EwkMuDQM.cc

Go to the documentation of this file.

#include "DQM/Physics/src/EwkMuDQM.h"
 
#include "FWCore/MessageLogger/interface/MessageLogger.h"
#include "FWCore/ParameterSet/interface/ParameterSet.h"
#include "DataFormats/Common/interface/Handle.h"
 
#include "FWCore/ServiceRegistry/interface/Service.h"
#include "CommonTools/UtilAlgos/interface/TFileService.h"
 
#include "DQMServices/Core/interface/DQMStore.h"
 
#include "DataFormats/TrackReco/interface/Track.h"
#include "DataFormats/BeamSpot/interface/BeamSpot.h"
#include "DataFormats/VertexReco/interface/Vertex.h"
 
#include "DataFormats/MuonReco/interface/Muon.h"
#include "DataFormats/MuonReco/interface/MuonSelectors.h"
#include "DataFormats/METReco/interface/MET.h"
#include "DataFormats/JetReco/interface/Jet.h"
#include "DataFormats/EgammaCandidates/interface/Photon.h"
 
#include "DataFormats/GeometryVector/interface/Phi.h"
 
#include "FWCore/Common/interface/TriggerNames.h"
#include "FWCore/Framework/interface/Event.h"
#include "DataFormats/Common/interface/TriggerResults.h"
 
#include "DataFormats/Common/interface/View.h"
 
#include "HLTrigger/HLTcore/interface/HLTConfigProvider.h"
 
using namespace edm;
using namespace std;
using namespace reco;
 
EwkMuDQM::EwkMuDQM(const ParameterSet& cfg)
    :  // Input collections
      metTag_(cfg.getUntrackedParameter<edm::InputTag>("METTag", edm::InputTag("pfmet"))),
      jetTag_(cfg.getUntrackedParameter<edm::InputTag>("JetTag", edm::InputTag("ak4PFJets"))),
      //trigTag_(consumes<edm::TriggerResults>(
      // cfg.getUntrackedParameter<edm::InputTag>(
      // "TrigTag", edm::InputTag("TriggerResults::HLT")))),
      muonTag_(consumes<edm::View<reco::Muon> >(
          cfg.getUntrackedParameter<edm::InputTag>("MuonTag", edm::InputTag("muons")))),
      metToken_(
          consumes<edm::View<reco::MET> >(cfg.getUntrackedParameter<edm::InputTag>("METTag", edm::InputTag("pfmet")))),
      jetToken_(consumes<edm::View<reco::Jet> >(
          cfg.getUntrackedParameter<edm::InputTag>("JetTag", edm::InputTag("ak4PFJets")))),
      phoTag_(consumes<edm::View<reco::Photon> >(
          cfg.getUntrackedParameter<edm::InputTag>("phoTag", edm::InputTag("photons")))),
      vertexTag_(consumes<edm::View<reco::Vertex> >(
          cfg.getUntrackedParameter<edm::InputTag>("VertexTag", edm::InputTag("offlinePrimaryVertices")))),
      beamSpotTag_(consumes<reco::BeamSpot>(
          cfg.getUntrackedParameter<edm::InputTag>("beamSpotTag", edm::InputTag("offlineBeamSpot")))),
      // trigPathNames_(cfg.getUntrackedParameter<std::vector<std::string> >(
      //   "TrigPathNames")),
 
      // Muon quality cuts
      isAlsoTrackerMuon_(cfg.getUntrackedParameter<bool>("IsAlsoTrackerMuon", true)),  // Glb muon also tracker muon
      dxyCut_(cfg.getUntrackedParameter<double>("DxyCut", 0.2)),                       // dxy < 0.2 cm
      normalizedChi2Cut_(
          cfg.getUntrackedParameter<double>("NormalizedChi2Cut", 10.)),  // chi2/ndof (of global fit) <10.0
      trackerHitsCut_(cfg.getUntrackedParameter<int>("TrackerHitsCut",
                                                     11)),               // Tracker Hits >10
      pixelHitsCut_(cfg.getUntrackedParameter<int>("PixelHitsCut", 1)),  // Pixel Hits >0
      muonHitsCut_(cfg.getUntrackedParameter<int>("MuonHitsCut",
                                                  1)),                 // Valid Muon Hits >0
      nMatchesCut_(cfg.getUntrackedParameter<int>("NMatchesCut", 2)),  // At least 2 Chambers with matches
 
      // W-boson cuts
      isRelativeIso_(cfg.getUntrackedParameter<bool>("IsRelativeIso", true)),
      isCombinedIso_(cfg.getUntrackedParameter<bool>("IsCombinedIso", false)),
      isoCut03_(cfg.getUntrackedParameter<double>("IsoCut03", 0.1)),
      acopCut_(cfg.getUntrackedParameter<double>("AcopCut", 999.)),
      metMin_(cfg.getUntrackedParameter<double>("MetMin", -999999.)),
      metMax_(cfg.getUntrackedParameter<double>("MetMax", 999999.)),
      mtMin_(cfg.getUntrackedParameter<double>("MtMin", 50.)),
      mtMax_(cfg.getUntrackedParameter<double>("MtMax", 200.)),
      ptCut_(cfg.getUntrackedParameter<double>("PtCut", 20.)),
      etaCut_(cfg.getUntrackedParameter<double>("EtaCut", 2.4)),
 
