#include <TROOT.h>
-#include <TRandom.h>
+#include <TRandom3.h>
#include <TSystem.h>
#include <TInterpreter.h>
#include <TChain.h>
#include <TH2F.h>
#include <TH3F.h>
#include <TProfile.h>
+#include <TF1.h>
#include <TList.h>
#include <TLorentzVector.h>
#include <TClonesArray.h>
#include "TDatabasePDG.h"
+#include <TGrid.h>
#include "AliAnalysisTaskJetCluster.h"
#include "AliAnalysisManager.h"
#include "AliESDEvent.h"
#include "AliAODEvent.h"
#include "AliAODHandler.h"
+#include "AliAODExtension.h"
#include "AliAODTrack.h"
#include "AliAODJet.h"
#include "AliAODMCParticle.h"
#include "AliJetKineReaderHeader.h"
#include "AliGenCocktailEventHeader.h"
#include "AliInputEventHandler.h"
-
+#include "AliAODJetEventBackground.h"
#include "fastjet/PseudoJet.hh"
#include "fastjet/ClusterSequenceArea.hh"
// get info on how fastjet was configured
#include "fastjet/config.h"
+using std::vector;
ClassImp(AliAnalysisTaskJetCluster)
AliAnalysisTaskJetCluster::~AliAnalysisTaskJetCluster(){
+ //
+ // Destructor
+ //
+
delete fRef;
+ delete fRandom;
+
+ if(fTCAJetsOut)fTCAJetsOut->Delete();
+ delete fTCAJetsOut;
+
+ if(fTCAJetsOutRan)fTCAJetsOutRan->Delete();
+ delete fTCAJetsOutRan;
+
+ if(fTCARandomConesOut)fTCARandomConesOut->Delete();
+ delete fTCARandomConesOut;
+
+ if(fTCARandomConesOutRan)fTCARandomConesOutRan->Delete();
+ delete fTCARandomConesOutRan;
+
+ if(fAODJetBackgroundOut)fAODJetBackgroundOut->Reset();
+ delete fAODJetBackgroundOut;
}
-AliAnalysisTaskJetCluster::AliAnalysisTaskJetCluster(): AliAnalysisTaskSE(),
+AliAnalysisTaskJetCluster::AliAnalysisTaskJetCluster():
+ AliAnalysisTaskSE(),
fAOD(0x0),
fAODExtension(0x0),
fRef(new TRefArray),
fUseAODTrackInput(kFALSE),
fUseAODMCInput(kFALSE),
- fUseGlobalSelection(kFALSE),
+ fUseBackgroundCalc(kFALSE),
+ fEventSelection(kFALSE),
+ fRequireVZEROAC(kFALSE),
+ fRequireTZEROvtx(kFALSE),
+ fUseHFcuts(kFALSE),
fFilterMask(0),
+ fFilterMaskBestPt(0),
+ fFilterType(0),
+ fJetTypes(kJet),
fTrackTypeRec(kTrackUndef),
fTrackTypeGen(kTrackUndef),
fNSkipLeadingRan(0),
+ fNSkipLeadingCone(0),
+ fNRandomCones(0),
fAvgTrials(1),
- fExternalWeight(1),
+ fExternalWeight(1),
+ fTrackEtaWindow(0.9),
+ fRequireITSRefit(0),
+ fApplySharedClusterCut(0),
fRecEtaWindow(0.5),
fTrackPtCut(0.),
- fJetOutputMinPt(1),
+ fJetOutputMinPt(0.150),
+ fMaxTrackPtInJet(100.),
+ fJetTriggerPtCut(0),
+ fVtxZCut(8),
+ fVtxR2Cut(1),
+ fCentCutUp(0),
+ fCentCutLo(0),
+ fStoreRhoLeadingTrackCorr(kFALSE),
fNonStdBranch(""),
+ fBackgroundBranch(""),
fNonStdFile(""),
+ fMomResH1(0x0),
+ fMomResH2(0x0),
+ fMomResH3(0x0),
+ fMomResH1Fit(0x0),
+ fMomResH2Fit(0x0),
+ fMomResH3Fit(0x0),
+ fhEffH1(0x0),
+ fhEffH2(0x0),
+ fhEffH3(0x0),
+ fUseTrPtResolutionSmearing(kFALSE),
+ fUseDiceEfficiency(kFALSE),
+ fDiceEfficiencyMinPt(-1.),
+ fUseTrPtResolutionFromOADB(kFALSE),
+ fUseTrEfficiencyFromOADB(kFALSE),
+ fPathTrPtResolution(""),
+ fPathTrEfficiency(""),
+ fChangeEfficiencyFraction(0.),
+ fEfficiencyFixed(1.),
fRparam(1.0),
fAlgorithm(fastjet::kt_algorithm),
fStrategy(fastjet::Best),
fRecombScheme(fastjet::BIpt_scheme),
fAreaType(fastjet::active_area),
+ fGhostArea(0.01),
+ fActiveAreaRepeats(1),
+ fGhostEtamax(1.5),
+ fTCAJetsOut(0x0),
+ fTCAJetsOutRan(0x0),
+ fTCARandomConesOut(0x0),
+ fTCARandomConesOutRan(0x0),
+ fAODJetBackgroundOut(0x0),
+ fRandom(0),
fh1Xsec(0x0),
fh1Trials(0x0),
fh1PtHard(0x0),
fh1PtJetsRecInRan(0x0),
fh1PtTracksGenIn(0x0),
fh1Nch(0x0),
+ fh1CentralityPhySel(0x0),
+ fh1Centrality(0x0),
+ fh1CentralitySelect(0x0),
+ fh1ZPhySel(0x0),
+ fh1Z(0x0),
+ fh1ZSelect(0x0),
fh2NRecJetsPt(0x0),
fh2NRecTracksPt(0x0),
fh2NConstPt(0x0),
fh2PtNchNRan(0x0),
fh2TracksLeadingJetPhiPtRan(0x0),
fh2TracksLeadingJetPhiPtWRan(0x0),
+ fh3CentvsRhoLeadingTrackPt(0x0),
+ fh3CentvsSigmaLeadingTrackPt(0x0),
+ fh3MultvsRhoLeadingTrackPt(0x0),
+ fh3MultvsSigmaLeadingTrackPt(0x0),
+ fh3CentvsRhoLeadingTrackPtQ1(0x0),
+ fh3CentvsRhoLeadingTrackPtQ2(0x0),
+ fh3CentvsRhoLeadingTrackPtQ3(0x0),
+ fh3CentvsRhoLeadingTrackPtQ4(0x0),
+ fh3CentvsSigmaLeadingTrackPtQ1(0x0),
+ fh3CentvsSigmaLeadingTrackPtQ2(0x0),
+ fh3CentvsSigmaLeadingTrackPtQ3(0x0),
+ fh3CentvsSigmaLeadingTrackPtQ4(0x0),
+ fh3MultvsRhoLeadingTrackPtQ1(0x0),
+ fh3MultvsRhoLeadingTrackPtQ2(0x0),
+ fh3MultvsRhoLeadingTrackPtQ3(0x0),
+ fh3MultvsRhoLeadingTrackPtQ4(0x0),
+ fh3MultvsSigmaLeadingTrackPtQ1(0x0),
+ fh3MultvsSigmaLeadingTrackPtQ2(0x0),
+ fh3MultvsSigmaLeadingTrackPtQ3(0x0),
+ fh3MultvsSigmaLeadingTrackPtQ4(0x0),
+ fh3CentvsDeltaRhoLeadingTrackPtQ1(0x0),
+ fh3CentvsDeltaRhoLeadingTrackPtQ2(0x0),
+ fh3CentvsDeltaRhoLeadingTrackPtQ3(0x0),
+ fh3CentvsDeltaRhoLeadingTrackPtQ4(0x0),
+ fh2PtGenPtSmeared(0x0),
+ fp1Efficiency(0x0),
+ fp1PtResolution(0x0),
fHistList(0x0)
{
+ //
+ // Constructor
+ //
+ for(int i = 0;i<3;i++){
+ fh1BiARandomCones[i] = 0;
+ fh1BiARandomConesRan[i] = 0;
+ }
+ for(int i = 0;i<kMaxCent;i++){
+ fh2JetsLeadingPhiPtC[i] = 0;
+ fh2JetsLeadingPhiPtWC[i] = 0; //! jet correlation with leading jet
+ fh2TracksLeadingJetPhiPtC[i] = 0;
+ fh2TracksLeadingJetPhiPtWC[i] = 0;
+ }
}
AliAnalysisTaskJetCluster::AliAnalysisTaskJetCluster(const char* name):
fRef(new TRefArray),
fUseAODTrackInput(kFALSE),
fUseAODMCInput(kFALSE),
- fUseGlobalSelection(kFALSE),
+ fUseBackgroundCalc(kFALSE),
+ fEventSelection(kFALSE),
+ fRequireVZEROAC(kFALSE),
+ fRequireTZEROvtx(kFALSE),
+ fUseHFcuts(kFALSE),
fFilterMask(0),
+ fFilterMaskBestPt(0),
+ fFilterType(0),
+ fJetTypes(kJet),
fTrackTypeRec(kTrackUndef),
fTrackTypeGen(kTrackUndef),
fNSkipLeadingRan(0),
+ fNSkipLeadingCone(0),
+ fNRandomCones(0),
fAvgTrials(1),
fExternalWeight(1),
+ fTrackEtaWindow(0.9),
+ fRequireITSRefit(0),
+ fApplySharedClusterCut(0),
fRecEtaWindow(0.5),
fTrackPtCut(0.),
- fJetOutputMinPt(1),
+ fJetOutputMinPt(0.150),
+ fMaxTrackPtInJet(100.),
+ fJetTriggerPtCut(0),
+ fVtxZCut(8),
+ fVtxR2Cut(1),
+ fCentCutUp(0),
+ fCentCutLo(0),
+ fStoreRhoLeadingTrackCorr(kFALSE),
fNonStdBranch(""),
+ fBackgroundBranch(""),
fNonStdFile(""),
+ fMomResH1(0x0),
+ fMomResH2(0x0),
+ fMomResH3(0x0),
+ fMomResH1Fit(0x0),
+ fMomResH2Fit(0x0),
+ fMomResH3Fit(0x0),
+ fhEffH1(0x0),
+ fhEffH2(0x0),
+ fhEffH3(0x0),
+ fUseTrPtResolutionSmearing(kFALSE),
+ fUseDiceEfficiency(kFALSE),
+ fDiceEfficiencyMinPt(-1.),
+ fUseTrPtResolutionFromOADB(kFALSE),
+ fUseTrEfficiencyFromOADB(kFALSE),
+ fPathTrPtResolution(""),
+ fPathTrEfficiency(""),
+ fChangeEfficiencyFraction(0.),
+ fEfficiencyFixed(1.),
fRparam(1.0),
fAlgorithm(fastjet::kt_algorithm),
fStrategy(fastjet::Best),
fRecombScheme(fastjet::BIpt_scheme),
fAreaType(fastjet::active_area),
+ fGhostArea(0.01),
+ fActiveAreaRepeats(1),
+ fGhostEtamax(1.5),
+ fTCAJetsOut(0x0),
+ fTCAJetsOutRan(0x0),
+ fTCARandomConesOut(0x0),
+ fTCARandomConesOutRan(0x0),
+ fAODJetBackgroundOut(0x0),
+ fRandom(0),
fh1Xsec(0x0),
fh1Trials(0x0),
fh1PtHard(0x0),
fh1PtJetsRecInRan(0x0),
fh1PtTracksGenIn(0x0),
fh1Nch(0x0),
+ fh1CentralityPhySel(0x0),
+ fh1Centrality(0x0),
+ fh1CentralitySelect(0x0),
+ fh1ZPhySel(0x0),
+ fh1Z(0x0),
+ fh1ZSelect(0x0),
fh2NRecJetsPt(0x0),
fh2NRecTracksPt(0x0),
fh2NConstPt(0x0),
fh2PtNchNRan(0x0),
fh2TracksLeadingJetPhiPtRan(0x0),
fh2TracksLeadingJetPhiPtWRan(0x0),
+ fh3CentvsRhoLeadingTrackPt(0x0),
+ fh3CentvsSigmaLeadingTrackPt(0x0),
+ fh3MultvsRhoLeadingTrackPt(0x0),
+ fh3MultvsSigmaLeadingTrackPt(0x0),
+ fh3CentvsRhoLeadingTrackPtQ1(0x0),
+ fh3CentvsRhoLeadingTrackPtQ2(0x0),
+ fh3CentvsRhoLeadingTrackPtQ3(0x0),
+ fh3CentvsRhoLeadingTrackPtQ4(0x0),
+ fh3CentvsSigmaLeadingTrackPtQ1(0x0),
+ fh3CentvsSigmaLeadingTrackPtQ2(0x0),
+ fh3CentvsSigmaLeadingTrackPtQ3(0x0),
+ fh3CentvsSigmaLeadingTrackPtQ4(0x0),
+ fh3MultvsRhoLeadingTrackPtQ1(0x0),
+ fh3MultvsRhoLeadingTrackPtQ2(0x0),
+ fh3MultvsRhoLeadingTrackPtQ3(0x0),
+ fh3MultvsRhoLeadingTrackPtQ4(0x0),
+ fh3MultvsSigmaLeadingTrackPtQ1(0x0),
+ fh3MultvsSigmaLeadingTrackPtQ2(0x0),
+ fh3MultvsSigmaLeadingTrackPtQ3(0x0),
+ fh3MultvsSigmaLeadingTrackPtQ4(0x0),
+ fh3CentvsDeltaRhoLeadingTrackPtQ1(0x0),
+ fh3CentvsDeltaRhoLeadingTrackPtQ2(0x0),
+ fh3CentvsDeltaRhoLeadingTrackPtQ3(0x0),
+ fh3CentvsDeltaRhoLeadingTrackPtQ4(0x0),
+ fh2PtGenPtSmeared(0x0),
+ fp1Efficiency(0x0),
+ fp1PtResolution(0x0),
fHistList(0x0)
{
+ //
+ // named ctor
+ //
+
+ for(int i = 0;i<3;i++){
+ fh1BiARandomCones[i] = 0;
+ fh1BiARandomConesRan[i] = 0;
+ }
+ for(int i = 0;i<kMaxCent;i++){
+ fh2JetsLeadingPhiPtC[i] = 0;
+ fh2JetsLeadingPhiPtWC[i] = 0; //! jet correlation with leading jet
+ fh2TracksLeadingJetPhiPtC[i] = 0;
+ fh2TracksLeadingJetPhiPtWC[i] = 0;
+ }
DefineOutput(1, TList::Class());
}
// Create the output container
//
-
+ fRandom = new TRandom3(0);
// Connect the AOD
if (fDebug > 1) printf("AnalysisTaskJetCluster::UserCreateOutputObjects() \n");
-
+
if(fNonStdBranch.Length()!=0)
{
// Create a new branch for jets...
