#include <GlobalHitsProdHist.h>
Class to fill dqm monitor elements from existing EDM file
Definition at line 75 of file GlobalHitsProdHist.h.
GlobalHitsProdHist::GlobalHitsProdHist | ( | const edm::ParameterSet & | iPSet | ) | [explicit] |
Definition at line 13 of file GlobalHitsProdHist.cc.
References ECalEBSrc_, ECalEESrc_, ECalESSrc_, fName, frequency, getAllProvenances, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), hCaloEcal, hCaloEcalE, hCaloEcalEta, hCaloEcalPhi, hCaloEcalToF, hCaloHcal, hCaloHcalE, hCaloHcalEta, hCaloHcalPhi, hCaloHcalToF, hCaloPreSh, hCaloPreShE, hCaloPreShEta, hCaloPreShPhi, hCaloPreShToF, HCalSrc_, hGeantTrkE, hGeantTrkPt, hGeantVtxX, hGeantVtxY, hGeantVtxZ, histMap_, histName_, hMCG4Trk, hMCG4Vtx, hMCRGP, hMuon, hMuonCscToF, hMuonCscZ, hMuonDtR, hMuonDtToF, hMuonEta, hMuonPhi, hMuonRpcBR, hMuonRpcBToF, hMuonRpcFToF, hMuonRpcFZ, hTrackerPx, hTrackerPxBR, hTrackerPxBToF, hTrackerPxEta, hTrackerPxFToF, hTrackerPxFZ, hTrackerPxPhi, hTrackerSi, hTrackerSiBR, hTrackerSiBToF, hTrackerSiEta, hTrackerSiFToF, hTrackerSiFZ, hTrackerSiPhi, i, edm::InputTag::instance(), edm::InputTag::label(), MuonCscSrc_, MuonDtSrc_, MuonRpcSrc_, printProvenanceInfo, PxlBrlHighSrc_, PxlBrlLowSrc_, PxlFwdHighSrc_, PxlFwdLowSrc_, SiTECHighSrc_, SiTECLowSrc_, SiTIBHighSrc_, SiTIBLowSrc_, SiTIDHighSrc_, SiTIDLowSrc_, SiTOBHighSrc_, SiTOBLowSrc_, verbosity, and vtxunit.
: fName(""), verbosity(0), frequency(0), vtxunit(0), getAllProvenances(false), printProvenanceInfo(false), count(0) { std::string MsgLoggerCat = "GlobalHitsProdHist_GlobalHitsProdHist"; // 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"); //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"); // 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 EDProducer 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"; } //create histograms Char_t hname[200]; Char_t htitle[200]; // MCGeant sprintf(hname,"hMCRGP1"); histName_.push_back(hname); sprintf(htitle,"RawGenParticles"); hMCRGP[0] = new TH1F(hname,htitle,100,0.,5000.); sprintf(hname,"hMCRGP2"); histName_.push_back(hname); hMCRGP[1] = new TH1F(hname,htitle,100,0.,500.); for (Int_t i = 0; i < 2; ++i) { hMCRGP[i]->GetXaxis()->SetTitle("Number of Raw Generated Particles"); hMCRGP[i]->GetYaxis()->SetTitle("Count"); histMap_[hMCRGP[i]->GetName()] = hMCRGP[i]; } sprintf(hname,"hMCG4Vtx1"); histName_.push_back(hname); sprintf(htitle,"G4 Vertices"); hMCG4Vtx[0] = new TH1F(hname,htitle,100,0.,50000.); sprintf(hname,"hMCG4Vtx2"); histName_.push_back(hname); hMCG4Vtx[1] = new TH1F(hname,htitle,100,-0.5,99.5); for (Int_t i = 0; i < 2; ++i) { hMCG4Vtx[i]->GetXaxis()->SetTitle("Number of Vertices"); hMCG4Vtx[i]->GetYaxis()->SetTitle("Count"); histMap_[hMCG4Vtx[i]->GetName()] = hMCG4Vtx[i]; } sprintf(hname,"hMCG4Trk1"); histName_.push_back(hname); sprintf(htitle,"G4 Tracks"); hMCG4Trk[0] = new TH1F(hname,htitle,150,0.,15000.); sprintf(hname,"hMCG4Trk2"); histName_.push_back(hname); hMCG4Trk[1] = new TH1F(hname,htitle,150,-0.5,99.5); for (Int_t i = 0; i < 2; ++i) { hMCG4Trk[i]->GetXaxis()->SetTitle("Number of Tracks"); hMCG4Trk[i]->GetYaxis()->SetTitle("Count"); histMap_[hMCG4Trk[i]->GetName()] = hMCG4Trk[i]; } sprintf(hname,"hGeantVtxX1"); histName_.push_back(hname); sprintf(htitle,"Geant vertex x/micrometer"); hGeantVtxX[0] = new TH1F(hname,htitle,100,-8000000.,8000000.); sprintf(hname,"hGeantVtxX2"); histName_.push_back(hname); hGeantVtxX[1] = new TH1F(hname,htitle,100,-50.,50.); for (Int_t i = 0; i < 2; ++i) { hGeantVtxX[i]->GetXaxis()->SetTitle("x of Vertex (um)"); hGeantVtxX[i]->GetYaxis()->SetTitle("Count"); histMap_[hGeantVtxX[i]->GetName()] = hGeantVtxX[i]; } sprintf(hname,"hGeantVtxY1"); histName_.push_back(hname); sprintf(htitle,"Geant vertex y/micrometer"); hGeantVtxY[0] = new TH1F(hname,htitle,100,-8000000,8000000.); sprintf(hname,"hGeantVtxY2"); histName_.push_back(hname); hGeantVtxY[1] = new TH1F(hname,htitle,100,-50.,50.); for (Int_t i = 0; i < 2; ++i) { hGeantVtxY[i]->GetXaxis()->SetTitle("y of Vertex (um)"); hGeantVtxY[i]->GetYaxis()->SetTitle("Count"); histMap_[hGeantVtxY[i]->GetName()] = hGeantVtxY[i]; } sprintf(hname,"hGeantVtxZ1"); histName_.push_back(hname); sprintf(htitle,"Geant vertex z/millimeter"); hGeantVtxZ[0] = new TH1F(hname,htitle,100,-11000.,11000.); sprintf(hname,"hGeantVtxZ2"); histName_.push_back(hname); hGeantVtxZ[1] = new TH1F(hname,htitle,100,-250.,250.); for (Int_t i = 0; i < 2; ++i) { hGeantVtxZ[i]->GetXaxis()->SetTitle("z of Vertex (mm)"); hGeantVtxZ[i]->GetYaxis()->SetTitle("Count"); histMap_[hGeantVtxZ[i]->GetName()] = hGeantVtxZ[i]; } sprintf(hname,"hGeantTrkPt"); histName_.push_back(hname); sprintf(htitle,"Geant track pt/GeV"); hGeantTrkPt = new TH1F(hname,htitle,100,0.,200.); hGeantTrkPt->GetXaxis()->SetTitle("pT of Track (GeV)"); hGeantTrkPt->GetYaxis()->SetTitle("Count"); histMap_[hGeantTrkPt->GetName()] = hGeantTrkPt; sprintf(hname,"hGeantTrkE"); histName_.push_back(hname); sprintf(htitle,"Geant track E/GeV"); hGeantTrkE = new TH1F(hname,htitle,100,0.,5000.); hGeantTrkE->GetXaxis()->SetTitle("E