      // Z rejection
      ptThrForZ1_(cfg.getUntrackedParameter<double>("PtThrForZ1", 20.)),
      ptThrForZ2_(cfg.getUntrackedParameter<double>("PtThrForZ2", 10.)),
 
      // Z selection
      dimuonMassMin_(cfg.getUntrackedParameter<double>("dimuonMassMin", 80.)),
      dimuonMassMax_(cfg.getUntrackedParameter<double>("dimuonMassMax", 120.)),
 
      // Top rejection
      eJetMin_(cfg.getUntrackedParameter<double>("EJetMin", 999999.)),
      nJetMax_(cfg.getUntrackedParameter<int>("NJetMax", 999999)),
 
      // Photon cuts
      ptThrForPhoton_(cfg.getUntrackedParameter<double>("ptThrForPhoton", 5.)),
      nPhoMax_(cfg.getUntrackedParameter<int>("nPhoMax", 999999)),
      hltPrescaleProvider_(cfg, consumesCollector(), *this) {
  isValidHltConfig_ = false;
}
 
void EwkMuDQM::dqmBeginRun(const Run& iRun, const EventSetup& iSet) {
  nall = 0;
  nsel = 0;
  nz = 0;
 
  nrec = 0;
  niso = 0;
  nhlt = 0;
  nmet = 0;
 
  // passed as parameter to HLTConfigProvider::init(), not yet used
  bool isConfigChanged = false;
  // isValidHltConfig_ used to short-circuit analyze() in case of problems
  isValidHltConfig_ = hltPrescaleProvider_.init(iRun, iSet, "HLT", isConfigChanged);
}
 
void EwkMuDQM::bookHistograms(DQMStore::IBooker& ibooker, edm::Run const&, edm::EventSetup const&) {
  ibooker.setCurrentFolder("Physics/EwkMuDQM");
 
  char chtitle[256] = "";
 
  pt_before_ = ibooker.book1D("PT_BEFORECUTS", "Muon transverse momentum (global muon) [GeV]", 100, 0., 100.);
  pt_after_ = ibooker.book1D("PT_AFTERWCUTS", "Muon transverse momentum (global muon) [GeV]", 100, 0., 100.);
 
  eta_before_ = ibooker.book1D("ETA_BEFORECUTS", "Muon pseudo-rapidity", 50, -2.5, 2.5);
  eta_after_ = ibooker.book1D("ETA_AFTERWCUTS", "Muon pseudo-rapidity", 50, -2.5, 2.5);
 
  dxy_before_ = ibooker.book1D("DXY_BEFORECUTS", "Muon transverse distance to beam spot [cm]", 100, -0.5, 0.5);
  dxy_after_ = ibooker.book1D("DXY_AFTERWCUTS", "Muon transverse distance to beam spot [cm]", 100, -0.5, 0.5);
 
  goodewkmuon_before_ = ibooker.book1D("GOODEWKMUON_BEFORECUTS", "Quality-muon flag", 2, -0.5, 1.5);
  goodewkmuon_after_ = ibooker.book1D("GOODEWKMUON_AFTERWCUTS", "Quality-muon flag", 2, -0.5, 1.5);
 
  if (isRelativeIso_) {
    if (isCombinedIso_) {
      iso_before_ = ibooker.book1D("ISO_BEFORECUTS", "Relative (combined) isolation variable", 100, 0., 1.);
      iso_after_ = ibooker.book1D("ISO_AFTERWCUTS", "Relative (combined) isolation variable", 100, 0., 1.);
    } else {
      iso_before_ = ibooker.book1D("ISO_BEFORECUTS", "Relative (tracker) isolation variable", 100, 0., 1.);
      iso_after_ = ibooker.book1D("ISO_AFTERWCUTS", "Relative (tracker) isolation variable", 100, 0., 1.);
    }
  } else {
    if (isCombinedIso_) {
      iso_before_ = ibooker.book1D("ISO_BEFORECUTS", "Absolute (combined) isolation variable [GeV]", 100, 0., 20.);
      iso_after_ = ibooker.book1D("ISO_AFTERWCUTS", "Absolute (combined) isolation variable [GeV]", 100, 0., 20.);
    } else {
      iso_before_ = ibooker.book1D("ISO_BEFORECUTS", "Absolute (tracker) isolation variable [GeV]", 100, 0., 20.);
      iso_after_ = ibooker.book1D("ISO_AFTERWCUTS", "Absolute (tracker) isolation variable [GeV]", 100, 0., 20.);
    }
  }
 
  /*  trig_before_ = ibooker.book1D("TRIG_BEFORECUTS",
      "Trigger response (boolean of muon triggers)", 2, -0.5, 1.5);
  trig_after_ = ibooker.book1D("TRIG_AFTERWCUTS",
      "Trigger response (boolean of muon triggers)", 2, -0.5, 1.5);
*/
  snprintf(chtitle, 255, "Transverse mass (%s) [GeV]", metTag_.label().data());
  mt_before_ = ibooker.book1D("MT_BEFORECUTS", chtitle, 150, 0., 300.);
  mt_after_ = ibooker.book1D("MT_AFTERWCUTS", chtitle, 150, 0., 300.);
 