// -> cleared in the UserExec....
// here we can also have the case that the brnaches are written to a separate file
+
+ if(fJetTypes&kJet){
+ fTCAJetsOut = new TClonesArray("AliAODJet", 0);
+ fTCAJetsOut->SetName(fNonStdBranch.Data());
+ AddAODBranch("TClonesArray",&fTCAJetsOut,fNonStdFile.Data());
+ }
+
+ if(fJetTypes&kJetRan){
+ fTCAJetsOutRan = new TClonesArray("AliAODJet", 0);
+ fTCAJetsOutRan->SetName(Form("%s_%s",fNonStdBranch.Data(),"random"));
+ if(fUseDiceEfficiency || fUseTrPtResolutionSmearing) {
+ if( fEfficiencyFixed < 1.)
+ fTCAJetsOutRan->SetName(Form("%s_%sDetector%d%dEffFixed%d",fNonStdBranch.Data(),"random",fUseTrPtResolutionSmearing,fUseDiceEfficiency,(int)(fEfficiencyFixed*100.)));
+ else
+ fTCAJetsOutRan->SetName(Form("%s_%sDetector%d%dFr%d",fNonStdBranch.Data(),"random",fUseTrPtResolutionSmearing,fUseDiceEfficiency,(int)(fChangeEfficiencyFraction*100.)));
+ }
+ AddAODBranch("TClonesArray",&fTCAJetsOutRan,fNonStdFile.Data());
+ }
- TClonesArray *tca = new TClonesArray("AliAODJet", 0);
- tca->SetName(fNonStdBranch.Data());
- AddAODBranch("TClonesArray",&tca,fNonStdFile.Data());
+ if(fUseBackgroundCalc){
+ if(!AODEvent()->FindListObject(Form("%s_%s",AliAODJetEventBackground::StdBranchName(),fNonStdBranch.Data()))){
+ fAODJetBackgroundOut = new AliAODJetEventBackground();
+ fAODJetBackgroundOut->SetName(Form("%s_%s",AliAODJetEventBackground::StdBranchName(),fNonStdBranch.Data()));
+ if(fUseDiceEfficiency || fUseTrPtResolutionSmearing) {
+ if( fEfficiencyFixed < 1.)
+ fAODJetBackgroundOut->SetName(Form("%s_%sDetector%d%dEffFixed%d",AliAODJetEventBackground::StdBranchName(),fNonStdBranch.Data(),fUseTrPtResolutionSmearing,fUseDiceEfficiency,(int)(fEfficiencyFixed*100.)));
+ else
+ fAODJetBackgroundOut->SetName(Form("%s_%sDetector%d%dFr%d",AliAODJetEventBackground::StdBranchName(),fNonStdBranch.Data(),fUseTrPtResolutionSmearing,fUseDiceEfficiency,(int)(fChangeEfficiencyFraction*100.)));
+ }
+ AddAODBranch("AliAODJetEventBackground",&fAODJetBackgroundOut,fNonStdFile.Data());
+ }
+ }
+ // create the branch for the random cones with the same R
+ TString cName = Form("%sRandomConeSkip%02d",fNonStdBranch.Data(),fNSkipLeadingCone);
+ if(fUseDiceEfficiency || fUseTrPtResolutionSmearing) {
+ if( fEfficiencyFixed < 1.)
+ cName = Form("%sDetector%d%dEffFixed%d_RandomConeSkip%02d",fNonStdBranch.Data(),fUseTrPtResolutionSmearing,fUseDiceEfficiency,(int)(fEfficiencyFixed*100.),fNSkipLeadingCone);
+ else
+ cName = Form("%sDetector%d%dFr%d_RandomConeSkip%02d",fNonStdBranch.Data(),fUseTrPtResolutionSmearing,fUseDiceEfficiency,(int)(fChangeEfficiencyFraction*100.),fNSkipLeadingCone);
+ }
+ if(fNRandomCones>0){
+ if(fJetTypes&kRC){
+ if(!AODEvent()->FindListObject(cName.Data())){
+ fTCARandomConesOut = new TClonesArray("AliAODJet", 0);
+ fTCARandomConesOut->SetName(cName.Data());
+ AddAODBranch("TClonesArray",&fTCARandomConesOut,fNonStdFile.Data());
+ }
+ }
+ // create the branch with the random for the random cones on the random event
+ if(fJetTypes&kRCRan){
+ cName = Form("%sRandomCone_random",fNonStdBranch.Data());
+ if(!AODEvent()->FindListObject(cName.Data())){
+ fTCARandomConesOutRan = new TClonesArray("AliAODJet", 0);
+ fTCARandomConesOutRan->SetName(cName.Data());
+ AddAODBranch("TClonesArray",&fTCARandomConesOutRan,fNonStdFile.Data());
+ }
+ }
+ }
+
if(fNonStdFile.Length()!=0){
//
// case that we have an AOD extension we need to fetch the jets from the extended output
- // we identifay the extension aod event by looking for the branchname
+ // we identify the extension aod event by looking for the branchname
AliAODHandler *aodH = dynamic_cast<AliAODHandler*>(AliAnalysisManager::GetAnalysisManager()->GetOutputEventHandler());
- TObjArray* extArray = aodH->GetExtensions();
- if (extArray) {
- TIter next(extArray);
- while ((fAODExtension=(AliAODExtension*)next())){
- TObject *obj = fAODExtension->GetAOD()->FindListObject(fNonStdBranch.Data());
- if(fDebug>10){
- Printf("%s:%d Dumping..",(char*)__FILE__,__LINE__);
- fAODExtension->GetAOD()->Dump();
- }
- if(obj){
- if(fDebug>1)Printf("AODExtension found for %s",fNonStdBranch.Data());
- break;
- }
- fAODExtension = 0;
- }
- }
+ // case that we have an AOD extension we need can fetch the background maybe from the extended output
+ fAODExtension = (aodH?aodH->GetExtension(fNonStdFile.Data()):0);
}
}
- OpenFile(1);
if(!fHistList)fHistList = new TList();
+ fHistList->SetOwner();
+ PostData(1, fHistList); // post data in any case once
Bool_t oldStatus = TH1::AddDirectoryStatus();
TH1::AddDirectory(kFALSE);
//
// Histogram
- const Int_t nBinPt = 200;
+ const Int_t nBinPt = 100;
Double_t binLimitsPt[nBinPt+1];
for(Int_t iPt = 0;iPt <= nBinPt;iPt++){
if(iPt == 0){
binLimitsPt[iPt] = 0.0;
}
else {// 1.0
- binLimitsPt[iPt] = binLimitsPt[iPt-1] + 0.5;
+ binLimitsPt[iPt] = binLimitsPt[iPt-1] + 2.0;
}
}
}
}
- const int nChMax = 100;
+ const int nChMax = 5000;
fh1Xsec = new TProfile("fh1Xsec","xsec from pyxsec.root",1,0,1);
fh1Xsec->GetXaxis()->SetBinLabel(1,"<#sigma>");
fh1PtJetsLeadingRecInRan = new TH1F("fh1PtJetsLeadingRecInRan","Rec jets P_T;p_{T} (GeV/c)",nBinPt,binLimitsPt);
fh1PtJetConstRec = new TH1F("fh1PtJetsConstRec","Rec jets constituents P_T;p_{T} (GeV/c)",nBinPt,binLimitsPt);
fh1PtJetConstLeadingRec = new TH1F("fh1PtJetsConstLeadingRec","Rec jets constituents P_T;p_{T} (GeV/c)",nBinPt,binLimitsPt);
- fh1PtTracksRecIn = new TH1F("fh1PtTracksRecIn","Rec tracks P_T #eta < 0.9;p_{T} (GeV/c)",nBinPt,binLimitsPt);
- fh1PtTracksLeadingRecIn = new TH1F("fh1PtTracksLeadingRecIn","Rec tracks P_T #eta < 0.9;p_{T} (GeV/c)",nBinPt,binLimitsPt);
- fh1PtTracksGenIn = new TH1F("fh1PtTracksGenIn","gen tracks P_T #eta < 0.9;p_{T} (GeV/c)",nBinPt,binLimitsPt);
+ fh1PtTracksRecIn = new TH1F("fh1PtTracksRecIn",Form("Rec tracks P_T #eta < %1.2f;p_{T} (GeV/c)",fTrackEtaWindow),nBinPt,binLimitsPt);
+ fh1PtTracksLeadingRecIn = new TH1F("fh1PtTracksLeadingRecIn",Form("Rec tracks P_T #eta < %1.2f ;p_{T} (GeV/c)",fTrackEtaWindow),nBinPt,binLimitsPt);
+ fh1PtTracksGenIn = new TH1F("fh1PtTracksGenIn",Form("gen tracks P_T #eta < %1.2f ;p_{T} (GeV/c)",fTrackEtaWindow),nBinPt,binLimitsPt);
fh1Nch = new TH1F("fh1Nch","charged multiplicity; N_{ch}",nChMax,-0.5,nChMax-0.5);
+ fh1Centrality = new TH1F("fh1Centrality",";cent (%)",111,-0.5,110.5);
+ fh1CentralitySelect = new TH1F("fh1CentralitySelect",";cent (%)",111,-0.5,110.5);
+ fh1CentralityPhySel = new TH1F("fh1CentralityPhySel",";cent (%)",111,-0.5,110.5);
+
+ fh1Z = new TH1F("fh1Z",";zvtx",100,-25,25);
+ fh1ZSelect = new TH1F("fh1ZSelect",";zvtx",100,-25,25);
+ fh1ZPhySel = new TH1F("fh1ZPhySel",";zvtx",100,-25,25);
+
fh2NRecJetsPt = new TH2F("fh2NRecJetsPt","Number of jets above threshhold;p_{T,cut} (GeV/c);N_{jets}",nBinPt,binLimitsPt,50,-0.5,49.5);
fh2NRecJetsPtRan = new TH2F("fh2NRecJetsPtRan","Number of jets above threshhold;p_{T,cut} (GeV/c);N_{jets}",nBinPt,binLimitsPt,50,-0.5,49.5);
fh2NRecTracksPt = new TH2F("fh2NRecTracksPt","Number of tracks above threshhold;p_{T,cut} (GeV/c);N_{tracks}",nBinPt,binLimitsPt,50,-0.5,49.5);
nBinEta,binLimitsEta,nBinPt,binLimitsPt);
fh2TrackEtaPt = new TH2F("fh2TrackEtaPt","pt vs eta all jets;#eta;p_{T}",
- nBinEta,binLimitsEta,nBinPt,binLimitsPt);
+ nBinEta,binLimitsEta,nBinPt,binLimitsPt);
fh2LeadingTrackEtaPt = new TH2F("fh2LeadingTrackEtaPt","pT vs eta leading jets;#eta;p_{T}",
- nBinEta,binLimitsEta,nBinPt,binLimitsPt);
+ nBinEta,binLimitsEta,nBinPt,binLimitsPt);
fh2JetsLeadingPhiEta = new TH2F("fh2JetsLeadingPhiEta","delta eta vs delta phi to leading jet;#Delta#phi;#Delta#eta",
- nBinPhi,binLimitsPhi,nBinEta,binLimitsEta);
+ nBinPhi,binLimitsPhi,nBinEta,binLimitsEta);
fh2JetsLeadingPhiPt = new TH2F("fh2JetsLeadingPhiPt","leading p_T vs delta phi to leading jet;#Delta#phi;p_{T} (GeV/c)",
- nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
+ nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
fh2TracksLeadingPhiEta = new TH2F("fh2TracksLeadingPhiEta","delta eta vs delta phi to leading track;#Delta#phi;#Delta#eta",
nBinPhi,binLimitsPhi,nBinEta,binLimitsEta);
fh2TracksLeadingPhiPt = new TH2F("fh2TracksLeadingPhiPt","leading p_T vs delta phi to leading jet;#Delta#phi;p_{T} (GeV/c)",
- nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
+ nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
fh2TracksLeadingJetPhiPt = new TH2F("fh2TracksLeadingJetPhiPt","leading p_T vs delta phi to leading jet;#Delta#phi;p_{T} (GeV/c)",
- nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
+ nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
fh2TracksLeadingJetPhiPtRan = new TH2F("fh2TracksLeadingJetPhiPtRan","leading p_T vs delta phi to leading jet;#Delta#phi;p_{T} (GeV/c)",
- nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
+ nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
fh2JetsLeadingPhiPtW = new TH2F("fh2JetsLeadingPhiPtW","leading p_T vs delta phi p_T weigted to leading jet;#Delta#phi;p_{T} (GeV/c)",
- nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
+ nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
fh2TracksLeadingPhiPtW = new TH2F("fh2TracksLeadingPhiPtW","leading p_T vs delta phi to leading jet (p_T weighted);#Delta#phi;p_{T} (GeV/c)",
- nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
+ nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
fh2TracksLeadingJetPhiPtW = new TH2F("fh2TracksLeadingJetPhiPtW","leading p_T vs delta phi to leading jet;#Delta#phi;p_{T} (GeV/c)",
nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
fh2TracksLeadingJetPhiPtWRan = new TH2F("fh2TracksLeadingJetPhiPtWRan","leading p_T vs delta phi to leading jet;#Delta#phi;p_{T} (GeV/c)",
- nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
+ nBinPhi,binLimitsPhi,nBinPt,binLimitsPt);
+
+ if(fStoreRhoLeadingTrackCorr) {
+ fh3CentvsRhoLeadingTrackPt = new TH3F("fh3CentvsRhoLeadingTrackPt","centrality vs background density full event; centrality; #rho", 50,0.,100.,500,0.,250.,100,0.,100.);
+ fh3CentvsSigmaLeadingTrackPt = new TH3F("fh3CentvsSigmaLeadingTrackPt","centrality vs sigma full event; centrality; #sigma(#rho)", 50,0.,100.,50,0.,50.,100,0.,100.);
