#include <AliAODEvent.h>
#include <AliAODTrack.h>
#include <AliOADBContainer.h>
+//#include <AliVEventHandler.h>
+#include <AliInputEventHandler.h>
// emcal jet framework includes
#include <AliPicoTrack.h>
#include <AliEmcalJet.h>
ClassImp(AliAnalysisTaskJetV2)
AliAnalysisTaskJetV2::AliAnalysisTaskJetV2() : AliAnalysisTaskEmcalJet("AliAnalysisTaskJetV2", kTRUE),
- fDebug(0), fRunToyMC(kFALSE), fLocalInit(0), fAttachToEvent(kTRUE), fFillHistograms(kTRUE), fFillQAHistograms(kTRUE), fReduceBinsXByFactor(-1.), fReduceBinsYByFactor(-1.), fNoEventWeightsForQC(kTRUE), fCentralityClasses(0), fExpectedRuns(0), fExpectedSemiGoodRuns(0), fUserSuppliedV2(0), fUserSuppliedV3(0), fUserSuppliedR2(0), fUserSuppliedR3(0), fTracksCont(0), fClusterCont(0), fJetsCont(0), fLeadingJet(0), fNAcceptedTracks(0), fNAcceptedTracksQCn(0), fFitModulationType(kNoFit), fFitGoodnessTest(kChi2Poisson), fQCRecovery(kTryFit), fUsePtWeight(kTRUE), fUsePtWeightErrorPropagation(kTRUE), fDetectorType(kVZEROComb), fAnalysisType( kCharged), fFitModulationOptions("QWLI"), fRunModeType(kGrid), fDataType(kESD), fCollisionType(kPbPb), fRandom(0), fRunNumber(-1), fMappedRunNumber(0), fInCentralitySelection(-1), fFitModulation(0), fFitControl(0), fMinPvalue(0.01), fMaxPvalue(1), fNameSmallRho(""), fCachedRho(0), fSoftTrackMinPt(0.15), fSoftTrackMaxPt(5.), fSemiGoodJetMinPhi(0.), fSemiGoodJetMaxPhi(4.), fSemiGoodTrackMinPhi(0.), fSemiGoodTrackMaxPhi(4.), fAbsVertexZ(10), fHistCentrality(0), fHistVertexz(0), fHistRunnumbersPhi(0), fHistRunnumbersEta(0), fHistPvalueCDFROOT(0), fHistPvalueCDFROOTCent(0), fHistChi2ROOTCent(0), fHistPChi2Root(0), fHistPvalueCDF(0), fHistPvalueCDFCent(0), fHistChi2Cent(0), fHistPChi2(0), fHistKolmogorovTest(0), fHistKolmogorovTestCent(0), fHistPKolmogorov(0), fHistRhoStatusCent(0), fHistUndeterminedRunQA(0), fMinDisanceRCtoLJ(0), fMaxCones(-1), fExcludeLeadingJetsFromFit(1.), fRebinSwapHistoOnTheFly(kTRUE), fPercentageOfFits(10.), fOutputList(0), fOutputListGood(0), fOutputListBad(0), fHistAnalysisSummary(0), fHistSwap(0), fProfV2(0), fProfV2Cumulant(0), fProfV3(0), fProfV3Cumulant(0), fHistPsiControl(0), fHistPsiSpread(0), fHistPsiVZEROA(0), fHistPsiVZEROC(0), fHistPsiVZERO(0), fHistPsiTPC(0), fHistPsiVZEROAV0M(0), fHistPsiVZEROCV0M(0), fHistPsiVZEROVV0M(0), fHistPsiTPCV0M(0), fHistPsiVZEROATRK(0), fHistPsiVZEROCTRK(0), fHistPsiVZEROTRK(0), fHistPsiTPCTRK(0), fHistRhoVsMult(0), fHistRhoVsCent(0), fHistRhoAVsMult(0), fHistRhoAVsCent(0), fVZEROgainEqualization(0x0), fVZEROgainEqualizationPerRing(kFALSE), fChi2A(0x0), fChi2C(0x0), fChi3A(0x0), fChi3C(0x0), fOADB(0x0)
+ fRunToyMC(kFALSE), fLocalInit(0), fAttachToEvent(kTRUE), fFillHistograms(kTRUE), fFillQAHistograms(kTRUE), fReduceBinsXByFactor(-1.), fReduceBinsYByFactor(-1.), fNoEventWeightsForQC(kTRUE), fCentralityClasses(0), fExpectedRuns(0), fExpectedSemiGoodRuns(0), fUserSuppliedV2(0), fUserSuppliedV3(0), fUserSuppliedR2(0), fUserSuppliedR3(0), fEventPlaneWeights(0), fAcceptanceWeights(kFALSE), fEventPlaneWeight(1.), fTracksCont(0), fClusterCont(0), fJetsCont(0), fLeadingJet(0), fLeadingJetAfterSub(0), fNAcceptedTracks(0), fNAcceptedTracksQCn(0), fFitModulationType(kNoFit), fFitGoodnessTest(kChi2Poisson), fQCRecovery(kTryFit), fUsePtWeight(kTRUE), fUsePtWeightErrorPropagation(kTRUE), fDetectorType(kVZEROComb), fAnalysisType(kCharged), fFitModulationOptions("QWLI"), fRunModeType(kGrid), fDataType(kESD), fCollisionType(kPbPb), fRandom(0), fRunNumber(-1), fMappedRunNumber(0), fInCentralitySelection(-1), fFitModulation(0), fFitControl(0), fMinPvalue(0.01), fMaxPvalue(1), fNameSmallRho(""), fCachedRho(0), fSoftTrackMinPt(0.15), fSoftTrackMaxPt(5.), fSemiGoodJetMinPhi(0.), fSemiGoodJetMaxPhi(4.), fSemiGoodTrackMinPhi(0.), fSemiGoodTrackMaxPhi(4.), fAbsVertexZ(10), fHistCentrality(0), fHistCentralityPercIn(0), fHistCentralityPercOut(0), fHistCentralityPercLost(0), fHistVertexz(0), fHistRunnumbersPhi(0), fHistRunnumbersEta(0), fHistPvalueCDFROOT(0), fHistPvalueCDFROOTCent(0), fHistChi2ROOTCent(0), fHistPChi2Root(0), fHistPvalueCDF(0), fHistPvalueCDFCent(0), fHistChi2Cent(0), fHistPChi2(0), fHistKolmogorovTest(0), fHistKolmogorovTestCent(0), fHistPKolmogorov(0), fHistRhoStatusCent(0), fHistUndeterminedRunQA(0), fMinDisanceRCtoLJ(0), fMaxCones(-1), fExcludeLeadingJetsFromFit(1.), fRebinSwapHistoOnTheFly(kTRUE), fPercentageOfFits(10.), fOutputList(0), fOutputListGood(0), fOutputListBad(0), fHistAnalysisSummary(0), fHistSwap(0), fProfV2(0), fProfV2Cumulant(0), fProfV3(0), fProfV3Cumulant(0), fHistPsiControl(0), fHistPsiSpread(0), fHistPsiVZEROA(0), fHistPsiVZEROC(0), fHistPsiVZERO(0), fHistPsiTPC(0), fHistPsiVZEROAV0M(0), fHistPsiVZEROCV0M(0), fHistPsiVZEROVV0M(0), fHistPsiTPCV0M(0), fHistPsiVZEROATRK(0), fHistPsiVZEROCTRK(0), fHistPsiVZEROTRK(0), fHistPsiTPCTRK(0), fHistRhoVsMult(0), fHistRhoVsCent(0), fHistRhoAVsMult(0), fHistRhoAVsCent(0), fVZEROgainEqualization(0x0), fVZEROgainEqualizationPerRing(kFALSE), fChi2A(0x0), fChi2C(0x0), fChi3A(0x0), fChi3C(0x0), fOADB(0x0)
{
for(Int_t i(0); i < 10; i++) {
fProfV2Resolution[i] = 0;
fHistClusterPt[i] = 0;
fHistClusterEtaPhi[i] = 0;
fHistClusterEtaPhiWeighted[i] = 0;
+ fHistTriggerQAIn[i] = 0;
+ fHistTriggerQAOut[i] = 0;
fHistPsiTPCLeadingJet[i] = 0;
fHistPsiVZEROALeadingJet[i] = 0;
fHistPsiVZEROCLeadingJet[i] = 0;
fHistPsiVZEROCombLeadingJet[i] = 0;
fHistPsi2Correlation[i] = 0;
+ fHistLeadingJetBackground[i] = 0;
fHistRhoPackage[i] = 0;
fHistRho[i] = 0;
fHistRCPhiEta[i] = 0;
}
//_____________________________________________________________________________
AliAnalysisTaskJetV2::AliAnalysisTaskJetV2(const char* name, runModeType type) : AliAnalysisTaskEmcalJet(name, kTRUE),
- fDebug(0), fRunToyMC(kFALSE), fLocalInit(0), fAttachToEvent(kTRUE), fFillHistograms(kTRUE), fFillQAHistograms(kTRUE), fReduceBinsXByFactor(-1.), fReduceBinsYByFactor(-1.), fNoEventWeightsForQC(kTRUE), fCentralityClasses(0), fExpectedRuns(0), fExpectedSemiGoodRuns(0), fUserSuppliedV2(0), fUserSuppliedV3(0), fUserSuppliedR2(0), fUserSuppliedR3(0), fTracksCont(0), fClusterCont(0), fJetsCont(0), fLeadingJet(0), fNAcceptedTracks(0), fNAcceptedTracksQCn(0), fFitModulationType(kNoFit), fFitGoodnessTest(kChi2Poisson), fQCRecovery(kTryFit), fUsePtWeight(kTRUE), fUsePtWeightErrorPropagation(kTRUE), fDetectorType(kVZEROComb), fAnalysisType(kCharged), fFitModulationOptions("QWLI"), fRunModeType(type), fDataType(kESD), fCollisionType(kPbPb), fRandom(0), fRunNumber(-1), fMappedRunNumber(0), fInCentralitySelection(-1), fFitModulation(0), fFitControl(0), fMinPvalue(0.01), fMaxPvalue(1), fNameSmallRho(""), fCachedRho(0), fSoftTrackMinPt(0.15), fSoftTrackMaxPt(5.), fSemiGoodJetMinPhi(0.), fSemiGoodJetMaxPhi(4.), fSemiGoodTrackMinPhi(0.), fSemiGoodTrackMaxPhi(4.), fAbsVertexZ(10), fHistCentrality(0), fHistVertexz(0), fHistRunnumbersPhi(0), fHistRunnumbersEta(0), fHistPvalueCDFROOT(0), fHistPvalueCDFROOTCent(0), fHistChi2ROOTCent(0), fHistPChi2Root(0), fHistPvalueCDF(0), fHistPvalueCDFCent(0), fHistChi2Cent(0), fHistPChi2(0), fHistKolmogorovTest(0), fHistKolmogorovTestCent(0), fHistPKolmogorov(0), fHistRhoStatusCent(0), fHistUndeterminedRunQA(0), fMinDisanceRCtoLJ(0), fMaxCones(-1), fExcludeLeadingJetsFromFit(1.), fRebinSwapHistoOnTheFly(kTRUE), fPercentageOfFits(10.), fOutputList(0), fOutputListGood(0), fOutputListBad(0), fHistAnalysisSummary(0), fHistSwap(0), fProfV2(0), fProfV2Cumulant(0), fProfV3(0), fProfV3Cumulant(0), fHistPsiControl(0), fHistPsiSpread(0), fHistPsiVZEROA(0), fHistPsiVZEROC(0), fHistPsiVZERO(0), fHistPsiTPC(0), fHistPsiVZEROAV0M(0), fHistPsiVZEROCV0M(0), fHistPsiVZEROVV0M(0), fHistPsiTPCV0M(0), fHistPsiVZEROATRK(0), fHistPsiVZEROCTRK(0), fHistPsiVZEROTRK(0), fHistPsiTPCTRK(0), fHistRhoVsMult(0), fHistRhoVsCent(0), fHistRhoAVsMult(0), fHistRhoAVsCent(0), fVZEROgainEqualization(0x0), fVZEROgainEqualizationPerRing(kFALSE), fChi2A(0x0), fChi2C(0x0), fChi3A(0x0), fChi3C(0x0), fOADB(0x0)