  snprintf(chtitle, 255, "Missing transverse energy (%s) [GeV]", metTag_.label().data());
  met_before_ = ibooker.book1D("MET_BEFORECUTS", chtitle, 100, 0., 200.);
  met_after_ = ibooker.book1D("MET_AFTERWCUTS", chtitle, 100, 0., 200.);
  met_afterZ_ = ibooker.book1D("MET_AFTERZCUTS", chtitle, 100, 0., 200.);
 
  snprintf(chtitle, 255, "MU-MET (%s) acoplanarity", metTag_.label().data());
  acop_before_ = ibooker.book1D("ACOP_BEFORECUTS", chtitle, 50, 0., M_PI);
  acop_after_ = ibooker.book1D("ACOP_AFTERWCUTS", chtitle, 50, 0., M_PI);
 
  snprintf(chtitle, 255, "Z selection: muons above %.2f GeV", ptThrForZ1_);
  n_zselPt1thr_ = ibooker.book1D("NZSELPT1THR", chtitle, 10, -0.5, 9.5);
  snprintf(chtitle, 255, "Z selection: muons above %.2f GeV", ptThrForZ2_);
  n_zselPt2thr_ = ibooker.book1D("NZSELPT2THR", chtitle, 10, -0.5, 9.5);
 
  snprintf(chtitle, 255, "Number of jets (%s) above %.2f GeV", jetTag_.label().data(), eJetMin_);
  njets_before_ = ibooker.book1D("NJETS_BEFORECUTS", chtitle, 16, -0.5, 15.5);
  njets_after_ = ibooker.book1D("NJETS_AFTERWCUTS", chtitle, 16, -0.5, 15.5);
  njets_afterZ_ = ibooker.book1D("NJETS_AFTERZCUTS", chtitle, 16, -0.5, 15.5);
 
  leadingjet_pt_before_ = ibooker.book1D("LEADINGJET_PT_BEFORECUTS", "Leading Jet transverse momentum", 300, 0., 300.);
  leadingjet_pt_after_ = ibooker.book1D("LEADINGJET_PT_AFTERWCUTS", "Leading Jet transverse momentum", 300, 0., 300.);
  leadingjet_pt_afterZ_ = ibooker.book1D("LEADINGJET_PT_AFTERZCUTS", "Leading Jet transverse momentum", 300, 0., 300.);
 
  leadingjet_eta_before_ = ibooker.book1D("LEADINGJET_ETA_BEFORECUTS", "Leading Jet pseudo-rapidity", 50, -2.5, 2.5);
  leadingjet_eta_after_ = ibooker.book1D("LEADINGJET_ETA_AFTERWCUTS", "Leading Jet pseudo-rapidity", 50, -2.5, 2.5);
  leadingjet_eta_afterZ_ = ibooker.book1D("LEADINGJET_ETA_AFTERZCUTS", "Leading Jet pseudo-rapidity", 50, -2.5, 2.5);
 
  ptDiffPM_before_ = ibooker.book1D("PTDIFFPM_BEFORE_CUTS", "pt(Muon+)-pt(Muon-) after Z cuts [GeV]", 200, -100., 100.);
  ptDiffPM_afterZ_ = ibooker.book1D("PTDIFFPM_AFTERZ_CUTS", "pt(Muon+)-pt(Muon-) after Z cuts [GeV]", 200, -100., 100.);
 
  pt1_afterZ_ = ibooker.book1D("PT1_AFTERZCUTS", "Muon transverse momentum (global muon) [GeV]", 100, 0., 100.);
  eta1_afterZ_ = ibooker.book1D("ETA1_AFTERZCUTS", "Muon pseudo-rapidity", 50, -2.5, 2.5);
  dxy1_afterZ_ = ibooker.book1D("DXY1_AFTERZCUTS", "Muon transverse distance to beam spot [cm]", 100, -0.5, 0.5);
  goodewkmuon1_afterZ_ = ibooker.book1D("GOODEWKMUON1_AFTERZCUTS", "Quality-muon flag", 2, -0.5, 1.5);
 
  if (isRelativeIso_) {
    if (isCombinedIso_) {
      iso1_afterZ_ = ibooker.book1D("ISO1_AFTERZCUTS", "Relative (combined) isolation variable", 100, 0., 1.);
      iso2_afterZ_ = ibooker.book1D("ISO2_AFTERZCUTS", "Relative (combined) isolation variable", 100, 0., 1.);
    } else {
      iso1_afterZ_ = ibooker.book1D("ISO1_AFTERZCUTS", "Relative (tracker) isolation variable", 100, 0., 1.);
      iso2_afterZ_ = ibooker.book1D("ISO2_AFTERZCUTS", "Relative (tracker) isolation variable", 100, 0., 1.);
    }
  } else {
    if (isCombinedIso_) {
      iso1_afterZ_ = ibooker.book1D("ISO1_AFTERZCUTS", "Absolute (combined) isolation variable [GeV]", 100, 0., 20.);
      iso2_afterZ_ = ibooker.book1D("ISO2_AFTERZCUTS", "Absolute (combined) isolation variable [GeV]", 100, 0., 20.);
    } else {
      iso1_afterZ_ = ibooker.book1D("ISO1_AFTERZCUTS", "Absolute (tracker) isolation variable [GeV]", 100, 0., 20.);
      iso2_afterZ_ = ibooker.book1D("ISO2_AFTERZCUTS", "Absolute (tracker) isolation variable [GeV]", 100, 0., 20.);
    }
  }
 