+ fh3MultvsRhoLeadingTrackPt = new TH3F("fh3MultvsRhoLeadingTrackPt","multiplicity vs background density full event; multiplicity; #rho", 100,0.,5000.,500,0.,250.,100,0.,100.);
+ fh3MultvsSigmaLeadingTrackPt = new TH3F("fh3MultvsSigmaLeadingTrackPt","multiplicity vs sigma full event; multiplicity; #sigma(#rho)", 100,0.,5000.,50,0.,50.,100,0.,100.);
+
+
+ fh3CentvsRhoLeadingTrackPtQ1 = new TH3F("fh3CentvsRhoLeadingTrackPtQ1","centrality vs background density Q1; centrality; #rho; leading p_{t}^{track}", 50,0.,100.,500,0.,250.,100,0.,100.);
+ fh3CentvsRhoLeadingTrackPtQ2 = new TH3F("fh3CentvsRhoLeadingTrackPtQ2","centrality vs background density Q2; centrality; #rho; leading p_{t}^{track}", 50,0.,100.,500,0.,250.,100,0.,100.);
+ fh3CentvsRhoLeadingTrackPtQ3 = new TH3F("fh3CentvsRhoLeadingTrackPtQ3","centrality vs background density Q3; centrality; #rho; leading p_{t}^{track}", 50,0.,100.,500,0.,250.,100,0.,100.);
+ fh3CentvsRhoLeadingTrackPtQ4 = new TH3F("fh3CentvsRhoLeadingTrackPtQ4","centrality vs background density Q4; centrality; #rho; leading p_{t}^{track}", 50,0.,100.,500,0.,250.,100,0.,100.);
+
+ fh3CentvsSigmaLeadingTrackPtQ1 = new TH3F("fh3CentvsSigmaLeadingTrackPtQ1","centrality vs background density Q1; centrality; #sigma(#rho); leading p_{t}^{track}", 50,0.,100.,50,0.,50.,100,0.,100.);
+ fh3CentvsSigmaLeadingTrackPtQ2 = new TH3F("fh3CentvsSigmaLeadingTrackPtQ2","centrality vs background density Q2; centrality; #sigma(#rho); leading p_{t}^{track}", 50,0.,100.,50,0.,50.,100,0.,100.);
+ fh3CentvsSigmaLeadingTrackPtQ3 = new TH3F("fh3CentvsSigmaLeadingTrackPtQ3","centrality vs background density Q3; centrality; #sigma(#rho); leading p_{t}^{track}", 50,0.,100.,50,0.,50.,100,0.,100.);
+ fh3CentvsSigmaLeadingTrackPtQ4 = new TH3F("fh3CentvsSigmaLeadingTrackPtQ4","centrality vs background density Q4; centrality; #sigma(#rho); leading p_{t}^{track}", 50,0.,100.,50,0.,50.,100,0.,100.);
+
+ fh3MultvsRhoLeadingTrackPtQ1 = new TH3F("fh3MultvsRhoLeadingTrackPtQ1","multiplicity vs background density Q1; multiplicity; #rho; leading p_{t}^{track}", 100,0.,5000.,500,0.,250.,100,0.,100.);
+ fh3MultvsRhoLeadingTrackPtQ2 = new TH3F("fh3MultvsRhoLeadingTrackPtQ2","multiplicity vs background density Q2; multiplicity; #rho; leading p_{t}^{track}", 100,0.,5000.,500,0.,250.,100,0.,100.);
+ fh3MultvsRhoLeadingTrackPtQ3 = new TH3F("fh3MultvsRhoLeadingTrackPtQ3","multiplicity vs background density Q3; multiplicity; #rho; leading p_{t}^{track}", 100,0.,5000.,500,0.,250.,100,0.,100.);
+ fh3MultvsRhoLeadingTrackPtQ4 = new TH3F("fh3MultvsRhoLeadingTrackPtQ4","multiplicity vs background density Q4; multiplicity; #rho; leading p_{t}^{track}", 100,0.,5000.,500,0.,250.,100,0.,100.);
+
+ fh3MultvsSigmaLeadingTrackPtQ1 = new TH3F("fh3MultvsSigmaLeadingTrackPtQ1","multiplicity vs background density Q1; multiplicity; #sigma(#rho); leading p_{t}^{track}", 100,0.,5000.,50,0.,50.,100,0.,100.);
+ fh3MultvsSigmaLeadingTrackPtQ2 = new TH3F("fh3MultvsSigmaLeadingTrackPtQ2","multiplicity vs background density Q2; multiplicity; #sigma(#rho); leading p_{t}^{track}", 100,0.,5000.,50,0.,50.,100,0.,100.);
+ fh3MultvsSigmaLeadingTrackPtQ3 = new TH3F("fh3MultvsSigmaLeadingTrackPtQ3","multiplicity vs background density Q3; multiplicity; #sigma(#rho); leading p_{t}^{track}", 100,0.,5000.,50,0.,50.,100,0.,100.);
+ fh3MultvsSigmaLeadingTrackPtQ4 = new TH3F("fh3MultvsSigmaLeadingTrackPtQ4","multiplicity vs background density Q4; multiplicity; #sigma(#rho); leading p_{t}^{track}", 100,0.,5000.,50,0.,50.,100,0.,100.);
+
+
+ fh3CentvsDeltaRhoLeadingTrackPtQ1 = new TH3F("fh3CentvsDeltaRhoLeadingTrackPtQ1","centrality vs background density Q1; centrality; #rho_{quadrant}-#rho_{full event}; leading p_{t}^{track}", 50,0.,100.,200,-10.,10.,100,0.,100.);
+ fh3CentvsDeltaRhoLeadingTrackPtQ2 = new TH3F("fh3CentvsDeltaRhoLeadingTrackPtQ2","centrality vs background density Q2; centrality; #rho_{quadrant}-#rho_{full event}; leading p_{t}^{track}", 50,0.,100.,200,-10.,10.,100,0.,100.);
+ fh3CentvsDeltaRhoLeadingTrackPtQ3 = new TH3F("fh3CentvsDeltaRhoLeadingTrackPtQ3","centrality vs background density Q3; centrality; #rho_{quadrant}-#rho_{full event}; leading p_{t}^{track}", 50,0.,100.,200,-10.,10.,100,0.,100.);
+ fh3CentvsDeltaRhoLeadingTrackPtQ4 = new TH3F("fh3CentvsDeltaRhoLeadingTrackPtQ4","centrality vs background density Q4; centrality; #rho_{quadrant}-#rho_{full event}; leading p_{t}^{track}", 50,0.,100.,200,-10.,10.,100,0.,100.);
+
+ fHistList->Add(fh3CentvsRhoLeadingTrackPt);
+ fHistList->Add(fh3CentvsSigmaLeadingTrackPt);
+ fHistList->Add(fh3MultvsRhoLeadingTrackPt);
+ fHistList->Add(fh3MultvsSigmaLeadingTrackPt);
+
+ fHistList->Add(fh3CentvsRhoLeadingTrackPtQ1);
+ fHistList->Add(fh3CentvsRhoLeadingTrackPtQ2);
+ fHistList->Add(fh3CentvsRhoLeadingTrackPtQ3);
+ fHistList->Add(fh3CentvsRhoLeadingTrackPtQ4);
+
+ fHistList->Add(fh3CentvsSigmaLeadingTrackPtQ1);
+ fHistList->Add(fh3CentvsSigmaLeadingTrackPtQ2);
+ fHistList->Add(fh3CentvsSigmaLeadingTrackPtQ3);
+ fHistList->Add(fh3CentvsSigmaLeadingTrackPtQ4);
+
+ fHistList->Add(fh3MultvsRhoLeadingTrackPtQ1);
+ fHistList->Add(fh3MultvsRhoLeadingTrackPtQ2);
+ fHistList->Add(fh3MultvsRhoLeadingTrackPtQ3);
+ fHistList->Add(fh3MultvsRhoLeadingTrackPtQ4);
+
+ fHistList->Add(fh3MultvsSigmaLeadingTrackPtQ1);
+ fHistList->Add(fh3MultvsSigmaLeadingTrackPtQ2);
+ fHistList->Add(fh3MultvsSigmaLeadingTrackPtQ3);
+ fHistList->Add(fh3MultvsSigmaLeadingTrackPtQ4);
+
+ fHistList->Add(fh3CentvsDeltaRhoLeadingTrackPtQ1);
+ fHistList->Add(fh3CentvsDeltaRhoLeadingTrackPtQ2);
+ fHistList->Add(fh3CentvsDeltaRhoLeadingTrackPtQ3);
+ fHistList->Add(fh3CentvsDeltaRhoLeadingTrackPtQ4);
+
+ }
+
+ //Detector level effects histos
+ fh2PtGenPtSmeared = new TH2F("fh2PtGenPtSmeared","fh2PtGenPtSmeared",nBinPt,binLimitsPt,nBinPt,binLimitsPt);
+ fp1Efficiency = new TProfile("fp1Efficiency","fp1Efficiency",nBinPt,binLimitsPt);
+ fp1PtResolution = new TProfile("fp1PtResolution","fp1PtResolution",nBinPt,binLimitsPt);
+ fHistList->Add(fh2PtGenPtSmeared);
+ fHistList->Add(fp1Efficiency);
+ fHistList->Add(fp1PtResolution);
+
+ if(fNRandomCones>0&&fUseBackgroundCalc){
+ for(int i = 0;i<3;i++){
+ fh1BiARandomCones[i] = new TH1F(Form("fh1BiARandomCones%d",i),";B_{i}^{A} (GeV/c)",200,-100,100);
+ fh1BiARandomConesRan[i] = new TH1F(Form("fh1BiARandomConesRan%d",i),";B_{i}^{A} (GeV/c)",200,-100,100);
+ }
+ }
+
+ for(int i = 0;i < kMaxCent;i++){
+ fh2JetsLeadingPhiPtC[i] = (TH2F*)fh2JetsLeadingPhiPt->Clone(Form("%s_C%02d",fh2JetsLeadingPhiPt->GetName(),i+1));
+ fh2JetsLeadingPhiPtWC[i]= (TH2F*)fh2JetsLeadingPhiPtW->Clone(Form("%s_C%02d",fh2JetsLeadingPhiPtW->GetName(),i+1));
+ fh2TracksLeadingJetPhiPtC[i] = (TH2F*)fh2TracksLeadingJetPhiPt->Clone(Form("%s_C%02d",fh2TracksLeadingJetPhiPt->GetName(),i+1));
+ fh2TracksLeadingJetPhiPtWC[i] = (TH2F*)fh2TracksLeadingJetPhiPtW->Clone(Form("%s_C%02d",fh2TracksLeadingJetPhiPtW->GetName(),i+1));
+ }
const Int_t saveLevel = 3; // large save level more histos
if(saveLevel>0){
fHistList->Add(fh1NConstLeadingRecRan);
fHistList->Add(fh1PtJetsRecInRan);
fHistList->Add(fh1Nch);
+ fHistList->Add(fh1Centrality);
+ fHistList->Add(fh1CentralitySelect);
+ fHistList->Add(fh1CentralityPhySel);
+ fHistList->Add(fh1Z);
+ fHistList->Add(fh1ZSelect);
+ fHistList->Add(fh1ZPhySel);
+ if(fNRandomCones>0&&fUseBackgroundCalc){
+ for(int i = 0;i<3;i++){
+ fHistList->Add(fh1BiARandomCones[i]);
+ fHistList->Add(fh1BiARandomConesRan[i]);
+ }
+ }
+ for(int i = 0;i < kMaxCent;i++){
+ fHistList->Add(fh2JetsLeadingPhiPtC[i]);
+ fHistList->Add(fh2JetsLeadingPhiPtWC[i]);
+ fHistList->Add(fh2TracksLeadingJetPhiPtC[i]);
+ fHistList->Add(fh2TracksLeadingJetPhiPtWC[i]);
+ }
+
fHistList->Add(fh2NRecJetsPt);
fHistList->Add(fh2NRecTracksPt);
fHistList->Add(fh2NConstPt);
fHistList->Add(fh2NConstLeadingPtRan);
fHistList->Add(fh2TracksLeadingJetPhiPtRan);
fHistList->Add(fh2TracksLeadingJetPhiPtWRan);
- }
+ }
// =========== Switch on Sumw2 for all histos ===========
for (Int_t i=0; i<fHistList->GetEntries(); ++i) {
TH1::AddDirectory(oldStatus);
}
-void AliAnalysisTaskJetCluster::Init()
+void AliAnalysisTaskJetCluster::LocalInit()
{
//
// Initialization
if (fDebug > 1) printf("AnalysisTaskJetCluster::Init() \n");
+ if(fUseTrPtResolutionFromOADB) LoadTrPtResolutionRootFileFromOADB();
+ if(fUseTrEfficiencyFromOADB) LoadTrEfficiencyRootFileFromOADB();
+
+
+ FitMomentumResolution();
+
}
void AliAnalysisTaskJetCluster::UserExec(Option_t */*option*/)
{
- if(fUseGlobalSelection){
- // no selection by the service task, we continue
- if (fDebug > 1)Printf("Not selected %s:%d",(char*)__FILE__,__LINE__);
- PostData(1, fHistList);
- return;
- }
-
// handle and reset the output jet branch
- // only need this once
- TClonesArray* jarray = 0;
- if(fNonStdBranch.Length()!=0) {
- if(AODEvent())jarray = (TClonesArray*)(AODEvent()->FindListObject(fNonStdBranch.Data()));
- if(!jarray)jarray = (TClonesArray*)(fAODExtension->GetAOD()->FindListObject(fNonStdBranch.Data()));
- if(jarray)jarray->Delete(); // this is our responsibility, clear before filling again
- }
+ if(fTCAJetsOut)fTCAJetsOut->Delete();
+ if(fTCAJetsOutRan)fTCAJetsOutRan->Delete();
+ if(fTCARandomConesOut)fTCARandomConesOut->Delete();
+ if(fTCARandomConesOutRan)fTCARandomConesOutRan->Delete();
+ if(fAODJetBackgroundOut)fAODJetBackgroundOut->Reset();
+
+ AliAODJetEventBackground* externalBackground = 0;
+ if(!externalBackground&&fBackgroundBranch.Length()){
+ externalBackground = (AliAODJetEventBackground*)(AODEvent()->FindListObject(fBackgroundBranch.Data()));
+ if((!externalBackground)&&fAODExtension)externalBackground = (AliAODJetEventBackground*)(fAODExtension->GetAOD()->FindListObject(fBackgroundBranch.Data()));
+ if(!externalBackground)Printf("%s:%d Background branch not found %s",(char*)__FILE__,__LINE__,fBackgroundBranch.Data());;
+ }
//
// Execute analysis for current event
//
Printf("%s:%d AODEvent not found in Input Manager %d",(char*)__FILE__,__LINE__,fUseAODTrackInput);
return;
}
- // fethc the header
+ // fetch the header
}
else{
// assume that the AOD is in the general output...
