/************************************************************************** * Copyright(c) 1998-2009, 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. * **************************************************************************/ /* $Id$ */ ///////////////////////////////////////////////////////////// // // AliAnalysisTaskSE for D0 candidates invariant mass histogram // and comparison with the MC truth and cut variables distributions. // // Authors: A.Dainese, andrea.dainese@lnl.infn.it // Chiara Bianchin, chiara.bianchin@pd.infn.it (invariant mass) // Carmelo Di Giglio, carmelo.digiglio@ba.infn.it (like sign) ///////////////////////////////////////////////////////////// #include #include #include #include #include #include #include #include #include #include #include "AliAnalysisManager.h" #include "AliESDtrack.h" #include "AliVertexerTracks.h" #include "AliAODHandler.h" #include "AliAODEvent.h" #include "AliAODVertex.h" #include "AliAODTrack.h" #include "AliAODMCHeader.h" #include "AliAODMCParticle.h" #include "AliAODRecoDecayHF2Prong.h" #include "AliAODRecoCascadeHF.h" #include "AliAnalysisVertexingHF.h" #include "AliAnalysisTaskSE.h" #include "AliAnalysisTaskSED0Mass.h" #include "AliNormalizationCounter.h" ClassImp(AliAnalysisTaskSED0Mass) //________________________________________________________________________ AliAnalysisTaskSED0Mass::AliAnalysisTaskSED0Mass(): AliAnalysisTaskSE(), fOutputMass(0), fDistr(0), fNentries(0), fCuts(0), fArray(0), fReadMC(0), fCutOnDistr(0), fUsePid4Distr(0), fCounter(0), fNPtBins(1), fLsNormalization(1.), fFillOnlyD0D0bar(0), fDaughterTracks(), fIsSelectedCandidate(0), fFillVarHists(kTRUE), fSys(0) { // Default constructor } //________________________________________________________________________ AliAnalysisTaskSED0Mass::AliAnalysisTaskSED0Mass(const char *name,AliRDHFCutsD0toKpi* cuts): AliAnalysisTaskSE(name), fOutputMass(0), fDistr(0), fNentries(0), fCuts(0), fArray(0), fReadMC(0), fCutOnDistr(0), fUsePid4Distr(0), fCounter(0), fNPtBins(1), fLsNormalization(1.), fFillOnlyD0D0bar(0), fDaughterTracks(), fIsSelectedCandidate(0), fFillVarHists(kTRUE), fSys(0) { // Default constructor fNPtBins=cuts->GetNPtBins(); fCuts=cuts; // Output slot #1 writes into a TList container (mass with cuts) DefineOutput(1,TList::Class()); //My private output // Output slot #2 writes into a TList container (distributions) if(fFillVarHists) DefineOutput(2,TList::Class()); //My private output // Output slot #3 writes into a TH1F container (number of events) DefineOutput(3,TH1F::Class()); //My private output // Output slot #4 writes into a TList container (cuts) DefineOutput(4,AliRDHFCutsD0toKpi::Class()); //My private output // Output slot #5 writes Normalization Counter DefineOutput(5,AliNormalizationCounter::Class()); } //________________________________________________________________________ AliAnalysisTaskSED0Mass::~AliAnalysisTaskSED0Mass() { if (fOutputMass) { delete fOutputMass; fOutputMass = 0; } if (fDistr) { delete fDistr; fDistr = 0; } if (fCuts) { delete fCuts; fCuts = 0; } if (fNentries){ delete fNentries; fNentries = 0; } if(fCounter){ delete fCounter; fCounter=0; } } //________________________________________________________________________ void AliAnalysisTaskSED0Mass::Init() { // Initialization if(fDebug > 1) printf("AnalysisTaskSED0Mass::Init() \n"); AliRDHFCutsD0toKpi* copyfCuts=new AliRDHFCutsD0toKpi(*fCuts); const char* nameoutput=GetOutputSlot(4)->GetContainer()->GetName(); copyfCuts->SetName(nameoutput); // Post the data PostData(4,copyfCuts); return; } //________________________________________________________________________ void AliAnalysisTaskSED0Mass::UserCreateOutputObjects() { // Create the output container // if(fDebug > 1) printf("AnalysisTaskSED0Mass::UserCreateOutputObjects() \n"); // Several histograms are more conveniently managed in a TList fOutputMass = new TList(); fOutputMass->SetOwner(); fOutputMass->SetName("listMass"); fDistr = new TList(); fDistr->SetOwner(); fDistr->SetName("distributionslist"); TString nameMass=" ",nameSgn27=" ",nameSgn=" ", nameBkg=" ", nameRfl=" ",nameMassNocutsS =" ",nameMassNocutsB =" ", namedistr=" "; for(Int_t i=0;iGetNPtBins();i++){ nameMass="histMass_"; nameMass+=i; nameSgn27="histSgn27_"; nameSgn27+=i; nameSgn="histSgn_"; nameSgn+=i; nameBkg="histBkg_"; nameBkg+=i; nameRfl="histRfl_"; nameRfl+=i; nameMassNocutsS="hMassS_"; nameMassNocutsS+=i; nameMassNocutsB="hMassB_"; nameMassNocutsB+=i; //histograms of cut variable distributions if(fFillVarHists){ if(fReadMC){ // dca namedistr="hdcaS_"; namedistr+=i; TH1F *hdcaS = new TH1F(namedistr.Data(), "DCA distribution;dca [cm]",200,0.,0.1); // impact parameter namedistr="hd0piS_"; namedistr+=i; TH1F *hd0piS = new TH1F(namedistr.Data(), "Impact parameter distribution (pions);d0(#pi) [cm]",200,-0.1,0.1); namedistr="hd0KS_"; namedistr+=i; TH1F *hd0KS = new TH1F(namedistr.Data(), "Impact parameter distribution (kaons);d0(K) [cm]",200,-0.1,0.1); namedistr="hd0d0S_"; namedistr+=i; TH1F *hd0d0S = new TH1F(namedistr.Data(), "d_{0}#timesd_{0} distribution;d_{0}#timesd_{0} [cm^{2}]",200,-0.001,0.001); //decay lenght namedistr="hdeclS_"; namedistr+=i; TH1F *hdeclengthS = new TH1F(namedistr.Data(), "Decay Length^{2} distribution;Decay Length^{2} [cm]",200,0,0.015); namedistr="hnormdeclS_"; namedistr+=i; TH1F *hnormdeclengthS = new TH1F(namedistr.Data(), "Normalized Decay Length^{2} distribution;(Decay Length/Err)^{2} ",200,0,12.); namedistr="hdeclxyS_"; namedistr+=i; TH1F* hdeclxyS=new TH1F(namedistr.Data(),"Decay Length XY distribution;Decay Length XY [cm]",200,0,0.15); namedistr="hnormdeclxyS_"; namedistr+=i; TH1F* hnormdeclxyS=new