GlobalHitsAnalyzer.cc

Go to the documentation of this file.

 
#include "Geometry/Records/interface/CaloGeometryRecord.h"
 
#include "DQMServices/Core/interface/DQMStore.h"
#include "Validation/GlobalHits/interface/GlobalHitsAnalyzer.h"
 
#include "DataFormats/HcalDetId/interface/HcalDetId.h"
#include "Geometry/HcalCommonData/interface/HcalDDDRecConstants.h"
#include "Geometry/HcalCommonData/interface/HcalHitRelabeller.h"
#include "Geometry/HcalTowerAlgo/interface/HcalGeometry.h"
#include "Geometry/Records/interface/HcalRecNumberingRecord.h"
 
GlobalHitsAnalyzer::GlobalHitsAnalyzer(const edm::ParameterSet &iPSet)
    : fName(""),
      verbosity(0),
      frequency(0),
      vtxunit(0),
      label(""),
      getAllProvenances(false),
      printProvenanceInfo(false),
      testNumber(false),
      G4VtxSrc_Token_(consumes<edm::SimVertexContainer>((iPSet.getParameter<edm::InputTag>("G4VtxSrc")))),
      G4TrkSrc_Token_(consumes<edm::SimTrackContainer>(iPSet.getParameter<edm::InputTag>("G4TrkSrc"))),
      count(0) {
  consumesMany<edm::HepMCProduct>();
  std::string MsgLoggerCat = "GlobalHitsAnalyzer_GlobalHitsAnalyzer";
 
  // get information from parameter set
  fName = iPSet.getUntrackedParameter<std::string>("Name");
  verbosity = iPSet.getUntrackedParameter<int>("Verbosity");
  frequency = iPSet.getUntrackedParameter<int>("Frequency");
  vtxunit = iPSet.getUntrackedParameter<int>("VtxUnit");
  edm::ParameterSet m_Prov = iPSet.getParameter<edm::ParameterSet>("ProvenanceLookup");
  getAllProvenances = m_Prov.getUntrackedParameter<bool>("GetAllProvenances");
  printProvenanceInfo = m_Prov.getUntrackedParameter<bool>("PrintProvenanceInfo");
  testNumber = iPSet.getUntrackedParameter<bool>("testNumber");
 
  // get Labels to use to extract information
  PxlBrlLowSrc_ = iPSet.getParameter<edm::InputTag>("PxlBrlLowSrc");
  PxlBrlHighSrc_ = iPSet.getParameter<edm::InputTag>("PxlBrlHighSrc");
  PxlFwdLowSrc_ = iPSet.getParameter<edm::InputTag>("PxlFwdLowSrc");
  PxlFwdHighSrc_ = iPSet.getParameter<edm::InputTag>("PxlFwdHighSrc");
 
  SiTIBLowSrc_ = iPSet.getParameter<edm::InputTag>("SiTIBLowSrc");
  SiTIBHighSrc_ = iPSet.getParameter<edm::InputTag>("SiTIBHighSrc");
  SiTOBLowSrc_ = iPSet.getParameter<edm::InputTag>("SiTOBLowSrc");
  SiTOBHighSrc_ = iPSet.getParameter<edm::InputTag>("SiTOBHighSrc");
  SiTIDLowSrc_ = iPSet.getParameter<edm::InputTag>("SiTIDLowSrc");
  SiTIDHighSrc_ = iPSet.getParameter<edm::InputTag>("SiTIDHighSrc");
  SiTECLowSrc_ = iPSet.getParameter<edm::InputTag>("SiTECLowSrc");
  SiTECHighSrc_ = iPSet.getParameter<edm::InputTag>("SiTECHighSrc");
 
  MuonCscSrc_ = iPSet.getParameter<edm::InputTag>("MuonCscSrc");
  MuonDtSrc_ = iPSet.getParameter<edm::InputTag>("MuonDtSrc");
  MuonRpcSrc_ = iPSet.getParameter<edm::InputTag>("MuonRpcSrc");
 
  ECalEBSrc_ = iPSet.getParameter<edm::InputTag>("ECalEBSrc");
  ECalEESrc_ = iPSet.getParameter<edm::InputTag>("ECalEESrc");
  ECalESSrc_ = iPSet.getParameter<edm::InputTag>("ECalESSrc");
 
  HCalSrc_ = iPSet.getParameter<edm::InputTag>("HCalSrc");
 
  // fix for consumes
  PxlBrlLowSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("PxlBrlLowSrc"));
  PxlBrlHighSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("PxlBrlHighSrc"));
  PxlFwdLowSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("PxlFwdLowSrc"));
  PxlFwdHighSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("PxlFwdHighSrc"));
 
  SiTIBLowSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("SiTIBLowSrc"));
  SiTIBHighSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("SiTIBHighSrc"));
  SiTOBLowSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("SiTOBLowSrc"));
  SiTOBHighSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("SiTOBHighSrc"));
  SiTIDLowSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("SiTIDLowSrc"));
  SiTIDHighSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("SiTIDHighSrc"));
  SiTECLowSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("SiTECLowSrc"));
  SiTECHighSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("SiTECHighSrc"));
 
  MuonCscSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("MuonCscSrc"));
  MuonDtSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("MuonDtSrc"));
  MuonRpcSrc_Token_ = consumes<edm::PSimHitContainer>(iPSet.getParameter<edm::InputTag>("MuonRpcSrc"));
 
  ECalEBSrc_Token_ = consumes<edm::PCaloHitContainer>(iPSet.getParameter<edm::InputTag>("ECalEBSrc"));
  ECalEESrc_Token_ = consumes<edm::PCaloHitContainer>(iPSet.getParameter<edm::InputTag>("ECalEESrc"));
  ECalESSrc_Token_ = consumes<edm::PCaloHitContainer>(iPSet.getParameter<edm::InputTag>("ECalESSrc"));
  HCalSrc_Token_ = consumes<edm::PCaloHitContainer>(iPSet.getParameter<edm::InputTag>("HCalSrc"));
 
  // determine whether to process subdetector or not
  validHepMCevt = iPSet.getUntrackedParameter<bool>("validHepMCevt");
  validG4VtxContainer = iPSet.getUntrackedParameter<bool>("validG4VtxContainer");
  validG4trkContainer = iPSet.getUntrackedParameter<bool>("validG4trkContainer");
  validPxlBrlLow = iPSet.getUntrackedParameter<bool>("validPxlBrlLow", true);
  validPxlBrlHigh = iPSet.getUntrackedParameter<bool>("validPxlBrlHigh", true);
  validPxlFwdLow = iPSet.getUntrackedParameter<bool>("validPxlFwdLow", true);
  validPxlFwdHigh = iPSet.getUntrackedParameter<bool>("validPxlFwdHigh", true);
  validSiTIBLow = iPSet.getUntrackedParameter<bool>("validSiTIBLow", true);
  validSiTIBHigh = iPSet.getUntrackedParameter<bool>("validSiTIBHigh", true);
  validSiTOBLow = iPSet.getUntrackedParameter<bool>("validSiTOBLow", true);
  validSiTOBHigh = iPSet.getUntrackedParameter<bool>("validSiTOBHigh", true);
  validSiTIDLow = iPSet.getUntrackedParameter<bool>("validSiTIDLow", true);
  validSiTIDHigh = iPSet.getUntrackedParameter<bool>("validSiTIDHigh", true);
  validSiTECLow = iPSet.getUntrackedParameter<bool>("validSiTECLow", true);
  validSiTECHigh = iPSet.getUntrackedParameter<bool>("validSiTECHigh", true);
  validMuonCSC = iPSet.getUntrackedParameter<bool>("validMuonCSC", true);
  validMuonDt = iPSet.getUntrackedParameter<bool>("validMuonDt", true);
  validMuonRPC = iPSet.getUntrackedParameter<bool>("validMuonRPC", true);
  validEB = iPSet.getUntrackedParameter<bool>("validEB", true);
  validEE = iPSet.getUntrackedParameter<bool>("validEE", true);
  validPresh = iPSet.getUntrackedParameter<bool>("validPresh", true);
  validHcal = iPSet.getUntrackedParameter<bool>("validHcal", true);
 
  // use value of first digit to determine default output level (inclusive)
  // 0 is none, 1 is basic, 2 is fill output, 3 is gather output
  verbosity %= 10;
 