fESD = dynamic_cast<AliESDEvent*> (InputEvent());
}
}
-
+
+ //Check if information is provided detector level effects
+ if(!fMomResH1 || !fMomResH2 || !fMomResH3) fUseTrPtResolutionSmearing = kFALSE;
+ if( fEfficiencyFixed < 1. ) {
+ if (!fUseDiceEfficiency)
+ fUseDiceEfficiency = 1; // 1 is the default; 2 can be set by user
+ }
+ else {
+ if(!fhEffH1 || !fhEffH2 || !fhEffH3 ) fUseDiceEfficiency = kFALSE;
+ }
+
Bool_t selectEvent = false;
Bool_t physicsSelection = true;// handled by the framework(fInputHandler->IsEventSelected()&AliVEvent::kMB)==AliVEvent::kMB;
+ Float_t cent = 0;
+ Float_t zVtx = 0;
+ Int_t cenClass = -1;
if(fAOD){
const AliAODVertex *vtxAOD = fAOD->GetPrimaryVertex();
TString vtxTitle(vtxAOD->GetTitle());
+ zVtx = vtxAOD->GetZ();
+
+ cent = fAOD->GetHeader()->GetCentrality();
+ if(cent<10)cenClass = 0;
+ else if(cent<30)cenClass = 1;
+ else if(cent<50)cenClass = 2;
+ else if(cent<80)cenClass = 3;
+ if(physicsSelection){
+ fh1CentralityPhySel->Fill(cent);
+ fh1ZPhySel->Fill(zVtx);
+ }
- if(vtxAOD->GetNContributors()>2&&!vtxTitle.Contains("TPCVertex")){
- Float_t zvtx = vtxAOD->GetZ();
+ if(fEventSelection){
+ if(vtxAOD->GetNContributors()>2&&!vtxTitle.Contains("TPCVertex")){
Float_t yvtx = vtxAOD->GetY();
Float_t xvtx = vtxAOD->GetX();
Float_t r2 = yvtx*yvtx+xvtx*xvtx;
- if(TMath::Abs(zvtx)<8.&&r2<1.){
- if(physicsSelection)selectEvent = true;
+ if(TMath::Abs(zVtx)<fVtxZCut&&r2<fVtxR2Cut){ // apply vertex cut later on
+ if(physicsSelection){
+ selectEvent = true;
+ }
}
+ }
+ if(fCentCutUp>0){
+ if(cent<fCentCutLo||cent>fCentCutUp){
+ selectEvent = false;
+ }
+ }
+ }else{
+ selectEvent = true;
}
}
+
+
+ Bool_t T0 = false;
+ Bool_t V0 = false;
+ const AliAODVZERO *vzero = fAOD->GetVZEROData();
+ if(vzero){
+ if((vzero->GetTriggerChargeA()>0)&&(vzero->GetTriggerChargeC()>0)){
+ V0 = true;
+ }
+ }
+
+ const AliAODTZERO *tzero = fAOD->GetTZEROData();
+ if(tzero){
+ if(TMath::Abs(tzero->GetT0VertexRaw())<100){
+ T0 = true;
+ }
+ }
+
+ if(fRequireVZEROAC&&fRequireTZEROvtx)selectEvent = selectEvent&&V0&&T0;
+ else if(fRequireTZEROvtx)selectEvent = selectEvent&&T0;
+ else if(fRequireVZEROAC)selectEvent = selectEvent&&V0;
+
+
if(!selectEvent){
PostData(1, fHistList);
return;
}
-
+ fh1Centrality->Fill(cent);
+ fh1Z->Fill(zVtx);
fh1Trials->Fill("#sum{ntrials}",1);
Int_t nT = GetListOfTracks(&recParticles,fTrackTypeRec);
Float_t nCh = recParticles.GetEntries();
+ Float_t nGen=genParticles.GetEntries();
fh1Nch->Fill(nCh);
if(fDebug>2)Printf("%s:%d Selected Rec tracks: %d %d",(char*)__FILE__,__LINE__,nT,recParticles.GetEntries());
nT = GetListOfTracks(&genParticles,fTrackTypeGen);
vector<fastjet::PseudoJet> inputParticlesRec;
vector<fastjet::PseudoJet> inputParticlesRecRan;
+
+ // Generate the random cones
+
+ AliAODJet vTmpRan(1,0,0,1);
for(int i = 0; i < recParticles.GetEntries(); i++){
AliVParticle *vp = (AliVParticle*)recParticles.At(i);
+
// Carefull energy is not well determined in real data, should not matter for p_T scheme?
- // we talk total momentum here
- fastjet::PseudoJet jInp(vp->Px(),vp->Py(),vp->Pz(),vp->P());
- jInp.set_user_index(i);
- inputParticlesRec.push_back(jInp);
+ // we take total momentum here
+
+ if((!fUseTrPtResolutionSmearing) && (!fUseDiceEfficiency)) {
+ //Add particles to fastjet in case we are not running toy model
+ fastjet::PseudoJet jInp(vp->Px(),vp->Py(),vp->Pz(),vp->P());
+ jInp.set_user_index(i);
+ inputParticlesRec.push_back(jInp);
+ }
+ else if(fUseDiceEfficiency) {
+
+ // Dice to decide if particle is kept or not - toy model for efficiency
+ //
+ Double_t sumEff = 0.;
+ Double_t pT = 0.;
+ Double_t eff[3] = {0.};
+ Int_t cat[3] = {0};
+
+ Double_t rnd = fRandom->Uniform(1.);
+ if( fEfficiencyFixed<1. ) {
+ sumEff = fEfficiencyFixed;
+ if (fUseDiceEfficiency == 2) {
+ sumEff = (nCh - fEfficiencyFixed*nGen) / nCh; // rescale eff; fEfficiencyFixed is wrt to nGen, but dicing is fraction of nCh
+ }
+ } else {
+
+ pT = vp->Pt();
+ Double_t pTtmp = pT;
+ if(pT>10.) pTtmp = 10.;
+ Double_t eff1 = fhEffH1->GetBinContent(fhEffH1->FindBin(pTtmp));
+ Double_t eff2 = fhEffH2->GetBinContent(fhEffH2->FindBin(pTtmp));
+ Double_t eff3 = fhEffH3->GetBinContent(fhEffH3->FindBin(pTtmp));
+
+ //Sort efficiencies from large to small
+ if(eff1>eff2 && eff1>eff3) {
+ eff[0] = eff1;
+ cat[0] = 1;
+ if(eff2>eff3) {
+ eff[1] = eff2;
+ eff[2] = eff3;
+ cat[1] = 2;
+ cat[2] = 3;
+ } else {
+ eff[1] = eff3;
+ eff[2] = eff2;
+ cat[1] = 3;
+ cat[2] = 2;
+ }
+ }
+ else if(eff2>eff1 && eff2>eff3) {
+ eff[0] = eff2;
+ cat[0] = 2;
+ if(eff1>eff3) {
+ eff[1] = eff1;
+ eff[2] = eff3;
+ cat[1] = 1;
+ cat[2] = 3;
+ } else {
+ eff[1] = eff3;
+ eff[2] = eff1;
+ cat[1] = 3;
+ cat[2] = 1;
+ }
+ }
+ else if(eff3>eff1 && eff3>eff2) {
+ eff[0] = eff3;
+ cat[0] = 3;
+ if(eff1>eff2) {
+ eff[1] = eff1;
+ eff[2] = eff2;
+ cat[1] = 1;
+ cat[2] = 2;
+ } else {
+ eff[1] = eff2;
+ eff[2] = eff1;
+ cat[1] = 2;
+ cat[2] = 1;
+ }
+ }
+
+ sumEff = eff[0]+eff[1]+eff[2];
+ }
+ fp1Efficiency->Fill(vp->Pt(),sumEff);
+ if(rnd>sumEff && pT > fDiceEfficiencyMinPt) continue;
+
+ if(fUseTrPtResolutionSmearing) {
+ //Smear momentum of generated particle
+ Double_t smear = 1.;
+ //Select hybrid track category
+ if(rnd<=eff[2])
+ smear = GetMomentumSmearing(cat[2],pT);
+ else if(rnd<=(eff[2]+eff[1]))
+ smear = GetMomentumSmearing(cat[1],pT);
+ else
+ smear = GetMomentumSmearing(cat[0],pT);
+
+ fp1PtResolution->Fill(vp->Pt(),smear);
+
+ Double_t sigma = vp->Pt()*smear;
+ Double_t pTrec = fRandom->Gaus(vp->Pt(),sigma);
+
+ Double_t phi = vp->Phi();
+ Double_t theta = 2.*TMath::ATan(TMath::Exp(-1.*(vp->Eta())));
+ Double_t pX = pTrec * TMath::Cos(phi);
+ Double_t pY = pTrec * TMath::Sin(phi);
+ Double_t pZ = pTrec/TMath::Tan(theta);
+ Double_t p=TMath::Sqrt(pTrec*pTrec+pZ*pZ);
+
+ fh2PtGenPtSmeared->Fill(vp->Pt(),pTrec);
+
+ fastjet::PseudoJet jInp(pX,pY,pZ,p);
+ jInp.set_user_index(i);
+ inputParticlesRec.push_back(jInp);
+
+ }
+ else {
+ fastjet::PseudoJet jInp(vp->Px(),vp->Py(),vp->Pz(),vp->P());
+ jInp.set_user_index(i);
+ inputParticlesRec.push_back(jInp);
+
+ }
+
+ }
// the randomized input changes eta and phi, but keeps the p_T
if(i>=fNSkipLeadingRan){// eventually skip the leading particles
Double_t pT = vp->Pt();
- Double_t eta = 1.8 * gRandom->Rndm() - 0.9;
- Double_t phi = 2.* TMath::Pi() * gRandom->Rndm();
+ Double_t eta = 2.*fTrackEtaWindow * fRandom->Rndm() - fTrackEtaWindow;
+ Double_t phi = 2.* TMath::Pi() * fRandom->Rndm();
- Double_t theta = 2.*TMath::ATan(TMath::Exp(-2.*eta));
+ Double_t theta = 2.*TMath::ATan(TMath::Exp(-eta));
Double_t pZ = pT/TMath::Tan(theta);
Double_t pX = pT * TMath::Cos(phi);
Double_t pY = pT * TMath::Sin(phi);
Double_t p = TMath::Sqrt(pT*pT+pZ*pZ);
fastjet::PseudoJet jInpRan(pX,pY,pZ,p);
+
jInpRan.set_user_index(i);
inputParticlesRecRan.push_back(jInpRan);
+ vTmpRan.SetPxPyPzE(pX,pY,pZ,p);
}
// fill the tref array, only needed when we write out jets
- if(jarray){
+ if(fTCAJetsOut){
if(i == 0){
fRef->Delete(); // make sure to delete before placement new...
- new(fRef) TRefArray(TProcessID::GetProcessWithUID(vp));
+ if((!fUseTrPtResolutionSmearing) && (!fUseDiceEfficiency)) {
+ new(fRef) TRefArray(TProcessID::GetProcessWithUID(vp)); //TRefArray does not work with toy model ...
+ }
}
- fRef->Add(vp);
+ if((!fUseTrPtResolutionSmearing) && (!fUseDiceEfficiency)) fRef->Add(vp); //TRefArray does not work with toy model ...
}
- }
+ }// recparticles
if(inputParticlesRec.size()==0){
if(fDebug)Printf("%s:%d No input particles found, skipping event",(char*)__FILE__,__LINE__);
}
// run fast jet
+ // employ setters for these...
+
+
+ // now create the object that holds info about ghosts
+ /*
+ if(!fUseBackgroundCalc&& fNonStdBranch.Length()==0){
+ // reduce CPU time...
+ fGhostArea = 0.5;
+ fActiveAreaRepeats = 0;
+ }
+ */
+
+ fastjet::GhostedAreaSpec ghostSpec(fGhostEtamax, fActiveAreaRepeats, fGhostArea);
+ fastjet::AreaType areaType = fastjet::active_area;
+ fastjet::AreaDefinition areaDef = fastjet::AreaDefinition(areaType,ghostSpec);
fastjet::JetDefinition jetDef(fAlgorithm, fRparam, fRecombScheme, fStrategy);
- vector <fastjet::PseudoJet> inclusiveJets, sortedJets;
- fastjet::ClusterSequence clustSeq(inputParticlesRec, jetDef);
+ fastjet::ClusterSequenceArea clustSeq(inputParticlesRec, jetDef,areaDef);
- inclusiveJets = clustSeq.inclusive_jets();
- sortedJets = sorted_by_pt(inclusiveJets);
+ //range where to compute background
+ Double_t phiMin = 0, phiMax = 0, rapMin = 0, rapMax = 0;
+ phiMin = 0;
+ phiMax = 2*TMath::Pi();
+ rapMax = fGhostEtamax - fRparam;
+ rapMin = - fGhostEtamax + fRparam;
+ fastjet::RangeDefinition range(rapMin,rapMax, phiMin, phiMax);
+
+
+ const vector <fastjet::PseudoJet> &inclusiveJets = clustSeq.inclusive_jets();
+ const vector <fastjet::PseudoJet> &sortedJets = sorted_by_pt(inclusiveJets);
+
fh1NJetsRec->Fill(sortedJets.size());
- // loop over all jets an fill information, first on is the leading jet
+ // loop over all jets an fill information, first on is the leading jet
Int_t nRecOver = inclusiveJets.size();
Int_t nRec = inclusiveJets.size();
if(inclusiveJets.size()>0){
AliAODJet leadingJet (sortedJets[0].px(), sortedJets[0].py(), sortedJets[0].pz(), sortedJets[0].E());
+ Double_t area = clustSeq.area(sortedJets[0]);
+ leadingJet.SetEffArea(area,0);
Float_t pt = leadingJet.Pt();
Int_t nAodOutJets = 0;
Int_t nAodOutTracks = 0;
Float_t phi = leadingJet.Phi();
if(phi<0)phi+=TMath::Pi()*2.;
Float_t eta = leadingJet.Eta();
- pt = leadingJet.Pt();
-
+ Float_t pTback = 0;
+ if(externalBackground){
+ // carefull has to be filled in a task before
+ // todo, ReArrange to the botom
+ pTback = externalBackground->GetBackground(2)*leadingJet.EffectiveAreaCharged();
+ }
+ pt = leadingJet.Pt() - pTback;
// correlation of leading jet with tracks
TIterator *recIter = recParticles.MakeIterator();
recIter->Reset();
if(dPhi<(-1.*TMath::Pi()))dPhi = dPhi + 2.*TMath::Pi();
fh2TracksLeadingJetPhiPt->Fill(dPhi,pt);
fh2TracksLeadingJetPhiPtW->Fill(dPhi,pt,tmpPt);
+ if(cenClass>=0){
+ fh2TracksLeadingJetPhiPtC[cenClass]->Fill(dPhi,pt);
+ fh2TracksLeadingJetPhiPtWC[cenClass]->Fill(dPhi,pt,tmpPt);
+ }
+
}
+ TLorentzVector vecareab;
+ for(int j = 0; j < nRec;j++){
+ AliAODJet tmpRec (sortedJets[j].px(), sortedJets[j].py(), sortedJets[j].pz(), sortedJets[j].E());
+ aodOutJet = 0;
+ nAodOutTracks = 0;
+ Float_t tmpPt = tmpRec.Pt();
+
+ if(tmpPt>fJetOutputMinPt&&fTCAJetsOut){// cut on the non-background subtracted...
