Int_t AliPMDesdanal() { TStopwatch timer; gStyle->SetOptStat(111110); gStyle->SetOptFit(1); //****** File with the ESD TFile *ef=TFile::Open("AliESDs.root"); if (!ef || !ef->IsOpen()) {cerr<<"Can't AliESDs.root !\n"; return 1;} AliESDEvent * event = new AliESDEvent; TTree* tree = (TTree*) ef->Get("esdTree"); if (!tree) {cerr<<"no ESD tree found\n"; return 1;}; event->ReadFromTree(tree); Int_t n=0; //******* The loop over events while (tree->GetEvent(n)) { cout<<endl<<"Processing event number : "<<n++<<endl; Int_t npmdcl=event->GetNumberOfPmdTracks(); cout<<"Number of PMD tracks : "<<npmdcl<<endl; //****** The loop over PMD clusters while (npmdcl--) { AliESDPmdTrack *pmdtr = event->GetPmdTrack(npmdcl); Int_t det = pmdtr->GetDetector(); Float_t clsX = pmdtr->GetClusterX(); Float_t clsY = pmdtr->GetClusterY(); Float_t clsZ = pmdtr->GetClusterZ(); Float_t ncell = pmdtr->GetClusterCells(); Float_t adc = pmdtr->GetClusterADC(); Float_t pid = pmdtr->GetClusterPID(); } } delete event; timer.Stop(); timer.Print(); return 0; }
Bool_t CheckESD(const char* gAliceFileName = "galice.root", const char* esdFileName = "AliESDs.root") { // check the content of the ESD // check values Int_t checkNGenLow = 1; Double_t checkEffLow = 0.5; Double_t checkEffSigma = 3; Double_t checkFakeHigh = 0.5; Double_t checkFakeSigma = 3; Double_t checkResPtInvHigh = 5; Double_t checkResPtInvSigma = 3; Double_t checkResPhiHigh = 10; Double_t checkResPhiSigma = 3; Double_t checkResThetaHigh = 10; Double_t checkResThetaSigma = 3; Double_t checkPIDEffLow = 0.5; Double_t checkPIDEffSigma = 3; Double_t checkResTOFHigh = 500; Double_t checkResTOFSigma = 3; Double_t checkPHOSNLow = 5; Double_t checkPHOSEnergyLow = 0.3; Double_t checkPHOSEnergyHigh = 1.0; Double_t checkEMCALNLow = 50; Double_t checkEMCALEnergyLow = 0.05; Double_t checkEMCALEnergyHigh = 1.0; Double_t checkMUONNLow = 1; Double_t checkMUONPtLow = 0.5; Double_t checkMUONPtHigh = 10.; Double_t cutPtV0 = 0.3; Double_t checkV0EffLow = 0.02; Double_t checkV0EffSigma = 3; Double_t cutPtCascade = 0.5; Double_t checkCascadeEffLow = 0.01; Double_t checkCascadeEffSigma = 3; // open run loader and load gAlice, kinematics and header AliRunLoader* runLoader = AliRunLoader::Open(gAliceFileName); if (!runLoader) { Error("CheckESD", "getting run loader from file %s failed", gAliceFileName); return kFALSE; } runLoader->LoadgAlice(); gAlice = runLoader->GetAliRun(); if (!gAlice) { Error("CheckESD", "no galice object found"); return kFALSE; } runLoader->LoadKinematics(); runLoader->LoadHeader(); // open the ESD file TFile* esdFile = TFile::Open(esdFileName); if (!esdFile || !esdFile->IsOpen()) { Error("CheckESD", "opening ESD file %s failed", esdFileName); return kFALSE; } AliESDEvent * esd = new AliESDEvent; TTree* tree = (TTree*) esdFile->Get("esdTree"); if (!tree) { Error("CheckESD", "no ESD tree found"); return kFALSE; } esd->ReadFromTree(tree); //PMD plots TH1F *fhM[48]; for(Int_t i = 0; i < 48; i++) fhM[i] = Create1DHistos(i,"hEsDMod"); // PMD XY Plots histograms TH2F *fhEsdXYC = new TH2F("hEsdXYC"," Scattered Plot for CPV (ESD) ",100,-100. ,100.,100,-100.,100.); TH2F *fhEsdXYP = new TH2F("hEsdXYP"," Scattered Plot for PRE (ESD) ",100,-100. ,100.,100,-100.,100.); // efficiency and resolution histograms Int_t nBinsPt = 15; Float_t minPt = 0.1; Float_t maxPt = 3.1; TH1F* hGen = CreateHisto("hGen", "generated tracks", nBinsPt, minPt, maxPt, "p_{t} [GeV/c]", "N"); TH1F* hRec = CreateHisto("hRec", "reconstructed tracks", nBinsPt, minPt, maxPt, "p_{t} [GeV/c]", "N"); Int_t nGen = 0; Int_t nRec = 0; Int_t nFake = 0; TH1F* hResPtInv = CreateHisto("hResPtInv", "", 100, -10, 10, "(p_{t,rec}^{-1}-p_{t,sim}^{-1}) / p_{t,sim}^{-1} [%]", "N"); TH1F* hResPhi = CreateHisto("hResPhi", "", 100, -20, 20, "#phi_{rec}-#phi_{sim} [mrad]", "N"); TH1F* hResTheta = CreateHisto("hResTheta", "", 100, -20, 20, "#theta_{rec}-#theta_{sim} [mrad]", "N"); // PID Int_t partCode[AliPID::kSPECIES] = {kElectron, kMuonMinus, kPiPlus, kKPlus, kProton}; const char* partName[AliPID::kSPECIES+1] = {"electron", "muon", "pion", "kaon", "proton", "other"}; Double_t partFrac[AliPID::kSPECIES] = {0.01, 0.01, 0.85, 0.10, 0.05}; Int_t identified[AliPID::kSPECIES+1][AliPID::kSPECIES]; for (Int_t iGen = 0; iGen < AliPID::kSPECIES+1; iGen++) { for (Int_t iRec = 0; iRec < AliPID::kSPECIES; iRec++) { identified[iGen][iRec] = 0; } } Int_t nIdentified = 0; // dE/dx and TOF TH2F* hDEdxRight = new TH2F("hDEdxRight", "", 300, 0, 3, 100, 0, 400); hDEdxRight->SetStats(kFALSE); hDEdxRight->GetXaxis()->SetTitle("p [GeV/c]"); hDEdxRight->GetYaxis()->SetTitle("dE/dx_{TPC}"); hDEdxRight->SetMarkerStyle(kFullCircle); hDEdxRight->SetMarkerSize(0.4); TH2F* hDEdxWrong = new TH2F("hDEdxWrong", "", 300, 0, 3, 100, 0, 400); hDEdxWrong->SetStats(kFALSE); hDEdxWrong->GetXaxis()->SetTitle("p [GeV/c]"); hDEdxWrong->GetYaxis()->SetTitle("dE/dx_{TPC}"); hDEdxWrong->SetMarkerStyle(kFullCircle); hDEdxWrong->SetMarkerSize(0.4); hDEdxWrong->SetMarkerColor(kRed); TH1F* hResTOFRight = CreateHisto("hResTOFRight", "", 100, -1000, 1000, "t_{TOF}-t_{track} [ps]", "N"); TH1F* hResTOFWrong = CreateHisto("hResTOFWrong", "", 100, -1000, 1000, "t_{TOF}-t_{track} [ps]", "N"); hResTOFWrong->SetLineColor(kRed); // calorimeters TH1F* hEPHOS = CreateHisto("hEPHOS", "PHOS", 100, 0, 50, "E [GeV]", "N"); TH1F* hEEMCAL = CreateHisto("hEEMCAL", "EMCAL", 100, 0, 50, "E [GeV]", "N"); // muons TH1F* hPtMUON = CreateHisto("hPtMUON", "MUON", 100, 0, 20, "p_{t} [GeV/c]", "N"); // V0s and cascades TH1F* hMassK0 = CreateHisto("hMassK0", "K^{0}", 100, 0.4, 0.6, "M(#pi^{+}#pi^{-}) [GeV/c^{2}]", "N"); TH1F* hMassLambda = CreateHisto("hMassLambda", "#Lambda", 100, 1.0, 1.2, "M(p#pi^{-}) [GeV/c^{2}]", "N"); TH1F* hMassLambdaBar = CreateHisto("hMassLambdaBar", "#bar{#Lambda}", 100, 1.0, 1.2, "M(#bar{p}#pi^{+}) [GeV/c^{2}]", "N"); Int_t nGenV0s = 0; Int_t nRecV0s = 0; TH1F* hMassXi = CreateHisto("hMassXi", "#Xi", 100, 1.2, 1.5, "M(#Lambda#pi) [GeV/c^{2}]", "N"); TH1F* hMassOmega = CreateHisto("hMassOmega", "#Omega", 100, 1.5, 1.8, "M(#LambdaK) [GeV/c^{2}]", "N"); Int_t nGenCascades = 0; Int_t nRecCascades = 0; // loop over events for (Int_t iEvent = 0; iEvent < runLoader->GetNumberOfEvents(); iEvent++) { runLoader->GetEvent(iEvent); // select simulated primary particles, V0s and cascades AliStack* stack = runLoader->Stack(); Int_t nParticles = stack->GetNtrack(); TArrayF