  // print out Parameter Set information being used
  if (verbosity >= 0) {
    edm::LogInfo(MsgLoggerCat)
        << "\n===============================\n"
        << "Initialized as EDAnalyzer with parameter values:\n"
        << "    Name                  = " << fName << "\n"
        << "    Verbosity             = " << verbosity << "\n"
        << "    Frequency             = " << frequency << "\n"
        << "    VtxUnit               = " << vtxunit << "\n"
        << "    GetProv               = " << getAllProvenances << "\n"
        << "    PrintProv             = " << printProvenanceInfo << "\n"
        << "    PxlBrlLowSrc          = " << PxlBrlLowSrc_.label() << ":" << PxlBrlLowSrc_.instance() << "\n"
        << "    PxlBrlHighSrc         = " << PxlBrlHighSrc_.label() << ":" << PxlBrlHighSrc_.instance() << "\n"
        << "    PxlFwdLowSrc          = " << PxlFwdLowSrc_.label() << ":" << PxlBrlLowSrc_.instance() << "\n"
        << "    PxlFwdHighSrc         = " << PxlFwdHighSrc_.label() << ":" << PxlBrlHighSrc_.instance() << "\n"
        << "    SiTIBLowSrc           = " << SiTIBLowSrc_.label() << ":" << SiTIBLowSrc_.instance() << "\n"
        << "    SiTIBHighSrc          = " << SiTIBHighSrc_.label() << ":" << SiTIBHighSrc_.instance() << "\n"
        << "    SiTOBLowSrc           = " << SiTOBLowSrc_.label() << ":" << SiTOBLowSrc_.instance() << "\n"
        << "    SiTOBHighSrc          = " << SiTOBHighSrc_.label() << ":" << SiTOBHighSrc_.instance() << "\n"
        << "    SiTIDLowSrc           = " << SiTIDLowSrc_.label() << ":" << SiTIDLowSrc_.instance() << "\n"
        << "    SiTIDHighSrc          = " << SiTIDHighSrc_.label() << ":" << SiTIDHighSrc_.instance() << "\n"
        << "    SiTECLowSrc           = " << SiTECLowSrc_.label() << ":" << SiTECLowSrc_.instance() << "\n"
        << "    SiTECHighSrc          = " << SiTECHighSrc_.label() << ":" << SiTECHighSrc_.instance() << "\n"
        << "    MuonCscSrc            = " << MuonCscSrc_.label() << ":" << MuonCscSrc_.instance() << "\n"
        << "    MuonDtSrc             = " << MuonDtSrc_.label() << ":" << MuonDtSrc_.instance() << "\n"
        << "    MuonRpcSrc            = " << MuonRpcSrc_.label() << ":" << MuonRpcSrc_.instance() << "\n"
        << "    ECalEBSrc             = " << ECalEBSrc_.label() << ":" << ECalEBSrc_.instance() << "\n"
        << "    ECalEESrc             = " << ECalEESrc_.label() << ":" << ECalEESrc_.instance() << "\n"
        << "    ECalESSrc             = " << ECalESSrc_.label() << ":" << ECalESSrc_.instance() << "\n"
        << "    HCalSrc               = " << HCalSrc_.label() << ":" << HCalSrc_.instance() << "\n"
        << "\n"
        << "    validHepMCevt         = "
        << ":" << validHepMCevt << "\n"
        << "    validG4VtxContainer   = "
        << ":" << validG4VtxContainer << "\n"
        << "    validG4trkContainer   = "
        << ":" << validG4trkContainer << "\n"
        << "    validPxlBrlLow        = "
        << ":" << validPxlBrlLow << "\n"
        << "    validPxlBrlHigh       = "
        << ":" << validPxlBrlHigh << "\n"
        << "    validPxlFwdLow        = "
        << ":" << validPxlFwdLow << "\n"
        << "    validPxlFwdHigh       = "
        << ":" << validPxlFwdHigh << "\n"
        << "    validSiTIBLow         = "
        << ":" << validSiTIBLow << "\n"
        << "    validSiTIBHigh        = "
        << ":" << validSiTIBHigh << "\n"
        << "    validSiTOBLow         = "
        << ":" << validSiTOBLow << "\n"
        << "    validSiTOBHigh        = "
        << ":" << validSiTOBHigh << "\n"
        << "    validSiTIDLow         = "
        << ":" << validSiTIDLow << "\n"
        << "    validSiTIDHigh        = "
        << ":" << validSiTIDHigh << "\n"
        << "    validSiTECLow         = "
        << ":" << validSiTECLow << "\n"
        << "    validSiTECHigh        = "
        << ":" << validSiTECHigh << "\n"
        << "    validMuonCSC          = "
        << ":" << validMuonCSC << "\n"
        << "    validMuonDt           = "
        << ":" << validMuonDt << "\n"
        << "    validMuonRPC          = "
        << ":" << validMuonRPC << "\n"
        << "    validEB               = "
        << ":" << validEB << "\n"
        << "    validEE               = "
        << ":" << validEE << "\n"
        << "    validPresh            = "
        << ":" << validPresh << "\n"
        << "    validHcal             = "
        << ":" << validHcal << "\n"
        << "===============================\n";
  }
 
  // initialize monitor elements
  for (Int_t i = 0; i < 2; ++i) {
    meMCRGP[i] = nullptr;
    meMCG4Vtx[i] = nullptr;
    meGeantVtxX[i] = nullptr;
    meGeantVtxY[i] = nullptr;
    meGeantVtxZ[i] = nullptr;
    meMCG4Trk[i] = nullptr;
    meCaloEcal[i] = nullptr;
    meCaloEcalE[i] = nullptr;
    meCaloEcalToF[i] = nullptr;
    meCaloPreSh[i] = nullptr;
    meCaloPreShE[i] = nullptr;
    meCaloPreShToF[i] = nullptr;
    meCaloHcal[i] = nullptr;
    meCaloHcalE[i] = nullptr;
    meCaloHcalToF[i] = nullptr;
    meTrackerPx[i] = nullptr;
    meTrackerSi[i] = nullptr;
    meMuon[i] = nullptr;
    meMuonDtToF[i] = nullptr;
    meMuonCscToF[i] = nullptr;
    meMuonRpcFToF[i] = nullptr;
    meMuonRpcBToF[i] = nullptr;
    meGeantVtxRad[i] = nullptr;
  }
  meGeantTrkPt = nullptr;
  meGeantTrkE = nullptr;
  meGeantVtxEta = nullptr;
  meGeantVtxPhi = nullptr;
  meGeantVtxMulti = nullptr;
  meCaloEcalPhi = nullptr;
  meCaloEcalEta = nullptr;
  meCaloPreShPhi = nullptr;
  meCaloPreShEta = nullptr;
  meCaloHcalPhi = nullptr;
  meCaloHcalEta = nullptr;
  meTrackerPxPhi = nullptr;
  meTrackerPxEta = nullptr;
  meTrackerPxBToF = nullptr;
  meTrackerPxBR = nullptr;
  meTrackerPxFToF = nullptr;
  meTrackerPxFZ = nullptr;
  meTrackerSiPhi = nullptr;
  meTrackerSiEta = nullptr;
  meTrackerSiBToF = nullptr;
  meTrackerSiBR = nullptr;
  meTrackerSiFToF = nullptr;
  meTrackerSiFZ = nullptr;
  meMuonPhi = nullptr;
  meMuonEta = nullptr;
  meMuonDtR = nullptr;
  meMuonCscZ = nullptr;
  meMuonRpcBR = nullptr;
  meMuonRpcFZ = nullptr;
}
 
GlobalHitsAnalyzer::~GlobalHitsAnalyzer() {}
 
void GlobalHitsAnalyzer::bookHistograms(DQMStore::IBooker &iBooker, edm::Run const &run, edm::EventSetup const &es) {
  // book histograms
  Char_t hname[200];
  Char_t htitle[200];
 
  // MCGeant
  iBooker.setCurrentFolder("GlobalHitsV/MCGeant");
  sprintf(hname, "hMCRGP1");
  sprintf(htitle, "RawGenParticles");
  meMCRGP[0] = iBooker.book1D(hname, htitle, 100, 0., 5000.);
  sprintf(hname, "hMCRGP2");
  meMCRGP[1] = iBooker.book1D(hname, htitle, 100, 0., 500.);
  for (Int_t i = 0; i < 2; ++i) {
    meMCRGP[i]->setAxisTitle("Number of Raw Generated Particles", 1);
    meMCRGP[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hMCG4Vtx1");
  sprintf(htitle, "G4 Vertices");
  meMCG4Vtx[0] = iBooker.book1D(hname, htitle, 150, 0., 15000.);
  sprintf(hname, "hMCG4Vtx2");
  meMCG4Vtx[1] = iBooker.book1D(hname, htitle, 100, -0.5, 99.5);
  for (Int_t i = 0; i < 2; ++i) {
    meMCG4Vtx[i]->setAxisTitle("Number of Vertices", 1);
    meMCG4Vtx[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hMCG4Trk1");
  sprintf(htitle, "G4 Tracks");
  meMCG4Trk[0] = iBooker.book1D(hname, htitle, 150, 0., 15000.);
  sprintf(hname, "hMCG4Trk2");
  meMCG4Trk[1] = iBooker.book1D(hname, htitle, 150, -0.5, 99.5);
  for (Int_t i = 0; i < 2; ++i) {
    meMCG4Trk[i]->setAxisTitle("Number of Tracks", 1);
    meMCG4Trk[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hGeantVtxX1");
  sprintf(htitle, "Geant vertex x/micrometer");
  meGeantVtxX[0] = iBooker.book1D(hname, htitle, 100, -8000000., 8000000.);
  sprintf(hname, "hGeantVtxX2");
  meGeantVtxX[1] = iBooker.book1D(hname, htitle, 100, -50., 50.);
  for (Int_t i = 0; i < 2; ++i) {
    meGeantVtxX[i]->setAxisTitle("x of Vertex (um)", 1);
    meGeantVtxX[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hGeantVtxY1");
  sprintf(htitle, "Geant vertex y/micrometer");
  meGeantVtxY[0] = iBooker.book1D(hname, htitle, 100, -8000000, 8000000.);
  sprintf(hname, "hGeantVtxY2");
  meGeantVtxY[1] = iBooker.book1D(hname, htitle, 100, -50., 50.);
  for (Int_t i = 0; i < 2; ++i) {
    meGeantVtxY[i]->setAxisTitle("y of Vertex (um)", 1);
    meGeantVtxY[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hGeantVtxZ1");
  sprintf(htitle, "Geant vertex z/millimeter");
  meGeantVtxZ[0] = iBooker.book1D(hname, htitle, 100, -11000., 11000.);
  sprintf(hname, "hGeantVtxZ2");
  meGeantVtxZ[1] = iBooker.book1D(hname, htitle, 200, -500., 500.);
  // meGeantVtxZ[1] = iBooker.book1D(hname,htitle,100,-250.,250.);
  for (Int_t i = 0; i < 2; ++i) {
    meGeantVtxZ[i]->setAxisTitle("z of Vertex (mm)", 1);
    meGeantVtxZ[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hGeantTrkPt");
  sprintf(htitle, "Log10 Geant track pt/GeV");
  meGeantTrkPt = iBooker.book1D(hname, htitle, 80, -4., 4.);
  meGeantTrkPt->setAxisTitle("Log10 pT of Track (GeV)", 1);
  meGeantTrkPt->setAxisTitle("Count", 2);
 
  sprintf(hname, "hGeantTrkE");
  sprintf(htitle, "Log10 Geant track E/GeV");
  meGeantTrkE = iBooker.book1D(hname, htitle, 80, -4., 4.);
  meGeantTrkE->setAxisTitle("Log10 E of Track (GeV)", 1);
  meGeantTrkE->setAxisTitle("Count", 2);
 
  sprintf(hname, "hGeantVtxEta");
  sprintf(htitle, "Geant vertices eta");
  meGeantVtxEta = iBooker.book1D(hname, htitle, 220, -5.5, 5.5);
  meGeantVtxEta->setAxisTitle("eta of SimVertex", 1);
  meGeantVtxEta->setAxisTitle("Count", 2);
 
  sprintf(hname, "hGeantVtxPhi");
  sprintf(htitle, "Geant vertices phi/rad");
  meGeantVtxPhi = iBooker.book1D(hname, htitle, 100, -3.2, 3.2);
  meGeantVtxPhi->setAxisTitle("phi of SimVertex (rad)", 1);
  meGeantVtxPhi->setAxisTitle("Count", 2);
 
  sprintf(hname, "hGeantVtxRad1");
  sprintf(htitle, "Geant vertices radius/cm");
  meGeantVtxRad[0] = iBooker.book1D(hname, htitle, 130, 0., 130.);
  sprintf(hname, "hGeantVtxRad2");
  meGeantVtxRad[1] = iBooker.book1D(hname, htitle, 100, 0., 1000.);
  for (Int_t i = 0; i < 2; ++i) {
    meGeantVtxRad[i]->setAxisTitle("radius of SimVertex (cm)", 1);
    meGeantVtxRad[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hGeantVtxMulti");
  sprintf(htitle, "Geant vertices outgoing multiplicity");
  meGeantVtxMulti = iBooker.book1D(hname, htitle, 20, 0., 20);
  meGeantVtxMulti->setAxisTitle("multiplicity of particles attached to a SimVertex", 1);
  meGeantVtxMulti->setAxisTitle("Count", 2);
 