+ aodOutJet = new ((*fTCAJetsOut)[nAodOutJets++]) AliAODJet(tmpRec);
+ aodOutJet->GetRefTracks()->Clear();
+ Double_t area1 = clustSeq.area(sortedJets[j]);
+ aodOutJet->SetEffArea(area1,0);
+ fastjet::PseudoJet vecarea=clustSeq.area_4vector(sortedJets[j]);
+ vecareab.SetPxPyPzE(vecarea.px(),vecarea.py(),vecarea.pz(),vecarea.e());
+ aodOutJet->SetVectorAreaCharged(&vecareab);
+ }
+
+
+ Float_t tmpPtBack = 0;
+ if(externalBackground){
+ // carefull has to be filled in a task before
+ // todo, ReArrange to the botom
+ tmpPtBack = externalBackground->GetBackground(2)*tmpRec.EffectiveAreaCharged();
+ }
+ tmpPt = tmpPt - tmpPtBack;
+ if(tmpPt<0)tmpPt = 0; // avoid negative weights...
+
+ fh1PtJetsRecIn->Fill(tmpPt);
+ // Fill Spectra with constituentsemacs
+ const vector<fastjet::PseudoJet> &constituents = clustSeq.constituents(sortedJets[j]);
+
+ fh1NConstRec->Fill(constituents.size());
+ fh2PtNch->Fill(nCh,tmpPt);
+ fh2PtNchN->Fill(nCh,tmpPt,constituents.size());
+ fh2NConstPt->Fill(tmpPt,constituents.size());
+ // loop over constiutents and fill spectrum
+
+ AliVParticle *partLead = 0;
+ Float_t ptLead = -1;
+
+ for(unsigned int ic = 0; ic < constituents.size();ic++){
+ AliVParticle *part = (AliVParticle*)recParticles.At(constituents[ic].user_index());
+ if(!part) continue;
+ fh1PtJetConstRec->Fill(part->Pt());
+ if(aodOutJet){
+ if((!fUseTrPtResolutionSmearing) && (!fUseDiceEfficiency)) aodOutJet->AddTrack(fRef->At(constituents[ic].user_index()));
+ if(part->Pt()>fMaxTrackPtInJet){
+ aodOutJet->SetTrigger(AliAODJet::kHighTrackPtTriggered);
+ }
+ }
+ if(part->Pt()>ptLead){
+ ptLead = part->Pt();
+ partLead = part;
+ }
+ if(j==0)fh1PtJetConstLeadingRec->Fill(part->Pt());
+ }
+
+ AliAODTrack *aodT = 0;
+ if(partLead){
+ if(aodOutJet){
+ //set pT of leading constituent of jet
+ aodOutJet->SetPtLeading(partLead->Pt());
+ aodT = dynamic_cast<AliAODTrack*>(partLead);
+ if(aodT){
+ if(aodT->TestFilterBit(fFilterMaskBestPt)){
+ aodOutJet->SetTrigger(AliAODJet::kHighTrackPtBest);
+ }
+ }
+ }
+ }
- for(int j = 0; j < nRec;j++){
- AliAODJet tmpRec (sortedJets[j].px(), sortedJets[j].py(), sortedJets[j].pz(), sortedJets[j].E());
- aodOutJet = 0;
- nAodOutTracks = 0;
- Float_t tmpPt = tmpRec.Pt();
- fh1PtJetsRecIn->Fill(tmpPt);
- // Fill Spectra with constituents
- vector<fastjet::PseudoJet> constituents = clustSeq.constituents(sortedJets[j]);
- fh1NConstRec->Fill(constituents.size());
- fh2PtNch->Fill(nCh,tmpPt);
- fh2PtNchN->Fill(nCh,tmpPt,constituents.size());
- fh2NConstPt->Fill(tmpPt,constituents.size());
- // loop over constiutents and fill spectrum
-
- // Add the jet information and the track references to the output AOD
-
- if(tmpPt>fJetOutputMinPt&&jarray){
- aodOutJet = new ((*jarray)[nAodOutJets++]) AliAODJet(tmpRec);
- Double_t area=clustSeq.area(sortedJets[j]);
- aodOutJet->SetEffArea(area,0);
- }
+ // correlation
+ Float_t tmpPhi = tmpRec.Phi();
+ Float_t tmpEta = tmpRec.Eta();
+ if(tmpPhi<0)tmpPhi+=TMath::Pi()*2.;
+ if(j==0){
+ fh1PtJetsLeadingRecIn->Fill(tmpPt);
+ fh2LeadingJetPhiEta->Fill(tmpPhi,tmpEta);
+ fh2LeadingJetEtaPt->Fill(tmpEta,tmpPt);
+ fh1NConstLeadingRec->Fill(constituents.size());
+ fh2NConstLeadingPt->Fill(tmpPt,constituents.size());
+ continue;
+ }
+ fh2JetPhiEta->Fill(tmpRec.Phi(),tmpEta);
+ fh2JetEtaPt->Fill(tmpEta,tmpPt);
+ Float_t dPhi = phi - tmpPhi;
+ if(dPhi>TMath::Pi())dPhi = dPhi - 2.*TMath::Pi();
+ if(dPhi<(-1.*TMath::Pi()))dPhi = dPhi + 2.*TMath::Pi();
+ Float_t dEta = eta - tmpRec.Eta();
+ fh2JetsLeadingPhiEta->Fill(dPhi,dEta);
+ fh2JetsLeadingPhiPt->Fill(dPhi,pt);
+ if(cenClass>=0){
+ fh2JetsLeadingPhiPtC[cenClass]->Fill(dPhi,pt);
+ fh2JetsLeadingPhiPtWC[cenClass]->Fill(dPhi,pt,tmpPt);
+ }
+ fh2JetsLeadingPhiPtW->Fill(dPhi,pt,tmpPt);
+ }// loop over reconstructed jets
+ delete recIter;
+
+
+
+ // Add the random cones...
+ if(fNRandomCones>0&&fTCARandomConesOut){
+ // create a random jet within the acceptance
+ Double_t etaMax = fTrackEtaWindow - fRparam;
+ Int_t nCone = 0;
+ Int_t nConeRan = 0;
+ Double_t pTC = 1; // small number
+ for(int ir = 0;ir < fNRandomCones;ir++){
+ Double_t etaC = etaMax*2.*(fRandom->Rndm()-0.5); // +- etamax
+ Double_t phiC = fRandom->Rndm()*2.*TMath::Pi(); // 0 - 2pi
+ // massless jet
+ Double_t thetaC = 2.*TMath::ATan(TMath::Exp(-etaC));
+ Double_t pZC = pTC/TMath::Tan(thetaC);
+ Double_t pXC = pTC * TMath::Cos(phiC);
+ Double_t pYC = pTC * TMath::Sin(phiC);
+ Double_t pC = TMath::Sqrt(pTC*pTC+pZC*pZC);
+ AliAODJet tmpRecC (pXC,pYC,pZC, pC);
+ bool skip = false;
+ for(int jj = 0; jj < TMath::Min(nRec,fNSkipLeadingCone);jj++){// test for overlap with leading jets
+ AliAODJet jet (sortedJets[jj].px(), sortedJets[jj].py(), sortedJets[jj].pz(), sortedJets[jj].E());
+ if(jet.DeltaR(& tmpRecC)<2.*fRparam+0.2){
+ skip = true;
+ break;
+ }
+ }
+ // test for overlap with previous cones to avoid double counting
+ for(int iic = 0;iic<ir;iic++){
+ AliAODJet *iicone = (AliAODJet*)fTCARandomConesOut->At(iic);
+ if(iicone){
+ if(iicone->DeltaR(&tmpRecC)<2.*fRparam){
+ skip = true;
+ break;
+ }
+ }
+ }
+ if(skip)continue;
+ tmpRecC.SetBgEnergy(0,0); // this is use as temporary storage of the summed p_T below
+ tmpRecC.SetPtLeading(-1.);
+ if(fTCARandomConesOut)new ((*fTCARandomConesOut)[nCone++]) AliAODJet(tmpRecC);
+ if(fTCARandomConesOutRan)new ((*fTCARandomConesOutRan)[nConeRan++]) AliAODJet(tmpRecC);
+ }// loop over random cones creation
-
- for(unsigned int ic = 0; ic < constituents.size();ic++){
- AliVParticle *part = (AliVParticle*)recParticles.At(constituents[ic].user_index());
- fh1PtJetConstRec->Fill(part->Pt());
- if(aodOutJet){
- aodOutJet->AddTrack(fRef->At(constituents[ic].user_index()));
- }
- if(j==0)fh1PtJetConstLeadingRec->Fill(part->Pt());
- }
+
+ // loop over the reconstructed particles and add up the pT in the random cones
+ // maybe better to loop over randomized particles not in the real jets...
+ // but this by definition brings dow average energy in the whole event
+ AliAODJet vTmpRanR(1,0,0,1);
+ for(int i = 0; i < recParticles.GetEntries(); i++){
+ AliVParticle *vp = (AliVParticle*)recParticles.At(i);
+ if(fTCARandomConesOut){
+ for(int ir = 0;ir < fNRandomCones;ir++){
+ AliAODJet *jC = (AliAODJet*)fTCARandomConesOut->At(ir);
+ if(jC&&jC->DeltaR(vp)<fRparam){
+ if(vp->Pt()>fMaxTrackPtInJet)jC->SetTrigger(AliAODJet::kHighTrackPtTriggered);
+ jC->SetBgEnergy(jC->ChargedBgEnergy()+vp->Pt(),0);
+ if(vp->Pt() > jC->GetPtLeading()) jC->SetPtLeading(vp->Pt());
+ }
+ }
+ }// add up energy in cone
+
+ // the randomized input changes eta and phi, but keeps the p_T
+ if(i>=fNSkipLeadingRan){// eventually skip the leading particles
+ Double_t pTR = vp->Pt();
+ Double_t etaR = 2.*fTrackEtaWindow* fRandom->Rndm() - fTrackEtaWindow;
+ Double_t phiR = 2.* TMath::Pi() * fRandom->Rndm();
+
+ Double_t thetaR = 2.*TMath::ATan(TMath::Exp(-etaR));
+ Double_t pZR = pTR/TMath::Tan(thetaR);
+
+ Double_t pXR = pTR * TMath::Cos(phiR);
+ Double_t pYR = pTR * TMath::Sin(phiR);
+ Double_t pR = TMath::Sqrt(pTR*pTR+pZR*pZR);
+ vTmpRanR.SetPxPyPzE(pXR,pYR,pZR,pR);
+ if(fTCARandomConesOutRan){
+ for(int ir = 0;ir < fTCARandomConesOutRan->GetEntriesFast();ir++){
+ AliAODJet *jC = (AliAODJet*)fTCARandomConesOutRan->At(ir);
+ if(jC&&jC->DeltaR(&vTmpRanR)<fRparam){
+ if(vTmpRanR.Pt()>fMaxTrackPtInJet)jC->SetTrigger(AliAODJet::kHighTrackPtTriggered);
+ jC->SetBgEnergy(jC->ChargedBgEnergy()+vTmpRanR.Pt(),0);
+ if(vTmpRanR.Pt() > jC->GetPtLeading()) jC->SetPtLeading(vTmpRanR.Pt());
+ }
+ }
+ }
+ }
+ }// loop over recparticles
+
+ Float_t jetArea = fRparam*fRparam*TMath::Pi();
+ if(fTCARandomConesOut){
+ for(int ir = 0;ir < fTCARandomConesOut->GetEntriesFast();ir++){
+ // rescale the momentum vectors for the random cones
+
+ AliAODJet *rC = (AliAODJet*)fTCARandomConesOut->At(ir);
+ if(rC){
+ Double_t etaC = rC->Eta();
+ Double_t phiC = rC->Phi();
+ // massless jet, unit vector
+ pTC = rC->ChargedBgEnergy();
+ if(pTC<=0)pTC = 0.001; // for almost empty events
+ Double_t thetaC = 2.*TMath::ATan(TMath::Exp(-etaC));
+ Double_t pZC = pTC/TMath::Tan(thetaC);
+ Double_t pXC = pTC * TMath::Cos(phiC);
+ Double_t pYC = pTC * TMath::Sin(phiC);
+ Double_t pC = TMath::Sqrt(pTC*pTC+pZC*pZC);
+ rC->SetPxPyPzE(pXC,pYC,pZC, pC);
+ rC->SetBgEnergy(0,0);
+ rC->SetEffArea(jetArea,0);
+ }
+ }
+ }
+ if(fTCARandomConesOutRan){
+ for(int ir = 0;ir < fTCARandomConesOutRan->GetEntriesFast();ir++){
+ AliAODJet* rC = (AliAODJet*)fTCARandomConesOutRan->At(ir);
+ // same wit random
+ if(rC){
+ Double_t etaC = rC->Eta();
+ Double_t phiC = rC->Phi();
+ // massless jet, unit vector
+ pTC = rC->ChargedBgEnergy();
+ if(pTC<=0)pTC = 0.001;// for almost empty events
+ Double_t thetaC = 2.*TMath::ATan(TMath::Exp(-etaC));
+ Double_t pZC = pTC/TMath::Tan(thetaC);
+ Double_t pXC = pTC * TMath::Cos(phiC);
+ Double_t pYC = pTC * TMath::Sin(phiC);
+ Double_t pC = TMath::Sqrt(pTC*pTC+pZC*pZC);
+ rC->SetPxPyPzE(pXC,pYC,pZC, pC);
+ rC->SetBgEnergy(0,0);
+ rC->SetEffArea(jetArea,0);
+ }
+ }
+ }
+ }// if(fNRandomCones
+
+ //background estimates:all bckg jets(0) & wo the 2 hardest(1)
+ if(fAODJetBackgroundOut){
+ vector<fastjet::PseudoJet> jets2=sortedJets;
+ if(jets2.size()>2) jets2.erase(jets2.begin(),jets2.begin()+2);
+ Double_t bkg1=0;
+ Double_t sigma1=0.;
+ Double_t meanarea1=0.;
+ Double_t bkg2=0;
+ Double_t sigma2=0.;
+ Double_t meanarea2=0.;
-
-
+ Double_t bkg4=0;
+ Double_t sigma4=0.;
+ Double_t meanarea4=0.;
+ clustSeq.get_median_rho_and_sigma(jets2, range, true, bkg1, sigma1, meanarea1, true);
+ fAODJetBackgroundOut->SetBackground(0,bkg1,sigma1,meanarea1);