of Track (GeV)"); hGeantTrkE->GetYaxis()->SetTitle("Count"); histMap_[hGeantTrkE->GetName()] = hGeantTrkE; // ECal sprintf(hname,"hCaloEcal1"); histName_.push_back(hname); sprintf(htitle,"Ecal hits"); hCaloEcal[0] = new TH1F(hname,htitle,100,0.,10000.); sprintf(hname,"hCaloEcal2"); histName_.push_back(hname); hCaloEcal[1] = new TH1F(hname,htitle,100,-0.5,99.5); sprintf(hname,"hCaloEcalE1"); histName_.push_back(hname); sprintf(htitle,"Ecal hits, energy/GeV"); hCaloEcalE[0] = new TH1F(hname,htitle,100,0.,10.); sprintf(hname,"hCaloEcalE2"); histName_.push_back(hname); hCaloEcalE[1] = new TH1F(hname,htitle,100,0.,0.1); sprintf(hname,"hCaloEcalToF1"); histName_.push_back(hname); sprintf(htitle,"Ecal hits, ToF/ns"); hCaloEcalToF[0] = new TH1F(hname,htitle,100,0.,1000.); sprintf(hname,"hCaloEcalToF2"); histName_.push_back(hname); hCaloEcalToF[1] = new TH1F(hname,htitle,100,0.,100.); for (Int_t i = 0; i < 2; ++i) { hCaloEcal[i]->GetXaxis()->SetTitle("Number of Hits"); hCaloEcal[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloEcal[i]->GetName()] = hCaloEcal[i]; hCaloEcalE[i]->GetXaxis()->SetTitle("Energy of Hits (GeV)"); hCaloEcalE[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloEcalE[i]->GetName()] = hCaloEcalE[i]; hCaloEcalToF[i]->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hCaloEcalToF[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloEcalToF[i]->GetName()] = hCaloEcalToF[i]; } sprintf(hname,"hCaloEcalPhi"); histName_.push_back(hname); sprintf(htitle,"Ecal hits, phi/rad"); hCaloEcalPhi = new TH1F(hname,htitle,100,-3.2,3.2); hCaloEcalPhi->GetXaxis()->SetTitle("Phi of Hits (rad)"); hCaloEcalPhi->GetYaxis()->SetTitle("Count"); histMap_[hCaloEcalPhi->GetName()] = hCaloEcalPhi; sprintf(hname,"hCaloEcalEta"); histName_.push_back(hname); sprintf(htitle,"Ecal hits, eta"); hCaloEcalEta = new TH1F(hname,htitle,100,-5.5,5.5); hCaloEcalEta->GetXaxis()->SetTitle("Eta of Hits"); hCaloEcalEta->GetYaxis()->SetTitle("Count"); histMap_[hCaloEcalEta->GetName()] = hCaloEcalEta; sprintf(hname,"hCaloPreSh1"); histName_.push_back(hname); sprintf(htitle,"PreSh hits"); hCaloPreSh[0] = new TH1F(hname,htitle,100,0.,10000.); sprintf(hname,"hCaloPreSh2"); histName_.push_back(hname); hCaloPreSh[1] = new TH1F(hname,htitle,100,-0.5,99.5); sprintf(hname,"hCaloPreShE1"); histName_.push_back(hname); sprintf(htitle,"PreSh hits, energy/GeV"); hCaloPreShE[0] = new TH1F(hname,htitle,100,0.,10.); sprintf(hname,"hCaloPreShE2"); histName_.push_back(hname); hCaloPreShE[1] = new TH1F(hname,htitle,100,0.,0.1); sprintf(hname,"hCaloPreShToF1"); histName_.push_back(hname); sprintf(htitle,"PreSh hits, ToF/ns"); hCaloPreShToF[0] = new TH1F(hname,htitle,100,0.,1000.); sprintf(hname,"hCaloPreShToF2"); histName_.push_back(hname); hCaloPreShToF[1] = new TH1F(hname,htitle,100,0.,100.); for (Int_t i = 0; i < 2; ++i) { hCaloPreSh[i]->GetXaxis()->SetTitle("Number of Hits"); hCaloPreSh[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloPreSh[i]->GetName()] = hCaloPreSh[i]; hCaloPreShE[i]->GetXaxis()->SetTitle("Energy of Hits (GeV)"); hCaloPreShE[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloPreShE[i]->GetName()] = hCaloPreShE[i]; hCaloPreShToF[i]->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hCaloPreShToF[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloPreShToF[i]->GetName()] = hCaloPreShToF[i]; } sprintf(hname,"hCaloPreShPhi"); histName_.push_back(hname); sprintf(htitle,"PreSh hits, phi/rad"); hCaloPreShPhi = new TH1F(hname,htitle,100,-3.2,3.2); hCaloPreShPhi->GetXaxis()->SetTitle("Phi of Hits (rad)"); hCaloPreShPhi->GetYaxis()->SetTitle("Count"); histMap_[hCaloPreShPhi->GetName()] = hCaloPreShPhi; sprintf(hname,"hCaloPreShEta"); histName_.push_back(hname); sprintf(htitle,"PreSh hits, eta"); hCaloPreShEta = new TH1F(hname,htitle,100,-5.5,5.5); hCaloPreShEta->GetXaxis()->SetTitle("Eta of Hits"); hCaloPreShEta->GetYaxis()->SetTitle("Count"); histMap_[hCaloPreShEta->GetName()] = hCaloPreShEta; // Hcal sprintf(hname,"hCaloHcal1"); histName_.push_back(hname); sprintf(htitle,"Hcal hits"); hCaloHcal[0] = new TH1F(hname,htitle,100,0.,10000.); sprintf(hname,"hCaloHcal2"); histName_.push_back(hname); hCaloHcal[1] = new TH1F(hname,htitle,100,-0.5,99.5); sprintf(hname,"hCaloHcalE1"); histName_.push_back(hname); sprintf(htitle,"Hcal hits, energy/GeV"); hCaloHcalE[0] = new TH1F(hname,htitle,100,0.,10.); sprintf(hname,"hCaloHcalE2"); histName_.push_back(hname); hCaloHcalE[1] = new TH1F(hname,htitle,100,0.,0.1); sprintf(hname,"hCaloHcalToF1"); histName_.push_back(hname); sprintf(htitle,"Hcal hits, ToF/ns"); hCaloHcalToF[0] = new TH1F(hname,htitle,100,0.,1000.); sprintf(hname,"hCaloHcalToF2"); histName_.push_back(hname); hCaloHcalToF[1] = new TH1F(hname,htitle,100,0.,100.); for (Int_t i = 0; i < 2; ++i) { hCaloHcal[i]->GetXaxis()->SetTitle("Number of Hits"); hCaloHcal[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloHcal[i]->GetName()] = hCaloHcal[i]; hCaloHcalE[i]->GetXaxis()->SetTitle("Energy of Hits (GeV)"); hCaloHcalE[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloHcalE[i]->GetName()] = hCaloHcalE[i]; hCaloHcalToF[i]->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hCaloHcalToF[i]->GetYaxis()->SetTitle("Count"); histMap_[hCaloHcalToF[i]->GetName()] = hCaloHcalToF[i]; } sprintf(hname,"hCaloHcalPhi"); histName_.push_back(hname); sprintf(htitle,"Hcal hits, phi/rad"); hCaloHcalPhi = new TH1F(hname,htitle,100,-3.2,3.2); hCaloHcalPhi->GetXaxis()->SetTitle("Phi of Hits (rad)"); hCaloHcalPhi->GetYaxis()->SetTitle("Count"); histMap_[hCaloHcalPhi->GetName()] = hCaloHcalPhi; sprintf(hname,"hCaloHcalEta"); histName_.push_back(hname); sprintf(htitle,"Hcal hits, eta"); hCaloHcalEta = new TH1F(hname,htitle,100,-5.5,5.5); hCaloHcalEta->GetXaxis()->SetTitle("Eta of Hits"); hCaloHcalEta->GetYaxis()->SetTitle("Count"); histMap_[hCaloHcalEta->GetName()] = hCaloHcalEta; // tracker sprintf(hname,"hTrackerPx1"); histName_.push_back(hname); sprintf(htitle,"Pixel hits"); hTrackerPx[0] = new TH1F(hname,htitle,100,0.,10000.); sprintf(hname,"hTrackerPx2"); histName_.push_back(hname); hTrackerPx[1] = new TH1F(hname,htitle,100,-0.5,99.5); for (Int_t i = 0; i < 2; ++i) { hTrackerPx[i]->GetXaxis()->SetTitle("Number of Pixel Hits"); hTrackerPx[i]->GetYaxis()->SetTitle("Count"); histMap_[hTrackerPx[i]->GetName()] = hTrackerPx[i]; } sprintf(hname,"hTrackerPxPhi"); histName_.push_back(hname); sprintf(htitle,"Pixel hits phi/rad"); hTrackerPxPhi = new TH1F(hname,htitle,100,-3.2,3.2); hTrackerPxPhi->GetXaxis()->SetTitle("Phi of Hits (rad)"); hTrackerPxPhi->GetYaxis()->SetTitle("Count"); histMap_[hTrackerPxPhi->GetName()] = hTrackerPxPhi; sprintf(hname,"hTrackerPxEta"); histName_.push_back(hname); sprintf(htitle,"Pixel hits eta"); hTrackerPxEta = new TH1F(hname,htitle,100,-3.5,3.5); hTrackerPxEta->GetXaxis()->SetTitle("Eta of Hits"); hTrackerPxEta->GetYaxis()->SetTitle("Count"); histMap_[hTrackerPxEta->GetName()] = hTrackerPxEta; sprintf(hname,"hTrackerPxBToF"); histName_.push_back(hname); sprintf(htitle,"Pixel barrel hits, ToF/ns"); hTrackerPxBToF = new TH1F(hname,htitle,100,0.,40.); hTrackerPxBToF->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hTrackerPxBToF->GetYaxis()->SetTitle("Count"); histMap_[hTrackerPxBToF->GetName()] = hTrackerPxBToF; sprintf(hname,"hTrackerPxBR"); histName_.push_back(hname); sprintf(htitle,"Pixel barrel hits, R/cm"); hTrackerPxBR = new TH1F(hname,htitle,100,0.,50.); hTrackerPxBR->GetXaxis()->SetTitle("R of Hits (cm)"); hTrackerPxBR->GetYaxis()->SetTitle("Count"); histMap_[hTrackerPxBR->GetName()] = hTrackerPxBR; sprintf(hname,"hTrackerPxFToF"); histName_.push_back(hname); sprintf(htitle,"Pixel forward hits, ToF/ns"); hTrackerPxFToF = new TH1F(hname,htitle,100,0.,50.); hTrackerPxFToF->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hTrackerPxFToF->GetYaxis()->SetTitle("Count"); histMap_[hTrackerPxFToF->GetName()] = hTrackerPxFToF; sprintf(hname,"hTrackerPxFZ"); histName_.push_back(hname); sprintf(htitle,"Pixel forward hits, Z/cm"); hTrackerPxFZ = new TH1F(hname,htitle,200,-100.,100.); hTrackerPxFZ->GetXaxis()->SetTitle("Z of Hits (cm)"); hTrackerPxFZ->GetYaxis()->SetTitle("Count"); histMap_[hTrackerPxFZ->GetName()] = hTrackerPxFZ; sprintf(hname,"hTrackerSi1"); histName_.push_back(hname); sprintf(htitle,"Silicon hits"); hTrackerSi[0] = new TH1F(hname,htitle,100,0.,10000.); sprintf(hname,"hTrackerSi2"); histName_.push_back(hname); hTrackerSi[1] = new TH1F(hname,htitle,100,-0.5,99.5); for (Int_t i = 0; i < 2; ++i) { hTrackerSi[i]->GetXaxis()->SetTitle("Number of Silicon Hits"); hTrackerSi[i]->GetYaxis()->SetTitle("Count"); histMap_[hTrackerSi[i]->GetName()] = hTrackerSi[i]; } sprintf(hname,"hTrackerSiPhi"); histName_.push_back(hname); sprintf(htitle,"Silicon hits phi/rad"); hTrackerSiPhi = new TH1F(hname,htitle,100,-3.2,3.2); hTrackerSiPhi->GetXaxis()->SetTitle("Phi of Hits (rad)"); hTrackerSiPhi->GetYaxis()->SetTitle("Count"); histMap_[hTrackerSiPhi->GetName()] = hTrackerSiPhi; sprintf(hname,"hTrackerSiEta"); histName_.push_back(hname); sprintf(htitle,"Silicon hits eta"); hTrackerSiEta = new TH1F(hname,htitle,100,-3.5,3.5); hTrackerSiEta->GetXaxis()->SetTitle("Eta of Hits"); hTrackerSiEta->GetYaxis()->SetTitle("Count"); histMap_[hTrackerSiEta->GetName()] = hTrackerSiEta; sprintf(hname,"hTrackerSiBToF"); histName_.push_back(hname); sprintf(htitle,"Silicon barrel hits, ToF/ns"); hTrackerSiBToF = new TH1F(hname,htitle,100,0.,50.); hTrackerSiBToF->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hTrackerSiBToF->GetYaxis()->SetTitle("Count"); histMap_[hTrackerSiBToF->GetName()] = hTrackerSiBToF; sprintf(hname,"hTrackerSiBR"); histName_.push_back(hname); sprintf(htitle,"Silicon barrel hits, R/cm"); hTrackerSiBR = new TH1F(hname,htitle,100,0.,200.); hTrackerSiBR->GetXaxis()->SetTitle("R of Hits (cm)"); hTrackerSiBR->GetYaxis()->SetTitle("Count"); histMap_[hTrackerSiBR->GetName()] = hTrackerSiBR; sprintf(hname,"hTrackerSiFToF"); histName_.push_back(hname); sprintf(htitle,"Silicon forward hits, ToF/ns"); hTrackerSiFToF = new