  // ECal
  iBooker.setCurrentFolder("GlobalHitsV/ECals");
  sprintf(hname, "hCaloEcal1");
  sprintf(htitle, "Ecal hits");
  meCaloEcal[0] = iBooker.book1D(hname, htitle, 100, 0., 10000.);
  sprintf(hname, "hCaloEcal2");
  meCaloEcal[1] = iBooker.book1D(hname, htitle, 100, -0.5, 99.5);
 
  sprintf(hname, "hCaloEcalE1");
  sprintf(htitle, "Ecal hits, energy/GeV");
  meCaloEcalE[0] = iBooker.book1D(hname, htitle, 100, 0., 10.);
  sprintf(hname, "hCaloEcalE2");
  meCaloEcalE[1] = iBooker.book1D(hname, htitle, 100, 0., 0.1);
  sprintf(hname, "hCaloEcalToF1");
  sprintf(htitle, "Ecal hits, ToF/ns");
  meCaloEcalToF[0] = iBooker.book1D(hname, htitle, 100, 0., 1000.);
  sprintf(hname, "hCaloEcalToF2");
  meCaloEcalToF[1] = iBooker.book1D(hname, htitle, 100, 0., 100.);
 
  for (Int_t i = 0; i < 2; ++i) {
    meCaloEcal[i]->setAxisTitle("Number of Hits", 1);
    meCaloEcal[i]->setAxisTitle("Count", 2);
    meCaloEcalE[i]->setAxisTitle("Energy of Hits (GeV)", 1);
    meCaloEcalE[i]->setAxisTitle("Count", 2);
    meCaloEcalToF[i]->setAxisTitle("Time of Flight of Hits (ns)", 1);
    meCaloEcalToF[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hCaloEcalPhi");
  sprintf(htitle, "Ecal hits, phi/rad");
  meCaloEcalPhi = iBooker.book1D(hname, htitle, 100, -3.2, 3.2);
  meCaloEcalPhi->setAxisTitle("Phi of Hits (rad)", 1);
  meCaloEcalPhi->setAxisTitle("Count", 2);
 
  sprintf(hname, "hCaloEcalEta");
  sprintf(htitle, "Ecal hits, eta");
  meCaloEcalEta = iBooker.book1D(hname, htitle, 100, -5.5, 5.5);
  meCaloEcalEta->setAxisTitle("Eta of Hits", 1);
  meCaloEcalEta->setAxisTitle("Count", 2);
 
  sprintf(hname, "hCaloPreSh1");
  sprintf(htitle, "PreSh hits");
  meCaloPreSh[0] = iBooker.book1D(hname, htitle, 100, 0., 10000.);
  sprintf(hname, "hCaloPreSh2");
  meCaloPreSh[1] = iBooker.book1D(hname, htitle, 100, -0.5, 99.5);
 
  sprintf(hname, "hCaloPreShE1");
  sprintf(htitle, "PreSh hits, energy/GeV");
  meCaloPreShE[0] = iBooker.book1D(hname, htitle, 100, 0., 10.);
  sprintf(hname, "hCaloPreShE2");
  meCaloPreShE[1] = iBooker.book1D(hname, htitle, 100, 0., 0.1);
 
  sprintf(hname, "hCaloPreShToF1");
  sprintf(htitle, "PreSh hits, ToF/ns");
  meCaloPreShToF[0] = iBooker.book1D(hname, htitle, 100, 0., 1000.);
  sprintf(hname, "hCaloPreShToF2");
  meCaloPreShToF[1] = iBooker.book1D(hname, htitle, 100, 0., 100.);
 
  for (Int_t i = 0; i < 2; ++i) {
    meCaloPreSh[i]->setAxisTitle("Number of Hits", 1);
    meCaloPreSh[i]->setAxisTitle("Count", 2);
    meCaloPreShE[i]->setAxisTitle("Energy of Hits (GeV)", 1);
    meCaloPreShE[i]->setAxisTitle("Count", 2);
    meCaloPreShToF[i]->setAxisTitle("Time of Flight of Hits (ns)", 1);
    meCaloPreShToF[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hCaloPreShPhi");
  sprintf(htitle, "PreSh hits, phi/rad");
  meCaloPreShPhi = iBooker.book1D(hname, htitle, 100, -3.2, 3.2);
  meCaloPreShPhi->setAxisTitle("Phi of Hits (rad)", 1);
  meCaloPreShPhi->setAxisTitle("Count", 2);
 
  sprintf(hname, "hCaloPreShEta");
  sprintf(htitle, "PreSh hits, eta");
  meCaloPreShEta = iBooker.book1D(hname, htitle, 100, -5.5, 5.5);
  meCaloPreShEta->setAxisTitle("Eta of Hits", 1);
  meCaloPreShEta->setAxisTitle("Count", 2);
 
  // Hcal
  iBooker.setCurrentFolder("GlobalHitsV/HCals");
  sprintf(hname, "hCaloHcal1");
  sprintf(htitle, "Hcal hits");
  meCaloHcal[0] = iBooker.book1D(hname, htitle, 100, 0., 10000.);
  sprintf(hname, "hCaloHcal2");
  meCaloHcal[1] = iBooker.book1D(hname, htitle, 100, -0.5, 99.5);
 
  sprintf(hname, "hCaloHcalE1");
  sprintf(htitle, "Hcal hits, energy/GeV");
  meCaloHcalE[0] = iBooker.book1D(hname, htitle, 100, 0., 10.);
  sprintf(hname, "hCaloHcalE2");
  meCaloHcalE[1] = iBooker.book1D(hname, htitle, 100, 0., 0.1);
 
  sprintf(hname, "hCaloHcalToF1");
  sprintf(htitle, "Hcal hits, ToF/ns");
  meCaloHcalToF[0] = iBooker.book1D(hname, htitle, 100, 0., 1000.);
  sprintf(hname, "hCaloHcalToF2");
  meCaloHcalToF[1] = iBooker.book1D(hname, htitle, 100, 0., 100.);
 
  for (Int_t i = 0; i < 2; ++i) {
    meCaloHcal[i]->setAxisTitle("Number of Hits", 1);
    meCaloHcal[i]->setAxisTitle("Count", 2);
    meCaloHcalE[i]->setAxisTitle("Energy of Hits (GeV)", 1);
    meCaloHcalE[i]->setAxisTitle("Count", 2);
    meCaloHcalToF[i]->setAxisTitle("Time of Flight of Hits (ns)", 1);
    meCaloHcalToF[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hCaloHcalPhi");
  sprintf(htitle, "Hcal hits, phi/rad");
  meCaloHcalPhi = iBooker.book1D(hname, htitle, 100, -3.2, 3.2);
  meCaloHcalPhi->setAxisTitle("Phi of Hits (rad)", 1);
  meCaloHcalPhi->setAxisTitle("Count", 2);
 
  sprintf(hname, "hCaloHcalEta");
  sprintf(htitle, "Hcal hits, eta");
  meCaloHcalEta = iBooker.book1D(hname, htitle, 100, -5.5, 5.5);
  meCaloHcalEta->setAxisTitle("Eta of Hits", 1);
  meCaloHcalEta->setAxisTitle("Count", 2);
 
  // SiPixels
  iBooker.setCurrentFolder("GlobalHitsV/SiPixels");
  sprintf(hname, "hTrackerPx1");
  sprintf(htitle, "Pixel hits");
  meTrackerPx[0] = iBooker.book1D(hname, htitle, 100, 0., 10000.);
  sprintf(hname, "hTrackerPx2");
  meTrackerPx[1] = iBooker.book1D(hname, htitle, 100, -0.5, 99.5);
  for (Int_t i = 0; i < 2; ++i) {
    meTrackerPx[i]->setAxisTitle("Number of Pixel Hits", 1);
    meTrackerPx[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hTrackerPxPhi");
  sprintf(htitle, "Pixel hits phi/rad");
  meTrackerPxPhi = iBooker.book1D(hname, htitle, 100, -3.2, 3.2);
  meTrackerPxPhi->setAxisTitle("Phi of Hits (rad)", 1);
  meTrackerPxPhi->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerPxEta");
  sprintf(htitle, "Pixel hits eta");
  meTrackerPxEta = iBooker.book1D(hname, htitle, 100, -3.5, 3.5);
  meTrackerPxEta->setAxisTitle("Eta of Hits", 1);
  meTrackerPxEta->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerPxBToF");
  sprintf(htitle, "Pixel barrel hits, ToF/ns");
  meTrackerPxBToF = iBooker.book1D(hname, htitle, 100, 0., 40.);
  meTrackerPxBToF->setAxisTitle("Time of Flight of Hits (ns)", 1);
  meTrackerPxBToF->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerPxBR");
  sprintf(htitle, "Pixel barrel hits, R/cm");
  meTrackerPxBR = iBooker.book1D(hname, htitle, 100, 0., 50.);
  meTrackerPxBR->setAxisTitle("R of Hits (cm)", 1);
  meTrackerPxBR->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerPxFToF");
  sprintf(htitle, "Pixel forward hits, ToF/ns");
  meTrackerPxFToF = iBooker.book1D(hname, htitle, 100, 0., 50.);
  meTrackerPxFToF->setAxisTitle("Time of Flight of Hits (ns)", 1);
  meTrackerPxFToF->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerPxFZ");
  sprintf(htitle, "Pixel forward hits, Z/cm");
  meTrackerPxFZ = iBooker.book1D(hname, htitle, 200, -100., 100.);
  meTrackerPxFZ->setAxisTitle("Z of Hits (cm)", 1);
  meTrackerPxFZ->setAxisTitle("Count", 2);
 