+ fRunToyMC(kFALSE), fLocalInit(0), fAttachToEvent(kTRUE), fFillHistograms(kTRUE), fFillQAHistograms(kTRUE), fReduceBinsXByFactor(-1.), fReduceBinsYByFactor(-1.), fNoEventWeightsForQC(kTRUE), fCentralityClasses(0), fExpectedRuns(0), fExpectedSemiGoodRuns(0), fUserSuppliedV2(0), fUserSuppliedV3(0), fUserSuppliedR2(0), fUserSuppliedR3(0), fEventPlaneWeights(0), fAcceptanceWeights(kFALSE), fEventPlaneWeight(1.), fTracksCont(0), fClusterCont(0), fJetsCont(0), fLeadingJet(0), fLeadingJetAfterSub(0), fNAcceptedTracks(0), fNAcceptedTracksQCn(0), fFitModulationType(kNoFit), fFitGoodnessTest(kChi2Poisson), fQCRecovery(kTryFit), fUsePtWeight(kTRUE), fUsePtWeightErrorPropagation(kTRUE), fDetectorType(kVZEROComb), fAnalysisType(kCharged), fFitModulationOptions("QWLI"), fRunModeType(type), fDataType(kESD), fCollisionType(kPbPb), fRandom(0), fRunNumber(-1), fMappedRunNumber(0), fInCentralitySelection(-1), fFitModulation(0), fFitControl(0), fMinPvalue(0.01), fMaxPvalue(1), fNameSmallRho(""), fCachedRho(0), fSoftTrackMinPt(0.15), fSoftTrackMaxPt(5.), fSemiGoodJetMinPhi(0.), fSemiGoodJetMaxPhi(4.), fSemiGoodTrackMinPhi(0.), fSemiGoodTrackMaxPhi(4.), fAbsVertexZ(10), fHistCentrality(0), fHistCentralityPercIn(0), fHistCentralityPercOut(0), fHistCentralityPercLost(0), fHistVertexz(0), fHistRunnumbersPhi(0), fHistRunnumbersEta(0), fHistPvalueCDFROOT(0), fHistPvalueCDFROOTCent(0), fHistChi2ROOTCent(0), fHistPChi2Root(0), fHistPvalueCDF(0), fHistPvalueCDFCent(0), fHistChi2Cent(0), fHistPChi2(0), fHistKolmogorovTest(0), fHistKolmogorovTestCent(0), fHistPKolmogorov(0), fHistRhoStatusCent(0), fHistUndeterminedRunQA(0), fMinDisanceRCtoLJ(0), fMaxCones(-1), fExcludeLeadingJetsFromFit(1.), fRebinSwapHistoOnTheFly(kTRUE), fPercentageOfFits(10.), fOutputList(0), fOutputListGood(0), fOutputListBad(0), fHistAnalysisSummary(0), fHistSwap(0), fProfV2(0), fProfV2Cumulant(0), fProfV3(0), fProfV3Cumulant(0), fHistPsiControl(0), fHistPsiSpread(0), fHistPsiVZEROA(0), fHistPsiVZEROC(0), fHistPsiVZERO(0), fHistPsiTPC(0), fHistPsiVZEROAV0M(0), fHistPsiVZEROCV0M(0), fHistPsiVZEROVV0M(0), fHistPsiTPCV0M(0), fHistPsiVZEROATRK(0), fHistPsiVZEROCTRK(0), fHistPsiVZEROTRK(0), fHistPsiTPCTRK(0), fHistRhoVsMult(0), fHistRhoVsCent(0), fHistRhoAVsMult(0), fHistRhoAVsCent(0), fVZEROgainEqualization(0x0), fVZEROgainEqualizationPerRing(kFALSE), fChi2A(0x0), fChi2C(0x0), fChi3A(0x0), fChi3C(0x0), fOADB(0x0)
{
for(Int_t i(0); i < 10; i++) {
fProfV2Resolution[i] = 0;
fHistClusterPt[i] = 0;
fHistClusterEtaPhi[i] = 0;
fHistClusterEtaPhiWeighted[i] = 0;
+ fHistTriggerQAIn[i] = 0;
+ fHistTriggerQAOut[i] = 0;
fHistPsiTPCLeadingJet[i] = 0;
fHistPsiVZEROALeadingJet[i] = 0;
fHistPsiVZEROCLeadingJet[i] = 0;
fHistPsiVZEROCombLeadingJet[i] = 0;
fHistPsi2Correlation[i] = 0;
+ fHistLeadingJetBackground[i] = 0;
fHistRhoPackage[i] = 0;
fHistRho[i] = 0;
fHistRCPhiEta[i] = 0;
DefineOutput(2, TList::Class());
DefineOutput(3, TList::Class());
} break;
- default: fDebug = -1; // suppress debug info explicitely when not running locally
+ default: break;
}
switch (fCollisionType) {
case kPythia : {
AliAnalysisTaskJetV2::~AliAnalysisTaskJetV2()
{
// destructor
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+
if(fOutputList) {delete fOutputList; fOutputList = 0x0;}
if(fOutputListGood) {delete fOutputListGood; fOutputListGood = 0x0;}
if(fOutputListBad) {delete fOutputListBad; fOutputListBad = 0x0;}
void AliAnalysisTaskJetV2::ExecOnce()
{
// Init the analysis
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
fLocalRho = new AliLocalRhoParameter(fLocalRhoName.Data(), 0);
if(fAttachToEvent) {
if(!(InputEvent()->FindListObject(fLocalRho->GetName()))) {
Bool_t AliAnalysisTaskJetV2::Notify()
{
// determine the run number to see if the track and jet cuts should be refreshed for semi-good TPC runs
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(fRunNumber != InputEvent()->GetRunNumber()) {
fRunNumber = InputEvent()->GetRunNumber(); // set the current run number
- if(fDebug > 0) printf("__FUNC__ %s > NEW RUNNUMBER DETECTED \n ", __func__);
+ #ifdef DEBUGTASK
+ printf("__FUNC__ %s > NEW RUNNUMBER DETECTED \n ", __func__);
+ #endif
// check if this is 10h or 11h data
switch (fCollisionType) {
case kPbPb10h : {
- if(fDebug > 0) printf(" LHC10h data, assuming full acceptance, reading VZERO calibration DB \n ");
+ #ifdef DEBUGTASK
+ printf(" LHC10h data, assuming full acceptance, reading VZERO calibration DB \n ");
+ #endif
// for 10h data the vzero event plane calibration needs to be cached
ReadVZEROCalibration2010h();
// no need to change rho or acceptance for 10h, so we're done
return kTRUE;
} break;
default : {
- if(fDebug > 0) printf(" checking runnumber to adjust acceptance on the fly \n");
+ #ifdef DEBUGTASK
+ printf(" checking runnumber to adjust acceptance on the fly \n");
+ #endif
} break;
}
// reset the cuts. should be a pointless operation except for the case where the run number changes
} break;
}
if(fCachedRho) { // if there's a cached rho, it's the default, so switch back
- if(fDebug > 0) printf("__FUNC__ %s > replacing rho with cached rho \n ", __func__);
+ #ifdef DEBUGTASK
+ printf("__FUNC__ %s > replacing rho with cached rho \n ", __func__);
+ #endif
fRho = fCachedRho; // reset rho back to cached value. again, should be pointless
}
Bool_t flaggedAsSemiGood(kFALSE); // not flagged as anything
for(Int_t i(0); i < fExpectedSemiGoodRuns->GetSize(); i++) {
if(fExpectedSemiGoodRuns->At(i) == fRunNumber) { // run is semi-good
- if(fDebug > 0) printf("__FUNC__ %s > semi-good tpc run detected, adjusting acceptance \n ", __func__);
+ #ifdef DEBUGTASK
+ printf("__FUNC__ %s > semi-good tpc run detected, adjusting acceptance \n ", __func__);
+ #endif
flaggedAsSemiGood = kTRUE;
switch (fAnalysisType) {
// for full jets the jet acceptance does not have to be changed as emcal does not
// for semi-good runs, also try to get the 'small rho' estimate, if it is available
AliRhoParameter* tempRho(dynamic_cast<AliRhoParameter*>(InputEvent()->FindListObject(fNameSmallRho.Data())));
if(tempRho) {
- if(fDebug > 0) printf("__FUNC__ %s > switching to small rho, caching normal rho \n ", __func__);
+ #ifdef DEBUGTASK
+ printf("__FUNC__ %s > switching to small rho, caching normal rho \n ", __func__);
+ #endif
fHistAnalysisSummary->SetBinContent(54, 1.); // bookkeep the fact that small rho is used
fCachedRho = fRho; // cache the original rho ...