+ // fh1BiARandomCones[0]->Fill(omCone-(bkg1*areaRandomCone));
+ // fh1BiARandomConesRan[0]->Fill(ptRandomConeRan-(bkg1*areaRandomCone));
+ clustSeq.get_median_rho_and_sigma(sortedJets, range, true, bkg4, sigma4, meanarea4, true);
+ fAODJetBackgroundOut->SetBackground(3,bkg4,sigma4,meanarea4);
+
+ //////////////////////
- // correlation
- Float_t tmpPhi = tmpRec.Phi();
- Float_t tmpEta = tmpRec.Eta();
- if(tmpPhi<0)tmpPhi+=TMath::Pi()*2.;
+ clustSeq.get_median_rho_and_sigma(jets2, range, false, bkg2, sigma2, meanarea2, true);
+ fAODJetBackgroundOut->SetBackground(1,bkg2,sigma2,meanarea2);
+ // fh1BiARandomCones[1]->Fill(ptRandomCone-(bkg2*areaRandomCone));
+ // fh1BiARandomConesRan[1]->Fill(ptRandomConeRan-(bkg2*areaRandomCone));
+
+ }
+ }
+
+ if(fStoreRhoLeadingTrackCorr) {
+ vector<fastjet::PseudoJet> jets3=sortedJets;
+ if(jets3.size()>2) jets3.erase(jets3.begin(),jets3.begin()+2);
+
+ Double_t bkg2=0;
+ Double_t sigma2=0.;
+ Double_t meanarea2=0.;
+
+ clustSeq.get_median_rho_and_sigma(jets3, range, false, bkg2, sigma2, meanarea2, true);
+ fAODJetBackgroundOut->SetBackground(1,bkg2,sigma2,meanarea2);
+
+ //Get leading track in event
+ AliVParticle *leading = (AliVParticle*)recParticles.At(0);
+
+ fh3CentvsRhoLeadingTrackPt->Fill(cent,bkg2,leading->Pt());
+ fh3CentvsSigmaLeadingTrackPt->Fill(cent,sigma2,leading->Pt());
+ fh3MultvsRhoLeadingTrackPt->Fill(nCh,bkg2,leading->Pt());
+ fh3MultvsSigmaLeadingTrackPt->Fill(nCh,sigma2,leading->Pt());
- if(j==0){
- fh1PtJetsLeadingRecIn->Fill(tmpPt);
- fh2LeadingJetPhiEta->Fill(tmpPhi,tmpEta);
- fh2LeadingJetEtaPt->Fill(tmpEta,tmpPt);
- fh1NConstLeadingRec->Fill(constituents.size());
- fh2NConstLeadingPt->Fill(tmpPt,constituents.size());
- continue;
- }
- fh2JetPhiEta->Fill(tmpRec.Phi(),tmpEta);
- fh2JetEtaPt->Fill(tmpEta,tmpPt);
- Float_t dPhi = phi - tmpPhi;
- if(dPhi>TMath::Pi())dPhi = dPhi - 2.*TMath::Pi();
- if(dPhi<(-1.*TMath::Pi()))dPhi = dPhi + 2.*TMath::Pi();
- Float_t dEta = eta - tmpRec.Eta();
- fh2JetsLeadingPhiEta->Fill(dPhi,dEta);
- fh2JetsLeadingPhiPt->Fill(dPhi,pt);
- fh2JetsLeadingPhiPtW->Fill(dPhi,pt,tmpPt);
- }
- delete recIter;
+
+ //Calculate rho with 4-vector area method for different quadrants with respect to the leading track in the event
+ //exclude 2 leading jets from event
+ //Quadrant 1: |phi_leadingTrack - phi_bkgCluster| < pi/2./2. - R (Near side to leading track)
+ //Quadrant 2: pi/2 - (pi/2./2. - R) < |phi_leadingTrack - phi_bkgCluster| < pi/2 + (pi/2./2. - R) (Orthogonal to leading track)
+ //Quadrant 3: pi - (pi/2/2 - R) < |phi_leadingTrack - phi_bkgCluster| < pi + (pi/2./2. - R) (Away side to leading track)
+ //Quadrant 4: 3/2*pi - (pi/2./2. - R) < |phi_leadingTrack - phi_bkgCluster| < 3/2*pi + (pi/2./2. - R) (Orthogonal to leading track)
+
+ //Assuming R=0.2 for background clusters
+
+ Double_t bkg2Q[4] = {0.};
+ Double_t sigma2Q[4] = {0.};
+ Double_t meanarea2Q[4] = {0.};
+
+ //Get phi of leading track in event
+ Float_t phiLeadingTrack = leading->Phi();
+ Float_t phiStep = (TMath::Pi()/2./2. - 0.2);
+
+ //Quadrant1 - near side
+ phiMin = phiLeadingTrack - phiStep;
+ phiMax = phiLeadingTrack + phiStep;
+ fastjet::RangeDefinition rangeQ1(rapMin,rapMax, phiMin, phiMax);
+ clustSeq.get_median_rho_and_sigma(jets3, rangeQ1, false, bkg2Q[0], sigma2Q[0], meanarea2Q[0], true);
+
+ //Quadrant2 - orthogonal
+ Double_t phiQ2 = phiLeadingTrack + TMath::Pi()/2.;
+ if(phiQ2>TMath::TwoPi()) phiQ2 = phiQ2 - TMath::TwoPi();
+ phiMin = phiQ2 - phiStep;
+ phiMax = phiQ2 + phiStep;
+ fastjet::RangeDefinition rangeQ2(rapMin,rapMax, phiMin, phiMax);
+ clustSeq.get_median_rho_and_sigma(jets3, rangeQ2, false, bkg2Q[1], sigma2Q[1], meanarea2Q[1], true);
+
+ //Quadrant3 - away side
+ Double_t phiQ3 = phiLeadingTrack + TMath::Pi();
+ if(phiQ3>TMath::TwoPi()) phiQ3 = phiQ3 - TMath::TwoPi();
+ phiMin = phiQ3 - phiStep;
+ phiMax = phiQ3 + phiStep;
+ fastjet::RangeDefinition rangeQ3(rapMin,rapMax, phiMin, phiMax);
+ clustSeq.get_median_rho_and_sigma(jets3, rangeQ3, false, bkg2Q[2], sigma2Q[2], meanarea2Q[2], true);
+
+ //Quadrant4 - othogonal
+ Double_t phiQ4 = phiLeadingTrack + 3./2.*TMath::Pi();
+ if(phiQ4>TMath::TwoPi()) phiQ4 = phiQ4 - TMath::TwoPi();
+ phiMin = phiQ4 - phiStep;
+ phiMax = phiQ4 + phiStep;
+ fastjet::RangeDefinition rangeQ4(rapMin,rapMax, phiMin, phiMax);
+ clustSeq.get_median_rho_and_sigma(jets3, rangeQ4, false, bkg2Q[3], sigma2Q[3], meanarea2Q[3], true);
+
+ fh3CentvsRhoLeadingTrackPtQ1->Fill(cent,bkg2Q[0],leading->Pt());
+ fh3CentvsRhoLeadingTrackPtQ2->Fill(cent,bkg2Q[1],leading->Pt());
+ fh3CentvsRhoLeadingTrackPtQ3->Fill(cent,bkg2Q[2],leading->Pt());
+ fh3CentvsRhoLeadingTrackPtQ4->Fill(cent,bkg2Q[3],leading->Pt());
+
+ fh3CentvsSigmaLeadingTrackPtQ1->Fill(cent,sigma2Q[0],leading->Pt());
+ fh3CentvsSigmaLeadingTrackPtQ2->Fill(cent,sigma2Q[1],leading->Pt());
+ fh3CentvsSigmaLeadingTrackPtQ3->Fill(cent,sigma2Q[2],leading->Pt());
+ fh3CentvsSigmaLeadingTrackPtQ4->Fill(cent,sigma2Q[3],leading->Pt());
+
+ fh3MultvsRhoLeadingTrackPtQ1->Fill(nCh,bkg2Q[0],leading->Pt());
+ fh3MultvsRhoLeadingTrackPtQ2->Fill(nCh,bkg2Q[1],leading->Pt());
+ fh3MultvsRhoLeadingTrackPtQ3->Fill(nCh,bkg2Q[2],leading->Pt());
+ fh3MultvsRhoLeadingTrackPtQ4->Fill(nCh,bkg2Q[3],leading->Pt());
+
+ fh3MultvsSigmaLeadingTrackPtQ1->Fill(nCh,sigma2Q[0],leading->Pt());
+ fh3MultvsSigmaLeadingTrackPtQ2->Fill(nCh,sigma2Q[1],leading->Pt());
+ fh3MultvsSigmaLeadingTrackPtQ3->Fill(nCh,sigma2Q[2],leading->Pt());
+ fh3MultvsSigmaLeadingTrackPtQ4->Fill(nCh,sigma2Q[3],leading->Pt());
+
+ fh3CentvsDeltaRhoLeadingTrackPtQ1->Fill(cent,bkg2Q[0]-bkg2,leading->Pt());
+ fh3CentvsDeltaRhoLeadingTrackPtQ2->Fill(cent,bkg2Q[1]-bkg2,leading->Pt());
+ fh3CentvsDeltaRhoLeadingTrackPtQ3->Fill(cent,bkg2Q[2]-bkg2,leading->Pt());
+ fh3CentvsDeltaRhoLeadingTrackPtQ4->Fill(cent,bkg2Q[3]-bkg2,leading->Pt());
+
}
+
+
+
+
- // fill track information
- Int_t nTrackOver = recParticles.GetSize();
+ // fill track information
+ Int_t nTrackOver = recParticles.GetSize();
// do the same for tracks and jets
- if(nTrackOver>0){
- TIterator *recIter = recParticles.MakeIterator();
- AliVParticle *tmpRec = (AliVParticle*)(recIter->Next());
- Float_t pt = tmpRec->Pt();
- // Printf("Leading track p_t %3.3E",pt);
- for(int i = 1;i <= fh2NRecTracksPt->GetNbinsX();i++){
- Float_t ptCut = fh2NRecTracksPt->GetXaxis()->GetBinCenter(i);
- while(pt<ptCut&&tmpRec){
- nTrackOver--;
- tmpRec = (AliVParticle*)(recIter->Next());
- if(tmpRec){
- pt = tmpRec->Pt();
- }
- }
- if(nTrackOver<=0)break;
- fh2NRecTracksPt->Fill(ptCut,nTrackOver);
- }
+
+ if(nTrackOver>0){
+ TIterator *recIter = recParticles.MakeIterator();
+ AliVParticle *tmpRec = (AliVParticle*)(recIter->Next());
+ Float_t pt = tmpRec->Pt();
+
+ // Printf("Leading track p_t %3.3E",pt);
+ for(int i = 1;i <= fh2NRecTracksPt->GetNbinsX();i++){
+ Float_t ptCut = fh2NRecTracksPt->GetXaxis()->GetBinCenter(i);
+ while(pt<ptCut&&tmpRec){
+ nTrackOver--;
+ tmpRec = (AliVParticle*)(recIter->Next());
+ if(tmpRec){
+ pt = tmpRec->Pt();
+ }
+ }
+ if(nTrackOver<=0)break;
+ fh2NRecTracksPt->Fill(ptCut,nTrackOver);
+ }
- recIter->Reset();
- AliVParticle *leading = (AliVParticle*)recParticles.At(0);
- Float_t phi = leading->Phi();
- if(phi<0)phi+=TMath::Pi()*2.;
- Float_t eta = leading->Eta();
- pt = leading->Pt();
- while((tmpRec = (AliVParticle*)(recIter->Next()))){
- Float_t tmpPt = tmpRec->Pt();
- Float_t tmpEta = tmpRec->Eta();
- fh1PtTracksRecIn->Fill(tmpPt);
- fh2TrackEtaPt->Fill(tmpEta,tmpPt);
- if(tmpRec==leading){
- fh1PtTracksLeadingRecIn->Fill(tmpPt);
- fh2LeadingTrackEtaPt->Fill(tmpEta,tmpPt);
- continue;
- }
+ recIter->Reset();
+ AliVParticle *leading = (AliVParticle*)recParticles.At(0);
+ Float_t phi = leading->Phi();
+ if(phi<0)phi+=TMath::Pi()*2.;
+ Float_t eta = leading->Eta();
+ pt = leading->Pt();
+ while((tmpRec = (AliVParticle*)(recIter->Next()))){
+ Float_t tmpPt = tmpRec->Pt();
+ Float_t tmpEta = tmpRec->Eta();
+ fh1PtTracksRecIn->Fill(tmpPt);
+ fh2TrackEtaPt->Fill(tmpEta,tmpPt);
+ if(tmpRec==leading){
+ fh1PtTracksLeadingRecIn->Fill(tmpPt);
+ fh2LeadingTrackEtaPt->Fill(tmpEta,tmpPt);
+ continue;
+ }
// correlation
- Float_t tmpPhi = tmpRec->Phi();
+ Float_t tmpPhi = tmpRec->Phi();
- if(tmpPhi<0)tmpPhi+=TMath::Pi()*2.;
- Float_t dPhi = phi - tmpPhi;
- if(dPhi>TMath::Pi())dPhi = dPhi - 2.*TMath::Pi();
- if(dPhi<(-1.*TMath::Pi()))dPhi = dPhi + 2.*TMath::Pi();
- Float_t dEta = eta - tmpRec->Eta();
- fh2TracksLeadingPhiEta->Fill(dPhi,dEta);
- fh2TracksLeadingPhiPt->Fill(dPhi,pt);
- fh2TracksLeadingPhiPtW->Fill(dPhi,pt,tmpPt);
- }
- delete recIter;
- }
+ if(tmpPhi<0)tmpPhi+=TMath::Pi()*2.;
+ Float_t dPhi = phi - tmpPhi;
+ if(dPhi>TMath::Pi())dPhi = dPhi - 2.*TMath::Pi();
+ if(dPhi<(-1.*TMath::Pi()))dPhi = dPhi + 2.*TMath::Pi();
+ Float_t dEta = eta - tmpRec->Eta();
+ fh2TracksLeadingPhiEta->Fill(dPhi,dEta);
+ fh2TracksLeadingPhiPt->Fill(dPhi,pt);
+ fh2TracksLeadingPhiPtW->Fill(dPhi,pt,tmpPt);
+ }
+ delete recIter;
+ }
- // find the random jets
- vector <fastjet::PseudoJet> inclusiveJetsRan, sortedJetsRan;
- fastjet::ClusterSequence clustSeqRan(inputParticlesRecRan, jetDef);
-
- inclusiveJetsRan = clustSeqRan.inclusive_jets();
- sortedJetsRan = sorted_by_pt(inclusiveJetsRan);
+ // find the random jets
- // fill the jet information from random track
+ fastjet::ClusterSequenceArea clustSeqRan(inputParticlesRecRan, jetDef, areaDef);
+
+ // fill the jet information from random track
+ const vector <fastjet::PseudoJet> &inclusiveJetsRan = clustSeqRan.inclusive_jets();