TH1F(hname,htitle,100,0.,75.); hTrackerSiFToF->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hTrackerSiFToF->GetYaxis()->SetTitle("Count"); histMap_[hTrackerSiFToF->GetName()] = hTrackerSiFToF; sprintf(hname,"hTrackerSiFZ"); histName_.push_back(hname); sprintf(htitle,"Silicon forward hits, Z/cm"); hTrackerSiFZ = new TH1F(hname,htitle,200,-300.,300.); hTrackerSiFZ->GetXaxis()->SetTitle("Z of Hits (cm)"); hTrackerSiFZ->GetYaxis()->SetTitle("Count"); histMap_[hTrackerSiFZ->GetName()] = hTrackerSiFZ; // muon sprintf(hname,"hMuon1"); histName_.push_back(hname); sprintf(htitle,"Muon hits"); hMuon[0] = new TH1F(hname,htitle,100,0.,10000.); sprintf(hname,"hMuon2"); histName_.push_back(hname); hMuon[1] = new TH1F(hname,htitle,100,-0.5,99.5); for (Int_t i = 0; i < 2; ++i) { hMuon[i]->GetXaxis()->SetTitle("Number of Muon Hits"); hMuon[i]->GetYaxis()->SetTitle("Count"); histMap_[hMuon[i]->GetName()] = hMuon[i]; } sprintf(hname,"hMuonPhi"); histName_.push_back(hname); sprintf(htitle,"Muon hits phi/rad"); hMuonPhi = new TH1F(hname,htitle,100,-3.2,3.2); hMuonPhi->GetXaxis()->SetTitle("Phi of Hits (rad)"); hMuonPhi->GetYaxis()->SetTitle("Count"); histMap_[hMuonPhi->GetName()] = hMuonPhi; sprintf(hname,"hMuonEta"); histName_.push_back(hname); sprintf(htitle,"Muon hits eta"); hMuonEta = new TH1F(hname,htitle,100,-3.5,3.5); hMuonEta->GetXaxis()->SetTitle("Eta of Hits"); hMuonEta->GetYaxis()->SetTitle("Count"); histMap_[hMuonEta->GetName()] = hMuonEta; sprintf(hname,"hMuonCscToF1"); histName_.push_back(hname); sprintf(htitle,"Muon CSC hits, ToF/ns"); hMuonCscToF[0] = new TH1F(hname,htitle,100,0.,250.); sprintf(hname,"hMuonCscToF2"); histName_.push_back(hname); hMuonCscToF[1] = new TH1F(hname,htitle,100,0.,50.); for (Int_t i = 0; i < 2; ++i) { hMuonCscToF[i]->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hMuonCscToF[i]->GetYaxis()->SetTitle("Count"); histMap_[hMuonCscToF[i]->GetName()] = hMuonCscToF[i]; } sprintf(hname,"hMuonCscZ"); histName_.push_back(hname); sprintf(htitle,"Muon CSC hits, Z/cm"); hMuonCscZ = new TH1F(hname,htitle,200,-1500.,1500.); hMuonCscZ->GetXaxis()->SetTitle("Z of Hits (cm)"); hMuonCscZ->GetYaxis()->SetTitle("Count"); histMap_[hMuonCscZ->GetName()] = hMuonCscZ; sprintf(hname,"hMuonDtToF1"); histName_.push_back(hname); sprintf(htitle,"Muon DT hits, ToF/ns"); hMuonDtToF[0] = new TH1F(hname,htitle,100,0.,250.); sprintf(hname,"hMuonDtToF2"); histName_.push_back(hname); hMuonDtToF[1] = new TH1F(hname,htitle,100,0.,50.); for (Int_t i = 0; i < 2; ++i) { hMuonDtToF[i]->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hMuonDtToF[i]->GetYaxis()->SetTitle("Count"); histMap_[hMuonDtToF[i]->GetName()] = hMuonDtToF[i]; } sprintf(hname,"hMuonDtR"); histName_.push_back(hname); sprintf(htitle,"Muon DT hits, R/cm"); hMuonDtR = new TH1F(hname,htitle,100,0.,1500.); hMuonDtR->GetXaxis()->SetTitle("R of Hits (cm)"); hMuonDtR->GetYaxis()->SetTitle("Count"); histMap_[hMuonDtR->GetName()] = hMuonDtR; sprintf(hname,"hMuonRpcFToF1"); histName_.push_back(hname); sprintf(htitle,"Muon RPC forward hits, ToF/ns"); hMuonRpcFToF[0] = new TH1F(hname,htitle,100,0.,250.); sprintf(hname,"hMuonRpcFToF2"); histName_.push_back(hname); hMuonRpcFToF[1] = new TH1F(hname,htitle,100,0.,50.); for (Int_t i = 0; i < 2; ++i) { hMuonRpcFToF[i]->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hMuonRpcFToF[i]->GetYaxis()->SetTitle("Count"); histMap_[hMuonRpcFToF[i]->GetName()] = hMuonRpcFToF[i]; } sprintf(hname,"hMuonRpcFZ"); histName_.push_back(hname); sprintf(htitle,"Muon RPC forward hits, Z/cm"); hMuonRpcFZ = new TH1F(hname,htitle,201,-1500.,1500.); hMuonRpcFZ->GetXaxis()->SetTitle("Z of Hits (cm)"); hMuonRpcFZ->GetYaxis()->SetTitle("Count"); histMap_[hMuonRpcFZ->GetName()] = hMuonRpcFZ; sprintf(hname,"hMuonRpcBToF1"); histName_.push_back(hname); sprintf(htitle,"Muon RPC barrel hits, ToF/ns"); hMuonRpcBToF[0] = new TH1F(hname,htitle,100,0.,250.); sprintf(hname,"hMuonRpcBToF2"); histName_.push_back(hname); hMuonRpcBToF[1] = new TH1F(hname,htitle,100,0.,50.); for (Int_t i = 0; i < 2; ++i) { hMuonRpcBToF[i]->GetXaxis()->SetTitle("Time of Flight of Hits (ns)"); hMuonRpcBToF[i]->GetYaxis()->SetTitle("Count"); histMap_[hMuonRpcBToF[i]->GetName()] = hMuonRpcBToF[i]; } sprintf(hname,"hMuonRpcBR"); histName_.push_back(hname); sprintf(htitle,"Muon RPC barrel hits, R/cm"); hMuonRpcBR = new TH1F(hname,htitle,100,0.,1500.); hMuonRpcBR->GetXaxis()->SetTitle("R of Hits (cm)"); hMuonRpcBR->GetYaxis()->SetTitle("Count"); histMap_[hMuonRpcBR->GetName()] = hMuonRpcBR; // create persistent objects for (std::size_t i = 0; i < histName_.size(); ++i) { produces<TH1F, edm::InRun>(histName_[i]).setBranchAlias(histName_[i]); } }
GlobalHitsProdHist::~GlobalHitsProdHist | ( | ) | [virtual] |
Definition at line 612 of file GlobalHitsProdHist.cc.
{ }
void GlobalHitsProdHist::beginJob | ( | void | ) | [virtual] |
Reimplemented from edm::EDProducer.
Definition at line 616 of file GlobalHitsProdHist.cc.
{
return;
}
void GlobalHitsProdHist::endJob | ( | void | ) | [virtual] |
Reimplemented from edm::EDProducer.
Definition at line 621 of file GlobalHitsProdHist.cc.
References count, and verbosity.