fRho = tempRho; // ... and use the small rho
Bool_t AliAnalysisTaskJetV2::InitializeAnalysis()
{
// initialize the anaysis
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
// if not set, estimate the number of cones that would fit into the selected acceptance
if(fMaxCones <= 0) fMaxCones = TMath::CeilNint((TMath::Abs(GetJetContainer()->GetJetEtaMax()-GetJetContainer()->GetJetEtaMin())*TMath::Abs(GetJetContainer()->GetJetPhiMax()-GetJetContainer()->GetJetPhiMin()))/(TMath::Pi()*GetJetRadius()*GetJetRadius()));
// manually 'override' the default acceptance cuts of the emcal framework (use with caution)
TH1F* AliAnalysisTaskJetV2::BookTH1F(const char* name, const char* x, Int_t bins, Double_t min, Double_t max, Int_t c, Bool_t append)
{
// book a TH1F and connect it to the output container
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(fReduceBinsXByFactor > 0 ) bins = TMath::Nint(bins/fReduceBinsXByFactor);
- if(!fOutputList) return 0x0;
+ if(append && !fOutputList) return 0x0;
TString title(name);
if(c!=-1) { // format centrality dependent histograms accordingly
name = Form("%s_%i", name, c);
TH2F* AliAnalysisTaskJetV2::BookTH2F(const char* name, const char* x, const char* y, Int_t binsx, Double_t minx, Double_t maxx, Int_t binsy, Double_t miny, Double_t maxy, Int_t c, Bool_t append)
{
// book a TH2F and connect it to the output container
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(fReduceBinsXByFactor > 0 ) binsx = TMath::Nint(binsx/fReduceBinsXByFactor);
if(fReduceBinsYByFactor > 0 ) binsy = TMath::Nint(binsy/fReduceBinsYByFactor);
- if(!fOutputList) return 0x0;
+ if(append && !fOutputList) return 0x0;
TString title(name);
if(c!=-1) { // format centrality dependent histograms accordingly
name = Form("%s_%i", name, c);
TH3F* AliAnalysisTaskJetV2::BookTH3F(const char* name, const char* x, const char* y, const char* z, Int_t binsx, Double_t minx, Double_t maxx, Int_t binsy, Double_t miny, Double_t maxy, Int_t binsz, Double_t minz, Double_t maxz, Int_t c, Bool_t append)
{
// book a TH2F and connect it to the output container
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(fReduceBinsXByFactor > 0 ) {
binsx = TMath::Nint(binsx/fReduceBinsXByFactor);
binsy = TMath::Nint(binsy/fReduceBinsXByFactor);
binsz = TMath::Nint(binsz/fReduceBinsXByFactor);
}
- if(!fOutputList) return 0x0;
+ if(append && !fOutputList) return 0x0;
TString title(name);
if(c!=-1) { // format centrality dependent histograms accordingly
name = Form("%s_%i", name, c);
{
// create output objects. also initializes some default values in case they aren't
// loaded via the AddTask macro
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
fOutputList = new TList();
fOutputList->SetOwner(kTRUE);
if(!fCentralityClasses) { // classes must be defined at this point
// global QA
fHistCentrality = BookTH1F("fHistCentrality", "centrality", 102, -2, 100);
fHistVertexz = BookTH1F("fHistVertexz", "vertex z (cm)", 100, -12, 12);
+ if(fAcceptanceWeights) {
+ fHistCentralityPercIn = new TProfile("fHistCentralityPercIn", "fHistCentralityPercIn", 102, -2, 100);
+ fHistCentralityPercOut = new TProfile("fHistCentralityPercOut", "fHistCentralityPercOut", 102, -2, 100);
+ fHistCentralityPercLost = new TProfile("fHistCentralityPercLost", "fHistCentralityPercLost", 102, -2, 100);
+ }
// for some histograms adjust the bounds according to analysis acceptance
Double_t etaMin(-1.), etaMax(1.), phiMin(0.), phiMax(TMath::TwoPi());
default : break;
}
- // pico track and emcal cluster kinematics
+ // pico track and emcal cluster kinematics, trigger qa
for(Int_t i(0); i < fCentralityClasses->GetSize()-1; i++) {
fHistPicoTrackPt[i] = BookTH1F("fHistPicoTrackPt", "p_{t} [GeV/c]", 100, 0, 100, i);
fHistPicoTrackMult[i] = BookTH1F("fHistPicoTrackMult", "multiplicity", 100, 0, 5000, i);
fHistClusterEtaPhi[i] = BookTH2F("fHistClusterEtaPhi", "#eta", "#phi", 100, etaMax, etaMax, 100, phiMin, phiMax, i);
fHistClusterEtaPhiWeighted[i] = BookTH2F("fHistClusterEtaPhiWeighted", "#eta", "#phi", 100, etaMin, etaMax, 100, phiMin, phiMax, i);
}
- fHistPsiTPCLeadingJet[i] = BookTH3F("fHistPsiTPCLeadingJet", "p_{t} [GeV/c]", "#Psi_{TPC}", "#varphi_{jet}", 70, -100, 250, 50, -1.*TMath::Pi()/2., TMath::Pi()/2., 50, phiMin, phiMax, i);
- fHistPsiVZEROALeadingJet[i] = BookTH3F("fHistPsiVZEROALeadingJet", "p_{t} [GeV/c]", "#Psi_{VZEROA}", "#varphi_{jet}", 70, -100, 250, 50, -1.*TMath::Pi()/2., TMath::Pi()/2., 50, phiMin, phiMax, i);
- fHistPsiVZEROCLeadingJet[i] = BookTH3F("fHistPsiVZEROCLeadingJet", "p_{t} [GeV/c]", "#Psi_{VZEROC}", "#varphi_{jet}", 70, -100, 250, 50, -1.*TMath::Pi()/2., TMath::Pi()/2., 50, phiMin, phiMax, i);
- fHistPsiVZEROCombLeadingJet[i] = BookTH3F("fHistPsiVZEROCombLeadingJet", "p_{t} [GeV/c]", "#Psi_{VZEROComb}", "#varphi_{jet}", 70, -100, 250, 50, -1.*TMath::Pi()/2., TMath::Pi()/2., 50, phiMin, phiMax, i);
+ fHistPsiTPCLeadingJet[i] = BookTH3F("fHistPsiTPCLeadingJet", "p_{t} [GeV/c]", "#Psi_{TPC}", "#varphi_{jet}", 70, 0, 210, 50, -1.*TMath::Pi()/2., TMath::Pi()/2., 50, phiMin, phiMax, i);
+ fHistPsiVZEROALeadingJet[i] = BookTH3F("fHistPsiVZEROALeadingJet", "p_{t} [GeV/c]", "#Psi_{VZEROA}", "#varphi_{jet}", 70, 0, 210, 50, -1.*TMath::Pi()/2., TMath::Pi()/2., 50, phiMin, phiMax, i);
+ fHistPsiVZEROCLeadingJet[i] = BookTH3F("fHistPsiVZEROCLeadingJet", "p_{t} [GeV/c]", "#Psi_{VZEROC}", "#varphi_{jet}", 70, 0, 210, 50, -1.*TMath::Pi()/2., TMath::Pi()/2., 50, phiMin, phiMax, i);
+ fHistPsiVZEROCombLeadingJet[i] = BookTH3F("fHistPsiVZEROCombLeadingJet", "p_{t} [GeV/c]", "#Psi_{VZEROComb}", "#varphi_{jet}", 70, 0, 210, 50, -1.*TMath::Pi()/2., TMath::Pi()/2., 50, phiMin, phiMax, i);
fHistPsi2Correlation[i] = BookTH3F("fHistPsi2Correlation", "#Psi_{TPC}", "#Psi_{VZEROA}", "#Psi_{VZEROC}", 20, -1.*TMath::Pi()/2., TMath::Pi()/2., 20, -1.*TMath::Pi()/2., TMath::Pi()/2., 20, -1.*TMath::Pi()/2., TMath::Pi()/2., i);
+ fHistLeadingJetBackground[i] = BookTH2F("fHistLeadingJetBackground", "#Delta #eta (leading jet with, without sub)", "Delta #varphi (leading jet with, without sub)", 50, 0., 2, 50, 0., TMath::TwoPi(), i);
+ // trigger qa
+ fHistTriggerQAIn[i] = BookTH2F("fHistTriggerQAIn", "trigger configuration", "p_{T}^{jet} (GeV/c) in-plane jets", 16, 0.5, 16.5, 70, -100, 250, i);
+ fHistTriggerQAOut[i] = BookTH2F("fHistTriggerQAOut", "trigger configuration", "p_{T}^{jet} (GeV/c) out-of-plane jets", 16, 0.5, 16.5, 70, -100, 250, i);
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(1, "no trigger");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(2, "kAny");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(3, "kAnyINT");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(4, "kMB");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(5, "kCentral");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(6, "kSemiCentral");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(7, "kEMCEJE");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(8, "kEMCEGA");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(9, "kEMCEJE & kMB");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(10, "kEMCEJE & kCentral");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(11, "kEMCEJE & kSemiCentral");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(12, "kEMCEJE & all min bias");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(13, "kEMCEGA & kMB");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(14, "kEMCEGA & kCentral");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(15, "kEMCEGA & kSemiCentral");
+ fHistTriggerQAIn[i]->GetXaxis()->SetBinLabel(16, "kEMCEGA & all min bias");
+ fHistTriggerQAIn[i]->LabelsOption("v");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(1, "no trigger");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(2, "kAny");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(3, "kAnyINT");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(4, "kMB");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(5, "kCentral");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(6, "kSemiCentral");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(7, "kEMCEJE");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(8, "kEMCEGA");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(9, "kEMCEJE & kMB");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(10, "kEMCEJE & kCentral");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(11, "kEMCEJE & kSemiCentral");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(12, "kEMCEJE & all min bias");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(13, "kEMCEGA & kMB");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(14, "kEMCEGA & kCentral");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(15, "kEMCEGA & kSemiCentral");
+ fHistTriggerQAOut[i]->GetXaxis()->SetBinLabel(16, "kEMCEGA & all min bias");
+ fHistTriggerQAOut[i]->LabelsOption("v");
}
}
fHistSwap = new TH1F("fHistSwap", "fHistSwap", 20, 0, TMath::TwoPi());
if(fUsePtWeight) fHistSwap->Sumw2();
- if(fUserSuppliedV2) fOutputList->Add(fUserSuppliedV2);
- if(fUserSuppliedV3) fOutputList->Add(fUserSuppliedV3);
- if(fUserSuppliedR2) fOutputList->Add(fUserSuppliedR2);
- if(fUserSuppliedR3) fOutputList->Add(fUserSuppliedR3);
+ if(fUserSuppliedV2) fOutputList->Add(fUserSuppliedV2);
+ if(fUserSuppliedV3) fOutputList->Add(fUserSuppliedV3);
+ if(fUserSuppliedR2) fOutputList->Add(fUserSuppliedR2);
+ if(fUserSuppliedR3) fOutputList->Add(fUserSuppliedR3);
+ if(fEventPlaneWeights) {
+ // add the original event plane weight histogram
+ fOutputList->Add((TH1F*)(fEventPlaneWeights->Clone("EP_distribution_original")));
+ // calculate the weights that will actually be used
+ fEventPlaneWeights = GetEventPlaneWeights(fEventPlaneWeights);
+ fOutputList->Add(fEventPlaneWeights);
+ }
// increase readability of output list
fOutputList->Sort();
// cdf and pdf of chisquare distribution
Bool_t AliAnalysisTaskJetV2::Run()
{
// called for each accepted event (call made from user exec of parent class)
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(!fTracks||!fJets||!fRho) {
if(!fTracks) printf(" > Failed to retrieve fTracks ! < \n");
if(!fJets) printf(" > Failed to retrieve fJets ! < \n");
case kFixedEP : { psi2 = 0.; psi3 = 1.;} break;
default : break;
}
+ // if requested extract the event plane weight
+ if(fEventPlaneWeights) {
+ fEventPlaneWeight = fEventPlaneWeights->GetBinContent(fEventPlaneWeights->FindBin(psi2));
+ }
+ // if requested store the acceptance weights
+ if(fAcceptanceWeights) {
+ Double_t percIn(0.), percOut(0.), percLost(0.);