  // SiStrips
  iBooker.setCurrentFolder("GlobalHitsV/SiStrips");
  sprintf(hname, "hTrackerSi1");
  sprintf(htitle, "Silicon hits");
  meTrackerSi[0] = iBooker.book1D(hname, htitle, 100, 0., 10000.);
  sprintf(hname, "hTrackerSi2");
  meTrackerSi[1] = iBooker.book1D(hname, htitle, 100, -0.5, 99.5);
  for (Int_t i = 0; i < 2; ++i) {
    meTrackerSi[i]->setAxisTitle("Number of Silicon Hits", 1);
    meTrackerSi[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hTrackerSiPhi");
  sprintf(htitle, "Silicon hits phi/rad");
  meTrackerSiPhi = iBooker.book1D(hname, htitle, 100, -3.2, 3.2);
  meTrackerSiPhi->setAxisTitle("Phi of Hits (rad)", 1);
  meTrackerSiPhi->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerSiEta");
  sprintf(htitle, "Silicon hits eta");
  meTrackerSiEta = iBooker.book1D(hname, htitle, 100, -3.5, 3.5);
  meTrackerSiEta->setAxisTitle("Eta of Hits", 1);
  meTrackerSiEta->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerSiBToF");
  sprintf(htitle, "Silicon barrel hits, ToF/ns");
  meTrackerSiBToF = iBooker.book1D(hname, htitle, 100, 0., 50.);
  meTrackerSiBToF->setAxisTitle("Time of Flight of Hits (ns)", 1);
  meTrackerSiBToF->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerSiBR");
  sprintf(htitle, "Silicon barrel hits, R/cm");
  meTrackerSiBR = iBooker.book1D(hname, htitle, 100, 0., 200.);
  meTrackerSiBR->setAxisTitle("R of Hits (cm)", 1);
  meTrackerSiBR->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerSiFToF");
  sprintf(htitle, "Silicon forward hits, ToF/ns");
  meTrackerSiFToF = iBooker.book1D(hname, htitle, 100, 0., 75.);
  meTrackerSiFToF->setAxisTitle("Time of Flight of Hits (ns)", 1);
  meTrackerSiFToF->setAxisTitle("Count", 2);
 
  sprintf(hname, "hTrackerSiFZ");
  sprintf(htitle, "Silicon forward hits, Z/cm");
  meTrackerSiFZ = iBooker.book1D(hname, htitle, 200, -300., 300.);
  meTrackerSiFZ->setAxisTitle("Z of Hits (cm)", 1);
  meTrackerSiFZ->setAxisTitle("Count", 2);
 
  // Muon
  iBooker.setCurrentFolder("GlobalHitsV/Muons");
  sprintf(hname, "hMuon1");
  sprintf(htitle, "Muon hits");
  meMuon[0] = iBooker.book1D(hname, htitle, 100, 0., 10000.);
  sprintf(hname, "hMuon2");
  meMuon[1] = iBooker.book1D(hname, htitle, 100, -0.5, 99.5);
  for (Int_t i = 0; i < 2; ++i) {
    meMuon[i]->setAxisTitle("Number of Muon Hits", 1);
    meMuon[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hMuonPhi");
  sprintf(htitle, "Muon hits phi/rad");
  meMuonPhi = iBooker.book1D(hname, htitle, 100, -3.2, 3.2);
  meMuonPhi->setAxisTitle("Phi of Hits (rad)", 1);
  meMuonPhi->setAxisTitle("Count", 2);
 
  sprintf(hname, "hMuonEta");
  sprintf(htitle, "Muon hits eta");
  meMuonEta = iBooker.book1D(hname, htitle, 100, -3.5, 3.5);
  meMuonEta->setAxisTitle("Eta of Hits", 1);
  meMuonEta->setAxisTitle("Count", 2);
 
  sprintf(hname, "hMuonCscToF1");
  sprintf(htitle, "Muon CSC hits, ToF/ns");
  meMuonCscToF[0] = iBooker.book1D(hname, htitle, 100, 0., 250.);
  sprintf(hname, "hMuonCscToF2");
  meMuonCscToF[1] = iBooker.book1D(hname, htitle, 100, 0., 50.);
  for (Int_t i = 0; i < 2; ++i) {
    meMuonCscToF[i]->setAxisTitle("Time of Flight of Hits (ns)", 1);
    meMuonCscToF[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hMuonCscZ");
  sprintf(htitle, "Muon CSC hits, Z/cm");
  meMuonCscZ = iBooker.book1D(hname, htitle, 200, -1500., 1500.);
  meMuonCscZ->setAxisTitle("Z of Hits (cm)", 1);
  meMuonCscZ->setAxisTitle("Count", 2);
 
  sprintf(hname, "hMuonDtToF1");
  sprintf(htitle, "Muon DT hits, ToF/ns");
  meMuonDtToF[0] = iBooker.book1D(hname, htitle, 100, 0., 250.);
  sprintf(hname, "hMuonDtToF2");
  meMuonDtToF[1] = iBooker.book1D(hname, htitle, 100, 0., 50.);
  for (Int_t i = 0; i < 2; ++i) {
    meMuonDtToF[i]->setAxisTitle("Time of Flight of Hits (ns)", 1);
    meMuonDtToF[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hMuonDtR");
  sprintf(htitle, "Muon DT hits, R/cm");
  meMuonDtR = iBooker.book1D(hname, htitle, 100, 0., 1500.);
  meMuonDtR->setAxisTitle("R of Hits (cm)", 1);
  meMuonDtR->setAxisTitle("Count", 2);
 
  sprintf(hname, "hMuonRpcFToF1");
  sprintf(htitle, "Muon RPC forward hits, ToF/ns");
  meMuonRpcFToF[0] = iBooker.book1D(hname, htitle, 100, 0., 250.);
  sprintf(hname, "hMuonRpcFToF2");
  meMuonRpcFToF[1] = iBooker.book1D(hname, htitle, 100, 0., 50.);
  for (Int_t i = 0; i < 2; ++i) {
    meMuonRpcFToF[i]->setAxisTitle("Time of Flight of Hits (ns)", 1);
    meMuonRpcFToF[i]->setAxisTitle("Count", 2);
  }
  sprintf(hname, "hMuonRpcFZ");
  sprintf(htitle, "Muon RPC forward hits, Z/cm");
  meMuonRpcFZ = iBooker.book1D(hname, htitle, 201, -1500., 1500.);
  meMuonRpcFZ->setAxisTitle("Z of Hits (cm)", 1);
  meMuonRpcFZ->setAxisTitle("Count", 2);
 
  sprintf(hname, "hMuonRpcBToF1");
  sprintf(htitle, "Muon RPC barrel hits, ToF/ns");
  meMuonRpcBToF[0] = iBooker.book1D(hname, htitle, 100, 0., 250.);
  sprintf(hname, "hMuonRpcBToF2");
  meMuonRpcBToF[1] = iBooker.book1D(hname, htitle, 100, 0., 50.);
  for (Int_t i = 0; i < 2; ++i) {
    meMuonRpcBToF[i]->setAxisTitle("Time of Flight of Hits (ns)", 1);
    meMuonRpcBToF[i]->setAxisTitle("Count", 2);
  }
 
  sprintf(hname, "hMuonRpcBR");
  sprintf(htitle, "Muon RPC barrel hits, R/cm");
  meMuonRpcBR = iBooker.book1D(hname, htitle, 100, 0., 1500.);
  meMuonRpcBR->setAxisTitle("R of Hits (cm)", 1);
  meMuonRpcBR->setAxisTitle("Count", 2);
}
 
void GlobalHitsAnalyzer::analyze(const edm::Event &iEvent, const edm::EventSetup &iSetup) {
  std::string MsgLoggerCat = "GlobalHitsAnalyzer_analyze";
 
  // keep track of number of events processed
  ++count;
 
  // get event id information
  edm::RunNumber_t nrun = iEvent.id().run();
  edm::EventNumber_t nevt = iEvent.id().event();
 
  if (verbosity > 0) {
    edm::LogInfo(MsgLoggerCat) << "Processing run " << nrun << ", event " << nevt << " (" << count << " events total)";
  } else if (verbosity == 0) {
    if (nevt % frequency == 0 || nevt == 1) {
      edm::LogInfo(MsgLoggerCat) << "Processing run " << nrun << ", event " << nevt << " (" << count
                                 << " events total)";
    }
  }
 
  // look at information available in the event
  if (getAllProvenances) {
    std::vector<const edm::StableProvenance *> AllProv;
    iEvent.getAllStableProvenance(AllProv);
 
    if (verbosity >= 0)
      edm::LogInfo(MsgLoggerCat) << "Number of Provenances = " << AllProv.size();
 
    if (printProvenanceInfo && (verbosity >= 0)) {
      TString eventout("\nProvenance info:\n");
 
      for (unsigned int i = 0; i < AllProv.size(); ++i) {
        eventout += "\n       ******************************";
        eventout += "\n       Module       : ";
        eventout += AllProv[i]->moduleLabel();
        eventout += "\n       ProductID    : ";
        eventout += AllProv[i]->productID().id();
        eventout += "\n       ClassName    : ";
        eventout += AllProv[i]->className();
        eventout += "\n       InstanceName : ";
        eventout += AllProv[i]->productInstanceName();
        eventout += "\n       BranchName   : ";
        eventout += AllProv[i]->branchName();
      }
      eventout += "\n       ******************************\n";
      edm::LogInfo(MsgLoggerCat) << eventout << "\n";
      printProvenanceInfo = false;
    }
    getAllProvenances = false;
  }
 
  // call fill functions
  // gather G4MC information from event
  fillG4MC(iEvent);
  // gather Tracker information from event
  fillTrk(iEvent, iSetup);
  // gather muon information from event
  fillMuon(iEvent, iSetup);
  // gather Ecal information from event
  fillECal(iEvent, iSetup);
  // gather Hcal information from event
  fillHCal(iEvent, iSetup);
 
  if (verbosity > 0)
    edm::LogInfo(MsgLoggerCat) << "Done gathering data from event.";
 
  return;
}
 
//==================fill and store functions================================
void GlobalHitsAnalyzer::fillG4MC(const edm::Event &iEvent) {
  std::string MsgLoggerCat = "GlobalHitsAnalyzer_fillG4MC";
 
  TString eventout;
  if (verbosity > 0)
    eventout = "\nGathering info:";
 
  // get MC information
  edm::Handle<edm::HepMCProduct> HepMCEvt;
  std::vector<edm::Handle<edm::HepMCProduct>> AllHepMCEvt;
  iEvent.getManyByType(AllHepMCEvt);
 