{ std::string MsgLoggerCat = "GlobalHitsProdHist_endJob"; if (verbosity >= 0) edm::LogInfo(MsgLoggerCat) << "Terminating having processed " << count << " events."; return; }
void GlobalHitsProdHist::endRun | ( | edm::Run & | iRun, |
const edm::EventSetup & | iSetup | ||
) | [virtual] |
Reimplemented from edm::EDProducer.
Definition at line 706 of file GlobalHitsProdHist.cc.
References histMap_, histName_, i, edm::Run::put(), verbosity, and warning.
{ std::string MsgLoggerCat = "GlobalHitsProdHist_endRun"; TString eventout; TString eventoutw; bool warning = false; if (verbosity > 0) edm::LogInfo (MsgLoggerCat) << "\nStoring histograms."; // store persistent objects std::map<std::string, TH1F*>::iterator iter; for (std::size_t i = 0; i < histName_.size(); ++i) { iter = histMap_.find(histName_[i]); if (iter != histMap_.end()) { std::auto_ptr<TH1F> hist1D(iter->second); eventout += "\n Storing histogram " + histName_[i]; iRun.put(hist1D, histName_[i]); } else { warning = true; eventoutw += "\n Unable to find histogram with name " + histName_[i]; } } if (verbosity > 0) { edm::LogInfo(MsgLoggerCat) << eventout << "\n"; if (warning) edm::LogWarning(MsgLoggerCat) << eventoutw << "\n"; } return; }
void GlobalHitsProdHist::fillECal | ( | edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [private] |
Definition at line 1574 of file GlobalHitsProdHist.cc.
References dEcal, ExpressReco_HICollisions_FallBack::detector, ECalEBSrc_, ECalEESrc_, ECalESSrc_, PV3DBase< T, PVType, FrameType >::eta(), edm::EventSetup::get(), edm::Event::getByLabel(), CaloGeometry::getGeometry(), CaloCellGeometry::getPosition(), hCaloEcal, hCaloEcalE, hCaloEcalEta, hCaloEcalPhi, hCaloEcalToF, hCaloPreSh, hCaloPreShE, hCaloPreShEta, hCaloPreShPhi, hCaloPreShToF, i, edm::HandleBase::isValid(), edm::ESHandleBase::isValid(), j, PV3DBase< T, PVType, FrameType >::phi(), sdEcalBrl, sdEcalFwd, sdEcalPS, and verbosity.
Referenced by produce().
{ std::string MsgLoggerCat = "GlobalHitsProdHist_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.getByLabel(ECalEBSrc_,EBContainer); if (!EBContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find EcalHitsEB in event!"; return; } // extract EE container edm::Handle<edm::PCaloHitContainer> EEContainer; iEvent.getByLabel(ECalEESrc_,EEContainer); if (!EEContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find EcalHitsEE in event!"; return; } // place both containers into new container theECalHits.insert(theECalHits.end(),EBContainer->begin(), EBContainer->end()); 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 const CaloCellGeometry *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 (hCaloEcalE[0]) hCaloEcalE[0]->Fill(itHit->energy()); if (hCaloEcalE[1]) hCaloEcalE[1]->Fill(itHit->energy()); if (hCaloEcalToF[0]) hCaloEcalToF[0]->Fill(itHit->time()); if (hCaloEcalToF[1]) hCaloEcalToF[1]->Fill(itHit->time()); if (hCaloEcalPhi) hCaloEcalPhi->Fill(globalposition.phi()); if (hCaloEcalEta) hCaloEcalEta->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 (hCaloEcal[0]) hCaloEcal[0]->Fill((float)j); if (hCaloEcal[1]) hCaloEcal[1]->Fill((float)j); // Get Preshower information // extract PreShower container edm::Handle<edm::PCaloHitContainer> PreShContainer; iEvent.getByLabel(ECalESSrc_,PreShContainer); if (!PreShContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find EcalHitsES in event!"; return; } // cycle through container 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 const CaloCellGeometry *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 (hCaloPreShE[0]) hCaloPreShE[0]->Fill(itHit->energy()); if (hCaloPreShE[1]) hCaloPreShE[1]->Fill(itHit->energy()); if (hCaloPreShToF[0]) hCaloPreShToF[0]->Fill(itHit->time()); if (hCaloPreShToF[1]) hCaloPreShToF[1]->Fill(itHit->time()); if (hCaloPreShPhi) hCaloPreShPhi->Fill(globalposition.phi()); if (hCaloPreShEta) hCaloPreShEta->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 (hCaloPreSh[0]) hCaloPreSh[0]->Fill((float)j); if (hCaloPreSh[1]) hCaloPreSh[1]->Fill((float)j); if (verbosity > 0) edm::LogInfo(MsgLoggerCat) << eventout << "\n"; return; }
void GlobalHitsProdHist::fillG4MC | ( | edm::Event & | iEvent | ) | [private] |
Definition at line 742 of file GlobalHitsProdHist.cc.
References edm::Event::getByType(), edm::Event::getManyByType(), hGeantTrkE, hGeantTrkPt, hGeantVtxX, hGeantVtxY, hGeantVtxZ, hMCG4Trk, hMCG4Vtx, hMCRGP, i, edm::HandleBase::isValid(), moduleLabel(), nRawGenPart, edm::HandleBase::provenance(), mathSSE::sqrt(), csvLumiCalc::unit, verbosity, and vtxunit.
Referenced by produce().
{ std::string MsgLoggerCat = "GlobalHitsProdHist_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()->product()).moduleLabel() == "VtxSmeared") break; } if (!HepMCEvt.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find HepMCProduct in event!"; return; } else { eventout += "\n Using HepMCProduct: "; eventout += (HepMCEvt.provenance()->product()).moduleLabel(); } const HepMC::GenEvent* MCEvt = HepMCEvt->GetEvent(); nRawGenPart = MCEvt->particles_size(); if (verbosity > 1) { eventout += "\n Number of Raw Particles collected:......... "; eventout += nRawGenPart; } if (hMCRGP[0]) hMCRGP[0]->Fill((float)nRawGenPart); if (hMCRGP[1]) hMCRGP[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.getByType(G4VtxContainer); if (!G4VtxContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find SimVertex in event!"; return; } 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 (hGeantVtxX[0]) hGeantVtxX[0]->Fill((G4Vtx[0]*unit)/micrometer); if (hGeantVtxX[1]) hGeantVtxX[1]->Fill((G4Vtx[0]*unit)/micrometer); if (hGeantVtxY[0]) hGeantVtxY[0]->Fill((G4Vtx[1]*unit)/micrometer); if (hGeantVtxY[1]) hGeantVtxY[1]->Fill((G4Vtx[1]*unit)/micrometer); if (hGeantVtxZ[0]) hGeantVtxZ[0]->Fill((G4Vtx[2]*unit)/millimeter); if (hGeantVtxZ[1]) hGeantVtxZ[1]->Fill((G4Vtx[2]*unit)/millimeter); } if (verbosity > 1) { eventout += "\n Number of G4Vertices collected:............ "; eventout += i; } if (hMCG4Vtx[0]) hMCG4Vtx[0]->Fill((float)i); if (hMCG4Vtx[1]) hMCG4Vtx[1]->Fill((float)i); // get G4Track information edm::Handle<edm::SimTrackContainer> G4TrkContainer; iEvent.getByType(G4TrkContainer); if (!G4TrkContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find SimTrack in event!"; return; } 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 (hGeantTrkPt) hGeantTrkPt-> Fill(sqrt(G4Trk[0]*G4Trk[0]+G4Trk[1]*G4Trk[1])); if (hGeantTrkE) hGeantTrkE->Fill(G4Trk[3]); } if (verbosity > 1) { eventout += "\n Number of G4Tracks collected:.............. "; eventout += i; } if (hMCG4Trk[0]) hMCG4Trk[0]->Fill((float)i); if (hMCG4Trk[1]) hMCG4Trk[1]->Fill((float)i); if (verbosity > 0) edm::LogInfo(MsgLoggerCat) << eventout << "\n"; return; }
void GlobalHitsProdHist::fillHCal | ( | edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [private] |
Definition at line 1755 of file GlobalHitsProdHist.cc.