  pt2_afterZ_ = ibooker.book1D("PT2_AFTERZCUTS", "Muon transverse momentum (global muon) [GeV]", 100, 0., 100.);
  eta2_afterZ_ = ibooker.book1D("ETA2_AFTERZCUTS", "Muon pseudo-rapidity", 50, -2.5, 2.5);
  dxy2_afterZ_ = ibooker.book1D("DXY2_AFTERZCUTS", "Muon transverse distance to beam spot [cm]", 100, -0.5, 0.5);
  goodewkmuon2_afterZ_ = ibooker.book1D("GOODEWKMUON2_AFTERZCUTS", "Quality-muon flag", 2, -0.5, 1.5);
  /*  ztrig_afterZ_ = ibooker.book1D("ZTRIG_AFTERZCUTS",
      "Trigger response (boolean of muon triggers)", 2, -0.5, 1.5);
 */
  dimuonmass_before_ = ibooker.book1D("DIMUONMASS_BEFORECUTS", "DiMuonMass (2 globals)", 100, 0, 200);
  dimuonmass_afterZ_ = ibooker.book1D("DIMUONMASS_AFTERZCUTS", "DiMuonMass (2 globals)", 100, 0, 200);
  npvs_before_ = ibooker.book1D("NPVs_BEFORECUTS", "Number of Valid Primary Vertices", 51, -0.5, 50.5);
  npvs_after_ = ibooker.book1D("NPVs_AFTERWCUTS", "Number of Valid Primary Vertices", 51, -0.5, 50.5);
  npvs_afterZ_ = ibooker.book1D("NPVs_AFTERZCUTS", "Number of Valid Primary Vertices", 51, -0.5, 50.5);
  muoncharge_before_ = ibooker.book1D("MUONCHARGE_BEFORECUTS", "Muon Charge", 3, -1.5, 1.5);
  muoncharge_after_ = ibooker.book1D("MUONCHARGE_AFTERWCUTS", "Muon Charge", 3, -1.5, 1.5);
  muoncharge_afterZ_ = ibooker.book1D("MUONCHARGE_AFTERZCUTS", "Muon Charge", 3, -1.5, 1.5);
 
  // Adding these to replace the NZ ones (more useful, since they are more
  // general?)
  nmuons_ = ibooker.book1D("NMuons", "Number of muons in the event", 10, -0.5, 9.5);
  ngoodmuons_ = ibooker.book1D("NGoodMuons", "Number of muons passing the quality criteria", 10, -0.5, 9.5);
 
  nph_ = ibooker.book1D("nph", "Number of photons in the event", 20, 0., 20.);
  phPt_ = ibooker.book1D("phPt", "Photon transverse momentum [GeV]", 100, 0., 1000.);
  snprintf(chtitle, 255, "Photon pseudorapidity (pT>%4.1f)", ptThrForPhoton_);
  phEta_ = ibooker.book1D("phEta", chtitle, 100, -2.5, 2.5);
}
 
void EwkMuDQM::analyze(const Event& ev, const EventSetup& iSet) {
  // Muon collection
  Handle<View<Muon> > muonCollection;
  if (!ev.getByToken(muonTag_, muonCollection)) {
    // LogWarning("") << ">>> Muon collection does not exist !!!";
    return;
  }
  unsigned int muonCollectionSize = muonCollection->size();
 
  // Beam spot
  Handle<reco::BeamSpot> beamSpotHandle;
  if (!ev.getByToken(beamSpotTag_, beamSpotHandle)) {
    // LogWarning("") << ">>> No beam spot found !!!";
    return;
  }
 
  // Loop to reject/control Z->mumu is done separately
  unsigned int nmuonsForZ1 = 0;
  unsigned int nmuonsForZ2 = 0;
  bool cosmic = false;
  for (unsigned int i = 0; i < muonCollectionSize; i++) {
    const Muon& mu = muonCollection->at(i);
    if (!mu.isGlobalMuon())
      continue;
    double pt = mu.pt();
    double dxy = mu.innerTrack()->dxy(beamSpotHandle->position());
 
    if (fabs(dxy) > 1) {
      cosmic = true;
      break;
    }
 
    if (pt > ptThrForZ1_)
      nmuonsForZ1++;
    if (pt > ptThrForZ2_)
      nmuonsForZ2++;
 
    for (unsigned int j = i + 1; j < muonCollectionSize; j++) {
      const Muon& mu2 = muonCollection->at(j);
      if (mu2.isGlobalMuon() && (mu.charge() * mu2.charge() == -1)) {
        const math::XYZTLorentzVector ZRecoGlb(
            mu.px() + mu2.px(), mu.py() + mu2.py(), mu.pz() + mu2.pz(), mu.p() + mu2.p());
        dimuonmass_before_->Fill(ZRecoGlb.mass());
        if (mu.charge() > 0) {
          ptDiffPM_before_->Fill(mu.pt() - mu2.pt());
        } else {
          ptDiffPM_before_->Fill(mu2.pt() - mu.pt());
        }
      }
    }
  }
  if (cosmic)
    return;
 
  LogTrace("") << "> Z rejection: muons above " << ptThrForZ1_ << " [GeV]: " << nmuonsForZ1;
  LogTrace("") << "> Z rejection: muons above " << ptThrForZ2_ << " [GeV]: " << nmuonsForZ2;
 