+ const vector <fastjet::PseudoJet> &sortedJetsRan = sorted_by_pt(inclusiveJetsRan);
fh1NJetsRecRan->Fill(sortedJetsRan.size());
- // loop over all jets an fill information, first on is the leading jet
+ // loop over all jets an fill information, first on is the leading jet
+
+ Int_t nRecOverRan = inclusiveJetsRan.size();
+ Int_t nRecRan = inclusiveJetsRan.size();
- Int_t nRecOverRan = inclusiveJetsRan.size();
- Int_t nRecRan = inclusiveJetsRan.size();
- if(inclusiveJetsRan.size()>0){
- AliAODJet leadingJet (sortedJetsRan[0].px(), sortedJetsRan[0].py(), sortedJetsRan[0].pz(), sortedJetsRan[0].E());
- Float_t pt = leadingJet.Pt();
+ if(inclusiveJetsRan.size()>0){
+ AliAODJet leadingJet (sortedJetsRan[0].px(), sortedJetsRan[0].py(), sortedJetsRan[0].pz(), sortedJetsRan[0].E());
+ Float_t pt = leadingJet.Pt();
- Int_t iCount = 0;
- for(int i = 1;i <= fh2NRecJetsPtRan->GetNbinsX();i++){
- Float_t ptCut = fh2NRecJetsPtRan->GetXaxis()->GetBinCenter(i);
+ Int_t iCount = 0;
+ TLorentzVector vecarearanb;
+
+ for(int i = 1;i <= fh2NRecJetsPtRan->GetNbinsX();i++){
+ Float_t ptCut = fh2NRecJetsPtRan->GetXaxis()->GetBinCenter(i);
while(pt<ptCut&&iCount<nRecRan){
nRecOverRan--;
iCount++;
fh2TracksLeadingJetPhiPtWRan->Fill(dPhi,pt,tmpPt);
}
-
-
+ Int_t nAodOutJetsRan = 0;
+ AliAODJet *aodOutJetRan = 0;
for(int j = 0; j < nRecRan;j++){
AliAODJet tmpRec (sortedJetsRan[j].px(), sortedJetsRan[j].py(), sortedJetsRan[j].pz(), sortedJetsRan[j].E());
Float_t tmpPt = tmpRec.Pt();
fh1PtJetsRecInRan->Fill(tmpPt);
// Fill Spectra with constituents
- vector<fastjet::PseudoJet> constituents = clustSeqRan.constituents(sortedJetsRan[j]);
+ const vector<fastjet::PseudoJet> &constituents = clustSeqRan.constituents(sortedJetsRan[j]);
fh1NConstRecRan->Fill(constituents.size());
fh2NConstPtRan->Fill(tmpPt,constituents.size());
fh2PtNchRan->Fill(nCh,tmpPt);
fh2PtNchNRan->Fill(nCh,tmpPt,constituents.size());
+
+
+ if(tmpPt>fJetOutputMinPt&&fTCAJetsOutRan){
+ aodOutJetRan = new ((*fTCAJetsOutRan)[nAodOutJetsRan++]) AliAODJet(tmpRec);
+ Double_t arearan=clustSeqRan.area(sortedJetsRan[j]);
+ aodOutJetRan->GetRefTracks()->Clear();
+ aodOutJetRan->SetEffArea(arearan,0);
+ fastjet::PseudoJet vecarearan=clustSeqRan.area_4vector(sortedJetsRan[j]);
+ vecarearanb.SetPxPyPzE(vecarearan.px(),vecarearan.py(),vecarearan.pz(),vecarearan.e());
+ aodOutJetRan->SetVectorAreaCharged(&vecarearanb);
+
+ }
+
// correlation
Float_t tmpPhi = tmpRec.Phi();
if(tmpPhi<0)tmpPhi+=TMath::Pi()*2.;
continue;
}
}
- }
-
- if (fDebug > 10)Printf("%s:%d",(char*)__FILE__,__LINE__);
- PostData(1, fHistList);
+
+ if(fAODJetBackgroundOut){
+ Double_t bkg3=0.;
+ Double_t sigma3=0.;
+ Double_t meanarea3=0.;
+ clustSeqRan.get_median_rho_and_sigma(sortedJetsRan ,range, false, bkg3, sigma3, meanarea3, true);
+ fAODJetBackgroundOut->SetBackground(2,bkg3,sigma3,meanarea3);
+ // float areaRandomCone = rRandomCone2 *TMath::Pi();
+ /*
+ fh1BiARandomCones[2]->Fill(ptRandomCone-(bkg3*areaRandomCone));
+ fh1BiARandomConesRan[2]->Fill(ptRandomConeRan-(bkg3*areaRandomCone));
+ */
+ }
+
+
+
+ }
+
+
+ // do the event selection if activated
+ if(fJetTriggerPtCut>0){
+ bool select = false;
+ Float_t minPt = fJetTriggerPtCut;
+ /*
+ // hard coded for now ...
+ // 54.50 44.5 29.5 18.5 for anti-kt rejection 1E-3
+ if(cent<10)minPt = 50;
+ else if(cent<30)minPt = 42;
+ else if(cent<50)minPt = 28;
+ else if(cent<80)minPt = 18;
+ */
+ float rho = 0;
+ if(externalBackground)rho = externalBackground->GetBackground(2);
+ if(fTCAJetsOut){
+ for(int i = 0;i < fTCAJetsOut->GetEntriesFast();i++){
+ AliAODJet *jet = (AliAODJet*)fTCAJetsOut->At(i);
+ Float_t ptSub = jet->Pt() - rho *jet->EffectiveAreaCharged();
+ if(ptSub>=minPt){
+ select = true;
+ break;
+ }
+ }
+ }
+
+ if(select){
+ static AliAODHandler *aodH = dynamic_cast<AliAODHandler*>(AliAnalysisManager::GetAnalysisManager()->GetOutputEventHandler());
+ fh1CentralitySelect->Fill(cent);
+ fh1ZSelect->Fill(zVtx);
+ aodH->SetFillAOD(kTRUE);
+ }
+ }
+ if (fDebug > 2){
+ if(fTCAJetsOut)Printf("%s:%d Rec Jets %d",(char*)__FILE__,__LINE__,fTCAJetsOut->GetEntriesFast());
+ if(fTCAJetsOutRan)Printf("%s:%d Rec Jets Ran %d",(char*)__FILE__,__LINE__,fTCAJetsOutRan->GetEntriesFast());
+ if(fTCARandomConesOut)Printf("%s:%d RC %d",(char*)__FILE__,__LINE__,fTCARandomConesOut->GetEntriesFast());
+ if(fTCARandomConesOutRan)Printf("%s:%d RC Ran %d",(char*)__FILE__,__LINE__,fTCARandomConesOutRan->GetEntriesFast());
+ }
+ PostData(1, fHistList);
}
void AliAnalysisTaskJetCluster::Terminate(Option_t */*option*/)
{
-// Terminate analysis
-//
- if (fDebug > 1) printf("AnalysisJetCluster: Terminate() \n");
+ //
+ // Terminate analysis
+ //
+ if (fDebug > 1) printf("AnalysisJetCluster: Terminate() \n");
+
+ if(fMomResH1Fit) delete fMomResH1Fit;
+ if(fMomResH2Fit) delete fMomResH2Fit;
+ if(fMomResH3Fit) delete fMomResH3Fit;
+
}
Int_t AliAnalysisTaskJetCluster::GetListOfTracks(TList *list,Int_t type){
- if(fDebug>2)Printf("%s:%d Selecting tracks with %d",(char*)__FILE__,__LINE__,type);
+ //
+ // get list of tracks/particles for different types
+ //
+
+ if(fDebug>2) Printf("%s:%d Selecting tracks with %d",(char*)__FILE__,__LINE__,type);
Int_t iCount = 0;
- if(type==kTrackAOD){
- AliAODEvent *aod = 0;
- if(fUseAODTrackInput)aod = dynamic_cast<AliAODEvent*>(InputEvent());
- else aod = AODEvent();
- if(!aod){
- return iCount;
+ if(type==kTrackAOD || type==kTrackAODextra || type==kTrackAODextraonly || type==kTrackAODMCextra || type==kTrackAODMCextraonly){
+
+ if(type!=kTrackAODextraonly && type!=kTrackAODMCextraonly) {
+ AliAODEvent *aod = 0;
+ if(fUseAODTrackInput)aod = dynamic_cast<AliAODEvent*>(InputEvent());
+ else aod = AODEvent();
+ if(!aod){
+ if(fDebug>2)Printf("%s:%d No AOD",(char*)__FILE__,__LINE__);
+ return iCount;
+ }
+
+ for(int it = 0;it < aod->GetNumberOfTracks();++it){
+ AliAODTrack *tr = aod->GetTrack(it);
+ Bool_t bGood = false;
+ if(fFilterType == 0)bGood = true;
+ else if(fFilterType == 1)bGood = tr->IsHybridTPCConstrainedGlobal();
+ else if(fFilterType == 2)bGood = tr->IsHybridGlobalConstrainedGlobal();
+ if((fFilterMask>0)&&((!tr->TestFilterBit(fFilterMask)||(!bGood)))){
+ if(fDebug>10)Printf("%s:%d Not matching filter %d/%d %d/%d",(char*)__FILE__,__LINE__,it,aod->GetNumberOfTracks(),fFilterMask,tr->GetFilterMap());
+ continue;
+ }
+
+ // heavy flavor jets
+ if(fFilterMask==528 && fUseHFcuts){
+ Double_t ntpcClus = tr->GetTPCNcls();
+ Double_t trPt=tr->Pt();
+ TFormula NTPCClsCut("f1NClustersTPCLinearPtDep","70.+30./20.*x");
+
+ if (trPt <= 20. && (ntpcClus < NTPCClsCut.Eval(trPt))) continue;
+ else if (trPt > 20. && ntpcClus < 100) continue;
+
+ if (AvoidDoubleCountingHF(aod,tr)) continue;
+ }
+ //
+
+ if(fRequireITSRefit){if((tr->GetStatus()&AliESDtrack::kITSrefit)==0)continue;}
+ if (fApplySharedClusterCut) {
+ Double_t frac = Double_t(tr->GetTPCnclsS()) /Double_t(tr->GetTPCncls());
+ if (frac > 0.4) continue;
+ }
+ if(TMath::Abs(tr->Eta())>fTrackEtaWindow){
+ if(fDebug>10)Printf("%s:%d Not matching eta %d/%d",(char*)__FILE__,__LINE__,it,aod->GetNumberOfTracks());
+ continue;
+ }
+ if(tr->Pt()<fTrackPtCut){
+ if(fDebug>10)Printf("%s:%d Not matching pt %d/%d",(char*)__FILE__,__LINE__,it,aod->GetNumberOfTracks());
+ continue;
+ }
+ if(fDebug>10)Printf("%s:%d MATCHED %d/%d",(char*)__FILE__,__LINE__,it,aod->GetNumberOfTracks());
+ list->Add(tr);
+ iCount++;
+ }
}
- for(int it = 0;it < aod->GetNumberOfTracks();++it){
- AliAODTrack *tr = aod->GetTrack(it);
- if((fFilterMask>0)&&!(tr->TestFilterBit(fFilterMask)))continue;
- if(TMath::Abs(tr->Eta())>0.9)continue;
- // if(tr->Pt()<0.3)continue;
- list->Add(tr);
- iCount++;
+ if(type==kTrackAODextra || type==kTrackAODextraonly) {
+ AliAODEvent *aod = 0;
+ if(fUseAODTrackInput)aod = dynamic_cast<AliAODEvent*>(InputEvent());
+ else aod = AODEvent();
+
+ if(!aod){
+ return iCount;
+ }
+ TClonesArray *aodExtraTracks = dynamic_cast<TClonesArray*>(aod->FindListObject("aodExtraTracks"));
+ if(!aodExtraTracks)return iCount;
+ for(int it =0; it<aodExtraTracks->GetEntries(); it++) {
+ AliVParticle *track = dynamic_cast<AliVParticle*> ((*aodExtraTracks)[it]);
+ if (!track) continue;
+
+ AliAODTrack *trackAOD = dynamic_cast<AliAODTrack*> (track);
+ if(!trackAOD)continue;
+ Bool_t bGood = false;
+ if(fFilterType == 0)bGood = true;
+ else if(fFilterType == 1)bGood = trackAOD->IsHybridTPCConstrainedGlobal();
+ else if(fFilterType == 2)bGood = trackAOD->IsHybridGlobalConstrainedGlobal();
+ if((fFilterMask>0)&&((!trackAOD->TestFilterBit(fFilterMask)||(!bGood))))continue;
+ if(fRequireITSRefit){if((trackAOD->GetStatus()&AliESDtrack::kITSrefit)==0)continue;}
+ if (fApplySharedClusterCut) {
+ Double_t frac = Double_t(trackAOD->GetTPCnclsS()) /Double_t(trackAOD->GetTPCncls());
+ if (frac > 0.4) continue;
+ }
+
+
+ if(TMath::Abs(trackAOD->Eta())>fTrackEtaWindow) continue;
+ if(trackAOD->Pt()<fTrackPtCut) continue;
+ if(fDebug) printf("pt extra track %.2f \n", trackAOD->Pt());
+ list->Add(trackAOD);
+ iCount++;
+ }
}
+
+ if(type==kTrackAODMCextra || type==kTrackAODMCextraonly) { //embed generator level particles
+ AliAODEvent *aod = 0;
+ if(fUseAODTrackInput)aod = dynamic_cast<AliAODEvent*>(InputEvent());
+ else aod = AODEvent();
+ if(!aod){
+ return iCount;
+ }
+ TClonesArray *aodExtraTracks = dynamic_cast<TClonesArray*>(aod->FindListObject("aodExtraMCparticles"));
+ if(!aodExtraTracks)return iCount;
+ for(int it =0; it<aodExtraTracks->GetEntries(); it++) {
+ AliVParticle *track = dynamic_cast<AliVParticle*> ((*aodExtraTracks)[it]);