References ExpressReco_HICollisions_FallBack::detector, dHcal, PV3DBase< T, PVType, FrameType >::eta(), edm::EventSetup::get(), edm::Event::getByLabel(), CaloGeometry::getGeometry(), CaloCellGeometry::getPosition(), hCaloHcal, hCaloHcalE, hCaloHcalEta, hCaloHcalPhi, hCaloHcalToF, HCalSrc_, i, edm::HandleBase::isValid(), edm::ESHandleBase::isValid(), j, PV3DBase< T, PVType, FrameType >::phi(), sdHcalBrl, sdHcalEC, sdHcalFwd, sdHcalOut, and verbosity.
Referenced by produce().
{ std::string MsgLoggerCat = "GlobalHitsProdHist_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); // iterator to access containers edm::PCaloHitContainer::const_iterator itHit; // get HCal information // extract HCal container edm::Handle<edm::PCaloHitContainer> HCalContainer; iEvent.getByLabel(HCalSrc_,HCalContainer); if (!HCalContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find HCalHits in event!"; return; } // 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(itHit->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 CaloCellGeometry *theDet = theCalo. getSubdetectorGeometry(theDetUnitId)->getGeometry(theDetUnitId); if (!theDet) { edm::LogWarning(MsgLoggerCat) << "Unable to get CaloCellGeometry from HCalContainer for Hit " << i; continue; } ++j; // get the global position of the cell const GlobalPoint& globalposition = theDet->getPosition(); if (hCaloHcalE[0]) hCaloHcalE[0]->Fill(itHit->energy()); if (hCaloHcalE[1]) hCaloHcalE[1]->Fill(itHit->energy()); if (hCaloHcalToF[0]) hCaloHcalToF[0]->Fill(itHit->time()); if (hCaloHcalToF[1]) hCaloHcalToF[1]->Fill(itHit->time()); if (hCaloHcalPhi) hCaloHcalPhi->Fill(globalposition.phi()); if (hCaloHcalEta) hCaloHcalEta->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 (hCaloHcal[0]) hCaloHcal[0]->Fill((float)j); if (hCaloHcal[1]) hCaloHcal[1]->Fill((float)j); if (verbosity > 0) edm::LogInfo(MsgLoggerCat) << eventout << "\n"; return; }
void GlobalHitsProdHist::fillMuon | ( | edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [private] |
Definition at line 1278 of file GlobalHitsProdHist.cc.
References ExpressReco_HICollisions_FallBack::detector, dMuon, eta(), edm::EventSetup::get(), edm::Event::getByLabel(), hMuon, hMuonCscToF, hMuonCscZ, hMuonDtR, hMuonDtToF, hMuonEta, hMuonPhi, hMuonRpcBR, hMuonRpcBToF, hMuonRpcFToF, hMuonRpcFZ, i, CSCGeometry::idToDetUnit(), RPCGeometry::idToDetUnit(), edm::ESHandleBase::isValid(), edm::HandleBase::isValid(), j, DTGeometry::layer(), MuonCscSrc_, MuonDtSrc_, MuonRpcSrc_, nMuonHits, perp(), phi, RPCDetId::region(), sdMuonCSC, sdMuonDT, sdMuonRPC, sdMuonRPCRgnBrl, sdMuonRPCRgnFwdn, sdMuonRPCRgnFwdp, GeomDet::surface(), Surface::toGlobal(), verbosity, and z.
Referenced by produce().
{ nMuonHits = 0; std::string MsgLoggerCat = "GlobalHitsProdHist_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.getByLabel(MuonCscSrc_,MuonCSCContainer); if (!MuonCSCContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find MuonCSCHits in event!"; return; } // 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 (hMuonCscToF[0]) hMuonCscToF[0]->Fill(itHit->tof()); if (hMuonCscToF[1]) hMuonCscToF[1]->Fill(itHit->tof()); if (hMuonCscZ) hMuonCscZ->Fill(bSurface.toGlobal(itHit->localPosition()).z()); if (hMuonPhi) hMuonPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi()); if (hMuonEta) hMuonEta->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.getByLabel(MuonDtSrc_,MuonDtContainer); if (!MuonDtContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find MuonDTHits in event!"; return; } // cycle through container 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 (hMuonDtToF[0]) hMuonDtToF[0]->Fill(itHit->tof()); if (hMuonDtToF[1]) hMuonDtToF[1]->Fill(itHit->tof()); if (hMuonDtR) hMuonDtR->Fill(bSurface.toGlobal(itHit->localPosition()).perp()); if (hMuonPhi) hMuonPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi()); if (hMuonEta) hMuonEta->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.getByLabel(MuonRpcSrc_,MuonRPCContainer); if (!MuonRPCContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find MuonRPCHits in event!"; return; } // cycle through container 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 (hMuonRpcFToF[0]) hMuonRpcFToF[0]->Fill(itHit->tof()); if (hMuonRpcFToF[1]) hMuonRpcFToF[1]->Fill(itHit->tof()); if (hMuonRpcFZ) hMuonRpcFZ->Fill(bSurface.toGlobal(itHit->localPosition()).z()); if (hMuonPhi) hMuonPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi()); if (hMuonEta) hMuonEta->Fill(bSurface.toGlobal(itHit->localPosition()).eta()); } else if (region == sdMuonRPCRgnBrl) { ++RPCBrl; if (hMuonRpcBToF[0]) hMuonRpcBToF[0]->Fill(itHit->tof()); if (hMuonRpcBToF[1]) hMuonRpcBToF[1]->Fill(itHit->tof()); if (hMuonRpcBR) hMuonRpcBR->Fill(bSurface.toGlobal(itHit->localPosition()).perp()); if (hMuonPhi) hMuonPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi()); if (hMuonEta) hMuonEta->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 (hMuon[0]) hMuon[0]->Fill((float)nMuonHits); if (hMuon[1]) hMuon[1]->Fill((float)nMuonHits); if (verbosity > 0) edm::LogInfo(MsgLoggerCat) << eventout << "\n"; return; }
void GlobalHitsProdHist::fillTrk | ( | edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [private] |
Definition at line 877 of file GlobalHitsProdHist.cc.