  // MET
  Handle<View<MET> > metCollection;
  if (!ev.getByToken(metToken_, metCollection)) {
    // LogWarning("") << ">>> MET collection does not exist !!!";
    return;
  }
  const MET& met = metCollection->at(0);
  double met_et = met.pt();
  LogTrace("") << ">>> MET, MET_px, MET_py: " << met_et << ", " << met.px() << ", " << met.py() << " [GeV]";
  met_before_->Fill(met_et);
 
  // Vertices in the event
  Handle<View<reco::Vertex> > vertexCollection;
  if (!ev.getByToken(vertexTag_, vertexCollection)) {
    LogError("") << ">>> Vertex collection does not exist !!!";
    return;
  }
  unsigned int vertexCollectionSize = vertexCollection->size();
 
  int nvvertex = 0;
  for (unsigned int i = 0; i < vertexCollectionSize; i++) {
    const Vertex& vertex = vertexCollection->at(i);
    if (vertex.isValid())
      nvvertex++;
  }
 
  npvs_before_->Fill(nvvertex);
 
  // bool trigger_fired = false;
  //Handle<TriggerResults> triggerResults;
  // if (!ev.getByToken(trigTag_, triggerResults)) {
  // LogWarning("") << ">>> TRIGGER collection does not exist !!!";
  // return;
  // }
  // const edm::TriggerNames& trigNames = ev.triggerNames(*triggerResults);
  //  LogWarning("")<<"Loop over triggers";
 
  //HLTConfigProvider const&  hltConfigProvider = hltPrescaleProvider_.hltConfigProvider();
 
  /*  change faulty logic of triggering
  for (unsigned int i=0; i<triggerResults->size(); i++)
  {
          const std::string trigName = trigNames.triggerName(i);
 
          bool found=false;
          for(unsigned int index=0; index<trigPathNames_.size() && found==false;
  index++) {
               size_t trigPath = trigName.find(trigPathNames_[index]); // 0 if
  found, pos if not
               if (trigPath==0) found=true;
          }
          if(!found) {continue;}
 
          bool prescaled=false;
          for (unsigned int ps= 0; ps<  hltConfigProvider.prescaleSize();
  ps++){
              const unsigned int prescaleValue =
  hltConfigProvider.prescaleValue(ps, trigName) ;
              if (prescaleValue != 1) prescaled =true;
          }
 
          if( triggerResults->accept(i) && !prescaled){   trigger_fired=true;}
                    // LogWarning("")<<"TrigNo: "<<i<<"  "<<found<<"
  "<<trigName<<" ---> FIRED";}
  }
  */
 
  // get the prescale set for this event
  const int prescaleSet = hltPrescaleProvider_.prescaleSet(ev, iSet);
  if (prescaleSet == -1) {
    LogTrace("") << "Failed to determine prescaleSet\n";
    // std::cout << "Failed to determine prescaleSet. Check the GlobalTag in
    // cfg\n";
    return;
  }
 
  // for (unsigned int i = 0;
  //    (i < triggerResults->size()) && (trigger_fired == false); i++) {
  // skip trigger, if it did not fire
  //if (!triggerResults->accept(i)) continue;
 
  // skip trigger, if it is not on our list
  //bool found = false;
  //const std::string trigName = trigNames.triggerName(i);
  //for (unsigned int index = 0;
  //   index < trigPathNames_.size() && found == false; index++) {
  // if (trigName.find(trigPathNames_.at(index)) == 0) found = true;
  // }
  // if (!found) continue;
 
  // skip trigger, if it is prescaled
  /* if (prescaleSet != -1) {
      if (hltConfigProvider.prescaleValue(prescaleSet, trigName) != 1)
        continue;
    } else {
      // prescaleSet is not known.
      // This branch is not needed, if prescaleSet=-1 forces to skip event
      int prescaled = 0;
      for (unsigned int ps = 0;
           !prescaled && (ps < hltConfigProvider.prescaleSize()); ++ps) {
        if (hltConfigProvider.prescaleValue(ps, trigName) != 1) {
          prescaled = 1;
        }
      }
      if (prescaled) {
        // std::cout << "trigger prescaled\n";
        continue;
      }
    }
*/
  // std::cout << "found unprescaled trigger that fired: " << trigName <<
  // "\n";
  // trigger_fired = true;
  // }
  // if (trigger_fired) std::cout << "\n\tGot Trigger\n";
 
  // trig_before_->Fill(trigger_fired);
 
  // Jet collection
  Handle<View<Jet> > jetCollection;
  if (!ev.getByToken(jetToken_, jetCollection)) {
    // LogError("") << ">>> JET collection does not exist !!!";
    return;
  }
  unsigned int jetCollectionSize = jetCollection->size();
  int njets = 0;
  int LEADJET = -1;
  double max_pt = 0;
  for (unsigned int i = 0; i < jetCollectionSize; i++) {
    const Jet& jet = jetCollection->at(i);
    double minDistance = 99999;  // This is in order to use PFJets
    for (unsigned int j = 0; j < muonCollectionSize; j++) {
      const Muon& mu = muonCollection->at(j);
      double distance =
          sqrt((mu.eta() - jet.eta()) * (mu.eta() - jet.eta()) + (mu.phi() - jet.phi()) * (mu.phi() - jet.phi()));
      if (minDistance > distance)
        minDistance = distance;
    }
    if (minDistance < 0.3)
      continue;  // 0.3 is the isolation cone around the muon
    if (jet.et() > max_pt) {
      LEADJET = i;
      max_pt = jet.et();
    }
    if (jet.et() > eJetMin_) {
      njets++;
    }
  }
 