vertex(3); runLoader->GetHeader()->GenEventHeader()->PrimaryVertex(vertex); TObjArray selParticles; TObjArray selV0s; TObjArray selCascades; for (Int_t iParticle = 0; iParticle < nParticles; iParticle++) { TParticle* particle = stack->Particle(iParticle); if (!particle) continue; if (particle->Pt() < 0.001) continue; if (TMath::Abs(particle->Eta()) > 0.9) continue; TVector3 dVertex(particle->Vx() - vertex[0], particle->Vy() - vertex[1], particle->Vz() - vertex[2]); if (dVertex.Mag() > 0.0001) continue; switch (TMath::Abs(particle->GetPdgCode())) { case kElectron: case kMuonMinus: case kPiPlus: case kKPlus: case kProton: { if (particle->Pt() > minPt) { selParticles.Add(particle); nGen++; hGen->Fill(particle->Pt()); } break; } case kK0Short: case kLambda0: { if (particle->Pt() > cutPtV0) { nGenV0s++; selV0s.Add(particle); } break; } case kXiMinus: case kOmegaMinus: { if (particle->Pt() > cutPtCascade) { nGenCascades++; selCascades.Add(particle); } break; } default: break; } } // get the event summary data tree->GetEvent(iEvent); if (!esd) { Error("CheckESD", "no ESD object found for event %d", iEvent); return kFALSE; } //------------- Loop over PMD track ---- Int_t npmdcl = 0; npmdcl = esd->GetNumberOfPmdTracks(); while (npmdcl--) { AliESDPmdTrack *pmdtr = esd->GetPmdTrack(npmdcl); Int_t det = pmdtr->GetDetector(); Int_t smn = pmdtr->GetSmn(); Float_t adc = pmdtr->GetClusterADC(); Int_t ncell = pmdtr->GetClusterCells(); Float_t clsX = pmdtr->GetClusterX(); Float_t clsY = pmdtr->GetClusterY(); if(det == 0) { fhEsdXYP->Fill(clsX,clsY); if(ncell < 3) fhM[smn]->Fill(adc); } else if(det == 1) { fhEsdXYC->Fill(clsX,clsY); if(ncell < 3)fhM[24+smn]->Fill(adc); } } //----------------------- // loop over tracks for (Int_t iTrack = 0; iTrack < esd->GetNumberOfTracks(); iTrack++) { AliESDtrack* track = esd->GetTrack(iTrack); // select tracks of selected particles Int_t label = TMath::Abs(track->GetLabel()); if (label > stack->GetNtrack()) continue; // background TParticle* particle = stack->Particle(label); if (!selParticles.Contains(particle)) continue; if ((track->GetStatus() & AliESDtrack::kITSrefit) == 0) continue; if (track->GetConstrainedChi2() > 1e9) continue; selParticles.Remove(particle); // don't count multiple tracks nRec++; hRec->Fill(particle->Pt()); if (track->GetLabel() < 0) nFake++; // resolutions hResPtInv->Fill(100. * (TMath::Abs(track->GetSigned1Pt()) - 1./particle->Pt()) * particle->Pt()); hResPhi->Fill(1000. * (track->Phi() - particle->Phi())); hResTheta->Fill(1000. * (track->Theta() - particle->Theta())); // PID if ((track->GetStatus() & AliESDtrack::kESDpid) == 0) continue; Int_t iGen = 5; for (Int_t i = 0; i < AliPID::kSPECIES; i++) { if (TMath::Abs(particle->GetPdgCode()) == partCode[i]) iGen = i; } Double_t probability[AliPID::kSPECIES]; track->GetESDpid(probability); Double_t pMax = 0; Int_t iRec = 0; for (Int_t i = 0; i < AliPID::kSPECIES; i++) { probability[i] *= partFrac[i]; if (probability[i] > pMax) { pMax = probability[i]; iRec = i; } } identified[iGen][iRec]++; if (iGen == iRec) nIdentified++; // dE/dx and TOF Double_t time[AliPID::kSPECIES]; track->GetIntegratedTimes(time); if (iGen == iRec) { hDEdxRight->Fill(particle->P(), track->GetTPCsignal()); if ((track->GetStatus() & AliESDtrack::kTOFpid) != 0) { hResTOFRight->Fill(track->GetTOFsignal() - time[iRec]); } } else { hDEdxWrong->Fill(particle->P(), track->GetTPCsignal()); if ((track->GetStatus() & AliESDtrack::kTOFpid) != 0) { hResTOFWrong->Fill(track->GetTOFsignal() - time[iRec]); } } } // loop over muon tracks { for (Int_t iTrack = 0; iTrack < esd->GetNumberOfMuonTracks(); iTrack++) { AliESDMuonTrack* muonTrack = esd->GetMuonTrack(iTrack); Double_t ptInv = TMath::Abs(muonTrack->GetInverseBendingMomentum()); if (ptInv > 0.001) { hPtMUON->Fill(1./ptInv); } } } // loop over V0s for (Int_t iV0 = 0; iV0 < esd->GetNumberOfV0s(); iV0++) { AliESDv0* v0 = esd->GetV0(iV0); if (v0->GetOnFlyStatus()) continue; v0->ChangeMassHypothesis(kK0Short); hMassK0->Fill(v0->GetEffMass()); v0->ChangeMassHypothesis(kLambda0); hMassLambda->Fill(v0->GetEffMass()); v0->ChangeMassHypothesis(kLambda0Bar); hMassLambdaBar->Fill(v0->GetEffMass()); Int_t negLabel = TMath::Abs(esd->GetTrack(v0->GetNindex())->GetLabel()); if (negLabel > stack->GetNtrack()) continue; // background Int_t negMother = stack->Particle(negLabel)->GetMother(0); if (negMother < 0) continue; Int_t posLabel = TMath::Abs(esd->GetTrack(v0->GetPindex())->GetLabel()); if (posLabel > stack->GetNtrack()) continue; // background Int_t posMother = stack->Particle(posLabel)->GetMother(0); if (negMother != posMother) continue; TParticle* particle = stack->Particle(negMother); if (!selV0s.Contains(particle)) continue; selV0s.Remove(particle); nRecV0s++; } // loop over Cascades for (Int_t iCascade = 0; iCascade < esd->GetNumberOfCascades(); iCascade++) { AliESDcascade* cascade = esd->GetCascade(iCascade); Double_t v0q; cascade->ChangeMassHypothesis(v0q,kXiMinus); hMassXi->Fill(cascade->GetEffMassXi()); cascade->ChangeMassHypothesis(v0q,kOmegaMinus); hMassOmega->Fill(cascade->GetEffMassXi()); Int_t negLabel = TMath::Abs(esd->GetTrack(cascade->GetNindex()) ->GetLabel()); if (negLabel > stack->GetNtrack()) continue; // background Int_t negMother = stack->Particle(negLabel)->GetMother(0); if (negMother < 0) continue; Int_t posLabel = TMath::Abs(esd->GetTrack(cascade->GetPindex()) ->GetLabel()); if (posLabel > stack->GetNtrack()) continue; // background Int_t posMother = stack->Particle(posLabel)->GetMother(0); if (negMother != posMother) continue; Int_t v0Mother = stack->Particle(negMother)->GetMother(0); if (v0Mother < 0) continue; Int_t bacLabel = TMath::Abs(esd->GetTrack(cascade->GetBindex()) ->GetLabel()); if (bacLabel > stack->GetNtrack()) continue; // background Int_t bacMother = stack->Particle(bacLabel)->GetMother(0); if (v0Mother != bacMother) continue; TParticle* particle = stack->Particle(v0Mother); if (!selCascades.Contains(particle)) continue; selCascades.Remove(particle); nRecCascades++; } // loop over the clusters { for (Int_t iCluster=0; iCluster<esd->GetNumberOfCaloClusters(); iCluster++) { AliESDCaloCluster * clust = esd->GetCaloCluster(iCluster); if (clust->IsPHOS()) hEPHOS->Fill(clust->E()); if (clust->IsEMCAL()) hEEMCAL->Fill(clust->E()); } } } // perform checks if (nGen < checkNGenLow) { Warning("CheckESD", "low number of generated particles: %d", Int_t(nGen)); } TH1F* hEff = CreateEffHisto(hGen, hRec); Info("CheckESD", "%d out of %d tracks reconstructed including %d " "fake tracks", nRec, nGen, nFake); if (nGen > 0) { // efficiency Double_t eff = nRec*1./nGen; Double_t effError = TMath::Sqrt(eff*(1.