References ExpressReco_HICollisions_FallBack::detector, dTrk, eta(), edm::EventSetup::get(), edm::Event::getByLabel(), hTrackerPx, hTrackerPxBR, hTrackerPxBToF, hTrackerPxEta, hTrackerPxFToF, hTrackerPxFZ, hTrackerPxPhi, hTrackerSi, hTrackerSiBR, hTrackerSiBToF, hTrackerSiEta, hTrackerSiFToF, hTrackerSiFZ, hTrackerSiPhi, i, TrackerGeometry::idToDetUnit(), edm::ESHandleBase::isValid(), edm::HandleBase::isValid(), j, nPxlHits, nSiHits, perp(), phi, PxlBrlHighSrc_, PxlBrlLowSrc_, PxlFwdHighSrc_, PxlFwdLowSrc_, sdPxlBrl, sdPxlFwd, sdSiTEC, sdSiTIB, sdSiTID, sdSiTOB, SiTECHighSrc_, SiTECLowSrc_, SiTIBHighSrc_, SiTIBLowSrc_, SiTIDHighSrc_, SiTIDLowSrc_, SiTOBHighSrc_, SiTOBLowSrc_, GeomDet::surface(), Surface::toGlobal(), verbosity, and z.
Referenced by produce().
{ nPxlHits = 0; std::string MsgLoggerCat = "GlobalHitsProdHist_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.getByLabel(PxlBrlLowSrc_,PxlBrlLowContainer); if (!PxlBrlLowContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsPixelBarrelLowTof in event!"; return; } // extract high container edm::Handle<edm::PSimHitContainer> PxlBrlHighContainer; iEvent.getByLabel(PxlBrlHighSrc_,PxlBrlHighContainer); if (!PxlBrlHighContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsPixelBarrelHighTof in event!"; return; } // place both containers into new container thePxlBrlHits.insert(thePxlBrlHits.end(),PxlBrlLowContainer->begin(), PxlBrlLowContainer->end()); 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(hTrackerPxBToF) hTrackerPxBToF->Fill(itHit->tof()); if(hTrackerPxBR) hTrackerPxBR->Fill(bSurface.toGlobal(itHit->localPosition()).perp()); if(hTrackerPxPhi) hTrackerPxPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi()); if(hTrackerPxEta) hTrackerPxEta->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.getByLabel(PxlFwdLowSrc_,PxlFwdLowContainer); if (!PxlFwdLowContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsPixelEndcapLowTof in event!"; return; } // extract high container edm::Handle<edm::PSimHitContainer> PxlFwdHighContainer; iEvent.getByLabel(PxlFwdHighSrc_,PxlFwdHighContainer); if (!PxlFwdHighContainer.isValid()) { edm::LogWarning("GlobalHitsProdHist_fillTrk") << "Unable to find TrackerHitsPixelEndcapHighTof in event!"; return; } // place both containers into new container thePxlFwdHits.insert(thePxlFwdHits.end(),PxlFwdLowContainer->begin(), PxlFwdLowContainer->end()); 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(hTrackerPxFToF) hTrackerPxFToF->Fill(itHit->tof()); if(hTrackerPxFZ) hTrackerPxFZ->Fill(bSurface.toGlobal(itHit->localPosition()).z()); if(hTrackerPxPhi) hTrackerPxPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi()); if(hTrackerPxEta) hTrackerPxEta->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 (hTrackerPx[0]) hTrackerPx[0]->Fill((float)nPxlHits); if (hTrackerPx[1]) hTrackerPx[1]->Fill((float)nPxlHits); // get Silicon Barrel information nSiHits = 0; edm::PSimHitContainer theSiBrlHits; // extract TIB low container edm::Handle<edm::PSimHitContainer> SiTIBLowContainer; iEvent.getByLabel(SiTIBLowSrc_,SiTIBLowContainer); if (!SiTIBLowContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsTIBLowTof in event!"; return; } // extract TIB high container edm::Handle<edm::PSimHitContainer> SiTIBHighContainer; iEvent.getByLabel(SiTIBHighSrc_,SiTIBHighContainer); if (!SiTIBHighContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsTIBHighTof in event!"; return; } // extract TOB low container edm::Handle<edm::PSimHitContainer> SiTOBLowContainer; iEvent.getByLabel(SiTOBLowSrc_,SiTOBLowContainer); if (!SiTOBLowContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsTOBLowTof in event!"; return; } // extract TOB high container edm::Handle<edm::PSimHitContainer> SiTOBHighContainer; iEvent.getByLabel(SiTOBHighSrc_,SiTOBHighContainer); if (!SiTOBHighContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsTOBHighTof in event!"; return; } // place all containers into new container theSiBrlHits.insert(theSiBrlHits.end(),SiTIBLowContainer->begin(), SiTIBLowContainer->end()); theSiBrlHits.insert(theSiBrlHits.end(),SiTIBHighContainer->begin(), SiTIBHighContainer->end()); theSiBrlHits.insert(theSiBrlHits.end(),SiTOBLowContainer->begin(), SiTOBLowContainer->end()); 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(hTrackerSiBToF) hTrackerSiBToF->Fill(itHit->tof()); if(hTrackerSiBR) hTrackerSiBR->Fill(bSurface.toGlobal(itHit->localPosition()).perp()); if(hTrackerSiPhi) hTrackerSiPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi()); if(hTrackerSiEta) hTrackerSiEta->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.getByLabel(SiTIDLowSrc_,SiTIDLowContainer); if (!SiTIDLowContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsTIDLowTof in event!"; return; } // extract TID high container edm::Handle<edm::PSimHitContainer> SiTIDHighContainer; iEvent.getByLabel(SiTIDHighSrc_,SiTIDHighContainer); if (!SiTIDHighContainer.isValid()) { edm::LogWarning("GlobalHitsProdHist_fillTrk") << "Unable to find TrackerHitsTIDHighTof in event!"; return; } // extract TEC low container edm::Handle<edm::PSimHitContainer> SiTECLowContainer; iEvent.getByLabel(SiTECLowSrc_,SiTECLowContainer); if (!SiTECLowContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsTECLowTof in event!"; return; } // extract TEC high container edm::Handle<edm::PSimHitContainer> SiTECHighContainer; iEvent.getByLabel(SiTECHighSrc_,SiTECHighContainer); if (!SiTECHighContainer.isValid()) { edm::LogWarning(MsgLoggerCat) << "Unable to find TrackerHitsTECHighTof in event!"; return; } // place all containers into new container theSiFwdHits.insert(theSiFwdHits.end(),SiTIDLowContainer->begin(), SiTIDLowContainer->end()); theSiFwdHits.insert(theSiFwdHits.end(),SiTIDHighContainer->begin(), SiTIDHighContainer->end()); theSiFwdHits.insert(theSiFwdHits.end(),SiTECLowContainer->begin(), SiTECLowContainer->end()); 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(hTrackerSiFToF) hTrackerSiFToF->Fill(itHit->tof()); if(hTrackerSiFZ) hTrackerSiFZ->Fill(bSurface.toGlobal(itHit->localPosition()).z()); if(hTrackerSiPhi) hTrackerSiPhi->Fill(bSurface.toGlobal(itHit->localPosition()).phi()); if(hTrackerSiEta) hTrackerSiEta->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 (hTrackerSi[0]) hTrackerSi[0]->Fill((float)nSiHits); if (hTrackerSi[1]) hTrackerSi[1]->Fill((float)nSiHits); if (verbosity > 0) edm::LogInfo(MsgLoggerCat) << eventout << "\n"; return; }
void GlobalHitsProdHist::produce | ( | edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [virtual] |
Implements edm::EDProducer.