  LogTrace("") << ">>> Total number of jets: " << jetCollectionSize;
  LogTrace("") << ">>> Number of jets above " << eJetMin_ << " [GeV]: " << njets;
  njets_before_->Fill(njets);
  double lead_jet_pt = -1;
  double lead_jet_eta = -100;
  if (LEADJET != -1) {
    const Jet& leadJet = jetCollection->at(LEADJET);
    leadingjet_pt_before_->Fill(leadJet.pt());
    leadingjet_eta_before_->Fill(leadJet.eta());
    lead_jet_pt = leadJet.pt();
    lead_jet_eta = leadJet.eta();
  }
  // Photon Collection
  Handle<View<Photon> > photonCollection;
  if (!ev.getByToken(phoTag_, photonCollection)) {
    // LogError("")
    return;
  }
  unsigned int ngam = 0;
 
  for (unsigned int i = 0; i < photonCollection->size(); i++) {
    const Photon& ph = photonCollection->at(i);
    double photonPt = ph.pt();
    if (photonPt > ptThrForPhoton_) {
      ngam++;
      phEta_->Fill(ph.eta());
    }
    phPt_->Fill(photonPt);
  }
  nph_->Fill(ngam);
  LogTrace("") << " >>> N photons " << ngam << std::endl;
 
  nmuons_->Fill(muonCollectionSize);
 
  // Start counting
  nall++;
 
  // Histograms per event should be done only once, so keep track of them
  // bool hlt_hist_done = false;
  // bool zhlt_hist_done = false;
  bool zjets_hist_done = false;
  bool zfullsel_hist_done = false;
  bool met_hist_done = false;
  bool njets_hist_done = false;
  bool wfullsel_hist_done = false;
 
  // Central W->mu nu selection criteria
  const int NFLAGS = 10;
  bool muon_sel[NFLAGS];
  const int NFLAGSZ = 12;
  bool zmuon_sel[NFLAGSZ];
  bool muon4Z = false;
 
  double number_of_muons = 0;
  double number_of_goodMuons = 0;
 
  for (unsigned int i = 0; i < muonCollectionSize; i++) {
    for (int j = 0; j < NFLAGS; ++j) {
      muon_sel[j] = false;
    }
 
    number_of_muons++;
 
    const Muon& mu = muonCollection->at(i);
    if (!mu.isGlobalMuon())
      continue;
    if (mu.globalTrack().isNull())
      continue;
    if (mu.innerTrack().isNull())
      continue;
 
    LogTrace("") << "> Wsel: processing muon number " << i << "...";
    reco::TrackRef gm = mu.globalTrack();
    reco::TrackRef tk = mu.innerTrack();
 
    // Pt,eta cuts
    double pt = mu.pt();
    double eta = mu.eta();
    LogTrace("") << "\t... pt, eta: " << pt << " [GeV], " << eta;
    ;
    if (pt > ptCut_)
      muon_sel[0] = true;
    if (fabs(eta) < etaCut_)
      muon_sel[1] = true;
 
    double charge = mu.charge();
 
    // d0, chi2, nhits quality cuts
    double dxy = gm->dxy(beamSpotHandle->position());
    double normalizedChi2 = gm->normalizedChi2();
    double trackerHits = tk->hitPattern().numberOfValidTrackerHits();
    int pixelHits = tk->hitPattern().numberOfValidPixelHits();
    int muonHits = gm->hitPattern().numberOfValidMuonHits();
    int nMatches = mu.numberOfMatches();
 
    LogTrace("") << "\t... dxy, normalizedChi2, trackerHits, isTrackerMuon?: " << dxy << " [cm], " << normalizedChi2
                 << ", " << trackerHits << ", " << mu.isTrackerMuon();
    if (fabs(dxy) < dxyCut_)
      muon_sel[2] = true;
 
    bool quality = true;
 
    if (normalizedChi2 > normalizedChi2Cut_)
      quality = false;
    if (trackerHits < trackerHitsCut_)
      quality = false;
    if (pixelHits < pixelHitsCut_)
      quality = false;
    if (muonHits < muonHitsCut_)
      quality = false;
    ;
    if (!mu.isTrackerMuon())
      quality = false;
    if (nMatches < nMatchesCut_)
      quality = false;
    muon_sel[3] = quality;
    if (quality)
      number_of_goodMuons++;
 
    pt_before_->Fill(pt);
    eta_before_->Fill(eta);
    dxy_before_->Fill(dxy);
    muoncharge_before_->Fill(charge);
    goodewkmuon_before_->Fill(quality);
 
    // Charge asymmetry
    // if (quality) {
    //  if (charge>0) ptPlus_before_->Fill(pt);
    //  if (charge<0) ptMinus_before_->Fill(pt);
    //}
 
    // Isolation cuts
    double isovar = mu.isolationR03().sumPt;
    if (isCombinedIso_) {
      isovar += mu.isolationR03().emEt;
      isovar += mu.isolationR03().hadEt;
    }
    if (isRelativeIso_)
      isovar /= pt;
    if (isovar < isoCut03_)
      muon_sel[4] = true;
 
    LogTrace("") << "\t... isolation value" << isovar << ", isolated? " << muon_sel[6];
    iso_before_->Fill(isovar);
 