  // loop through products and extract VtxSmearing if available. Any of them
  // should have the information needed
  for (unsigned int i = 0; i < AllHepMCEvt.size(); ++i) {
    HepMCEvt = AllHepMCEvt[i];
    if ((HepMCEvt.provenance()->branchDescription()).moduleLabel() == "generatorSmeared")
      break;
  }
 
  if (!HepMCEvt.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find HepMCProduct in event!";
    validHepMCevt = false;
  } else {
    eventout += "\n          Using HepMCProduct: ";
    eventout += (HepMCEvt.provenance()->branchDescription()).moduleLabel();
  }
  if (validHepMCevt) {
    const HepMC::GenEvent *MCEvt = HepMCEvt->GetEvent();
    nRawGenPart = MCEvt->particles_size();
 
    if (verbosity > 1) {
      eventout += "\n          Number of Raw Particles collected:......... ";
      eventout += nRawGenPart;
    }
 
    if (meMCRGP[0])
      meMCRGP[0]->Fill((float)nRawGenPart);
    if (meMCRGP[1])
      meMCRGP[1]->Fill((float)nRawGenPart);
  }
 
  // get G4Vertex information
  // convert unit stored in SimVertex to mm
  float unit = 0.;
  if (vtxunit == 0)
    unit = 1.;  // already in mm
  if (vtxunit == 1)
    unit = 10.;  // stored in cm, convert to mm
 
  edm::Handle<edm::SimVertexContainer> G4VtxContainer;
  iEvent.getByToken(G4VtxSrc_Token_, G4VtxContainer);
 
  // needed here by vertex multiplicity
  edm::Handle<edm::SimTrackContainer> G4TrkContainer;
  iEvent.getByToken(G4TrkSrc_Token_, G4TrkContainer);
 
  if (!G4VtxContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find SimVertex in event!";
    validG4VtxContainer = false;
  }
  if (validG4VtxContainer) {
    int i = 0;
    edm::SimVertexContainer::const_iterator itVtx;
    for (itVtx = G4VtxContainer->begin(); itVtx != G4VtxContainer->end(); ++itVtx) {
      ++i;
 
      const math::XYZTLorentzVector G4Vtx1(
          itVtx->position().x(), itVtx->position().y(), itVtx->position().z(), itVtx->position().e());
 
      double G4Vtx[4];
      G4Vtx1.GetCoordinates(G4Vtx);
 
      if (meGeantVtxX[0])
        meGeantVtxX[0]->Fill((G4Vtx[0] * unit) / micrometer);
      if (meGeantVtxX[1])
        meGeantVtxX[1]->Fill((G4Vtx[0] * unit) / micrometer);
 
      if (meGeantVtxY[0])
        meGeantVtxY[0]->Fill((G4Vtx[1] * unit) / micrometer);
      if (meGeantVtxY[1])
        meGeantVtxY[1]->Fill((G4Vtx[1] * unit) / micrometer);
 
      if (meGeantVtxZ[0])
        meGeantVtxZ[0]->Fill((G4Vtx[2] * unit) / millimeter);
      if (meGeantVtxZ[1])
        meGeantVtxZ[1]->Fill((G4Vtx[2] * unit) / millimeter);
 
      if (meGeantVtxEta)
        meGeantVtxEta->Fill(G4Vtx1.eta());
      if (meGeantVtxPhi)
        meGeantVtxPhi->Fill(G4Vtx1.phi());
      if (meGeantVtxRad[0])
        meGeantVtxRad[0]->Fill(G4Vtx1.rho());
      if (meGeantVtxRad[1])
        meGeantVtxRad[1]->Fill(G4Vtx1.rho());
 
      if (meGeantVtxMulti) {
        int multi = 0;
        if (G4TrkContainer.isValid()) {
          edm::SimTrackContainer::const_iterator itTrk;
          for (itTrk = G4TrkContainer->begin(); itTrk != G4TrkContainer->end(); ++itTrk) {
            if ((*itTrk).vertIndex() == i) {
              multi++;
            }
          }
        }
        meGeantVtxMulti->Fill(((double)multi + 0.5));
      }
    }
 
    if (verbosity > 1) {
      eventout += "\n          Number of G4Vertices collected:............ ";
      eventout += i;
    }
 
    if (meMCG4Vtx[0])
      meMCG4Vtx[0]->Fill((float)i);
    if (meMCG4Vtx[1])
      meMCG4Vtx[1]->Fill((float)i);
  }
 
  // get G4Track information
  if (!G4TrkContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find SimTrack in event!";
    validG4trkContainer = false;
  }
  if (validG4trkContainer) {
    int i = 0;
    edm::SimTrackContainer::const_iterator itTrk;
    for (itTrk = G4TrkContainer->begin(); itTrk != G4TrkContainer->end(); ++itTrk) {
      ++i;
 
      const math::XYZTLorentzVector G4Trk1(
          itTrk->momentum().x(), itTrk->momentum().y(), itTrk->momentum().z(), itTrk->momentum().e());
      double G4Trk[4];
      G4Trk1.GetCoordinates(G4Trk);
 
      if (meGeantTrkPt)
        meGeantTrkPt->Fill(std::log10(std::max(sqrt(G4Trk[0] * G4Trk[0] + G4Trk[1] * G4Trk[1]), -9.)));
      if (meGeantTrkE)
        meGeantTrkE->Fill(std::log10(std::max(G4Trk[3], -9.)));
    }
 
    if (verbosity > 1) {
      eventout += "\n          Number of G4Tracks collected:.............. ";
      eventout += i;
    }
 
    if (meMCG4Trk[0])
      meMCG4Trk[0]->Fill((float)i);
    if (meMCG4Trk[1])
      meMCG4Trk[1]->Fill((float)i);
  }
 
  if (verbosity > 0)
    edm::LogInfo(MsgLoggerCat) << eventout << "\n";
 
  return;
}
 
void GlobalHitsAnalyzer::fillTrk(const edm::Event &iEvent, const edm::EventSetup &iSetup) {
  nPxlHits = 0;
  std::string MsgLoggerCat = "GlobalHitsAnalyzer_fillTrk";
 
  TString eventout;
  if (verbosity > 0)
    eventout = "\nGathering info:";
 
  // access the tracker geometry
  edm::ESHandle<TrackerGeometry> theTrackerGeometry;
  iSetup.get<TrackerDigiGeometryRecord>().get(theTrackerGeometry);
  if (!theTrackerGeometry.isValid()) {
    edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerDigiGeometryRecord in event!";
    return;
  }
  const TrackerGeometry &theTracker(*theTrackerGeometry);
 
  // iterator to access containers
  edm::PSimHitContainer::const_iterator itHit;
 
  // get Pixel Barrel information
  edm::PSimHitContainer thePxlBrlHits;
  // extract low container
  edm::Handle<edm::PSimHitContainer> PxlBrlLowContainer;
  iEvent.getByToken(PxlBrlLowSrc_Token_, PxlBrlLowContainer);
  if (!PxlBrlLowContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsPixelBarrelLowTof in event!";
    validPxlBrlLow = false;
  }
  // extract high container
  edm::Handle<edm::PSimHitContainer> PxlBrlHighContainer;
  iEvent.getByToken(PxlBrlHighSrc_Token_, PxlBrlHighContainer);
  if (!PxlBrlHighContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsPixelBarrelHighTof in event!";
    validPxlBrlHigh = false;
  }
  // place both containers into new container
  if (validPxlBrlLow)
    thePxlBrlHits.insert(thePxlBrlHits.end(), PxlBrlLowContainer->begin(), PxlBrlLowContainer->end());
  if (validPxlBrlHigh)
    thePxlBrlHits.insert(thePxlBrlHits.end(), PxlBrlHighContainer->begin(), PxlBrlHighContainer->end());
 
  // cycle through new container
  int i = 0, j = 0;
  for (itHit = thePxlBrlHits.begin(); itHit != thePxlBrlHits.end(); ++itHit) {
    ++i;
 
    // create a DetId from the detUnitId
    DetId theDetUnitId(itHit->detUnitId());
    int detector = theDetUnitId.det();
    int subdetector = theDetUnitId.subdetId();
 
    // check that expected detector is returned
    if ((detector == dTrk) && (subdetector == sdPxlBrl)) {
      // get the GeomDetUnit from the geometry using theDetUnitID
      const GeomDetUnit *theDet = theTracker.idToDetUnit(theDetUnitId);
 
      if (!theDet) {
        edm::LogWarning(MsgLoggerCat) << "Unable to get GeomDetUnit from PxlBrlHits for Hit " << i;
        continue;
      }
 
      ++j;
 
      // get the Surface of the hit (knows how to go from local <-> global)
      const BoundPlane &bSurface = theDet->surface();
 
      if (meTrackerPxBToF)
        meTrackerPxBToF->Fill(itHit->tof());
      if (meTrackerPxBR)
        meTrackerPxBR->Fill(bSurface.toGlobal(itHit->localPosition()).perp());
      if (meTrackerPxPhi)
        meTrackerPxPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi());
      if (meTrackerPxEta)
        meTrackerPxEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta());
 
    } else {
      edm::LogWarning(MsgLoggerCat) << "PxlBrl PSimHit " << i << " is expected to be (det,subdet) = (" << dTrk << ","
                                    << sdPxlBrl << "); value returned is: (" << detector << "," << subdetector << ")";
      continue;
    }  // end detector type check
  }    // end loop through PxlBrl Hits
 
  if (verbosity > 1) {
    eventout += "\n          Number of Pixel Barrel Hits collected:..... ";
    eventout += j;
  }
 
  nPxlHits += j;
 
  // get Pixel Forward information
  edm::PSimHitContainer thePxlFwdHits;
  // extract low container
  edm::Handle<edm::PSimHitContainer> PxlFwdLowContainer;
  iEvent.getByToken(PxlFwdLowSrc_Token_, PxlFwdLowContainer);
  if (!PxlFwdLowContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsPixelEndcapLowTof in event!";
    validPxlFwdLow = false;
  }
  // extract high container
  edm::Handle<edm::PSimHitContainer> PxlFwdHighContainer;
  iEvent.getByToken(PxlFwdHighSrc_Token_, PxlFwdHighContainer);
  if (!PxlFwdHighContainer.isValid()) {
    LogDebug("GlobalHitsAnalyzer_fillTrk") << "Unable to find TrackerHitsPixelEndcapHighTof in event!";
    validPxlFwdHigh = false;
  }
  // place both containers into new container
  if (validPxlFwdLow)
    thePxlFwdHits.insert(thePxlFwdHits.end(), PxlFwdLowContainer->begin(), PxlFwdLowContainer->end());
  if (validPxlFwdHigh)
    thePxlFwdHits.insert(thePxlFwdHits.end(), PxlFwdHighContainer->begin(), PxlFwdHighContainer->end());
 