TH1F(namedistr.Data(),"Normalized decay Length XY distribution;Decay Length XY/Err",200,0,6.); namedistr="hdeclxyd0d0S_"; namedistr+=i; TH2F* hdeclxyd0d0S=new TH2F(namedistr.Data(),"Correlation decay Length XY - d_{0}#times d_{0};Decay Length XY [cm];d_{0}#times d_{0}[cm^{2}]",200,0,0.15,200,-0.001,0.001); namedistr="hnormdeclxyd0d0S_"; namedistr+=i; TH2F* hnormdeclxyd0d0S=new TH2F(namedistr.Data(),"Correlation normalized decay Length XY - d_{0}#times d_{0};Decay Length XY/Err;d_{0}#times d_{0}[cm^{2}]",200,0,6,200,-0.001,0.001); // costhetapoint namedistr="hcosthetapointS_"; namedistr+=i; TH1F *hcosthetapointS = new TH1F(namedistr.Data(), "cos#theta_{Point} distribution;cos#theta_{Point}",200,0,1.); namedistr="hcosthetapointxyS_"; namedistr+=i; TH1F *hcosthetapointxyS = new TH1F(namedistr.Data(), "cos#theta_{Point} XYdistribution;cos#theta_{Point}",300,0.,1.); TH1F* tmpMS = new TH1F(nameMassNocutsS.Data(),"D^{0} invariant mass; M [GeV]; Entries",300,1.5648,2.1648); //range (MD0-300MeV, mD0 + 300MeV) tmpMS->Sumw2(); fDistr->Add(hdcaS); fDistr->Add(hd0piS); fDistr->Add(hd0KS); fDistr->Add(hd0d0S); fDistr->Add(hcosthetapointS); fDistr->Add(hcosthetapointxyS); fDistr->Add(hdeclengthS); fDistr->Add(hnormdeclengthS); fDistr->Add(hdeclxyS); fDistr->Add(hnormdeclxyS); fDistr->Add(hdeclxyd0d0S); fDistr->Add(hnormdeclxyd0d0S); fDistr->Add(tmpMS); } // dca namedistr="hdcaB_"; namedistr+=i; TH1F *hdcaB = new TH1F(namedistr.Data(), "DCA distribution;dca [cm]",200,0.,0.1); // impact parameter namedistr="hd0B_"; namedistr+=i; TH1F *hd0B = new TH1F(namedistr.Data(), "Impact parameter distribution (both);d0 [cm]",200,-0.1,0.1); namedistr="hd0d0B_"; namedistr+=i; TH1F *hd0d0B = new TH1F(namedistr.Data(), "d_{0}#timesd_{0} distribution;d_{0}#timesd_{0} [cm^{2}]",200,-0.001,0.001); //decay lenght namedistr="hdeclB_"; namedistr+=i; TH1F *hdeclengthB = new TH1F(namedistr.Data(), "Decay Length^{2} distribution;Decay Length^{2} [cm^{2}]",200,0,0.015); namedistr="hnormdeclB_"; namedistr+=i; TH1F *hnormdeclengthB = new TH1F(namedistr.Data(), "Normalized Decay Length distribution;(Decay Length/Err)^{2} ",200,0,12.); namedistr="hdeclxyB_"; namedistr+=i; TH1F* hdeclxyB=new TH1F(namedistr.Data(),"Decay Length XY distribution;Decay Length XY [cm]",200,0,0.15); namedistr="hnormdeclxyB_"; namedistr+=i; TH1F* hnormdeclxyB=new TH1F(namedistr.Data(),"Normalized decay Length XY distribution;Decay Length XY/Err",200,0,6.); namedistr="hdeclxyd0d0B_"; namedistr+=i; TH2F* hdeclxyd0d0B=new TH2F(namedistr.Data(),"Correlation decay Length XY - d_{0}#times d_{0};Decay Length XY [cm];d_{0}#times d_{0}[cm^{2}]",200,0,0.15,200,-0.001,0.001); namedistr="hnormdeclxyd0d0B_"; namedistr+=i; TH2F* hnormdeclxyd0d0B=new TH2F(namedistr.Data(),"Correlation normalized decay Length XY - d_{0}#times d_{0};Decay Length XY/Err;d_{0}#times d_{0}[cm^{2}]",200,0,6,200,-0.001,0.001); // costhetapoint namedistr="hcosthetapointB_"; namedistr+=i; TH1F *hcosthetapointB = new TH1F(namedistr.Data(), "cos#theta_{Point} distribution;cos#theta_{Point}",200,0,1.); namedistr="hcosthetapointxyB_"; namedistr+=i; TH1F *hcosthetapointxyB = new TH1F(namedistr.Data(), "cos#theta_{Point} XY distribution;cos#theta_{Point} XY",300,0.,1.); TH1F* tmpMB = new TH1F(nameMassNocutsB.Data(),"D^{0} invariant mass; M [GeV]; Entries",300,1.5648,2.1648); //range (MD0-300MeV, mD0 + 300MeV) tmpMB->Sumw2(); fDistr->Add(hdcaB); fDistr->Add(hd0B); fDistr->Add(hd0d0B); fDistr->Add(hcosthetapointB); fDistr->Add(hcosthetapointxyB); fDistr->Add(hdeclengthB); fDistr->Add(hnormdeclengthB); fDistr->Add(hdeclxyB); fDistr->Add(hnormdeclxyB); fDistr->Add(hdeclxyd0d0B); fDistr->Add(hnormdeclxyd0d0B); fDistr->Add(tmpMB); //histograms filled only when the secondary vertex is recalculated w/o the daughter tracks (as requested in the cut object) if(fCuts->GetIsPrimaryWithoutDaughters()){ if(fReadMC){ namedistr="hd0vpiS_"; namedistr+=i; TH1F *hd0vpiS = new TH1F(namedistr.Data(), "Impact parameter distribution (pions)(vtx w/o these tracks);d0(#pi) [cm]",200,-0.1,0.1); namedistr="hd0vKS_"; namedistr+=i; TH1F *hd0vKS = new TH1F(namedistr.Data(), "Impact parameter distribution (kaons) (vtx w/o these tracks);d0(K) [cm]",200,-0.1,0.1); namedistr="hd0d0vS_"; namedistr+=i; TH1F *hd0d0vS = new TH1F(namedistr.Data(), "d_{0}#timesd_{0} distribution (vtx w/o these tracks);d_{0}#timesd_{0} [cm^{2}]",200,-0.001,0.001); namedistr="hdeclvS_"; namedistr+=i; TH1F *hdeclengthvS = new TH1F(namedistr.Data(), "Decay Length distribution (vtx w/o tracks);Decay Length [cm]",200,0,0.6); namedistr="hnormdeclvS_"; namedistr+=i; TH1F *hnormdeclengthvS = new TH1F(namedistr.Data(), "Normalized Decay Length distribution (vtx w/o tracks);Decay Length/Err ",200,0,10.); fDistr->Add(hd0vpiS); fDistr->Add(hd0vKS); fDistr->Add(hd0d0vS); fDistr->Add(hdeclengthvS); fDistr->Add(hnormdeclengthvS); } namedistr="hd0vmoresB_"; namedistr+=i; TH1F *hd0vmoresB = new TH1F(namedistr.Data(), "Impact parameter distribution (both);d0 [cm]",200,-0.1,0.1); namedistr="hd0d0vmoresB_"; namedistr+=i; TH1F *hd0d0vmoresB = new TH1F(namedistr.Data(), "Impact parameter distribution (prong +);d0 [cm]",200,-0.001,0.001); namedistr="hd0vB_"; namedistr+=i; TH1F *hd0vB = new TH1F(namedistr.Data(), "Impact parameter distribution (vtx w/o these tracks);d0 [cm]",200,-0.1,0.1); namedistr="hd0vp0B_"; namedistr+=i; TH1F *hd0vp0B = new TH1F(namedistr.Data(), "Impact parameter distribution (prong + ** vtx w/o these tracks);d0 [cm]",200,-0.1,0.1); namedistr="hd0vp1B_"; namedistr+=i; TH1F *hd0vp1B = new TH1F(namedistr.Data(), "Impact parameter distribution (prong - ** vtx w/o these tracks);d0 [cm]",200,-0.1,0.1); namedistr="hd0d0vB_"; namedistr+=i; TH1F *hd0d0vB = new TH1F(namedistr.Data(), "d_{0}#timesd_{0} distribution (vtx w/o these tracks);d_{0}#timesd_{0} [cm^{2}]",200,-0.001,0.001); namedistr="hdeclvB_"; namedistr+=i; TH1F *hdeclengthvB = new TH1F(namedistr.Data(), "Decay Length distribution (vtx w/o tracks);Decay Length [cm]",200,0,0.6); namedistr="hnormdeclvB_"; namedistr+=i; TH1F *hnormdeclengthvB = new TH1F(namedistr.Data(), "Normalized Decay Length distribution (vtx w/o tracks);Decay Length/Err ",200,0,10.); fDistr->Add(hd0vB); fDistr->Add(hd0vp0B); fDistr->Add(hd0vp1B); fDistr->Add(hd0vmoresB); fDistr->Add(hd0d0vB); fDistr->Add(hd0d0vmoresB); fDistr->Add(hdeclengthvB); fDistr->Add(hnormdeclengthvB); } } //histograms of invariant mass distributions //MC signal if(fReadMC){ TH1F* tmpSt = new TH1F(nameSgn.Data(), "D^{0} invariant mass - MC; M [GeV]; Entries",200,1.5648,2.1648); TH1F *tmpSl=(TH1F*)tmpSt->Clone(); tmpSt->Sumw2(); tmpSl->Sumw2(); //Reflection: histo filled with D0Mass which pass the cut (also) as D0bar and with D0bar which pass (also) the cut as D0 TH1F* tmpRt = new TH1F(nameRfl.Data(), "Reflected signal invariant mass - MC; M [GeV]; Entries",200,1.5648,2.1648); //TH1F *tmpRl=(TH1F*)tmpRt->Clone(); TH1F* tmpBt = new TH1F(nameBkg.Data(), "Background invariant mass - MC; M [GeV]; Entries",200,1.5648,2.1648); //TH1F *tmpBl=(TH1F*)tmpBt->Clone(); tmpBt->Sumw2(); //tmpBl->Sumw2(); tmpRt->Sumw2(); //tmpRl->Sumw2(); fOutputMass->Add(tmpSt); fOutputMass->Add(tmpRt); fOutputMass->Add(tmpBt); } //mass TH1F* tmpMt = new TH1F(nameMass.Data(),"D^{0} invariant mass; M [GeV]; Entries",200,1.5648,2.1648); //TH1F *tmpMl=(TH1F*)tmpMt->Clone(); tmpMt->Sumw2(); //tmpMl->Sumw2(); //distribution w/o cuts large range // TH1F* tmpMS = new TH1F(nameMassNocutsS.Data(),"D^{0} invariant mass; M [GeV]; Entries",300,0.7,3.); fOutputMass->Add(tmpMt); if(fSys==0){ //histograms filled only in pp to save time in PbPb if(fFillVarHists){ if(fReadMC){ // pT namedistr="hptpiS_"; namedistr+=i; TH1F *hptpiS = new TH1F(namedistr.Data(), "P_{T} distribution (pions);p_{T} [GeV/c]",200,0.,8.); namedistr="hptKS_"; namedistr+=i; TH1F *hptKS = new TH1F(namedistr.Data(), "P_{T} distribution (kaons);p_{T} [GeV/c]",200,0.,8.); // costhetastar namedistr="hcosthetastarS_"; namedistr+=i; TH1F *hcosthetastarS = new TH1F(namedistr.Data(), "cos#theta* distribution;cos#theta*",200,-1.,1.); //pT no mass cut namedistr="hptpiSnoMcut_"; namedistr+=i; TH1F *hptpiSnoMcut = new TH1F(namedistr.Data(), "P_{T} distribution (pions);p_{T} [GeV/c]",200,0.,8.); namedistr="hptKSnoMcut_"; namedistr+=i; TH1F *hptKSnoMcut = new TH1F(namedistr.Data(), "P_{T} distribution (kaons);p_{T} [GeV/c]",200,0.,8.); fDistr->Add(hptpiS); fDistr->Add(hptKS); fDistr->Add(hcosthetastarS); fDistr->Add(hptpiSnoMcut); fDistr->Add(hptKSnoMcut); // costhetapoint vs d0 or d0d0 namedistr="hcosthpointd0S_"; namedistr+=i; TH2F *hcosthpointd0S= new TH2F(namedistr.Data(),"Correlation cos#theta_{Point}-d_{0};cos#theta_{Point};d_{0} [cm^{2}]",200,0,1.,200,-0.001,0.001); namedistr="hcosthpointd0d0S_"; namedistr+=i; TH2F *hcosthpointd0d0S= new TH2F(namedistr.Data(),"Correlation cos#theta_{Point}-d_{0}#timesd_{0};cos#theta_{Point};d_{0}#timesd_{0} [cm^{2}]",200,0,1.,200,-0.001,0.001); fDistr->Add(hcosthpointd0S); fDistr->Add(hcosthpointd0d0S); //to compare with AliAnalysisTaskCharmFraction TH1F* tmpS27t = new TH1F(nameSgn27.Data(),"D^{0} invariant mass in M(D^{0}) +/- 27 MeV - MC; M [GeV]; Entries",200,1.5648,2.1648); TH1F *tmpS27l=(TH1F*)tmpS27t->Clone(); tmpS27t->Sumw2(); tmpS27l->Sumw2(); fOutputMass->Add(tmpS27t); fOutputMass->Add(tmpS27l); } // pT namedistr="hptB_"; namedistr+=i; TH1F *hptB = new TH1F(namedistr.Data(), "P_{T} distribution;p_{T} [GeV/c]",200,0.,8.); // costhetastar namedistr="hcosthetastarB_"; namedistr+=i; TH1F *hcosthetastarB = new TH1F(namedistr.Data(), "cos#theta* distribution;cos#theta*",200,-1.,1.); //pT no mass cut namedistr="hptB1prongnoMcut_"; namedistr+=i; TH1F *hptB1pnoMcut = new TH1F(namedistr.Data(), "P_{T} distribution;p_{T} [GeV/c]",200,0.,8.); namedistr="hptB2prongsnoMcut_"; namedistr+=i; TH1F *hptB2pnoMcut = new TH1F(namedistr.Data(), "P_{T} distribution;p_{T} [GeV/c]",200,0.,8.); fDistr->Add(hptB); fDistr->Add(hcosthetastarB); fDistr->Add(hptB1pnoMcut); fDistr->Add(hptB2pnoMcut); //impact parameter of negative/positive track namedistr="hd0p0B_"; namedistr+=i; TH1F *hd0p0B = new TH1F(namedistr.Data(), "Impact parameter distribution (prong +);d0 [cm]",200,-0.1,0.1); namedistr="hd0p1B_"; namedistr+=i; TH1F *hd0p1B = new TH1F(namedistr.Data(), "Impact parameter distribution (prong -);d0 [cm]",200,-0.1,0.1); //impact parameter corrected for strangeness namedistr="hd0moresB_"; namedistr+=i; TH1F *hd0moresB = new TH1F(namedistr.Data(), "Impact parameter distribution (both);d0 [cm]",200,-0.1,0.1); namedistr="hd0d0moresB_"; namedistr+=i; TH1F *hd0d0moresB = new TH1F(namedistr.Data(), "Impact parameter distribution (prong +);d0 [cm]",200,-0.001,0.001); namedistr="hcosthetapointmoresB_"; namedistr+=i; TH1F *hcosthetapointmoresB = new TH1F(namedistr.Data(), "cos#theta_{Point} distribution;cos#theta_{Point}",200,0,1.); // costhetapoint vs d0 or d0d0 namedistr="hcosthpointd0B_"; namedistr+=i; TH2F *hcosthpointd0B= new TH2F(namedistr.Data(),"Correlation cos#theta_{Point}-d_{0};cos#theta_{Point};d_{0} [cm^{2}]",200,0,1.,200,-0.001,0.001); namedistr="hcosthpointd0d0B_"; namedistr+=i; TH2F *hcosthpointd0d0B= new TH2F(namedistr.Data(),"Correlation cos#theta_{Point}-d_{0}#timesd_{0};cos#theta_{Point};d_{0}#timesd_{0} [cm^{2}]",200,0,1.,200,-0.001,0.001); fDistr->Add(hd0p0B); fDistr->Add(hd0p1B); fDistr->Add(hd0moresB); fDistr->Add(hd0d0moresB); fDistr->Add(hcosthetapointmoresB); fDistr->Add(hcosthpointd0B); fDistr->Add(hcosthpointd0d0B); } } //end