+ NumericalOverlap(GetJetContainer()->GetJetEtaMin(), GetJetContainer()->GetJetEtaMax(),
+ psi2, percIn, percOut, percLost);
+ fHistCentralityPercIn->Fill(fCent, percIn);
+ fHistCentralityPercOut->Fill(fCent, percOut);
+ fHistCentralityPercLost->Fill(fCent, percLost);
+ }
switch (fFitModulationType) { // do the fits
case kNoFit : {
switch (fCollisionType) {
}
// if all went well, update the local rho parameter
fLocalRho->SetLocalRho(fFitModulation);
+ // and only at this point can the leading jet after rho subtraction be evaluated
+ if(fFillQAHistograms) fLeadingJetAfterSub = GetLeadingJet(fLocalRho);
// fill a number of histograms. event qa needs to be filled first as it also determines the runnumber for the track qa
- if(fFillQAHistograms) FillQAHistograms(InputEvent());
- if(fFillHistograms) FillHistogramsAfterSubtraction(psi2, vzero, vzeroComb, tpc);
+ if(fFillQAHistograms) FillWeightedQAHistograms(InputEvent());
+ if(fFillHistograms) FillHistogramsAfterSubtraction(psi2, vzero, vzeroComb, tpc);
// send the output to the connected output container
PostData(1, fOutputList);
switch (fRunModeType) {
void AliAnalysisTaskJetV2::Exec(Option_t* c)
{
// for stand alone, avoid framework event setup
- switch (fCollisionType) {
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+ switch (fCollisionType) {
case kJetFlowMC : {
// need to call ExecOnce as it is not loaded otherwise
if(!fLocalRho) AliAnalysisTaskJetV2::ExecOnce();
}
}
//_____________________________________________________________________________
+void AliAnalysisTaskJetV2::NumericalOverlap(Double_t x1, Double_t x2, Double_t psi2, Double_t &percIn, Double_t &percOut, Double_t &percLost)
+{
+ // numerically integrate with finite resolution
+ // idea is the following:
+ // 1) choose a vector phi
+ // 2) see if it is in a region of overlap between detector and in/out of plane spectrum
+ // 3) bookkeep percentages over overlap
+ Double_t a(psi2 - TMath::Pi()/4.);
+ // poor man's appproach: fix the frame
+ if(a < 0) a += TMath::Pi();
+ // set the rest of the event
+ Double_t b(a + TMath::Pi()/2.);
+ Double_t c(b + TMath::Pi()/2.);
+ Double_t d(c + TMath::Pi()/2.);
+ Double_t e(d + TMath::Pi()/2.); // may seem mysterious but here for good reasons
+ // get percetnages
+ Double_t interval(TMath::TwoPi() / 1000.);
+ percIn = 0.;
+ percOut = 0.;
+ percLost = 0.;
+ Int_t status(-1);
+ // automagically do the integration
+ for(Double_t i = a; i < a+TMath::TwoPi()-interval; i += interval) {
+ status = OverlapsWithPlane(x1, x2, a, b, c, d, e, i);
+ if(status == 0 ) percLost += .001;
+ else if(status == 1 ) percIn += 0.001;
+ else if(status == 2 ) percOut += 0.001;
+ }
+}
+//_____________________________________________________________________________
+Int_t AliAnalysisTaskJetV2::OverlapsWithPlane (
+ Double_t x1, Double_t x2, // detector geometry relative to ep
+ Double_t a, Double_t b, Double_t c, Double_t d, Double_t e, // in-plane, out-of-plane boundaries (see comments)
+ Double_t phi) // variable
+{
+ // 'numerical integration' of geometric overlap
+ //
+ // works as follows: for a given vector phi determines whether
+ // or not this vector points towards an overlap region of
+ // detector geometry and plane (in or out)
+ //
+ // returns
+ // 1) if overlap with in plane
+ // 2) if overlap with out of plane
+ // 0) if no overlap at all
+ Int_t overlap(0);
+ // check for condition in-plane
+ // conditions are always checked as
+ // 1) is the angle within in-plane sector?
+ // 2) is the angle also within detector acceptance?
+ if(phi > a && phi < b && phi > x1 && phi < x2) overlap = 1;
+ if(phi > c && phi < d && phi > x1 && phi < x2) overlap = 1;
+ // likewise for out-of-plane
+ if(phi > b && phi < c && phi > x1 && phi < x2) overlap = 2;
+ if(phi > d && phi < e && phi > x1 && phi < x2) overlap = 2;
+
+ // life would be so much easier if the detector was flat instead of cylindrical ....
+ x1+=TMath::TwoPi();
+ x2+=TMath::TwoPi();
+
+ if(phi > a && phi < b && phi > x1 && phi < x2) overlap = 1;
+ if(phi > c && phi < d && phi > x1 && phi < x2) overlap = 1;
+ // likewise for out-of-plane
+ if(phi > b && phi < c && phi > x1 && phi < x2) overlap = 2;
+ if(phi > d && phi < e && phi > x1 && phi < x2) overlap = 2;
+
+ return overlap;
+}
+//_____________________________________________________________________________
Double_t AliAnalysisTaskJetV2::CalculateEventPlaneChi(Double_t res)
{
// return chi for given resolution to combine event plane estimates from two subevents
void AliAnalysisTaskJetV2::CalculateEventPlaneVZERO(Double_t vzero[2][2]) const
{
// get the vzero event plane (a and c separately)
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
switch (fCollisionType) {
case kPbPb10h : {
// for 10h data, get the calibrated q-vector from the database
void AliAnalysisTaskJetV2::CalculateEventPlaneCombinedVZERO(Double_t* comb) const
{
// return the combined vzero event plane
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
switch (fCollisionType) {
// for 10h data call calibration info
case kPbPb10h : {
void AliAnalysisTaskJetV2::CalculateEventPlaneTPC(Double_t* tpc)
{
// grab the TPC event plane
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
fNAcceptedTracks = 0; // reset the track counter
Double_t qx2(0), qy2(0); // for psi2
Double_t qx3(0), qy3(0); // for psi3
void AliAnalysisTaskJetV2::CalculateEventPlaneResolution(Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc)
{
// fill the profiles for the resolution parameters
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
fProfV2Resolution[fInCentralitySelection]->Fill(2., TMath::Cos(2.*(vzero[0][0] - vzero[1][0])));
fProfV2Resolution[fInCentralitySelection]->Fill(3., TMath::Cos(2.*(vzero[1][0] - vzero[0][0])));
fProfV2Resolution[fInCentralitySelection]->Fill(4., TMath::Cos(2.*(vzero[0][0] - tpc[0])));
//
// Qa2[0] = Qx2 for vzero A Qa2[1] = Qy2 for vzero A (etc)
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
// placeholders for geometric information
Double_t phi(-999.), weight(-999.);
// reset placeholders for Q-vector components
// calculate calibrated q-vector of the combined vzeroa, vzeroc system
// this is somewhat ugly as CalculateQvectorCombinedVZERO is called more than once per event
// but for now it will have to do ...
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
// first step: retrieve the q-vectors component-wise per vzero detector
Double_t QA2[] = {-999., -999.};
AliParticleContainer* tracksCont, AliClusterContainer* clusterCont, AliEmcalJet* jet) const
{
// get a random cone
- if(fDebug > 1) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
pt = 0; eta = 0; phi = 0;
Float_t etaJet(999), phiJet(999), dJet(999); // no jet: same as jet very far away
if(jet) { // if a leading jet is given, use its kinematic properties to exclude it
//_____________________________________________________________________________
Double_t AliAnalysisTaskJetV2::CalculateQC2(Int_t harm) {
// get the second order q-cumulant, a -999 return will be caught in the qa routine of CorrectRho
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Double_t reQ(0), imQ(0), modQ(0), M11(0), M(0);
if(fUsePtWeight) { // for the weighted 2-nd order q-cumulant
QCnQnk(harm, 1, reQ, imQ); // get the weighted 2-nd order q-vectors
//_____________________________________________________________________________
Double_t AliAnalysisTaskJetV2::CalculateQC4(Int_t harm) {
// get the fourth order q-cumulant, a -999 return will be caught in the qa routine of CorrectRho
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Double_t reQn1(0), imQn1(0), reQ2n2(0), imQ2n2(0), reQn3(0), imQn3(0), M1111(0), M(0);
Double_t a(0), b(0), c(0), d(0), e(0), f(0), g(0); // terms of the calculation
if(fUsePtWeight) { // for the weighted 4-th order q-cumulant
//_____________________________________________________________________________
void AliAnalysisTaskJetV2::QCnQnk(Int_t n, Int_t k, Double_t &reQ, Double_t &imQ) {
// get the weighted n-th order q-vector, pass real and imaginary part as reference
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(!fTracks) return;
fNAcceptedTracksQCn = 0;
Int_t iTracks(fTracks->GetEntriesFast());
TClonesArray* pois, TArrayD* ptBins, Bool_t vpart, Double_t* repn, Double_t* impn,
Double_t *mp, Double_t *reqn, Double_t *imqn, Double_t* mq, Int_t n)
{
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
- // get unweighted differential flow vectors
+ // get unweighted differential flow vectors
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Int_t iPois(pois->GetEntriesFast());
if(vpart) {
for(Int_t i(0); i < iPois; i++) {
//_____________________________________________________________________________
Double_t AliAnalysisTaskJetV2::QCnS(Int_t i, Int_t j) {
// get the weighted ij-th order autocorrelation correction
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(!fTracks || i <= 0 || j <= 0) return -999;
Int_t iTracks(fTracks->GetEntriesFast());
Double_t Sij(0);
//_____________________________________________________________________________
Double_t AliAnalysisTaskJetV2::QCnM() {
// get multiplicity for unweighted q-cumulants. function QCnQnk should be called first
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
return (Double_t) fNAcceptedTracksQCn;
}
//_____________________________________________________________________________
Double_t AliAnalysisTaskJetV2::QCnM11() {
// get multiplicity weights for the weighted two particle cumulant
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
return (QCnS(2,1) - QCnS(1,2));
}
//_____________________________________________________________________________
Double_t AliAnalysisTaskJetV2::QCnM1111() {
// get multiplicity weights for the weighted four particle cumulant
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
return (QCnS(4,1)-6*QCnS(1,2)*QCnS(2,1)+8*QCnS(1,3)*QCnS(1,1)+3*QCnS(2,2)-6*QCnS(1,4));
}
//_____________________________________________________________________________
Bool_t AliAnalysisTaskJetV2::QCnRecovery(Double_t psi2, Double_t psi3) {
// decides how to deal with the situation where c2 or c3 is negative
// returns kTRUE depending on whether or not a modulated rho is used for the jet background
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(TMath::AreEqualAbs(fFitModulation->GetParameter(3), .0, 1e-10) && TMath::AreEqualAbs(fFitModulation->GetParameter(7), .0,1e-10)) {
fFitModulation->SetParameter(7, 0);
fFitModulation->SetParameter(3, 0);
// the fit can be done with either v2, v3 or a combination.