  // cycle through new container
  i = 0;
  j = 0;
  for (itHit = thePxlFwdHits.begin(); itHit != thePxlFwdHits.end(); ++itHit) {
    ++i;
 
    // create a DetId from the detUnitId
    DetId theDetUnitId(itHit->detUnitId());
    int detector = theDetUnitId.det();
    int subdetector = theDetUnitId.subdetId();
 
    // check that expected detector is returned
    if ((detector == dTrk) && (subdetector == sdPxlFwd)) {
      // get the GeomDetUnit from the geometry using theDetUnitID
      const GeomDetUnit *theDet = theTracker.idToDetUnit(theDetUnitId);
 
      if (!theDet) {
        edm::LogWarning(MsgLoggerCat) << "Unable to get GeomDetUnit from PxlFwdHits for Hit " << i;
        ;
        continue;
      }
 
      ++j;
 
      // get the Surface of the hit (knows how to go from local <-> global)
      const BoundPlane &bSurface = theDet->surface();
 
      if (meTrackerPxFToF)
        meTrackerPxFToF->Fill(itHit->tof());
      if (meTrackerPxFZ)
        meTrackerPxFZ->Fill(bSurface.toGlobal(itHit->localPosition()).z());
      if (meTrackerPxPhi)
        meTrackerPxPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi());
      if (meTrackerPxEta)
        meTrackerPxEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta());
 
    } else {
      edm::LogWarning(MsgLoggerCat) << "PxlFwd PSimHit " << i << " is expected to be (det,subdet) = (" << dTrk << ","
                                    << sdPxlFwd << "); value returned is: (" << detector << "," << subdetector << ")";
      continue;
    }  // end detector type check
  }    // end loop through PxlFwd Hits
 
  if (verbosity > 1) {
    eventout += "\n          Number of Pixel Forward Hits collected:.... ";
    eventout += j;
  }
 
  nPxlHits += j;
 
  if (meTrackerPx[0])
    meTrackerPx[0]->Fill((float)nPxlHits);
  if (meTrackerPx[1])
    meTrackerPx[1]->Fill((float)nPxlHits);
 
  // get Silicon Barrel information
  nSiHits = 0;
  edm::PSimHitContainer theSiBrlHits;
  // extract TIB low container
  edm::Handle<edm::PSimHitContainer> SiTIBLowContainer;
  iEvent.getByToken(SiTIBLowSrc_Token_, SiTIBLowContainer);
  if (!SiTIBLowContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsTIBLowTof in event!";
    validSiTIBLow = false;
  }
  // extract TIB high container
  edm::Handle<edm::PSimHitContainer> SiTIBHighContainer;
  iEvent.getByToken(SiTIBHighSrc_Token_, SiTIBHighContainer);
  if (!SiTIBHighContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsTIBHighTof in event!";
    validSiTIBHigh = false;
  }
  // extract TOB low container
  edm::Handle<edm::PSimHitContainer> SiTOBLowContainer;
  iEvent.getByToken(SiTOBLowSrc_Token_, SiTOBLowContainer);
  if (!SiTOBLowContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsTOBLowTof in event!";
    validSiTOBLow = false;
  }
  // extract TOB high container
  edm::Handle<edm::PSimHitContainer> SiTOBHighContainer;
  iEvent.getByToken(SiTOBHighSrc_Token_, SiTOBHighContainer);
  if (!SiTOBHighContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsTOBHighTof in event!";
    validSiTOBHigh = false;
  }
  // place all containers into new container
  if (validSiTIBLow)
    theSiBrlHits.insert(theSiBrlHits.end(), SiTIBLowContainer->begin(), SiTIBLowContainer->end());
  if (validSiTIBHigh)
    theSiBrlHits.insert(theSiBrlHits.end(), SiTIBHighContainer->begin(), SiTIBHighContainer->end());
  if (validSiTOBLow)
    theSiBrlHits.insert(theSiBrlHits.end(), SiTOBLowContainer->begin(), SiTOBLowContainer->end());
  if (validSiTOBHigh)
    theSiBrlHits.insert(theSiBrlHits.end(), SiTOBHighContainer->begin(), SiTOBHighContainer->end());
 
  // cycle through new container
  i = 0;
  j = 0;
  for (itHit = theSiBrlHits.begin(); itHit != theSiBrlHits.end(); ++itHit) {
    ++i;
 
    // create a DetId from the detUnitId
    DetId theDetUnitId(itHit->detUnitId());
    int detector = theDetUnitId.det();
    int subdetector = theDetUnitId.subdetId();
 
    // check that expected detector is returned
    if ((detector == dTrk) && ((subdetector == sdSiTIB) || (subdetector == sdSiTOB))) {
      // get the GeomDetUnit from the geometry using theDetUnitID
      const GeomDetUnit *theDet = theTracker.idToDetUnit(theDetUnitId);
 
      if (!theDet) {
        edm::LogWarning(MsgLoggerCat) << "Unable to get GeomDetUnit from SiBrlHits for Hit " << i;
        continue;
      }
 
      ++j;
 
      // get the Surface of the hit (knows how to go from local <-> global)
      const BoundPlane &bSurface = theDet->surface();
 
      if (meTrackerSiBToF)
        meTrackerSiBToF->Fill(itHit->tof());
      if (meTrackerSiBR)
        meTrackerSiBR->Fill(bSurface.toGlobal(itHit->localPosition()).perp());
      if (meTrackerSiPhi)
        meTrackerSiPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi());
      if (meTrackerSiEta)
        meTrackerSiEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta());
 
    } else {
      edm::LogWarning(MsgLoggerCat) << "SiBrl PSimHit " << i << " is expected to be (det,subdet) = (" << dTrk << ","
                                    << sdSiTIB << " || " << sdSiTOB << "); value returned is: (" << detector << ","
                                    << subdetector << ")";
      continue;
    }  // end detector type check
  }    // end loop through SiBrl Hits
 
  if (verbosity > 1) {
    eventout += "\n          Number of Silicon Barrel Hits collected:... ";
    eventout += j;
  }
 
  nSiHits += j;
 
  // get Silicon Forward information
  edm::PSimHitContainer theSiFwdHits;
  // extract TID low container
  edm::Handle<edm::PSimHitContainer> SiTIDLowContainer;
  iEvent.getByToken(SiTIDLowSrc_Token_, SiTIDLowContainer);
  if (!SiTIDLowContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsTIDLowTof in event!";
    validSiTIDLow = false;
  }
  // extract TID high container
  edm::Handle<edm::PSimHitContainer> SiTIDHighContainer;
  iEvent.getByToken(SiTIDHighSrc_Token_, SiTIDHighContainer);
  if (!SiTIDHighContainer.isValid()) {
    LogDebug("GlobalHitsAnalyzer_fillTrk") << "Unable to find TrackerHitsTIDHighTof in event!";
    validSiTIDHigh = false;
  }
  // extract TEC low container
  edm::Handle<edm::PSimHitContainer> SiTECLowContainer;
  iEvent.getByToken(SiTECLowSrc_Token_, SiTECLowContainer);
  if (!SiTECLowContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsTECLowTof in event!";
    validSiTECLow = false;
  }
  // extract TEC high container
  edm::Handle<edm::PSimHitContainer> SiTECHighContainer;
  iEvent.getByToken(SiTECHighSrc_Token_, SiTECHighContainer);
  if (!SiTECHighContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find TrackerHitsTECHighTof in event!";
    validSiTECHigh = false;
  }
  // place all containers into new container
  if (validSiTIDLow)
    theSiFwdHits.insert(theSiFwdHits.end(), SiTIDLowContainer->begin(), SiTIDLowContainer->end());
  if (validSiTIDHigh)
    theSiFwdHits.insert(theSiFwdHits.end(), SiTIDHighContainer->begin(), SiTIDHighContainer->end());
  if (validSiTECLow)
    theSiFwdHits.insert(theSiFwdHits.end(), SiTECLowContainer->begin(), SiTECLowContainer->end());
  if (validSiTECHigh)
    theSiFwdHits.insert(theSiFwdHits.end(), SiTECHighContainer->begin(), SiTECHighContainer->end());
 
  // cycle through container
  i = 0;
  j = 0;
  for (itHit = theSiFwdHits.begin(); itHit != theSiFwdHits.end(); ++itHit) {
    ++i;
 
    // create a DetId from the detUnitId
    DetId theDetUnitId(itHit->detUnitId());
    int detector = theDetUnitId.det();
    int subdetector = theDetUnitId.subdetId();
 
    // check that expected detector is returned
    if ((detector == dTrk) && ((subdetector == sdSiTID) || (subdetector == sdSiTEC))) {
      // get the GeomDetUnit from the geometry using theDetUnitID
      const GeomDetUnit *theDet = theTracker.idToDetUnit(theDetUnitId);
 
      if (!theDet) {
        edm::LogWarning(MsgLoggerCat) << "Unable to get GeomDetUnit from SiFwdHits Hit " << i;
        return;
      }
 
      ++j;
 
      // get the Surface of the hit (knows how to go from local <-> global)
      const BoundPlane &bSurface = theDet->surface();
 
      if (meTrackerSiFToF)
        meTrackerSiFToF->Fill(itHit->tof());
      if (meTrackerSiFZ)
        meTrackerSiFZ->Fill(bSurface.toGlobal(itHit->localPosition()).z());
      if (meTrackerSiPhi)
        meTrackerSiPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi());
      if (meTrackerSiEta)
        meTrackerSiEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta());
 
    } else {
      edm::LogWarning(MsgLoggerCat) << "SiFwd PSimHit " << i << " is expected to be (det,subdet) = (" << dTrk << ","
                                    << sdSiTOB << " || " << sdSiTEC << "); value returned is: (" << detector << ","
                                    << subdetector << ")";
      continue;
    }  // end check detector type
  }    // end loop through SiFwd Hits
 
  if (verbosity > 1) {
    eventout += "\n          Number of Silicon Forward Hits collected:.. ";
    eventout += j;
  }
 
  nSiHits += j;
 
  if (meTrackerSi[0])
    meTrackerSi[0]->Fill((float)nSiHits);
  if (meTrackerSi[1])
    meTrackerSi[1]->Fill((float)nSiHits);
 
  if (verbosity > 0)
    edm::LogInfo(MsgLoggerCat) << eventout << "\n";
 
  return;
}
 
void GlobalHitsAnalyzer::fillMuon(const edm::Event &iEvent, const edm::EventSetup &iSetup) {
  nMuonHits = 0;
  std::string MsgLoggerCat = "GlobalHitsAnalyzer_fillMuon";
 