pp histo } //for Like sign analysis if(fArray==1){ namedistr="hpospair"; TH1F* hpospair=new TH1F(namedistr.Data(),"Number of positive pairs",fCuts->GetNPtBins(),-0.5,fCuts->GetNPtBins()-0.5); namedistr="hnegpair"; TH1F* hnegpair=new TH1F(namedistr.Data(),"Number of negative pairs",fCuts->GetNPtBins(),-0.5,fCuts->GetNPtBins()-0.5); fOutputMass->Add(hpospair); fOutputMass->Add(hnegpair); } const char* nameoutput=GetOutputSlot(3)->GetContainer()->GetName(); fNentries=new TH1F(nameoutput, "Integral(1,2) = number of AODs *** Integral(2,3) = number of candidates selected with cuts *** Integral(3,4) = number of D0 selected with cuts *** Integral(4,5) = events with good vertex *** Integral(5,6) = pt out of bounds", 16,-0.5,15.5); fNentries->GetXaxis()->SetBinLabel(1,"nEventsAnal"); fNentries->GetXaxis()->SetBinLabel(2,"nCandSel(Cuts)"); if(fReadMC) fNentries->GetXaxis()->SetBinLabel(3,"nD0Selected"); else fNentries->GetXaxis()->SetBinLabel(3,"Dstar<-D0"); fNentries->GetXaxis()->SetBinLabel(4,"nEventsGoodVtxS"); fNentries->GetXaxis()->SetBinLabel(5,"ptbin = -1"); fNentries->GetXaxis()->SetBinLabel(6,"no daughter"); if(fSys==0) fNentries->GetXaxis()->SetBinLabel(7,"nCandSel(Tr)"); if(fFillVarHists){ fNentries->GetXaxis()->SetBinLabel(8,"PID=0"); fNentries->GetXaxis()->SetBinLabel(9,"PID=1"); fNentries->GetXaxis()->SetBinLabel(10,"PID=2"); fNentries->GetXaxis()->SetBinLabel(11,"PID=3"); } if(fReadMC && fSys==0){ fNentries->GetXaxis()->SetBinLabel(12,"K"); fNentries->GetXaxis()->SetBinLabel(13,"Lambda"); } fNentries->GetXaxis()->SetBinLabel(14,"Pile-up Rej"); fNentries->GetXaxis()->SetBinLabel(15,"N. of 0SMH"); if(fSys==1) fNentries->GetXaxis()->SetBinLabel(16,"Nev in centr"); fNentries->GetXaxis()->SetNdivisions(1,kFALSE); fCounter = new AliNormalizationCounter(Form("%s",GetOutputSlot(5)->GetContainer()->GetName())); // Post the data PostData(1,fOutputMass); if(fFillVarHists) PostData(2,fDistr); PostData(3,fNentries); PostData(5,fCounter); return; } //________________________________________________________________________ void AliAnalysisTaskSED0Mass::UserExec(Option_t */*option*/) { // Execute analysis for current event: // heavy flavor candidates association to MC truth //cout<<"I'm in UserExec"< %f\n",fD0toKpiCuts[3]); // printf(" pTpi [GeV/c] > %f\n",fD0toKpiCuts[4]); // printf(" |d0K| [cm] < %f\n",fD0toKpiCuts[5]); // printf(" |d0pi| [cm] < %f\n",fD0toKpiCuts[6]); // printf(" d0d0 [cm^2] < %f\n",fD0toKpiCuts[7]); // printf(" cosThetaPoint > %f\n",fD0toKpiCuts[8]); AliAODEvent *aod = dynamic_cast (InputEvent()); TString bname; if(fArray==0){ //D0 candidates // load D0->Kpi candidates //cout<<"D0 candidates"< (AODEvent()); // in this case the braches in the deltaAOD (AliAOD.VertexingHF.root) // have to taken from the AOD event hold by the AliAODExtension AliAODHandler* aodHandler = (AliAODHandler*) ((AliAnalysisManager::GetAnalysisManager())->GetOutputEventHandler()); if(aodHandler->GetExtensions()) { AliAODExtension *ext = (AliAODExtension*)aodHandler->GetExtensions()->FindObject("AliAOD.VertexingHF.root"); AliAODEvent* aodFromExt = ext->GetAOD(); inputArray=(TClonesArray*)aodFromExt->GetList()->FindObject(bname.Data()); } } else if(aod) { inputArray=(TClonesArray*)aod->GetList()->FindObject(bname.Data()); } if(!inputArray || !aod) { printf("AliAnalysisTaskSED0Mass::UserExec: input branch not found!\n"); return; } // fix for temporary bug in ESDfilter // the AODs with null vertex pointer didn't pass the PhysSel if(!aod->GetPrimaryVertex() || TMath::Abs(aod->GetMagneticField())<0.001) return; TClonesArray *mcArray = 0; AliAODMCHeader *mcHeader = 0; if(fReadMC) { // load MC particles mcArray = (TClonesArray*)aod->GetList()->FindObject(AliAODMCParticle::StdBranchName()); if(!mcArray) { printf("AliAnalysisTaskSED0Mass::UserExec: MC particles branch not found!\n"); return; } // load MC header mcHeader = (AliAODMCHeader*)aod->GetList()->FindObject(AliAODMCHeader::StdBranchName()); if(!mcHeader) { printf("AliAnalysisTaskSED0Mass::UserExec: MC header branch not found!\n"); return; } } //printf("VERTEX Z %f %f\n",vtx1->GetZ(),mcHeader->GetVtxZ()); //histogram filled with 1 for every AOD fNentries->Fill(0); fCounter->StoreEvent(aod,fReadMC); // trigger class for PbPb C0SMH-B-NOPF-ALLNOTRD, C0SMH-B-NOPF-ALL TString trigclass=aod->GetFiredTriggerClasses(); if(trigclass.Contains("C0SMH-B-NOPF-ALLNOTRD") || trigclass.Contains("C0SMH-B-NOPF-ALL")) fNentries->Fill(14); if(!fCuts->IsEventSelected(aod)) { if(fCuts->GetWhyRejection()==1) // rejected for pileup fNentries->Fill(13); if(fSys==1 && (fCuts->GetWhyRejection()==2 || fCuts->GetWhyRejection()==3)) fNentries->Fill(15); return; } // AOD primary vertex AliAODVertex *vtx1 = (AliAODVertex*)aod->GetPrimaryVertex(); Bool_t isGoodVtx=kFALSE; //vtx1->Print(); TString primTitle = vtx1->GetTitle(); if(primTitle.Contains("VertexerTracks") && vtx1->GetNContributors()>0) { isGoodVtx=kTRUE; fNentries->Fill(3); } // loop over candidates Int_t nInD0toKpi = inputArray->GetEntriesFast(); if(fDebug>2) printf("Number of D0->Kpi: %d\n",nInD0toKpi); // FILE *f=fopen("4display.txt","a"); // fprintf(f,"Number of D0->Kpi: %d\n",nInD0toKpi); Int_t nSelectedloose=0,nSelectedtight=0; for (Int_t iD0toKpi = 0; iD0toKpi < nInD0toKpi; iD0toKpi++) { AliAODRecoDecayHF2Prong *d = (AliAODRecoDecayHF2Prong*)inputArray->UncheckedAt(iD0toKpi); if(d->GetSelectionMap()) if(!d->HasSelectionBit(AliRDHFCuts::kD0toKpiCuts)){ fNentries->Fill(2); continue; //skip the D0 from Dstar } // Bool_t unsetvtx=kFALSE; // if(!d->GetOwnPrimaryVtx()) { // d->SetOwnPrimaryVtx(vtx1); // needed to compute all variables // unsetvtx=kTRUE; // } if ( fCuts->IsInFiducialAcceptance(d->Pt(),d->Y(421)) ) { nSelectedloose++; nSelectedtight++; if(fSys==0){ if(fCuts->IsSelected(d,AliRDHFCuts::kTracks,aod))fNentries->Fill(6); } Int_t ptbin=fCuts->PtBin(d->Pt()); if(ptbin==-1) {fNentries->Fill(4); continue;} //out of bounds fIsSelectedCandidate=fCuts->IsSelected(d,AliRDHFCuts::kCandidate,aod); //selected if(fFillVarHists) { //if(!fCutOnDistr || (fCutOnDistr && fIsSelectedCandidate)) { fDaughterTracks.AddAt((AliAODTrack*)d->GetDaughter(0),0); fDaughterTracks.AddAt((AliAODTrack*)d->GetDaughter(1),1); //check daughters if(!fDaughterTracks.UncheckedAt(0) || !fDaughterTracks.UncheckedAt(1)) { AliDebug(1,"at least one daughter not found!"); fNentries->Fill(5); fDaughterTracks.Clear(); continue; } //} FillVarHists(aod,d,mcArray,fCuts,fDistr); } FillMassHists(d,mcArray,fCuts,fOutputMass); } fDaughterTracks.Clear(); //if(unsetvtx) d->UnsetOwnPrimaryVtx(); } //end for prongs fCounter->StoreCandidates(aod,nSelectedloose,kTRUE); fCounter->StoreCandidates(aod,nSelectedtight,kFALSE); // Post the data PostData(1,fOutputMass); if(fFillVarHists) PostData(2,fDistr); PostData(3,fNentries); PostData(5,fCounter); return; } //____________________________________________________________________________ void AliAnalysisTaskSED0Mass::FillVarHists(AliAODEvent* aod,AliAODRecoDecayHF2Prong *part, TClonesArray *arrMC, AliRDHFCutsD0toKpi *cuts, TList *listout){ // // function used in UserExec to fill variable histograms: // Int_t pdgDgD0toKpi[2]={321,211}; Int_t lab=-9999; if(fReadMC) lab=part->MatchToMC(421,arrMC,2,pdgDgD0toKpi); //return MC particle label if the array corresponds to a D0, -1 if not (cf. AliAODRecoDecay.cxx) //Double_t pt = d->Pt(); //mother pt Int_t isSelectedPID=3; if(!fReadMC || (fReadMC && fUsePid4Distr)) isSelectedPID=cuts->IsSelectedPID(part); //0 rejected,1 D0,2 Dobar, 3 both if (isSelectedPID==0)fNentries->Fill(7); if (isSelectedPID==1)fNentries->Fill(8); if (isSelectedPID==2)fNentries->Fill(9); if (isSelectedPID==3)fNentries->Fill(10); //fNentries->Fill(8+isSelectedPID); if(fCutOnDistr && !fIsSelectedCandidate) return; //printf("\nif no cuts or cuts passed\n"); //add distr here UInt_t pdgs[2]; Double_t mPDG=TDatabasePDG::Instance()->GetParticle(421)->Mass(); pdgs[0]=211; pdgs[1]=321; Double_t minvD0 = part->InvMassD0(); pdgs[1]=211; pdgs[0]=321; Double_t minvD0bar = part->InvMassD0bar(); //cout<<"inside mass cut"<PtBin(part->Pt()); Double_t dz1[2],dz2[2],covar1[3],covar2[3];//,d0xd0proper,errd0xd0proper; dz1[0]=-99; dz2[0]=-99; Double_t d0[2]; Double_t decl[2]={-99,-99}; Bool_t recalcvtx=kFALSE; if(fCuts->GetIsPrimaryWithoutDaughters()){ recalcvtx=kTRUE; //recalculate vertex AliAODVertex *vtxProp=0x0; vtxProp=GetPrimaryVtxSkipped(aod); if(vtxProp) { part->SetOwnPrimaryVtx(vtxProp); //Bool_t unsetvtx=kTRUE; //Calculate d0 for daughter tracks with Vtx Skipped AliESDtrack *esdtrack1=new AliESDtrack((AliVTrack*)fDaughterTracks.UncheckedAt(0)); AliESDtrack *esdtrack2=new AliESDtrack((AliVTrack*)fDaughterTracks.UncheckedAt(1)); esdtrack1->PropagateToDCA(vtxProp,aod->GetMagneticField(),1.,dz1,covar1); esdtrack2->PropagateToDCA(vtxProp,aod->GetMagneticField(),1.,dz2,covar2); delete vtxProp; vtxProp=NULL; delete esdtrack1; delete esdtrack2; } d0[0]=dz1[0]; d0[1]=dz2[0]; decl[0]=part->DecayLength2(); decl[1]=part->NormalizedDecayLength2(); part->UnsetOwnPrimaryVtx(); } Double_t cosThetaStarD0 = 99; Double_t cosThetaStarD0bar = 99; Double_t cosPointingAngle = 99; Double_t normalizedDecayLength2 = -1, normalizedDecayLengthxy=-1; Double_t decayLength2 = -1, decayLengthxy=-1; Double_t ptProng[2]={-99,-99}; Double_t d0Prong[2]={-99,-99}; //disable the PID if(!fUsePid4Distr) isSelectedPID=0; if((lab>=0 && fReadMC) || (!fReadMC && isSelectedPID)){ //signal (from MC or PID) //check pdg of the prongs AliAODTrack *prong0=(AliAODTrack*)fDaughterTracks.UncheckedAt(0); AliAODTrack *prong1=(AliAODTrack*)fDaughterTracks.UncheckedAt(1); if(!prong0 || !prong1) { return; } Int_t labprong[2]; if(fReadMC){ labprong[0]=prong0->GetLabel(); labprong[1]=prong1->GetLabel(); } AliAODMCParticle *mcprong=0; Int_t pdgProng[2]={0,0}; for (Int_t iprong=0;iprong<2;iprong++){ if(fReadMC && labprong[iprong]>=0) { mcprong= (AliAODMCParticle*)arrMC->At(labprong[iprong]); pdgProng[iprong]=mcprong->GetPdgCode(); } } if(fSys==0){ //no mass cut ditributions: ptbis fillthispi="hptpiSnoMcut_"; fillthispi+=ptbin; fillthisK="hptKSnoMcut_"; fillthisK+=ptbin; if ((TMath::Abs(pdgProng[0]) == 211 && TMath::Abs(pdgProng[1]) == 321) || (isSelectedPID==1 || isSelectedPID==3)){ ((TH1F*)listout->FindObject(fillthispi))->Fill(prong0->Pt()); ((TH1F*)listout->FindObject(fillthisK))->Fill(prong1->Pt()); } if ((TMath::Abs(pdgProng[0]) == 321 && TMath::Abs(pdgProng[1]) == 211) || (isSelectedPID==2 || isSelectedPID==3)){ ((TH1F*)listout->FindObject(fillthisK))->Fill(prong0->Pt()); ((TH1F*)listout->FindObject(fillthispi))->Fill(prong1->Pt()); } } //no mass cut ditributions: mass fillthis="hMassS_"; fillthis+=ptbin; if ((fReadMC && ((AliAODMCParticle*)arrMC->At(lab))->GetPdgCode() == 421) || (!fReadMC && (isSelectedPID==1 || isSelectedPID==3))){//D0 ((TH1F*)listout->FindObject(fillthis))->Fill(minvD0); } else { //D0bar if(fReadMC || (!fReadMC && isSelectedPID > 1)) ((TH1F*)listout->FindObject(fillthis))->Fill(minvD0bar); } //apply cut on invariant mass on the pair if(TMath::Abs(minvD0-mPDG)CosThetaStarD0(); cosThetaStarD0bar = part->CosThetaStarD0bar(); cosPointingAngle = part->CosPointingAngle(); normalizedDecayLength2 = part->NormalizedDecayLength2(); decayLength2 = part->DecayLength2(); decayLengthxy = part->DecayLengthXY(); normalizedDecayLengthxy=decayLengthxy/part->DecayLengthXYError(); ptProng[0]=prong0->Pt(); ptProng[1]=prong1->Pt(); d0Prong[0]=part->Getd0Prong(0); d0Prong[1]=part->Getd0Prong(1); if(fArray==1) cout<<"LS signal: ERROR"<GetLabel(); //cout<<"prong name = "<GetName()<<" label = "<GetLabel()<=0) { mcprong= (AliAODMCParticle*)arrMC->At(labprong[iprong]); pdgprong=mcprong->GetPdgCode(); } Bool_t isPionHere[2]={(isSelectedPID==1 || isSelectedPID==3) ? kTRUE : kFALSE,(isSelectedPID==2 || isSelectedPID==3) ? kTRUE : kFALSE}; if(TMath::Abs(pdgprong)==211 || isPionHere[iprong]) { //cout<<"pi"<FindObject(fillthispi))->Fill(ptProng[iprong]); } fillthispi="hd0piS_"; fillthispi+=ptbin; ((TH1F*)listout->FindObject(fillthispi))->Fill(d0Prong[iprong]); if(recalcvtx) { fillthispi="hd0vpiS_"; fillthispi+=ptbin; ((TH1F*)listout->FindObject(fillthispi))->Fill(d0[iprong]); } } if(TMath::Abs(pdgprong)==321 || !isPionHere[iprong]) { //cout<<"kappa"<FindObject(fillthisK))->Fill(ptProng[iprong]); } fillthisK="hd0KS_"; fillthisK+=ptbin; ((TH1F*)listout->FindObject(fillthisK))->Fill(d0Prong[iprong]); if (recalcvtx){ fillthisK="hd0vKS_"; fillthisK+=ptbin; ((TH1F*)listout->FindObject(fillthisK))->Fill(d0[iprong]); } } if(fSys==0){ fillthis="hcosthpointd0S_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(cosPointingAngle,d0Prong[iprong]); } } //end loop on prongs fillthis="hdcaS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(part->GetDCA()); fillthis="hcosthetapointS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(cosPointingAngle); fillthis="hcosthetapointxyS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(part->CosPointingAngleXY()); fillthis="hd0d0S_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(part->Prodd0d0()); fillthis="hdeclS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(decayLength2); fillthis="hnormdeclS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(normalizedDecayLength2); fillthis="hdeclxyS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(decayLengthxy); fillthis="hnormdeclxyS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(normalizedDecayLengthxy); fillthis="hdeclxyd0d0S_"; fillthis+=ptbin; ((TH2F*)listout->FindObject(fillthis))->Fill(decayLengthxy,d0Prong[0]*d0Prong[1]); fillthis="hnormdeclxyd0d0S_"; fillthis+=ptbin; ((TH2F*)listout->FindObject(fillthis))->Fill(normalizedDecayLengthxy,d0Prong[0]*d0Prong[1]); if(recalcvtx) { fillthis="hdeclvS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(decl[0]); fillthis="hnormdeclvS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(decl[1]); fillthis="hd0d0vS_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0[0]*d0[1]); } if(fSys==0){ fillthis="hcosthetastarS_"; fillthis+=ptbin; if ((fReadMC && ((AliAODMCParticle*)arrMC->At(lab))->GetPdgCode() == 421)) ((TH1F*)listout->FindObject(fillthis))->Fill(cosThetaStarD0); else { if (fReadMC || isSelectedPID>1)((TH1F*)listout->FindObject(fillthis))->Fill(cosThetaStarD0bar); if(isSelectedPID==1 || isSelectedPID==3)((TH1F*)listout->FindObject(fillthis))->Fill(cosThetaStarD0); } fillthis="hcosthpointd0d0S_"; fillthis+=ptbin; ((TH2F*)listout->FindObject(fillthis))->Fill(cosPointingAngle,part->Prodd0d0()); } } //end mass cut } else{ //Background or LS //if(!fReadMC){ //cout<<"is background"<FindObject(fillthis))->Fill(minvD0); if (!fCutOnDistr || (fCutOnDistr && fIsSelectedCandidate>1)) ((TH1F*)listout->FindObject(fillthis))->Fill(minvD0bar); if(fSys==0){ fillthis="hptB1prongnoMcut_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(((AliAODTrack*)fDaughterTracks.UncheckedAt(0))->Pt()); fillthis="hptB2prongsnoMcut_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(((AliAODTrack*)fDaughterTracks.UncheckedAt(0))->Pt()); ((TH1F*)listout->FindObject(fillthis))->Fill(((AliAODTrack*)fDaughterTracks.UncheckedAt(0))->Pt()); } //apply cut on invariant mass on the pair if(TMath::Abs(minvD0-mPDG)Pt(); ptProng[1]=((AliAODTrack*)fDaughterTracks.UncheckedAt(0))->Pt(); cosThetaStarD0 = part->CosThetaStarD0(); cosThetaStarD0bar = part->CosThetaStarD0bar(); } cosPointingAngle = part->CosPointingAngle(); normalizedDecayLength2 = part->NormalizedDecayLength2(); decayLength2 = part->DecayLength2(); decayLengthxy = part->DecayLengthXY(); normalizedDecayLengthxy=decayLengthxy/part->DecayLengthXYError(); d0Prong[0]=part->Getd0Prong(0); d0Prong[1]=part->Getd0Prong(1); AliAODTrack *prongg=(AliAODTrack*)fDaughterTracks.UncheckedAt(0); if(!prongg) { if(fDebug>2) cout<<"No daughter found"; return; } else{ if(fArray==1){ if(prongg->Charge()==1) { //fTotPosPairs[ptbin]++; ((TH1F*)fOutputMass->FindObject("hpospair"))->Fill(ptbin); } else { //fTotNegPairs[ptbin]++; ((TH1F*)fOutputMass->FindObject("hnegpair"))->Fill(ptbin); } } } fillthis="hd0B_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0Prong[0]); ((TH1F*)listout->FindObject(fillthis))->Fill(d0Prong[1]); if(fReadMC){ Int_t pdgMother[2]={0,0}; Double_t factor[2]={1,1}; for(Int_t iprong=0;iprong<2;iprong++){ AliAODTrack *prong=(AliAODTrack*)fDaughterTracks.UncheckedAt(iprong); lab=prong->GetLabel(); if(lab>=0){ AliAODMCParticle* mcprong=(AliAODMCParticle*)arrMC->At(lab); if(mcprong){ Int_t labmom=mcprong->GetMother(); if(labmom>=0){ AliAODMCParticle* mcmother=(AliAODMCParticle*)arrMC->At(labmom); if(mcmother) pdgMother[iprong]=mcmother->GetPdgCode(); } } } if(fSys==0){ fillthis="hd0moresB_"; fillthis+=ptbin; if(TMath::Abs(pdgMother[iprong])==310 || TMath::Abs(pdgMother[iprong])==130 || TMath::Abs(pdgMother[iprong])==321){ //K^0_S, K^0_L, K^+- if(ptProng[iprong]<=1)factor[iprong]=1./.7; else factor[iprong]=1./.6; fNentries->Fill(11); } if(TMath::Abs(pdgMother[iprong])==3122) { //Lambda factor[iprong]=1./0.25; fNentries->Fill(12); } fillthis="hd0moresB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0Prong[iprong],factor[iprong]); if(recalcvtx){ fillthis="hd0vmoresB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0[iprong],factor[iprong]); } } } //loop on prongs if(fSys==0){ fillthis="hd0d0moresB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(part->Prodd0d0(),factor[0]*factor[1]); fillthis="hcosthetapointmoresB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(cosPointingAngle,factor[0]*factor[1]); if(recalcvtx){ fillthis="hd0d0vmoresB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0[0]*d0[1],factor[0]*factor[1]); } } } //readMC if(fSys==0){ //normalise pt distr to half afterwards fillthis="hptB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(ptProng[0]); ((TH1F*)listout->FindObject(fillthis))->Fill(ptProng[1]); fillthis="hcosthetastarB_"; fillthis+=ptbin; if (!fCutOnDistr || (fCutOnDistr && (fIsSelectedCandidate==1 || fIsSelectedCandidate==3)))((TH1F*)listout->FindObject(fillthis))->Fill(cosThetaStarD0); if (!fCutOnDistr || (fCutOnDistr && fIsSelectedCandidate>1))((TH1F*)listout->FindObject(fillthis))->Fill(cosThetaStarD0bar); fillthis="hd0p0B_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0Prong[0]); fillthis="hd0p1B_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0Prong[1]); fillthis="hcosthpointd0d0B_"; fillthis+=ptbin; ((TH2F*)listout->FindObject(fillthis))->Fill(cosPointingAngle,part->Prodd0d0()); fillthis="hcosthpointd0B_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(cosPointingAngle,d0Prong[0]); ((TH1F*)listout->FindObject(fillthis))->Fill(cosPointingAngle,d0Prong[1]); if(recalcvtx){ fillthis="hd0vp0B_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0[0]); fillthis="hd0vp1B_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0[1]); fillthis="hd0vB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0[0]); ((TH1F*)listout->FindObject(fillthis))->Fill(d0[1]); } } fillthis="hdcaB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(part->GetDCA()); fillthis="hd0d0B_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0Prong[0]*d0Prong[1]); if(recalcvtx){ fillthis="hd0d0vB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(d0[0]*d0[1]); } fillthis="hcosthetapointB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(cosPointingAngle); fillthis="hcosthetapointxyB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(part->CosPointingAngleXY()); fillthis="hdeclB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(decayLength2); fillthis="hnormdeclB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(normalizedDecayLength2); fillthis="hdeclxyB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(decayLengthxy); fillthis="hnormdeclxyB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(normalizedDecayLengthxy); fillthis="hdeclxyd0d0B_"; fillthis+=ptbin; ((TH2F*)listout->FindObject(fillthis))->Fill(decayLengthxy,d0Prong[0]*d0Prong[1]); fillthis="hnormdeclxyd0d0B_"; fillthis+=ptbin; ((TH2F*)listout->FindObject(fillthis))->Fill(normalizedDecayLengthxy,d0Prong[0]*d0Prong[1]); if(recalcvtx) { fillthis="hdeclvB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(decl[0]); fillthis="hnormdeclvB_"; fillthis+=ptbin; ((TH1F*)listout->FindObject(fillthis))->Fill(decl[1]); } }//mass cut }//else (background) return; } //____________________________________________________________________________ void AliAnalysisTaskSED0Mass::FillMassHists(AliAODRecoDecayHF2Prong *part, TClonesArray *arrMC, AliRDHFCutsD0toKpi* cuts, TList *listout){ // // function used in UserExec to fill mass histograms: // Double_t mPDG=TDatabasePDG::Instance()->GetParticle(421)->Mass(); //cout<<"is selected = "<GetWhy()<2) cout<<"Candidate selected"<InvMassD0(), invmassD0bar = part->InvMassD0bar(); //printf("SELECTED\n"); Int_t ptbin=cuts->PtBin(part->Pt()); // AliAODTrack *prong=(AliAODTrack*)fDaughterTracks.UncheckedAt(0); // if(!prong) { // AliDebug(2,"No daughter found"); // return; // } // else{ // if(prong->Charge()==1) { // ((TH1F*)fDistr->FindObject("hpospair"))->Fill(fCuts->GetNPtBins()+ptbin); // //fTotPosPairs[ptbin]++; // } else { // ((TH1F*)fDistr->FindObject("hnegpair"))->Fill(fCuts->GetNPtBins()+ptbin); // //fTotNegPairs[ptbin]++; // } // } // for(Int_t it=0;it<2;it++){ // //request on spd points to be addes // if(/*nSPD==2 && */part->Pt() > 5. && (TMath::Abs(invmassD0-mPDG)<0.01 || TMath::Abs(invmassD0bar-mPDG)<0.01)){ // FILE *f=fopen("4display.txt","a"); // fprintf(f,"pt: %f \n Rapidity: %f \t Period Number: %x \t Run Number: %d \t BunchCrossNumb: %d \t OrbitNumber: %d\n",part->Pt(),part->Y(421),aod->GetPeriodNumber(),aod->GetRunNumber(),aod->GetBunchCrossNumber(),aod->GetOrbitNumber()); // fclose(f); // //printf("PrimVtx NContributors: %d \n Prongs Rel Angle: %f \n \n",ncont,relangle); // } // } TString fillthis=""; Int_t pdgDgD0toKpi[2]={321,211}; Int_t labD0=-1; if (fReadMC) labD0 = part->MatchToMC(421,arrMC,2,pdgDgD0toKpi); //return MC particle label if the array corresponds to a D0, -1 if not (cf. AliAODRecoDecay.cxx) //count candidates selected by cuts fNentries->Fill(1); //count true D0 selected by cuts if (fReadMC && labD0>=0) fNentries->Fill(2); if ((fIsSelectedCandidate==1 || fIsSelectedCandidate==3) && fFillOnlyD0D0bar<2) { //D0 if(fReadMC){ if(labD0>=0) { if(fArray==1) cout<<"LS signal ERROR"<At(labD0); Int_t pdgD0 = partD0->GetPdgCode(); //cout<<"pdg = "<FindObject(fillthis)))->Fill(invmassD0); if(fSys==0){ if(TMath::Abs(invmassD0 - mPDG) < 0.027){ fillthis="histSgn27_"; fillthis+=ptbin; ((TH1F*)(listout->FindObject(fillthis)))->Fill(invmassD0); } } } else{ //it was a D0bar fillthis="histRfl_"; fillthis+=ptbin; ((TH1F*)(listout->FindObject(fillthis)))->Fill(invmassD0); } } else {//background fillthis="histBkg_"; fillthis+=ptbin; ((TH1F*)(listout->FindObject(fillthis)))->Fill(invmassD0); } }else{ fillthis="histMass_"; fillthis+=ptbin; //cout<<"Filling "<FindObject(fillthis)))->Fill(invmassD0); } } if (fIsSelectedCandidate>1 && (fFillOnlyD0D0bar==0 || fFillOnlyD0D0bar==2)) { //D0bar if(fReadMC){ if(labD0>=0) { if(fArray==1) cout<<"LS signal ERROR"<At(labD0); Int_t pdgD0 = partD0->GetPdgCode(); //cout<<" pdg = "<FindObject(fillthis)))->Fill(invmassD0bar); // if (TMath::Abs(invmassD0bar - mPDG) < 0.027){ // fillthis="histSgn27_"; // fillthis+=ptbin; // ((TH1F*)(listout->FindObject(fillthis)))->Fill(invmassD0bar); // } } else{ fillthis="histRfl_"; fillthis+=ptbin; ((TH1F*)(listout->FindObject(fillthis)))->Fill(invmassD0bar); } } else {//background or LS fillthis="histBkg_"; fillthis+=ptbin; ((TH1F*)(listout->FindObject(fillthis)))->Fill(invmassD0bar); } }else{ fillthis="histMass_"; fillthis+=ptbin; //printf("Fill mass with D0bar"); ((TH1F*)listout->FindObject(fillthis))->Fill(invmassD0bar); } } return; } //__________________________________________________________________________ AliAODVertex* AliAnalysisTaskSED0Mass::GetPrimaryVtxSkipped(AliAODEvent *aodev){ //Calculate the primary vertex w/o the daughter tracks of the candidate Int_t skipped[2]; Int_t nTrksToSkip=2; AliAODTrack *dgTrack = (AliAODTrack*)fDaughterTracks.UncheckedAt(0); if(!dgTrack){ AliDebug(2,"no daughter found!"); return 0x0; } skipped[0]=dgTrack->GetID(); dgTrack = (AliAODTrack*)fDaughterTracks.UncheckedAt(1); if(!dgTrack){ AliDebug(2,"no daughter found!"); return 0x0; } skipped[1]=dgTrack->GetID(); AliESDVertex *vertexESD=0x0; AliAODVertex *vertexAOD=0x0; AliVertexerTracks *vertexer = new AliVertexerTracks(aodev->GetMagneticField()); // vertexer->SetSkipTracks(nTrksToSkip,skipped); vertexer->SetMinClusters(4); vertexESD = (AliESDVertex*)vertexer->FindPrimaryVertex(aodev); if(!vertexESD) return vertexAOD; if(vertexESD->GetNContributors()<=0) { AliDebug(2,"vertexing failed"); delete vertexESD; vertexESD=NULL; return vertexAOD; } delete vertexer; vertexer=NULL; // convert to AliAODVertex Double_t pos[3],cov[6],chi2perNDF; vertexESD->GetXYZ(pos); // position vertexESD->GetCovMatrix(cov); //covariance matrix chi2perNDF = vertexESD->GetChi2toNDF(); delete vertexESD; vertexESD=NULL; vertexAOD = new AliAODVertex(pos,cov,chi2perNDF); return vertexAOD; } //________________________________________________________________________ void AliAnalysisTaskSED0Mass::Terminate(Option_t */*option*/) { // Terminate analysis // if(fDebug > 1) printf("AnalysisTaskSED0Mass: Terminate() \n"); fOutputMass = dynamic_cast (GetOutputData(1)); if (!fOutputMass) { printf("ERROR: fOutputMass not available\n"); return; } if(fFillVarHists){ fDistr = dynamic_cast (GetOutputData(2)); if (!fDistr) { printf("ERROR: fDistr not available\n"); return; } } fNentries = dynamic_cast(GetOutputData(3)); if(!fNentries){ printf("ERROR: fNEntries not available\n"); return; } fCuts = dynamic_cast(GetOutputData(4)); if(!fCuts){ printf("ERROR: fCuts not available\n"); return; } fCounter = dynamic_cast(GetOutputData(5)); if (!fCounter) { printf("ERROR: fCounter not available\n"); return; } Int_t nptbins=fCuts->GetNPtBins(); for(Int_t ipt=0;iptFindObject("hpospair"))->Integral(nptbins+ipt+1,nptbins+ipt+2)*((TH1F*)fOutputMass->FindObject("hnegpair"))->Integral(nptbins+ipt+1,nptbins+ipt+2)); //after cuts if(fLsNormalization>1e-6) { TString massName="histMass_"; massName+=ipt; ((TH1F*)fOutputMass->FindObject(massName))->Scale((1/fLsNormalization)*((TH1F*)fOutputMass->FindObject(massName))->GetEntries()); } fLsNormalization = 2.*TMath::Sqrt(((TH1F*)fOutputMass->FindObject("hpospair"))->Integral(ipt+1,ipt+2)*((TH1F*)fOutputMass->FindObject("hnegpair"))->Integral(ipt+1,ipt+2)); //fLsNormalization = 2.*TMath::Sqrt(fTotPosPairs[4]*fTotNegPairs[4]); if(fLsNormalization>1e-6) { TString nameDistr="hptB_"; nameDistr+=ipt; ((TH1F*)fDistr->FindObject(nameDistr))->Scale((1/fLsNormalization)*((TH1F*)fDistr->FindObject(nameDistr))->GetEntries()); nameDistr="hdcaB_"; nameDistr+=ipt; ((TH1F*)fDistr->FindObject(nameDistr))->Scale((1/fLsNormalization)*((TH1F*)fDistr->FindObject(nameDistr))->GetEntries()); nameDistr="hcosthetastarB_"; nameDistr+=ipt; ((TH1F*)fDistr->FindObject(nameDistr))->Scale((1/fLsNormalization)*((TH1F*)fDistr->FindObject(nameDistr))->GetEntries()); nameDistr="hd0B_"; nameDistr+=ipt; ((TH1F*)fDistr->FindObject(nameDistr))->Scale((1/fLsNormalization)*((TH1F*)fDistr->FindObject(nameDistr))->GetEntries()); nameDistr="hd0d0B_"; nameDistr+=ipt; ((TH1F*)fDistr->FindObject(nameDistr))->Scale((1/fLsNormalization)*((TH1F*)fDistr->FindObject(nameDistr))->GetEntries()); nameDistr="hcosthetapointB_"; nameDistr+=ipt; ((TH1F*)fDistr->FindObject(nameDistr))->Scale((1/fLsNormalization)*((TH1F*)fDistr->FindObject(nameDistr))->GetEntries()); if(fSys==0){ nameDistr="hcosthpointd0d0B_"; nameDistr+=ipt; ((TH2F*)fDistr->FindObject(nameDistr))->Scale((1/fLsNormalization)*((TH2F*)fDistr->FindObject(nameDistr))->GetEntries()); } } } } TString cvname,cstname; if (fArray==0){ cvname="D0invmass"; cstname="cstat0"; } else { cvname="LSinvmass"; cstname="cstat1"; } TCanvas *cMass=new TCanvas(cvname,cvname); cMass->cd(); ((TH1F*)fOutputMass->FindObject("histMass_3"))->Draw(); TCanvas* cStat=new TCanvas(cstname,Form("Stat%s",fArray ? "LS" : "D0")); cStat->cd(); cStat->SetGridy(); fNentries->Draw("htext0"); // TCanvas *ccheck=new TCanvas(Form("cc%d",fArray),Form("cc%d",fArray)); // ccheck->cd(); return; }