectronGenericFilter(), makePSetForEtFilter(), makePSetForL1SeedFilter(), makePSetForL1SeedToSuperClusterMatchFilter(), makePSetForOneOEMinusOneOPFilter(), and makePSetForPixelMatchFilter().

edm::EDGetTokenT<trigger::TriggerEventWithRefs> EmDQM::triggerObject_token

private

Definition at line 224 of file EmDQM.h.

Referenced by analyze(), and EmDQM().

const unsigned EmDQM::TYPE_DOUBLE_ELE = 1

staticprivate

Definition at line 237 of file EmDQM.h.

Referenced by dqmBeginRun(), and findEgammaPaths().

const unsigned EmDQM::TYPE_DOUBLE_PHOTON = 3

staticprivate

Definition at line 239 of file EmDQM.h.

Referenced by dqmBeginRun(), and findEgammaPaths().

const unsigned EmDQM::TYPE_SINGLE_ELE = 0

staticprivate

Definition at line 236 of file EmDQM.h.

Referenced by dqmBeginRun(), and findEgammaPaths().

const unsigned EmDQM::TYPE_SINGLE_PHOTON = 2

staticprivate

Definition at line 238 of file EmDQM.h.

Referenced by dqmBeginRun(), and findEgammaPaths().

const unsigned EmDQM::TYPE_TRIPLE_ELE = 4

staticprivate

Definition at line 240 of file EmDQM.h.

Referenced by dqmBeginRun(), and findEgammaPaths().

bool EmDQM::useHumanReadableHistTitles_

private

Definition at line 113 of file EmDQM.h.

Referenced by bookHistograms(), and EmDQM().

unsigned int EmDQM::verbosity_

private

Definition at line 100 of file EmDQM.h.

Referenced by analyze(), checkGeneratedParticlesRequirement(), checkRecoParticlesRequirement(), dqmBeginRun(), EmDQM(), endRun(), makePSetForEgammaGenericFilter(), makePSetForEgammaGenericQuadraticFilter(), and makePSetForElectronGenericFilter().