/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id: $ */ //_________________________________________________________________________ // Class to check results from simulations or reconstructed real data. // Fill few histograms and do some checking plots // //-- Author: Gustavo Conesa (INFN-LNF) //_________________________________________________________________________ // --- ROOT system --- //#include "Riostream.h" #include "TObjArray.h" #include "TParticle.h" #include "TDatabasePDG.h" #include "TCanvas.h" #include "TPad.h" #include "TROOT.h" #include "TH3F.h" #include "TH2F.h" #include "TLegend.h" #include "TStyle.h" #include //---- AliRoot system ---- #include "AliAnaCalorimeterQA.h" #include "AliCaloTrackReader.h" #include "AliStack.h" #include "AliVCaloCells.h" #include "AliFiducialCut.h" #include "AliVTrack.h" #include "AliVCluster.h" #include "AliVEvent.h" #include "AliVEventHandler.h" #include "AliAnalysisManager.h" #include "AliAODMCParticle.h" #include "AliMCAnalysisUtils.h" #include "AliAODPid.h" #include "AliExternalTrackParam.h" ClassImp(AliAnaCalorimeterQA) //____________________________________________________________________________ AliAnaCalorimeterQA::AliAnaCalorimeterQA() : AliAnaPartCorrBaseClass(), fCalorimeter(""), fStyleMacro(""), fFillAllPosHisto(kFALSE), fFillAllTH12(kFALSE), fCorrelate(kTRUE), fNModules(12), fNRCU(2), fTimeCutMin(-1), fTimeCutMax(9999999), fEMCALCellAmpMin(0),fPHOSCellAmpMin(0), fHistoFinePtBins(1000), fHistoFinePtMax(5.), fHistoFinePtMin(0.), fHistoPOverEBins(100), fHistoPOverEMax(100.), fHistoPOverEMin(0.), fHistodEdxBins(100), fHistodEdxMax(100.), fHistodEdxMin(0.), fHistodRBins(100), fHistodRMax(100.), fHistodRMin(0.), fHistoTimeBins(100), fHistoTimeMax(100.), fHistoTimeMin(0.), fHistoNBins(100), fHistoNMax(100), fHistoNMin(0), fHistoRatioBins(100), fHistoRatioMax(100.), fHistoRatioMin(0.), fHistoVertexDistBins(100), fHistoVertexDistMax(100.), fHistoVertexDistMin(0.), fHistoRBins(100), fHistoRMax(1000), fHistoRMin(-1000), fHistoXBins(100), fHistoXMax(1000), fHistoXMin(-1000), fHistoYBins(100), fHistoYMax(1000), fHistoYMin(-1000), fHistoZBins(100), fHistoZMax(1000), fHistoZMin(-1000), fHistoSSBins(25), fHistoSSMax(5), fHistoSSMin(0), fhE(0),fhPt(0),fhPhi(0),fhEta(0), fhEtaPhiE(0), fhECharged(0),fhPtCharged(0),fhPhiCharged(0),fhEtaCharged(0), fhEtaPhiECharged(0), fhDeltaE(0), fhDeltaPt(0),fhDeltaPhi(0),fhDeltaEta(0), fhRatioE(0), fhRatioPt(0),fhRatioPhi(0),fhRatioEta(0), fh2E(0),fh2Pt(0),fh2Phi(0),fh2Eta(0), fhLambda(0), fhDispersion(0), fhIM(0), fhIMCellCut(0),fhAsym(0), fhNCellsPerCluster(0),fhNCellsPerClusterMIP(0), fhNCellsPerClusterMIPCharged(0), fhNClusters(0), fhClusterTimeEnergy(0),fhCellTimeSpreadRespectToCellMax(0),fhCellIdCellLargeTimeSpread(0), fhRNCells(0),fhXNCells(0),fhYNCells(0),fhZNCells(0), fhRE(0), fhXE(0), fhYE(0), fhZE(0), fhXYZ(0), fhRCellE(0), fhXCellE(0), fhYCellE(0), fhZCellE(0),fhXYZCell(0), fhDeltaCellClusterRNCells(0),fhDeltaCellClusterXNCells(0),fhDeltaCellClusterYNCells(0),fhDeltaCellClusterZNCells(0), fhDeltaCellClusterRE(0), fhDeltaCellClusterXE(0), fhDeltaCellClusterYE(0), fhDeltaCellClusterZE(0), fhNCells(0), fhAmplitude(0), fhAmpId(0), fhEtaPhiAmp(0), fhTime(0), fhTimeId(0), fhTimeAmp(0), //fhT0Time(0), fhT0TimeId(0), fhT0TimeAmp(0), fhCaloCorrNClusters(0), fhCaloCorrEClusters(0), fhCaloCorrNCells(0), fhCaloCorrECells(0), fhCaloV0SCorrNClusters(0), fhCaloV0SCorrEClusters(0), fhCaloV0SCorrNCells(0), fhCaloV0SCorrECells(0), fhCaloV0MCorrNClusters(0), fhCaloV0MCorrEClusters(0), fhCaloV0MCorrNCells(0), fhCaloV0MCorrECells(0), fhCaloTrackMCorrNClusters(0), fhCaloTrackMCorrEClusters(0), fhCaloTrackMCorrNCells(0), fhCaloTrackMCorrECells(0), fhEMod(0), fhNClustersMod(0), fhNCellsPerClusterMod(0), fhNCellsMod(0), fhGridCellsMod(0), fhGridCellsEMod(0), fhGridCellsTimeMod(0), fhAmplitudeMod(0), fhAmplitudeModFraction(0),fhTimeAmpPerRCU(0), //fhT0TimeAmpPerRCU(0), fhTimeCorrRCU(0), fhIMMod(0), fhIMCellCutMod(0), fhGenGamPt(0),fhGenGamEta(0),fhGenGamPhi(0),fhGenPi0Pt(0),fhGenPi0Eta(0),fhGenPi0Phi(0), fhGenEtaPt(0),fhGenEtaEta(0),fhGenEtaPhi(0),fhGenOmegaPt(0),fhGenOmegaEta(0),fhGenOmegaPhi(0), fhGenElePt(0),fhGenEleEta(0),fhGenElePhi(0), fhEMVxyz(0), fhEMR(0), fhHaVxyz(0), fhHaR(0), fhGamE(0),fhGamPt(0),fhGamPhi(0),fhGamEta(0), fhGamDeltaE(0), fhGamDeltaPt(0),fhGamDeltaPhi(0),fhGamDeltaEta(0), fhGamRatioE(0), fhGamRatioPt(0),fhGamRatioPhi(0),fhGamRatioEta(0), fhEleE(0),fhElePt(0),fhElePhi(0),fhEleEta(0), fhPi0E(0),fhPi0Pt(0),fhPi0Phi(0),fhPi0Eta(0), fhNeHadE(0),fhNeHadPt(0),fhNeHadPhi(0),fhNeHadEta(0), fhChHadE(0),fhChHadPt(0),fhChHadPhi(0),fhChHadEta(0), fhGamECharged(0),fhGamPtCharged(0),fhGamPhiCharged(0),fhGamEtaCharged(0), fhEleECharged(0),fhElePtCharged(0),fhElePhiCharged(0),fhEleEtaCharged(0), fhPi0ECharged(0),fhPi0PtCharged(0),fhPi0PhiCharged(0),fhPi0EtaCharged(0), fhNeHadECharged(0),fhNeHadPtCharged(0),fhNeHadPhiCharged(0),fhNeHadEtaCharged(0), fhChHadECharged(0),fhChHadPtCharged(0),fhChHadPhiCharged(0),fhChHadEtaCharged(0), fhGenGamAccE(0),fhGenGamAccPt(0),fhGenGamAccEta(0),fhGenGamAccPhi(0), fhGenPi0AccE(0),fhGenPi0AccPt(0),fhGenPi0AccEta(0),fhGenPi0AccPhi(0), fh1pOverE(0),fh1dR(0),fh2EledEdx(0), fh2MatchdEdx(0),fhMCEle1pOverE(0),fhMCEle1dR(0),fhMCEle2MatchdEdx(0), fhMCChHad1pOverE(0), fhMCChHad1dR(0), fhMCChHad2MatchdEdx(0), fhMCNeutral1pOverE(0),fhMCNeutral1dR(0),fhMCNeutral2MatchdEdx(0), fh1pOverER02(0), fhMCEle1pOverER02(0), fhMCChHad1pOverER02(0), fhMCNeutral1pOverER02(0) { //Default Ctor //Initialize parameters InitParameters(); } //________________________________________________________________________ TObjString * AliAnaCalorimeterQA::GetAnalysisCuts() { //Save parameters used for analysis TString parList ; //this will be list of parameters used for this analysis. const Int_t buffersize = 255; char onePar[buffersize] ; snprintf(onePar,buffersize,"--- AliAnaCalorimeterQA ---\n") ; parList+=onePar ; snprintf(onePar,buffersize,"Calorimeter: %s\n",fCalorimeter.Data()) ; parList+=onePar ; snprintf(onePar,buffersize,"Time Cut : %2.2f < T < %2.2f ns \n",fTimeCutMin, fTimeCutMax) ; parList+=onePar ; snprintf(onePar,buffersize,"PHOS Cell Amplitude > %2.2f GeV, EMCAL Cell Amplitude > %2.2f GeV \n",fPHOSCellAmpMin, fEMCALCellAmpMin) ; parList+=onePar ; //Get parameters set in base class. //parList += GetBaseParametersList() ; //Get parameters set in FiducialCut class (not available yet) //parlist += GetFidCut()->GetFidCutParametersList() return new TObjString(parList) ; } //________________________________________________________________________ TList * AliAnaCalorimeterQA::GetCreateOutputObjects() { // Create histograms to be saved in output file and // store them in outputContainer TList * outputContainer = new TList() ; outputContainer->SetName("QAHistos") ; //Histograms Int_t nptbins = GetHistoPtBins(); Float_t ptmax = GetHistoPtMax(); Float_t ptmin = GetHistoPtMin(); Int_t nfineptbins = GetHistoFinePtBins(); Float_t ptfinemax = GetHistoFinePtMax(); Float_t ptfinemin = GetHistoFinePtMin(); Int_t nphibins = GetHistoPhiBins(); Float_t phimax = GetHistoPhiMax(); Float_t phimin = GetHistoPhiMin(); Int_t netabins = GetHistoEtaBins(); Float_t etamax = GetHistoEtaMax(); Float_t etamin = GetHistoEtaMin(); Int_t nmassbins = GetHistoMassBins(); Float_t massmax = GetHistoMassMax(); Float_t massmin = GetHistoMassMin(); Int_t nasymbins = GetHistoAsymmetryBins(); Float_t asymmax = GetHistoAsymmetryMax(); Float_t asymmin = GetHistoAsymmetryMin(); Int_t nPoverEbins = GetHistoPOverEBins(); Float_t pOverEmax = GetHistoPOverEMax(); Float_t pOverEmin = GetHistoPOverEMin(); Int_t ndedxbins = GetHistodEdxBins(); Float_t dedxmax = GetHistodEdxMax(); Float_t dedxmin = GetHistodEdxMin(); Int_t ndRbins = GetHistodRBins(); Float_t dRmax = GetHistodRMax(); Float_t dRmin = GetHistodRMin(); Int_t ntimebins = GetHistoTimeBins(); Float_t timemax = GetHistoTimeMax(); Float_t timemin = GetHistoTimeMin(); Int_t nbins = GetHistoNClusterCellBins(); Int_t nmax = GetHistoNClusterCellMax(); Int_t nmin = GetHistoNClusterCellMin(); Int_t nratiobins = GetHistoRatioBins(); Float_t ratiomax = GetHistoRatioMax(); Float_t ratiomin = GetHistoRatioMin(); Int_t nvdistbins = GetHistoVertexDistBins(); Float_t vdistmax = GetHistoVertexDistMax(); Float_t vdistmin = GetHistoVertexDistMin(); Int_t rbins = GetHistoRBins(); Float_t rmax = GetHistoRMax(); Float_t rmin = GetHistoRMin(); Int_t xbins = GetHistoXBins(); Float_t xmax = GetHistoXMax(); Float_t xmin = GetHistoXMin(); Int_t ybins = GetHistoYBins(); Float_t ymax = GetHistoYMax(); Float_t ymin = GetHistoYMin(); Int_t zbins = GetHistoZBins(); Float_t zmax = GetHistoZMax(); Float_t zmin = GetHistoZMin(); Int_t ssbins = GetHistoShowerShapeBins(); Float_t ssmax = GetHistoShowerShapeMax(); Float_t ssmin = GetHistoShowerShapeMin(); Int_t nv0sbins = GetHistoV0SignalBins(); Int_t nv0smax = GetHistoV0SignalMax(); Int_t nv0smin = GetHistoV0SignalMin(); Int_t nv0mbins = GetHistoV0MultiplicityBins();Int_t nv0mmax = GetHistoV0MultiplicityMax();Int_t nv0mmin = GetHistoV0MultiplicityMin(); Int_t ntrmbins = GetHistoTrackMultiplicityBins();Int_t ntrmmax = GetHistoTrackMultiplicityMax();Int_t ntrmmin = GetHistoTrackMultiplicityMin(); //EMCAL Int_t colmax = 48; Int_t rowmax = 24; fNRCU = 2 ; //PHOS if(fCalorimeter=="PHOS"){ colmax = 56; rowmax = 64; fNRCU = 4 ; } fhE = new TH1F ("hE","E reconstructed clusters ", nptbins*5,ptmin,ptmax*5); fhE->SetXTitle("E (GeV)"); outputContainer->Add(fhE); if(fFillAllTH12){ fhPt = new TH1F ("hPt","p_{T} reconstructed clusters", nptbins,ptmin,ptmax); fhPt->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhPt); fhPhi = new TH1F ("hPhi","#phi reconstructed clusters ",nphibins,phimin,phimax); fhPhi->SetXTitle("#phi (rad)"); outputContainer->Add(fhPhi); fhEta = new TH1F ("hEta","#eta reconstructed clusters ",netabins,etamin,etamax); fhEta->SetXTitle("#eta "); outputContainer->Add(fhEta); } fhEtaPhiE = new TH3F ("hEtaPhiE","#eta vs #phi vs energy, reconstructed clusters", netabins,etamin,etamax,nphibins,phimin,phimax,nptbins,ptmin,ptmax); fhEtaPhiE->SetXTitle("#eta "); fhEtaPhiE->SetYTitle("#phi (rad)"); fhEtaPhiE->SetZTitle("E (GeV) "); outputContainer->Add(fhEtaPhiE); fhClusterTimeEnergy = new TH2F ("hClusterTimeEnergy","energy vs TOF, reconstructed clusters", nptbins,ptmin,ptmax, ntimebins,timemin,timemax); fhClusterTimeEnergy->SetXTitle("E (GeV) "); fhClusterTimeEnergy->SetYTitle("TOF (ns)"); outputContainer->Add(fhClusterTimeEnergy); //Shower shape fhLambda = new TH3F ("hLambda","#lambda_{0}^{2} vs #lambda_{1}^{2} vs energy, reconstructed clusters", ssbins,ssmin,ssmax,ssbins,ssmin,ssmax,nptbins,ptmin,ptmax); fhLambda->SetXTitle("#lambda_{0}^{2} "); fhLambda->SetYTitle("#lambda_{1}^{2} "); fhLambda->SetZTitle("E (GeV) "); outputContainer->Add(fhLambda); fhDispersion = new TH2F ("hDispersion"," dispersion vs energy, reconstructed clusters", ssbins,ssmin,ssmax,nptbins,ptmin,ptmax); fhDispersion->SetXTitle("Dispersion "); fhDispersion->SetYTitle("E (GeV) "); outputContainer->Add(fhDispersion); //Track Matching if(fFillAllTH12){ fhECharged = new TH1F ("hECharged","E reconstructed clusters, matched with track", nptbins,ptmin,ptmax); fhECharged->SetXTitle("E (GeV)"); outputContainer->Add(fhECharged); fhPtCharged = new TH1F ("hPtCharged","p_{T} reconstructed clusters, matched with track", nptbins,ptmin,ptmax); fhPtCharged->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhPtCharged); fhPhiCharged = new TH1F ("hPhiCharged","#phi reconstructed clusters, matched with track",nphibins,phimin,phimax); fhPhiCharged->SetXTitle("#phi (rad)"); outputContainer->Add(fhPhiCharged); fhEtaCharged = new TH1F ("hEtaCharged","#eta reconstructed clusters, matched with track",netabins,etamin,etamax); fhEtaCharged->SetXTitle("#eta "); outputContainer->Add(fhEtaCharged); } fhEtaPhiECharged = new TH3F ("hEtaPhiECharged","#eta vs #phi, reconstructed clusters, matched with track", netabins,etamin,etamax,nphibins,phimin,phimax,nptbins,ptmin,ptmax); fhEtaPhiECharged->SetXTitle("#eta "); fhEtaPhiECharged->SetYTitle("#phi "); fhEtaPhiECharged->SetZTitle("E (GeV) "); outputContainer->Add(fhEtaPhiECharged); fh1pOverE = new TH2F("h1pOverE","TRACK matches p/E",nptbins,ptmin,ptmax, nPoverEbins,pOverEmin,pOverEmax); fh1pOverE->SetYTitle("p/E"); fh1pOverE->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fh1pOverE); fh1dR = new TH1F("h1dR","TRACK matches dR",ndRbins,dRmin,dRmax); fh1dR->SetXTitle("#Delta R (rad)"); outputContainer->Add(fh1dR) ; fh2MatchdEdx = new TH2F("h2MatchdEdx","dE/dx vs. p for all matches",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); fh2MatchdEdx->SetXTitle("p (GeV/c)"); fh2MatchdEdx->SetYTitle(""); outputContainer->Add(fh2MatchdEdx); fh2EledEdx = new TH2F("h2EledEdx","dE/dx vs. p for electrons",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); fh2EledEdx->SetXTitle("p (GeV/c)"); fh2EledEdx->SetYTitle(""); outputContainer->Add(fh2EledEdx) ; fh1pOverER02 = new TH2F("h1pOverER02","TRACK matches p/E, all",nptbins,ptmin,ptmax, nPoverEbins,pOverEmin,pOverEmax); fh1pOverER02->SetYTitle("p/E"); fh1pOverER02->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fh1pOverER02); fhIM = new TH2F ("hIM","Cluster pairs Invariant mass vs reconstructed pair energy",nptbins,ptmin,ptmax,nmassbins,massmin,massmax); fhIM->SetXTitle("p_{T, cluster pairs} (GeV) "); fhIM->SetYTitle("M_{cluster pairs} (GeV/c^{2})"); outputContainer->Add(fhIM); fhIMCellCut = new TH2F ("hIMCellCut","Cluster (n cell > 1) pairs Invariant mass vs reconstructed pair energy",nptbins,ptmin,ptmax,nmassbins,massmin,massmax); fhIMCellCut->SetXTitle("p_{T, cluster pairs} (GeV) "); fhIMCellCut->SetYTitle("M_{cluster pairs} (GeV/c^{2})"); outputContainer->Add(fhIMCellCut); fhAsym = new TH2F ("hAssym","Cluster pairs Asymmetry vs reconstructed pair energy",nptbins,ptmin,ptmax,nasymbins,asymmin,asymmax); fhAsym->SetXTitle("p_{T, cluster pairs} (GeV) "); fhAsym->SetYTitle("Asymmetry"); outputContainer->Add(fhAsym); Int_t nlargeetabins = 3; if(fCalorimeter=="EMCAL") nlargeetabins = 8; fhNCellsPerCluster = new TH3F ("hNCellsPerCluster","# cells per cluster vs energy vs #eta",nptbins,ptmin,ptmax, nbins,nmin,nmax, nlargeetabins,etamin,etamax); fhNCellsPerCluster->SetXTitle("E (GeV)"); fhNCellsPerCluster->SetYTitle("n cells"); fhNCellsPerCluster->SetZTitle("#eta"); outputContainer->Add(fhNCellsPerCluster); fhNCellsPerClusterMIP = new TH3F ("hNCellsPerClusterMIP","# cells per cluster vs energy vs #eta, smaller bin for MIP search", 40,0.,2., 11,0,10,nlargeetabins,etamin,etamax); fhNCellsPerClusterMIP->SetXTitle("E (GeV)"); fhNCellsPerClusterMIP->SetYTitle("n cells"); fhNCellsPerClusterMIP->SetZTitle("#eta"); outputContainer->Add(fhNCellsPerClusterMIP); fhNCellsPerClusterMIPCharged = new TH3F ("hNCellsPerClusterMIPCharged","# cells per track-matched cluster vs energy vs #eta, smaller bin for MIP search", 40,0.,2., 11,0,10,nlargeetabins,etamin,etamax); fhNCellsPerClusterMIPCharged->SetXTitle("E (GeV)"); fhNCellsPerClusterMIPCharged->SetYTitle("n cells"); fhNCellsPerClusterMIPCharged->SetZTitle("#eta"); outputContainer->Add(fhNCellsPerClusterMIPCharged); fhNClusters = new TH1F ("hNClusters","# clusters", nbins,nmin,nmax); fhNClusters->SetXTitle("number of clusters"); outputContainer->Add(fhNClusters); fhXYZ = new TH3F ("hXYZ","Cluster: x vs y vs z",xbins,xmin,xmax,ybins,ymin,ymax,zbins,zmin,zmax); fhXYZ->SetXTitle("x (cm)"); fhXYZ->SetYTitle("y (cm)"); fhXYZ->SetZTitle("z (cm) "); outputContainer->Add(fhXYZ); fhXNCells = new TH2F ("hXNCells","Cluster X position vs N Clusters per Cell",xbins,xmin,xmax,nbins,nmin,nmax); fhXNCells->SetXTitle("x (cm)"); fhXNCells->SetYTitle("N cells per cluster"); outputContainer->Add(fhXNCells); fhZNCells = new TH2F ("hZNCells","Cluster Z position vs N Clusters per Cell",zbins,zmin,zmax,nbins,nmin,nmax); fhZNCells->SetXTitle("z (cm)"); fhZNCells->SetYTitle("N cells per cluster"); outputContainer->Add(fhZNCells); fhXE = new TH2F ("hXE","Cluster X position vs cluster energy",xbins,xmin,xmax,nptbins,ptmin,ptmax); fhXE->SetXTitle("x (cm)"); fhXE->SetYTitle("E (GeV)"); outputContainer->Add(fhXE); fhZE = new TH2F ("hZE","Cluster Z position vs cluster energy",zbins,zmin,zmax,nptbins,ptmin,ptmax); fhZE->SetXTitle("z (cm)"); fhZE->SetYTitle("E (GeV)"); outputContainer->Add(fhZE); fhRNCells = new TH2F ("hRNCells","Cluster R position vs N Clusters per Cell",rbins,rmin,rmax,nbins,nmin,nmax); fhRNCells->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); fhRNCells->SetYTitle("N cells per cluster"); outputContainer->Add(fhRNCells); fhYNCells = new TH2F ("hYNCells","Cluster Y position vs N Clusters per Cell",ybins,ymin,ymax,nbins,nmin,nmax); fhYNCells->SetXTitle("y (cm)"); fhYNCells->SetYTitle("N cells per cluster"); outputContainer->Add(fhYNCells); fhRE = new TH2F ("hRE","Cluster R position vs cluster energy",rbins,rmin,rmax,nptbins,ptmin,ptmax); fhRE->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); fhRE->SetYTitle("E (GeV)"); outputContainer->Add(fhRE); fhYE = new TH2F ("hYE","Cluster Y position vs cluster energy",ybins,ymin,ymax,nptbins,ptmin,ptmax); fhYE->SetXTitle("y (cm)"); fhYE->SetYTitle("E (GeV)"); outputContainer->Add(fhYE); if(fFillAllPosHisto){ fhRCellE = new TH2F ("hRCellE","Cell R position vs cell energy",rbins,rmin,rmax,nptbins,ptmin,ptmax); fhRCellE->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); fhRCellE->SetYTitle("E (GeV)"); outputContainer->Add(fhRCellE); fhXCellE = new TH2F ("hXCellE","Cell X position vs cell energy",xbins,xmin,xmax,nptbins,ptmin,ptmax); fhXCellE->SetXTitle("x (cm)"); fhXCellE->SetYTitle("E (GeV)"); outputContainer->Add(fhXCellE); fhYCellE = new TH2F ("hYCellE","Cell Y position vs cell energy",ybins,ymin,ymax,nptbins,ptmin,ptmax); fhYCellE->SetXTitle("y (cm)"); fhYCellE->SetYTitle("E (GeV)"); outputContainer->Add(fhYCellE); fhZCellE = new TH2F ("hZCellE","Cell Z position vs cell energy",zbins,zmin,zmax,nptbins,ptmin,ptmax); fhZCellE->SetXTitle("z (cm)"); fhZCellE->SetYTitle("E (GeV)"); outputContainer->Add(fhZCellE); fhXYZCell = new TH3F ("hXYZCell","Cell : x vs y vs z",xbins,xmin,xmax,ybins,ymin,ymax,zbins,zmin,zmax); fhXYZCell->SetXTitle("x (cm)"); fhXYZCell->SetYTitle("y (cm)"); fhXYZCell->SetZTitle("z (cm)"); outputContainer->Add(fhXYZCell); Float_t dx = TMath::Abs(xmin)+TMath::Abs(xmax); Float_t dy = TMath::Abs(ymin)+TMath::Abs(ymax); Float_t dz = TMath::Abs(zmin)+TMath::Abs(zmax); Float_t dr = TMath::Abs(rmin)+TMath::Abs(rmax); fhDeltaCellClusterRNCells = new TH2F ("hDeltaCellClusterRNCells","Cluster-Cell R position vs N Clusters per Cell",rbins*2,-dr,dr,nbins,nmin,nmax); fhDeltaCellClusterRNCells->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); fhDeltaCellClusterRNCells->SetYTitle("N cells per cluster"); outputContainer->Add(fhDeltaCellClusterRNCells); fhDeltaCellClusterXNCells = new TH2F ("hDeltaCellClusterXNCells","Cluster-Cell X position vs N Clusters per Cell",xbins*2,-dx,dx,nbins,nmin,nmax); fhDeltaCellClusterXNCells->SetXTitle("x (cm)"); fhDeltaCellClusterXNCells->SetYTitle("N cells per cluster"); outputContainer->Add(fhDeltaCellClusterXNCells); fhDeltaCellClusterYNCells = new TH2F ("hDeltaCellClusterYNCells","Cluster-Cell Y position vs N Clusters per Cell",ybins*2,-dy,dy,nbins,nmin,nmax); fhDeltaCellClusterYNCells->SetXTitle("y (cm)"); fhDeltaCellClusterYNCells->SetYTitle("N cells per cluster"); outputContainer->Add(fhDeltaCellClusterYNCells); fhDeltaCellClusterZNCells = new TH2F ("hDeltaCellClusterZNCells","Cluster-Cell Z position vs N Clusters per Cell",zbins*2,-dz,dz,nbins,nmin,nmax); fhDeltaCellClusterZNCells->SetXTitle("z (cm)"); fhDeltaCellClusterZNCells->SetYTitle("N cells per cluster"); outputContainer->Add(fhDeltaCellClusterZNCells); fhDeltaCellClusterRE = new TH2F ("hDeltaCellClusterRE","Cluster-Cell R position vs cluster energy",rbins*2,-dr,dr,nptbins,ptmin,ptmax); fhDeltaCellClusterRE->SetXTitle("r = #sqrt{x^{2}+y^{2}} (cm)"); fhDeltaCellClusterRE->SetYTitle("E (GeV)"); outputContainer->Add(fhDeltaCellClusterRE); fhDeltaCellClusterXE = new TH2F ("hDeltaCellClusterXE","Cluster-Cell X position vs cluster energy",xbins*2,-dx,dx,nptbins,ptmin,ptmax); fhDeltaCellClusterXE->SetXTitle("x (cm)"); fhDeltaCellClusterXE->SetYTitle("E (GeV)"); outputContainer->Add(fhDeltaCellClusterXE); fhDeltaCellClusterYE = new TH2F ("hDeltaCellClusterYE","Cluster-Cell Y position vs cluster energy",ybins*2,-dy,dy,nptbins,ptmin,ptmax); fhDeltaCellClusterYE->SetXTitle("y (cm)"); fhDeltaCellClusterYE->SetYTitle("E (GeV)"); outputContainer->Add(fhDeltaCellClusterYE); fhDeltaCellClusterZE = new TH2F ("hDeltaCellClusterZE","Cluster-Cell Z position vs cluster energy",zbins*2,-dz,dz,nptbins,ptmin,ptmax); fhDeltaCellClusterZE->SetXTitle("z (cm)"); fhDeltaCellClusterZE->SetYTitle("E (GeV)"); outputContainer->Add(fhDeltaCellClusterZE); fhEtaPhiAmp = new TH3F ("hEtaPhiAmp","Cell #eta vs cell #phi vs cell energy",netabins,etamin,etamax,nphibins,phimin,phimax,nptbins,ptmin,ptmax); fhEtaPhiAmp->SetXTitle("#eta "); fhEtaPhiAmp->SetYTitle("#phi (rad)"); fhEtaPhiAmp->SetZTitle("E (GeV) "); outputContainer->Add(fhEtaPhiAmp); } //Calo cells fhNCells = new TH1F ("hNCells","# cells", colmax*rowmax*fNModules,0,colmax*rowmax*fNModules); fhNCells->SetXTitle("n cells"); outputContainer->Add(fhNCells); fhAmplitude = new TH1F ("hAmplitude","Cell Energy", nptbins*2,ptmin,ptmax); fhAmplitude->SetXTitle("Cell Energy (GeV)"); outputContainer->Add(fhAmplitude); fhAmpId = new TH2F ("hAmpId","Cell Energy", nfineptbins,ptfinemin,ptfinemax,rowmax*colmax*fNModules,0,rowmax*colmax*fNModules); fhAmpId->SetXTitle("Cell Energy (GeV)"); outputContainer->Add(fhAmpId); //Cell Time histograms, time only available in ESDs if(GetReader()->GetDataType()==AliCaloTrackReader::kESD) { fhCellTimeSpreadRespectToCellMax = new TH1F ("hCellTimeSpreadRespectToCellMax","t_{cell max}-t_{cell i} per cluster", 100,-200,200); fhCellTimeSpreadRespectToCellMax->SetXTitle("#Delta t (ns)"); outputContainer->Add(fhCellTimeSpreadRespectToCellMax); fhCellIdCellLargeTimeSpread= new TH1F ("hCellIdCellLargeTimeSpread","", colmax*rowmax*fNModules,0,colmax*rowmax*fNModules); fhCellIdCellLargeTimeSpread->SetXTitle("Absolute Cell Id"); outputContainer->Add(fhCellIdCellLargeTimeSpread); fhTime = new TH1F ("hTime","Cell Time",ntimebins,timemin,timemax); fhTime->SetXTitle("Cell Time (ns)"); outputContainer->Add(fhTime); fhTimeId = new TH2F ("hTimeId","Cell Time vs Absolute Id",ntimebins,timemin,timemax,rowmax*colmax*fNModules,0,rowmax*colmax*fNModules); fhTimeId->SetXTitle("Cell Time (ns)"); fhTimeId->SetYTitle("Cell Absolute Id"); outputContainer->Add(fhTimeId); fhTimeAmp = new TH2F ("hTimeAmp","Cell Time vs Cell Energy",nptbins*2,ptmin,ptmax,ntimebins,timemin,timemax); fhTimeAmp->SetYTitle("Cell Time (ns)"); fhTimeAmp->SetXTitle("Cell Energy (GeV)"); outputContainer->Add(fhTimeAmp); // fhT0Time = new TH1F ("hT0Time","Cell Time",ntimebins,timemin,timemax); // fhT0Time->SetXTitle("T_{0} - T_{EMCal} (ns)"); // outputContainer->Add(fhT0Time); // // fhT0TimeId = new TH2F ("hT0TimeId","Cell Time vs Absolute Id",ntimebins,timemin,timemax,rowmax*colmax*fNModules,0,rowmax*colmax*fNModules); // fhT0TimeId->SetXTitle("T_{0} - T_{EMCal} (ns)"); // fhT0TimeId->SetYTitle("Cell Absolute Id"); // outputContainer->Add(fhT0TimeId); // // fhT0TimeAmp = new TH2F ("hT0TimeAmp","Cell Time vs Cell Energy",nptbins*2,ptmin,ptmax,ntimebins,timemin,timemax); // fhT0TimeAmp->SetYTitle("T_{0} - T_{EMCal} (ns)"); // fhT0TimeAmp->SetXTitle("Cell Energy (GeV)"); // outputContainer->Add(fhT0TimeAmp); } if(fCorrelate){ //PHOS vs EMCAL fhCaloCorrNClusters = new TH2F ("hCaloCorrNClusters","# clusters in EMCAL vs PHOS", nbins,nmin,nmax,nbins,nmin,nmax); fhCaloCorrNClusters->SetXTitle("number of clusters in EMCAL"); fhCaloCorrNClusters->SetYTitle("number of clusters in PHOS"); outputContainer->Add(fhCaloCorrNClusters); fhCaloCorrEClusters = new TH2F ("hCaloCorrEClusters","summed energy of clusters in EMCAL vs PHOS", nptbins,ptmin,ptmax,nptbins,ptmin,ptmax); fhCaloCorrEClusters->SetXTitle("#Sigma E of clusters in EMCAL (GeV)"); fhCaloCorrEClusters->SetYTitle("#Sigma E of clusters in PHOS (GeV)"); outputContainer->Add(fhCaloCorrEClusters); fhCaloCorrNCells = new TH2F ("hCaloCorrNCells","# Cells in EMCAL vs PHOS", nbins,nmin,nmax, nbins,nmin,nmax); fhCaloCorrNCells->SetXTitle("number of Cells in EMCAL"); fhCaloCorrNCells->SetYTitle("number of Cells in PHOS"); outputContainer->Add(fhCaloCorrNCells); fhCaloCorrECells = new TH2F ("hCaloCorrECells","summed energy of Cells in EMCAL vs PHOS", nptbins*2,ptmin,ptmax*2,nptbins*2,ptmin,ptmax*2); fhCaloCorrECells->SetXTitle("#Sigma E of Cells in EMCAL (GeV)"); fhCaloCorrECells->SetYTitle("#Sigma E of Cells in PHOS (GeV)"); outputContainer->Add(fhCaloCorrECells); //Calorimeter VS V0 signal fhCaloV0SCorrNClusters = new TH2F ("hCaloV0SNClusters",Form("# clusters in %s vs V0 signal",fCalorimeter.Data()), nv0sbins,nv0smin,nv0smax,nbins,nmin,nmax); fhCaloV0SCorrNClusters->SetXTitle("V0 signal"); fhCaloV0SCorrNClusters->SetYTitle(Form("number of clusters in %s",fCalorimeter.Data())); outputContainer->Add(fhCaloV0SCorrNClusters); fhCaloV0SCorrEClusters = new TH2F ("hCaloV0SEClusters",Form("summed energy of clusters in %s vs V0 signal",fCalorimeter.Data()), nv0sbins,nv0smin,nv0smax,nptbins,ptmin,ptmax); fhCaloV0SCorrEClusters->SetXTitle("V0 signal"); fhCaloV0SCorrEClusters->SetYTitle(Form("#Sigma E of clusters in %s (GeV)",fCalorimeter.Data())); outputContainer->Add(fhCaloV0SCorrEClusters); fhCaloV0SCorrNCells = new TH2F ("hCaloV0SNCells",Form("# Cells in %s vs V0 signal",fCalorimeter.Data()), nv0sbins,nv0smin,nv0smax, nbins,nmin,nmax); fhCaloV0SCorrNCells->SetXTitle("V0 