  TString eventout;
  if (verbosity > 0)
    eventout = "\nGathering info:";
 
  // iterator to access containers
  edm::PSimHitContainer::const_iterator itHit;
 
  // access the CSC Muon
  // access the CSC Muon geometry
  edm::ESHandle<CSCGeometry> theCSCGeometry;
  iSetup.get<MuonGeometryRecord>().get(theCSCGeometry);
  if (!theCSCGeometry.isValid()) {
    edm::LogWarning(MsgLoggerCat) << "Unable to find MuonGeometryRecord for the CSCGeometry in event!";
    return;
  }
  const CSCGeometry &theCSCMuon(*theCSCGeometry);
 
  // get Muon CSC information
  edm::Handle<edm::PSimHitContainer> MuonCSCContainer;
  iEvent.getByToken(MuonCscSrc_Token_, MuonCSCContainer);
  if (!MuonCSCContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find MuonCSCHits in event!";
    validMuonCSC = false;
  }
 
  if (validMuonCSC) {
    // cycle through container
    int i = 0, j = 0;
    for (itHit = MuonCSCContainer->begin(); itHit != MuonCSCContainer->end(); ++itHit) {
      ++i;
 
      // create a DetId from the detUnitId
      DetId theDetUnitId(itHit->detUnitId());
      int detector = theDetUnitId.det();
      int subdetector = theDetUnitId.subdetId();
 
      // check that expected detector is returned
      if ((detector == dMuon) && (subdetector == sdMuonCSC)) {
        // get the GeomDetUnit from the geometry using theDetUnitID
        const GeomDetUnit *theDet = theCSCMuon.idToDetUnit(theDetUnitId);
 
        if (!theDet) {
          edm::LogWarning(MsgLoggerCat) << "Unable to get GeomDetUnit from theCSCMuon for hit " << i;
          continue;
        }
 
        ++j;
 
        // get the Surface of the hit (knows how to go from local <-> global)
        const BoundPlane &bSurface = theDet->surface();
 
        if (meMuonCscToF[0])
          meMuonCscToF[0]->Fill(itHit->tof());
        if (meMuonCscToF[1])
          meMuonCscToF[1]->Fill(itHit->tof());
        if (meMuonCscZ)
          meMuonCscZ->Fill(bSurface.toGlobal(itHit->localPosition()).z());
        if (meMuonPhi)
          meMuonPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi());
        if (meMuonEta)
          meMuonEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta());
 
      } else {
        edm::LogWarning(MsgLoggerCat) << "MuonCsc PSimHit " << i << " is expected to be (det,subdet) = (" << dMuon
                                      << "," << sdMuonCSC << "); value returned is: (" << detector << "," << subdetector
                                      << ")";
        continue;
      }  // end detector type check
    }    // end loop through CSC Hits
 
    if (verbosity > 1) {
      eventout += "\n          Number of CSC muon Hits collected:......... ";
      eventout += j;
    }
 
    nMuonHits += j;
  }
 
  // access the DT Muon
  // access the DT Muon geometry
  edm::ESHandle<DTGeometry> theDTGeometry;
  iSetup.get<MuonGeometryRecord>().get(theDTGeometry);
  if (!theDTGeometry.isValid()) {
    edm::LogWarning(MsgLoggerCat) << "Unable to find MuonGeometryRecord for the DTGeometry in event!";
    return;
  }
  const DTGeometry &theDTMuon(*theDTGeometry);
 
  // get Muon DT information
  edm::Handle<edm::PSimHitContainer> MuonDtContainer;
  iEvent.getByToken(MuonDtSrc_Token_, MuonDtContainer);
  if (!MuonDtContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find MuonDTHits in event!";
    validMuonDt = false;
  }
 
  if (validMuonDt) {
    // cycle through container
    int i = 0, j = 0;
    for (itHit = MuonDtContainer->begin(); itHit != MuonDtContainer->end(); ++itHit) {
      ++i;
 
      // create a DetId from the detUnitId
      DetId theDetUnitId(itHit->detUnitId());
      int detector = theDetUnitId.det();
      int subdetector = theDetUnitId.subdetId();
 
      // check that expected detector is returned
      if ((detector == dMuon) && (subdetector == sdMuonDT)) {
        // CSC uses wires and layers rather than the full detID
        // get the wireId
        DTWireId wireId(itHit->detUnitId());
 
        // get the DTLayer from the geometry using the wireID
        const DTLayer *theDet = theDTMuon.layer(wireId.layerId());
 
        if (!theDet) {
          edm::LogWarning(MsgLoggerCat) << "Unable to get GeomDetUnit from theDtMuon for hit " << i;
          continue;
        }
 
        ++j;
 
        // get the Surface of the hit (knows how to go from local <-> global)
        const BoundPlane &bSurface = theDet->surface();
 
        if (meMuonDtToF[0])
          meMuonDtToF[0]->Fill(itHit->tof());
        if (meMuonDtToF[1])
          meMuonDtToF[1]->Fill(itHit->tof());
        if (meMuonDtR)
          meMuonDtR->Fill(bSurface.toGlobal(itHit->localPosition()).perp());
        if (meMuonPhi)
          meMuonPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi());
        if (meMuonEta)
          meMuonEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta());
 
      } else {
        edm::LogWarning(MsgLoggerCat) << "MuonDt PSimHit " << i << " is expected to be (det,subdet) = (" << dMuon << ","
                                      << sdMuonDT << "); value returned is: (" << detector << "," << subdetector << ")";
        continue;
      }  // end detector type check
    }    // end loop through DT Hits
 
    if (verbosity > 1) {
      eventout += "\n          Number of DT muon Hits collected:.......... ";
      eventout += j;
    }
 
    nMuonHits += j;
  }
 
  // int RPCBrl = 0, RPCFwd = 0;
  // access the RPC Muon
  // access the RPC Muon geometry
  edm::ESHandle<RPCGeometry> theRPCGeometry;
  iSetup.get<MuonGeometryRecord>().get(theRPCGeometry);
  if (!theRPCGeometry.isValid()) {
    edm::LogWarning(MsgLoggerCat) << "Unable to find MuonGeometryRecord for the RPCGeometry in event!";
    return;
  }
  const RPCGeometry &theRPCMuon(*theRPCGeometry);
 
  // get Muon RPC information
  edm::Handle<edm::PSimHitContainer> MuonRPCContainer;
  iEvent.getByToken(MuonRpcSrc_Token_, MuonRPCContainer);
  if (!MuonRPCContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find MuonRPCHits in event!";
    validMuonRPC = false;
  }
 
  if (validMuonRPC) {
    // cycle through container
    int i = 0, j = 0;
    int RPCBrl = 0, RPCFwd = 0;
    for (itHit = MuonRPCContainer->begin(); itHit != MuonRPCContainer->end(); ++itHit) {
      ++i;
 
      // create a DetID from the detUnitId
      DetId theDetUnitId(itHit->detUnitId());
      int detector = theDetUnitId.det();
      int subdetector = theDetUnitId.subdetId();
 
      // check that expected detector is returned
      if ((detector == dMuon) && (subdetector == sdMuonRPC)) {
        // get an RPCDetID from the detUnitID
        RPCDetId RPCId(itHit->detUnitId());
 
        // find the region of the RPC hit
        int region = RPCId.region();
 
        // get the GeomDetUnit from the geometry using the RPCDetId
        const GeomDetUnit *theDet = theRPCMuon.idToDetUnit(theDetUnitId);
 
        if (!theDet) {
          edm::LogWarning(MsgLoggerCat) << "Unable to get GeomDetUnit from theRPCMuon for hit " << i;
          continue;
        }
 
        ++j;
 
        // get the Surface of the hit (knows how to go from local <-> global)
        const BoundPlane &bSurface = theDet->surface();
 
        // gather necessary information
        if ((region == sdMuonRPCRgnFwdp) || (region == sdMuonRPCRgnFwdn)) {
          ++RPCFwd;
 
          if (meMuonRpcFToF[0])
            meMuonRpcFToF[0]->Fill(itHit->tof());
          if (meMuonRpcFToF[1])
            meMuonRpcFToF[1]->Fill(itHit->tof());
          if (meMuonRpcFZ)
            meMuonRpcFZ->Fill(bSurface.toGlobal(itHit->localPosition()).z());
          if (meMuonPhi)
            meMuonPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi());
          if (meMuonEta)
            meMuonEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta());
 
        } else if (region == sdMuonRPCRgnBrl) {
          ++RPCBrl;
 
          if (meMuonRpcBToF[0])
            meMuonRpcBToF[0]->Fill(itHit->tof());
          if (meMuonRpcBToF[1])
            meMuonRpcBToF[1]->Fill(itHit->tof());
          if (meMuonRpcBR)
            meMuonRpcBR->Fill(bSurface.toGlobal(itHit->localPosition()).perp());
          if (meMuonPhi)
            meMuonPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi());
          if (meMuonEta)
            meMuonEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta());
 
        } else {
          edm::LogWarning(MsgLoggerCat) << "Invalid region for RPC Muon hit" << i;
          continue;
        }  // end check of region
      } else {
        edm::LogWarning(MsgLoggerCat) << "MuonRpc PSimHit " << i << " is expected to be (det,subdet) = (" << dMuon
                                      << "," << sdMuonRPC << "); value returned is: (" << detector << "," << subdetector
                                      << ")";
        continue;
      }  // end detector type check
    }    // end loop through RPC Hits
 
    if (verbosity > 1) {
      eventout += "\n          Number of RPC muon Hits collected:......... ";
      eventout += j;
      eventout += "\n                    RPC Barrel muon Hits:............ ";
      eventout += RPCBrl;
      eventout += "\n                    RPC Forward muon Hits:........... ";
      eventout += RPCFwd;
    }
 
    nMuonHits += j;
  }
 
  if (meMuon[0])
    meMuon[0]->Fill((float)nMuonHits);
  if (meMuon[1])
    meMuon[1]->Fill((float)nMuonHits);
 
  if (verbosity > 0)
    edm::LogInfo(MsgLoggerCat) << eventout << "\n";
 
  return;
}
 
void GlobalHitsAnalyzer::fillECal(const edm::Event &iEvent, const edm::EventSetup &iSetup) {
  std::string MsgLoggerCat = "GlobalHitsAnalyzer_fillECal";
 