    // HLT (not mtched to muon for the time being)
    // if (trigger_fired) muon_sel[5] = true;
 
    // For Z:
    if (pt > ptThrForZ1_ && fabs(eta) < etaCut_ && fabs(dxy) < dxyCut_ && quality && isovar < isoCut03_) {
      muon4Z = true;
    }
 
    // MET/MT cuts
    double w_et = met_et + mu.pt();
    double w_px = met.px() + mu.px();
    double w_py = met.py() + mu.py();
 
    double massT = w_et * w_et - w_px * w_px - w_py * w_py;
    massT = (massT > 0) ? sqrt(massT) : 0;
 
    LogTrace("") << "\t... W mass, W_et, W_px, W_py: " << massT << ", " << w_et << ", " << w_px << ", " << w_py
                 << " [GeV]";
    if (massT > mtMin_ && massT < mtMax_)
      muon_sel[5] = true;
    mt_before_->Fill(massT);
    if (met_et > metMin_ && met_et < metMax_)
      muon_sel[6] = true;
 
    // Acoplanarity cuts
    Geom::Phi<double> deltaphi(mu.phi() - atan2(met.py(), met.px()));
    double acop = deltaphi.value();
    if (acop < 0)
      acop = -acop;
    acop = M_PI - acop;
    LogTrace("") << "\t... acoplanarity: " << acop;
    if (acop < acopCut_)
      muon_sel[7] = true;
    acop_before_->Fill(acop);
 
    // Remaining flags (from global event information)
    if (nmuonsForZ1 < 1 || nmuonsForZ2 < 2)
      muon_sel[8] = true;
    if (njets <= nJetMax_)
      muon_sel[9] = true;
 
    // Collect necessary flags "per muon"
    int flags_passed = 0;
    for (int j = 0; j < NFLAGS; ++j) {
      if (muon_sel[j])
        flags_passed += 1;
    }
 
    // Do N-1 histograms now (and only once for global event quantities)
    if (flags_passed >= (NFLAGS - 1)) {
      if (!muon_sel[0] || flags_passed == NFLAGS)
        pt_after_->Fill(pt);
      if (!muon_sel[1] || flags_passed == NFLAGS)
        eta_after_->Fill(eta);
      if (!muon_sel[2] || flags_passed == NFLAGS)
        dxy_after_->Fill(dxy);
      if (!muon_sel[3] || flags_passed == NFLAGS)
        goodewkmuon_after_->Fill(quality);
      if (!muon_sel[4] || flags_passed == NFLAGS)
        iso_after_->Fill(isovar);
      // if (!muon_sel[5] || flags_passed == NFLAGS)
      //   if (!hlt_hist_done) trig_after_->Fill(trigger_fired);
      //hlt_hist_done = true;
      if (!muon_sel[5] || flags_passed == NFLAGS)
        mt_after_->Fill(massT);
      if (!muon_sel[6] || flags_passed == NFLAGS)
        if (!met_hist_done)
          met_after_->Fill(met_et);
      met_hist_done = true;
      if (!muon_sel[7] || flags_passed == NFLAGS)
        acop_after_->Fill(acop);
      // no action here for muon_sel[8]
      if (!muon_sel[9] || flags_passed == NFLAGS) {
        if (!njets_hist_done) {
          njets_after_->Fill(njets);
          leadingjet_pt_after_->Fill(lead_jet_pt);
          leadingjet_eta_after_->Fill(lead_jet_eta);
        }
        njets_hist_done = true;
      }
      if (flags_passed == NFLAGS) {
        if (!wfullsel_hist_done) {
          npvs_after_->Fill(nvvertex);
          muoncharge_after_->Fill(charge);
          // if (charge>0) ptPlus_afterW_->Fill(pt);
          // if (charge<0) ptMinus_afterW_->Fill(pt);
        }
        wfullsel_hist_done = true;
      }
    }
 
    // The cases in which the event is rejected as a Z are considered
    // independently:
    if (muon4Z && !muon_sel[8]) {
      // Plots for 2 muons
      for (unsigned int j = i + 1; j < muonCollectionSize; j++) {
        for (int ij = 0; ij < NFLAGSZ; ++ij) {
          zmuon_sel[ij] = false;
        }
 
        for (int ji = 0; ji < 5; ++ji) {
          zmuon_sel[ji] = muon_sel[ji];
        }
 