// in all cases, a cut can be made on the p-value of the chi-squared value of the fit
// and a check can be performed to see if rho has no negative local minimum
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Int_t freeParams(2); // free parameters of the fit (for NDF)
switch (fFitModulationType) { // for approaches where no fitting is required
case kQC2 : {
Bool_t AliAnalysisTaskJetV2::PassesCuts(AliVEvent* event)
{
// event cuts
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
switch (fCollisionType) {
case kJetFlowMC : {
fInCentralitySelection = 0;
for(Int_t i(0); i < fCentralityClasses->GetSize()-1; i++) {
if(fCent >= fCentralityClasses->At(i) && fCent <= fCentralityClasses->At(1+i)) {
fInCentralitySelection = i;
- break; }
+ break;
+ }
}
if(fInCentralitySelection<0) return kFALSE; // should be null op
// see if input containers are filled
void AliAnalysisTaskJetV2::FillHistogramsAfterSubtraction(Double_t psi2, Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc)
{
// fill histograms
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
- FillTrackHistograms();
- if(fAnalysisType == AliAnalysisTaskJetV2::kFull) FillClusterHistograms();
- FillJetHistograms(psi2);
- if(fFillQAHistograms) FillEventPlaneHistograms(vzero, vzeroComb, tpc);
- FillRhoHistograms();
- FillDeltaPtHistograms(psi2);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+ // fill histograms. weight is 1 when no procedure is defined
+ FillWeightedTrackHistograms();
+ if(fAnalysisType == AliAnalysisTaskJetV2::kFull) FillWeightedClusterHistograms();
+ FillWeightedJetHistograms(psi2);
+ if(fFillQAHistograms) FillWeightedEventPlaneHistograms(vzero, vzeroComb, tpc);
+ FillWeightedRhoHistograms();
+ FillWeightedDeltaPtHistograms(psi2);
+}
+//_____________________________________________________________________________
+void AliAnalysisTaskJetV2::FillQAHistograms(AliVTrack* vtrack) const
+{
+ // fill qa histograms for pico tracks
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+ if(!vtrack) return;
+ AliPicoTrack* track = static_cast<AliPicoTrack*>(vtrack);
+ fHistRunnumbersPhi->Fill(fMappedRunNumber, track->Phi());
+ fHistRunnumbersEta->Fill(fMappedRunNumber, track->Eta());
+ Int_t type((int)(track->GetTrackType()));
+ switch (type) {
+ case 0:
+ fHistPicoCat1[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
+ break;
+ case 1:
+ fHistPicoCat2[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
+ break;
+ case 2:
+ fHistPicoCat3[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
+ break;
+ default: break;
+ }
}
//_____________________________________________________________________________
-void AliAnalysisTaskJetV2::FillTrackHistograms() const
+void AliAnalysisTaskJetV2::FillQAHistograms(AliVEvent* vevent)
+{
+ // fill qa histograms for events
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+ if(!vevent) return;
+ fHistVertexz->Fill(vevent->GetPrimaryVertex()->GetZ());
+ fHistCentrality->Fill(fCent);
+ Int_t runNumber(InputEvent()->GetRunNumber());
+ if(fLeadingJet && fLeadingJetAfterSub) fHistLeadingJetBackground[fInCentralitySelection]->Fill(TMath::Abs(fLeadingJet->Eta()-fLeadingJetAfterSub->Eta()), PhaseShift(fLeadingJet->Phi()-fLeadingJetAfterSub->Phi()));
+ for(fMappedRunNumber = 0; fMappedRunNumber < fExpectedRuns->GetSize(); fMappedRunNumber++) {
+ if(fExpectedRuns->At(fMappedRunNumber) == runNumber) return;
+ }
+ #ifdef DEBUGTASK
+ printf("\n > TASK %s CANNOT IDENTIFY RUN - CONFIGURATION COULD BE INCORRECT < \n", GetName());
+ #endif
+}
+//_____________________________________________________________________________
+void AliAnalysisTaskJetV2::FillWeightedTrackHistograms() const
{
// fill track histograms
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Int_t iTracks(fTracks->GetEntriesFast()), iAcceptedTracks(0);
for(Int_t i(0); i < iTracks; i++) {
AliVTrack* track = static_cast<AliVTrack*>(fTracks->At(i));
if(!PassesCuts(track)) continue;
iAcceptedTracks++;
- fHistPicoTrackPt[fInCentralitySelection]->Fill(track->Pt());
+ fHistPicoTrackPt[fInCentralitySelection]->Fill(track->Pt(), fEventPlaneWeight);
if(fFillQAHistograms) FillQAHistograms(track);
}
- fHistPicoTrackMult[fInCentralitySelection]->Fill(iAcceptedTracks);
+ fHistPicoTrackMult[fInCentralitySelection]->Fill(iAcceptedTracks, fEventPlaneWeight);
}
//_____________________________________________________________________________
-void AliAnalysisTaskJetV2::FillClusterHistograms() const
+void AliAnalysisTaskJetV2::FillWeightedClusterHistograms() const
{
// fill cluster histograms
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(!fClusterCont) return;
Int_t iClusters(fClusterCont->GetNClusters());
TLorentzVector clusterLorentzVector;
AliVCluster* cluster = fClusterCont->GetCluster(i);
if (!PassesCuts(cluster)) continue;
cluster->GetMomentum(clusterLorentzVector, const_cast<Double_t*>(fVertex));
- fHistClusterPt[fInCentralitySelection]->Fill(clusterLorentzVector.Pt());
- fHistClusterEtaPhi[fInCentralitySelection]->Fill(clusterLorentzVector.Eta(), clusterLorentzVector.Phi());
- fHistClusterEtaPhiWeighted[fInCentralitySelection]->Fill(clusterLorentzVector.Eta(), clusterLorentzVector.Phi(), clusterLorentzVector.Pt());
+ fHistClusterPt[fInCentralitySelection]->Fill(clusterLorentzVector.Pt(), fEventPlaneWeight);
+ fHistClusterEtaPhi[fInCentralitySelection]->Fill(clusterLorentzVector.Eta(), clusterLorentzVector.Phi(), fEventPlaneWeight);
+ fHistClusterEtaPhiWeighted[fInCentralitySelection]->Fill(clusterLorentzVector.Eta(), clusterLorentzVector.Phi(), clusterLorentzVector.Pt()*fEventPlaneWeight);
}
return;
}
//_____________________________________________________________________________
-void AliAnalysisTaskJetV2::FillEventPlaneHistograms(Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc) const
+void AliAnalysisTaskJetV2::FillWeightedEventPlaneHistograms(Double_t vzero[2][2], Double_t* vzeroComb, Double_t* tpc) const
{
// fill event plane histograms, only called in qa mode
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
- fHistPsiControl->Fill(0.5, vzero[0][0]); // vzero a psi2
- fHistPsiControl->Fill(1.5, vzero[1][0]); // vzero c psi2
- fHistPsiControl->Fill(2.5, tpc[0]); // tpc psi 2
- fHistPsiControl->Fill(5.5, vzero[0][1]); // vzero a psi3
- fHistPsiControl->Fill(6.5, vzero[1][1]); // vzero b psi3
- fHistPsiControl->Fill(7.5, tpc[1]); // tpc psi 3
- fHistPsiVZEROA->Fill(vzero[0][0]);
- fHistPsiVZEROC->Fill(vzero[1][0]);
- fHistPsiVZERO->Fill(vzeroComb[0]);
- fHistPsiTPC->Fill(tpc[0]);
- fHistPsiSpread->Fill(0.5, TMath::Abs(vzero[0][0]-vzero[1][0]));
- fHistPsiSpread->Fill(1.5, TMath::Abs(vzero[0][0]-tpc[0]));
- fHistPsiSpread->Fill(2.5, TMath::Abs(vzero[1][0]-tpc[0]));
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+ fHistPsiControl->Fill(0.5, vzero[0][0], fEventPlaneWeight); // vzero a psi2
+ fHistPsiControl->Fill(1.5, vzero[1][0], fEventPlaneWeight); // vzero c psi2
+ fHistPsiControl->Fill(2.5, tpc[0], fEventPlaneWeight); // tpc psi 2
+ fHistPsiControl->Fill(5.5, vzero[0][1], fEventPlaneWeight); // vzero a psi3
+ fHistPsiControl->Fill(6.5, vzero[1][1], fEventPlaneWeight); // vzero b psi3
+ fHistPsiControl->Fill(7.5, tpc[1], fEventPlaneWeight); // tpc psi 3
+ fHistPsiVZEROA->Fill(vzero[0][0], fEventPlaneWeight);
+ fHistPsiVZEROC->Fill(vzero[1][0], fEventPlaneWeight);
+ fHistPsiVZERO->Fill(vzeroComb[0], fEventPlaneWeight);
+ fHistPsiTPC->Fill(tpc[0], fEventPlaneWeight);
+ fHistPsiSpread->Fill(0.5, TMath::Abs(vzero[0][0]-vzero[1][0]), fEventPlaneWeight);
+ fHistPsiSpread->Fill(1.5, TMath::Abs(vzero[0][0]-tpc[0]), fEventPlaneWeight);
+ fHistPsiSpread->Fill(2.5, TMath::Abs(vzero[1][0]-tpc[0]), fEventPlaneWeight);
// event plane vs centrality QA histo's to check recentering
Double_t TRK(InputEvent()->GetCentrality()->GetCentralityPercentile("TRK"));
Double_t V0M(InputEvent()->GetCentrality()->GetCentralityPercentile("V0M"));
- fHistPsiVZEROAV0M->Fill(V0M, vzero[0][0]);
- fHistPsiVZEROCV0M->Fill(V0M, vzero[1][0]);
- fHistPsiVZEROVV0M->Fill(V0M, vzeroComb[0]);
- fHistPsiTPCV0M->Fill(V0M, tpc[0]);
- fHistPsiVZEROATRK->Fill(TRK, vzero[0][0]);
- fHistPsiVZEROCTRK->Fill(TRK, vzero[1][0]);
- fHistPsiVZEROTRK->Fill(TRK, vzeroComb[0]);
- fHistPsiTPCTRK->Fill(TRK, tpc[0]);