Definition at line 630 of file GlobalHitsProdHist.cc.
References count, edm::EventID::event(), fillECal(), fillG4MC(), fillHCal(), fillMuon(), fillTrk(), frequency, edm::Event::getAllProvenance(), getAllProvenances, i, edm::EventBase::id(), printProvenanceInfo, edm::EventID::run(), and verbosity.
{ std::string MsgLoggerCat = "GlobalHitsProdHist_produce"; // keep track of number of events processed ++count; // get event id information int nrun = iEvent.id().run(); int 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::Provenance*> AllProv; iEvent.getAllProvenance(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; }
unsigned int GlobalHitsProdHist::count [private] |
Definition at line 207 of file GlobalHitsProdHist.h.
edm::InputTag GlobalHitsProdHist::ECalEBSrc_ [private] |
Definition at line 132 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
edm::InputTag GlobalHitsProdHist::ECalEESrc_ [private] |
Definition at line 133 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
edm::InputTag GlobalHitsProdHist::ECalESSrc_ [private] |
Definition at line 141 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
std::string GlobalHitsProdHist::fName [private] |
Definition at line 101 of file GlobalHitsProdHist.h.
Referenced by GlobalHitsProdHist().
int GlobalHitsProdHist::frequency [private] |
Definition at line 103 of file GlobalHitsProdHist.h.
Referenced by GlobalHitsProdHist(), and produce().
bool GlobalHitsProdHist::getAllProvenances [private] |
Definition at line 105 of file GlobalHitsProdHist.h.
Referenced by GlobalHitsProdHist(), and produce().
TH1F* GlobalHitsProdHist::hCaloEcal[2] [private] |
Definition at line 127 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloEcalE[2] [private] |
Definition at line 128 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloEcalEta [private] |
Definition at line 131 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloEcalPhi [private] |
Definition at line 130 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloEcalToF[2] [private] |
Definition at line 129 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloHcal[2] [private] |
Definition at line 145 of file GlobalHitsProdHist.h.
Referenced by fillHCal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloHcalE[2] [private] |
Definition at line 146 of file GlobalHitsProdHist.h.
Referenced by fillHCal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloHcalEta [private] |
Definition at line 149 of file GlobalHitsProdHist.h.
Referenced by fillHCal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloHcalPhi [private] |
Definition at line 148 of file GlobalHitsProdHist.h.
Referenced by fillHCal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloHcalToF[2] [private] |
Definition at line 147 of file GlobalHitsProdHist.h.
Referenced by fillHCal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloPreSh[2] [private] |
Definition at line 136 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloPreShE[2] [private] |
Definition at line 137 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloPreShEta [private] |
Definition at line 140 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloPreShPhi [private] |
Definition at line 139 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hCaloPreShToF[2] [private] |
Definition at line 138 of file GlobalHitsProdHist.h.
Referenced by fillECal(), and GlobalHitsProdHist().
edm::InputTag GlobalHitsProdHist::HCalSrc_ [private] |
Definition at line 150 of file GlobalHitsProdHist.h.
Referenced by fillHCal(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hGeantTrkE [private] |
Definition at line 122 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hGeantTrkPt [private] |
Definition at line 121 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hGeantVtxX[2] [private] |
Definition at line 117 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hGeantVtxY[2] [private] |
Definition at line 118 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hGeantVtxZ[2] [private] |
Definition at line 119 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().
std::map<std::string, TH1F*> GlobalHitsProdHist::histMap_ [private] |
Definition at line 112 of file GlobalHitsProdHist.h.
Referenced by endRun(), and GlobalHitsProdHist().
std::vector<std::string> GlobalHitsProdHist::histName_ [private] |
Definition at line 111 of file GlobalHitsProdHist.h.
Referenced by endRun(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMCG4Trk[2] [private] |
Definition at line 120 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMCG4Vtx[2] [private] |
Definition at line 116 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMCRGP[2] [private] |
Definition at line 115 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuon[2] [private] |
Definition at line 186 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonCscToF[2] [private] |
Definition at line 196 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonCscZ [private] |
Definition at line 197 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonDtR [private] |
Definition at line 193 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonDtToF[2] [private] |
Definition at line 192 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonEta [private] |
Definition at line 188 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonPhi [private] |
Definition at line 187 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonRpcBR [private] |
Definition at line 203 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonRpcBToF[2] [private] |
Definition at line 202 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonRpcFToF[2] [private] |
Definition at line 200 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hMuonRpcFZ [private] |
Definition at line 201 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerPx[2] [private] |
Definition at line 155 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerPxBR [private] |
Definition at line 159 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerPxBToF [private] |
Definition at line 158 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerPxEta [private] |
Definition at line 157 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerPxFToF [private] |
Definition at line 160 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerPxFZ [private] |
Definition at line 161 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerPxPhi [private] |
Definition at line 156 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerSi[2] [private] |
Definition at line 169 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerSiBR [private] |
Definition at line 173 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerSiBToF [private] |
Definition at line 172 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerSiEta [private] |
Definition at line 171 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerSiFToF [private] |
Definition at line 174 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerSiFZ [private] |
Definition at line 175 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
TH1F* GlobalHitsProdHist::hTrackerSiPhi [private] |
Definition at line 170 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
edm::InputTag GlobalHitsProdHist::MuonCscSrc_ [private] |
Definition at line 198 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
edm::InputTag GlobalHitsProdHist::MuonDtSrc_ [private] |
Definition at line 194 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
edm::InputTag GlobalHitsProdHist::MuonRpcSrc_ [private] |
Definition at line 204 of file GlobalHitsProdHist.h.
Referenced by fillMuon(), and GlobalHitsProdHist().
int GlobalHitsProdHist::nMuonHits [private] |
Definition at line 189 of file GlobalHitsProdHist.h.
Referenced by fillMuon().
int GlobalHitsProdHist::nPxlHits [private] |
Definition at line 154 of file GlobalHitsProdHist.h.
Referenced by fillTrk().
int GlobalHitsProdHist::nRawGenPart [private] |
Definition at line 123 of file GlobalHitsProdHist.h.
Referenced by fillG4MC().
int GlobalHitsProdHist::nSiHits [private] |
Definition at line 168 of file GlobalHitsProdHist.h.
Referenced by fillTrk().
bool GlobalHitsProdHist::printProvenanceInfo [private] |
Definition at line 106 of file GlobalHitsProdHist.h.
Referenced by GlobalHitsProdHist(), and produce().
Definition at line 163 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 162 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 165 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 164 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 183 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 182 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 177 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 176 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 181 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 180 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 179 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
Definition at line 178 of file GlobalHitsProdHist.h.
Referenced by fillTrk(), and GlobalHitsProdHist().
int GlobalHitsProdHist::verbosity [private] |
Definition at line 102 of file GlobalHitsProdHist.h.
Referenced by endJob(), endRun(), fillECal(), fillG4MC(), fillHCal(), fillMuon(), fillTrk(), GlobalHitsProdHist(), and produce().
int GlobalHitsProdHist::vtxunit [private] |
Definition at line 104 of file GlobalHitsProdHist.h.
Referenced by fillG4MC(), and GlobalHitsProdHist().