-eff) / nGen); Double_t fake = nFake*1./nGen; Double_t fakeError = TMath::Sqrt(fake*(1.-fake) / nGen); Info("CheckESD", "eff = (%.1f +- %.1f) %% fake = (%.1f +- %.1f) %%", 100.*eff, 100.*effError, 100.*fake, 100.*fakeError); if (eff < checkEffLow - checkEffSigma*effError) { Warning("CheckESD", "low efficiency: (%.1f +- %.1f) %%", 100.*eff, 100.*effError); } if (fake > checkFakeHigh + checkFakeSigma*fakeError) { Warning("CheckESD", "high fake: (%.1f +- %.1f) %%", 100.*fake, 100.*fakeError); } // resolutions Double_t res, resError; if (FitHisto(hResPtInv, res, resError)) { Info("CheckESD", "relative inverse pt resolution = (%.1f +- %.1f) %%", res, resError); if (res > checkResPtInvHigh + checkResPtInvSigma*resError) { Warning("CheckESD", "bad pt resolution: (%.1f +- %.1f) %%", res, resError); } } if (FitHisto(hResPhi, res, resError)) { Info("CheckESD", "phi resolution = (%.1f +- %.1f) mrad", res, resError); if (res > checkResPhiHigh + checkResPhiSigma*resError) { Warning("CheckESD", "bad phi resolution: (%.1f +- %.1f) mrad", res, resError); } } if (FitHisto(hResTheta, res, resError)) { Info("CheckESD", "theta resolution = (%.1f +- %.1f) mrad", res, resError); if (res > checkResThetaHigh + checkResThetaSigma*resError) { Warning("CheckESD", "bad theta resolution: (%.1f +- %.1f) mrad", res, resError); } } // PID if (nRec > 0) { Double_t eff = nIdentified*1./nRec; Double_t effError = TMath::Sqrt(eff*(1.-eff) / nRec); Info("CheckESD", "PID eff = (%.1f +- %.1f) %%", 100.*eff, 100.*effError); if (eff < checkPIDEffLow - checkPIDEffSigma*effError) { Warning("CheckESD", "low PID efficiency: (%.1f +- %.1f) %%", 100.*eff, 100.*effError); } } printf("%9s:", "gen\\rec"); for (Int_t iRec = 0; iRec < AliPID::kSPECIES; iRec++) { printf("%9s", partName[iRec]); } printf("\n"); for (Int_t iGen = 0; iGen < AliPID::kSPECIES+1; iGen++) { printf("%9s:", partName[iGen]); for (Int_t iRec = 0; iRec < AliPID::kSPECIES; iRec++) { printf("%9d", identified[iGen][iRec]); } printf("\n"); } if (FitHisto(hResTOFRight, res, resError)) { Info("CheckESD", "TOF resolution = (%.1f +- %.1f) ps", res, resError); if (res > checkResTOFHigh + checkResTOFSigma*resError) { Warning("CheckESD", "bad TOF resolution: (%.1f +- %.1f) ps", res, resError); } } // calorimeters if (hEPHOS->Integral() < checkPHOSNLow) { Warning("CheckESD", "low number of PHOS particles: %d", Int_t(hEPHOS->Integral())); } else { Double_t mean = hEPHOS->GetMean(); if (mean < checkPHOSEnergyLow) { Warning("CheckESD", "low mean PHOS energy: %.1f GeV", mean); } else if (mean > checkPHOSEnergyHigh) { Warning("CheckESD", "high mean PHOS energy: %.1f GeV", mean); } } if (hEEMCAL->Integral() < checkEMCALNLow) { Warning("CheckESD", "low number of EMCAL particles: %d", Int_t(hEEMCAL->Integral())); } else { Double_t mean = hEEMCAL->GetMean(); if (mean < checkEMCALEnergyLow) { Warning("CheckESD", "low mean EMCAL energy: %.1f GeV", mean); } else if (mean > checkEMCALEnergyHigh) { Warning("CheckESD", "high