+ AliAODMCParticle *partmc = dynamic_cast<AliAODMCParticle*> ((*aodExtraTracks)[it]);
+ if (!track) {
+ if(fDebug>10) printf("track %d does not exist\n",it);
+ continue;
+ }
+
+ if(!partmc) continue;
+ if(!partmc->IsPhysicalPrimary())continue;
+
+ if (track->Pt()<fTrackPtCut) {
+ if(fDebug>10) printf("track %d has too low pt %.2f\n",it,track->Pt());
+ continue;
+ }
+
+ /*
+ AliAODTrack *trackAOD = dynamic_cast<AliAODTrack*>((*aodExtraTracks)[it]);//(track);
+
+ if(!trackAOD) {
+ if(fDebug>10) printf("trackAOD %d does not exist\n",it);
+ continue;
+ }
+
+ trackAOD->SetFlags(AliESDtrack::kEmbedded);
+ trackAOD->SetFilterMap(fFilterMask);
+ */
+ if(fDebug>10) printf("pt extra track %.2f \n", track->Pt());
+
+ if(TMath::Abs(track->Eta())>fTrackEtaWindow) continue;
+ if(track->Pt()<fTrackPtCut) continue;
+ list->Add(track);
+
+ iCount++;
+ }
+ }
+
}
else if (type == kTrackKineAll||type == kTrackKineCharged){
AliMCEvent* mcEvent = MCEvent();
if(!mcEvent->IsPhysicalPrimary(it))continue;
AliMCParticle* part = (AliMCParticle*)mcEvent->GetTrack(it);
if(type == kTrackKineAll){
+ if(part->Pt()<fTrackPtCut)continue;
list->Add(part);
iCount++;
}
else if(type == kTrackKineCharged){
if(part->Particle()->GetPDG()->Charge()==0)continue;
+ if(part->Pt()<fTrackPtCut)continue;
list->Add(part);
iCount++;
}
AliAODMCParticle *part = (AliAODMCParticle*)(tca->At(it));
if(!part->IsPhysicalPrimary())continue;
if(type == kTrackAODMCAll){
+ if(part->Pt()<fTrackPtCut)continue;
list->Add(part);
iCount++;
}
else if (type == kTrackAODMCCharged || type == kTrackAODMCChargedAcceptance ){
if(part->Charge()==0)continue;
+ if(part->Pt()<fTrackPtCut)continue;
if(kTrackAODMCCharged){
list->Add(part);
}
else {
- if(TMath::Abs(part->Eta())>0.9)continue;
+ if(TMath::Abs(part->Eta())>fTrackEtaWindow)continue;
list->Add(part);
}
iCount++;
}
}
}// AODMCparticle
+ else if (type == kTrackAODMCHF){
+
+ AliAODEvent *aod = 0;
+ if(fUseAODMCInput)aod = dynamic_cast<AliAODEvent*>(InputEvent());
+ else aod = AODEvent();
+ if(!aod)return iCount;
+ TClonesArray *tca = dynamic_cast<TClonesArray*>(aod->FindListObject(AliAODMCParticle::StdBranchName()));
+ if(!tca)return iCount;
+ for(int it = 0;it < tca->GetEntriesFast();++it){
+ AliAODMCParticle *part = (AliAODMCParticle*)(tca->At(it));
+ if(!part) continue;
+ int partpdg= part->PdgCode();
+ if(!part->IsPhysicalPrimary() && !IsBMeson(partpdg) && !IsDMeson(partpdg) )continue;
+
+ if (IsBMeson(partpdg) || IsDMeson(partpdg)) {
+ iCount+= AddDaughters( list , part,tca);
+ }
+ else {
+
+ if(part->Pt()<fTrackPtCut) continue;
+ if(TMath::Abs(part->Eta())>fTrackEtaWindow) continue;
+ if(part->Charge()==0) continue;
+
+ if((part->Pt()>=fTrackPtCut) && (TMath::Abs(part->Eta())<=fTrackEtaWindow) && (part->Charge()!=0))list->Add(part);
+ iCount++;
+ }
+ }
+ }
+
list->Sort();
return iCount;
+}
+
+Int_t AliAnalysisTaskJetCluster::AddDaughters(TList * list, AliAODMCParticle *part, TClonesArray * tca){
+ Int_t count=0;
+ Int_t nDaugthers = part->GetNDaughters();
+ for(Int_t i=0;i< nDaugthers;++i){
+ AliAODMCParticle *partdaughter = (AliAODMCParticle*)(tca->At(i));
+ if(!partdaughter) continue;
+ if(partdaughter->Pt()<fTrackPtCut)continue;
+ if(TMath::Abs(partdaughter->Eta())>fTrackEtaWindow)continue;
+ if(partdaughter->Charge()==0)continue;
+
+ if(!IsDMeson(partdaughter->PdgCode()) && !IsBMeson(partdaughter->PdgCode()) ){
+ list->Add(partdaughter);
+ count++;
+ }
+ else count+=AddDaughters(list,part,tca);
+ }
+return count;
+}
+
+
+Bool_t AliAnalysisTaskJetCluster::AvoidDoubleCountingHF(AliAODEvent *aod, AliAODTrack *tr1){
+
+ if(!(tr1->TestFilterBit(BIT(9)))) return kFALSE;
+
+ Int_t idtr1 = tr1->GetID();
+
+ for(int jt = 0;jt < aod->GetNumberOfTracks();++jt){
+
+ const AliAODTrack *tr2 = aod->GetTrack(jt);
+ Int_t idtr2 = tr2->GetID();
+
+ if (!(tr2->TestFilterBit(BIT(4)))) continue;
+ if (idtr1==(idtr2+1)*-1.) return kTRUE;
+
+ }
+ return kFALSE;
+}
+void AliAnalysisTaskJetCluster::LoadTrPtResolutionRootFileFromOADB() {
+
+ if (!gGrid) {
+ AliInfo("Trying to connect to AliEn ...");
+ TGrid::Connect("alien://");
+ }
+
+ TFile *f = TFile::Open(fPathTrPtResolution.Data());
+
+ if(!f)return;
+
+ TProfile *fProfPtPtSigma1PtGlobSt = (TProfile*)f->Get("fProfPtPtSigma1PtGlobSt");
+ TProfile *fProfPtPtSigma1PtGlobCnoITS = (TProfile*)f->Get("fProfPtPtSigma1PtGlobCnoITS");
+ TProfile *fProfPtPtSigma1PtGlobCnoSPD = (TProfile*)f->Get("fProfPtPtSigma1PtGlobCnoSPD");
+
+ SetSmearResolution(kTRUE);
+ SetMomentumResolutionHybrid(fProfPtPtSigma1PtGlobSt,fProfPtPtSigma1PtGlobCnoITS,fProfPtPtSigma1PtGlobCnoSPD);
+
+
+}
+
+void AliAnalysisTaskJetCluster::LoadTrEfficiencyRootFileFromOADB() {
+
+ if (!gGrid) {
+ AliInfo("Trying to connect to AliEn ...");
+ TGrid::Connect("alien://");
+ }
+
+ TFile *f = TFile::Open(fPathTrEfficiency.Data());
+ if(!f)return;
+
+ TH1D *hEffPosGlobSt = (TH1D*)f->Get("hEffPosGlobSt");
+ TH1D *hEffPosGlobCnoITS = (TH1D*)f->Get("hEffPosGlobCnoITS");
+ TH1D *hEffPosGlobCnoSPD = (TH1D*)f->Get("hEffPosGlobCnoSPD");
+
+ SetDiceEfficiency(kTRUE);
+
+ if(fChangeEfficiencyFraction>0.) {
+
+ TH1D *hEffPosGlobStMin = (TH1D*)hEffPosGlobSt->Clone("hEffPosGlobStMin");
+
+ for(int bin=1; bin<=hEffPosGlobSt->GetNbinsX(); bin++) {
+ Double_t content = hEffPosGlobSt->GetBinContent(bin);
+ hEffPosGlobStMin->SetBinContent(bin,content-fChangeEfficiencyFraction);
+ }
+
+ SetEfficiencyHybrid(hEffPosGlobStMin,hEffPosGlobCnoITS,hEffPosGlobCnoSPD);
+
+ }
+ else
+ SetEfficiencyHybrid(hEffPosGlobSt,hEffPosGlobCnoITS,hEffPosGlobCnoSPD);
+
+}
+
+void AliAnalysisTaskJetCluster::SetMomentumResolutionHybrid(TProfile *p1, TProfile *p2, TProfile *p3) {
+
+ //
+ // set mom res profiles
+ //
+
+ if(fMomResH1) delete fMomResH1;
+ if(fMomResH2) delete fMomResH2;
+ if(fMomResH3) delete fMomResH3;
+
+ fMomResH1 = new TProfile(*p1);//(TProfile*)p1->Clone("fMomResH1");
+ fMomResH2 = new TProfile(*p2);//(TProfile*)p2->Clone("fMomResH2");
+ fMomResH3 = new TProfile(*p3);//(TProfile*)p3->Clone("fMomResH3");
+
+}
+
+void AliAnalysisTaskJetCluster:: SetEfficiencyHybrid(TH1 *h1, TH1 *h2, TH1 *h3) {
+ //
+ // set tracking efficiency histos
+ //
+
+ fhEffH1 = (TH1*)h1->Clone("fhEffH1");
+ fhEffH2 = (TH1*)h2->Clone("fhEffH2");
+ fhEffH3 = (TH1*)h3->Clone("fhEffH3");
+}
+
+Double_t AliAnalysisTaskJetCluster::GetMomentumSmearing(Int_t cat, Double_t pt) {
+
+ //
+ // Get smearing on generated momentum
+ //
+
+ //printf("GetMomentumSmearing for cat %d and pt = %f \n",cat,pt);
+
+ TProfile *fMomRes = 0x0;
+ if(cat==1) fMomRes = (TProfile*)fMomResH1->Clone("fMomRes");
+ if(cat==2) fMomRes = (TProfile*)fMomResH2->Clone("fMomRes");
+ if(cat==3) fMomRes = (TProfile*)fMomResH3->Clone("fMomRes");
+
+ if(!fMomRes) {
+ return 0.;
+ }
+
+
+ Double_t smear = 0.;
+
+ if(pt>20.) {
+ if(cat==1 && fMomResH1Fit) smear = fMomResH1Fit->Eval(pt);
+ if(cat==2 && fMomResH2Fit) smear = fMomResH2Fit->Eval(pt);
+ if(cat==3 && fMomResH3Fit) smear = fMomResH3Fit->Eval(pt);
+ }
+ else {
+
+ Int_t bin = fMomRes->FindBin(pt);
+
+ smear = fRandom->Gaus(fMomRes->GetBinContent(bin),fMomRes->GetBinError(bin));
+
+ }
+
+ if(fMomRes) delete fMomRes;
+
+ return smear;
+}
+
+void AliAnalysisTaskJetCluster::FitMomentumResolution() {
+ //
+ // Fit linear function on momentum resolution at high pT
+ //
+
+ if(!fMomResH1Fit && fMomResH1) {
+ fMomResH1Fit = new TF1("fMomResH1Fit","[0]+[1]*x",0.,200.);
+ fMomResH1->Fit(fMomResH1Fit,"LL V0","",5.,30.);
+ fMomResH1Fit ->SetRange(5.,100.);
+ }
+
+ if(!fMomResH2Fit && fMomResH2) {
+ fMomResH2Fit = new TF1("fMomResH2Fit","[0]+[1]*x",0.,200.);
+ fMomResH2->Fit(fMomResH2Fit,"LL V0","",5.,30.);
+ fMomResH2Fit ->SetRange(5.,100.);
+ }
+
+ if(!fMomResH3Fit && fMomResH3) {
+ fMomResH3Fit = new TF1("fMomResH3Fit","[0]+[1]*x",0.,200.);
+ fMomResH3->Fit(fMomResH3Fit,"LL V0","",5.,30.);
+ fMomResH3Fit ->SetRange(5.,100.);
+ }
}
/*
-Int_t AliAnalysisTaskJetCluster::AddParticlesFastJet(TList &particles,vector<fastjet::PseudoJet> &inputParticles){
+ Int_t AliAnalysisTaskJetCluster::AddParticlesFastJet(TList &particles,vector<fastjet::PseudoJet> &inputParticles){
for(int i = 0; i < particles.GetEntries(); i++){
- AliVParticle *vp = (AliVParticle*)particles.At(i);
- // Carefull energy is not well determined in real data, should not matter for p_T scheme?
- fastjet::PseudoJet jInp(vp->Px(),vp->Py(),vp->Pz(),vp->E());
- jInp.set_user_index(i);
- inputParticles.push_back(jInp);
+ AliVParticle *vp = (AliVParticle*)particles.At(i);
+ // Carefull energy is not well determined in real data, should not matter for p_T scheme?
+ fastjet::PseudoJet jInp(vp->Px(),vp->Py(),vp->Pz(),vp->E());
+ jInp.set_user_index(i);
+ inputParticles.push_back(jInp);
}
return 0;
-}
+ }
*/
+
+
+bool AliAnalysisTaskJetCluster::IsBMeson(int pc){
+ int bPdG[] = {511,521,10511,10521,513,523,10513,10523,20513,20523,20513,20523,515,525,531,
+ 10531,533,10533,20533,535,541,10541,543,10543,20543,545,551,10551,100551,
+ 110551,200551,210551,553,10553,20553,30553,100553,110553,120553,130553,200553,210553,220553,
+ 300553,9000533,9010553,555,10555,20555,100555,110555,120555,200555,557,100557};
+ for(int i=0;i< (int)(sizeof(bPdG)/sizeof(int));++i) if(abs(pc) == bPdG[i]) return true;
+return false;
+}
+bool AliAnalysisTaskJetCluster::IsDMeson(int pc){
+ int bPdG[] = {411,421,10411,10421,413,423,10413,10423,20431,20423,415,
+ 425,431,10431,433,10433,20433,435,441,10441,100441,443,10443,20443,
+ 100443,30443,9000443,9010443,9020443,445,100445};
+ for(int i=0;i< (int)(sizeof(bPdG)/sizeof(int));++i) if(abs(pc) == bPdG[i]) return true;
+return false;
+}
+