+ fHistPsiVZEROAV0M->Fill(V0M, vzero[0][0], fEventPlaneWeight);
+ fHistPsiVZEROCV0M->Fill(V0M, vzero[1][0], fEventPlaneWeight);
+ fHistPsiVZEROVV0M->Fill(V0M, vzeroComb[0], fEventPlaneWeight);
+ fHistPsiTPCV0M->Fill(V0M, tpc[0], fEventPlaneWeight);
+ fHistPsiVZEROATRK->Fill(TRK, vzero[0][0], fEventPlaneWeight);
+ fHistPsiVZEROCTRK->Fill(TRK, vzero[1][0], fEventPlaneWeight);
+ fHistPsiVZEROTRK->Fill(TRK, vzeroComb[0], fEventPlaneWeight);
+ fHistPsiTPCTRK->Fill(TRK, tpc[0], fEventPlaneWeight);
// leading jet vs event plane bias
if(fLeadingJet) {
Double_t rho(fLocalRho->GetLocalVal(fLeadingJet->Phi(), GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
Double_t pt(fLeadingJet->Pt() - fLeadingJet->Area()*rho);
- fHistPsiTPCLeadingJet[fInCentralitySelection]->Fill(pt, tpc[0], fLeadingJet->Phi());
- fHistPsiVZEROALeadingJet[fInCentralitySelection]->Fill(pt, vzero[0][0], fLeadingJet->Phi());
- fHistPsiVZEROCLeadingJet[fInCentralitySelection]->Fill(pt, vzero[1][0], fLeadingJet->Phi());
- fHistPsiVZEROCombLeadingJet[fInCentralitySelection]->Fill(pt, vzeroComb[0], fLeadingJet->Phi());
+ fHistPsiTPCLeadingJet[fInCentralitySelection]->Fill(pt, tpc[0], fLeadingJet->Phi(), fEventPlaneWeight);
+ fHistPsiVZEROALeadingJet[fInCentralitySelection]->Fill(pt, vzero[0][0], fLeadingJet->Phi(), fEventPlaneWeight);
+ fHistPsiVZEROCLeadingJet[fInCentralitySelection]->Fill(pt, vzero[1][0], fLeadingJet->Phi(), fEventPlaneWeight);
+ fHistPsiVZEROCombLeadingJet[fInCentralitySelection]->Fill(pt, vzeroComb[0], fLeadingJet->Phi(), fEventPlaneWeight);
}
// correlation of event planes
- fHistPsi2Correlation[fInCentralitySelection]->Fill(tpc[0], vzero[0][0], vzero[1][0]);
+ fHistPsi2Correlation[fInCentralitySelection]->Fill(tpc[0], vzero[0][0], vzero[1][0], fEventPlaneWeight);
}
//_____________________________________________________________________________
-void AliAnalysisTaskJetV2::FillRhoHistograms()
+void AliAnalysisTaskJetV2::FillWeightedRhoHistograms()
{
// fill rho histograms
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
- fHistRhoPackage[fInCentralitySelection]->Fill(fLocalRho->GetVal()); // save the rho estimate from the emcal jet package
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+ fHistRhoPackage[fInCentralitySelection]->Fill(fLocalRho->GetVal(), fEventPlaneWeight); // save the rho estimate from the emcal jet package
// get multiplicity FIXME inefficient
Int_t iJets(fJets->GetEntriesFast());
Double_t rho(fLocalRho->GetLocalVal(TMath::Pi(), TMath::Pi(), fLocalRho->GetVal()));
- fHistRho[fInCentralitySelection]->Fill(rho);
- fHistRhoVsMult->Fill(fTracks->GetEntries(), rho);
- fHistRhoVsCent->Fill(fCent, rho);
+ fHistRho[fInCentralitySelection]->Fill(rho, fEventPlaneWeight);
+ fHistRhoVsMult->Fill(fTracks->GetEntries(), rho, fEventPlaneWeight);
+ fHistRhoVsCent->Fill(fCent, rho, fEventPlaneWeight);
for(Int_t i(0); i < iJets; i++) {
AliEmcalJet* jet = static_cast<AliEmcalJet*>(fJets->At(i));
if(!PassesCuts(jet)) continue;
- fHistRhoAVsMult->Fill(fTracks->GetEntries(), rho * jet->Area());
- fHistRhoAVsCent->Fill(fCent, rho * jet->Area());
+ fHistRhoAVsMult->Fill(fTracks->GetEntries(), rho * jet->Area(), fEventPlaneWeight);
+ fHistRhoAVsCent->Fill(fCent, rho * jet->Area(), fEventPlaneWeight);
}
}
//_____________________________________________________________________________
-void AliAnalysisTaskJetV2::FillDeltaPtHistograms(Double_t psi2) const
+void AliAnalysisTaskJetV2::FillWeightedDeltaPtHistograms(Double_t psi2) const
{
// fill delta pt histograms
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Int_t i(0);
const Float_t areaRC = GetJetRadius()*GetJetRadius()*TMath::Pi();
// we're retrieved the leading jet, now get a random cone
// get a random cone without constraints on leading jet position
CalculateRandomCone(pt, eta, phi, fTracksCont, fClusterCont, 0x0);
if(pt > 0) {
- if(fFillQAHistograms) fHistRCPhiEta[fInCentralitySelection]->Fill(phi, eta);
- fHistRhoVsRCPt[fInCentralitySelection]->Fill(pt, fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal())*areaRC);
- fHistRCPt[fInCentralitySelection]->Fill(pt);
- fHistDeltaPtDeltaPhi2[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
- fHistDeltaPtDeltaPhi2Rho0[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetVal());
+ if(fFillQAHistograms) fHistRCPhiEta[fInCentralitySelection]->Fill(phi, eta, fEventPlaneWeight);
+ fHistRhoVsRCPt[fInCentralitySelection]->Fill(pt, fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal())*areaRC, fEventPlaneWeight);
+ fHistRCPt[fInCentralitySelection]->Fill(pt, fEventPlaneWeight);
+ fHistDeltaPtDeltaPhi2[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()), fEventPlaneWeight);
+ fHistDeltaPtDeltaPhi2Rho0[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetVal(), fEventPlaneWeight);
}
// get a random cone excluding leading jet area
CalculateRandomCone(pt, eta, phi, fTracksCont, fClusterCont, fLeadingJet);
if(pt > 0) {
- if(fFillQAHistograms) fHistRCPhiEtaExLJ[fInCentralitySelection]->Fill(phi, eta);
- fHistRhoVsRCPtExLJ[fInCentralitySelection]->Fill(pt, fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal())*areaRC);
- fHistRCPtExLJ[fInCentralitySelection]->Fill(pt);
- fHistDeltaPtDeltaPhi2ExLJ[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
- fHistDeltaPtDeltaPhi2ExLJRho0[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetVal());
+ if(fFillQAHistograms) fHistRCPhiEtaExLJ[fInCentralitySelection]->Fill(phi, eta, fEventPlaneWeight);
+ fHistRhoVsRCPtExLJ[fInCentralitySelection]->Fill(pt, fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal())*areaRC, fEventPlaneWeight);
+ fHistRCPtExLJ[fInCentralitySelection]->Fill(pt, fEventPlaneWeight);
+ fHistDeltaPtDeltaPhi2ExLJ[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()), fEventPlaneWeight);
+ fHistDeltaPtDeltaPhi2ExLJRho0[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt - areaRC*fLocalRho->GetVal(), fEventPlaneWeight);
}
}
}
//_____________________________________________________________________________
-void AliAnalysisTaskJetV2::FillJetHistograms(Double_t psi2)
+void AliAnalysisTaskJetV2::FillWeightedJetHistograms(Double_t psi2)
{
// fill jet histograms
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Int_t iJets(fJets->GetEntriesFast());
+ UInt_t trigger(0);
+ if(fFillQAHistograms) {
+ trigger = ((AliInputEventHandler*)(AliAnalysisManager::GetAnalysisManager()->GetInputEventHandler()))->IsEventSelected();
+ #ifdef DEBUGTASK
+ PrintTriggerSummary(trigger);
+ #endif
+ }
for(Int_t i(0); i < iJets; i++) {
AliEmcalJet* jet = static_cast<AliEmcalJet*>(fJets->At(i));
if(PassesCuts(jet)) {
Double_t pt(jet->Pt()), area(jet->Area()), eta(jet->Eta()), phi(jet->Phi());
Double_t rho(fLocalRho->GetLocalVal(phi, GetJetContainer()->GetJetRadius(), fLocalRho->GetVal()));
- fHistJetPtRaw[fInCentralitySelection]->Fill(pt);
- fHistJetPt[fInCentralitySelection]->Fill(pt-area*rho);
- if(fFillQAHistograms) fHistJetEtaPhi[fInCentralitySelection]->Fill(eta, phi);
- fHistJetPtArea[fInCentralitySelection]->Fill(pt-area*rho, area);
- fHistJetPtEta[fInCentralitySelection]->Fill(pt-area*rho, eta);
- fHistJetPsi2Pt[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt-area*rho);
- fHistJetPsi2PtRho0[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt-area*fLocalRho->GetVal());
- fHistJetPtConstituents[fInCentralitySelection]->Fill(pt-area*rho, jet->GetNumberOfConstituents());
- fHistJetEtaRho[fInCentralitySelection]->Fill(eta, pt/area);
+ fHistJetPtRaw[fInCentralitySelection]->Fill(pt, fEventPlaneWeight);
+ fHistJetPt[fInCentralitySelection]->Fill(pt-area*rho, fEventPlaneWeight);
+ if(fFillQAHistograms) {
+ fHistJetEtaPhi[fInCentralitySelection]->Fill(eta, phi, fEventPlaneWeight);
+ FillWeightedTriggerQA(PhaseShift(phi-psi2, 2.), pt - area*rho, trigger);
+ }
+ fHistJetPtArea[fInCentralitySelection]->Fill(pt-area*rho, area, fEventPlaneWeight);
+ fHistJetPtEta[fInCentralitySelection]->Fill(pt-area*rho, eta, fEventPlaneWeight);
+ fHistJetPsi2Pt[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt-area*rho, fEventPlaneWeight);
+ fHistJetPsi2PtRho0[fInCentralitySelection]->Fill(PhaseShift(phi-psi2, 2.), pt-area*fLocalRho->GetVal(), fEventPlaneWeight);