signal"); fhCaloV0SCorrNCells->SetYTitle(Form("number of Cells in %s",fCalorimeter.Data())); outputContainer->Add(fhCaloV0SCorrNCells); fhCaloV0SCorrECells = new TH2F ("hCaloV0SECells",Form("summed energy of Cells in %s vs V0 signal",fCalorimeter.Data()), nv0sbins,nv0smin,nv0smax,nptbins,ptmin,ptmax); fhCaloV0SCorrECells->SetXTitle("V0 signal"); fhCaloV0SCorrECells->SetYTitle(Form("#Sigma E of Cells in %s (GeV)",fCalorimeter.Data())); outputContainer->Add(fhCaloV0SCorrECells); //Calorimeter VS V0 multiplicity fhCaloV0MCorrNClusters = new TH2F ("hCaloV0MNClusters",Form("# clusters in %s vs V0 signal",fCalorimeter.Data()), nv0mbins,nv0mmin,nv0mmax,nbins,nmin,nmax); fhCaloV0MCorrNClusters->SetXTitle("V0 signal"); fhCaloV0MCorrNClusters->SetYTitle(Form("number of clusters in %s",fCalorimeter.Data())); outputContainer->Add(fhCaloV0MCorrNClusters); fhCaloV0MCorrEClusters = new TH2F ("hCaloV0MEClusters",Form("summed energy of clusters in %s vs V0 signal",fCalorimeter.Data()), nv0mbins,nv0mmin,nv0mmax,nptbins,ptmin,ptmax); fhCaloV0MCorrEClusters->SetXTitle("V0 signal"); fhCaloV0MCorrEClusters->SetYTitle(Form("#Sigma E of clusters in %s (GeV)",fCalorimeter.Data())); outputContainer->Add(fhCaloV0MCorrEClusters); fhCaloV0MCorrNCells = new TH2F ("hCaloV0MNCells",Form("# Cells in %s vs V0 signal",fCalorimeter.Data()), nv0mbins,nv0mmin,nv0mmax, nbins,nmin,nmax); fhCaloV0MCorrNCells->SetXTitle("V0 signal"); fhCaloV0MCorrNCells->SetYTitle(Form("number of Cells in %s",fCalorimeter.Data())); outputContainer->Add(fhCaloV0MCorrNCells); fhCaloV0MCorrECells = new TH2F ("hCaloV0MECells",Form("summed energy of Cells in %s vs V0 signal",fCalorimeter.Data()), nv0mbins,nv0mmin,nv0mmax,nptbins,ptmin,ptmax); fhCaloV0MCorrECells->SetXTitle("V0 signal"); fhCaloV0MCorrECells->SetYTitle(Form("#Sigma E of Cells in %s (GeV)",fCalorimeter.Data())); outputContainer->Add(fhCaloV0MCorrECells); //Calorimeter VS Track multiplicity fhCaloTrackMCorrNClusters = new TH2F ("hCaloTrackMNClusters",Form("# clusters in %s vs V0 signal",fCalorimeter.Data()), ntrmbins,ntrmmin,ntrmmax,nbins,nmin,nmax); fhCaloTrackMCorrNClusters->SetXTitle("Track Multiplicity"); fhCaloTrackMCorrNClusters->SetYTitle(Form("number of clusters in %s",fCalorimeter.Data())); outputContainer->Add(fhCaloTrackMCorrNClusters); fhCaloTrackMCorrEClusters = new TH2F ("hCaloTrackMEClusters",Form("summed energy of clusters in %s vs V0 signal",fCalorimeter.Data()), ntrmbins,ntrmmin,ntrmmax,nptbins,ptmin,ptmax); fhCaloTrackMCorrEClusters->SetXTitle("Track Multiplicity"); fhCaloTrackMCorrEClusters->SetYTitle(Form("#Sigma E of clusters in %s (GeV)",fCalorimeter.Data())); outputContainer->Add(fhCaloTrackMCorrEClusters); fhCaloTrackMCorrNCells = new TH2F ("hCaloTrackMNCells",Form("# Cells in %s vs V0 signal",fCalorimeter.Data()), ntrmbins,ntrmmin,ntrmmax, nbins,nmin,nmax); fhCaloTrackMCorrNCells->SetXTitle("Track Multiplicity"); fhCaloTrackMCorrNCells->SetYTitle(Form("number of Cells in %s",fCalorimeter.Data())); outputContainer->Add(fhCaloTrackMCorrNCells); fhCaloTrackMCorrECells = new TH2F ("hCaloTrackMECells",Form("summed energy of Cells in %s vs V0 signal",fCalorimeter.Data()), ntrmbins,ntrmmin,ntrmmax,nptbins,ptmin,ptmax); fhCaloTrackMCorrECells->SetXTitle("Track Multiplicity"); fhCaloTrackMCorrECells->SetYTitle(Form("#Sigma E of Cells in %s (GeV)",fCalorimeter.Data())); outputContainer->Add(fhCaloTrackMCorrECells); }//correlate calorimeters //Module histograms fhEMod = new TH1F*[fNModules]; fhNClustersMod = new TH1F*[fNModules]; fhNCellsPerClusterMod = new TH2F*[fNModules]; fhNCellsMod = new TH1F*[fNModules]; fhGridCellsMod = new TH2F*[fNModules]; fhGridCellsEMod = new TH2F*[fNModules]; fhGridCellsTimeMod = new TH2F*[fNModules]; fhAmplitudeMod = new TH1F*[fNModules]; if(fCalorimeter=="EMCAL") fhAmplitudeModFraction = new TH1F*[fNModules*3]; fhTimeAmpPerRCU = new TH2F*[fNModules*fNRCU]; //fhT0TimeAmpPerRCU = new TH2F*[fNModules*fNRCU]; //fhTimeCorrRCU = new TH2F*[fNModules*fNRCU*fNModules*fNRCU]; fhIMMod = new TH2F*[fNModules]; fhIMCellCutMod = new TH2F*[fNModules]; for(Int_t imod = 0; imod < fNModules; imod++){ fhEMod[imod] = new TH1F (Form("hE_Mod%d",imod),Form("Cluster reconstructed Energy in Module %d ",imod), nptbins,ptmin,ptmax); fhEMod[imod]->SetXTitle("E (GeV)"); outputContainer->Add(fhEMod[imod]); fhNClustersMod[imod] = new TH1F (Form("hNClusters_Mod%d",imod),Form("# clusters in Module %d",imod), nbins,nmin,nmax); fhNClustersMod[imod]->SetXTitle("number of clusters"); outputContainer->Add(fhNClustersMod[imod]); fhNCellsPerClusterMod[imod] = new TH2F (Form("hNCellsPerCluster_Mod%d",imod), Form("# cells per cluster vs cluster energy in Module %d",imod), nptbins,ptmin,ptmax, nbins,nmin,nmax); fhNCellsPerClusterMod[imod]->SetXTitle("E (GeV)"); fhNCellsPerClusterMod[imod]->SetYTitle("n cells"); outputContainer->Add(fhNCellsPerClusterMod[imod]); fhNCellsMod[imod] = new TH1F (Form("hNCells_Mod%d",imod),Form("# cells in Module %d",imod), colmax*rowmax,0,colmax*rowmax); fhNCellsMod[imod]->SetXTitle("n cells"); outputContainer->Add(fhNCellsMod[imod]); fhGridCellsMod[imod] = new TH2F (Form("hGridCells_Mod%d",imod),Form("Entries in grid of cells in Module %d",imod), colmax+2,-1.5,colmax+0.5, rowmax+2,-1.5,rowmax+0.5); fhGridCellsMod[imod]->SetYTitle("row (phi direction)"); fhGridCellsMod[imod]->SetXTitle("column (eta direction)"); outputContainer->Add(fhGridCellsMod[imod]); fhGridCellsEMod[imod] = new TH2F (Form("hGridCellsE_Mod%d",imod),Form("Accumulated energy in grid of cells in Module %d",imod), colmax+2,-1.5,colmax+0.5, rowmax+2,-1.5,rowmax+0.5); fhGridCellsEMod[imod]->SetYTitle("row (phi direction)"); fhGridCellsEMod[imod]->SetXTitle("column (eta direction)"); outputContainer->Add(fhGridCellsEMod[imod]); fhGridCellsTimeMod[imod] = new TH2F (Form("hGridCellsTime_Mod%d",imod),Form("Accumulated time in grid of cells in Module %d, with E > 0.5 GeV",imod), colmax+2,-1.5,colmax+0.5, rowmax+2,-1.5,rowmax+0.5); fhGridCellsTimeMod[imod]->SetYTitle("row (phi direction)"); fhGridCellsTimeMod[imod]->SetXTitle("column (eta direction)"); outputContainer->Add(fhGridCellsTimeMod[imod]); fhAmplitudeMod[imod] = new TH1F (Form("hAmplitude_Mod%d",imod),Form("Cell Energy in Module %d",imod), nptbins*2,ptmin,ptmax); fhAmplitudeMod[imod]->SetXTitle("Cell Energy (GeV)"); outputContainer->Add(fhAmplitudeMod[imod]); if(fCalorimeter == "EMCAL"){ for(Int_t ifrac = 0; ifrac < 3; ifrac++){ fhAmplitudeModFraction[imod*3+ifrac] = new TH1F (Form("hAmplitude_Mod%d_Frac%d",imod,ifrac),Form("Cell reconstructed Energy in Module %d, Fraction %d ",imod,ifrac), nptbins,ptmin,ptmax); fhAmplitudeModFraction[imod*3+ifrac]->SetXTitle("E (GeV)"); outputContainer->Add(fhAmplitudeModFraction[imod*3+ifrac]); } } for(Int_t ircu = 0; ircu < fNRCU; ircu++){ fhTimeAmpPerRCU[imod*fNRCU+ircu] = new TH2F (Form("hTimeAmp_Mod%d_RCU%d",imod,ircu), Form("Cell Energy vs Cell Time in Module %d, RCU %d ",imod,ircu), nptbins,ptmin,ptmax,ntimebins,timemin,timemax); fhTimeAmpPerRCU[imod*fNRCU+ircu]->SetXTitle("E (GeV)"); fhTimeAmpPerRCU[imod*fNRCU+ircu]->SetYTitle("time (ns)"); outputContainer->Add(fhTimeAmpPerRCU[imod*fNRCU+ircu]); // fhT0TimeAmpPerRCU[imod*fNRCU+ircu] = new TH2F (Form("hT0TimeAmp_Mod%d_RCU%d",imod,ircu), // Form("Cell Energy vs T0-Cell Time in Module %d, RCU %d ",imod,ircu), // nptbins,ptmin,ptmax,ntimebins,timemin,timemax); // fhT0TimeAmpPerRCU[imod*fNRCU+ircu]->SetXTitle("E (GeV)"); // fhT0TimeAmpPerRCU[imod*fNRCU+ircu]->SetYTitle("T_{0} - T_{EMCal} (ns)"); // outputContainer->Add(fhT0TimeAmpPerRCU[imod*fNRCU+ircu]); // // for(Int_t imod2 = 0; imod2 < fNModules; imod2++){ // for(Int_t ircu2 = 0; ircu2 < fNModules; ircu2++){ // Int_t index = (imod2*fNRCU+ircu2)+(fNModules*fNRCU)*(ircu+imod)+fNRCU*fNModules*imod; // fhTimeCorrRCU[index] = new TH2F (Form("hTimeCorrRCU_Mod%d_RCU%d_CompareTo_Mod%d_RCU%d",imod, ircu,imod2, ircu2), // Form("Cell Energy > 0.3, Correlate cell Time in Module %d, RCU %d to Module %d, RCU %d",imod,ircu,imod2, ircu2), // ntimebins,timemin,timemax,ntimebins,timemin,timemax); // fhTimeCorrRCU[index]->SetXTitle("Trigger Cell Time (ns)"); // fhTimeCorrRCU[index]->SetYTitle("Cell Time (ns)"); // outputContainer->Add(fhTimeCorrRCU[index]); // } // } } fhIMMod[imod] = new TH2F (Form("hIM_Mod%d",imod), Form("Cluster pairs Invariant mass vs reconstructed pair energy in Module %d",imod), nptbins,ptmin,ptmax,nmassbins,massmin,massmax); fhIMMod[imod]->SetXTitle("p_{T, cluster pairs} (GeV) "); fhIMMod[imod]->SetYTitle("M_{cluster pairs} (GeV/c^{2})"); outputContainer->Add(fhIMMod[imod]); fhIMCellCutMod[imod] = new TH2F (Form("hIMCellCut_Mod%d",imod), Form("Cluster (n cells > 1) pairs Invariant mass vs reconstructed pair energy in Module %d",imod), nptbins,ptmin,ptmax,nmassbins,massmin,massmax); fhIMCellCutMod[imod]->SetXTitle("p_{T, cluster pairs} (GeV) "); fhIMCellCutMod[imod]->SetYTitle("M_{cluster pairs} (GeV/c^{2})"); outputContainer->Add(fhIMCellCutMod[imod]); } //Monte Carlo Histograms if(IsDataMC()){ fhDeltaE = new TH1F ("hDeltaE","MC - Reco E ", nptbins*2,-ptmax,ptmax); fhDeltaE->SetXTitle("#Delta E (GeV)"); outputContainer->Add(fhDeltaE); fhDeltaPt = new TH1F ("hDeltaPt","MC - Reco p_{T} ", nptbins*2,-ptmax,ptmax); fhDeltaPt->SetXTitle("#Delta p_{T} (GeV/c)"); outputContainer->Add(fhDeltaPt); fhDeltaPhi = new TH1F ("hDeltaPhi","MC - Reco #phi ",nphibins*2,-phimax,phimax); fhDeltaPhi->SetXTitle("#Delta #phi (rad)"); outputContainer->Add(fhDeltaPhi); fhDeltaEta = new TH1F ("hDeltaEta","MC- Reco #eta",netabins*2,-etamax,etamax); fhDeltaEta->SetXTitle("#Delta #eta "); outputContainer->Add(fhDeltaEta); fhRatioE = new TH1F ("hRatioE","Reco/MC E ", nratiobins,ratiomin,ratiomax); fhRatioE->SetXTitle("E_{reco}/E_{gen}"); outputContainer->Add(fhRatioE); fhRatioPt = new TH1F ("hRatioPt","Reco/MC p_{T} ", nratiobins,ratiomin,ratiomax); fhRatioPt->SetXTitle("p_{T, reco}/p_{T, gen}"); outputContainer->Add(fhRatioPt); fhRatioPhi = new TH1F ("hRatioPhi","Reco/MC #phi ",nratiobins,ratiomin,ratiomax); fhRatioPhi->SetXTitle("#phi_{reco}/#phi_{gen}"); outputContainer->Add(fhRatioPhi); fhRatioEta = new TH1F ("hRatioEta","Reco/MC #eta",nratiobins,ratiomin,ratiomax); fhRatioEta->SetXTitle("#eta_{reco}/#eta_{gen} "); outputContainer->Add(fhRatioEta); fh2E = new TH2F ("h2E","E distribution, reconstructed vs generated", nptbins,ptmin,ptmax,nptbins,ptmin,ptmax); fh2E->SetXTitle("E_{rec} (GeV)"); fh2E->SetYTitle("E_{gen} (GeV)"); outputContainer->Add(fh2E); fh2Pt = new TH2F ("h2Pt","p_T distribution, reconstructed vs generated", nptbins,ptmin,ptmax,nptbins,ptmin,ptmax); fh2Pt->SetXTitle("p_{T,rec} (GeV/c)"); fh2Pt->SetYTitle("p_{T,gen} (GeV/c)"); outputContainer->Add(fh2Pt); fh2Phi = new TH2F ("h2Phi","#phi distribution, reconstructed vs generated", nphibins,phimin,phimax, nphibins,phimin,phimax); fh2Phi->SetXTitle("#phi_{rec} (rad)"); fh2Phi->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fh2Phi); fh2Eta = new TH2F ("h2Eta","#eta distribution, reconstructed vs generated", netabins,etamin,etamax,netabins,etamin,etamax); fh2Eta->SetXTitle("#eta_{rec} "); fh2Eta->SetYTitle("#eta_{gen} "); outputContainer->Add(fh2Eta); //Fill histos depending on origin of cluster fhGamE = new TH2F ("hGamE","E reconstructed vs E generated from #gamma", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhGamE->SetXTitle("E_{rec} (GeV)"); fhGamE->SetXTitle("E_{gen} (GeV)"); outputContainer->Add(fhGamE); fhGamPt = new TH2F ("hGamPt","p_{T} reconstructed vs E generated from #gamma", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhGamPt->SetXTitle("p_{T rec} (GeV/c)"); fhGamPt->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhGamPt); fhGamPhi = new TH2F ("hGamPhi","#phi reconstructed vs E generated from #gamma",nphibins,phimin,phimax,nphibins,phimin,phimax); fhGamPhi->SetXTitle("#phi_{rec} (rad)"); fhGamPhi->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhGamPhi); fhGamEta = new TH2F ("hGamEta","#eta reconstructed vs E generated from #gamma",netabins,etamin,etamax,netabins,etamin,etamax); fhGamEta->SetXTitle("#eta_{rec} "); fhGamEta->SetYTitle("#eta_{gen} "); outputContainer->Add(fhGamEta); fhGamDeltaE = new TH1F ("hGamDeltaE","#gamma MC - Reco E ", nptbins*2,-ptmax,ptmax); fhGamDeltaE->SetXTitle("#Delta E (GeV)"); outputContainer->Add(fhGamDeltaE); fhGamDeltaPt = new TH1F ("hGamDeltaPt","#gamma MC - Reco p_{T} ", nptbins*2,-ptmax,ptmax); fhGamDeltaPt->SetXTitle("#Delta p_{T} (GeV/c)"); outputContainer->Add(fhGamDeltaPt); fhGamDeltaPhi = new TH1F ("hGamDeltaPhi","#gamma MC - Reco #phi ",nphibins*2,-phimax,phimax); fhGamDeltaPhi->SetXTitle("#Delta #phi (rad)"); outputContainer->Add(fhGamDeltaPhi); fhGamDeltaEta = new TH1F ("hGamDeltaEta","#gamma MC- Reco #eta",netabins*2,-etamax,etamax); fhGamDeltaEta->SetXTitle("#Delta #eta "); outputContainer->Add(fhGamDeltaEta); fhGamRatioE = new TH1F ("hGamRatioE","#gamma Reco/MC E ", nratiobins,ratiomin,ratiomax); fhGamRatioE->SetXTitle("E_{reco}/E_{gen}"); outputContainer->Add(fhGamRatioE); fhGamRatioPt = new TH1F ("hGamRatioPt","#gamma Reco/MC p_{T} ", nratiobins,ratiomin,ratiomax); fhGamRatioPt->SetXTitle("p_{T, reco}/p_{T, gen}"); outputContainer->Add(fhGamRatioPt); fhGamRatioPhi = new TH1F ("hGamRatioPhi","#gamma Reco/MC #phi ",nratiobins,ratiomin,ratiomax); fhGamRatioPhi->SetXTitle("#phi_{reco}/#phi_{gen}"); outputContainer->Add(fhGamRatioPhi); fhGamRatioEta = new TH1F ("hGamRatioEta","#gamma Reco/MC #eta",nratiobins,ratiomin,ratiomax); fhGamRatioEta->SetXTitle("#eta_{reco}/#eta_{gen} "); outputContainer->Add(fhGamRatioEta); fhPi0E = new TH2F ("hPi0E","E reconstructed vs E generated from #pi^{0}", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhPi0E->SetXTitle("E_{rec} (GeV)"); fhPi0E->SetYTitle("E_{gen} (GeV)"); outputContainer->Add(fhPi0E); fhPi0Pt = new TH2F ("hPi0Pt","p_{T} reconstructed vs E generated from #pi^{0}", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhPi0Pt->SetXTitle("p_{T rec} (GeV/c)"); fhPi0Pt->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhPi0Pt); fhPi0Phi = new TH2F ("hPi0Phi","#phi reconstructed vs E generated from #pi^{0}",nphibins,phimin,phimax,nphibins,phimin,phimax); fhPi0Phi->SetXTitle("#phi_{rec} (rad)"); fhPi0Phi->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhPi0Phi); fhPi0Eta = new TH2F ("hPi0Eta","#eta reconstructed vs E generated from #pi^{0}",netabins,etamin,etamax,netabins,etamin,etamax); fhPi0Eta->SetXTitle("#eta_{rec} "); fhPi0Eta->SetYTitle("#eta_{gen} "); outputContainer->Add(fhPi0Eta); fhEleE = new TH2F ("hEleE","E reconstructed vs E generated from e^{#pm}", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhEleE->SetXTitle("E_{rec} (GeV)"); fhEleE->SetXTitle("E_{gen} (GeV)"); outputContainer->Add(fhEleE); fhElePt = new TH2F ("hElePt","p_{T} reconstructed vs E generated from e^{#pm}", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhElePt->SetXTitle("p_{T rec} (GeV/c)"); fhElePt->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhElePt); fhElePhi = new TH2F ("hElePhi","#phi reconstructed vs E generated from e^{#pm}",nphibins,phimin,phimax,nphibins,phimin,phimax); fhElePhi->SetXTitle("#phi_{rec} (rad)"); fhElePhi->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhElePhi); fhEleEta = new TH2F ("hEleEta","#eta reconstructed vs E generated from e^{#pm}",netabins,etamin,etamax,netabins,etamin,etamax); fhEleEta->SetXTitle("#eta_{rec} "); fhEleEta->SetYTitle("#eta_{gen} "); outputContainer->Add(fhEleEta); fhNeHadE = new TH2F ("hNeHadE","E reconstructed vs E generated from neutral hadron", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhNeHadE->SetXTitle("E_{rec} (GeV)"); fhNeHadE->SetYTitle("E_{gen} (GeV)"); outputContainer->Add(fhNeHadE); fhNeHadPt = new TH2F ("hNeHadPt","p_{T} reconstructed vs E generated from neutral hadron", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhNeHadPt->SetXTitle("p_{T rec} (GeV/c)"); fhNeHadPt->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhNeHadPt); fhNeHadPhi = new TH2F ("hNeHadPhi","#phi reconstructed vs E generated from neutral hadron",nphibins,phimin,phimax,nphibins,phimin,phimax); fhNeHadPhi->SetXTitle("#phi_{rec} (rad)"); fhNeHadPhi->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhNeHadPhi); fhNeHadEta = new TH2F ("hNeHadEta","#eta reconstructed vs E generated from neutral hadron",netabins,etamin,etamax,netabins,etamin,etamax); fhNeHadEta->SetXTitle("#eta_{rec} "); fhNeHadEta->SetYTitle("#eta_{gen} "); outputContainer->Add(fhNeHadEta); fhChHadE = new TH2F ("hChHadE","E reconstructed vs E generated from charged hadron", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhChHadE->SetXTitle("E_{rec} (GeV)"); fhChHadE->SetYTitle("E_{gen} (GeV)"); outputContainer->Add(fhChHadE); fhChHadPt = new TH2F ("hChHadPt","p_{T} reconstructed vs E generated from charged hadron", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhChHadPt->SetXTitle("p_{T rec} (GeV/c)"); fhChHadPt->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhChHadPt); fhChHadPhi = new TH2F ("hChHadPhi","#phi reconstructed vs E generated from charged hadron",nphibins,phimin,phimax,nphibins,phimin,phimax); fhChHadPhi->SetXTitle("#phi_{rec} (rad)"); fhChHadPhi->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhChHadPhi); fhChHadEta = new TH2F ("hChHadEta","#eta reconstructed vs E generated from charged hadron",netabins,etamin,etamax,netabins,etamin,etamax); fhChHadEta->SetXTitle("#eta_{rec} "); fhChHadEta->SetYTitle("#eta_{gen} "); outputContainer->Add(fhChHadEta); //Charged clusters fhGamECharged = new TH2F ("hGamECharged","E reconstructed vs E generated from #gamma, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhGamECharged->SetXTitle("E_{rec} (GeV)"); fhGamECharged->SetXTitle("E_{gen} (GeV)"); outputContainer->Add(fhGamECharged); fhGamPtCharged = new TH2F ("hGamPtCharged","p_{T} reconstructed vs E generated from #gamma, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhGamPtCharged->SetXTitle("p_{T rec} (GeV/c)"); fhGamPtCharged->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhGamPtCharged); fhGamPhiCharged = new TH2F ("hGamPhiCharged","#phi reconstructed vs E generated from #gamma, track matched cluster",nphibins,phimin,phimax,nphibins,phimin,phimax); fhGamPhiCharged->SetXTitle("#phi_{rec} (rad)"); fhGamPhiCharged->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhGamPhiCharged); fhGamEtaCharged = new TH2F ("hGamEtaCharged","#eta reconstructed vs E generated from #gamma, track matched cluster",netabins,etamin,etamax,netabins,etamin,etamax); fhGamEtaCharged->SetXTitle("#eta_{rec} "); fhGamEtaCharged->SetYTitle("#eta_{gen} "); outputContainer->Add(fhGamEtaCharged); fhPi0ECharged = new TH2F ("hPi0ECharged","E reconstructed vs E generated from #pi^{0}, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhPi0ECharged->SetXTitle("E_{rec} (GeV)"); fhPi0ECharged->SetYTitle("E_{gen} (GeV)"); outputContainer->Add(fhPi0ECharged); fhPi0PtCharged = new TH2F ("hPi0PtCharged","p_{T} reconstructed vs E generated from #pi^{0}, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhPi0PtCharged->SetXTitle("p_{T rec} (GeV/c)"); fhPi0PtCharged->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhPi0PtCharged); fhPi0PhiCharged = new TH2F ("hPi0PhiCharged","#phi reconstructed vs E generated from #pi^{0}, track matched cluster",nphibins,phimin,phimax,nphibins,phimin,phimax); fhPi0PhiCharged->SetXTitle("#phi_{rec} (rad)"); fhPi0PhiCharged->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhPi0PhiCharged); fhPi0EtaCharged = new TH2F ("hPi0EtaCharged","#eta reconstructed vs E generated from #pi^{0}, track matched cluster",netabins,etamin,etamax,netabins,etamin,etamax); fhPi0EtaCharged->SetXTitle("#eta_{rec} "); fhPi0EtaCharged->SetYTitle("#eta_{gen} "); outputContainer->Add(fhPi0EtaCharged); fhEleECharged = new TH2F ("hEleECharged","E reconstructed vs E generated from e^{#pm}, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhEleECharged->SetXTitle("E_{rec} (GeV)"); fhEleECharged->SetXTitle("E_{gen} (GeV)"); outputContainer->Add(fhEleECharged); fhElePtCharged = new TH2F ("hElePtCharged","p_{T} reconstructed vs E generated from e^{#pm}, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhElePtCharged->SetXTitle("p_{T rec} (GeV/c)"); fhElePtCharged->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhElePtCharged); fhElePhiCharged = new TH2F ("hElePhiCharged","#phi reconstructed vs E generated from e^{#pm}, track matched cluster",nphibins,phimin,phimax,nphibins,phimin,phimax); fhElePhiCharged->SetXTitle("#phi_{rec} (rad)"); fhElePhiCharged->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhElePhiCharged); fhEleEtaCharged = new TH2F ("hEleEtaCharged","#eta reconstructed vs E generated from e^{#pm}, track matched cluster",netabins,etamin,etamax,netabins,etamin,etamax); fhEleEtaCharged->SetXTitle("#eta_{rec} "); fhEleEtaCharged->SetYTitle("#eta_{gen} "); outputContainer->Add(fhEleEtaCharged); fhNeHadECharged = new TH2F ("hNeHadECharged","E reconstructed vs E generated from neutral hadron, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhNeHadECharged->SetXTitle("E_{rec} (GeV)"); fhNeHadECharged->SetYTitle("E_{gen} (GeV)"); outputContainer->Add(fhNeHadECharged); fhNeHadPtCharged = new TH2F ("hNeHadPtCharged","p_{T} reconstructed vs E generated from neutral hadron, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhNeHadPtCharged->SetXTitle("p_{T rec} (GeV/c)"); fhNeHadPtCharged->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhNeHadPtCharged); fhNeHadPhiCharged = new TH2F ("hNeHadPhiCharged","#phi reconstructed vs E generated from neutral hadron, track matched cluster",nphibins,phimin,phimax,nphibins,phimin,phimax); fhNeHadPhiCharged->SetXTitle("#phi_{rec} (rad)"); fhNeHadPhiCharged->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhNeHadPhiCharged); fhNeHadEtaCharged = new TH2F ("hNeHadEtaCharged","#eta reconstructed vs E generated from neutral hadron, track matched cluster",netabins,etamin,etamax,netabins,etamin,etamax); fhNeHadEtaCharged->SetXTitle("#eta_{rec} "); fhNeHadEtaCharged->SetYTitle("#eta_{gen} "); outputContainer->Add(fhNeHadEtaCharged); fhChHadECharged = new TH2F ("hChHadECharged","E reconstructed vs E generated from charged hadron, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhChHadECharged->SetXTitle("E_{rec} (GeV)"); fhChHadECharged->SetYTitle("E_{gen} (GeV)"); outputContainer->Add(fhChHadECharged); fhChHadPtCharged = new TH2F ("hChHadPtCharged","p_{T} reconstructed vs E generated from charged hadron, track matched cluster", nptbins,ptmin,ptmax, nptbins,ptmin,ptmax); fhChHadPtCharged->SetXTitle("p_{T rec} (GeV/c)"); fhChHadPtCharged->SetYTitle("p_{T gen} (GeV/c)"); outputContainer->Add(fhChHadPtCharged); fhChHadPhiCharged = new TH2F ("hChHadPhiCharged","#phi reconstructed vs E generated from charged hadron, track matched cluster",nphibins,phimin,phimax,nphibins,phimin,phimax); fhChHadPhiCharged->SetXTitle("#phi (rad)"); fhChHadPhiCharged->SetXTitle("#phi_{rec} (rad)"); fhChHadPhiCharged->SetYTitle("#phi_{gen} (rad)"); outputContainer->Add(fhChHadPhiCharged); fhChHadEtaCharged = new TH2F ("hChHadEtaCharged","#eta reconstructed vs E generated from charged hadron, track matched cluster",netabins,etamin,etamax,netabins,etamin,etamax); fhChHadEtaCharged->SetXTitle("#eta_{rec} "); fhChHadEtaCharged->SetYTitle("#eta_{gen} "); outputContainer->Add(fhChHadEtaCharged); //Vertex of generated particles fhEMVxyz = new TH2F ("hEMVxyz","Production vertex of reconstructed ElectroMagnetic particles",nvdistbins,vdistmin,vdistmax,nvdistbins,vdistmin,vdistmax);//,100,0,500); fhEMVxyz->SetXTitle("v_{x}"); fhEMVxyz->SetYTitle("v_{y}"); //fhEMVxyz->SetZTitle("v_{z}"); outputContainer->Add(fhEMVxyz); fhHaVxyz = new TH2F ("hHaVxyz","Production vertex of reconstructed hadrons",nvdistbins,vdistmin,vdistmax,nvdistbins,vdistmin,vdistmax);//,100,0,500); fhHaVxyz->SetXTitle("v_{x}"); fhHaVxyz->SetYTitle("v_{y}"); //fhHaVxyz->SetZTitle("v_{z}"); outputContainer->Add(fhHaVxyz); fhEMR = new TH2F ("hEMR","Distance to production vertex of reconstructed ElectroMagnetic particles vs E rec",nptbins,ptmin,ptmax,nvdistbins,vdistmin,vdistmax); fhEMR->SetXTitle("E (GeV)"); fhEMR->SetYTitle("TMath::Sqrt(v_{x}^{2}+v_{y}^{2})"); outputContainer->Add(fhEMR); fhHaR = new TH2F ("hHaR","Distance to production vertex of reconstructed Hadrons vs E rec",nptbins,ptmin,ptmax,nvdistbins,vdistmin,vdistmax); fhHaR->SetXTitle("E (GeV)"); fhHaR->SetYTitle("TMath::Sqrt(v_{x}^{2}+v_{y}^{2})"); outputContainer->Add(fhHaR); //Pure MC fhGenGamPt = new TH1F("hGenGamPt" ,"p_{T} of generated #gamma",nptbins,ptmin,ptmax); fhGenGamEta = new TH1F("hGenGamEta","Y of generated #gamma",netabins,etamin,etamax); fhGenGamPhi = new TH1F("hGenGamPhi","#phi of generated #gamma",nphibins,phimin,phimax); fhGenPi0Pt = new TH1F("hGenPi0Pt" ,"p_{T} of generated #pi^{0}",nptbins,ptmin,ptmax); fhGenPi0Eta = new TH1F("hGenPi0Eta","Y of generated #pi^{0}",netabins,etamin,etamax); fhGenPi0Phi = new TH1F("hGenPi0Phi","#phi of generated #pi^{0}",nphibins,phimin,phimax); fhGenEtaPt = new TH1F("hGenEtaPt" ,"p_{T} of generated #eta",nptbins,ptmin,ptmax); fhGenEtaEta = new TH1F("hGenEtaEta","Y of generated #eta",netabins,etamin,etamax); fhGenEtaPhi = new TH1F("hGenEtaPhi","#phi of generated #eta",nphibins,phimin,phimax); fhGenOmegaPt = new TH1F("hGenOmegaPt" ,"p_{T} of generated #omega",nptbins,ptmin,ptmax); fhGenOmegaEta = new TH1F("hGenOmegaEta","Y of generated #omega",netabins,etamin,etamax); fhGenOmegaPhi = new TH1F("hGenOmegaPhi","#phi of generated #omega",nphibins,phimin,phimax); fhGenElePt = new TH1F("hGenElePt" ,"p_{T} of generated e^{#pm}",nptbins,ptmin,ptmax); fhGenEleEta = new TH1F("hGenEleEta","Y of generated e^{#pm}",netabins,etamin,etamax); fhGenElePhi = new TH1F("hGenElePhi","#phi of generated e^{#pm}",nphibins,phimin,phimax); fhGenGamPt->SetXTitle("p_{T} (GeV/c)"); fhGenGamEta->SetXTitle("#eta"); fhGenGamPhi->SetXTitle("#phi (rad)"); outputContainer->Add(fhGenGamPt); outputContainer->Add(fhGenGamEta); outputContainer->Add(fhGenGamPhi); fhGenPi0Pt->SetXTitle("p_{T} (GeV/c)"); fhGenPi0Eta->SetXTitle("#eta"); fhGenPi0Phi->SetXTitle("#phi (rad)"); outputContainer->Add(fhGenPi0Pt); outputContainer->Add(fhGenPi0Eta); outputContainer->Add(fhGenPi0Phi); fhGenEtaPt->SetXTitle("p_{T} (GeV/c)"); fhGenEtaEta->SetXTitle("#eta"); fhGenEtaPhi->SetXTitle("#phi (rad)"); outputContainer->Add(fhGenEtaPt); outputContainer->Add(fhGenEtaEta); outputContainer->Add(fhGenEtaPhi); fhGenOmegaPt->SetXTitle("p_{T} (GeV/c)"); fhGenOmegaEta->SetXTitle("#eta"); fhGenOmegaPhi->SetXTitle("#phi (rad)"); outputContainer->Add(fhGenOmegaPt); outputContainer->Add(fhGenOmegaEta); outputContainer->Add(fhGenOmegaPhi); fhGenElePt->SetXTitle("p_{T} (GeV/c)"); fhGenEleEta->SetXTitle("#eta"); fhGenElePhi->SetXTitle("#phi (rad)"); outputContainer->Add(fhGenElePt); outputContainer->Add(fhGenEleEta); outputContainer->Add(fhGenElePhi); fhGenGamAccE = new TH1F("hGenGamAccE" ,"E of generated #gamma in calorimeter acceptance",nptbins,ptmin,ptmax); fhGenGamAccPt = new TH1F("hGenGamAccPt" ,"p_{T} of generated #gamma in calorimeter acceptance",nptbins,ptmin,ptmax); fhGenGamAccEta = new TH1F("hGenGamAccEta","Y of generated #gamma in calorimeter acceptance",netabins,etamin,etamax); fhGenGamAccPhi = new TH1F("hGenGamAccPhi","#phi of generated #gamma in calorimeter acceptance",nphibins,phimin,phimax); fhGenPi0AccE = new TH1F("hGenPi0AccE" ,"E of generated #pi^{0} in calorimeter acceptance",nptbins,ptmin,ptmax); fhGenPi0AccPt = new TH1F("hGenPi0AccPt" ,"p_{T} of generated #pi^{0} in calorimeter acceptance",nptbins,ptmin,ptmax); fhGenPi0AccEta = new TH1F("hGenPi0AccEta","Y of generated #pi^{0} in calorimeter acceptance",netabins,etamin,etamax); fhGenPi0AccPhi = new TH1F("hGenPi0AccPhi","#phi of generated #pi^{0} in calorimeter acceptance",nphibins,phimin,phimax); fhGenGamAccE ->SetXTitle("E (GeV)"); fhGenGamAccPt ->SetXTitle("p_{T} (GeV/c)"); fhGenGamAccEta->SetXTitle("#eta"); fhGenGamAccPhi->SetXTitle("#phi (rad)"); outputContainer->Add(fhGenGamAccE); outputContainer->Add(fhGenGamAccPt); outputContainer->Add(fhGenGamAccEta); outputContainer->Add(fhGenGamAccPhi); fhGenPi0AccE ->SetXTitle("E (GeV)"); fhGenPi0AccPt ->SetXTitle("p_{T} (GeV/c)"); fhGenPi0AccEta->SetXTitle("#eta"); fhGenPi0AccPhi->SetXTitle("#phi (rad)"); outputContainer->Add(fhGenPi0AccE); outputContainer->Add(fhGenPi0AccPt); outputContainer->Add(fhGenPi0AccEta); outputContainer->Add(fhGenPi0AccPhi); //Track Matching fhMCEle1pOverE = new TH2F("hMCEle1pOverE","TRACK matches p/E, MC electrons",nptbins,ptmin,ptmax, nPoverEbins,pOverEmin,pOverEmax); fhMCEle1pOverE->SetYTitle("p/E"); fhMCEle1pOverE->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhMCEle1pOverE); fhMCEle1dR = new TH1F("hMCEle1dR","TRACK matches dR, MC electrons",ndRbins,dRmin,dRmax); fhMCEle1dR->SetXTitle("#Delta R (rad)"); outputContainer->Add(fhMCEle1dR) ; fhMCEle2MatchdEdx = new TH2F("hMCEle2MatchdEdx","dE/dx vs. p for all matches, MC electrons",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); fhMCEle2MatchdEdx->SetXTitle("p (GeV/c)"); fhMCEle2MatchdEdx->SetYTitle(""); outputContainer->Add(fhMCEle2MatchdEdx); fhMCChHad1pOverE = new TH2F("hMCChHad1pOverE","TRACK matches p/E, MC charged hadrons",nptbins,ptmin,ptmax, nPoverEbins,pOverEmin,pOverEmax); fhMCChHad1pOverE->SetYTitle("p/E"); fhMCChHad1pOverE->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhMCChHad1pOverE); fhMCChHad1dR = new TH1F("hMCChHad1dR","TRACK matches dR, MC charged hadrons",ndRbins,dRmin,dRmax); fhMCChHad1dR->SetXTitle("#Delta R (rad)"); outputContainer->Add(fhMCChHad1dR) ; fhMCChHad2MatchdEdx = new TH2F("hMCChHad2MatchdEdx","dE/dx vs. p for all matches, MC charged hadrons",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); fhMCChHad2MatchdEdx->SetXTitle("p (GeV/c)"); fhMCChHad2MatchdEdx->SetYTitle(""); outputContainer->Add(fhMCChHad2MatchdEdx); fhMCNeutral1pOverE = new TH2F("hMCNeutral1pOverE","TRACK matches p/E, MC neutrals",nptbins,ptmin,ptmax, nPoverEbins,pOverEmin,pOverEmax); fhMCNeutral1pOverE->SetYTitle("p/E"); fhMCNeutral1pOverE->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhMCNeutral1pOverE); fhMCNeutral1dR = new TH1F("hMCNeutral1dR","TRACK matches dR, MC neutrals",ndRbins,dRmin,dRmax); fhMCNeutral1dR->SetXTitle("#Delta R (rad)"); outputContainer->Add(fhMCNeutral1dR) ; fhMCNeutral2MatchdEdx = new TH2F("hMCNeutral2MatchdEdx","dE/dx vs. p for all matches, MC neutrals",nptbins,ptmin,ptmax,ndedxbins,dedxmin,dedxmax); fhMCNeutral2MatchdEdx->SetXTitle("p (GeV/c)"); fhMCNeutral2MatchdEdx->SetYTitle(""); outputContainer->Add(fhMCNeutral2MatchdEdx); fhMCEle1pOverER02 = new TH2F("hMCEle1pOverER02","TRACK matches p/E, MC electrons",nptbins,ptmin,ptmax, nPoverEbins,pOverEmin,pOverEmax); fhMCEle1pOverER02->SetYTitle("p/E"); fhMCEle1pOverER02->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhMCEle1pOverER02); fhMCChHad1pOverER02 = new TH2F("hMCChHad1pOverER02","TRACK matches p/E, MC charged hadrons",nptbins,ptmin,ptmax, nPoverEbins,pOverEmin,pOverEmax); fhMCChHad1pOverER02->SetYTitle("p/E"); fhMCChHad1pOverER02->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhMCChHad1pOverER02); fhMCNeutral1pOverER02 = new TH2F("hMCNeutral1pOverER02","TRACK matches p/E, MC neutrals",nptbins,ptmin,ptmax, nPoverEbins,pOverEmin,pOverEmax); fhMCNeutral1pOverER02->SetYTitle("p/E"); fhMCNeutral1pOverER02->SetXTitle("p_{T} (GeV/c)"); outputContainer->Add(fhMCNeutral1pOverER02); } // for(Int_t i = 0; i < outputContainer->GetEntries() ; i++) // printf("i=%d, name= %s\n",i,outputContainer->At(i)->GetName()); return outputContainer; } //_______________________________________________________________________________________________________________________________________ Int_t AliAnaCalorimeterQA::GetNewRebinForRePlotting(TH1D* histo, const Float_t newXmin, const Float_t newXmax,const Int_t newXnbins) const { //Calculate the rebinning for the new requested bin size, only used when replotting executing the Terminte Float_t oldbinsize = histo->GetBinWidth(0); Float_t newbinsize = TMath::Abs(newXmax-newXmin) / newXnbins; //printf("bin size, old %f, new %f\n",oldbinsize,newbinsize); if(newbinsize > oldbinsize) return (Int_t) (newbinsize/oldbinsize); else return 1; } //__________________________________________________ void AliAnaCalorimeterQA::Init() { //Check if the data or settings are ok if(fCalorimeter != "PHOS" && fCalorimeter !="EMCAL"){ printf("AliAnaCalorimeterQA::Init() - Wrong calorimeter name <%s>, END\n", fCalorimeter.Data()); abort(); } if(GetReader()->GetDataType()== AliCaloTrackReader::kMC){ printf("AliAnaCalorimeterQA::Init() - Analysis of reconstructed data, MC reader not aplicable\n"); abort(); } } //__________________________________________________ void AliAnaCalorimeterQA::InitParameters() { //Initialize the parameters of the analysis. AddToHistogramsName("AnaCaloQA_"); fCalorimeter = "EMCAL"; //or PHOS fStyleMacro = "" ; fNModules = 12; // set maximum to maximum number of EMCAL modules fNRCU = 2; // set maximum number of RCU in EMCAL per SM fTimeCutMin = -1; fTimeCutMax = 9999999; fEMCALCellAmpMin = 0.0; fPHOSCellAmpMin = 0.0; fHistoPOverEBins = 100 ; fHistoPOverEMax = 10. ; fHistoPOverEMin = 0. ; fHistodEdxBins = 200 ; fHistodEdxMax = 400. ; fHistodEdxMin = 0. ; fHistodRBins = 300 ; fHistodRMax = 3.15 ; fHistodRMin = 0. ; fHistoTimeBins = 1000; fHistoTimeMax = 1.e3 ; fHistoTimeMin = 0. ;//ns fHistoNBins = 300 ; fHistoNMax = 300 ; fHistoNMin = 0 ; fHistoRatioBins = 200 ; fHistoRatioMax = 2 ; fHistoRatioMin = 0. ; fHistoVertexDistBins = 100 ; fHistoVertexDistMax = 500. ; fHistoVertexDistMin = 0. ; fHistoRBins = 100 ; fHistoRMax = 500 ; fHistoRMin = -500 ;//cm fHistoXBins = 100 ; fHistoXMax = 500 ; fHistoXMin = -500 ;//cm fHistoYBins = 100 ; fHistoYMax = 500 ; fHistoYMin = -500 ;//cm fHistoZBins = 100 ; fHistoZMax = 600 ; fHistoZMin = -500 ;//cm fHistoSSBins = 40 ; fHistoSSMax = 10 ; fHistoSSMin = 0 ; } //__________________________________________________________________ void AliAnaCalorimeterQA::Print(const Option_t * opt) const { //Print some relevant parameters set for the analysis if(! opt) return; printf("**** Print %s %s ****\n", GetName(), GetTitle() ) ; AliAnaPartCorrBaseClass::Print(" "); printf("Select Calorimeter %s \n",fCalorimeter.Data()); printf("Plots style macro %s \n",fStyleMacro.Data()); printf("Time Cut: %3.1f < TOF < %3.1f\n", fTimeCutMin, fTimeCutMax); printf("EMCAL Min Amplitude : %2.1f GeV/c\n", fEMCALCellAmpMin) ; printf("PHOS Min Amplitude : %2.1f GeV/c\n", fPHOSCellAmpMin) ; printf("Histograms: %3.1f < p/E < %3.1f, Nbin = %d\n", fHistoPOverEMin, fHistoPOverEMax, fHistoPOverEBins); printf("Histograms: %3.1f < dEdx < %3.1f, Nbin = %d\n", fHistodEdxMin, fHistodEdxMax, fHistodEdxBins); printf("Histograms: %3.1f < dR (track cluster) < %3.1f, Nbin = %d\n", fHistodRMin, fHistodRMax, fHistodRBins); printf("Histograms: %3.1f < R=sqrt{x^2+y^2} < %3.1f, Nbin = %d\n", fHistoRMin, fHistoRMax, fHistoRBins); printf("Histograms: %3.1f < X < %3.1f, Nbin = %d\n", fHistoXMin, fHistoXMax, fHistoXBins); printf("Histograms: %3.1f < Y < %3.1f, Nbin = %d\n", fHistoYMin, fHistoYMax, fHistoYBins); printf("Histograms: %3.1f < Z < %3.1f, Nbin = %d\n", fHistoZMin, fHistoZMax, fHistoZBins); printf("Histograms: %g < Time < %g, Nbin = %d\n" , fHistoTimeMin, fHistoTimeMax, fHistoTimeBins); printf("Histograms: %d < N < %d, Nbin = %d\n" , fHistoNMin, fHistoNMax, fHistoNBins); printf("Histograms: %3.1f < Ratio< %3.1f, Nbin = %d\n", fHistoRatioMin, fHistoRatioMax, fHistoRatioBins); printf("Histograms: %3.1f < Vertex Distance < %3.1f, Nbin = %d\n", fHistoVertexDistMin, fHistoVertexDistMax, fHistoVertexDistBins); } //__________________________________________________________________ void AliAnaCalorimeterQA::MakeAnalysisFillHistograms() { //Fill Calorimeter QA histograms TLorentzVector mom ; TLorentzVector mom2 ; TObjArray * caloClusters = NULL; Int_t nLabel = 0; Int_t *labels=0x0; Int_t nCaloClusters = 0; Int_t nCaloClustersAccepted = 0; Int_t nCaloCellsPerCluster = 0; Int_t nTracksMatched = 0; Int_t trackIndex = 0; Int_t nModule = -1; //Get vertex for photon momentum calculation and event selection Double_t v[3] = {0,0,0}; //vertex ; GetReader()->GetVertex(v); if (TMath::Abs(v[2]) > GetZvertexCut()) return ; //Play with the MC stack if available //Get the MC arrays and do some checks if(IsDataMC()){ if(GetReader()->ReadStack()){ if(!GetMCStack()) { printf("AliAnaPhoton::MakeAnalysisFillHistograms() - Stack not available, is the MC handler called? STOP\n"); abort(); } //Fill some pure MC histograms, only primaries. for(Int_t i=0 ; iGetNprimary(); i++){//Only primary particles, for all MC transport put GetNtrack() TParticle *primary = GetMCStack()->Particle(i) ; //printf("i %d, %s: status = %d, primary? %d\n",i, primary->GetName(), primary->GetStatusCode(), primary->IsPrimary()); if (primary->GetStatusCode() > 11) continue; //Working for PYTHIA and simple generators, check for HERWIG primary->Momentum(mom); MCHistograms(mom,TMath::Abs(primary->GetPdgCode())); } //primary loop } else if(GetReader()->ReadAODMCParticles()){ if(!GetReader()->GetAODMCParticles(0)) { printf("AliAnaPhoton::MakeAnalysisFillHistograms() - AODMCParticles not available!\n"); abort(); } //Fill some pure MC histograms, only primaries. for(Int_t i=0 ; i < (GetReader()->GetAODMCParticles(0))->GetEntriesFast(); i++){ AliAODMCParticle *aodprimary = (AliAODMCParticle*) (GetReader()->GetAODMCParticles(0))->At(i) ; //printf("i %d, %s: primary? %d physical primary? %d, flag %d\n", // i,(TDatabasePDG::Instance()->GetParticle(aodprimary->GetPdgCode()))->GetName(), // aodprimary->IsPrimary(), aodprimary->IsPhysicalPrimary(), aodprimary->GetFlag()); if (!aodprimary->IsPrimary()) continue; //accept all which is not MC transport generated. Don't know how to avoid partons //aodprimary->Momentum(mom); mom.SetPxPyPzE(aodprimary->Px(),aodprimary->Py(),aodprimary->Pz(),aodprimary->E()); MCHistograms(mom,TMath::Abs(aodprimary->GetPdgCode())); } //primary loop } }// is data and MC //Get List with CaloClusters if (fCalorimeter == "PHOS") caloClusters = GetAODPHOS(); else if (fCalorimeter == "EMCAL") caloClusters = GetAODEMCAL(); else AliFatal(Form("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - Wrong calorimeter name <%s>, END\n", fCalorimeter.Data())); // if (fCalorimeter == "EMCAL") GetReader()->GetInputEvent()->GetEMCALClusters(caloClusters);//GetAODEMCAL(); // else if(fCalorimeter == "PHOS") GetReader()->GetInputEvent()->GetPHOSClusters (caloClusters);//GetAODPHOS(); // else // AliFatal(Form("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - Wrong calorimeter name <%s>, END\n", fCalorimeter.Data())); if(!caloClusters) { AliFatal(Form("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - No CaloClusters available\n")); } else{ //---------------------------------------------------------- //Correlate Calorimeters and V0 and track Multiplicity //---------------------------------------------------------- if(fCorrelate) Correlate(); //---------------------------------------------------------- // CALOCLUSTERS //---------------------------------------------------------- nCaloClusters = caloClusters->GetEntriesFast() ; Int_t *nClustersInModule = new Int_t[fNModules]; for(Int_t imod = 0; imod < fNModules; imod++ ) nClustersInModule[imod] = 0; if(GetDebug() > 0) printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - In %s there are %d clusters \n", fCalorimeter.Data(), nCaloClusters); AliVTrack * track = 0x0; Float_t pos[3] ; Float_t showerShape[3] ; Double_t tof = 0; //Loop over CaloClusters //if(nCaloClusters > 0)printf("QA : Vertex Cut passed %f, cut %f, entries %d, %s\n",v[2], 40., nCaloClusters, fCalorimeter.Data()); for(Int_t iclus = 0; iclus < nCaloClusters; iclus++){ if(GetDebug() > 0) printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - cluster: %d/%d, data %d \n", iclus+1,nCaloClusters,GetReader()->GetDataType()); AliVCluster* clus = (AliVCluster*)caloClusters->At(iclus); AliVCaloCells * cell = 0x0; if(fCalorimeter == "PHOS") cell = GetPHOSCells(); else cell = GetEMCALCells(); //Get cluster kinematics clus->GetPosition(pos); clus->GetMomentum(mom,v); tof = clus->GetTOF()*1e9; if(tof < fTimeCutMin || tof > fTimeCutMax) continue; //Check only certain regions Bool_t in = kTRUE; if(IsFiducialCutOn()) in = GetFiducialCut()->IsInFiducialCut(mom,fCalorimeter) ; if(!in) continue; //Get module of cluster nCaloClustersAccepted++; nModule = GetModuleNumber(clus); if(nModule >=0 && nModule < fNModules) nClustersInModule[nModule]++; //MC labels nLabel = clus->GetNLabels(); labels = clus->GetLabels(); //Cells per cluster nCaloCellsPerCluster = clus->GetNCells(); //if(mom.E() > 10 && nCaloCellsPerCluster == 1 ) printf("%s:************** E = %f ********** ncells = %d\n",fCalorimeter.Data(), mom.E(),nCaloCellsPerCluster); //matched cluster with tracks nTracksMatched = clus->GetNTracksMatched(); trackIndex = clus->GetTrackMatchedIndex(); if(trackIndex >= 0){ track = (AliVTrack*)GetReader()->GetInputEvent()->GetTrack(trackIndex); } else{ if(nTracksMatched == 1) nTracksMatched = 0; track = 0; } //Shower shape parameters showerShape[0] = clus->GetM20(); showerShape[1] = clus->GetM02(); showerShape[2] = clus->GetDispersion(); //====================== //Cells in cluster //====================== //Get list of contributors UShort_t * indexList = clus->GetCellsAbsId() ; // check time of cells respect to max energy cell //Get maximum energy cell Float_t emax = -1; Double_t tmax = -1; Int_t imax = -1; Int_t absId = -1 ; //printf("nCaloCellsPerCluster %d\n",nCaloCellsPerCluster); //Loop on cluster cells for (Int_t ipos = 0; ipos < nCaloCellsPerCluster; ipos++) { // printf("Index %d\n",ipos); absId = indexList[ipos]; //Get position of cell compare to cluster if(fFillAllPosHisto){ if(fCalorimeter=="EMCAL" && GetCaloUtils()->IsEMCALGeoMatrixSet()){ Double_t cellpos[] = {0, 0, 0}; GetEMCALGeometry()->GetGlobal(absId, cellpos); fhDeltaCellClusterXNCells->Fill(pos[0]-cellpos[0],nCaloCellsPerCluster) ; fhDeltaCellClusterYNCells->Fill(pos[1]-cellpos[1],nCaloCellsPerCluster) ; fhDeltaCellClusterZNCells->Fill(pos[2]-cellpos[2],nCaloCellsPerCluster) ; fhDeltaCellClusterXE->Fill(pos[0]-cellpos[0],mom.E()) ; fhDeltaCellClusterYE->Fill(pos[1]-cellpos[1],mom.E()) ; fhDeltaCellClusterZE->Fill(pos[2]-cellpos[2],mom.E()) ; Float_t r = TMath::Sqrt(pos[0]*pos[0] +pos[1]*pos[1]);// +pos[2]*pos[2]); Float_t rcell = TMath::Sqrt(cellpos[0]*cellpos[0]+cellpos[1]*cellpos[1]);//+cellpos[2]*cellpos[2]); fhDeltaCellClusterRNCells->Fill(r-rcell, nCaloCellsPerCluster) ; fhDeltaCellClusterRE ->Fill(r-rcell, mom.E()) ; // Float_t celleta = 0, cellphi = 0; // GetEMCALGeometry()->EtaPhiFromIndex(absId, celleta, cellphi); // Int_t imod = -1, iTower = -1, iIphi = -1, iIeta = -1, iphi = -1, ieta = -1; // GetEMCALGeometry()->GetCellIndex(absId,imod,iTower,iIphi,iIeta); // GetEMCALGeometry()->GetCellPhiEtaIndexInSModule(imod,iTower, // iIphi, iIeta,iphi,ieta); // printf("AbsId %d, SM %d, Index eta %d, phi %d\n", absId, imod, ieta, iphi); // printf("Cluster E %f, eta %f, phi %f; Cell: Amp %f, eta %f, phi%f\n", mom.E(),mom.Eta(), mom.Phi()*TMath::RadToDeg(), cell->GetCellAmplitude(absId),celleta, cellphi*TMath::RadToDeg()); // printf("x cluster %f, x cell %f, cluster-cell %f\n",pos[0], cellpos[0],pos[0]-cellpos[0]); // printf("y cluster %f, y cell %f, cluster-cell %f\n",pos[1], cellpos[1],pos[1]-cellpos[1]); // printf("z cluster %f, z cell %f, cluster-cell %f\n",pos[2], cellpos[2],pos[2]-cellpos[2]); // printf("r cluster %f, r cell %f, cluster-cell %f\n",r, rcell, r-rcell); // }//EMCAL and its matrices are available else if(fCalorimeter=="PHOS" && GetCaloUtils()->IsPHOSGeoMatrixSet()){ TVector3 xyz; Int_t relId[4], module; Float_t xCell, zCell; GetPHOSGeometry()->AbsToRelNumbering(absId,relId); module = relId[0]; GetPHOSGeometry()->RelPosInModule(relId,xCell,zCell); GetPHOSGeometry()->Local2Global(module,xCell,zCell,xyz); fhDeltaCellClusterXNCells->Fill(pos[0]-xyz.X(),nCaloCellsPerCluster) ; fhDeltaCellClusterYNCells->Fill(pos[1]-xyz.Y(),nCaloCellsPerCluster) ; fhDeltaCellClusterZNCells->Fill(pos[2]-xyz.Z(),nCaloCellsPerCluster) ; fhDeltaCellClusterXE->Fill(pos[0]-xyz.X(),mom.E()) ; fhDeltaCellClusterYE->Fill(pos[1]-xyz.Y(),mom.E()) ; fhDeltaCellClusterZE->Fill(pos[2]-xyz.Z(),mom.E()) ; Float_t r = TMath::Sqrt(pos[0]*pos[0] +pos[1]*pos[1]);// +pos[2]*pos[2]); Float_t rcell = TMath::Sqrt(xyz.X()*xyz.X()+xyz.Y()*xyz.Y());//+xyz.Z()*xyz.Z()); fhDeltaCellClusterRNCells->Fill(r-rcell, nCaloCellsPerCluster) ; fhDeltaCellClusterRE ->Fill(r-rcell, mom.E()) ; // printf("x cluster %f, x cell %f, cluster-cell %f\n",pos[0], cellpos[0],pos[0]-cellpos[0]); // printf("y cluster %f, y cell %f, cluster-cell %f\n",pos[1], cellpos[1],pos[1]-cellpos[1]); // printf("z cluster %f, z cell %f, cluster-cell %f\n",pos[2], cellpos[2],pos[2]-cellpos[2]); // printf("r cluster %f, r cell %f, cluster-cell %f\n",r, rcell, r-rcell); }//PHOS and its matrices are available }//Fill all position histograms //Find maximum energy cluster if(cell->GetCellAmplitude(absId) > emax) { imax = ipos; emax = cell->GetCellAmplitude(absId); tmax = cell->GetCellTime(absId); } }// cluster cell loop // check time of cells respect to max energy cell if(nCaloCellsPerCluster > 1 && GetReader()->GetDataType()==AliCaloTrackReader::kESD) { for (Int_t ipos = 0; ipos < nCaloCellsPerCluster; ipos++) { if(imax == ipos) continue; absId = indexList[ipos]; Float_t diff = (tmax-cell->GetCellTime(absId))*1e9; printf("diff time %f %p",diff,fhCellTimeSpreadRespectToCellMax); fhCellTimeSpreadRespectToCellMax->Fill(diff); if(TMath::Abs(TMath::Abs(diff) > 100)) fhCellIdCellLargeTimeSpread->Fill(absId); }// fill cell-cluster histogram loop }//check time of cells respect to max energy cell //----------------------------------------------------------- //Fill histograms related to single cluster or track matching //----------------------------------------------------------- ClusterHistograms(mom, tof, pos, showerShape, nCaloCellsPerCluster, nModule, nTracksMatched, track, labels, nLabel); //----------------------------------------------------------- //Invariant mass //----------------------------------------------------------- if(GetDebug()>1) printf("Invariant mass \n"); //do not do for bad vertex // Float_t fZvtxCut = 40. ; if(v[2]<-GetZvertexCut() || v[2]> GetZvertexCut()) continue ; //Event can not be used (vertex, centrality,... cuts not fulfilled) Int_t nModule2 = -1; Int_t nCaloCellsPerCluster2=0; if (nCaloClusters > 1 ) { for(Int_t jclus = iclus + 1 ; jclus < nCaloClusters ; jclus++) { AliVCluster* clus2 = (AliVCluster*)caloClusters->At(jclus); //Get cluster kinematics clus2->GetMomentum(mom2,v); //Check only certain regions Bool_t in2 = kTRUE; if(IsFiducialCutOn()) in2 = GetFiducialCut()->IsInFiducialCut(mom2,fCalorimeter) ; if(!in2) continue; //Get module of cluster nModule2 = GetModuleNumber(clus2); //Cells per cluster nCaloCellsPerCluster2 = clus2->GetNCells(); } //Fill invariant mass histograms //All modules //printf("QA : Fill inv mass histo: pt1 %f, pt2 %f, pt12 %f, mass %f, calo %s \n",mom.Pt(),mom2.Pt(),(mom+mom2).Pt(),(mom+mom2).M(), fCalorimeter.Data()); fhIM ->Fill((mom+mom2).Pt(),(mom+mom2).M()); //Single module if(nModule == nModule2 && nModule >=0 && nModule < fNModules) fhIMMod[nModule]->Fill((mom+mom2).Pt(),(mom+mom2).M()); //Select only clusters with at least 2 cells if(nCaloCellsPerCluster > 1 && nCaloCellsPerCluster2 > 1) { //All modules fhIMCellCut ->Fill((mom+mom2).Pt(),(mom+mom2).M()); //Single modules if(nModule == nModule2 && nModule >=0 && nModule < fNModules) fhIMCellCutMod[nModule]->Fill((mom+mom2).Pt(),(mom+mom2).M()); } //Asymetry histograms fhAsym->Fill((mom+mom2).Pt(),TMath::Abs((mom.E()-mom2.E())/(mom.E()+mom2.E()))); }// 2nd cluster loop }//cluster loop //Number of clusters histograms if(nCaloClustersAccepted > 0) fhNClusters->Fill(nCaloClustersAccepted); // Number of clusters per module for(Int_t imod = 0; imod < fNModules; imod++ ){ if(GetDebug() > 1) printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - module %d calo %s clusters %d\n", imod, fCalorimeter.Data(), nClustersInModule[imod]); fhNClustersMod[imod]->Fill(nClustersInModule[imod]); } delete [] nClustersInModule; //delete caloClusters; }// calo clusters array exists //---------------------------------------------------------- // CALOCELLS //---------------------------------------------------------- Int_t *nCellsInModule = new Int_t[fNModules]; for(Int_t imod = 0; imod < fNModules; imod++ ) nCellsInModule[imod] = 0; Int_t icol = -1; Int_t irow = -1; Int_t iRCU = -1; Float_t amp = 0.; Float_t time = 0.; Int_t id = -1; Float_t recalF = 1.; AliVCaloCells * cell = 0x0; Int_t ncells = 0; if(fCalorimeter == "PHOS") cell = GetPHOSCells(); else cell = GetEMCALCells(); if(!cell) { printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - STOP: No %s ESD CELLS available for analysis\n",fCalorimeter.Data()); abort(); } if(GetDebug() > 0) printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - In ESD %s cell entries %d\n", fCalorimeter.Data(), cell->GetNumberOfCells()); for (Int_t iCell = 0; iCell < cell->GetNumberOfCells(); iCell++) { if(GetDebug() > 2) printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - Cell : amp %f, absId %d \n", cell->GetAmplitude(iCell), cell->GetCellNumber(iCell)); nModule = GetModuleNumberCellIndexes(cell->GetCellNumber(iCell),fCalorimeter, icol, irow, iRCU); if(GetDebug() > 2) printf("\t module %d, column %d, row %d \n", nModule,icol,irow); if(nModule < fNModules) { //Check if the cell is a bad channel if(GetCaloUtils()->IsBadChannelsRemovalSwitchedOn()){ if(fCalorimeter=="EMCAL"){ if(GetCaloUtils()->GetEMCALChannelStatus(nModule,icol,irow)) continue; } else { if(GetCaloUtils()->GetPHOSChannelStatus(nModule,icol,irow)) { printf("PHOS bad channel\n"); continue; } } } //Get Recalibration factor if set if (GetCaloUtils()->IsRecalibrationOn()) { if(fCalorimeter == "PHOS") recalF = GetCaloUtils()->GetPHOSChannelRecalibrationFactor(nModule,icol,irow); else recalF = GetCaloUtils()->GetEMCALChannelRecalibrationFactor(nModule,icol,irow); //if(fCalorimeter == "PHOS")printf("Recalibration factor (sm,row,col)=(%d,%d,%d) - %f\n",nModule,icol,irow,recalF); } amp = cell->GetAmplitude(iCell)*recalF; time = cell->GetTime(iCell)*1e9;//transform time to ns if(time < fTimeCutMin || time > fTimeCutMax) continue; //if(amp > 3 && fCalorimeter=="EMCAL") printf("Amp = %f, time = %f, (mod, col, row)= (%d,%d,%d)\n", // amp,time,nModule,icol,irow); //printf("%s: time %g\n",fCalorimeter.Data(), time); id = cell->GetCellNumber(iCell); fhAmplitude->Fill(amp); fhAmpId ->Fill(amp,id); fhTime ->Fill(time); fhTimeId ->Fill(time,id); fhTimeAmp ->Fill(amp,time); //Double_t t0 = GetReader()->GetInputEvent()->GetT0(); //printf("---->>> Time EMCal %e, T0 %e, T0 vertex %e, T0 clock %e, T0 trig %d \n",time,t0, // GetReader()->GetInputEvent()->GetT0zVertex(), // GetReader()->GetInputEvent()->GetT0clock(), // GetReader()->GetInputEvent()->GetT0Trig()); //fhT0Time ->Fill(time-t0); //fhT0TimeId ->Fill(time-t0,id); //fhT0TimeAmp ->Fill(amp,time-t0); fhAmplitudeMod[nModule]->Fill(amp); if(fCalorimeter=="EMCAL"){ Int_t ifrac = 0; if(icol > 15 && icol < 32) ifrac = 1; else if(icol > 31) ifrac = 2; fhAmplitudeModFraction[nModule*3+ifrac]->Fill(amp); } fhTimeAmpPerRCU [nModule*fNRCU+iRCU]->Fill(amp, time); //printf("id %d, nModule %d, iRCU %d: Histo Name %s\n",id, nModule,iRCU, fhTimeAmpPerRCU[nModule*fNRCU+iRCU]->GetName()); //fhT0TimeAmpPerRCU[nModule*fNRCU+iRCU]->Fill(amp, time-t0); nCellsInModule[nModule]++; fhGridCellsMod[nModule] ->Fill(icol,irow); fhGridCellsEMod[nModule] ->Fill(icol,irow,amp); if(amp > 0.3){ fhGridCellsTimeMod[nModule]->Fill(icol,irow,time); // AliESDCaloCells * cell2 = 0x0; // if(fCalorimeter == "PHOS") cell2 = GetReader()->GetInputEvent()->GetPHOSCells(); // else cell2 = GetReader()->GetInputEvent()->GetEMCALCells(); // Int_t icol2 = -1; // Int_t irow2 = -1; // Int_t iRCU2 = -1; // Float_t amp2 = 0.; // Float_t time2 = 0.; // Int_t id2 = -1; // Int_t nModule2 = -1; // for (Int_t iCell2 = 0; iCell2 < ncells; iCell2++) { // amp2 = cell2->GetAmplitude(iCell2); // if(amp2 < 0.3) continue; // if(iCell2 == iCell) continue; // time2 = cell2->GetTime(iCell2)*1e9;//transform time to ns // //printf("%s: time %g\n",fCalorimeter.Data(), time); // id2 = cell2->GetCellNumber(iCell2); // nModule2 = GetModuleNumberCellIndexes(cell2->GetCellNumber(iCell2), fCalorimeter, icol2, irow2, iRCU2); // Int_t index = (nModule2*fNRCU+iRCU2)+(fNModules*fNRCU)*(iRCU+fNRCU*nModule); // //printf("id %d, nModule %d, iRCU %d, id2 %d, nModule2 %d, iRCU2 %d, index %d: Histo Name %s\n",id, nModule,iRCU,cell2->GetCellNumber(iCell2),nModule2,iRCU2,index, fhTimeCorrRCU[index]->GetName()); // fhTimeCorrRCU[index]->Fill(time,time2); // // }// second cell loop }// amplitude cut }//nmodules //Get Eta-Phi position of Cell if(fFillAllPosHisto) { if(fCalorimeter=="EMCAL" && GetCaloUtils()->IsEMCALGeoMatrixSet()){ Float_t celleta = 0.; Float_t cellphi = 0.; GetEMCALGeometry()->EtaPhiFromIndex(id, celleta, cellphi); fhEtaPhiAmp->Fill(celleta,cellphi,amp); Double_t cellpos[] = {0, 0, 0}; GetEMCALGeometry()->GetGlobal(id, cellpos); fhXCellE->Fill(cellpos[0],amp) ; fhYCellE->Fill(cellpos[1],amp) ; fhZCellE->Fill(cellpos[2],amp) ; Float_t rcell = TMath::Sqrt(cellpos[0]*cellpos[0]+cellpos[1]*cellpos[1]);//+cellpos[2]*cellpos[2]); fhRCellE->Fill(rcell,amp) ; fhXYZCell->Fill(cellpos[0],cellpos[1],cellpos[2]) ; }//EMCAL Cells else if(fCalorimeter=="PHOS" && GetCaloUtils()->IsPHOSGeoMatrixSet()){ TVector3 xyz; Int_t relId[4], module; Float_t xCell, zCell; GetPHOSGeometry()->AbsToRelNumbering(id,relId); module = relId[0]; GetPHOSGeometry()->RelPosInModule(relId,xCell,zCell); GetPHOSGeometry()->Local2Global(module,xCell,zCell,xyz); Float_t rcell = TMath::Sqrt(xyz.X()*xyz.X()+xyz.Y()*xyz.Y()); fhXCellE ->Fill(xyz.X(),amp) ; fhYCellE ->Fill(xyz.Y(),amp) ; fhZCellE ->Fill(xyz.Z(),amp) ; fhRCellE ->Fill(rcell ,amp) ; fhXYZCell->Fill(xyz.X(),xyz.Y(),xyz.Z()) ; }//PHOS cells }//fill cell position histograms if (fCalorimeter=="EMCAL" && amp > fEMCALCellAmpMin) ncells ++ ; else if(fCalorimeter=="PHOS" && amp > fPHOSCellAmpMin) ncells ++ ; //else // printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - no %s CELLS passed the analysis cut\n",fCalorimeter.Data()); }//cell loop if(ncells > 0 )fhNCells->Fill(ncells) ; //fill the cells after the cut //Number of cells per module for(Int_t imod = 0; imod < fNModules; imod++ ) { if(GetDebug() > 1) printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - module %d calo %s cells %d\n", imod, fCalorimeter.Data(), nCellsInModule[imod]); fhNCellsMod[imod]->Fill(nCellsInModule[imod]) ; } delete [] nCellsInModule; if(GetDebug() > 0) printf("AliAnaCalorimeterQA::MakeAnalysisFillHistograms() - End \n"); } //_____________________________________________________________________________________________ void AliAnaCalorimeterQA::ClusterHistograms(const TLorentzVector mom, const Double_t tof, Float_t *pos, Float_t *showerShape, const Int_t nCaloCellsPerCluster,const Int_t nModule, const Int_t nTracksMatched, const AliVTrack * track, const Int_t * labels, const Int_t nLabels){ //Fill CaloCluster related histograms AliAODMCParticle * aodprimary = 0x0; TParticle * primary = 0x0; Int_t tag = 0; Float_t e = mom.E(); Float_t pt = mom.Pt(); Float_t eta = mom.Eta(); Float_t phi = mom.Phi(); if(phi < 0) phi +=TMath::TwoPi(); if(GetDebug() > 0) { printf("AliAnaCalorimeterQA::ClusterHistograms() - cluster: E %2.3f, pT %2.3f, eta %2.3f, phi %2.3f \n",e,pt,eta,phi*TMath::RadToDeg()); if(IsDataMC()) { //printf("\t Primaries: nlabels %d, labels pointer %p\n",nLabels,labels); printf("\t Primaries: nlabels %d\n",nLabels); if(!nLabels || !labels) printf("\t Strange, no labels!!!\n"); } } fhE ->Fill(e); if(nModule >=0 && nModule < fNModules) fhEMod[nModule]->Fill(e); if(fFillAllTH12){ fhPt ->Fill(pt); fhPhi ->Fill(phi); fhEta ->Fill(eta); } fhEtaPhiE->Fill(eta,phi,e); //Cells per cluster fhNCellsPerCluster ->Fill(e, nCaloCellsPerCluster,eta); fhNCellsPerClusterMIP->Fill(e, nCaloCellsPerCluster,eta); //Position if(fFillAllPosHisto) { fhXE ->Fill(pos[0],e); fhYE ->Fill(pos[1],e); fhZE ->Fill(pos[2],e); fhXYZ ->Fill(pos[0], pos[1],pos[2]); fhXNCells->Fill(pos[0],nCaloCellsPerCluster); fhYNCells->Fill(pos[1],nCaloCellsPerCluster); fhZNCells->Fill(pos[2],nCaloCellsPerCluster); Float_t rxyz = TMath::Sqrt(pos[0]*pos[0]+pos[1]*pos[1]);//+pos[2]*pos[2]); fhRE ->Fill(rxyz,e); fhRNCells->Fill(rxyz ,nCaloCellsPerCluster); } fhClusterTimeEnergy->Fill(e,tof); //Shower shape parameters fhLambda->Fill(showerShape[0], showerShape[1], e); fhDispersion->Fill(showerShape[2],e); if(nModule >=0 && nModule < fNModules) fhNCellsPerClusterMod[nModule]->Fill(e, nCaloCellsPerCluster); //Fill histograms only possible when simulation if(IsDataMC() && nLabels > 0 && labels){ //Play with the MC stack if available Int_t label = labels[0]; if(label < 0) { if(GetDebug() >= 0) printf("AliAnaCalorimeterQA::ClusterHistograms() *** bad label ***: label %d \n", label); return; } Int_t pdg =-1; Int_t pdg0 =-1;Int_t status = -1; Int_t iMother = -1; Int_t iParent = -1; Float_t vxMC= 0; Float_t vyMC = 0; Float_t eMC = 0; Float_t ptMC= 0; Float_t phiMC =0; Float_t etaMC = 0; Int_t charge = 0; //Check the origin. tag = GetMCAnalysisUtils()->CheckOrigin(labels,nLabels, GetReader(),0); if(GetReader()->ReadStack() && !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCUnknown)){ //it MC stack and known tag if( label >= GetMCStack()->GetNtrack()) { if(GetDebug() >= 0) printf("AliAnaCalorimeterQA::ClusterHistograms() *** large label ***: label %d, n tracks %d \n", label, GetMCStack()->GetNtrack()); return ; } primary = GetMCStack()->Particle(label); iMother = label; pdg0 = TMath::Abs(primary->GetPdgCode()); pdg = pdg0; status = primary->GetStatusCode(); vxMC = primary->Vx(); vyMC = primary->Vy(); iParent = primary->GetFirstMother(); if(GetDebug() > 1 ) { printf("AliAnaCalorimeterQA::ClusterHistograms() - Cluster most contributing mother: \n"); printf("\t Mother label %d, pdg %d, %s, status %d, parent %d \n",iMother, pdg0, primary->GetName(),status, iParent); } //Get final particle, no conversion products if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion)){ //Get the parent primary = GetMCStack()->Particle(iParent); pdg = TMath::Abs(primary->GetPdgCode()); if(GetDebug() > 1 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Converted cluster!. Find before conversion: \n"); while((pdg == 22 || pdg == 11) && status != 1){ iMother = iParent; primary = GetMCStack()->Particle(iMother); status = primary->GetStatusCode(); iParent = primary->GetFirstMother(); pdg = TMath::Abs(primary->GetPdgCode()); if(GetDebug() > 1 )printf("\t pdg %d, index %d, %s, status %d \n",pdg, iMother, primary->GetName(),status); } if(GetDebug() > 1 ) { printf("AliAnaCalorimeterQA::ClusterHistograms() - Converted Cluster mother before conversion: \n"); printf("\t Mother label %d, pdg %d, %s, status %d, parent %d \n",iMother, pdg, primary->GetName(), status, iParent); } } //Overlapped pi0 (or eta, there will be very few), get the meson if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0) || GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta)){ if(GetDebug() > 1 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Overlapped Meson decay!, Find it: \n"); while(pdg != 111 && pdg != 221){ iMother = iParent; primary = GetMCStack()->Particle(iMother); status = primary->GetStatusCode(); iParent = primary->GetFirstMother(); pdg = TMath::Abs(primary->GetPdgCode()); if(GetDebug() > 1 ) printf("\t pdg %d, %s, index %d\n",pdg, primary->GetName(),iMother); if(iMother==-1) { printf("AliAnaCalorimeterQA::ClusterHistograms() - Tagged as Overlapped photon but meson not found, why?\n"); //break; } } if(GetDebug() > 2 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Overlapped %s decay, label %d \n", primary->GetName(),iMother); } eMC = primary->Energy(); ptMC = primary->Pt(); phiMC = primary->Phi(); etaMC = primary->Eta(); pdg = TMath::Abs(primary->GetPdgCode()); charge = (Int_t) TDatabasePDG::Instance()->GetParticle(pdg)->Charge(); } else if(GetReader()->ReadAODMCParticles() && !GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCUnknown)){//it MC AOD and known tag //Get the list of MC particles if(!GetReader()->GetAODMCParticles(0)) { printf("AliAnaCalorimeterQA::ClusterHistograms() - MCParticles not available!\n"); abort(); } aodprimary = (AliAODMCParticle*) (GetReader()->GetAODMCParticles(0))->At(label); iMother = label; pdg0 = TMath::Abs(aodprimary->GetPdgCode()); pdg = pdg0; status = aodprimary->IsPrimary(); vxMC = aodprimary->Xv(); vyMC = aodprimary->Yv(); iParent = aodprimary->GetMother(); if(GetDebug() > 1 ) { printf("AliAnaCalorimeterQA::ClusterHistograms() - Cluster most contributing mother: \n"); printf("\t Mother label %d, pdg %d, Primary? %d, Physical Primary? %d, parent %d \n", iMother, pdg0, aodprimary->IsPrimary(), aodprimary->IsPhysicalPrimary(), iParent); } //Get final particle, no conversion products if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCConversion)){ if(GetDebug() > 1 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Converted cluster!. Find before conversion: \n"); //Get the parent aodprimary = (AliAODMCParticle*)(GetReader()->GetAODMCParticles(0))->At(iParent); pdg = TMath::Abs(aodprimary->GetPdgCode()); while ((pdg == 22 || pdg == 11) && !aodprimary->IsPhysicalPrimary()) { iMother = iParent; aodprimary = (AliAODMCParticle*)(GetReader()->GetAODMCParticles(0))->At(iMother); status = aodprimary->IsPrimary(); iParent = aodprimary->GetMother(); pdg = TMath::Abs(aodprimary->GetPdgCode()); if(GetDebug() > 1 ) printf("\t pdg %d, index %d, Primary? %d, Physical Primary? %d \n", pdg, iMother, aodprimary->IsPrimary(), aodprimary->IsPhysicalPrimary()); } if(GetDebug() > 1 ) { printf("AliAnaCalorimeterQA::ClusterHistograms() - Converted Cluster mother before conversion: \n"); printf("\t Mother label %d, pdg %d, parent %d, Primary? %d, Physical Primary? %d \n", iMother, pdg, iParent, aodprimary->IsPrimary(), aodprimary->IsPhysicalPrimary()); } } //Overlapped pi0 (or eta, there will be very few), get the meson if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0) || GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta)){ if(GetDebug() > 1 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Overlapped Meson decay!, Find it: PDG %d, mom %d \n",pdg, iMother); while(pdg != 111 && pdg != 221){ iMother = iParent; aodprimary = (AliAODMCParticle*)(GetReader()->GetAODMCParticles(0))->At(iMother); status = aodprimary->IsPrimary(); iParent = aodprimary->GetMother(); pdg = TMath::Abs(aodprimary->GetPdgCode()); if(GetDebug() > 1 ) printf("\t pdg %d, index %d\n",pdg, iMother); if(iMother==-1) { printf("AliAnaCalorimeterQA::ClusterHistograms() - Tagged as Overlapped photon but meson not found, why?\n"); //break; } } if(GetDebug() > 2 ) printf("AliAnaCalorimeterQA::ClusterHistograms() - Overlapped %s decay, label %d \n", aodprimary->GetName(),iMother); } status = aodprimary->IsPrimary(); eMC = aodprimary->E(); ptMC = aodprimary->Pt(); phiMC = aodprimary->Phi(); etaMC = aodprimary->Eta(); pdg = TMath::Abs(aodprimary->GetPdgCode()); charge = aodprimary->Charge(); } //Float_t vz = primary->Vz(); Float_t rVMC = TMath::Sqrt(vxMC*vxMC + vyMC*vyMC); if((pdg == 22 || TMath::Abs(pdg)==11) && status!=1) { fhEMVxyz ->Fill(vxMC,vyMC);//,vz); fhEMR ->Fill(e,rVMC); } //printf("reco e %f, pt %f, phi %f, eta %f \n", e, pt, phi, eta); //printf("prim e %f, pt %f, phi %f, eta %f \n", eMC,ptMC,phiMC ,etaMC ); //printf("vertex: vx %f, vy %f, vz %f, r %f \n", vxMC, vyMC, vz, r); fh2E ->Fill(e, eMC); fh2Pt ->Fill(pt, ptMC); fh2Phi ->Fill(phi, phiMC); fh2Eta ->Fill(eta, etaMC); fhDeltaE ->Fill(eMC-e); fhDeltaPt ->Fill(ptMC-pt); fhDeltaPhi->Fill(phiMC-phi); fhDeltaEta->Fill(etaMC-eta); if(eMC > 0) fhRatioE ->Fill(e/eMC); if(ptMC > 0) fhRatioPt ->Fill(pt/ptMC); if(phiMC > 0) fhRatioPhi->Fill(phi/phiMC); if(etaMC > 0) fhRatioEta->Fill(eta/etaMC); //Overlapped pi0 (or eta, there will be very few) if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPi0) || GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCEta)){ fhPi0E ->Fill(e,eMC); fhPi0Pt ->Fill(pt,ptMC); fhPi0Eta ->Fill(eta,etaMC); fhPi0Phi ->Fill(phi,phiMC); if( nTracksMatched > 0){ fhPi0ECharged ->Fill(e,eMC); fhPi0PtCharged ->Fill(pt,ptMC); fhPi0PhiCharged ->Fill(phi,phiMC); fhPi0EtaCharged ->Fill(eta,etaMC); } }//Overlapped pizero decay else if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCPhoton)){ fhGamE ->Fill(e,eMC); fhGamPt ->Fill(pt,ptMC); fhGamEta ->Fill(eta,etaMC); fhGamPhi ->Fill(phi,phiMC); fhGamDeltaE ->Fill(eMC-e); fhGamDeltaPt ->Fill(ptMC-pt); fhGamDeltaPhi->Fill(phiMC-phi); fhGamDeltaEta->Fill(etaMC-eta); if(eMC > 0) fhGamRatioE ->Fill(e/eMC); if(ptMC > 0) fhGamRatioPt ->Fill(pt/ptMC); if(phiMC > 0) fhGamRatioPhi->Fill(phi/phiMC); if(etaMC > 0) fhGamRatioEta->Fill(eta/etaMC); if( nTracksMatched > 0){ fhGamECharged ->Fill(e,eMC); fhGamPtCharged ->Fill(pt,ptMC); fhGamPhiCharged ->Fill(phi,phiMC); fhGamEtaCharged ->Fill(eta,etaMC); } }//photon else if(GetMCAnalysisUtils()->CheckTagBit(tag, AliMCAnalysisUtils::kMCElectron)){ fhEleE ->Fill(e,eMC); fhElePt ->Fill(pt,ptMC); fhEleEta ->Fill(eta,etaMC); fhElePhi ->Fill(phi,phiMC); fhEMVxyz ->Fill(vxMC,vyMC);//,vz); fhEMR ->Fill(e,rVMC); if( nTracksMatched > 0){ fhEleECharged ->Fill(e,eMC); fhElePtCharged ->Fill(pt,ptMC); fhElePhiCharged ->Fill(phi,phiMC); fhEleEtaCharged ->Fill(eta,etaMC); } } else if(charge == 0){ fhNeHadE ->Fill(e,eMC); fhNeHadPt ->Fill(pt,ptMC); fhNeHadEta ->Fill(eta,etaMC); fhNeHadPhi ->Fill(phi,phiMC); fhHaVxyz ->Fill(vxMC,vyMC);//,vz); fhHaR ->Fill(e,rVMC); if( nTracksMatched > 0){ fhNeHadECharged ->Fill(e,eMC); fhNeHadPtCharged ->Fill(pt,ptMC); fhNeHadPhiCharged ->Fill(phi,phiMC); fhNeHadEtaCharged ->Fill(eta,etaMC); } } else if(charge!=0){ fhChHadE ->Fill(e,eMC); fhChHadPt ->Fill(pt,ptMC); fhChHadEta ->Fill(eta,etaMC); fhChHadPhi ->Fill(phi,phiMC); fhHaVxyz ->Fill(vxMC,vyMC);//,vz); fhHaR ->Fill(e,rVMC); if( nTracksMatched > 0){ fhChHadECharged ->Fill(e,eMC); fhChHadPtCharged ->Fill(pt,ptMC); fhChHadPhiCharged ->Fill(phi,phiMC); fhChHadEtaCharged ->Fill(eta,etaMC); } } }//Work with MC //Match tracks and clusters //To be Modified in case of AODs //if(ntracksmatched==1 && trackIndex==-1) ntracksmatched=0; if( nTracksMatched > 0){ if(fFillAllTH12){ fhECharged ->Fill(e); fhPtCharged ->Fill(pt); fhPhiCharged ->Fill(phi); fhEtaCharged ->Fill(eta); } fhEtaPhiECharged->Fill(eta,phi,e); fhNCellsPerClusterMIPCharged->Fill(e, nCaloCellsPerCluster,eta); //printf("track index %d ntracks %d\n", esd->GetNumberOfTracks()); //Study the track and matched cluster if track exists. if(!track) return; Double_t emcpos[3] = {0.,0.,0.}; Double_t emcmom[3] = {0.,0.,0.}; Double_t radius = 441.0; //[cm] EMCAL radius +13cm Double_t bfield = 0.; Double_t tphi = 0; Double_t teta = 0; Double_t tmom = 0; Double_t tpt = 0; Double_t tmom2 = 0; Double_t tpcSignal = 0; Bool_t okpos = kFALSE; Bool_t okmom = kFALSE; Bool_t okout = kFALSE; Int_t nITS = 0; Int_t nTPC = 0; //In case of ESDs get the parameters in this way // if(GetReader()->GetDataType()==AliCaloTrackReader::kESD) { if (track->GetOuterParam() ) { okout = kTRUE; bfield = GetReader()->GetInputEvent()->GetMagneticField(); okpos = track->GetOuterParam()->GetXYZAt(radius,bfield,emcpos); okmom = track->GetOuterParam()->GetPxPyPzAt(radius,bfield,emcmom); if(!(okpos && okmom)) return; TVector3 position(emcpos[0],emcpos[1],emcpos[2]); TVector3 momentum(emcmom[0],emcmom[1],emcmom[2]); tphi = position.Phi(); teta = position.Eta(); tmom = momentum.Mag(); //Double_t tphi = track->GetOuterParam()->Phi(); //Double_t teta = track->GetOuterParam()->Eta(); //Double_t tmom = track->GetOuterParam()->P(); tpt = track->Pt(); tmom2 = track->P(); tpcSignal = track->GetTPCsignal(); nITS = track->GetNcls(0); nTPC = track->GetNcls(1); }//Outer param available //}// ESDs // else if(GetReader()->GetDataType()==AliCaloTrackReader::kAOD) { // AliAODPid* pid = (AliAODPid*) ((AliAODTrack *) track)->GetDetPid(); // if (pid) { // okout = kTRUE; // pid->GetEMCALPosition(emcpos); // pid->GetEMCALMomentum(emcmom); // // TVector3 position(emcpos[0],emcpos[1],emcpos[2]); // TVector3 momentum(emcmom[0],emcmom[1],emcmom[2]); // tphi = position.Phi(); // teta = position.Eta(); // tmom = momentum.Mag(); // // tpt = ((AliAODTrack*)track)->Pt(); // tmom2 = ((AliAODTrack*)track)->P(); // tpcSignal = pid->GetTPCsignal(); // // //nITS = ((AliAODTrack*)track)->GetNcls(0); // //nTPC = ((AliAODTrack*)track)->GetNcls(1); // }//Outer param available // }//AODs // else return; //Do nothing case not implemented. if(okout){ Double_t deta = teta - eta; Double_t dphi = tphi - phi; if(dphi > TMath::Pi()) dphi -= 2*TMath::Pi(); if(dphi < -TMath::Pi()) dphi += 2*TMath::Pi(); Double_t dR = sqrt(dphi*dphi + deta*deta); Double_t pOverE = tmom/e; fh1pOverE->Fill(tpt, pOverE); if(dR < 0.02) fh1pOverER02->Fill(tpt,pOverE); fh1dR->Fill(dR); fh2MatchdEdx->Fill(tmom2,tpcSignal); if(IsDataMC() && primary){ Int_t pdg = primary->GetPdgCode(); Double_t charge = TDatabasePDG::Instance()->GetParticle(pdg)->Charge(); if(TMath::Abs(pdg) == 11){ fhMCEle1pOverE->Fill(tpt,pOverE); fhMCEle1dR->Fill(dR); fhMCEle2MatchdEdx->Fill(tmom2,tpcSignal); if(dR < 0.02) fhMCEle1pOverER02->Fill(tpt,pOverE); } else if(charge!=0){ fhMCChHad1pOverE->Fill(tpt,pOverE); fhMCChHad1dR->Fill(dR); fhMCChHad2MatchdEdx->Fill(tmom2,tpcSignal); if(dR < 0.02) fhMCChHad1pOverER02->Fill(tpt,pOverE); } else if(charge == 0){ fhMCNeutral1pOverE->Fill(tpt,pOverE); fhMCNeutral1dR->Fill(dR); fhMCNeutral2MatchdEdx->Fill(tmom2,tpcSignal); if(dR < 0.02) fhMCNeutral1pOverER02->Fill(tpt,pOverE); } }//DataMC if(dR < 0.02 && pOverE > 0.5 && pOverE < 1.5 && nCaloCellsPerCluster > 1 && nITS > 3 && nTPC > 20) { fh2EledEdx->Fill(tmom2,tpcSignal); } } else{//no ESD external param or AODPid // ULong_t status=AliESDtrack::kTPCrefit; // status|=AliESDtrack::kITSrefit; //printf("track status %d\n", track->GetStatus() ); // fhEChargedNoOut ->Fill(e); // fhPtChargedNoOut ->Fill(pt); // fhPhiChargedNoOut ->Fill(phi); // fhEtaChargedNoOut ->Fill(eta); // fhEtaPhiChargedNoOut ->Fill(eta,phi); // if(GetDebug() >= 0 && ((track->GetStatus() & status) == status)) printf("ITS+TPC\n"); if(GetDebug() >= 0) printf("No ESD external param or AliAODPid \n"); }//No out params }//matched clusters with tracks }// Clusters //__________________________________ void AliAnaCalorimeterQA::Correlate(){ // Correlate information from PHOS and EMCAL and with V0 and track multiplicity //Clusters TObjArray * caloClustersEMCAL = GetAODEMCAL(); TObjArray * caloClustersPHOS = GetAODPHOS(); Int_t nclEMCAL = caloClustersEMCAL->GetEntriesFast(); Int_t nclPHOS = caloClustersPHOS ->GetEntriesFast(); Float_t sumClusterEnergyEMCAL = 0; Float_t sumClusterEnergyPHOS = 0; Int_t iclus = 0; for(iclus = 0 ; iclus < caloClustersEMCAL->GetEntriesFast() ; iclus++) sumClusterEnergyEMCAL += ((AliVCluster*)caloClustersEMCAL->At(iclus))->E(); for(iclus = 0 ; iclus < caloClustersPHOS->GetEntriesFast(); iclus++) sumClusterEnergyPHOS += ((AliVCluster*)caloClustersPHOS->At(iclus))->E(); //Cells AliVCaloCells * cellsEMCAL = GetEMCALCells(); AliVCaloCells * cellsPHOS = GetPHOSCells(); Int_t ncellsEMCAL = cellsEMCAL->GetNumberOfCells(); Int_t ncellsPHOS = cellsPHOS ->GetNumberOfCells(); Float_t sumCellEnergyEMCAL = 0; Float_t sumCellEnergyPHOS = 0; Int_t icell = 0; for(icell = 0 ; icell < cellsEMCAL->GetNumberOfCells() ; icell++) sumCellEnergyEMCAL += cellsEMCAL->GetAmplitude(icell); for(icell = 0 ; icell < cellsPHOS->GetNumberOfCells(); icell++) sumCellEnergyPHOS += cellsPHOS->GetAmplitude(icell); //Fill Histograms fhCaloCorrNClusters->Fill(nclEMCAL,nclPHOS); fhCaloCorrEClusters->Fill(sumClusterEnergyEMCAL,sumClusterEnergyPHOS); fhCaloCorrNCells ->Fill(ncellsEMCAL,ncellsPHOS); fhCaloCorrECells ->Fill(sumCellEnergyEMCAL,sumCellEnergyPHOS); Int_t v0S = GetV0Signal(0)+GetV0Signal(1); Int_t v0M = GetV0Multiplicity(0)+GetV0Multiplicity(1); Int_t trM = GetTrackMultiplicity(); if(fCalorimeter=="PHOS"){ fhCaloV0MCorrNClusters ->Fill(v0M,nclPHOS); fhCaloV0MCorrEClusters ->Fill(v0M,sumClusterEnergyPHOS); fhCaloV0MCorrNCells ->Fill(v0M,ncellsPHOS); fhCaloV0MCorrECells ->Fill(v0M,sumCellEnergyPHOS); fhCaloV0SCorrNClusters ->Fill(v0S,nclPHOS); fhCaloV0SCorrEClusters ->Fill(v0S,sumClusterEnergyPHOS); fhCaloV0SCorrNCells ->Fill(v0S,ncellsPHOS); fhCaloV0SCorrECells ->Fill(v0S,sumCellEnergyPHOS); fhCaloTrackMCorrNClusters->Fill(trM,nclPHOS); fhCaloTrackMCorrEClusters->Fill(trM,sumClusterEnergyPHOS); fhCaloTrackMCorrNCells ->Fill(trM,ncellsPHOS); fhCaloTrackMCorrECells ->Fill(trM,sumCellEnergyPHOS); } else{ fhCaloV0MCorrNClusters ->Fill(v0M,nclEMCAL); fhCaloV0MCorrEClusters ->Fill(v0M,sumClusterEnergyEMCAL); fhCaloV0MCorrNCells ->Fill(v0M,ncellsEMCAL); fhCaloV0MCorrECells ->Fill(v0M,sumCellEnergyEMCAL); fhCaloV0SCorrNClusters ->Fill(v0S,nclEMCAL); fhCaloV0SCorrEClusters ->Fill(v0S,sumClusterEnergyEMCAL); fhCaloV0SCorrNCells ->Fill(v0S,ncellsEMCAL); fhCaloV0SCorrECells ->Fill(v0S,sumCellEnergyEMCAL); fhCaloTrackMCorrNClusters->Fill(trM,nclEMCAL); fhCaloTrackMCorrEClusters->Fill(trM,sumClusterEnergyEMCAL); fhCaloTrackMCorrNCells ->Fill(trM,ncellsEMCAL); fhCaloTrackMCorrECells ->Fill(trM,sumCellEnergyEMCAL); } if(GetDebug() > 0 ) { printf("AliAnaCalorimeterQA::Correlate(): \n"); printf("\t EMCAL: N cells %d, N clusters %d, summed E cells %f, summed E clusters %f \n", ncellsEMCAL,nclEMCAL, sumCellEnergyEMCAL,sumClusterEnergyEMCAL); printf("\t PHOS : N cells %d, N clusters %d, summed E cells %f, summed E clusters %f \n", ncellsPHOS,nclPHOS,sumCellEnergyPHOS,sumClusterEnergyPHOS); printf("\t V0 : Signal %d, Multiplicity %d, Track Multiplicity %d \n", v0S,v0M,trM); } } //______________________________________________________________________________ void AliAnaCalorimeterQA::MCHistograms(const TLorentzVector mom, const Int_t pdg){ //Fill pure monte carlo related histograms Float_t eMC = mom.E(); Float_t ptMC = mom.Pt(); Float_t phiMC = mom.Phi(); if(phiMC < 0) phiMC += TMath::TwoPi(); Float_t etaMC = mom.Eta(); if (TMath::Abs(etaMC) > 1) return; Bool_t in = kTRUE; if(IsFiducialCutOn()) in = GetFiducialCut()->IsInFiducialCut(mom,fCalorimeter) ; if (pdg==22) { fhGenGamPt ->Fill(ptMC); fhGenGamEta->Fill(etaMC); fhGenGamPhi->Fill(phiMC); if(in){ fhGenGamAccE ->Fill(eMC); fhGenGamAccPt ->Fill(ptMC); fhGenGamAccEta->Fill(etaMC); fhGenGamAccPhi->Fill(phiMC); } } else if (pdg==111) { fhGenPi0Pt ->Fill(ptMC); fhGenPi0Eta->Fill(etaMC); fhGenPi0Phi->Fill(phiMC); if(in){ fhGenPi0AccE ->Fill(eMC); fhGenPi0AccPt ->Fill(ptMC); fhGenPi0AccEta->Fill(etaMC); fhGenPi0AccPhi->Fill(phiMC); } } else if (pdg==221) { fhGenEtaPt ->Fill(ptMC); fhGenEtaEta->Fill(etaMC); fhGenEtaPhi->Fill(phiMC); } else if (pdg==223) { fhGenOmegaPt ->Fill(ptMC); fhGenOmegaEta->Fill(etaMC); fhGenOmegaPhi->Fill(phiMC); } else if (TMath::Abs(pdg)==11) { fhGenElePt ->Fill(ptMC); fhGenEleEta->Fill(etaMC); fhGenElePhi->Fill(phiMC); } } //________________________________________________________________________ void AliAnaCalorimeterQA::ReadHistograms(TList* outputList) { // Needed when Terminate is executed in distributed environment // Refill analysis histograms of this class with corresponding histograms in output list. // Histograms of this analsys are kept in the same list as other analysis, recover the position of // the first one and then add the next Int_t index = outputList->IndexOf(outputList->FindObject(GetAddedHistogramsStringToName()+"hE")); //printf("Calo: %s, index: %d, nmodules %d\n",fCalorimeter.Data(),index,fNModules); //Read histograms, must be in the same order as in GetCreateOutputObject. fhE = (TH1F *) outputList->At(index++); if(fFillAllTH12){ fhPt = (TH1F *) outputList->At(index++); fhPhi = (TH1F *) outputList->At(index++); fhEta = (TH1F *) outputList->At(index++); } fhEtaPhiE = (TH3F *) outputList->At(index++); fhClusterTimeEnergy = (TH2F*) outputList->At(index++); fhLambda = (TH3F *) outputList->At(index++); fhDispersion = (TH2F *) outputList->At(index++); if(fFillAllTH12){ fhECharged = (TH1F *) outputList->At(index++); fhPtCharged = (TH1F *) outputList->At(index++); fhPhiCharged = (TH1F *) outputList->At(index++); fhEtaCharged = (TH1F *) outputList->At(index++); } fhEtaPhiECharged = (TH3F *) outputList->At(index++); fh1pOverE = (TH2F *) outputList->At(index++); fh1dR = (TH1F *) outputList->At(index++); fh2MatchdEdx = (TH2F *) outputList->At(index++); fh2EledEdx = (TH2F *) outputList->At(index++); fh1pOverER02 = (TH2F *) outputList->At(index++); fhIM = (TH2F *) outputList->At(index++); fhIMCellCut = (TH2F *) outputList->At(index++); fhAsym = (TH2F *) outputList->At(index++); fhNCellsPerCluster = (TH3F *) outputList->At(index++); fhNCellsPerClusterMIP = (TH3F *) outputList->At(index++); fhNCellsPerClusterMIPCharged = (TH3F *) outputList->At(index++); fhNClusters = (TH1F *) outputList->At(index++); fhRNCells = (TH2F *) outputList->At(index++); fhXNCells = (TH2F *) outputList->At(index++); fhYNCells = (TH2F *) outputList->At(index++); fhZNCells = (TH2F *) outputList->At(index++); fhRE = (TH2F *) outputList->At(index++); fhXE = (TH2F *) outputList->At(index++); fhYE = (TH2F *) outputList->At(index++); fhZE = (TH2F *) outputList->At(index++); fhXYZ = (TH3F *) outputList->At(index++); if(fFillAllPosHisto){ fhRCellE = (TH2F *) outputList->At(index++); fhXCellE = (TH2F *) outputList->At(index++); fhYCellE = (TH2F *) outputList->At(index++); fhZCellE = (TH2F *) outputList->At(index++); fhXYZCell = (TH3F *) outputList->At(index++); fhDeltaCellClusterRNCells = (TH2F *) outputList->At(index++); fhDeltaCellClusterXNCells = (TH2F *) outputList->At(index++); fhDeltaCellClusterYNCells = (TH2F *) outputList->At(index++); fhDeltaCellClusterZNCells = (TH2F *) outputList->At(index++); fhDeltaCellClusterRE = (TH2F *) outputList->At(index++); fhDeltaCellClusterXE = (TH2F *) outputList->At(index++); fhDeltaCellClusterYE = (TH2F *) outputList->At(index++); fhDeltaCellClusterZE = (TH2F *) outputList->At(index++); fhEtaPhiAmp = (TH3F *) outputList->At(index++); } fhNCells = (TH1F *) outputList->At(index++); fhAmplitude = (TH1F *) outputList->At(index++); fhAmpId = (TH2F *) outputList->At(index++); if(GetReader()->GetDataType()==AliCaloTrackReader::kESD) { fhCellTimeSpreadRespectToCellMax = (TH1F *) outputList->At(index++); fhCellIdCellLargeTimeSpread = (TH1F *) outputList->At(index++); fhTime = (TH1F *) outputList->At(index++); fhTimeId = (TH2F *) outputList->At(index++); fhTimeAmp = (TH2F *) outputList->At(index++); // fhT0Time = (TH1F *) outputList->At(index++); // fhT0TimeId = (TH2F *) outputList->At(index++); // fhT0TimeAmp = (TH2F *) outputList->At(index++); } if(fCorrelate){ fhCaloCorrNClusters = (TH2F *) outputList->At(index++); fhCaloCorrEClusters = (TH2F *) outputList->At(index++); fhCaloCorrNCells = (TH2F *) outputList->At(index++); fhCaloCorrECells = (TH2F *) outputList->At(index++); fhCaloV0SCorrNClusters = (TH2F *) outputList->At(index++); fhCaloV0SCorrEClusters = (TH2F *) outputList->At(index++); fhCaloV0SCorrNCells = (TH2F *) outputList->At(index++); fhCaloV0SCorrECells = (TH2F *) outputList->At(index++); fhCaloV0MCorrNClusters = (TH2F *) outputList->At(index++); fhCaloV0MCorrEClusters = (TH2F *) outputList->At(index++); fhCaloV0MCorrNCells = (TH2F *) outputList->At(index++); fhCaloV0MCorrECells = (TH2F *) outputList->At(index++); fhCaloTrackMCorrNClusters = (TH2F *) outputList->At(index++); fhCaloTrackMCorrEClusters = (TH2F *) outputList->At(index++); fhCaloTrackMCorrNCells = (TH2F *) outputList->At(index++); fhCaloTrackMCorrECells = (TH2F *) outputList->At(index++); } //Module histograms fhEMod = new TH1F*[fNModules]; fhNClustersMod = new TH1F*[fNModules]; fhNCellsPerClusterMod = new TH2F*[fNModules]; fhNCellsMod = new TH1F*[fNModules]; fhGridCellsMod = new TH2F*[fNModules]; fhGridCellsEMod = new TH2F*[fNModules]; if(GetReader()->GetDataType()==AliCaloTrackReader::kESD) fhGridCellsTimeMod = new TH2F*[fNModules]; fhAmplitudeMod = new TH1F*[fNModules]; if(fCalorimeter=="EMCAL") fhAmplitudeModFraction = new TH1F*[fNModules*3]; //EMCAL fhTimeAmpPerRCU = new TH2F*[fNModules*fNRCU]; fhIMMod = new TH2F*[fNModules]; fhIMCellCutMod = new TH2F*[fNModules]; for(Int_t imod = 0 ; imod < fNModules; imod++){ fhEMod[imod] = (TH1F *) outputList->At(index++); fhNClustersMod[imod] = (TH1F *) outputList->At(index++); fhNCellsPerClusterMod[imod] = (TH2F *) outputList->At(index++); fhNCellsMod[imod] = (TH1F *) outputList->At(index++); fhGridCellsMod[imod] = (TH2F *) outputList->At(index++); fhGridCellsEMod[imod] = (TH2F *) outputList->At(index++); if(GetReader()->GetDataType()==AliCaloTrackReader::kESD) fhGridCellsTimeMod[imod] = (TH2F *) outputList->At(index++); fhAmplitudeMod[imod] = (TH1F *) outputList->At(index++); if(fCalorimeter=="EMCAL"){ for(Int_t ifrac = 0; ifrac < 3; ifrac++){ fhAmplitudeModFraction[imod*3+ifrac] = (TH1F *) outputList->At(index++); } } for(Int_t ircu = 0; ircu < fNRCU; ircu++){ fhTimeAmpPerRCU[imod*fNRCU+ircu] = (TH2F *) outputList->At(index++); //fhT0TimeAmpPerRCU[imod*fNRCU+ircu] = (TH2F *) outputList->At(index++); // for(Int_t imod2 = 0; imod2 < fNModules; imod2++){ // for(Int_t ircu2 = 0; ircu2 < fNModules; ircu2++){ // fhTimeCorrRCU[imod*fNRCU+ircu+imod2*fNRCU+ircu2] = (TH2F *) outputList->At(index++); // } // } } fhIMMod[imod] = (TH2F *) outputList->At(index++); fhIMCellCutMod[imod] = (TH2F *) outputList->At(index++); } if(IsDataMC()){ fhDeltaE = (TH1F *) outputList->At(index++); fhDeltaPt = (TH1F *) outputList->At(index++); fhDeltaPhi = (TH1F *) outputList->At(index++); fhDeltaEta = (TH1F *) outputList->At(index++); fhRatioE = (TH1F *) outputList->At(index++); fhRatioPt = (TH1F *) outputList->At(index++); fhRatioPhi = (TH1F *) outputList->At(index++); fhRatioEta = (TH1F *) outputList->At(index++); fh2E = (TH2F *) outputList->At(index++); fh2Pt = (TH2F *) outputList->At(index++); fh2Phi = (TH2F *) outputList->At(index++); fh2Eta = (TH2F *) outputList->At(index++); fhGamE = (TH2F *) outputList->At(index++); fhGamPt = (TH2F *) outputList->At(index++); fhGamPhi = (TH2F *) outputList->At(index++); fhGamEta = (TH2F *) outputList->At(index++); fhGamDeltaE = (TH1F *) outputList->At(index++); fhGamDeltaPt = (TH1F *) outputList->At(index++); fhGamDeltaPhi = (TH1F *) outputList->At(index++); fhGamDeltaEta = (TH1F *) outputList->At(index++); fhGamRatioE = (TH1F *) outputList->At(index++); fhGamRatioPt = (TH1F *) outputList->At(index++); fhGamRatioPhi = (TH1F *) outputList->At(index++); fhGamRatioEta = (TH1F *) outputList->At(index++); fhPi0E = (TH2F *) outputList->At(index++); fhPi0Pt = (TH2F *) outputList->At(index++); fhPi0Phi = (TH2F *) outputList->At(index++); fhPi0Eta = (TH2F *) outputList->At(index++); fhEleE = (TH2F *) outputList->At(index++); fhElePt = (TH2F *) outputList->At(index++); fhElePhi = (TH2F *) outputList->At(index++); fhEleEta = (TH2F *) outputList->At(index++); fhNeHadE = (TH2F *) outputList->At(index++); fhNeHadPt = (TH2F *) outputList->At(index++); fhNeHadPhi = (TH2F *) outputList->At(index++); fhNeHadEta = (TH2F *) outputList->At(index++); fhChHadE = (TH2F *) outputList->At(index++); fhChHadPt = (TH2F *) outputList->At(index++); fhChHadPhi = (TH2F *) outputList->At(index++); fhChHadEta = (TH2F *) outputList->At(index++); fhGamECharged = (TH2F *) outputList->At(index++); fhGamPtCharged = (TH2F *) outputList->At(index++); fhGamPhiCharged = (TH2F *) outputList->At(index++); fhGamEtaCharged = (TH2F *) outputList->At(index++); fhPi0ECharged = (TH2F *) outputList->At(index++); fhPi0PtCharged = (TH2F *) outputList->At(index++); fhPi0PhiCharged = (TH2F *) outputList->At(index++); fhPi0EtaCharged = (TH2F *) outputList->At(index++); fhEleECharged = (TH2F *) outputList->At(index++); fhElePtCharged = (TH2F *) outputList->At(index++); fhElePhiCharged = (TH2F *) outputList->At(index++); fhEleEtaCharged = (TH2F *) outputList->At(index++); fhNeHadECharged = (TH2F *) outputList->At(index++); fhNeHadPtCharged = (TH2F *) outputList->At(index++); fhNeHadPhiCharged = (TH2F *) outputList->At(index++); fhNeHadEtaCharged = (TH2F *) outputList->At(index++); fhChHadECharged = (TH2F *) outputList->At(index++); fhChHadPtCharged = (TH2F *) outputList->At(index++); fhChHadPhiCharged = (TH2F *) outputList->At(index++); fhChHadEtaCharged = (TH2F *) outputList->At(index++); // fhEMVxyz = (TH3F *) outputList->At(index++); // fhHaVxyz = (TH3F *) outputList->At(index++); fhEMVxyz = (TH2F *) outputList->At(index++); fhHaVxyz = (TH2F *) outputList->At(index++); fhEMR = (TH2F *) outputList->At(index++); fhHaR = (TH2F *) outputList->At(index++); fhGenGamPt = (TH1F *) outputList->At(index++); fhGenGamEta = (TH1F *) outputList->At(index++); fhGenGamPhi = (TH1F *) outputList->At(index++); fhGenPi0Pt = (TH1F *) outputList->At(index++); fhGenPi0Eta = (TH1F *) outputList->At(index++); fhGenPi0Phi = (TH1F *) outputList->At(index++); fhGenEtaPt = (TH1F *) outputList->At(index++); fhGenEtaEta = (TH1F *) outputList->At(index++); fhGenEtaPhi = (TH1F *) outputList->At(index++); fhGenOmegaPt = (TH1F *) outputList->At(index++); fhGenOmegaEta = (TH1F *) outputList->At(index++); fhGenOmegaPhi = (TH1F *) outputList->At(index++); fhGenElePt = (TH1F *) outputList->At(index++); fhGenEleEta = (TH1F *) outputList->At(index++); fhGenElePhi = (TH1F *) outputList->At(index++); fhGenGamAccE = (TH1F *) outputList->At(index++); fhGenGamAccPt = (TH1F *) outputList->At(index++); fhGenGamAccEta = (TH1F *) outputList->At(index++); fhGenGamAccPhi = (TH1F *) outputList->At(index++); fhGenPi0AccE = (TH1F *) outputList->At(index++); fhGenPi0AccPt = (TH1F *) outputList->At(index++); fhGenPi0AccEta = (TH1F *) outputList->At(index++); fhGenPi0AccPhi = (TH1F *) outputList->At(index++); fhMCEle1pOverE = (TH2F *) outputList->At(index++); fhMCEle1dR = (TH1F *) outputList->At(index++); fhMCEle2MatchdEdx = (TH2F *) outputList->At(index++); fhMCChHad1pOverE = (TH2F *) outputList->At(index++); fhMCChHad1dR = (TH1F *) outputList->At(index++); fhMCChHad2MatchdEdx = (TH2F *) outputList->At(index++); fhMCNeutral1pOverE = (TH2F *) outputList->At(index++); fhMCNeutral1dR = (TH1F *) outputList->At(index++); fhMCNeutral2MatchdEdx = (TH2F *) outputList->At(index++); fhMCEle1pOverER02 = (TH2F *) outputList->At(index++); fhMCChHad1pOverER02 = (TH2F *) outputList->At(index++); fhMCNeutral1pOverER02 = (TH2F *) outputList->At(index++); } } //__________________________________________________________________ void AliAnaCalorimeterQA::Terminate(TList* outputList) { //Do plots if requested if(GetDebug() > 0) printf("AliAnaCalorimeterQA::Terminate() - Make plots for %s? %d\n",fCalorimeter.Data(), MakePlotsOn()); //Do some plots to end if(fStyleMacro!="")gROOT->Macro(fStyleMacro); //Recover histograms from output histograms list, needed for distributed analysis. ReadHistograms(outputList); //printf(" AliAnaCalorimeterQA::Terminate() *** %s Report:", GetName()) ; //printf(" AliAnaCalorimeterQA::Terminate() pt : %5.3f , RMS : %5.3f \n", fhPt->GetMean(), fhPt->GetRMS() ) ; const Int_t buffersize = 255; char name[buffersize]; char cname[buffersize]; //In case terminate is executed after the analysis, in a second step, and we want to rebin or to change the range of the histograms for plotting Int_t nptbins = GetHistoPtBins(); Float_t ptmax = GetHistoPtMax(); Float_t ptmin = GetHistoPtMin(); Int_t nphibins = GetHistoPhiBins(); Float_t phimax = GetHistoPhiMax(); Float_t phimin = GetHistoPhiMin(); Int_t netabins = GetHistoEtaBins(); Float_t etamax = GetHistoEtaMax(); Float_t etamin = GetHistoEtaMin(); // Int_t nmassbins = GetHistoMassBins(); Float_t massmax = GetHistoMassMax(); Float_t massmin = GetHistoMassMin(); // Int_t nasymbins = GetHistoAsymmetryBins(); Float_t asymmax = GetHistoAsymmetryMax(); Float_t asymmin = GetHistoAsymmetryMin(); // Int_t nPoverEbins = GetHistoPOverEBins(); Float_t pOverEmax = GetHistoPOverEMax(); Float_t pOverEmin = GetHistoPOverEMin(); // Int_t ndedxbins = GetHistodEdxBins(); Float_t dedxmax = GetHistodEdxMax(); Float_t dedxmin = GetHistodEdxMin(); // Int_t ndRbins = GetHistodRBins(); Float_t dRmax = GetHistodRMax(); Float_t dRmin = GetHistodRMin(); Int_t ntimebins = GetHistoTimeBins(); Float_t timemax = GetHistoTimeMax(); Float_t timemin = GetHistoTimeMin(); Int_t nbins = GetHistoNClusterCellBins(); Int_t nmax = GetHistoNClusterCellMax(); Int_t nmin = GetHistoNClusterCellMin(); // Int_t nratiobins = GetHistoRatioBins(); Float_t ratiomax = GetHistoRatioMax(); Float_t ratiomin = GetHistoRatioMin(); // Int_t nvdistbins = GetHistoVertexDistBins(); Float_t vdistmax = GetHistoVertexDistMax(); Float_t vdistmin = GetHistoVertexDistMin(); Int_t rbins = GetHistoRBins(); Float_t rmax = GetHistoRMax(); Float_t rmin = GetHistoRMin(); Int_t xbins = GetHistoXBins(); Float_t xmax = GetHistoXMax(); Float_t xmin = GetHistoXMin(); Int_t ybins = GetHistoYBins(); Float_t ymax = GetHistoYMax(); Float_t ymin = GetHistoYMin(); Int_t zbins = GetHistoZBins(); Float_t zmax = GetHistoZMax(); Float_t zmin = GetHistoZMin(); //Color code for the different modules Int_t modColorIndex[]={2,4,6,8}; //-------------------------------------------------- // Cluster energy distributions, module dependence //-------------------------------------------------- snprintf(cname,buffersize,"QA_%s_ClusterEnergy",fCalorimeter.Data()); TCanvas * c = new TCanvas(cname, "Energy distributions", 800, 400) ; c->Divide(2, 1); Int_t rbE = GetNewRebinForRePlotting((TH1D*)fhE, ptmin, ptmax,nptbins) ; //printf("new E rb %d\n",rbE); fhE->Rebin(rbE); fhE->SetAxisRange(ptmin,ptmax,"X"); c->cd(1) ; if(fhE->GetEntries() > 0) gPad->SetLogy(); TLegend pLegendE(0.7,0.6,0.9,0.8); pLegendE.SetTextSize(0.03); pLegendE.AddEntry(fhE,"all modules","L"); pLegendE.SetFillColor(10); pLegendE.SetBorderSize(1); fhE->SetMinimum(1); fhE->SetLineColor(1); fhE->Draw("HE"); for(Int_t imod = 0; imod < fNModules; imod++){ fhEMod[imod]->Rebin(rbE); fhEMod[imod]->SetLineColor(modColorIndex[imod]); fhEMod[imod]->Draw("HE same"); pLegendE.AddEntry(fhEMod[imod],Form("module %d",imod),"L"); } pLegendE.Draw(); //Ratio of modules c->cd(2) ; TLegend pLegendER(0.55,0.8,0.9,0.9); pLegendER.SetTextSize(0.03); pLegendER.SetFillColor(10); pLegendER.SetBorderSize(1); for(Int_t imod = 1; imod < fNModules; imod++){ TH1D * htmp = (TH1D*)fhEMod[imod]->Clone(Form("hERat%d",imod)); htmp->Divide(fhEMod[0]); htmp->SetLineColor(modColorIndex[imod]); if(imod==1){ htmp->SetTitle("Ratio module X / module 0"); htmp->SetAxisRange(ptmin,ptmax,"X"); htmp->SetMaximum(5); htmp->SetMinimum(0); htmp->SetAxisRange(ptmin,ptmax,"X"); htmp->Draw("HE"); } else htmp->Draw("same HE"); pLegendER.AddEntry(fhEMod[imod],Form("module %d / module 0",imod),"L"); } pLegendER.Draw(); snprintf(name,buffersize,"QA_%s_ClusterEnergy.eps",fCalorimeter.Data()); c->Print(name); printf("Plot: %s\n",name); //-------------------------------------------------- // Cell energy distributions, module dependence //-------------------------------------------------- snprintf(cname,buffersize,"%s_QA_CellEnergy",fCalorimeter.Data()); TCanvas * ca = new TCanvas(cname, "Cell Energy distributions", 800, 400) ; ca->Divide(2, 1); Int_t rbAmp = GetNewRebinForRePlotting((TH1D*)fhAmplitude, ptmin, ptmax,nptbins*2) ; //printf("new Amp rb %d\n",rbAmp); fhAmplitude->Rebin(rbAmp); fhAmplitude->SetAxisRange(ptmin,ptmax,"X"); ca->cd(1) ; if(fhAmplitude->GetEntries() > 0) gPad->SetLogy(); TLegend pLegendA(0.7,0.6,0.9,0.8); pLegendA.SetTextSize(0.03); pLegendA.AddEntry(fhE,"all modules","L"); pLegendA.SetFillColor(10); pLegendA.SetBorderSize(1); fhAmplitude->SetMinimum(0.1); fhAmplitude->SetLineColor(1); fhAmplitude->Draw("HE"); for(Int_t imod = 0; imod < fNModules; imod++){ fhAmplitudeMod[imod]->Rebin(rbAmp); fhAmplitudeMod[imod]->SetLineColor(modColorIndex[imod]); fhAmplitudeMod[imod]->Draw("HE same"); pLegendA.AddEntry(fhAmplitudeMod[imod],Form("module %d",imod),"L"); } pLegendA.Draw(); ca->cd(2) ; TLegend pLegendAR(0.55,0.8,0.9,0.9); pLegendAR.SetTextSize(0.03); pLegendAR.SetFillColor(10); pLegendAR.SetBorderSize(1); for(Int_t imod = 1; imod < fNModules; imod++){ TH1D * htmp = (TH1D*)fhAmplitudeMod[imod]->Clone(Form("hAmpRat%d",imod)); htmp->Divide(fhAmplitudeMod[0]); htmp->SetLineColor(modColorIndex[imod]); if(imod==1){ htmp->SetTitle("Ratio cells energy in module X / module 0"); htmp->SetAxisRange(ptmin,ptmax,"X"); htmp->SetMaximum(5); htmp->SetMinimum(0); htmp->Draw("HE"); } else htmp->Draw("same HE"); pLegendAR.AddEntry(fhAmplitudeMod[imod],Form("module %d",imod),"L"); } pLegendAR.Draw(); snprintf(name,buffersize,"QA_%s_CellEnergy.eps",fCalorimeter.Data()); ca->Print(name); printf("Plot: %s\n",name); //---------------------------------------------------------- // Cell energy distributions, FRACTION of module dependence // See Super Module calibration difference //--------------------------------------------------------- if(fCalorimeter=="EMCAL"){ //Close To Eta 0 snprintf(cname,buffersize,"%s_QA_SMThirds",fCalorimeter.Data()); TCanvas * cfrac = new TCanvas(cname, "SM Thirds ratios", 800, 1200) ; cfrac->Divide(2, 3); cfrac->cd(1) ; if(fhAmplitude->GetEntries() > 0) gPad->SetLogy(); TLegend pLegend1(0.6,0.6,0.9,0.8); pLegend1.SetTextSize(0.03); pLegend1.SetFillColor(10); pLegend1.SetBorderSize(1); pLegend1.SetHeader("Third close to Eta=0"); fhAmplitudeModFraction[0]->SetTitle("Third close to Eta=0"); fhAmplitudeModFraction[0]->SetAxisRange(ptmin,ptmax,"X"); fhAmplitudeModFraction[0]->Draw("axis"); TH1D * hAverageThird1 = (TH1D *)fhAmplitudeModFraction[3*0+2]->Clone("AverageThird1"); for(Int_t imod = 0; imod < fNModules; imod++){ Int_t ifrac = 0; if(imod%2==0) ifrac = 2; if(imod > 0) hAverageThird1->Add( fhAmplitudeModFraction[3*imod+ifrac]); fhAmplitudeModFraction[3*imod+ifrac]->SetLineColor(modColorIndex[imod]); fhAmplitudeModFraction[3*imod+ifrac]->Draw("HE same"); pLegend1.AddEntry(fhAmplitudeModFraction[3*imod+ifrac],Form("super module %d",imod),"L"); } hAverageThird1 ->Scale(1./fNModules); pLegend1.Draw(); //Ratio cfrac->cd(2) ; for(Int_t imod = 0; imod < fNModules; imod++){ Int_t ifrac = 0; if(imod%2==0) ifrac = 2; TH1D * htmp = (TH1D*)fhAmplitudeModFraction[3*imod+ifrac]->Clone(Form("ThirdFractionAverage_%d_%d",imod,ifrac)); htmp->Divide(hAverageThird1); if(imod ==0) { htmp ->SetTitle("Close to eta = 0"); htmp ->SetMaximum(5); htmp ->SetMinimum(0); htmp ->SetAxisRange(ptmin,ptmax,"X"); htmp ->SetYTitle("ratio third to average"); htmp -> Draw("HE"); } else htmp -> Draw("same HE"); } //pLegend1.Draw(); //Middle Eta cfrac->cd(3) ; if(fhAmplitude->GetEntries() > 0) gPad->SetLogy(); TLegend pLegend2(0.6,0.6,0.9,0.8); pLegend2.SetTextSize(0.03); pLegend2.SetFillColor(10); pLegend2.SetBorderSize(1); pLegend2.SetHeader("Middle Third"); fhAmplitudeModFraction[0]->SetTitle("Middle Third"); fhAmplitudeModFraction[0]->SetAxisRange(ptmin,ptmax,"X"); fhAmplitudeModFraction[0]->Draw("axis"); TH1D * hAverageThird2 = (TH1D *)fhAmplitudeModFraction[3*0+1]->Clone("AverageThird2"); for(Int_t imod = 0; imod < fNModules; imod++){ Int_t ifrac = 1; if(imod > 0) hAverageThird2->Add( fhAmplitudeModFraction[3*imod+ifrac]); fhAmplitudeModFraction[3*imod+ifrac]->SetLineColor(modColorIndex[imod]); fhAmplitudeModFraction[3*imod+ifrac]->Draw("HE same"); pLegend2.AddEntry(fhAmplitudeModFraction[3*imod+ifrac],Form("super module %d",imod),"L"); } hAverageThird2->Scale(1./fNModules); pLegend2.Draw(); //Ratio cfrac->cd(4) ; for(Int_t imod = 0; imod < fNModules; imod++){ Int_t ifrac = 1; TH1D * htmp = (TH1D*)fhAmplitudeModFraction[3*imod+ifrac]->Clone(Form("ThirdFractionAverage_%d_%d",imod,ifrac)); htmp->Divide(hAverageThird2); if(imod ==0) { htmp ->SetTitle("Middle"); htmp ->SetMaximum(5); htmp ->SetMinimum(0); htmp ->SetAxisRange(ptmin,ptmax,"X"); htmp ->SetYTitle("ratio third to average"); htmp -> Draw("HE"); } else htmp -> Draw("same HE"); } //pLegend2.Draw(); //Close To Eta 0.7 cfrac->cd(5) ; if(fhAmplitude->GetEntries() > 0) gPad->SetLogy(); TLegend pLegend3(0.6,0.6,0.9,0.8); pLegend3.SetTextSize(0.03); pLegend3.SetFillColor(10); pLegend3.SetBorderSize(1); pLegend3.SetHeader("Third close to Eta=0.7"); fhAmplitudeModFraction[0]->SetTitle("Third close to Eta=0.7"); fhAmplitudeModFraction[0]->SetAxisRange(ptmin,ptmax,"X"); fhAmplitudeModFraction[0]->Draw("axis"); TH1D * hAverageThird3 = (TH1D *)fhAmplitudeModFraction[3*0+0]->Clone("AverageThird3"); for(Int_t imod = 0; imod < 4; imod++){ Int_t ifrac = 2; if(imod%2==0) ifrac = 0; if(imod > 0) hAverageThird3->Add( fhAmplitudeModFraction[3*imod+ifrac]); fhAmplitudeModFraction[3*imod+ifrac]->SetLineColor(modColorIndex[imod]); fhAmplitudeModFraction[3*imod+ifrac]->Draw("HE same"); pLegend3.AddEntry(fhAmplitudeModFraction[3*imod+ifrac],Form("super module %d",imod),"L"); } hAverageThird3 ->Scale(1./fNModules); pLegend3.Draw(); cfrac->cd(6) ; for(Int_t imod = 0; imod < fNModules; imod++){ Int_t ifrac = 2; if(imod%2==0) ifrac = 0; TH1D * htmp = (TH1D*)fhAmplitudeModFraction[3*imod+ifrac]->Clone(Form("ThirdFractionAverage_%d_%d",imod,ifrac)); htmp->Divide(hAverageThird3); if(imod ==0) { htmp ->SetTitle("Close to eta = 0.7"); htmp ->SetMaximum(5); htmp ->SetMinimum(0); htmp ->SetAxisRange(ptmin,ptmax,"X"); htmp ->SetYTitle("ratio third to average"); htmp ->Draw("HE"); } else htmp ->Draw("same HE"); } //pLegend3.Draw(); snprintf(name,buffersize,"QA_%s_CellEnergyModuleFraction.eps",fCalorimeter.Data()); cfrac->Print(name); printf("Create plot %s\n",name); }//EMCAL //---------------------------------------------------------- // Cluster eta and phi distributions, energy cut dependence //--------------------------------------------------------- snprintf(cname,buffersize,"%s_QA_EtaPhiCluster",fCalorimeter.Data()); TCanvas * cetaphic = new TCanvas(cname, "Eta-Phi Reconstructed distributions", 1200, 400) ; cetaphic->Divide(3, 1); Int_t binmin = 0; Int_t rbPhi = 1; Int_t rbEta = 1; Int_t ncuts = 7; Float_t ecut[] = {0.1, 0.3, 0.5, 0.7, 0.9, 1.1, 1.3}; Int_t ecutcolor[]= {2, 4, 6, 7, 8, 9, 12}; TH1D * hE = fhEtaPhiE->ProjectionZ(); //PHI cetaphic->cd(1) ; gPad->SetLogy(); gPad->SetGridy(); TLegend pLegendPhiCl(0.83,0.6,0.95,0.93); pLegendPhiCl.SetTextSize(0.03); pLegendPhiCl.SetFillColor(10); pLegendPhiCl.SetBorderSize(1); TH1D * htmp = fhEtaPhiE->ProjectionY("hphi_cluster_nocut",0,-1,0,-1); if(htmp){ htmp->SetMinimum(1); rbPhi = GetNewRebinForRePlotting(htmp, phimin, phimax,nphibins) ; //printf("new Phi rb %d\n",rbPhi); htmp->Rebin(rbPhi); htmp->SetTitle("#phi of clusters for energy in cluster > threshold"); htmp->SetAxisRange(phimin,phimax,"X"); htmp->Draw("HE"); pLegendPhiCl.AddEntry(htmp,"No cut","L"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhEtaPhiE->ProjectionY(Form("hphi_cluster_cut%d",i),0,-1,binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbPhi); htmp->Draw("same HE"); pLegendPhiCl.AddEntry(htmp,Form("E>%1.1f",ecut[i]),"L"); } } pLegendPhiCl.Draw(); //ETA cetaphic->cd(2) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhEtaPhiE->ProjectionX("heta_cluster_nocut",0,-1,0,-1); if(htmp){ rbEta = GetNewRebinForRePlotting(htmp,etamin, etamax,netabins) ; //printf("new Eta rb %d\n",rbEta); htmp->Rebin(rbEta); htmp->SetMinimum(1); htmp ->SetLineColor(1); htmp->SetTitle("#eta of clusters for energy in cluster > threshold"); htmp->SetAxisRange(etamin,etamax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhEtaPhiE->ProjectionX(Form("heta_cluster_cut%d",i),0,-1,binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbEta); htmp->Draw("same HE"); } } //ETA vs PHI cetaphic->cd(3) ; TH2D* hEtaPhiCl = (TH2D*) fhEtaPhiE->Project3D("xy"); hEtaPhiCl->SetAxisRange(etamin,etamax,"X"); hEtaPhiCl->SetAxisRange(phimin,phimax,"Y"); hEtaPhiCl->Draw("colz"); snprintf(name,buffersize,"QA_%s_ClusterEtaPhi.eps",fCalorimeter.Data()); cetaphic->Print(name); printf("Create plot %s\n",name); //---------------------------------------------------------- // Cell eta and phi distributions, energy cut dependence //--------------------------------------------------------- snprintf(cname,buffersize,"%s_QA_EtaPhiCell",fCalorimeter.Data()); TCanvas * cetaphicell = new TCanvas(cname, "Eta-Phi Cells distributions", 1200, 400) ; cetaphicell->Divide(3, 1); //PHI cetaphicell->cd(1) ; gPad->SetLogy(); gPad->SetGridy(); TLegend pLegendPhiCell(0.83,0.6,0.95,0.93); pLegendPhiCell.SetTextSize(0.03); pLegendPhiCell.SetFillColor(10); pLegendPhiCell.SetBorderSize(1); delete htmp; htmp = fhEtaPhiAmp->ProjectionY("hphi_cell_nocut",0,-1,0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbPhi); htmp->SetTitle("#phi of cells for cell energy > threshold"); htmp->SetAxisRange(phimin,phimax,"X"); htmp->Draw("HE"); pLegendPhiCell.AddEntry(htmp,"No cut","L"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhEtaPhiAmp->ProjectionY(Form("hphi_cell_cut%d",i),0,-1,binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbPhi); htmp->Draw("same HE"); pLegendPhiCl.AddEntry(htmp,Form("E>%1.1f",ecut[i]),"L"); } } pLegendPhiCell.Draw(); //ETA cetaphicell->cd(2) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhEtaPhiAmp->ProjectionX("heta_cell_nocut",0,-1,0,-1); if(htmp){ htmp ->SetLineColor(1); htmp->Rebin(rbEta); htmp->SetMinimum(1); htmp->SetTitle("#eta of cells for cell energy > threshold"); htmp->SetAxisRange(etamin,etamax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhEtaPhiAmp->ProjectionX(Form("heta_cell_cut%d",i),0,-1,binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbEta); htmp->Draw("same HE"); } } //ETA vs PHI cetaphicell->cd(3) ; TH2D* hEtaPhiCell = (TH2D*) fhEtaPhiAmp->Project3D("xy"); hEtaPhiCell->SetAxisRange(etamin,etamax,"X"); hEtaPhiCell->SetAxisRange(phimin,phimax,"Y"); hEtaPhiCell->Draw("colz"); snprintf(name,buffersize,"QA_%s_CellEtaPhi.eps",fCalorimeter.Data()); cetaphicell->Print(name); printf("Create plot %s\n",name); //////////////////////////////////////// ///////// Global Positions ///////////// //////////////////////////////////////// //CLUSTERS Int_t rbX = 1; Int_t rbY = 1; Int_t rbZ = 1; if(fFillAllPosHisto) { snprintf(cname,buffersize,"%s_QA_ClusterXY",fCalorimeter.Data()); TCanvas * cxyz = new TCanvas(cname, "Cluster XY distributions", 1200, 400) ; cxyz->Divide(3, 1); cxyz->cd(1) ; TH2D * hXY = (TH2D*) fhXYZ->Project3D("yx" ); hXY->SetTitle("Cluster X vs Y"); hXY->GetYaxis()->SetTitleOffset(1.6); hXY->Draw("colz"); cxyz->cd(2) ; TH2D * hYZ = (TH2D*) fhXYZ->Project3D("yz" ); hYZ->SetTitle("Cluster Z vs Y"); hYZ->GetYaxis()->SetTitleOffset(1.6); hYZ->Draw("colz"); cxyz->cd(3) ; TH2D * hXZ = (TH2D*) fhXYZ->Project3D("zx" ); hXZ->SetTitle("Cluster X vs