  TString eventout;
  if (verbosity > 0)
    eventout = "\nGathering info:";
 
  // access the calorimeter geometry
  edm::ESHandle<CaloGeometry> theCaloGeometry;
  iSetup.get<CaloGeometryRecord>().get(theCaloGeometry);
  if (!theCaloGeometry.isValid()) {
    edm::LogWarning(MsgLoggerCat) << "Unable to find CaloGeometryRecord in event!";
    return;
  }
  const CaloGeometry &theCalo(*theCaloGeometry);
 
  // iterator to access containers
  edm::PCaloHitContainer::const_iterator itHit;
 
  // get  ECal information
  edm::PCaloHitContainer theECalHits;
  // extract EB container
  edm::Handle<edm::PCaloHitContainer> EBContainer;
  iEvent.getByToken(ECalEBSrc_Token_, EBContainer);
  if (!EBContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find EcalHitsEB in event!";
    validEB = false;
  }
  // extract EE container
  edm::Handle<edm::PCaloHitContainer> EEContainer;
  iEvent.getByToken(ECalEESrc_Token_, EEContainer);
  if (!EEContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find EcalHitsEE in event!";
    validEE = false;
  }
  // place both containers into new container
  if (validEB)
    theECalHits.insert(theECalHits.end(), EBContainer->begin(), EBContainer->end());
  if (validEE)
    theECalHits.insert(theECalHits.end(), EEContainer->begin(), EEContainer->end());
 
  // cycle through new container
  int i = 0, j = 0;
  for (itHit = theECalHits.begin(); itHit != theECalHits.end(); ++itHit) {
    ++i;
 
    // create a DetId from the detUnitId
    DetId theDetUnitId(itHit->id());
    int detector = theDetUnitId.det();
    int subdetector = theDetUnitId.subdetId();
 
    // check that expected detector is returned
    if ((detector == dEcal) && ((subdetector == sdEcalBrl) || (subdetector == sdEcalFwd))) {
      // get the Cell geometry
      auto theDet = (theCalo.getSubdetectorGeometry(theDetUnitId))->getGeometry(theDetUnitId);
 
      if (!theDet) {
        edm::LogWarning(MsgLoggerCat) << "Unable to get CaloCellGeometry from ECalHits for Hit " << i;
        continue;
      }
 
      ++j;
 
      // get the global position of the cell
      const GlobalPoint &globalposition = theDet->getPosition();
 
      if (meCaloEcalE[0])
        meCaloEcalE[0]->Fill(itHit->energy());
      if (meCaloEcalE[1])
        meCaloEcalE[1]->Fill(itHit->energy());
      if (meCaloEcalToF[0])
        meCaloEcalToF[0]->Fill(itHit->time());
      if (meCaloEcalToF[1])
        meCaloEcalToF[1]->Fill(itHit->time());
      if (meCaloEcalPhi)
        meCaloEcalPhi->Fill(globalposition.phi());
      if (meCaloEcalEta)
        meCaloEcalEta->Fill(globalposition.eta());
 
    } else {
      edm::LogWarning(MsgLoggerCat) << "ECal PCaloHit " << i << " is expected to be (det,subdet) = (" << dEcal << ","
                                    << sdEcalBrl << " || " << sdEcalFwd << "); value returned is: (" << detector << ","
                                    << subdetector << ")";
      continue;
    }  // end detector type check
  }    // end loop through ECal Hits
 
  if (verbosity > 1) {
    eventout += "\n          Number of ECal Hits collected:............. ";
    eventout += j;
  }
 
  if (meCaloEcal[0])
    meCaloEcal[0]->Fill((float)j);
  if (meCaloEcal[1])
    meCaloEcal[1]->Fill((float)j);
 
  // Get Preshower information
  // extract PreShower container
  edm::Handle<edm::PCaloHitContainer> PreShContainer;
  iEvent.getByToken(ECalESSrc_Token_, PreShContainer);
  if (!PreShContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find EcalHitsES in event!";
    validPresh = false;
  }
 
  if (validPresh) {
    // cycle through container
    int i = 0, j = 0;
    for (itHit = PreShContainer->begin(); itHit != PreShContainer->end(); ++itHit) {
      ++i;
 
      // create a DetId from the detUnitId
      DetId theDetUnitId(itHit->id());
      int detector = theDetUnitId.det();
      int subdetector = theDetUnitId.subdetId();
 
      // check that expected detector is returned
      if ((detector == dEcal) && (subdetector == sdEcalPS)) {
        // get the Cell geometry
        auto theDet = (theCalo.getSubdetectorGeometry(theDetUnitId))->getGeometry(theDetUnitId);
 
        if (!theDet) {
          edm::LogWarning(MsgLoggerCat) << "Unable to get CaloCellGeometry from PreShContainer for Hit " << i;
          continue;
        }
 
        ++j;
 
        // get the global position of the cell
        const GlobalPoint &globalposition = theDet->getPosition();
 
        if (meCaloPreShE[0])
          meCaloPreShE[0]->Fill(itHit->energy());
        if (meCaloPreShE[1])
          meCaloPreShE[1]->Fill(itHit->energy());
        if (meCaloPreShToF[0])
          meCaloPreShToF[0]->Fill(itHit->time());
        if (meCaloPreShToF[1])
          meCaloPreShToF[1]->Fill(itHit->time());
        if (meCaloPreShPhi)
          meCaloPreShPhi->Fill(globalposition.phi());
        if (meCaloPreShEta)
          meCaloPreShEta->Fill(globalposition.eta());
 
      } else {
        edm::LogWarning(MsgLoggerCat) << "PreSh PCaloHit " << i << " is expected to be (det,subdet) = (" << dEcal << ","
                                      << sdEcalPS << "); value returned is: (" << detector << "," << subdetector << ")";
        continue;
      }  // end detector type check
    }    // end loop through PreShower Hits
 
    if (verbosity > 1) {
      eventout += "\n          Number of PreSh Hits collected:............ ";
      eventout += j;
    }
 
    if (meCaloPreSh[0])
      meCaloPreSh[0]->Fill((float)j);
    if (meCaloPreSh[1])
      meCaloPreSh[1]->Fill((float)j);
  }
 
  if (verbosity > 0)
    edm::LogInfo(MsgLoggerCat) << eventout << "\n";
 
  return;
}
 
void GlobalHitsAnalyzer::fillHCal(const edm::Event &iEvent, const edm::EventSetup &iSetup) {
  std::string MsgLoggerCat = "GlobalHitsAnalyzer_fillHCal";
 
  TString eventout;
  if (verbosity > 0)
    eventout = "\nGathering info:";
 
  // access the calorimeter geometry
  edm::ESHandle<CaloGeometry> theCaloGeometry;
  iSetup.get<CaloGeometryRecord>().get(theCaloGeometry);
  if (!theCaloGeometry.isValid()) {
    edm::LogWarning(MsgLoggerCat) << "Unable to find CaloGeometryRecord in event!";
    return;
  }
  const CaloGeometry &theCalo(*theCaloGeometry);
 
  edm::ESHandle<HcalDDDRecConstants> pHRNDC;
  iSetup.get<HcalRecNumberingRecord>().get(pHRNDC);
  const HcalDDDRecConstants *hcons = &(*pHRNDC);
 
  // iterator to access containers
  edm::PCaloHitContainer::const_iterator itHit;
 
  // get  HCal information
  // extract HCal container
  edm::Handle<edm::PCaloHitContainer> HCalContainer;
  iEvent.getByToken(HCalSrc_Token_, HCalContainer);
  if (!HCalContainer.isValid()) {
    LogDebug(MsgLoggerCat) << "Unable to find HCalHits in event!";
    validHcal = false;
  }
 
  if (validHcal) {
    // cycle through container
    int i = 0, j = 0;
    for (itHit = HCalContainer->begin(); itHit != HCalContainer->end(); ++itHit) {
      ++i;
 
      // create a DetId from the detUnitId
      DetId theDetUnitId;
      unsigned int id_ = itHit->id();
      if (testNumber)
        theDetUnitId = HcalHitRelabeller::relabel(id_, hcons);
      else
        theDetUnitId = id_;
 
      int detector = theDetUnitId.det();
      int subdetector = theDetUnitId.subdetId();
 
      // check that expected detector is returned
      if ((detector == dHcal) && ((subdetector == sdHcalBrl) || (subdetector == sdHcalEC) ||
                                  (subdetector == sdHcalOut) || (subdetector == sdHcalFwd))) {
        // get the Cell geometry
        const HcalGeometry *theDet = dynamic_cast<const HcalGeometry *>(theCalo.getSubdetectorGeometry(theDetUnitId));
 
        if (!theDet) {
          edm::LogWarning(MsgLoggerCat) << "Unable to get HcalGeometry from HCalContainer for Hit " << i;
          continue;
        }
 
        ++j;
 
        // get the global position of the cell
        const GlobalPoint &globalposition = theDet->getPosition(theDetUnitId);
 
        if (meCaloHcalE[0])
          meCaloHcalE[0]->Fill(itHit->energy());
        if (meCaloHcalE[1])
          meCaloHcalE[1]->Fill(itHit->energy());
        if (meCaloHcalToF[0])
          meCaloHcalToF[0]->Fill(itHit->time());
        if (meCaloHcalToF[1])
          meCaloHcalToF[1]->Fill(itHit->time());
        if (meCaloHcalPhi)
          meCaloHcalPhi->Fill(globalposition.phi());
        if (meCaloHcalEta)
          meCaloHcalEta->Fill(globalposition.eta());
 
      } else {
        edm::LogWarning(MsgLoggerCat) << "HCal PCaloHit " << i << " is expected to be (det,subdet) = (" << dHcal << ","
                                      << sdHcalBrl << " || " << sdHcalEC << " || " << sdHcalOut << " || " << sdHcalFwd
                                      << "); value returned is: (" << detector << "," << subdetector << ")";
        continue;
      }  // end detector type check
    }    // end loop through HCal Hits
 
    if (verbosity > 1) {
      eventout += "\n          Number of HCal Hits collected:............. ";
      eventout += j;
    }
 
    if (meCaloHcal[0])
      meCaloHcal[0]->Fill((float)j);
    if (meCaloHcal[1])
      meCaloHcal[1]->Fill((float)j);
  }
 
  if (verbosity > 0)
    edm::LogInfo(MsgLoggerCat) << eventout << "\n";
 
  return;
}