        const Muon& mu2 = muonCollection->at(j);
        if (!mu2.isGlobalMuon())
          continue;
        if (mu2.charge() * charge != -1)
          continue;
        reco::TrackRef gm2 = mu2.globalTrack();
        reco::TrackRef tk2 = mu2.innerTrack();
        double pt2 = mu2.pt();
        if (pt2 > ptThrForZ2_)
          zmuon_sel[5] = true;
        double eta2 = mu2.eta();
        if (fabs(eta2) < etaCut_)
          zmuon_sel[6] = true;
        double dxy2 = gm2->dxy(beamSpotHandle->position());
        if (fabs(dxy2) < dxyCut_)
          zmuon_sel[7] = true;
        double normalizedChi22 = gm2->normalizedChi2();
        double trackerHits2 = tk2->hitPattern().numberOfValidTrackerHits();
        int pixelHits2 = tk2->hitPattern().numberOfValidPixelHits();
        int muonHits2 = gm2->hitPattern().numberOfValidMuonHits();
        int nMatches2 = mu2.numberOfMatches();
        bool quality2 = true;
        if (normalizedChi22 > normalizedChi2Cut_)
          quality2 = false;
        if (trackerHits2 < trackerHitsCut_)
          quality2 = false;
        if (pixelHits2 < pixelHitsCut_)
          quality2 = false;
        if (muonHits2 < muonHitsCut_)
          quality2 = false;
        if (!mu2.isTrackerMuon())
          quality2 = false;
        if (nMatches2 < nMatchesCut_)
          quality2 = false;
        zmuon_sel[8] = quality2;
        double isovar2 = mu2.isolationR03().sumPt;
        if (isCombinedIso_) {
          isovar2 += mu2.isolationR03().emEt;
          isovar2 += mu2.isolationR03().hadEt;
        }
        if (isRelativeIso_)
          isovar2 /= pt2;
        if (isovar2 < isoCut03_)
          zmuon_sel[9] = true;
        //  if (trigger_fired) zmuon_sel[10] = true;
        const math::XYZTLorentzVector ZRecoGlb(
            mu.px() + mu2.px(), mu.py() + mu2.py(), mu.pz() + mu2.pz(), mu.p() + mu2.p());
        if (ZRecoGlb.mass() > dimuonMassMin_ && ZRecoGlb.mass() < dimuonMassMax_)
          zmuon_sel[10] = true;
 
        // jet flag
        if (njets <= nJetMax_)
          zmuon_sel[11] = true;
 
        // start filling histos: N-1 plots
        int flags_passed_z = 0;
 
        for (int jj = 0; jj < NFLAGSZ; ++jj) {
          if (zmuon_sel[jj])
            ++flags_passed_z;
        }
 
        if (flags_passed_z >= (NFLAGSZ - 1)) {
          if (!zmuon_sel[0] || flags_passed_z == NFLAGSZ) {
            pt1_afterZ_->Fill(pt);
          }
          if (!zmuon_sel[1] || flags_passed_z == NFLAGSZ) {
            eta1_afterZ_->Fill(eta);
          }
          if (!zmuon_sel[2] || flags_passed_z == NFLAGSZ) {
            dxy1_afterZ_->Fill(dxy);
          }
          if (!zmuon_sel[3] || flags_passed_z == NFLAGSZ) {
            goodewkmuon1_afterZ_->Fill(quality);
          }
          if (!zmuon_sel[4] || flags_passed_z == NFLAGSZ) {
            iso1_afterZ_->Fill(isovar);
          }
          if (!zmuon_sel[5] || flags_passed_z == NFLAGSZ) {
            pt2_afterZ_->Fill(pt2);
          }
          if (!zmuon_sel[6] || flags_passed_z == NFLAGSZ) {
            eta2_afterZ_->Fill(eta2);
          }
          if (!zmuon_sel[7] || flags_passed_z == NFLAGSZ) {
            dxy2_afterZ_->Fill(dxy2);
          }
          if (!zmuon_sel[8] || flags_passed_z == NFLAGSZ) {
            goodewkmuon2_afterZ_->Fill(quality2);
          }
          if (!zmuon_sel[9] || flags_passed_z == NFLAGSZ) {
            iso2_afterZ_->Fill(isovar2);
          }
          //     if (!zmuon_sel[10] || flags_passed_z == NFLAGSZ) {
          //     if (!zhlt_hist_done) ztrig_afterZ_->Fill(trigger_fired);
          //   zhlt_hist_done = true;
          //  }
          if (!zmuon_sel[10] || flags_passed_z == NFLAGSZ) {
            dimuonmass_afterZ_->Fill(ZRecoGlb.mass());
          }
          if (!zmuon_sel[11] || flags_passed_z == NFLAGSZ) {
            if (!zjets_hist_done) {
              njets_afterZ_->Fill(njets);
              leadingjet_pt_afterZ_->Fill(lead_jet_pt);
              leadingjet_eta_afterZ_->Fill(lead_jet_eta);
            }
            zjets_hist_done = true;
          }
          if (flags_passed_z == NFLAGSZ) {
            met_afterZ_->Fill(met_et);
            if (!zfullsel_hist_done) {
              npvs_afterZ_->Fill(nvvertex);
              muoncharge_afterZ_->Fill(charge);
              if (charge > 0) {
                // ptPlus_afterZ_->Fill(mu.pt());
                // ptMinus_afterZ_->Fill(mu2.pt());
                ptDiffPM_afterZ_->Fill(mu.pt() - mu2.pt());
              } else {
                // ptPlus_afterZ_->Fill(mu2.pt());
                // ptMinus_afterZ_->Fill(mu.pt());
                ptDiffPM_afterZ_->Fill(mu2.pt() - mu.pt());
              }
            }
            zfullsel_hist_done = true;
          }
        }
      }
    }
  }
 
  if (zfullsel_hist_done) {
    // here was a Z candidate
    n_zselPt1thr_->Fill(nmuonsForZ1);
    n_zselPt2thr_->Fill(nmuonsForZ2);
  }
 
  // nmuons_->Fill(number_of_muons);
  // nmuons_->Fill(muonCollectionSize);
  ngoodmuons_->Fill(number_of_goodMuons);
 
  return;
}
 
// Local Variables:
// show-trailing-whitespace: t
// truncate-lines: t
// End: