/************************************************************************** * 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. * **************************************************************************/ //----------------------------------------------------------------------- // Efficiency between different steps of the procedure. // The ouptut of the task is a AliCFContainer from which the efficiencies // can be calculated //----------------------------------------------------------------------- // Author : Marta Verweij - UU //----------------------------------------------------------------------- #ifndef ALIPWG4HIGHPTSPECTRA_CXX #define ALIPWG4HIGHPTSPECTRA_CXX #include "AliPWG4HighPtSpectra.h" #include "TVector3.h" #include #include "TH1.h" #include "TH2.h" #include "TH3.h" #include "TProfile.h" #include "TList.h" #include "TChain.h" #include "TKey.h" #include "TSystem.h" #include "TFile.h" #include "AliAnalysisManager.h" #include "AliESDInputHandler.h" #include "AliESDtrack.h" #include "AliESDtrackCuts.h" #include "AliExternalTrackParam.h" #include "AliCentrality.h" #include "AliLog.h" #include "AliStack.h" #include "TParticle.h" #include "AliMCEvent.h" #include "AliMCEventHandler.h" #include "AliCFContainer.h" #include "AliGenPythiaEventHeader.h" #include "AliGenHijingEventHeader.h" #include "AliGenCocktailEventHeader.h" //#include "$ALICE_ROOT/PWG4/JetTasks/AliAnalysisHelperJetTasks.h" //#include using namespace std; //required for resolving the 'cout' symbol ClassImp(AliPWG4HighPtSpectra) //__________________________________________________________________________ AliPWG4HighPtSpectra::AliPWG4HighPtSpectra() : AliAnalysisTask("AliPWG4HighPtSpectra", ""), fReadAODData(0), fCFManagerPos(0x0), fCFManagerNeg(0x0), fESD(0x0), fMC(0x0), fStack(0x0), fVtx(0x0), fTriggerMask(AliVEvent::kMB), fIsPbPb(0), fCentClass(10), fTrackType(0), fTrackCuts(0x0), fTrackCutsReject(0x0), fbSelectHIJING(kFALSE), fSigmaConstrainedMax(100.), fAvgTrials(1), fHistList(0), fNEventAll(0), fNEventSel(0), fNEventReject(0), fh1Centrality(0x0), fh1Xsec(0), fh1Trials(0), fh1PtHard(0), fh1PtHardTrials(0), fPtRelUncertainty1PtPrim(0x0), fPtRelUncertainty1PtSec(0x0) { // //Default ctor // } //___________________________________________________________________________ AliPWG4HighPtSpectra::AliPWG4HighPtSpectra(const Char_t* name) : AliAnalysisTask(name,""), fReadAODData(0), fCFManagerPos(0x0), fCFManagerNeg(0x0), fESD(0x0), fMC(0x0), fStack(0x0), fVtx(0x0), fTriggerMask(AliVEvent::kMB), fIsPbPb(0), fCentClass(10), fTrackType(0), fTrackCuts(0x0), fTrackCutsReject(0x0), fbSelectHIJING(kFALSE), fSigmaConstrainedMax(100.), fAvgTrials(1), fHistList(0), fNEventAll(0), fNEventSel(0), fNEventReject(0), fh1Centrality(0x0), fh1Xsec(0), fh1Trials(0), fh1PtHard(0), fh1PtHardTrials(0), fPtRelUncertainty1PtPrim(0x0), fPtRelUncertainty1PtSec(0x0) { // // Constructor. Initialization of Inputs and Outputs // AliDebug(2,Form("AliPWG4HighPtSpectra Calling Constructor")); // Input slot #0 works with a TChain ESD DefineInput(0, TChain::Class()); // Output slot #0 writes into a TList DefineOutput(0,TList::Class()); // Output slot #1, #2 writes into a AliCFContainer DefineOutput(1,AliCFContainer::Class()); DefineOutput(2,AliCFContainer::Class()); // Output slot #3 writes into a AliESDtrackCuts DefineOutput(3, AliESDtrackCuts::Class()); DefineOutput(4, AliESDtrackCuts::Class()); } //________________________________________________________________________ void AliPWG4HighPtSpectra::LocalInit() { // // Only called once at beginning // PostData(3,fTrackCuts); } //________________________________________________________________________ void AliPWG4HighPtSpectra::ConnectInputData(Option_t *) { // Connect ESD here // Called once AliDebug(2,Form(">> AliPWG4HighPtSpectra::ConnectInputData \n")); TTree* tree = dynamic_cast (GetInputData(0)); if (!tree) { AliDebug(2,Form( "ERROR: Could not read chain from input slot 0 \n")); return; } AliESDInputHandler *esdH = dynamic_cast (AliAnalysisManager::GetAnalysisManager()->GetInputEventHandler()); if (!esdH) { AliDebug(2,Form("ERROR: Could not get ESDInputHandler")); return; } else fESD = esdH->GetEvent(); AliMCEventHandler *eventHandler = dynamic_cast (AliAnalysisManager::GetAnalysisManager()->GetMCtruthEventHandler()); if (!eventHandler) { AliDebug(2,Form( "ERROR: Could not retrieve MC event handler \n")); } else fMC = eventHandler->MCEvent(); } //________________________________________________________________________ Bool_t AliPWG4HighPtSpectra::SelectEvent() { // // Decide if event should be selected for analysis // // Checks following requirements: // - fESD available // - trigger info from AliPhysicsSelection // - number of reconstructed tracks > 1 // - primary vertex reconstructed // - z-vertex < 10 cm Bool_t selectEvent = kTRUE; //fESD object available? if (!fESD) { AliDebug(2,Form("ERROR: fInputEvent not available\n")); fNEventReject->Fill("noESD",1); selectEvent = kFALSE; return selectEvent; } //Trigger UInt_t isSelected = ((AliInputEventHandler*)(AliAnalysisManager::GetAnalysisManager()->GetInputEventHandler()))->IsEventSelected(); if(fTriggerMask != AliVEvent::kAny && !(isSelected&fTriggerMask)) { //Select collison candidates AliDebug(2,Form(" Trigger Selection: event REJECTED ... ")); fNEventReject->Fill("Trigger",1); selectEvent = kFALSE; return selectEvent; } //Check if number of reconstructed tracks is larger than 1 if(!fESD->GetNumberOfTracks() || fESD->GetNumberOfTracks()<2) { fNEventReject->Fill("NTracks<2",1); selectEvent = kFALSE; return selectEvent; } //Check if vertex is reconstructed fVtx = fESD->GetPrimaryVertexSPD(); if(!fVtx) { fNEventReject->Fill("noVTX",1); selectEvent = kFALSE; return selectEvent; } if(!fVtx->GetStatus()) { fNEventReject->Fill("VtxStatus",1); selectEvent = kFALSE; return selectEvent; } // Need vertex cut // TString vtxName(fVtx->GetName()); if(fVtx->GetNContributors()<2) { fNEventReject->Fill("NCont<2",1); selectEvent = kFALSE; return selectEvent; } //Check if z-vertex < 10 cm double primVtx[3]; fVtx->GetXYZ(primVtx); if(TMath::Sqrt(primVtx[0]*primVtx[0] + primVtx[1]*primVtx[1])>1. || TMath::Abs(primVtx[2]>10.)){ fNEventReject->Fill("ZVTX>10",1); selectEvent = kFALSE; return selectEvent; } //Centrality selection should only be done in case of PbPb if(IsPbPb()) { Float_t cent = 0.; if(fCentClass!=CalculateCentrality(fESD) && fCentClass!=10) { fNEventReject->Fill("cent",1); selectEvent = kFALSE; return selectEvent; } else { if(dynamic_cast(fESD)->GetCentrality()) { cent = dynamic_cast(fESD)->GetCentrality()->GetCentralityPercentile("V0M"); } if(cent>90.) { fNEventReject->Fill("cent>90",1); selectEvent = kFALSE; return selectEvent; } fh1Centrality->Fill(cent); } } return selectEvent; } //________________________________________________________________________ Int_t AliPWG4HighPtSpectra::CalculateCentrality(AliESDEvent *esd){ Float_t cent = 999; if(esd){ if(esd->GetCentrality()){ cent = esd->GetCentrality()->GetCentralityPercentile("V0M"); } } if(cent<0) return 5; if(cent>80)return 4; if(cent>50)return 3; if(cent>30)return 2; if(cent>10)return 1; return 0; } //_________________________________________________ void AliPWG4HighPtSpectra::Exec(Option_t *) { // // Main loop function // AliDebug(2,Form(">> AliPWG4HighPtSpectra::Exec \n")); // All events without selection fNEventAll->Fill(0.); if(!SelectEvent()) { // Post output data PostData(0,fHistList); PostData(1,fCFManagerPos->GetParticleContainer()); PostData(2,fCFManagerNeg->GetParticleContainer()); return; } //MCEvent available? //if yes: get stack if(fMC) { AliDebug(2,Form("MC particles: %d", fMC->GetNumberOfTracks())); fStack = fMC->Stack(); //Particles Stack AliDebug(2,Form("MC particles stack: %d", fStack->GetNtrack())); } Int_t nTracks = fESD->GetNumberOfTracks(); AliDebug(2,Form("nTracks %d", nTracks)); if(!fTrackCuts) { fNEventReject->Fill("noTrackCuts",1); // Post output data PostData(0,fHistList); PostData(1,fCFManagerPos->GetParticleContainer()); PostData(2,fCFManagerNeg->GetParticleContainer()); return; } // Selected events for analysis fNEventSel->Fill(0.); const Int_t nvar = 4; Double_t containerInputRec[nvar] = {0.,0.,0.,0.}; Double_t containerInputMC[nvar] = {0.,0.,0.,0.}; Double_t containerInputRecMC[nvar] = {0.,0.,0.,0.}; //reconstructed yield as function of MC variable //Now go to rec level for (Int_t iTrack = 0; iTrackGetTrack(iTrack); if(!esdtrack) continue; if(fTrackType==4) { if (!(fTrackCuts->AcceptTrack(esdtrack))) continue; } if(fTrackType==1) track = AliESDtrackCuts::GetTPCOnlyTrack(fESD,esdtrack->GetID()); else if(fTrackType==2 || fTrackType==4) { track = AliESDtrackCuts::GetTPCOnlyTrack(const_cast(fESD),esdtrack->GetID()); if(!track) continue; AliExternalTrackParam exParam; Bool_t relate = track->RelateToVertexTPC(fVtx,fESD->GetMagneticField(),kVeryBig,&exParam); if( !relate ) { if(track) delete track; continue; } track->Set(exParam.GetX(),exParam.GetAlpha(),exParam.GetParameter(),exParam.GetCovariance()); } else if(fTrackType==5 || fTrackType==6) { if(fTrackCuts->AcceptTrack(esdtrack)) { continue; } else { if( !(fTrackCutsReject->AcceptTrack(esdtrack)) && fTrackCuts->AcceptTrack(esdtrack) ) { if(fTrackType==5) { //use TPConly constrained track track = AliESDtrackCuts::GetTPCOnlyTrack(fESD,esdtrack->GetID()); if(!track) continue; AliExternalTrackParam exParam; Bool_t relate = track->RelateToVertexTPC(fVtx,fESD->GetMagneticField(),kVeryBig,&exParam); if( !relate ) { if(track) delete track; continue; } track->Set(exParam.GetX(),exParam.GetAlpha(),exParam.GetParameter(),exParam.GetCovariance()); } else if(fTrackType==6) { //use global constrained track track = new AliESDtrack(*esdtrack); track->Set(esdtrack->GetConstrainedParam()->GetX(),esdtrack->GetConstrainedParam()->GetAlpha(),esdtrack->GetConstrainedParam()->GetParameter(),esdtrack->GetConstrainedParam()->GetCovariance()); } } } } else if(fTrackType==7) { //use global constrained track track = new AliESDtrack(*esdtrack); } else track = esdtrack; if(!track) continue; if(fTrackType==2 || fTrackType==4 || fTrackType==5) { //Cut on chi2 of constrained fit if(track->GetConstrainedChi2TPC() > fSigmaConstrainedMax*fSigmaConstrainedMax && fSigmaConstrainedMax>0.) { if(track) delete track; continue; } } if (!(fTrackCuts->AcceptTrack(track)) && fTrackType!=4 && fTrackType!=5 && fTrackType!=6) { if(fTrackType==1 || fTrackType==2 || fTrackType==7) { if(track) delete track; } continue; } if(fTrackType==7) { if(fTrackCutsReject ) { if(fTrackCutsReject->AcceptTrack(track) ) { if(track) delete track; continue; } } if(esdtrack->GetConstrainedParam()) track->Set(esdtrack->GetConstrainedParam()->GetX(),esdtrack->GetConstrainedParam()->GetAlpha(),esdtrack->GetConstrainedParam()->GetParameter(),esdtrack->GetConstrainedParam()->GetCovariance()); } if(!track) { if(fTrackType==1 || fTrackType==2 || fTrackType==4 || fTrackType==5 || fTrackType==6 || fTrackType==7) { if(track) delete track; } continue; } //fill the container containerInputRec[0] = track->Pt(); containerInputRec[1] = track->Phi(); containerInputRec[2] = track->Eta(); containerInputRec[3] = track->GetTPCNclsIter1(); if(track->GetSign()>0.) fCFManagerPos->GetParticleContainer()->Fill(containerInputRec,kStepReconstructed); if(track->GetSign()<0.) fCFManagerNeg->GetParticleContainer()->Fill(containerInputRec,kStepReconstructed); //Only fill the MC containers if MC information is available if(fMC) { Int_t label = TMath::Abs(track->GetLabel()); if(label>fStack->GetNtrack()) { if(fTrackType==1 || fTrackType==2 || fTrackType==7) delete track; continue; } //Only select particles generated by HIJING if requested if(fbSelectHIJING) { if(!IsHIJINGParticle(label)) { if(fTrackType==1 || fTrackType==2 || fTrackType==7) delete track; continue; } } TParticle *particle = fStack->Particle(label) ; if(!particle) { if(fTrackType==1 || fTrackType==2 || fTrackType==7) delete track; continue; } containerInputRecMC[0] = particle->Pt(); containerInputRecMC[1] = particle->Phi(); containerInputRecMC[2] = particle->Eta(); containerInputRecMC[3] = track->GetTPCNclsIter1(); //Container with primaries if(fStack->IsPhysicalPrimary(label)) { if(particle->GetPDG()->Charge()>0.) { fCFManagerPos->GetParticleContainer()->Fill(containerInputRecMC,kStepReconstructedMC); } if(particle->GetPDG()->Charge()<0.) { fCFManagerNeg->GetParticleContainer()->Fill(containerInputRecMC,kStepReconstructedMC); } //Fill pT resolution plots for primaries fPtRelUncertainty1PtPrim->Fill(containerInputRec[0],containerInputRec[0]*TMath::Sqrt(track->GetSigma1Pt2())); } //Container with secondaries if (!fStack->IsPhysicalPrimary(label) ) { if(particle->GetPDG()->Charge()>0.) { fCFManagerPos->GetParticleContainer()->Fill(containerInputMC,kStepSecondaries); } if(particle->GetPDG()->Charge()<0.) { fCFManagerNeg->GetParticleContainer()->Fill(containerInputMC,kStepSecondaries); } //Fill pT resolution plots for primaries fPtRelUncertainty1PtSec->Fill(containerInputRec[0],containerInputRec[0]*TMath::Sqrt(track->GetSigma1Pt2())); } } if(fTrackType==1 || fTrackType==2 || fTrackType==4 || fTrackType==5 || fTrackType==6 || fTrackType==7) { if(track) delete track; } }//track loop //Fill MC containers if particles are findable if(fMC) { for(int iPart = 1; iPart<(fMC->GetNumberOfPrimaries()); iPart++) { AliMCParticle *mcPart = (AliMCParticle*)fMC->GetTrack(iPart); if(!mcPart) continue; //Only select particles generated by HIJING if requested if(fbSelectHIJING) { if(!IsHIJINGParticle(iPart)) continue; } Int_t pdg = mcPart->PdgCode(); // select charged pions, protons, kaons , electrons, muons if(TMath::Abs(pdg) == 211 || TMath::Abs(pdg) == 2212 || TMath::Abs(pdg) == 321 || TMath::Abs(pdg) == 11 || TMath::Abs(pdg) == 13){ //fill the container containerInputMC[0] = mcPart->Pt(); containerInputMC[1] = mcPart->Phi(); containerInputMC[2] = mcPart->Eta(); // AliESDtrack *esdtrack = fESD->GetTrack(mcPart->GetLabel()); containerInputMC[3] = 159.; if(fStack->IsPhysicalPrimary(iPart)) { if(mcPart->Charge()>0. && fCFManagerPos->CheckParticleCuts(kStepMCAcceptance,mcPart)) fCFManagerPos->GetParticleContainer()->Fill(containerInputMC,kStepMCAcceptance); if(mcPart->Charge()<0. && fCFManagerNeg->CheckParticleCuts(kStepMCAcceptance,mcPart)) fCFManagerNeg->GetParticleContainer()->Fill(containerInputMC,kStepMCAcceptance); } } } } PostData(0,fHistList); PostData(1,fCFManagerPos->GetParticleContainer()); PostData(2,fCFManagerNeg->GetParticleContainer()); } //________________________________________________________________________ Bool_t AliPWG4HighPtSpectra::PythiaInfoFromFile(const char* currFile,Float_t &fXsec,Float_t &fTrials){ // // get the cross section and the trails either from pyxsec.root or from pysec_hists.root // This is to called in Notify and should provide the path to the AOD/ESD file // Copied from AliAnalysisTaskJetSpectrum2 // TString file(currFile); fXsec = 0; fTrials = 1; if(file.Contains("root_archive.zip#")){ Ssiz_t pos1 = file.Index("root_archive",12,TString::kExact); Ssiz_t pos = file.Index("#",1,pos1,TString::kExact); file.Replace(pos+1,20,""); } else { // not an archive take the basename.... file.ReplaceAll(gSystem->BaseName(file.Data()),""); } // Printf("%s",file.Data()); TFile *fxsec = TFile::Open(Form("%s%s",file.Data(),"pyxsec.root")); // problem that we cannot really test the existance of a file in a archive so we have to lvie with open error message from root if(!fxsec){ // next trial fetch the histgram file fxsec = TFile::Open(Form("%s%s",file.Data(),"pyxsec_hists.root")); if(!fxsec){ // not a severe condition but indicates that we have no information return kFALSE; } else{ // find the tlist we want to be independtent of the name so use the Tkey TKey* key = (TKey*)fxsec->GetListOfKeys()->At(0); if(!key){ fxsec->Close(); return kFALSE; } TList *list = dynamic_cast(key->ReadObj()); if(!list){ fxsec->Close(); return kFALSE; } fXsec = ((TProfile*)list->FindObject("h1Xsec"))->GetBinContent(1); fTrials = ((TH1F*)list->FindObject("h1Trials"))->GetBinContent(1); fxsec->Close(); } } // no tree pyxsec.root else { TTree *xtree = (TTree*)fxsec->Get("Xsection"); if(!xtree){ fxsec->Close(); return kFALSE; } UInt_t ntrials = 0; Double_t xsection = 0; xtree->SetBranchAddress("xsection",&xsection); xtree->SetBranchAddress("ntrials",&ntrials); xtree->GetEntry(0); fTrials = ntrials; fXsec = xsection; fxsec->Close(); } return kTRUE; } //________________________________________________________________________ Bool_t AliPWG4HighPtSpectra::Notify() { // // Implemented Notify() to read the cross sections // and number of trials from pyxsec.root // Copied from AliAnalysisTaskJetSpectrum2 // TTree *tree = AliAnalysisManager::GetAnalysisManager()->GetTree(); Float_t xsection = 0; Float_t ftrials = 1; if(tree){ TFile *curfile = tree->GetCurrentFile(); if (!curfile) { Error("Notify","No current file"); return kFALSE; } if(!fh1Xsec||!fh1Trials){ // Printf("%s%d No Histogram fh1Xsec",(char*)__FILE__,__LINE__); return kFALSE; } PythiaInfoFromFile(curfile->GetName(),xsection,ftrials); fh1Xsec->Fill("<#sigma>",xsection); fh1Trials->Fill("#sum{ntrials}",ftrials); } return kTRUE; } //________________________________________________________________________ AliGenPythiaEventHeader* AliPWG4HighPtSpectra::GetPythiaEventHeader(AliMCEvent *mcEvent){ if(!mcEvent)return 0; AliGenEventHeader* genHeader = mcEvent->GenEventHeader(); AliGenPythiaEventHeader* pythiaGenHeader = dynamic_cast(genHeader); if(!pythiaGenHeader){ // cocktail ?? AliGenCocktailEventHeader* genCocktailHeader = dynamic_cast(genHeader); if (!genCocktailHeader) { // AliWarningGeneral(Form(" %s:%d",(char*)__FILE__,__LINE__),"Unknown header type (not Pythia or Cocktail)"); // AliWarning(Form("%s %d: Unknown header type (not Pythia or Cocktail)",(char*)__FILE__,__LINE__)); return 0; } TList* headerList = genCocktailHeader->GetHeaders(); for (Int_t i=0; iGetEntries(); i++) { pythiaGenHeader = dynamic_cast(headerList->At(i)); if (pythiaGenHeader) break; } if(!pythiaGenHeader){ AliWarningGeneral(Form(" %s:%d",(char*)__FILE__,__LINE__),"Pythia event header not found"); return 0; } } return pythiaGenHeader; } //________________________________________________________________________ AliGenHijingEventHeader* AliPWG4HighPtSpectra::GetHijingEventHeader(AliMCEvent *mcEvent){ if(!mcEvent)return 0; AliGenEventHeader* genHeader = mcEvent->GenEventHeader(); AliGenHijingEventHeader* hijingGenHeader = dynamic_cast(genHeader); if(!hijingGenHeader){ // cocktail ?? AliGenCocktailEventHeader* genCocktailHeader = dynamic_cast(genHeader); if (!genCocktailHeader) { // AliWarningGeneral(Form(" %s:%d",(char*)__FILE__,__LINE__),"Unknown header type (not Pythia or Cocktail)"); // AliWarning(Form("%s %d: Unknown header type (not Pythia or Cocktail)",(char*)__FILE__,__LINE__)); return 0; } TList* headerList = genCocktailHeader->GetHeaders(); for (Int_t i=0; iGetEntries(); i++) { hijingGenHeader = dynamic_cast(headerList->At(i)); if (hijingGenHeader) break; } if(!hijingGenHeader){ AliWarningGeneral(Form(" %s:%d",(char*)__FILE__,__LINE__),"Hijing event header not found"); return 0; } } return hijingGenHeader; } //___________________________________________________________________________ void AliPWG4HighPtSpectra::Terminate(Option_t*) { // The Terminate() function is the last function to be called during // a query. It always runs on the client, it can be used to present // the results graphically or save the results to file. } //___________________________________________________________________________ void AliPWG4HighPtSpectra::CreateOutputObjects() { //HERE ONE CAN CREATE OUTPUT OBJECTS, IN PARTICULAR IF THE OBJECT PARAMETERS DON'T NEED //TO BE SET BEFORE THE EXECUTION OF THE TASK // AliDebug(2,Form("CreateOutputObjects CreateOutputObjects of task %s", GetName())); Bool_t oldStatus = TH1::AddDirectoryStatus(); TH1::AddDirectory(kFALSE); //slot #1 OpenFile(0); fHistList = new TList(); fHistList->SetOwner(kTRUE); fNEventAll = new TH1F("fNEventAll","NEventAll",1,-0.5,0.5); fHistList->Add(fNEventAll); fNEventSel = new TH1F("fNEventSel","NEvent Selected for analysis",1,-0.5,0.5); fHistList->Add(fNEventSel); fNEventReject = new TH1F("fNEventReject","Reason events are rejectected for analysis",20,0,20); //Set labels fNEventReject->Fill("noESD",0); fNEventReject->Fill("Trigger",0); fNEventReject->Fill("NTracks<2",0); fNEventReject->Fill("noVTX",0); fNEventReject->Fill("VtxStatus",0); fNEventReject->Fill("NCont<2",0); fNEventReject->Fill("ZVTX>10",0); fNEventReject->Fill("cent",0); fNEventReject->Fill("cent>90",0); fHistList->Add(fNEventReject); fh1Centrality = new TH1F("fh1Centrality","fh1Centrality; Centrality %",100,0,100); fHistList->Add(fh1Centrality); fh1Xsec = new TProfile("fh1Xsec","xsec from pyxsec.root",1,0,1); fh1Xsec->GetXaxis()->SetBinLabel(1,"<#sigma>"); fHistList->Add(fh1Xsec); fh1Trials = new TH1F("fh1Trials","trials root file",1,0,1); fh1Trials->GetXaxis()->SetBinLabel(1,"#sum{ntrials}"); fHistList->Add(fh1Trials); fh1PtHard = new TH1F("fh1PtHard","PYTHIA Pt hard;p_{T,hard}",350,-.5,349.5); fHistList->Add(fh1PtHard); fh1PtHardTrials = new TH1F("fh1PtHardTrials","PYTHIA Pt hard weight with trials;p_{T,hard}",350,-.5,349.5); fHistList->Add(fh1PtHardTrials); Int_t fgkNPtBins = 100; Float_t kMinPt = 0.; Float_t kMaxPt = 100.; Double_t *binsPt = new Double_t[fgkNPtBins+1]; for(Int_t i=0; i<=fgkNPtBins; i++) binsPt[i]=(Double_t)kMinPt + (kMaxPt-kMinPt)/fgkNPtBins*(Double_t)i ; Int_t fgkNRel1PtUncertaintyBins=50; Float_t fgkRel1PtUncertaintyMin = 0.; Float_t fgkRel1PtUncertaintyMax = 1.; Double_t *binsRel1PtUncertainty=new Double_t[fgkNRel1PtUncertaintyBins+1]; for(Int_t i=0; i<=fgkNRel1PtUncertaintyBins; i++) binsRel1PtUncertainty[i]=(Double_t)fgkRel1PtUncertaintyMin + (fgkRel1PtUncertaintyMax-fgkRel1PtUncertaintyMin)/fgkNRel1PtUncertaintyBins*(Double_t)i ; fPtRelUncertainty1PtPrim = new TH2F("fPtRelUncertainty1PtPrim","fPtRelUncertainty1PtPrim",fgkNPtBins,binsPt,fgkNRel1PtUncertaintyBins,binsRel1PtUncertainty); fHistList->Add(fPtRelUncertainty1PtPrim); fPtRelUncertainty1PtSec = new TH2F("fPtRelUncertainty1PtSec","fPtRelUncertainty1PtSec",fgkNPtBins,binsPt,fgkNRel1PtUncertaintyBins,binsRel1PtUncertainty); fHistList->Add(fPtRelUncertainty1PtSec); TH1::AddDirectory(oldStatus); PostData(0,fHistList); PostData(1,fCFManagerPos->GetParticleContainer()); PostData(2,fCFManagerNeg->GetParticleContainer()); if(binsPt) delete [] binsPt; if(binsRel1PtUncertainty) delete [] binsRel1PtUncertainty; } //________________________________________________________________________ Bool_t AliPWG4HighPtSpectra::IsHIJINGParticle(Int_t label) { // // Return kTRUE in case particle is from HIJING event // AliGenHijingEventHeader* hijingHeader = GetHijingEventHeader(fMC); Int_t nproduced = hijingHeader->NProduced(); TParticle * mom = fStack->Particle(label); Int_t iMom = label; Int_t iParent = mom->GetFirstMother(); while(iParent!=-1){ iMom = iParent; mom = fStack->Particle(iMom); iParent = mom->GetFirstMother(); } if(iMom