mean EMCAL energy: %.1f GeV", mean); } } // muons if (hPtMUON->Integral() < checkMUONNLow) { Warning("CheckESD", "low number of MUON particles: %d", Int_t(hPtMUON->Integral())); } else { Double_t mean = hPtMUON->GetMean(); if (mean < checkMUONPtLow) { Warning("CheckESD", "low mean MUON pt: %.1f GeV/c", mean); } else if (mean > checkMUONPtHigh) { Warning("CheckESD", "high mean MUON pt: %.1f GeV/c", mean); } } // V0s if (nGenV0s > 0) { Double_t eff = nRecV0s*1./nGenV0s; Double_t effError = TMath::Sqrt(eff*(1.-eff) / nGenV0s); if (effError == 0) effError = checkV0EffLow / TMath::Sqrt(1.*nGenV0s); Info("CheckESD", "V0 eff = (%.1f +- %.1f) %%", 100.*eff, 100.*effError); if (eff < checkV0EffLow - checkV0EffSigma*effError) { Warning("CheckESD", "low V0 efficiency: (%.1f +- %.1f) %%", 100.*eff, 100.*effError); } } // Cascades if (nGenCascades > 0) { Double_t eff = nRecCascades*1./nGenCascades; Double_t effError = TMath::Sqrt(eff*(1.-eff) / nGenCascades); if (effError == 0) effError = checkV0EffLow / TMath::Sqrt(1.*nGenCascades); Info("CheckESD", "Cascade eff = (%.1f +- %.1f) %%", 100.*eff, 100.*effError); if (eff < checkCascadeEffLow - checkCascadeEffSigma*effError) { Warning("CheckESD", "low Cascade efficiency: (%.1f +- %.1f) %%", 100.*eff, 100.*effError); } } } // draw the histograms if not in batch mode if (!gROOT->IsBatch()) { new TCanvas; hEff->DrawCopy(); new TCanvas; hResPtInv->DrawCopy("E"); new TCanvas; hResPhi->DrawCopy("E"); new TCanvas; hResTheta->DrawCopy("E"); new TCanvas; hDEdxRight->DrawCopy(); hDEdxWrong->DrawCopy("SAME"); new TCanvas; hResTOFRight->DrawCopy("E"); hResTOFWrong->DrawCopy("SAME"); new TCanvas; hEPHOS->DrawCopy("E"); new TCanvas; hEEMCAL->DrawCopy("E"); new TCanvas; hPtMUON->DrawCopy("E"); new TCanvas; hMassK0->DrawCopy("E"); new TCanvas; hMassLambda->DrawCopy("E"); new TCanvas; hMassLambdaBar->DrawCopy("E"); new TCanvas; hMassXi->DrawCopy("E"); new TCanvas; hMassOmega->DrawCopy("E"); } // write the output histograms to a file TFile* outputFile = TFile::Open("check.root", "recreate"); if (!outputFile || !outputFile->IsOpen()) { Error("CheckESD", "opening output file check.root failed"); return kFALSE; } hEff->Write(); hResPtInv->Write(); hResPhi->Write(); hResTheta->Write(); hDEdxRight->Write(); hDEdxWrong->Write(); hResTOFRight->Write(); hResTOFWrong->Write(); hEPHOS->Write(); hEEMCAL->Write(); hPtMUON->Write(); hMassK0->Write(); hMassLambda->Write(); hMassLambdaBar->Write(); hMassXi->Write(); hMassOmega->Write(); for(Int_t i = 0; i < 48; i++) fhM[i]->Write(); fhEsdXYP->Write(); fhEsdXYC->Write(); outputFile->Close(); delete outputFile; // clean up delete fhEsdXYC; delete fhEsdXYP; delete [] fhM; delete hGen; delete hRec; delete hEff; delete hResPtInv; delete hResPhi; delete hResTheta; delete hDEdxRight; delete hDEdxWrong; delete hResTOFRight; delete hResTOFWrong; delete hEPHOS; delete hEEMCAL; delete hPtMUON; delete hMassK0; delete hMassLambda; delete hMassLambdaBar; delete hMassXi; delete hMassOmega; delete esd; esdFile->Close(); delete esdFile; runLoader->UnloadHeader(); runLoader->UnloadKinematics(); delete runLoader; // result of check Info("CheckESD", "check of ESD was successfull"); return kTRUE; }