Z"); hXZ->GetYaxis()->SetTitleOffset(1.6); hXZ->Draw("colz"); snprintf(name,buffersize,"QA_%s_ClusterXY_YZ_XZ.eps",fCalorimeter.Data()); cxyz->Print(name); printf("Create plot %s\n",name); snprintf(cname,buffersize,"QA_%s_ClusterX",fCalorimeter.Data()); TCanvas * cx = new TCanvas(cname, "Cluster X distributions", 1200, 400) ; cx->Divide(3, 1); cx->cd(1) ; TH1D * hX = (TH1D*) fhXYZ->Project3D("xe" ); //gPad->SetLogy(); gPad->SetGridy(); hX->SetTitle("Cluster X "); hX->Draw("HE"); rbX = GetNewRebinForRePlotting(hX, xmin, xmax,xbins) ; //printf("new X rb %d\n",rbX); hX->Rebin(rbX); hX->SetMinimum(hX->GetMaximum()/2); hX->SetAxisRange(xmin,xmax); cx->cd(2) ; TH1D * hY = (TH1D*) fhXYZ->Project3D("ye" ); //gPad->SetLogy(); hY->SetTitle("Cluster Y "); rbY = GetNewRebinForRePlotting(hY, ymin, ymax, ybins) ; //printf("new Y rb %d\n",rbY); hY->Rebin(rbY); hY->SetMinimum(1); hY->SetAxisRange(ymin,ymax); hY->Draw("HE"); cx->cd(3) ; TH1D * hZ = (TH1D*) fhXYZ->Project3D("ze" ); //gPad->SetLogy(); gPad->SetGridy(); rbZ = GetNewRebinForRePlotting(hZ,zmin, zmax,zbins) ; //printf("new Z rb %d\n",rbZ); hZ->Rebin(rbZ); hZ->SetMinimum(hZ->GetMaximum()/2); hZ->SetAxisRange(zmin,zmax); hZ->Draw("HE"); snprintf(name,buffersize,"QA_%s_ClusterX_Y_Z.eps",fCalorimeter.Data()); cx->Print(name); printf("Create plot %s\n",name); } //CELLS if(fFillAllPosHisto) { snprintf(cname,buffersize,"%s_QA_CellXY",fCalorimeter.Data()); TCanvas * cellxyz = new TCanvas(cname, "Cell XY distributions", 1200, 400) ; cellxyz->Divide(3, 1); cellxyz->cd(1) ; TH2D * hXYCell = (TH2D*) fhXYZCell->Project3D("yx" ); hXYCell->SetTitle("Cell X vs Y"); hXYCell->GetYaxis()->SetTitleOffset(1.6); hXYCell->Draw("colz"); cellxyz->cd(2) ; TH2D * hYZCell = (TH2D*) fhXYZCell->Project3D("yz" ); hYZCell->SetTitle("Cell Z vs Y"); hYZCell->GetYaxis()->SetTitleOffset(1.6); hYZCell->Draw("colz"); cellxyz->cd(3) ; TH2D * hXZCell = (TH2D*) fhXYZCell->Project3D("zx" ); hXZCell->SetTitle("Cell X vs Z"); hXZCell->GetYaxis()->SetTitleOffset(1.6); hXZCell->Draw("colz"); snprintf(name,buffersize,"QA_%s_CellXY_YZ_XZ.eps",fCalorimeter.Data()); cellxyz->Print(name); printf("Create plot %s\n",name); snprintf(cname,buffersize,"%s_QA_CellX",fCalorimeter.Data()); TCanvas * cellx = new TCanvas(cname, "Cell X distributions", 1200, 400) ; cellx->Divide(3, 1); cellx->cd(1) ; TH1D * hXCell = (TH1D*) fhXYZCell->Project3D("xe" ); //gPad->SetLogy(); gPad->SetGridy(); hXCell->SetTitle("Cell X "); hXCell->Rebin(rbX); hXCell->SetMinimum(hXCell->GetMaximum()/2); hXCell->SetAxisRange(xmin,xmax); hXCell->Draw("HE"); cellx->cd(2) ; TH1D * hYCell = (TH1D*) fhXYZCell->Project3D("ye" ); //gPad->SetLogy(); hYCell->SetTitle("Cell Y "); hYCell->Rebin(rbY); hYCell->SetAxisRange(ymin,ymax); hYCell->SetMinimum(1); hYCell->Draw("HE"); cellx->cd(3) ; TH1D * hZCell = (TH1D*) fhXYZCell->Project3D("ze" ); //gPad->SetLogy(); gPad->SetGridy(); hZCell->SetAxisRange(zmin,zmax); hZCell->SetTitle("Cell Z "); hZCell->Rebin(rbZ); hZCell->SetMinimum(hZCell->GetMaximum()/2); hZCell->Draw("HE"); snprintf(name,buffersize,"QA_%s_CellX_Y_Z.eps",fCalorimeter.Data()); cellx->Print(name); printf("Create plot %s\n",name); //---------------------------------------------------------- // Cluster X, Y, Z, R, energy cut dependence //--------------------------------------------------------- snprintf(cname,buffersize,"%s_QA_ClusterX_Y_Z_R_ECut",fCalorimeter.Data()); TCanvas * cxe = new TCanvas(cname, "Cluster X Y Z R, E cut", 800, 800) ; cxe->Divide(2, 2); //R cxe->cd(1) ; gPad->SetLogy(); gPad->SetGridy(); TLegend pLegendXCl(0.83,0.6,0.95,0.93); pLegendXCl.SetTextSize(0.03); pLegendXCl.SetFillColor(10); pLegendXCl.SetBorderSize(1); delete htmp; htmp = fhRE->ProjectionX("hre_cluster_nocut",0,-1); Int_t rbR=1; if(htmp){ htmp->SetMinimum(1); rbR = GetNewRebinForRePlotting(htmp, rmin, rmax,rbins) ; //printf("new R rb %d\n",rbR); htmp->Rebin(rbR); htmp->SetTitle("r of clusters for energy in cluster > threshold"); htmp->SetAxisRange(rmin,rmax,"X"); htmp->Draw("HE"); pLegendXCl.AddEntry(htmp,"No cut","L"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhRE->ProjectionX(Form("hre_cluster_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbR); htmp->Draw("same HE"); pLegendXCl.AddEntry(htmp,Form("E>%1.1f",ecut[i]),"L"); } } pLegendXCl.Draw(); //X cxe->cd(2) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhXE->ProjectionX("hxe_cluster_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbX); htmp->SetTitle("x of clusters for energy in cluster > threshold"); htmp->SetAxisRange(xmin,xmax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhXE->ProjectionX(Form("hxe_cluster_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbX); htmp->Draw("same HE"); } } //Y cxe->cd(3) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhYE->ProjectionX("hye_cluster_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbY); htmp->SetTitle("y of clusters for energy in cluster > threshold"); htmp->SetAxisRange(ymin,ymax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhYE->ProjectionX(Form("hye_cluster_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbY); htmp->Draw("same HE"); } } //Z cxe->cd(4) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhZE->ProjectionX("hze_cluster_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbZ); htmp->SetTitle("z of clusters for energy in cluster > threshold"); htmp->SetAxisRange(zmin,zmax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhZE->ProjectionX(Form("hze_cluster_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbZ); htmp->Draw("same HE"); } } snprintf(name,buffersize,"QA_%s_ClusterX_Y_Z_R_ECut.eps",fCalorimeter.Data()); cxe->Print(name); printf("Create plot %s\n",name); //---------------------------------------------------------- // Cluster X, Y, Z, R, NCells in cluster dependence //--------------------------------------------------------- Int_t ncellcut[]={2, 3, 4}; Int_t ncellcuts = 3; snprintf(cname,buffersize,"%s_QA_ClusterX_Y_Z_R_NCellsCut",fCalorimeter.Data()); TCanvas * cxn = new TCanvas(cname, "Cluster X Y Z R, NCells cut", 800, 800) ; cxn->Divide(2, 2); //R cxn->cd(1) ; gPad->SetLogy(); gPad->SetGridy(); TLegend pLegendXClN(0.83,0.6,0.95,0.93); pLegendXClN.SetTextSize(0.03); pLegendXClN.SetFillColor(10); pLegendXClN.SetBorderSize(1); delete htmp; htmp = fhRNCells->ProjectionX("hrn_cluster_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbR); htmp->SetTitle("r of clusters for energy in cluster > threshold"); htmp->SetAxisRange(rmin,rmax,"X"); htmp->Draw("HE"); pLegendXClN.AddEntry(htmp,"No cut","L"); for (Int_t i = 0; i < ncellcuts; i++) { if(i < ncellcuts-1) htmp = fhRNCells->ProjectionX(Form("hrn_cluster_cut%d",i),ncellcut[i],ncellcut[i]); else htmp = fhRNCells->ProjectionX(Form("hrn_cluster_cut%d",i),ncellcut[i],-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbR); htmp->Draw("same HE"); if(i < ncellcuts-1) pLegendXClN.AddEntry(htmp,Form("n = %1.1d",ncellcut[i]-1),"L"); else pLegendXClN.AddEntry(htmp,Form("n >= %1.1d",ncellcut[i]-1),"L"); } } pLegendXClN.Draw(); //X cxn->cd(2) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhXNCells->ProjectionX("hxn_cluster_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbX); htmp->SetTitle("x of clusters for energy in cluster > threshold"); htmp->SetAxisRange(xmin,xmax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncellcuts; i++) { if(i < ncellcuts-1)htmp = fhXNCells->ProjectionX(Form("hxn_cluster_cut%d",i),ncellcut[i],ncellcut[i]); else htmp = fhXNCells->ProjectionX(Form("hxn_cluster_cut%d",i),ncellcut[i],-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbX); htmp->Draw("same HE"); } } //Y cxn->cd(3) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhYNCells->ProjectionX("hyn_cluster_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbY); htmp->SetTitle("y of clusters for energy in cluster > threshold"); htmp->SetAxisRange(ymin,ymax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncellcuts; i++) { if(i < ncellcuts-1) htmp = fhYNCells->ProjectionX(Form("hyn_cluster_cut%d",i),ncellcut[i],ncellcut[i]); else htmp = fhYNCells->ProjectionX(Form("hyn_cluster_cut%d",i),ncellcut[i],-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbY); htmp->Draw("same HE"); } } //Z cxn->cd(4) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhZNCells->ProjectionX("hzn_cluster_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbZ); htmp->SetTitle("z of clusters for energy in cluster > threshold"); htmp->SetAxisRange(zmin,zmax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncellcuts; i++) { if(i < ncellcuts-1)htmp = fhZNCells->ProjectionX(Form("hzn_cluster_cut%d",i),ncellcut[i],ncellcut[i]); else htmp = fhZNCells->ProjectionX(Form("hzn_cluster_cut%d",i),ncellcut[i],-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbZ); htmp->Draw("same HE"); } } snprintf(name,buffersize,"QA_%s_ClusterX_Y_Z_R_NCellsCut.eps",fCalorimeter.Data()); cxn->Print(name); printf("Create plot %s\n",name); //---------------------------------------------------------- // Cell X, Y, Z, R, energy cut dependence //--------------------------------------------------------- snprintf(cname,buffersize,"%s_QA_CellX_Y_Z_R_ECut",fCalorimeter.Data()); TCanvas * cxecell = new TCanvas(cname, "Cell X Y Z R, E cut", 800, 800) ; cxecell->Divide(2, 2); //R cxecell->cd(1) ; gPad->SetLogy(); gPad->SetGridy(); TLegend pLegendXCell(0.83,0.6,0.95,0.93); pLegendXCell.SetTextSize(0.03); pLegendXCell.SetFillColor(10); pLegendXCell.SetBorderSize(1); delete htmp; htmp = fhRCellE->ProjectionX("hre_cell_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbR); htmp->SetTitle("r of cells for energy in cluster > threshold"); htmp->SetAxisRange(rmin,rmax,"X"); htmp->Draw("HE"); pLegendXCell.AddEntry(htmp,"No cut","L"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhRCellE->ProjectionX(Form("hre_celr_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbR); htmp->Draw("same HE"); pLegendXCell.AddEntry(htmp,Form("E>%1.1f",ecut[i]),"L"); } } pLegendXCell.Draw(); //X cxecell->cd(2) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhXCellE->ProjectionX("hxe_cells_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbX); htmp->SetTitle("x of cells for energy in cluster > threshold"); htmp->SetAxisRange(xmin,xmax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); htmp = fhXCellE->ProjectionX(Form("hxe_cells_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbX); htmp->Draw("same HE"); } } //Y cxecell->cd(3) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhYCellE->ProjectionX("hye_cells_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbY); htmp->SetTitle("y of cells for energy in cluster > threshold"); htmp->SetAxisRange(ymin,ymax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); delete htmp; htmp = fhYCellE->ProjectionX(Form("hye_cells_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbY); htmp->Draw("same HE"); } } //Z cxecell->cd(4) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhZCellE->ProjectionX("hze_cells_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbZ); htmp->SetTitle("z of cells for energy in cluster > threshold"); htmp->SetAxisRange(zmin,zmax,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); delete htmp; htmp = fhZCellE->ProjectionX(Form("hze_cells_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbZ); htmp->Draw("same HE"); } } snprintf(name,buffersize,"QA_%s_CellX_Y_Z_R_ECut.eps",fCalorimeter.Data()); cxecell->Print(name); printf("Create plot %s\n",name); //---------------------------------------------------------- // Cluster-Cell X, Y, Z, R, cluster energy cut dependence //--------------------------------------------------------- Int_t rbDR= 1;//rbR; Int_t rbDX= 1;//rbX; Int_t rbDY= 1;//rbY; Int_t rbDZ= 1;//rbZ; snprintf(cname,buffersize,"%s_QA_DeltaClusterCellX_Y_Z_R_ECut",fCalorimeter.Data()); TCanvas * cxde = new TCanvas(cname, "Cluster-Cell X, Y, Z, R, E cut", 800, 800) ; cxde->Divide(2, 2); //R cxde->cd(1) ; gPad->SetLogy(); gPad->SetGridy(); TLegend pLegendXClD(0.83,0.6,0.95,0.93); pLegendXClD.SetTextSize(0.03); pLegendXClD.SetFillColor(10); pLegendXClD.SetBorderSize(1); delete htmp; htmp = fhDeltaCellClusterRE->ProjectionX("hrde_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbDR); htmp->SetTitle("r clusters - r cells for energy in cluster > threshold"); htmp->SetAxisRange(-50,50,"X"); htmp->Draw("HE"); pLegendXCl.AddEntry(htmp,"No cut","L"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); delete htmp; htmp = fhDeltaCellClusterRE->ProjectionX(Form("hrde_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbDR); htmp->Draw("same HE"); pLegendXClD.AddEntry(htmp,Form("E>%1.1f",ecut[i]),"L"); } } pLegendXClD.Draw(); //X cxde->cd(2) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhDeltaCellClusterXE->ProjectionX("hxde_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbDX); htmp->SetTitle("x clusters -x cells for energy in cluster > threshold"); htmp->SetAxisRange(-50,50,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); delete htmp; htmp = fhDeltaCellClusterXE->ProjectionX(Form("hxde_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbDX); htmp->Draw("same HE"); } } //Y cxde->cd(3) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhDeltaCellClusterYE->ProjectionX("hyde_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbDY); htmp->SetTitle("y clusters - ycells for energy in cluster > threshold"); htmp->SetAxisRange(-50,50,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); delete htmp; htmp = fhDeltaCellClusterYE->ProjectionX(Form("hyde_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbDY); htmp->Draw("same HE"); } } //Z cxde->cd(4) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhDeltaCellClusterZE->ProjectionX("hzde_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbZ); htmp->SetTitle("z clusters - z cells for energy in cluster > threshold"); htmp->SetAxisRange(-50,50,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncuts; i++) { binmin = hE->FindBin(ecut[i]); //printf(" bins %d for e %f\n",binmin[i],ecut[i]); delete htmp; htmp = fhDeltaCellClusterZE->ProjectionX(Form("hzde_cut%d",i),binmin,-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbZ); htmp->Draw("same HE"); } } snprintf(name,buffersize,"QA_%s_DeltaClusterCellX_Y_Z_R_ECut.eps",fCalorimeter.Data()); cxde->Print(name); printf("Create plot %s\n",name); //---------------------------------------------------------- // Cluster-Cell X, Y, Z, R, NCells in cluster dependence //--------------------------------------------------------- snprintf(cname,buffersize,"%s_QA_DeltaClusterCellX_Y_Z_R_NCellsCut",fCalorimeter.Data()); TCanvas * cxdn = new TCanvas(cname, "Cluster-Cell X Y Z R, NCells cut", 800, 800) ; cxdn->Divide(2, 2); //R cxdn->cd(1) ; gPad->SetLogy(); gPad->SetGridy(); TLegend pLegendXClDN(0.83,0.6,0.95,0.93); pLegendXClDN.SetTextSize(0.03); pLegendXClDN.SetFillColor(10); pLegendXClDN.SetBorderSize(1); delete htmp; htmp = fhDeltaCellClusterRNCells->ProjectionX("hrdn_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbDR); htmp->SetTitle("r clusters - r cells for n cells in cluster > threshold"); htmp->SetAxisRange(-50,50,"X"); htmp->Draw("HE"); pLegendXClDN.AddEntry(htmp,"No cut","L"); for (Int_t i = 0; i < ncellcuts; i++) { delete htmp; if(i < ncellcuts-1) htmp = fhDeltaCellClusterRNCells->ProjectionX(Form("hrdn_cut%d",i),ncellcut[i],ncellcut[i]); else htmp = fhDeltaCellClusterRNCells->ProjectionX(Form("hrdn_cut%d",i),ncellcut[i],-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbDR); htmp->Draw("same HE"); if(i < ncellcuts-1) pLegendXClDN.AddEntry(htmp,Form("n = %1.1d",ncellcut[i]-1),"L"); else pLegendXClDN.AddEntry(htmp,Form("n >= %1.1d",ncellcut[i]-1),"L"); } } pLegendXClDN.Draw(); //X cxdn->cd(2) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhDeltaCellClusterXNCells->ProjectionX("hxdn_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbDX); htmp->SetTitle("x clusters - x cells for n cells in cluster > threshold"); htmp->SetAxisRange(-50,50,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncellcuts; i++) { delete htmp; if(i < ncellcuts-1)htmp = fhDeltaCellClusterXNCells->ProjectionX(Form("hxdn_cut%d",i),ncellcut[i],ncellcut[i]); else htmp = fhDeltaCellClusterXNCells->ProjectionX(Form("hxdn_cut%d",i),ncellcut[i],-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbDX); htmp->Draw("same HE"); } } //Y cxdn->cd(3) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhDeltaCellClusterYNCells->ProjectionX("hydn_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbDY); htmp->SetTitle("y clusters - y cells for n cells in cluster > threshold"); htmp->SetAxisRange(-50,50,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncellcuts; i++) { delete htmp; if(i < ncellcuts-1) htmp = fhDeltaCellClusterYNCells->ProjectionX(Form("hydn_cut%d",i),ncellcut[i],ncellcut[i]); else htmp = fhDeltaCellClusterYNCells->ProjectionX(Form("hydn_cut%d",i),ncellcut[i],-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbDY); htmp->Draw("same HE"); } } //Z cxdn->cd(4) ; gPad->SetLogy(); gPad->SetGridy(); delete htmp; htmp = fhDeltaCellClusterZNCells->ProjectionX("hzdn_nocut",0,-1); if(htmp){ htmp->SetMinimum(1); htmp->Rebin(rbDZ); htmp->SetTitle("z clusters - z cells for ncells in cluster > threshold"); htmp->SetAxisRange(-50,50,"X"); htmp->Draw("HE"); for (Int_t i = 0; i < ncellcuts; i++) { delete htmp; if(i < ncellcuts-1)htmp = fhDeltaCellClusterZNCells->ProjectionX(Form("hzdn_cut%d",i),ncellcut[i],ncellcut[i]); else htmp = fhDeltaCellClusterZNCells->ProjectionX(Form("hzdn_cut%d",i),ncellcut[i],-1); htmp->SetLineColor(ecutcolor[i]); htmp->Rebin(rbDZ); htmp->Draw("same HE"); } } snprintf(name,buffersize,"QA_%s_DeltaClusterCellX_Y_Z_R_NCellsCut.eps",fCalorimeter.Data()); cxdn->Print(name); printf("Create plot %s\n",name); } //---------------------------------------------------------- //Reconstructed clusters energy-eta-phi distributions, matched with tracks //---------------------------------------------------------- TH1F * hEChargedClone = 0 ; TH1F * hPtChargedClone = 0 ; TH1F * hEtaChargedClone = 0 ; TH1F * hPhiChargedClone = 0 ; if(fFillAllTH12){ hEChargedClone = (TH1F*) fhECharged->Clone(Form("%sClone",fhECharged->GetName())); hPtChargedClone = (TH1F*) fhPtCharged->Clone(Form("%sClone",fhPtCharged->GetName())); hEtaChargedClone = (TH1F*) fhEtaCharged->Clone(Form("%sClone",fhEtaCharged->GetName())); hPhiChargedClone = (TH1F*) fhPhiCharged->Clone(Form("%sClone",fhPhiCharged->GetName())); snprintf(cname,buffersize,"QA_%s_rectrackmatch",fCalorimeter.Data()); TCanvas * ccltm = new TCanvas(cname, "Reconstructed clusters E-Phi-Eta, matched with tracks", 1200, 400) ; ccltm->Divide(3, 1); ccltm->cd(1) ; if(fhECharged->GetEntries() > 0) gPad->SetLogy(); fhECharged->Rebin(rbE); fhECharged->SetAxisRange(ptmin,ptmax,"X"); fhECharged->SetMinimum(1); fhECharged->Draw(); ccltm->cd(2) ; if(fhPhiCharged->GetEntries() > 0) gPad->SetLogy(); fhPhiCharged->Rebin(rbPhi); fhPhiCharged->SetAxisRange(phimin,phimax,"X"); fhPhiCharged->Draw(); fhPhiCharged->Draw(); ccltm->cd(3) ; if(fhEtaCharged->GetEntries() > 0) gPad->SetLogy(); fhEtaCharged->Rebin(rbEta); fhEtaCharged->SetAxisRange(etamin,etamax,"X"); fhEtaCharged->Draw(); fhEtaCharged->Draw(); snprintf(name,buffersize,"QA_%s_ClusterEnergyPhiEta_TrackMatched.eps",fCalorimeter.Data()); ccltm->Print(name); printf("Plot: %s\n",name); //---------------------------------------------------------- // Ratio of reconstructed clusters energy-eta-phi distributions, matched with tracks over all //---------------------------------------------------------- snprintf(cname,buffersize,"%s_QA_ChargedRatio",fCalorimeter.Data()); TCanvas * ccharge = new TCanvas(cname, "Charged clusters over all clusters", 1200, 400) ; ccharge->Divide(3, 1); ccharge->cd(1) ; fhECharged->Sumw2(); fhE->Sumw2(); fhECharged->Divide(fhE); fhECharged->SetAxisRange(ptmin,ptmax,"X"); fhECharged->SetMaximum(0.5); fhECharged->SetYTitle("track-matched clusters / all clusters"); fhECharged->Draw("HE"); ccharge->cd(2) ; fhPhiCharged->Sumw2(); fhPhi->Rebin(rbPhi); fhPhi->Sumw2(); fhPhiCharged->Divide(fhPhi); fhPhiCharged->SetAxisRange(phimin,phimax,"X"); fhPhiCharged->SetMaximum(0.5); fhPhiCharged->SetYTitle("track-matched clusters / all clusters"); fhPhiCharged->Draw("HE"); ccharge->cd(3) ; fhEtaCharged->Sumw2(); fhEta->Rebin(rbEta); fhEta->Sumw2(); fhEtaCharged->Divide(fhEta); fhEtaCharged->SetAxisRange(etamin,etamax,"X"); fhEtaCharged->SetMaximum(0.5); fhEtaCharged->SetYTitle("track-matched clusters / all clusters"); fhEtaCharged->Draw("HE"); snprintf(name,buffersize,"QA_%s_ClustersMatchedToAllRatios.eps",fCalorimeter.Data()); ccharge->Print(name); printf("Create plot %s\n",name); } //------------------------------------------- // N Cells - N Clusters - N Cells per cluster //------------------------------------------- snprintf(cname,buffersize,"QA_%s_nclustercells",fCalorimeter.Data()); TCanvas * cN = new TCanvas(cname, " Number of CaloClusters and CaloCells", 800, 1200) ; cN->Divide(2, 3); cN->cd(1) ; TLegend pLegendN(0.7,0.6,0.9,0.8); pLegendN.SetTextSize(0.03); pLegendN.AddEntry(fhNClusters,"all modules","L"); pLegendN.SetFillColor(10); pLegendN.SetBorderSize(1); if(fhNClusters->GetEntries() > 0) gPad->SetLogy(); gPad->SetLogx(); fhNClusters->SetLineColor(1); Int_t rbN = 1; if(fhNClusters->GetNbinsX()> nbins) rbN = fhNClusters->GetNbinsX()/nbins; fhNClusters->SetAxisRange(nmin,nmax,"X"); fhNClusters->Draw("HE"); for(Int_t imod = 0; imod < fNModules; imod++){ fhNClustersMod[imod]->SetAxisRange(nmin,nmax,"X"); fhNClustersMod[imod]->SetLineColor(modColorIndex[imod]); fhNClustersMod[imod]->Draw("same"); pLegendN.AddEntry(fhNClustersMod[imod],Form("module %d",imod),"L"); } pLegendN.Draw(); cN->cd(2) ; gPad->SetLogx(); for(Int_t imod = 1; imod < fNModules; imod++){ delete htmp; htmp = (TH1D*)fhNClustersMod[imod]->Clone(Form("hNClustersRat%d",imod)); htmp->Divide(fhNClustersMod[0]); htmp->SetLineColor(modColorIndex[imod]); if(imod==1){ htmp->SetTitle("Ratio # clusters in module X / module 0"); htmp->SetMaximum(5); htmp->SetMinimum(0); htmp->Draw("HE"); } else htmp->Draw("same HE"); } cN->cd(3) ; if(fhNCells->GetEntries() > 0) gPad->SetLogy(); gPad->SetLogx(); fhNCells->SetLineColor(1); fhNCells->SetAxisRange(nmin,nmax,"X"); fhNCells->Draw("HE"); for(Int_t imod = 0; imod < fNModules; imod++){ fhNCellsMod[imod]->SetAxisRange(nmin,nmax,"X"); fhNCellsMod[imod]->SetLineColor(modColorIndex[imod]); fhNCellsMod[imod]->Draw("same HE"); } cN->cd(4) ; gPad->SetLogx(); for(Int_t imod = 1; imod < fNModules; imod++){ delete htmp; htmp = (TH1D*)fhNCellsMod[imod]->Clone(Form("hNCellsRat%d",imod)); htmp->Divide(fhNCellsMod[0]); htmp->SetLineColor(modColorIndex[imod]); if(imod==1){ htmp->SetTitle("Ratio # cells in module X / module 0"); htmp->SetMaximum(5); htmp->SetMinimum(0); htmp->Draw("HE"); } else htmp->Draw("same HE"); } cN->cd(5) ; if(fhNCellsPerCluster->GetEntries() > 0) gPad->SetLogy(); gPad->SetLogx(); TH1D *cpc = fhNCellsPerCluster->ProjectionY("cpc",-1,-1,-1,-1); cpc->SetLineColor(1); cpc->SetTitle("# cells per cluster"); cpc->Draw("HE"); TH1D ** hNCellsCluster1D = new TH1D*[fNModules]; for(Int_t imod = 0; imod < fNModules; imod++){ hNCellsCluster1D[imod] = fhNCellsPerClusterMod[imod]->ProjectionY(Form("cpc_%d",imod),-1,-1); hNCellsCluster1D[imod]->SetLineColor(modColorIndex[imod]); hNCellsCluster1D[imod]->Draw("same HE"); } cN->cd(6) ; gPad->SetLogx(); for(Int_t imod = 1; imod < fNModules; imod++){ delete htmp; htmp = (TH1D*)hNCellsCluster1D[imod]->Clone(Form("hNClustersCells1DRat%d",imod)); htmp->Divide(hNCellsCluster1D[0]); htmp->SetLineColor(modColorIndex[imod]); if(imod==1){ htmp->SetTitle("Ratio # cells per cluster in module X / module 0"); //htmp->SetAxisRange(ptmin,ptmax,"X"); htmp->SetMaximum(3.5); htmp->SetMinimum(0); htmp->Draw("HE"); } else htmp->Draw("same HE"); } delete [] hNCellsCluster1D; snprintf(name,buffersize,"QA_%s_NumberCaloClustersAndCaloCells.eps",fCalorimeter.Data()); cN->Print(name); printf("Print plot %s\n",name); //---------------------------------------------------- // Cell Time histograms, time only available in ESDs //---------------------------------------------------- if(GetReader()->GetDataType()==AliCaloTrackReader::kESD) { snprintf(cname,buffersize,"QA_%s_cellstime",fCalorimeter.Data()); TCanvas * ctime = new TCanvas(cname, " Cells time", 1200, 400) ; ctime->Divide(3, 1); Int_t rbTime = 1; if(fhTime->GetNbinsX()> ntimebins) rbTime = fhTime->GetNbinsX()/ntimebins; ctime->cd(1) ; if(fhTime->GetEntries() > 0) gPad->SetLogy(); fhTime->Rebin(rbTime); fhTime->SetAxisRange(timemin,timemax,"X"); fhTime->Draw(); ctime->cd(2) ; fhTimeId->SetTitleOffset(1.8,"Y"); fhTimeId->SetAxisRange(timemin,timemax,"X"); fhTimeId->Draw("colz"); ctime->cd(3) ; fhTimeAmp->SetTitle("Cell Energy vs Cell Time"); fhTimeAmp->SetTitleOffset(1.8,"Y"); fhTimeAmp->SetAxisRange(timemin,timemax,"Y"); fhTimeAmp->SetAxisRange(ptmin,ptmax,"X"); fhTimeAmp->Draw("colz"); snprintf(name,buffersize,"QA_%s_CellsTime.eps",fCalorimeter.Data()); ctime->Print(name); printf("Plot: %s\n",name); } //--------------------------------- //Grid of cell per module plots //--------------------------------- { //Number of entries per cell gStyle->SetPadRightMargin(0.15); snprintf(cname,buffersize,"%s_QA_GridCellEntries",fCalorimeter.Data()); TCanvas *cgrid = new TCanvas("cgrid","Number of entries per cell", 12,12,800,400); if(fNModules%2 == 0) cgrid->Divide(fNModules/2,2); else cgrid->Divide(fNModules/2+1,2); for(Int_t imod = 0; imod < fNModules ; imod++){ cgrid->cd(imod+1); gPad->SetLogz(); gPad->SetGridy(); gPad->SetGridx(); //fhGridCellsMod[imod]->GetYAxis()->SetTitleColor(1); fhGridCellsMod[imod]->SetZTitle("Counts "); fhGridCellsMod[imod]->SetYTitle("row (phi direction) "); //fhGridCellsMod[imod]->SetLabelSize(0.025,"z"); fhGridCellsMod[imod]->Draw("colz"); } snprintf(name,buffersize,"QA_%s_GridCellsEntries.eps",fCalorimeter.Data()); cgrid->Print(name); printf("Create plot %s\n",name); snprintf(cname,buffersize,"%s_QA_GridCellAccumEnergy",fCalorimeter.Data()); TCanvas *cgridE = new TCanvas("cgridE","Summed energy per cell", 12,12,800,400); if(fNModules%2 == 0) cgridE->Divide(fNModules/2,2); else cgridE->Divide(fNModules/2+1,2); for(Int_t imod = 0; imod < fNModules ; imod++){ cgridE->cd(imod+1); gPad->SetLogz(); gPad->SetGridy(); gPad->SetGridx(); //fhGridCellsEMod[imod]->SetLabelSize(0.025,"z"); fhGridCellsEMod[imod]->SetZTitle("Accumulated Energy (GeV) "); fhGridCellsEMod[imod]->SetYTitle("row (phi direction) "); fhGridCellsEMod[imod]->Draw("colz"); } snprintf(name,buffersize,"QA_%s_GridCellsAccumEnergy.eps",fCalorimeter.Data()); cgridE->Print(name); printf("Create plot %s\n",name); //Accumulated energy per cell snprintf(cname,buffersize,"%s_QA_GridCellAverageEnergy",fCalorimeter.Data()); TCanvas *cgridEA = new TCanvas("cgridEA","Average energy per cell", 12,12,800,400); if(fNModules%2 == 0) cgridEA->Divide(fNModules/2,2); else cgridEA->Divide(fNModules/2+1,2); for(Int_t imod = 0; imod < fNModules ; imod++){ cgridEA->cd(imod+1); gPad->SetLogz(); gPad->SetGridy(); gPad->SetGridx(); //fhGridCellsEMod[imod]->SetLabelSize(0.025,"z"); fhGridCellsEMod[imod]->SetZTitle("Average Energy (GeV) "); fhGridCellsEMod[imod]->Divide(fhGridCellsMod[imod]); fhGridCellsEMod[imod]->Draw("colz"); } snprintf(name,buffersize,"QA_%s_GridCellsAverageEnergy.eps",fCalorimeter.Data()); cgridEA->Print(name); printf("Create plot %s\n",name); //Accumulated Time per cell, E > 0.5 GeV snprintf(cname,buffersize,"%s_QA_GridCellAccumTime",fCalorimeter.Data()); TCanvas *cgridT = new TCanvas("cgridT","Summed time per cell", 12,12,800,400); if(fNModules%2 == 0) cgridT->Divide(fNModules/2,2); else cgridE->Divide(fNModules/2+1,2); for(Int_t imod = 0; imod < fNModules ; imod++){ cgridT->cd(imod+1); gPad->SetLogz(); gPad->SetGridy(); gPad->SetGridx(); //fhGridCellsTimeMod[imod]->SetLabelSize(0.025,"z"); fhGridCellsTimeMod[imod]->SetZTitle("Accumulated Time (ns) "); fhGridCellsTimeMod[imod]->SetYTitle("row (phi direction) "); fhGridCellsTimeMod[imod]->Draw("colz"); } snprintf(name,buffersize,"QA_%s_GridCellsAccumTime.eps",fCalorimeter.Data()); cgridT->Print(name); printf("Create plot %s\n",name); } //--------------------------------------------- //Calorimeter Correlation, PHOS vs EMCAL //--------------------------------------------- if(fCorrelate){ snprintf(cname,buffersize,"QA_%s_CaloCorr_EMCALvsPHOS",fCalorimeter.Data()); TCanvas * ccorr = new TCanvas(cname, " EMCAL vs PHOS", 400, 400) ; ccorr->Divide(2, 2); ccorr->cd(1) ; //gPad->SetLogy(); //gPad->SetLogx(); fhCaloCorrNClusters->SetAxisRange(nmin,nmax,"X"); fhCaloCorrNClusters->SetAxisRange(nmin,nmax,"Y"); fhCaloCorrNClusters ->Draw(); ccorr->cd(2) ; //gPad->SetLogy(); //gPad->SetLogx(); fhCaloCorrNCells->SetAxisRange(nmin,nmax,"X"); fhCaloCorrNCells->SetAxisRange(nmin,nmax,"Y"); fhCaloCorrNCells->Draw(); //gPad->SetLogy(); //gPad->SetLogx(); fhCaloCorrEClusters->SetAxisRange(ptmin,ptmax,"X"); fhCaloCorrEClusters->SetAxisRange(ptmin,ptmax,"Y"); fhCaloCorrEClusters->Draw(); ccorr->cd(4) ; //gPad->SetLogy(); //gPad->SetLogx(); fhCaloCorrECells->SetAxisRange(ptmin,ptmax,"X"); fhCaloCorrECells->SetAxisRange(ptmin,ptmax,"Y"); fhCaloCorrECells->Draw(); snprintf(name,buffersize,"QA_%s_CaloCorr_EMCALvsPHOS.eps",fCalorimeter.Data()); ccorr->Print(name); printf("Plot: %s\n",name); } //---------------------------- //Invariant mass //----------------------------- Int_t imbinmin = -1; Int_t imbinmax = -1; if(fhIM->GetEntries() > 1){ Int_t nebins = fhIM->GetNbinsX(); Int_t emax = (Int_t) fhIM->GetXaxis()->GetXmax(); Int_t emin = (Int_t) fhIM->GetXaxis()->GetXmin(); if (emin != 0 ) printf("emin != 0 \n"); //printf("IM: nBinsX %d, emin %2.2f, emax %2.2f\n",nebins,emin,emax); snprintf(cname,buffersize,"QA_%s_IM",fCalorimeter.Data()); // printf("c5\n"); TCanvas * c5 = new TCanvas(cname, "Invariant mass", 600, 400) ; c5->Divide(2, 3); c5->cd(1) ; //fhIM->SetLineColor(4); //fhIM->Draw(); imbinmin = 0; imbinmax = (Int_t) (1-emin)*nebins/emax; TH1D *pyim1 = fhIM->ProjectionY(Form("%s_py1",fhIM->GetName()),imbinmin,imbinmax); pyim1->SetTitle("E_{pair} < 1 GeV"); pyim1->SetLineColor(1); pyim1->Draw(); TLegend pLegendIM(0.7,0.6,0.9,0.8); pLegendIM.SetTextSize(0.03); pLegendIM.AddEntry(pyim1,"all modules","L"); pLegendIM.SetFillColor(10); pLegendIM.SetBorderSize(1); //FIXME for(Int_t imod = 0; imod < fNModules; imod++){ pyim1 = fhIMMod[imod]->ProjectionY(Form("%s_py1",fhIMMod[imod]->GetName()),imbinmin,imbinmax); pLegendIM.AddEntry(pyim1,Form("module %d",imod),"L"); pyim1->SetLineColor(imod+1); pyim1->Draw("same"); } pLegendIM.Draw(); c5->cd(2) ; imbinmin = (Int_t) (1-emin)*nebins/emax; imbinmax = (Int_t) (2-emin)*nebins/emax; TH1D *pyim2 = fhIM->ProjectionY(Form("%s_py2",fhIM->GetName()),imbinmin,imbinmax); pyim2->SetTitle("1 < E_{pair} < 2 GeV"); pyim2->SetLineColor(1); pyim2->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyim2 = fhIMMod[imod]->ProjectionY(Form("%s_py2",fhIMMod[imod]->GetName()),imbinmin,imbinmax); pyim2->SetLineColor(imod+1); pyim2->Draw("same"); } c5->cd(3) ; imbinmin = (Int_t) (2-emin)*nebins/emax; imbinmax = (Int_t) (3-emin)*nebins/emax; TH1D *pyim3 = fhIM->ProjectionY(Form("%s_py3",fhIM->GetName()),imbinmin,imbinmax); pyim3->SetTitle("2 < E_{pair} < 3 GeV"); pyim3->SetLineColor(1); pyim3->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyim3 = fhIMMod[imod]->ProjectionY(Form("%s_py3",fhIMMod[imod]->GetName()),imbinmin,imbinmax); pyim3->SetLineColor(imod+1); pyim3->Draw("same"); } c5->cd(4) ; imbinmin = (Int_t) (3-emin)*nebins/emax; imbinmax = (Int_t) (4-emin)*nebins/emax; TH1D *pyim4 = fhIM->ProjectionY(Form("%s_py4",fhIM->GetName()),imbinmin,imbinmax); pyim4->SetTitle("3 < E_{pair} < 4 GeV"); pyim4->SetLineColor(1); pyim4->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyim4 = fhIMMod[imod]->ProjectionY(Form("%s_py4",fhIMMod[imod]->GetName()),imbinmin,imbinmax); pyim4->SetLineColor(imod+1); pyim4->Draw("same"); } c5->cd(5) ; imbinmin = (Int_t) (4-emin)*nebins/emax; imbinmax = (Int_t) (5-emin)*nebins/emax; TH1D *pyim5 = fhIM->ProjectionY(Form("%s_py5",fhIM->GetName()),imbinmin,imbinmax); pyim5->SetTitle("4< E_{pair} < 5 GeV"); pyim5->SetLineColor(1); pyim5->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyim5 = fhIMMod[imod]->ProjectionY(Form("%s_py5",fhIMMod[imod]->GetName()),imbinmin,imbinmax); pyim5->SetLineColor(imod+1); pyim5->Draw("same"); } c5->cd(6) ; imbinmin = (Int_t) (5-emin)*nebins/emax; imbinmax = -1; TH1D *pyim10 = fhIM->ProjectionY(Form("%s_py6",fhIM->GetName()),imbinmin,imbinmax); pyim10->SetTitle("E_{pair} > 5 GeV"); pyim10->SetLineColor(1); pyim10->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyim10 = fhIMMod[imod]->ProjectionY(Form("%s_py6",fhIMMod[imod]->GetName()),imbinmin,imbinmax); pyim10->SetLineColor(imod+1); pyim10->Draw("same"); } snprintf(name,buffersize,"QA_%s_InvariantMass.eps",fCalorimeter.Data()); c5->Print(name); printf("Plot: %s\n",name); } //-------------------------------------------------- //Invariant mass, clusters with more than one cell //------------------------------------------------- if(fhIMCellCut->GetEntries() > 1){ Int_t nebins = fhIMCellCut->GetNbinsX(); Int_t emax = (Int_t) fhIMCellCut->GetXaxis()->GetXmax(); Int_t emin = (Int_t) fhIMCellCut->GetXaxis()->GetXmin(); if (emin != 0 ) printf("emin != 0 \n"); //printf("IMCellCut: nBinsX %d, emin %2.2f, emax %2.2f\n",nebins,emin,emax); snprintf(cname,buffersize,"QA_%s_IMCellCut",fCalorimeter.Data()); // printf("c5cc\n"); TCanvas * c5cc = new TCanvas(cname, "Invariant mass, Cell Cut", 600, 400) ; c5cc->Divide(2, 3); c5cc->cd(1) ; //fhIMCellCut->SetLineColor(4); //fhIMCellCut->Draw(); imbinmin = 0; imbinmax = (Int_t) (1-emin)*nebins/emax; TH1D *pyimcc1 = fhIMCellCut->ProjectionY(Form("%s_py1",fhIMCellCut->GetName()),imbinmin,imbinmax); pyimcc1->SetTitle("E_{pair} < 1 GeV"); pyimcc1->SetLineColor(1); pyimcc1->Draw(); TLegend pLegendIMCellCut(0.7,0.6,0.9,0.8); pLegendIMCellCut.SetTextSize(0.03); pLegendIMCellCut.AddEntry(pyimcc1,"all modules","L"); pLegendIMCellCut.SetFillColor(10); pLegendIMCellCut.SetBorderSize(1); for(Int_t imod = 0; imod < fNModules; imod++){ pyimcc1 = fhIMCellCutMod[imod]->ProjectionY(Form("%s_py1",fhIMCellCutMod[imod]->GetName()),imbinmin,imbinmax); pLegendIMCellCut.AddEntry(pyimcc1,Form("module %d",imod),"L"); pyimcc1->SetLineColor(imod+1); pyimcc1->Draw("same"); } pLegendIMCellCut.Draw(); c5cc->cd(2) ; imbinmin = (Int_t) (1-emin)*nebins/emax; imbinmax = (Int_t) (2-emin)*nebins/emax; TH1D *pyimcc2 = fhIMCellCut->ProjectionY(Form("%s_py2",fhIMCellCut->GetName()),imbinmin,imbinmax); pyimcc2->SetTitle("1 < E_{pair} < 2 GeV"); pyimcc2->SetLineColor(1); pyimcc2->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyimcc2 = fhIMCellCutMod[imod]->ProjectionY(Form("%s_py1",fhIMCellCutMod[imod]->GetName()),imbinmin,imbinmax); pyimcc2->SetLineColor(imod+1); pyimcc2->Draw("same"); } c5cc->cd(3) ; imbinmin = (Int_t) (2-emin)*nebins/emax; imbinmax = (Int_t) (3-emin)*nebins/emax; TH1D *pyimcc3 = fhIMCellCut->ProjectionY(Form("%s_py3",fhIMCellCut->GetName()),imbinmin,imbinmax); pyimcc3->SetTitle("2 < E_{pair} < 3 GeV"); pyimcc3->SetLineColor(1); pyimcc3->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyimcc3 = fhIMCellCutMod[imod]->ProjectionY(Form("%s_py1",fhIMCellCutMod[imod]->GetName()),imbinmin,imbinmax); pyimcc3->SetLineColor(imod+1); pyimcc3->Draw("same"); } c5cc->cd(4) ; imbinmin = (Int_t) (3-emin)*nebins/emax; imbinmax = (Int_t) (4-emin)*nebins/emax; TH1D *pyimcc4 = fhIMCellCut->ProjectionY(Form("%s_py4",fhIMCellCut->GetName()),imbinmin,imbinmax); pyimcc4->SetTitle("3 < E_{pair} < 4 GeV"); pyimcc4->SetLineColor(1); pyimcc4->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyimcc4 = fhIMCellCutMod[imod]->ProjectionY(Form("%s_py5",fhIMCellCutMod[imod]->GetName()),imbinmin,imbinmax); pyimcc4->SetLineColor(imod+1); pyimcc4->Draw("same"); } c5cc->cd(5) ; imbinmin = (Int_t) (4-emin)*nebins/emax; imbinmax = (Int_t) (5-emin)*nebins/emax; TH1D *pyimcc5cc = fhIMCellCut->ProjectionY(Form("%s_py5",fhIMCellCut->GetName()),imbinmin,imbinmax); pyimcc5cc->SetTitle("4< E_{pair} < 5 GeV"); pyimcc5cc->SetLineColor(1); pyimcc5cc->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyimcc5cc = fhIMCellCutMod[imod]->ProjectionY(Form("%s_py5",fhIMCellCutMod[imod]->GetName()),imbinmin,imbinmax); pyimcc5cc->SetLineColor(imod+1); pyimcc5cc->Draw("same"); } c5cc->cd(6) ; imbinmin = (Int_t) (5-emin)*nebins/emax; imbinmax = -1; TH1D *pyimcc10 = fhIMCellCut->ProjectionY(Form("%s_py6",fhIMCellCut->GetName()),imbinmin,imbinmax); pyimcc10->SetTitle("E_{pair} > 5 GeV"); pyimcc10->SetLineColor(1); pyimcc10->Draw(); for(Int_t imod = 0; imod < fNModules; imod++){ pyimcc10 = fhIMCellCutMod[imod]->ProjectionY(Form("%s_py1",fhIMCellCutMod[imod]->GetName()),imbinmin,imbinmax); pyimcc10->SetLineColor(imod+1); pyimcc10->Draw("same"); } snprintf(name,buffersize,"QA_%s_InvariantMass_CellCut.eps",fCalorimeter.Data()); c5cc->Print(name); printf("Plot: %s\n",name); } //Asymmetry if(fhAsym->GetEntries() > 1){ Int_t nebins = fhAsym->GetNbinsX(); Int_t emax = (Int_t) fhAsym->GetXaxis()->GetXmax(); Int_t emin = (Int_t) fhAsym->GetXaxis()->GetXmin(); if (emin != 0 ) printf("emin != 0 \n"); //printf("Asym: nBinsX %d, emin %2.2f, emax %2.2f\n",nebins,emin,emax); snprintf(cname,buffersize,"QA_%s_Asym",fCalorimeter.Data()); // printf("c5\n"); TCanvas * c5b = new TCanvas(cname, "Asymmetry", 400, 400) ; c5b->Divide(2, 2); c5b->cd(1) ; fhAsym->SetTitleOffset(1.6,"Y"); fhAsym->SetLineColor(4); fhAsym->Draw(); c5b->cd(2) ; imbinmin = 0; imbinmax = (Int_t) (5-emin)*nebins/emax; TH1D *pyAsym5 = fhAsym->ProjectionY(Form("%s_py5",fhAsym->GetName()),imbinmin,imbinmax); pyAsym5->SetTitle("E_{pair} < 5 GeV"); pyAsym5->SetLineColor(4); pyAsym5->Draw(); c5b->cd(3) ; imbinmin = (Int_t) (5-emin)*nebins/emax; imbinmax = (Int_t) (10-emin)*nebins/emax; TH1D *pyAsym510 = fhAsym->ProjectionY(Form("%s_py510",fhAsym->GetName()),imbinmin,imbinmax); pyAsym510->SetTitle("5 < E_{pair} < 10 GeV"); pyAsym510->SetLineColor(4); pyAsym510->Draw(); c5b->cd(4) ; imbinmin = (Int_t) (10-emin)*nebins/emax; imbinmax = -1; TH1D *pyAsym10 = fhAsym->ProjectionY(Form("%s_py10",fhAsym->GetName()),imbinmin,imbinmax); pyAsym10->SetTitle("E_{pair} > 10 GeV"); pyAsym10->SetLineColor(4); pyAsym10->Draw(); snprintf(name,buffersize,"QA_%s_Asymmetry.eps",fCalorimeter.Data()); c5b->Print(name); printf("Plot: %s\n",name); } if(IsDataMC()){ //Reconstructed vs MC distributions //printf("c6\n"); snprintf(cname,buffersize,"QA_%s_recvsmc",fCalorimeter.Data()); TCanvas * c6 = new TCanvas(cname, "Reconstructed vs MC distributions", 400, 400) ; c6->Divide(2, 2); c6->cd(1) ; fh2E->SetTitleOffset(1.6,"Y"); fh2E->SetLineColor(4); fh2E->Draw(); c6->cd(2) ; fh2Pt->SetTitleOffset(1.6,"Y"); fh2Pt->SetLineColor(4); fh2Pt->Draw(); c6->cd(3) ; fh2Phi->SetTitleOffset(1.6,"Y"); fh2Phi->SetLineColor(4); fh2Phi->Draw(); c6->cd(4) ; fh2Eta->SetTitleOffset(1.6,"Y"); fh2Eta->SetLineColor(4); fh2Eta->Draw(); snprintf(name,buffersize,"QA_%s_ReconstructedVSMCDistributions.eps",fCalorimeter.Data()); c6->Print(name); printf("Plot: %s\n",name); //Reconstructed vs MC distributions //printf("c6\n"); snprintf(cname,buffersize,"QA_%s_gamrecvsmc",fCalorimeter.Data()); TCanvas * c6Gam = new TCanvas(cname, "Reconstructed vs MC distributions", 400, 400) ; c6Gam->Divide(2, 2); c6Gam->cd(1) ; fhGamE->Draw(); c6Gam->cd(2) ; fhGamPt->Draw(); c6Gam->cd(3) ; fhGamPhi->Draw(); c6Gam->cd(4) ; fhGamEta->Draw(); snprintf(name,buffersize,"QA_%s_GammaReconstructedVSMCDistributions.eps",fCalorimeter.Data()); c6->Print(name); printf("Plot: %s\n",name); //Generated - reconstructed //printf("c7\n"); snprintf(cname,buffersize,"QA_%s_diffgenrec",fCalorimeter.Data()); TCanvas * c7 = new TCanvas(cname, "generated - reconstructed", 400, 400) ; c7->Divide(2, 2); c7->cd(1) ; if(fhDeltaE->GetEntries() > 0) gPad->SetLogy(); fhGamDeltaE->SetLineColor(4); fhDeltaE->Draw(); fhGamDeltaE->Draw("same"); TLegend pLegendd(0.65,0.55,0.9,0.8); pLegendd.SetTextSize(0.06); pLegendd.AddEntry(fhDeltaE,"all","L"); pLegendd.AddEntry(fhGamDeltaE,"from #gamma","L"); pLegendd.SetFillColor(10); pLegendd.SetBorderSize(1); pLegendd.Draw(); c7->cd(2) ; if(fhDeltaPt->GetEntries() > 0) gPad->SetLogy(); fhGamDeltaPt->SetLineColor(4); fhDeltaPt->Draw(); fhGamDeltaPt->Draw("same"); c7->cd(3) ; fhGamDeltaPhi->SetLineColor(4); fhDeltaPhi->Draw(); fhGamDeltaPhi->Draw("same"); c7->cd(4) ; fhGamDeltaEta->SetLineColor(4); fhDeltaEta->Draw(); fhGamDeltaEta->Draw("same"); snprintf(name,buffersize,"QA_%s_DiffGeneratedReconstructed.eps",fCalorimeter.Data()); c7->Print(name); printf("Plot: %s\n",name); // Reconstructed / Generated //printf("c8\n"); snprintf(cname,buffersize,"QA_%s_ratiorecgen",fCalorimeter.Data()); TCanvas * c8 = new TCanvas(cname, " reconstructed / generated", 400, 400) ; c8->Divide(2, 2); c8->cd(1) ; if(fhRatioE->GetEntries() > 0) gPad->SetLogy(); fhGamRatioE->SetLineColor(4); fhRatioE->Draw(); fhGamRatioE->Draw("same"); TLegend pLegendr(0.65,0.55,0.9,0.8); pLegendr.SetTextSize(0.06); pLegendr.AddEntry(fhRatioE,"all","L"); pLegendr.AddEntry(fhGamRatioE,"from #gamma","L"); pLegendr.SetFillColor(10); pLegendr.SetBorderSize(1); pLegendr.Draw(); c8->cd(2) ; if(fhRatioPt->GetEntries() > 0) gPad->SetLogy(); fhGamRatioPt->SetLineColor(4); fhRatioPt->Draw(); fhGamRatioPt->Draw("same"); c8->cd(3) ; fhGamRatioPhi->SetLineColor(4); fhRatioPhi->Draw(); fhGamRatioPhi->Draw("same"); c8->cd(4) ; fhGamRatioEta->SetLineColor(4); fhRatioEta->Draw(); fhGamRatioEta->Draw("same"); snprintf(name,buffersize,"QA_%s_ReconstructedDivGenerated.eps",fCalorimeter.Data()); c8->Print(name); printf("Plot: %s\n",name); //MC //Generated distributions //printf("c1\n"); snprintf(cname,buffersize,"QA_%s_gen",fCalorimeter.Data()); TCanvas * c10 = new TCanvas(cname, "Generated distributions", 600, 200) ; c10->Divide(3, 1); c10->cd(1) ; gPad->SetLogy(); TH1F * haxispt = (TH1F*) fhGenPi0Pt->Clone(Form("%s_axispt",fhGenPi0Pt->GetName())); haxispt->SetTitle("Generated Particles p_{T}, |#eta| < 1"); fhGenPi0Pt->SetLineColor(1); fhGenGamPt->SetLineColor(4); fhGenEtaPt->SetLineColor(2); fhGenOmegaPt->SetLineColor(7); fhGenElePt->SetLineColor(6); //Select the maximum of the histogram to show all lines. if(fhGenPi0Pt->GetMaximum() >= fhGenGamPt->GetMaximum() && fhGenPi0Pt->GetMaximum() >= fhGenEtaPt->GetMaximum() && fhGenPi0Pt->GetMaximum() >= fhGenOmegaPt->GetMaximum() && fhGenPi0Pt->GetMaximum() >= fhGenElePt->GetMaximum()) haxispt->SetMaximum(fhGenPi0Pt->GetMaximum()); else if(fhGenGamPt->GetMaximum() >= fhGenPi0Pt->GetMaximum() && fhGenGamPt->GetMaximum() >= fhGenEtaPt->GetMaximum() && fhGenGamPt->GetMaximum() >= fhGenOmegaPt->GetMaximum() && fhGenGamPt->GetMaximum() >= fhGenElePt->GetMaximum()) haxispt->SetMaximum(fhGenGamPt->GetMaximum()); else if(fhGenEtaPt->GetMaximum() >= fhGenPi0Pt->GetMaximum() && fhGenEtaPt->GetMaximum() >= fhGenGamPt->GetMaximum() && fhGenEtaPt->GetMaximum() >= fhGenOmegaPt->GetMaximum() && fhGenEtaPt->GetMaximum() >= fhGenElePt->GetMaximum()) haxispt->SetMaximum(fhGenEtaPt->GetMaximum()); else if(fhGenOmegaPt->GetMaximum() >= fhGenPi0Pt->GetMaximum() && fhGenOmegaPt->GetMaximum() >= fhGenEtaPt->GetMaximum() && fhGenOmegaPt->GetMaximum() >= fhGenGamPt->GetMaximum() && fhGenOmegaPt->GetMaximum() >= fhGenElePt->GetMaximum()) haxispt->SetMaximum(fhGenOmegaPt->GetMaximum()); else if(fhGenElePt->GetMaximum() >= fhGenPi0Pt->GetMaximum() && fhGenElePt->GetMaximum() >= fhGenEtaPt->GetMaximum() && fhGenElePt->GetMaximum() >= fhGenOmegaPt->GetMaximum() && fhGenElePt->GetMaximum() >= fhGenGamPt->GetMaximum()) haxispt->SetMaximum(fhGenElePt->GetMaximum()); haxispt->SetMinimum(1); haxispt->Draw("axis"); fhGenPi0Pt->Draw("same"); fhGenGamPt->Draw("same"); fhGenEtaPt->Draw("same"); fhGenOmegaPt->Draw("same"); fhGenElePt->Draw("same"); TLegend pLegend(0.85,0.65,0.95,0.93); pLegend.SetTextSize(0.06); pLegend.AddEntry(fhGenPi0Pt," #pi^{0}","L"); pLegend.AddEntry(fhGenGamPt," #gamma","L"); pLegend.AddEntry(fhGenEtaPt," #eta","L"); pLegend.AddEntry(fhGenOmegaPt," #omega","L"); pLegend.AddEntry(fhGenElePt," e^{#pm}","L"); pLegend.SetFillColor(10); pLegend.SetBorderSize(1); pLegend.Draw(); c10->cd(2) ; gPad->SetLogy(); TH1F * haxiseta = (TH1F*) fhGenPi0Eta->Clone(Form("%s_axiseta",fhGenPi0Eta->GetName())); haxiseta->SetTitle("Generated Particles #eta, |#eta| < 1"); fhGenPi0Eta->SetLineColor(1); fhGenGamEta->SetLineColor(4); fhGenEtaEta->SetLineColor(2); fhGenOmegaEta->SetLineColor(7); fhGenEleEta->SetLineColor(6); //Select the maximum of the histogram to show all lines. if(fhGenPi0Eta->GetMaximum() >= fhGenGamEta->GetMaximum() && fhGenPi0Eta->GetMaximum() >= fhGenEtaEta->GetMaximum() && fhGenPi0Eta->GetMaximum() >= fhGenOmegaEta->GetMaximum() && fhGenPi0Eta->GetMaximum() >= fhGenEleEta->GetMaximum()) haxiseta->SetMaximum(fhGenPi0Eta->GetMaximum()); else if(fhGenGamEta->GetMaximum() >= fhGenPi0Eta->GetMaximum() && fhGenGamEta->GetMaximum() >= fhGenEtaEta->GetMaximum() && fhGenGamEta->GetMaximum() >= fhGenOmegaEta->GetMaximum() && fhGenGamEta->GetMaximum() >= fhGenEleEta->GetMaximum()) haxiseta->SetMaximum(fhGenGamEta->GetMaximum()); else if(fhGenEtaEta->GetMaximum() >= fhGenPi0Eta->GetMaximum() && fhGenEtaEta->GetMaximum() >= fhGenGamEta->GetMaximum() && fhGenEtaEta->GetMaximum() >= fhGenOmegaEta->GetMaximum() && fhGenEtaEta->GetMaximum() >= fhGenEleEta->GetMaximum()) haxiseta->SetMaximum(fhGenEtaEta->GetMaximum()); else if(fhGenOmegaEta->GetMaximum() >= fhGenPi0Eta->GetMaximum() && fhGenOmegaEta->GetMaximum() >= fhGenEtaEta->GetMaximum() && fhGenOmegaEta->GetMaximum() >= fhGenGamEta->GetMaximum() && fhGenOmegaEta->GetMaximum() >= fhGenEleEta->GetMaximum()) haxiseta->SetMaximum(fhGenOmegaEta->GetMaximum()); else if(fhGenEleEta->GetMaximum() >= fhGenPi0Eta->GetMaximum() && fhGenEleEta->GetMaximum() >= fhGenEtaEta->GetMaximum() && fhGenEleEta->GetMaximum() >= fhGenOmegaEta->GetMaximum() && fhGenEleEta->GetMaximum() >= fhGenGamEta->GetMaximum()) haxiseta->SetMaximum(fhGenEleEta->GetMaximum()); haxiseta->SetMinimum(100); haxiseta->Draw("axis"); fhGenPi0Eta->Draw("same"); fhGenGamEta->Draw("same"); fhGenEtaEta->Draw("same"); fhGenOmegaEta->Draw("same"); fhGenEleEta->Draw("same"); c10->cd(3) ; gPad->SetLogy(); TH1F * haxisphi = (TH1F*) fhGenPi0Phi->Clone(Form("%s_axisphi",fhGenPi0Phi->GetName())); haxisphi->SetTitle("Generated Particles #phi, |#eta| < 1"); fhGenPi0Phi->SetLineColor(1); fhGenGamPhi->SetLineColor(4); fhGenEtaPhi->SetLineColor(2); fhGenOmegaPhi->SetLineColor(7); fhGenElePhi->SetLineColor(6); //Select the maximum of the histogram to show all lines. if(fhGenPi0Phi->GetMaximum() >= fhGenGamPhi->GetMaximum() && fhGenPi0Phi->GetMaximum() >= fhGenEtaPhi->GetMaximum() && fhGenPi0Phi->GetMaximum() >= fhGenOmegaPhi->GetMaximum() && fhGenPi0Phi->GetMaximum() >= fhGenElePhi->GetMaximum()) haxisphi->SetMaximum(fhGenPi0Phi->GetMaximum()); else if(fhGenGamPhi->GetMaximum() >= fhGenPi0Phi->GetMaximum() && fhGenGamPhi->GetMaximum() >= fhGenEtaPhi->GetMaximum() && fhGenGamPhi->GetMaximum() >= fhGenOmegaPhi->GetMaximum() && fhGenGamPhi->GetMaximum() >= fhGenElePhi->GetMaximum()) haxisphi->SetMaximum(fhGenGamPhi->GetMaximum()); else if(fhGenEtaPhi->GetMaximum() >= fhGenPi0Phi->GetMaximum() && fhGenEtaPhi->GetMaximum() >= fhGenGamPhi->GetMaximum() && fhGenEtaPhi->GetMaximum() >= fhGenOmegaPhi->GetMaximum() && fhGenEtaPhi->GetMaximum() >= fhGenElePhi->GetMaximum()) haxisphi->SetMaximum(fhGenEtaPhi->GetMaximum()); else if(fhGenOmegaPhi->GetMaximum() >= fhGenPi0Phi->GetMaximum() && fhGenOmegaPhi->GetMaximum() >= fhGenEtaPhi->GetMaximum() && fhGenOmegaPhi->GetMaximum() >= fhGenGamPhi->GetMaximum() && fhGenOmegaPhi->GetMaximum() >= fhGenElePhi->GetMaximum()) haxisphi->SetMaximum(fhGenOmegaPhi->GetMaximum()); else if(fhGenElePhi->GetMaximum() >= fhGenPi0Phi->GetMaximum() && fhGenElePhi->GetMaximum() >= fhGenEtaPhi->GetMaximum() && fhGenElePhi->GetMaximum() >= fhGenOmegaPhi->GetMaximum() && fhGenElePhi->GetMaximum() >= fhGenGamPhi->GetMaximum()) haxisphi->SetMaximum(fhGenElePhi->GetMaximum()); haxisphi->SetMinimum(100); haxisphi->Draw("axis"); fhGenPi0Phi->Draw("same"); fhGenGamPhi->Draw("same"); fhGenEtaPhi->Draw("same"); fhGenOmegaPhi->Draw("same"); fhGenElePhi->Draw("same"); snprintf(name,buffersize,"QA_%s_GeneratedDistributions.eps",fCalorimeter.Data()); c10->Print(name); printf("Plot: %s\n",name); //Reconstructed clusters depending on its original particle. //printf("c1\n"); snprintf(cname,buffersize,"QA_%s_recgenid",fCalorimeter.Data()); TCanvas * c11 = new TCanvas(cname, "Reconstructed particles, function of their original particle ID", 400, 400) ; c11->Divide(2, 2); c11->cd(1) ; gPad->SetLogy(); TH1F * hGamE = (TH1F*) fhGamE->ProjectionX(Form("%s_px",fhGamE->GetName()),-1,-1); TH1F * hPi0E = (TH1F*) fhPi0E->ProjectionX(Form("%s_px",fhPi0E->GetName()),-1,-1); TH1F * hEleE = (TH1F*) fhEleE->ProjectionX(Form("%s_px",fhEleE->GetName()),-1,-1); TH1F * hNeHadE = (TH1F*) fhNeHadE->ProjectionX(Form("%s_px",fhNeHadE->GetName()),-1,-1); TH1F * hChHadE = (TH1F*) fhChHadE->ProjectionX(Form("%s_px",fhChHadE->GetName()),-1,-1); TH1F * haxisE = (TH1F*) hPi0E->Clone(Form("%s_axisE",fhPi0E->GetName())); haxisE->SetTitle("Reconstructed particles E, function of their original particle ID"); hPi0E->SetLineColor(1); hGamE->SetLineColor(4); hNeHadE->SetLineColor(2); hChHadE->SetLineColor(7); hEleE->SetLineColor(6); //Select the maximum of the histogram to show all lines. if(hPi0E->GetMaximum() >= hGamE->GetMaximum() && hPi0E->GetMaximum() >= hNeHadE->GetMaximum() && hPi0E->GetMaximum() >= hChHadE->GetMaximum() && hPi0E->GetMaximum() >= hEleE->GetMaximum()) haxisE->SetMaximum(hPi0E->GetMaximum()); else if(hGamE->GetMaximum() >= hPi0E->GetMaximum() && hGamE->GetMaximum() >= hNeHadE->GetMaximum() && hGamE->GetMaximum() >= hChHadE->GetMaximum() && hGamE->GetMaximum() >= hEleE->GetMaximum()) haxisE->SetMaximum(hGamE->GetMaximum()); else if(hNeHadE->GetMaximum() >= hPi0E->GetMaximum() && hNeHadE->GetMaximum() >= hGamE->GetMaximum() && hNeHadE->GetMaximum() >= hChHadE->GetMaximum() && hNeHadE->GetMaximum() >= hEleE->GetMaximum()) haxisE->SetMaximum(hNeHadE->GetMaximum()); else if(hChHadE->GetMaximum() >= hPi0E->GetMaximum() && hChHadE->GetMaximum() >= hNeHadE->GetMaximum() && hChHadE->GetMaximum() >= hGamE->GetMaximum() && hChHadE->GetMaximum() >= hEleE->GetMaximum()) haxisE->SetMaximum(hChHadE->GetMaximum()); else if(hEleE->GetMaximum() >= hPi0E->GetMaximum() && hEleE->GetMaximum() >= hNeHadE->GetMaximum() && hEleE->GetMaximum() >= hChHadE->GetMaximum() && hEleE->GetMaximum() >= hGamE->GetMaximum()) haxisE->SetMaximum(hEleE->GetMaximum()); haxisE->SetXTitle("E (GeV)"); haxisE->SetMinimum(1); haxisE->Draw("axis"); hPi0E->Draw("same"); hGamE->Draw("same"); hNeHadE->Draw("same"); hChHadE->Draw("same"); hEleE->Draw("same"); TLegend pLegend2(0.8,0.65,0.95,0.93); pLegend2.SetTextSize(0.06); pLegend2.AddEntry(hPi0E," #pi^{0}","L"); pLegend2.AddEntry(hGamE," #gamma","L"); pLegend2.AddEntry(hEleE," e^{#pm}","L"); pLegend2.AddEntry(hChHadE," h^{#pm}","L"); pLegend2.AddEntry(hNeHadE," h^{0}","L"); pLegend2.SetFillColor(10); pLegend2.SetBorderSize(1); pLegend2.Draw(); c11->cd(2) ; gPad->SetLogy(); //printf("%s, %s, %s, %s, %s\n",fhGamPt->GetName(),fhPi0Pt->GetName(),fhElePt->GetName(),fhNeHadPt->GetName(), fhChHadPt->GetName()); TH1F * hGamPt = (TH1F*) fhGamPt->ProjectionX(Form("%s_px",fhGamPt->GetName()),-1,-1); TH1F * hPi0Pt = (TH1F*) fhPi0Pt->ProjectionX(Form("%s_px",fhPi0Pt->GetName()),-1,-1); TH1F * hElePt = (TH1F*) fhElePt->ProjectionX(Form("%s_px",fhElePt->GetName()),-1,-1); TH1F * hNeHadPt = (TH1F*) fhNeHadPt->ProjectionX(Form("%s_px",fhNeHadPt->GetName()),-1,-1); TH1F * hChHadPt = (TH1F*) fhChHadPt->ProjectionX(Form("%s_px",fhChHadPt->GetName()),-1,-1); haxispt = (TH1F*) hPi0Pt->Clone(Form("%s_axisPt",fhPi0Pt->GetName())); haxispt->SetTitle("Reconstructed particles p_{T}, function of their original particle ID"); hPi0Pt->SetLineColor(1); hGamPt->SetLineColor(4); hNeHadPt->SetLineColor(2); hChHadPt->SetLineColor(7); hElePt->SetLineColor(6); //Select the maximum of the histogram to show all lines. if(hPi0Pt->GetMaximum() >= hGamPt->GetMaximum() && hPi0Pt->GetMaximum() >= hNeHadPt->GetMaximum() && hPi0Pt->GetMaximum() >= hChHadPt->GetMaximum() && hPi0Pt->GetMaximum() >= hElePt->GetMaximum()) haxispt->SetMaximum(hPi0Pt->GetMaximum()); else if(hGamPt->GetMaximum() >= hPi0Pt->GetMaximum() && hGamPt->GetMaximum() >= hNeHadPt->GetMaximum() && hGamPt->GetMaximum() >= hChHadPt->GetMaximum() && hGamPt->GetMaximum() >= hElePt->GetMaximum()) haxispt->SetMaximum(hGamPt->GetMaximum()); else if(hNeHadPt->GetMaximum() >= hPi0Pt->GetMaximum() && hNeHadPt->GetMaximum() >= hGamPt->GetMaximum() && hNeHadPt->GetMaximum() >= hChHadPt->GetMaximum() && hNeHadPt->GetMaximum() >= hElePt->GetMaximum()) haxispt->SetMaximum(hNeHadPt->GetMaximum()); else if(hChHadPt->GetMaximum() >= hPi0Pt->GetMaximum() && hChHadPt->GetMaximum() >= hNeHadPt->GetMaximum() && hChHadPt->GetMaximum() >= hGamPt->GetMaximum() && hChHadPt->GetMaximum() >= hElePt->GetMaximum()) haxispt->SetMaximum(hChHadPt->GetMaximum()); else if(hElePt->GetMaximum() >= hPi0Pt->GetMaximum() && hElePt->GetMaximum() >= hNeHadPt->GetMaximum() && hElePt->GetMaximum() >= hChHadPt->GetMaximum() && hElePt->GetMaximum() >= hGamPt->GetMaximum()) haxispt->SetMaximum(hElePt->GetMaximum()); haxispt->SetXTitle("p_{T} (GeV/c)"); haxispt->SetMinimum(1); haxispt->Draw("axis"); hPi0Pt->Draw("same"); hGamPt->Draw("same"); hNeHadPt->Draw("same"); hChHadPt->Draw("same"); hElePt->Draw("same"); c11->cd(3) ; gPad->SetLogy(); TH1F * hGamEta = (TH1F*) fhGamEta->ProjectionX(Form("%s_px",fhGamEta->GetName()),-1,-1); TH1F * hPi0Eta = (TH1F*) fhPi0Eta->ProjectionX(Form("%s_px",fhPi0Eta->GetName()),-1,-1); TH1F * hEleEta = (TH1F*) fhEleEta->ProjectionX(Form("%s_px",fhEleEta->GetName()),-1,-1); TH1F * hNeHadEta = (TH1F*) fhNeHadEta->ProjectionX(Form("%s_px",fhNeHadEta->GetName()),-1,-1); TH1F * hChHadEta = (TH1F*) fhChHadEta->ProjectionX(Form("%s_px",fhChHadEta->GetName()),-1,-1); haxiseta = (TH1F*) hPi0Eta->Clone(Form("%s_axisEta",fhPi0Eta->GetName())); haxiseta->SetTitle("Reconstructed particles #eta, function of their original particle ID"); hPi0Eta->SetLineColor(1); hGamEta->SetLineColor(4); hNeHadEta->SetLineColor(2); hChHadEta->SetLineColor(7); hEleEta->SetLineColor(6); //Select the maximum of the histogram to show all lines. if(hPi0Eta->GetMaximum() >= hGamEta->GetMaximum() && hPi0Eta->GetMaximum() >= hNeHadEta->GetMaximum() && hPi0Eta->GetMaximum() >= hChHadEta->GetMaximum() && hPi0Eta->GetMaximum() >= hEleEta->GetMaximum()) haxiseta->SetMaximum(hPi0Eta->GetMaximum()); else if(hGamEta->GetMaximum() >= hPi0Eta->GetMaximum() && hGamEta->GetMaximum() >= hNeHadEta->GetMaximum() && hGamEta->GetMaximum() >= hChHadEta->GetMaximum() && hGamEta->GetMaximum() >= hEleEta->GetMaximum()) haxiseta->SetMaximum(hGamEta->GetMaximum()); else if(hNeHadEta->GetMaximum() >= hPi0Eta->GetMaximum() && hNeHadEta->GetMaximum() >= hGamEta->GetMaximum() && hNeHadEta->GetMaximum() >= hChHadEta->GetMaximum() && hNeHadEta->GetMaximum() >= hEleEta->GetMaximum()) haxiseta->SetMaximum(hNeHadEta->GetMaximum()); else if(hChHadEta->GetMaximum() >= hPi0Eta->GetMaximum() && hChHadEta->GetMaximum() >= hNeHadEta->GetMaximum() && hChHadEta->GetMaximum() >= hGamEta->GetMaximum() && hChHadEta->GetMaximum() >= hEleEta->GetMaximum()) haxiseta->SetMaximum(hChHadEta->GetMaximum()); else if(hEleEta->GetMaximum() >= hPi0Eta->GetMaximum() && hEleEta->GetMaximum() >= hNeHadEta->GetMaximum() && hEleEta->GetMaximum() >= hChHadEta->GetMaximum() && hEleEta->GetMaximum() >= hGamEta->GetMaximum()) haxiseta->SetMaximum(hEleEta->GetMaximum()); haxiseta->SetXTitle("#eta"); haxiseta->Draw("axis"); hPi0Eta->Draw("same"); hGamEta->Draw("same"); hNeHadEta->Draw("same"); hChHadEta->Draw("same"); hEleEta->Draw("same"); c11->cd(4) ; gPad->SetLogy(); TH1F * hGamPhi = (TH1F*) fhGamPhi->ProjectionX(Form("%s_px",fhGamPhi->GetName()),-1,-1); TH1F * hPi0Phi = (TH1F*) fhPi0Phi->ProjectionX(Form("%s_px",fhPi0Phi->GetName()),-1,-1); TH1F * hElePhi = (TH1F*) fhElePhi->ProjectionX(Form("%s_px",fhElePhi->GetName()),-1,-1); TH1F * hNeHadPhi = (TH1F*) fhNeHadPhi->ProjectionX(Form("%s_px",fhNeHadPhi->GetName()),-1,-1); TH1F * hChHadPhi = (TH1F*) fhChHadPhi->ProjectionX(Form("%s_px",fhChHadPhi->GetName()),-1,-1); haxisphi = (TH1F*) hPi0Phi->Clone(Form("%s_axisPhi",fhPi0Phi->GetName())); haxisphi->SetTitle("Reconstructed particles #phi, function of their original particle ID"); hPi0Phi->SetLineColor(1); hGamPhi->SetLineColor(4); hNeHadPhi->SetLineColor(2); hChHadPhi->SetLineColor(7); hElePhi->SetLineColor(6); //Select the maximum of the histogram to show all lines. if(hPi0Phi->GetMaximum() >= hGamPhi->GetMaximum() && hPi0Phi->GetMaximum() >= hNeHadPhi->GetMaximum() && hPi0Phi->GetMaximum() >= hChHadPhi->GetMaximum() && hPi0Phi->GetMaximum() >= hElePhi->GetMaximum()) haxisphi->SetMaximum(hPi0Phi->GetMaximum()); else if(hGamPhi->GetMaximum() >= hPi0Phi->GetMaximum() && hGamPhi->GetMaximum() >= hNeHadPhi->GetMaximum() && hGamPhi->GetMaximum() >= hChHadPhi->GetMaximum() && hGamPhi->GetMaximum() >= hElePhi->GetMaximum()) haxisphi->SetMaximum(hGamPhi->GetMaximum()); else if(hNeHadPhi->GetMaximum() >= hPi0Phi->GetMaximum() && hNeHadPhi->GetMaximum() >= hGamPhi->GetMaximum() && hNeHadPhi->GetMaximum() >= hChHadPhi->GetMaximum() && hNeHadPhi->GetMaximum() >= hElePhi->GetMaximum()) haxisphi->SetMaximum(hNeHadPhi->GetMaximum()); else if(hChHadPhi->GetMaximum() >= hPi0Phi->GetMaximum() && hChHadPhi->GetMaximum() >= hNeHadPhi->GetMaximum() && hChHadPhi->GetMaximum() >= hGamPhi->GetMaximum() && hChHadPhi->GetMaximum() >= hElePhi->GetMaximum()) haxisphi->SetMaximum(hChHadPhi->GetMaximum()); else if(hElePhi->GetMaximum() >= hPi0Phi->GetMaximum() && hElePhi->GetMaximum() >= hNeHadPhi->GetMaximum() && hElePhi->GetMaximum() >= hChHadPhi->GetMaximum() && hElePhi->GetMaximum() >= hGamPhi->GetMaximum()) haxisphi->SetMaximum(hElePhi->GetMaximum()); haxisphi->SetXTitle("#phi (rad)"); haxisphi->Draw("axis"); hPi0Phi->Draw("same"); hGamPhi->Draw("same"); hNeHadPhi->Draw("same"); hChHadPhi->Draw("same"); hElePhi->Draw("same"); snprintf(name,buffersize,"QA_%s_RecDistributionsGenID.eps",fCalorimeter.Data()); c11->Print(name); printf("Plot: %s\n",name); //Ratio reconstructed clusters / generated particles in acceptance, for different particle ID //printf("c1\n"); TH1F * hPi0EClone = (TH1F*) hPi0E ->Clone(Form("%s_Clone",fhPi0E->GetName())); TH1F * hGamEClone = (TH1F*) hGamE ->Clone(Form("%s_Clone",fhGamE->GetName())); TH1F * hPi0PtClone = (TH1F*) hPi0Pt ->Clone(Form("%s_Clone",fhPi0Pt->GetName())); TH1F * hGamPtClone = (TH1F*) hGamPt ->Clone(Form("%s_Clone",fhGamPt->GetName())); TH1F * hPi0EtaClone = (TH1F*) hPi0Eta->Clone(Form("%s_Clone",fhPi0Eta->GetName())); TH1F * hGamEtaClone = (TH1F*) hGamEta->Clone(Form("%s_Clone",fhGamEta->GetName())); TH1F * hPi0PhiClone = (TH1F*) hPi0Phi->Clone(Form("%s_Clone",fhPi0Phi->GetName())); TH1F * hGamPhiClone = (TH1F*) hGamPhi->Clone(Form("%s_Clone",fhGamPhi->GetName())); snprintf(cname,buffersize,"QA_%s_recgenidratio",fCalorimeter.Data()); TCanvas * c12 = new TCanvas(cname, "Ratio reconstructed clusters / generated particles in acceptance, for different particle ID", 400, 400) ; c12->Divide(2, 2); c12->cd(1) ; gPad->SetLogy(); haxisE->SetTitle("Ratio reconstructed clusters / generated particles in acceptance, for different particle ID"); hPi0EClone->Divide(fhGenPi0AccE); hGamEClone->Divide(fhGenGamAccE); haxisE->SetMaximum(5); haxisE->SetMinimum(1e-2); haxisE->SetXTitle("E (GeV)"); haxisE->SetYTitle("ratio = rec/gen"); haxisE->Draw("axis"); hPi0E->Draw("same"); hGamE->Draw("same"); TLegend pLegend3(0.75,0.2,0.9,0.4); pLegend3.SetTextSize(0.06); pLegend3.AddEntry(hPi0EClone," #pi^{0}","L"); pLegend3.AddEntry(hGamEClone," #gamma","L"); pLegend3.SetFillColor(10); pLegend3.SetBorderSize(1); pLegend3.Draw(); c12->cd(2) ; gPad->SetLogy(); haxispt->SetTitle("Ratio reconstructed clusters / generated particles in acceptance, for different particle ID"); hPi0PtClone->Divide(fhGenPi0AccPt); hGamPtClone->Divide(fhGenGamAccPt); haxispt->SetMaximum(5); haxispt->SetMinimum(1e-2); haxispt->SetXTitle("p_{T} (GeV/c)"); haxispt->SetYTitle("ratio = rec/gen"); haxispt->Draw("axis"); hPi0PtClone->Draw("same"); hGamPtClone->Draw("same"); c12->cd(3) ; gPad->SetLogy(); haxiseta->SetTitle("Ratio reconstructed clusters / generated particles in acceptance, for different particle ID"); hPi0EtaClone->Divide(fhGenPi0AccEta); hGamEtaClone->Divide(fhGenGamAccEta); haxiseta->SetMaximum(1.2); haxiseta->SetMinimum(1e-2); haxiseta->SetYTitle("ratio = rec/gen"); haxiseta->SetXTitle("#eta"); haxiseta->Draw("axis"); hPi0EtaClone->Draw("same"); hGamEtaClone->Draw("same"); c12->cd(4) ; gPad->SetLogy(); haxisphi->SetTitle("Ratio reconstructed clusters / generated particles in acceptance, for different particle ID"); hPi0PhiClone->Divide(fhGenPi0AccPhi); hGamPhiClone->Divide(fhGenGamAccPhi); haxisphi->SetYTitle("ratio = rec/gen"); haxisphi->SetXTitle("#phi (rad)"); haxisphi->SetMaximum(1.2); haxisphi->SetMinimum(1e-2); haxisphi->Draw("axis"); hPi0PhiClone->Draw("same"); hGamPhiClone->Draw("same"); snprintf(name,buffersize,"QA_%s_EfficiencyGenID.eps",fCalorimeter.Data()); c12->Print(name); printf("Plot: %s\n",name); //Reconstructed distributions //printf("c1\n"); snprintf(cname,buffersize,"QA_%s_vertex",fCalorimeter.Data()); TCanvas * c13 = new TCanvas(cname, "Particle vertex", 400, 400) ; c13->Divide(2, 2); c13->cd(1) ; //gPad->SetLogy(); fhEMVxyz->SetTitleOffset(1.6,"Y"); fhEMVxyz->Draw(); c13->cd(2) ; //gPad->SetLogy(); fhHaVxyz->SetTitleOffset(1.6,"Y"); fhHaVxyz->Draw(); c13->cd(3) ; gPad->SetLogy(); TH1F * hEMR = (TH1F*) fhEMR->ProjectionY(Form("%s_py",fhEMR->GetName()),-1,-1); hEMR->SetLineColor(4); hEMR->Draw(); c13->cd(4) ; gPad->SetLogy(); TH1F * hHaR = (TH1F*) fhHaR->ProjectionY(Form("%s_py",fhHaR->GetName()),-1,-1); hHaR->SetLineColor(4); hHaR->Draw(); snprintf(name,buffersize,"QA_%s_ParticleVertex.eps",fCalorimeter.Data()); c13->Print(name); printf("Plot: %s\n",name); //Track-matching distributions if(fFillAllTH12){ //Reconstructed distributions, matched with tracks, generated particle dependence //printf("c2\n"); snprintf(cname,buffersize,"QA_%s_rectrackmatchGenID",fCalorimeter.Data()); TCanvas * c22ch = new TCanvas(cname, "Reconstructed distributions, matched with tracks, for different particle ID", 400, 400) ; c22ch->Divide(2, 2); c22ch->cd(1) ; TH1F * hGamECharged = (TH1F*) fhGamECharged->ProjectionX(Form("%s_px",fhGamECharged->GetName()),-1,-1); TH1F * hPi0ECharged = (TH1F*) fhPi0ECharged->ProjectionX(Form("%s_px",fhPi0ECharged->GetName()),-1,-1); TH1F * hEleECharged = (TH1F*) fhEleECharged->ProjectionX(Form("%s_px",fhEleECharged->GetName()),-1,-1); TH1F * hNeHadECharged = (TH1F*) fhNeHadECharged->ProjectionX(Form("%s_px",fhNeHadECharged->GetName()),-1,-1); TH1F * hChHadECharged = (TH1F*) fhChHadECharged->ProjectionX(Form("%s_px",fhChHadECharged->GetName()),-1,-1); hPi0ECharged->SetLineColor(1); hGamECharged->SetLineColor(4); hNeHadECharged->SetLineColor(2); hChHadECharged->SetLineColor(7); hEleECharged->SetLineColor(6); gPad->SetLogy(); fhECharged->SetLineColor(3); fhECharged->SetMinimum(0.5); fhECharged->Draw(); hPi0ECharged->Draw("same"); hGamECharged->Draw("same"); hNeHadECharged->Draw("same"); hChHadECharged->Draw("same"); hEleECharged->Draw("same"); TLegend pLegend22(0.75,0.45,0.9,0.8); pLegend22.SetTextSize(0.06); pLegend22.AddEntry(fhECharged,"all","L"); pLegend22.AddEntry(hPi0ECharged,"#pi^{0}","L"); pLegend22.AddEntry(hGamECharged,"#gamma","L"); pLegend22.AddEntry(hEleECharged,"e^{#pm}","L"); pLegend22.AddEntry(hChHadECharged,"h^{#pm}","L"); pLegend22.AddEntry(hNeHadECharged,"h^{0}","L"); pLegend22.SetFillColor(10); pLegend22.SetBorderSize(1); pLegend22.Draw(); c22ch->cd(2) ; TH1F * hGamPtCharged = (TH1F*) fhGamPtCharged->ProjectionX(Form("%s_px",fhGamPtCharged->GetName()),-1,-1); TH1F * hPi0PtCharged = (TH1F*) fhPi0PtCharged->ProjectionX(Form("%s_px",fhPi0PtCharged->GetName()),-1,-1); TH1F * hElePtCharged = (TH1F*) fhElePtCharged->ProjectionX(Form("%s_px",fhElePtCharged->GetName()),-1,-1); TH1F * hNeHadPtCharged = (TH1F*) fhNeHadPtCharged->ProjectionX(Form("%s_px",fhNeHadPtCharged->GetName()),-1,-1); TH1F * hChHadPtCharged = (TH1F*) fhChHadPtCharged->ProjectionX(Form("%s_px",fhChHadPtCharged->GetName()),-1,-1); hPi0PtCharged->SetLineColor(1); hGamPtCharged->SetLineColor(4); hNeHadPtCharged->SetLineColor(2); hChHadPtCharged->SetLineColor(7); hElePtCharged->SetLineColor(6); gPad->SetLogy(); fhPtCharged->SetLineColor(3); fhPtCharged->SetMinimum(0.5); fhPtCharged->Draw(); hPi0PtCharged->Draw("same"); hGamPtCharged->Draw("same"); hNeHadPtCharged->Draw("same"); hChHadPtCharged->Draw("same"); hElePtCharged->Draw("same"); c22ch->cd(4) ; TH1F * hGamEtaCharged = (TH1F*) fhGamEtaCharged->ProjectionX(Form("%s_px",fhGamEtaCharged->GetName()),-1,-1); TH1F * hPi0EtaCharged = (TH1F*) fhPi0EtaCharged->ProjectionX(Form("%s_px",fhPi0EtaCharged->GetName()),-1,-1); TH1F * hEleEtaCharged = (TH1F*) fhEleEtaCharged->ProjectionX(Form("%s_px",fhEleEtaCharged->GetName()),-1,-1); TH1F * hNeHadEtaCharged = (TH1F*) fhNeHadEtaCharged->ProjectionX(Form("%s_px",fhNeHadEtaCharged->GetName()),-1,-1); TH1F * hChHadEtaCharged = (TH1F*) fhChHadEtaCharged->ProjectionX(Form("%s_px",fhChHadEtaCharged->GetName()),-1,-1); hPi0EtaCharged->SetLineColor(1); hGamEtaCharged->SetLineColor(4); hNeHadEtaCharged->SetLineColor(2); hChHadEtaCharged->SetLineColor(7); hEleEtaCharged->SetLineColor(6); gPad->SetLogy(); fhEtaCharged->SetLineColor(3); fhEtaCharged->SetMinimum(0.5); fhEtaCharged->Draw(); hPi0EtaCharged->Draw("same"); hGamEtaCharged->Draw("same"); hNeHadEtaCharged->Draw("same"); hChHadEtaCharged->Draw("same"); hEleEtaCharged->Draw("same"); c22ch->cd(3) ; TH1F * hGamPhiCharged = (TH1F*) fhGamPhiCharged->ProjectionX(Form("%s_px",fhGamPhiCharged->GetName()),-1,-1); TH1F * hPi0PhiCharged = (TH1F*) fhPi0PhiCharged->ProjectionX(Form("%s_px",fhPi0PhiCharged->GetName()),-1,-1); TH1F * hElePhiCharged = (TH1F*) fhElePhiCharged->ProjectionX(Form("%s_px",fhElePhiCharged->GetName()),-1,-1); TH1F * hNeHadPhiCharged = (TH1F*) fhNeHadPhiCharged->ProjectionX(Form("%s_px",fhNeHadPhiCharged->GetName()),-1,-1); TH1F * hChHadPhiCharged = (TH1F*) fhChHadPhiCharged->ProjectionX(Form("%s_px",fhChHadPhiCharged->GetName()),-1,-1); hPi0PhiCharged->SetLineColor(1); hGamPhiCharged->SetLineColor(4); hNeHadPhiCharged->SetLineColor(2); hChHadPhiCharged->SetLineColor(7); hElePhiCharged->SetLineColor(6); gPad->SetLogy(); fhPhiCharged->SetLineColor(3); fhPhiCharged->SetMinimum(0.5); fhPhiCharged->Draw(); hPi0PhiCharged->Draw("same"); hGamPhiCharged->Draw("same"); hNeHadPhiCharged->Draw("same"); hChHadPhiCharged->Draw("same"); hElePhiCharged->Draw("same"); snprintf(name,buffersize,"QA_%s_ReconstructedDistributions_TrackMatchedGenID.eps",fCalorimeter.Data()); c22ch->Print(name); printf("Plot: %s\n",name); TH1F * hGamEChargedClone = (TH1F*) hGamECharged->Clone(Form("%s_Clone",fhGamECharged->GetName())); TH1F * hGamPtChargedClone = (TH1F*) hGamPtCharged->Clone(Form("%s_Clone",fhGamPtCharged->GetName())); TH1F * hGamEtaChargedClone = (TH1F*) hGamEtaCharged->Clone(Form("%s_Clone",fhGamEtaCharged->GetName())); TH1F * hGamPhiChargedClone = (TH1F*) hGamPhiCharged->Clone(Form("%s_Clone",fhGamPhiCharged->GetName())); TH1F * hPi0EChargedClone = (TH1F*) hPi0ECharged->Clone(Form("%s_Clone",fhPi0ECharged->GetName())); TH1F * hPi0PtChargedClone = (TH1F*) hPi0PtCharged->Clone(Form("%s_Clone",fhPi0PtCharged->GetName())); TH1F * hPi0EtaChargedClone = (TH1F*) hPi0EtaCharged->Clone(Form("%s_Clone",fhPi0EtaCharged->GetName())); TH1F * hPi0PhiChargedClone = (TH1F*) hPi0PhiCharged->Clone(Form("%s_Clone",fhPi0PhiCharged->GetName())); TH1F * hEleEChargedClone = (TH1F*) hEleECharged->Clone(Form("%s_Clone",fhEleECharged->GetName())); TH1F * hElePtChargedClone = (TH1F*) hElePtCharged->Clone(Form("%s_Clone",fhElePtCharged->GetName())); TH1F * hEleEtaChargedClone = (TH1F*) hEleEtaCharged->Clone(Form("%s_Clone",fhEleEtaCharged->GetName())); TH1F * hElePhiChargedClone = (TH1F*) hElePhiCharged->Clone(Form("%s_Clone",fhElePhiCharged->GetName())); TH1F * hNeHadEChargedClone = (TH1F*) hNeHadECharged->Clone(Form("%s_Clone",fhNeHadECharged->GetName())); TH1F * hNeHadPtChargedClone = (TH1F*) hNeHadPtCharged->Clone(Form("%s_Clone",fhNeHadPtCharged->GetName())); TH1F * hNeHadEtaChargedClone = (TH1F*) hNeHadEtaCharged->Clone(Form("%s_Clone",fhNeHadEtaCharged->GetName())); TH1F * hNeHadPhiChargedClone = (TH1F*) hNeHadPhiCharged->Clone(Form("%s_Clone",fhNeHadPhiCharged->GetName())); TH1F * hChHadEChargedClone = (TH1F*) hChHadECharged->Clone(Form("%s_Clone",fhChHadECharged->GetName())); TH1F * hChHadPtChargedClone = (TH1F*) hChHadPtCharged->Clone(Form("%s_Clone",fhChHadPtCharged->GetName())); TH1F * hChHadEtaChargedClone = (TH1F*) hChHadEtaCharged->Clone(Form("%s_Clone",fhChHadEtaCharged->GetName())); TH1F * hChHadPhiChargedClone = (TH1F*) hChHadPhiCharged->Clone(Form("%s_Clone",fhChHadPhiCharged->GetName())); //Ratio: reconstructed track matched/ all reconstructed //printf("c3\n"); snprintf(cname,buffersize,"QA_%s_rectrackmatchratGenID",fCalorimeter.Data()); TCanvas * c3ch = new TCanvas(cname, "Ratio: reconstructed track matched/ all reconstructed, for different particle ID", 400, 400) ; c3ch->Divide(2, 2); c3ch->cd(1) ; hEChargedClone->SetMaximum(1.2); hEChargedClone->SetMinimum(0.001); hEChargedClone->SetLineColor(3); hEChargedClone->SetYTitle("track matched / all"); hPi0EChargedClone->Divide(hPi0E); hGamEChargedClone->Divide(hGamE); hEleEChargedClone->Divide(hEleE); hNeHadEChargedClone->Divide(hNeHadE); hChHadEChargedClone->Divide(hChHadE); hEChargedClone->Draw(); hPi0EChargedClone->Draw("same"); hGamEChargedClone->Draw("same"); hEleEChargedClone->Draw("same"); hNeHadEChargedClone->Draw("same"); hChHadEChargedClone->Draw("same"); TLegend pLegend3ch(0.75,0.45,0.9,0.8); pLegend3ch.SetTextSize(0.06); pLegend3ch.AddEntry(hEChargedClone,"all","L"); pLegend3ch.AddEntry(hPi0EChargedClone,"#pi^{0}","L"); pLegend3ch.AddEntry(hGamEChargedClone,"#gamma","L"); pLegend3ch.AddEntry(hEleEChargedClone,"e^{#pm}","L"); pLegend3ch.AddEntry(hChHadEChargedClone,"h^{#pm}","L"); pLegend3ch.AddEntry(hNeHadEChargedClone,"h^{0}","L"); pLegend3ch.SetFillColor(10); pLegend3ch.SetBorderSize(1); pLegend3ch.Draw(); c3ch->cd(2) ; hPtChargedClone->SetMaximum(1.2); hPtChargedClone->SetMinimum(0.001); hPtChargedClone->SetLineColor(3); hPtChargedClone->SetYTitle("track matched / all"); hPi0PtChargedClone->Divide(hPi0Pt); hGamPtChargedClone->Divide(hGamPt); hElePtChargedClone->Divide(hElePt); hNeHadPtChargedClone->Divide(hNeHadPt); hChHadPtChargedClone->Divide(hChHadPt); hPtChargedClone->Draw(); hPi0PtChargedClone->Draw("same"); hGamPtChargedClone->Draw("same"); hElePtChargedClone->Draw("same"); hNeHadPtChargedClone->Draw("same"); hChHadPtChargedClone->Draw("same"); c3ch->cd(4) ; hEtaChargedClone->SetMaximum(1.2); hEtaChargedClone->SetMinimum(0.001); hEtaChargedClone->SetLineColor(3); hEtaChargedClone->SetYTitle("track matched / all"); hPi0EtaChargedClone->Divide(hPi0Eta); hGamEtaChargedClone->Divide(hGamEta); hEleEtaChargedClone->Divide(hEleEta); hNeHadEtaChargedClone->Divide(hNeHadEta); hChHadEtaChargedClone->Divide(hChHadEta); hEtaChargedClone->Draw(); hPi0EtaChargedClone->Draw("same"); hGamEtaChargedClone->Draw("same"); hEleEtaChargedClone->Draw("same"); hNeHadEtaChargedClone->Draw("same"); hChHadEtaChargedClone->Draw("same"); c3ch->cd(3) ; hPhiChargedClone->SetMaximum(1.2); hPhiChargedClone->SetMinimum(0.001); hPhiChargedClone->SetLineColor(3); hPhiChargedClone->SetYTitle("track matched / all"); hPi0PhiChargedClone->Divide(hPi0Phi); hGamPhiChargedClone->Divide(hGamPhi); hElePhiChargedClone->Divide(hElePhi); hNeHadPhiChargedClone->Divide(hNeHadPhi); hChHadPhiChargedClone->Divide(hChHadPhi); hPhiChargedClone->Draw(); hPi0PhiChargedClone->Draw("same"); hGamPhiChargedClone->Draw("same"); hElePhiChargedClone->Draw("same"); hNeHadPhiChargedClone->Draw("same"); hChHadPhiChargedClone->Draw("same"); snprintf(name,buffersize,"QA_%s_RatioReconstructedMatchedDistributionsGenID.eps",fCalorimeter.Data()); c3ch->Print(name); printf("Plot: %s\n",name); } } //Track-matching distributions snprintf(cname,buffersize,"QA_%s_trkmatch",fCalorimeter.Data()); TCanvas *cme = new TCanvas(cname,"Track-matching distributions", 400, 400); cme->Divide(2,2); TLegend pLegendpE0(0.6,0.55,0.9,0.8); pLegendpE0.SetTextSize(0.04); pLegendpE0.AddEntry(fh1pOverE,"all","L"); pLegendpE0.AddEntry(fh1pOverER02,"dR < 0.02","L"); pLegendpE0.SetFillColor(10); pLegendpE0.SetBorderSize(1); //pLegendpE0.Draw(); cme->cd(1); if(fh1pOverE->GetEntries() > 0) gPad->SetLogy(); fh1pOverE->SetTitle("Track matches p/E"); fh1pOverE->Draw(); fh1pOverER02->SetLineColor(4); fh1pOverER02->Draw("same"); pLegendpE0.Draw(); cme->cd(2); if(fh1dR->GetEntries() > 0) gPad->SetLogy(); fh1dR->Draw(); cme->cd(3); fh2MatchdEdx->Draw(); cme->cd(4); fh2EledEdx->Draw(); snprintf(name,buffersize,"QA_%s_TrackMatchingEleDist.eps",fCalorimeter.Data()); cme->Print(name); printf("Plot: %s\n",name); if(IsDataMC()){ snprintf(cname,buffersize,"QA_%s_trkmatchMCEle",fCalorimeter.Data()); TCanvas *cmemc = new TCanvas(cname,"Track-matching distributions from MC electrons", 600, 200); cmemc->Divide(3,1); cmemc->cd(1); gPad->SetLogy(); fhMCEle1pOverE->Draw(); fhMCEle1pOverER02->SetLineColor(4); fhMCEle1pOverE->SetLineColor(1); fhMCEle1pOverER02->Draw("same"); pLegendpE0.Draw(); cmemc->cd(2); gPad->SetLogy(); fhMCEle1dR->Draw(); cmemc->cd(3); fhMCEle2MatchdEdx->Draw(); snprintf(name,buffersize,"QA_%s_TrackMatchingDistMCEle.eps",fCalorimeter.Data()); cmemc->Print(name); printf("Plot: %s\n",name); snprintf(cname,buffersize,"QA_%s_trkmatchMCChHad",fCalorimeter.Data()); TCanvas *cmemchad = new TCanvas(cname,"Track-matching distributions from MC charged hadrons", 600, 200); cmemchad->Divide(3,1); cmemchad->cd(1); gPad->SetLogy(); fhMCChHad1pOverE->Draw(); fhMCChHad1pOverER02->SetLineColor(4); fhMCChHad1pOverE->SetLineColor(1); fhMCChHad1pOverER02->Draw("same"); pLegendpE0.Draw(); cmemchad->cd(2); gPad->SetLogy(); fhMCChHad1dR->Draw(); cmemchad->cd(3); fhMCChHad2MatchdEdx->Draw(); snprintf(name,buffersize,"QA_%s_TrackMatchingDistMCChHad.eps",fCalorimeter.Data()); cmemchad->Print(name); printf("Plot: %s\n",name); snprintf(cname,buffersize,"QA_%s_trkmatchMCNeutral",fCalorimeter.Data()); TCanvas *cmemcn = new TCanvas(cname,"Track-matching distributions from MC neutrals", 600, 200); cmemcn->Divide(3,1); cmemcn->cd(1); gPad->SetLogy(); fhMCNeutral1pOverE->Draw(); fhMCNeutral1pOverE->SetLineColor(1); fhMCNeutral1pOverER02->SetLineColor(4); fhMCNeutral1pOverER02->Draw("same"); pLegendpE0.Draw(); cmemcn->cd(2); gPad->SetLogy(); fhMCNeutral1dR->Draw(); cmemcn->cd(3); fhMCNeutral2MatchdEdx->Draw(); snprintf(name,buffersize,"QA_%s_TrackMatchingDistMCNeutral.eps",fCalorimeter.Data()); cmemcn->Print(name); printf("Plot: %s\n",name); snprintf(cname,buffersize,"QA_%s_trkmatchpE",fCalorimeter.Data()); TCanvas *cmpoe = new TCanvas(cname,"Track-matching distributions, p/E", 400, 200); cmpoe->Divide(2,1); cmpoe->cd(1); gPad->SetLogy(); fh1pOverE->SetLineColor(1); fhMCEle1pOverE->SetLineColor(4); fhMCChHad1pOverE->SetLineColor(2); fhMCNeutral1pOverE->SetLineColor(7); fh1pOverER02->SetMinimum(0.5); fh1pOverE->Draw(); fhMCEle1pOverE->Draw("same"); fhMCChHad1pOverE->Draw("same"); fhMCNeutral1pOverE->Draw("same"); TLegend pLegendpE(0.65,0.55,0.9,0.8); pLegendpE.SetTextSize(0.06); pLegendpE.AddEntry(fh1pOverE,"all","L"); pLegendpE.AddEntry(fhMCEle1pOverE,"e^{#pm}","L"); pLegendpE.AddEntry(fhMCChHad1pOverE,"h^{#pm}","L"); pLegendpE.AddEntry(fhMCNeutral1pOverE,"neutrals","L"); pLegendpE.SetFillColor(10); pLegendpE.SetBorderSize(1); pLegendpE.Draw(); cmpoe->cd(2); gPad->SetLogy(); fh1pOverER02->SetTitle("Track matches p/E, dR<0.2"); fh1pOverER02->SetLineColor(1); fhMCEle1pOverER02->SetLineColor(4); fhMCChHad1pOverER02->SetLineColor(2); fhMCNeutral1pOverER02->SetLineColor(7); fh1pOverER02->SetMaximum(fh1pOverE->GetMaximum()); fh1pOverER02->SetMinimum(0.5); fh1pOverER02->Draw(); fhMCEle1pOverER02->Draw("same"); fhMCChHad1pOverER02->Draw("same"); fhMCNeutral1pOverER02->Draw("same"); // TLegend pLegendpE2(0.65,0.55,0.9,0.8); // pLegendpE2.SetTextSize(0.06); // pLegendpE2.SetHeader("dR < 0.02"); // pLegendpE2.SetFillColor(10); // pLegendpE2.SetBorderSize(1); // pLegendpE2.Draw(); snprintf(name,buffersize,"QA_%s_TrackMatchingPOverE.eps",fCalorimeter.Data()); cmpoe->Print(name); printf("Plot: %s\n",name); } char line[buffersize] ; snprintf(line, buffersize,".!tar -zcf QA_%s_%s.tar.gz *%s*.eps", fCalorimeter.Data(), GetName(),fCalorimeter.Data()) ; gROOT->ProcessLine(line); snprintf(line, buffersize,".!rm -fR *.eps"); gROOT->ProcessLine(line); printf("AliAnaCalorimeterQA::Terminate() - !! All the eps files are in QA_%s_%s.tar.gz !!!\n", fCalorimeter.Data(), GetName()); }