+ fHistJetPtConstituents[fInCentralitySelection]->Fill(pt-area*rho, jet->GetNumberOfConstituents(), fEventPlaneWeight);
+ fHistJetEtaRho[fInCentralitySelection]->Fill(eta, pt/area, fEventPlaneWeight);
}
}
}
//_____________________________________________________________________________
-void AliAnalysisTaskJetV2::FillQAHistograms(AliVTrack* vtrack) const
+void AliAnalysisTaskJetV2::FillWeightedQAHistograms(AliVTrack* vtrack) const
{
// fill qa histograms for pico tracks
- if(fDebug > 1) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(!vtrack) return;
AliPicoTrack* track = static_cast<AliPicoTrack*>(vtrack);
- fHistRunnumbersPhi->Fill(fMappedRunNumber, track->Phi());
- fHistRunnumbersEta->Fill(fMappedRunNumber, track->Eta());
+ fHistRunnumbersPhi->Fill(fMappedRunNumber, track->Phi(), fEventPlaneWeight);
+ fHistRunnumbersEta->Fill(fMappedRunNumber, track->Eta(), fEventPlaneWeight);
Int_t type((int)(track->GetTrackType()));
switch (type) {
case 0:
- fHistPicoCat1[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
+ fHistPicoCat1[fInCentralitySelection]->Fill(track->Eta(), track->Phi(), fEventPlaneWeight);
break;
case 1:
- fHistPicoCat2[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
+ fHistPicoCat2[fInCentralitySelection]->Fill(track->Eta(), track->Phi(), fEventPlaneWeight);
break;
case 2:
- fHistPicoCat3[fInCentralitySelection]->Fill(track->Eta(), track->Phi());
+ fHistPicoCat3[fInCentralitySelection]->Fill(track->Eta(), track->Phi(), fEventPlaneWeight);
break;
default: break;
}
}
//_____________________________________________________________________________
-void AliAnalysisTaskJetV2::FillQAHistograms(AliVEvent* vevent)
+void AliAnalysisTaskJetV2::FillWeightedQAHistograms(AliVEvent* vevent)
{
// fill qa histograms for events
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(!vevent) return;
fHistVertexz->Fill(vevent->GetPrimaryVertex()->GetZ());
fHistCentrality->Fill(fCent);
Int_t runNumber(InputEvent()->GetRunNumber());
+ if(fLeadingJet && fLeadingJetAfterSub) fHistLeadingJetBackground[fInCentralitySelection]->Fill(TMath::Abs(fLeadingJet->Eta()-fLeadingJetAfterSub->Eta()), PhaseShift(fLeadingJet->Phi()-fLeadingJetAfterSub->Phi()), fEventPlaneWeight);
for(fMappedRunNumber = 0; fMappedRunNumber < fExpectedRuns->GetSize(); fMappedRunNumber++) {
if(fExpectedRuns->At(fMappedRunNumber) == runNumber) return;
}
- if(fDebug > 0) printf("\n > TASK %s CANNOT IDENTIFY RUN - CONFIGURATION COULD BE INCORRECT < \n", GetName());
+ #ifdef DEBUGTASK
+ printf("\n > TASK %s CANNOT IDENTIFY RUN - CONFIGURATION COULD BE INCORRECT < \n", GetName());
+ #endif
+}
+//_____________________________________________________________________________
+void AliAnalysisTaskJetV2::FillWeightedTriggerQA(Double_t dPhi, Double_t pt, UInt_t trigger)
+{
+ // fill the trigger efficiency histograms
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+ // some trigger definitions for readability. the way this routine is set up is as follows
+ // 1) define combined trigger conditions, e.g. bitwise representation of a combined trigger
+ // trigger a = 0 0 1
+ // trigger b = 1 0 0
+ // combined trigger mask = 1 0 1
+ // combined trigger is mask is defined using bitwise OR
+ // 2) check the condition using bitwise AND and equals operator on unsigned integer
+ // (incoming trigger & mask) == mask
+ // 2a) which will do, when incoming trigger equals mask
+ // 1 0 1 & 1 0 1 -> 1 0 1
+ // when checked against requested mask
+ // UInt_t(1 0 1) == UInt_t(1 0 1) returns true
+ // 2b) for an imcompatible trigger, e.g.
+ // 0 0 1 & 1 0 1 -> 0 0 1
+ // UInt_t(0 0 1) == UInt_t(1 0 1) returns false
+
+ // preparing the combined trigger masks
+ UInt_t MB_EMCEJE(AliVEvent::kMB | AliVEvent::kEMCEJE);
+ UInt_t CEN_EMCEJE(AliVEvent::kCentral | AliVEvent::kEMCEJE);
+ UInt_t SEM_EMCEJE(AliVEvent::kSemiCentral | AliVEvent::kEMCEJE);
+ UInt_t ALL_EMCEJE(AliVEvent::kMB | AliVEvent::kCentral | AliVEvent::kSemiCentral | AliVEvent::kEMCEJE);
+ UInt_t MB_EMCEGA(AliVEvent::kMB | AliVEvent::kEMCEGA);
+ UInt_t CEN_EMCEGA(AliVEvent::kCentral | AliVEvent::kEMCEGA);
+ UInt_t SEM_EMCEGA(AliVEvent::kSemiCentral | AliVEvent::kEMCEGA);
+ UInt_t ALL_EMCEGA(AliVEvent::kMB | AliVEvent::kCentral | AliVEvent::kSemiCentral | AliVEvent::kEMCEGA);
+ // actual routine
+ if(IsInPlane(dPhi)) {
+ // in plane bookkeeping of fired triggers. not 'exclusive' so no == necessary
+ if(trigger == 0) fHistTriggerQAIn[fInCentralitySelection]->Fill(1, pt);
+ if(trigger & AliVEvent::kAny) fHistTriggerQAIn[fInCentralitySelection]->Fill(2, pt);
+ if(trigger & AliVEvent::kAnyINT) fHistTriggerQAIn[fInCentralitySelection]->Fill(3, pt);
+ if(trigger & AliVEvent::kMB) fHistTriggerQAIn[fInCentralitySelection]->Fill(4, pt);
+ if(trigger & AliVEvent::kCentral) fHistTriggerQAIn[fInCentralitySelection]->Fill(5, pt);
+ if(trigger & AliVEvent::kSemiCentral) fHistTriggerQAIn[fInCentralitySelection]->Fill(6, pt);
+ if(trigger & AliVEvent::kEMCEJE) fHistTriggerQAIn[fInCentralitySelection]->Fill(7, pt);
+ if(trigger & AliVEvent::kEMCEGA) fHistTriggerQAIn[fInCentralitySelection]->Fill(8, pt);
+ // in plane bookkeeping of trigger combinations (for efficiency)
+ if((trigger & MB_EMCEJE) == MB_EMCEJE) fHistTriggerQAIn[fInCentralitySelection]->Fill(9, pt);
+ if((trigger & CEN_EMCEJE) == CEN_EMCEJE) fHistTriggerQAIn[fInCentralitySelection]->Fill(10, pt);
+ if((trigger & SEM_EMCEJE) == SEM_EMCEJE) fHistTriggerQAIn[fInCentralitySelection]->Fill(11, pt);
+ if((trigger & ALL_EMCEJE) == ALL_EMCEJE) fHistTriggerQAIn[fInCentralitySelection]->Fill(12, pt);
+ if((trigger & MB_EMCEGA) == MB_EMCEGA) fHistTriggerQAIn[fInCentralitySelection]->Fill(13, pt);
+ if((trigger & CEN_EMCEGA) == CEN_EMCEGA) fHistTriggerQAIn[fInCentralitySelection]->Fill(14, pt);
+ if((trigger & SEM_EMCEGA) == SEM_EMCEGA) fHistTriggerQAIn[fInCentralitySelection]->Fill(15, pt);
+ if((trigger & ALL_EMCEGA) == ALL_EMCEGA) fHistTriggerQAIn[fInCentralitySelection]->Fill(16, pt);
+ } else {
+ // out-of-plane bookkeeping of fired triggers. not 'exclusive' so no == necessary
+ if(trigger == 0) fHistTriggerQAOut[fInCentralitySelection]->Fill(1, pt);
+ if(trigger & AliVEvent::kAny) fHistTriggerQAOut[fInCentralitySelection]->Fill(2, pt);
+ if(trigger & AliVEvent::kAnyINT) fHistTriggerQAOut[fInCentralitySelection]->Fill(3, pt);
+ if(trigger & AliVEvent::kMB) fHistTriggerQAOut[fInCentralitySelection]->Fill(4, pt);
+ if(trigger & AliVEvent::kCentral) fHistTriggerQAOut[fInCentralitySelection]->Fill(5, pt);
+ if(trigger & AliVEvent::kSemiCentral) fHistTriggerQAOut[fInCentralitySelection]->Fill(6, pt);
+ if(trigger & AliVEvent::kEMCEJE) fHistTriggerQAOut[fInCentralitySelection]->Fill(7, pt);
+ if(trigger & AliVEvent::kEMCEGA) fHistTriggerQAOut[fInCentralitySelection]->Fill(8, pt);
+ // out-of-plane bookkeeping of trigger combinations (for efficiency)
+ if((trigger & MB_EMCEJE) == MB_EMCEJE) fHistTriggerQAOut[fInCentralitySelection]->Fill(9, pt);
+ if((trigger & CEN_EMCEJE) == CEN_EMCEJE) fHistTriggerQAOut[fInCentralitySelection]->Fill(10, pt);
+ if((trigger & SEM_EMCEJE) == SEM_EMCEJE) fHistTriggerQAOut[fInCentralitySelection]->Fill(11, pt);
+ if((trigger & ALL_EMCEJE) == ALL_EMCEJE) fHistTriggerQAOut[fInCentralitySelection]->Fill(12, pt);
+ if((trigger & MB_EMCEGA) == MB_EMCEGA) fHistTriggerQAOut[fInCentralitySelection]->Fill(13, pt);
+ if((trigger & CEN_EMCEGA) == CEN_EMCEGA) fHistTriggerQAOut[fInCentralitySelection]->Fill(14, pt);
+ if((trigger & SEM_EMCEGA) == SEM_EMCEGA) fHistTriggerQAOut[fInCentralitySelection]->Fill(15, pt);
+ if((trigger & ALL_EMCEGA) == ALL_EMCEGA) fHistTriggerQAOut[fInCentralitySelection]->Fill(16, pt);
+ }
}
//_____________________________________________________________________________
void AliAnalysisTaskJetV2::FillAnalysisSummaryHistogram() const
{
// fill the analysis summary histrogram, saves all relevant analysis settigns
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
fHistAnalysisSummary->GetXaxis()->SetBinLabel(2, "fJetRadius");
fHistAnalysisSummary->SetBinContent(2, GetJetContainer()->GetJetRadius());
fHistAnalysisSummary->GetXaxis()->SetBinLabel(3, "fJetEtaMin");
// terminate
switch (fRunModeType) {
case kLocal : {
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
AliAnalysisTaskJetV2::Dump();
for(Int_t i(0); i < fHistAnalysisSummary->GetXaxis()->GetNbins(); i++) printf( " > flag: %s \t content %.2f \n", fHistAnalysisSummary->GetXaxis()->GetBinLabel(1+i), fHistAnalysisSummary->GetBinContent(1+i));
} break;
void AliAnalysisTaskJetV2::SetModulationFit(TF1* fit)
{
// set modulation fit
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if (fFitModulation) delete fFitModulation;
fFitModulation = fit;
}
void AliAnalysisTaskJetV2::SetUseControlFit(Bool_t c)
{
// set control fit
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if (fFitControl) delete fFitControl;
if (c) {
fFitControl = new TF1("controlFit", "pol0", 0, TMath::TwoPi());
{
// INTERFACE METHOD FOR OUTPUTFILE
// get the detector resolution, user has ownership of the returned histogram
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
if(!fOutputList) {
printf(" > Please add fOutputList first < \n");
return 0x0;
{
// INTERFACE METHOD FOR OUTPUT FILE
// correct the supplied differential vn histogram v for detector resolution
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
TH1F* r(GetResolutionFromOuptutFile(det, h, cen));
if(!r) {
printf(" > Couldn't find resolution < \n");
// INTERFACE METHOD FOR OUTPUT FILE
// correct the supplied intetrated vn histogram v for detector resolution
// integrated vn must have the same centrality binning as the resolotion correction
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
TH1F* r(GetResolutionFromOuptutFile(det, h, cen));
v->Divide(v, r);
return v;
TH1F* AliAnalysisTaskJetV2::GetDifferentialQC(TProfile* refCumulants, TProfile* diffCumlants, TArrayD* ptBins, Int_t h)
{
// get differential QC
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Double_t r(refCumulants->GetBinContent(h-1)); // v2 reference flow
if(r > 0) r = TMath::Sqrt(r);
TH1F* qc = new TH1F(Form("QC2v%i", h), Form("QC2v%i", h), ptBins->GetSize()-1, ptBins->GetArray());
}
return qc;
}
-
//_____________________________________________________________________________
void AliAnalysisTaskJetV2::ReadVZEROCalibration2010h()
{
// necessary for calibration of 10h vzero event plane. code copied from flow package
// (duplicate, but i didn't want to introduce an ulgy dependency )
// this function is only called when the runnumber changes
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
// 1) check if the proper chi weights for merging vzero a and vzero c ep are present
// if not, use sane defaults. centrality binning is equal to that given in the fVZEROcentralityBin snippet
Int_t AliAnalysisTaskJetV2::GetVZEROCentralityBin() const
{
// return cache index number corresponding to the event centrality
- if(fDebug > 0) printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
Float_t v0Centr(InputEvent()->GetCentrality()->GetCentralityPercentile("V0M"));
if(v0Centr < 5) return 0;
else if(v0Centr < 10) return 1;
else return 8;
}
//_____________________________________________________________________________
+AliEmcalJet* AliAnalysisTaskJetV2::GetLeadingJet(AliLocalRhoParameter* localRho) {
+ // return pointer to the highest pt jet (before background subtraction) within acceptance
+ // only rudimentary cuts are applied on this level, hence the implementation outside of
+ // the framework
+ #ifdef DEBUGTASK
+ printf("__FILE__ = %s \n __LINE __ %i , __FUNC__ %s \n ", __FILE__, __LINE__, __func__);
+ #endif
+ Int_t iJets(fJets->GetEntriesFast());
+ Double_t pt(0);
+ AliEmcalJet* leadingJet(0x0);
+ if(!localRho) {
+ for(Int_t i(0); i < iJets; i++) {
+ AliEmcalJet* jet = static_cast<AliEmcalJet*>(fJets->At(i));
+ if(!PassesSimpleCuts(jet)) continue;
+ if(jet->Pt() > pt) {
+ leadingJet = jet;
+ pt = leadingJet->Pt();
+ }
+ }
+ return leadingJet;
+ } else {
+ // return leading jet after background subtraction
+ Double_t rho(0);
+ for(Int_t i(0); i < iJets; i++) {
+ AliEmcalJet* jet = static_cast<AliEmcalJet*>(fJets->At(i));
+ if(!PassesSimpleCuts(jet)) continue;
+ rho = localRho->GetLocalVal(jet->Phi(), GetJetContainer()->GetJetRadius(), localRho->GetVal());
+ if((jet->Pt()-jet->Area()*rho) > pt) {
+ leadingJet = jet;
+ pt = (leadingJet->Pt()-jet->Area()*rho);
+ }
+ }
+ return leadingJet;
+
+ }
+ return 0x0;
+}
+//_____________________________________________________________________________
+TH1F* AliAnalysisTaskJetV2::GetEventPlaneWeights(TH1F* hist)
+{
+ // get event weights distribution from event plane distribution
+ TH1F* temp((TH1F*)hist->Clone("EP_weights"));
+ Double_t integral(hist->Integral()/hist->GetNbinsX());
+ // loop over bins and extract the weights
+ for(Int_t i(0); i < hist->GetNbinsX(); i++) {
+ temp->SetBinError(1+i, 0.); // uncertainty is irrelevant
+ temp->SetBinContent(1+i, integral/hist->GetBinContent(1+i));
+ }
+ return temp;
+}
+//_____________________________________________________________________________
+void AliAnalysisTaskJetV2::PrintTriggerSummary(UInt_t trigger)
+{
+ // test function to print binary representation of given trigger mask
+ // trigger mask is represented by 32 bits (hardcoded as it is an UInt_t )
+ TString triggerName[] = { // trigger names and their corresponding bits. some bits have multiple names
+ "kMB", // 0
+ "kINT7", // 1
+ "kMUON", // 2
+ "kHighMult", // 3
+ "kEMC1", // 4
+ "kCINT5", // 5
+ "kCMUS5 kMUSPB", // 6
+ "kMUSH7 kMUSHPB", // 7
+ "kMUL7 kMuonLikePB", // 8
+ "kMUU7 kMuonUnlikePB", // 9
+ "kEMC7 kEMC8", // 10
+ "kMUS7", // 11
+ "kPHI1", // 12
+ "kPHI7 kPHI8 kPHOSPb", // 13
+ "kEMCEJE", // 14
+ "kEMCEGA", // 15
+ "kCentral", // 16
+ "kSemiCentral", // 17
+ "kDG5", // 18
+ "kZED", // 19
+ "kSPI7 kSPI", // 20
+ "kINT8", // 21
+ "kMuonSingleLowPt", // 22
+ "kMuonSingleHighPt8", // 23
+ "kMuonLikeLowPt8", // 24
+ "kMuonUnlikeLowPt8", // 25
+ "kMuonUnlikeLowPt0", // 26
+ "kUserDefined", // 27
+ "kTRD"}; // 28
+ TString notTriggered = "not fired";
+ printf(" > trigger is %u \n ", trigger);
+
+ // extract which triggers have been fired exactly and print summary of bits
+ for (Int_t i(0); i < 29; i++) printf("[bit %i]\t [%u] [%s]\n", i, (trigger & ((UInt_t)1 << i)) ? 1U : 0U, (trigger & ((UInt_t)1 << i)) ? triggerName[i].Data() : notTriggered.Data());
+
+ // print accepted trigger combinations
+ printf(" ====== accepted trigger combinations ======= \n");
+ UInt_t MB_EMCEJE(AliVEvent::kMB | AliVEvent::kEMCEJE);
+ UInt_t CEN_EMCEJE(AliVEvent::kCentral | AliVEvent::kEMCEJE);
+ UInt_t SEM_EMCEJE(AliVEvent::kSemiCentral | AliVEvent::kEMCEJE);
+ UInt_t ALL_EMCEJE(AliVEvent::kMB | AliVEvent::kCentral | AliVEvent::kSemiCentral | AliVEvent::kEMCEJE);
+ UInt_t MB_EMCEGA(AliVEvent::kMB | AliVEvent::kEMCEGA);
+ UInt_t CEN_EMCEGA(AliVEvent::kCentral | AliVEvent::kEMCEGA);
+ UInt_t SEM_EMCEGA(AliVEvent::kSemiCentral | AliVEvent::kEMCEGA);
+ UInt_t ALL_EMCEGA(AliVEvent::kMB | AliVEvent::kCentral | AliVEvent::kSemiCentral | AliVEvent::kEMCEGA);
+ if(trigger == 0) printf("(trigger == 0)\n");
+ if(trigger & AliVEvent::kAny) printf("(trigger & AliVEvent::kAny)\n");
+ if(trigger & AliVEvent::kAnyINT) printf("(trigger & AliVEvent::kAnyINT\n");
+ if(trigger & AliVEvent::kMB) printf("(trigger & AliVEvent::kMB)\n");
+ if(trigger & AliVEvent::kCentral) printf("(trigger & AliVEvent::kCentral)\n");
+ if(trigger & AliVEvent::kSemiCentral) printf("(trigger & AliVEvent::kSemiCentral)\n");
+ if(trigger & AliVEvent::kEMCEJE) printf("(trigger & AliVEvent::kEMCEJE)\n");
+ if(trigger & AliVEvent::kEMCEGA) printf("(trigger & AliVEvent::kEMCEGA)\n");
+ if((trigger & MB_EMCEJE) == MB_EMCEJE) printf("(trigger & MB_EMCEJE) == MB_EMCEJE)\n");
+ if((trigger & CEN_EMCEJE) == CEN_EMCEJE) printf("(trigger & CEN_EMCEJE) == CEN_EMCEJE)\n");
+ if((trigger & SEM_EMCEJE) == SEM_EMCEJE) printf("(trigger & SEM_EMCEJE) == SEM_EMCEJE)\n");
+ if((trigger & ALL_EMCEJE) == ALL_EMCEJE) printf("(trigger & ALL_EMCEJE) == ALL_EMCEJE)\n");
+ if((trigger & MB_EMCEGA) == MB_EMCEGA) printf("(trigger & MB_EMCEGA) == MB_EMCEGA)\n");
+ if((trigger & CEN_EMCEGA) == CEN_EMCEGA) printf("(trigger & CEN_EMCEGA) == CEN_EMCEGA)\n");
+ if((trigger & SEM_EMCEGA) == SEM_EMCEGA) printf("(trigger & SEM_EMCEGA) == SEM_EMCEGA)\n");
+ if((trigger & ALL_EMCEGA) == ALL_EMCEGA) printf("(trigger & ALL_EMCEGA) == ALL_EMCEGA)\n");
+}
+//_____________________________________________________________________________