-// now in options\r
-//=============================================//\r
-//const char* centralityEstimator = "V0M";\r
-//const char* centralityEstimator = "CL1";\r
-//const char* centralityEstimator = "TRK";\r
-//=============================================//\r
-//Bool_t gRunShuffling = kFALSE;\r
-//Bool_t gRunShuffling = kTRUE;\r
-//=============================================//\r
-\r
-//PID config\r
-Bool_t kUseNSigmaPID = kFALSE;\r
-Double_t nSigmaMax = 3.0;\r
-Bool_t kUseBayesianPID = kTRUE;\r
-Double_t gMinAcceptedProbability = 0.7;\r
-\r
-//_________________________________________________________//\r
-AliAnalysisTaskBFPsi *AddTaskBalancePsiCentralityTrain(Double_t centrMin=0.,\r
- Double_t centrMax=100.,\r
- Bool_t gRunShuffling=kFALSE,\r
- Bool_t gRunMixing=kTRUE,\r
- Bool_t gRunMixingWithEventPlane=kFALSE,\r
- TString centralityEstimator="V0M",\r
- Double_t vertexZ=10.,\r
- Double_t DCAxy=-1,\r
- Double_t DCAz=-1,\r
- Double_t ptMin=0.3,\r
- Double_t ptMax=1.5,\r
- Double_t etaMin=-0.8,\r
- Double_t etaMax=0.8,\r
- Double_t maxTPCchi2 = -1, \r
- Int_t minNClustersTPC = -1,\r
- Bool_t kUsePID = kFALSE,\r
- Bool_t bResonancesCut = kTRUE,\r
- Bool_t bHBTcut = kTRUE,\r
- Double_t HBTCutValue = 0.02,\r
- Bool_t bConversionCut = kTRUE,\r
- Double_t invMassForConversionCut = 0.04,\r
- Bool_t bMomentumDifferenceCut = kTRUE,\r
- Double_t fQCutMin = 0.0,\r
- Int_t AODfilterBit = 128,\r
- Bool_t bCentralTrigger = kFALSE,\r
- TString fileNameBase="AnalysisResults",\r
- TString dirNameExtra="",\r
- TString fArgEventClass="Centrality",\r
- TString analysisTypeUser="AOD",\r
- Bool_t bVertexBinning=kTRUE,\r
- Double_t sigmaElectronRejection=3,\r
- Bool_t electronExclusiveRejection=kFALSE,\r
- TString correctionFileName = "",\r
- Int_t nCentralityArrayBinsForCorrection,\r
- Double_t *gCentralityArrayForCorrections) {\r
- // Creates a balance function analysis task and adds it to the analysis manager.\r
- // Get the pointer to the existing analysis manager via the static access method.\r
- TString outputFileName(fileNameBase);\r
- outputFileName.Append(".root");\r
-\r
- //===========================================================================\r
- AliAnalysisManager *mgr = AliAnalysisManager::GetAnalysisManager();\r
- if (!mgr) {\r
- ::Error("AddTaskBF", "No analysis manager to connect to.");\r
- return NULL;\r
- }\r
-\r
- // Check the analysis type using the event handlers connected to the analysis manager.\r
- //===========================================================================\r
- if (!mgr->GetInputEventHandler()) {\r
- ::Error("AddTaskBF", "This task requires an input event handler");\r
- return NULL;\r
- }\r
- TString analysisType = mgr->GetInputEventHandler()->GetDataType(); // can be "ESD" or "AOD"\r
- if(dynamic_cast<AliMCEventHandler*> (AliAnalysisManager::GetAnalysisManager()->GetMCtruthEventHandler())) analysisType = "MC";\r
- \r
- // to set the analysis type manually\r
- if(analysisTypeUser != ""){\r
- analysisType = analysisTypeUser;\r
- ::Info("AddTaskBF",Form("Analysis Type manually set to %s",analysisType.Data()));\r
- }\r
-\r
- // for local changed BF configuration\r
- //gROOT->LoadMacro("./configBalanceFunctionPsiAnalysis.C");\r
- gROOT->LoadMacro("$ALICE_ROOT/PWGCF/EBYE/macros/configBalanceFunctionPsiAnalysis.C");\r
- AliBalancePsi *bf = 0; // Balance Function object\r
- AliBalancePsi *bfs = 0; // shuffled Balance function object\r
- AliBalancePsi *bfm = 0; // mixing Balance function object\r
-\r
- //maximum Delta eta range\r
- Double_t deltaEtaMax=TMath::Abs(etaMax-etaMin);\r
-\r
- if (analysisType=="ESD"){\r
- bf = GetBalanceFunctionObject("ESD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunShuffling) bfs = GetBalanceFunctionObject("ESD",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunMixing) bfm = GetBalanceFunctionObject("ESD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- }\r
- else if (analysisType=="AOD"){\r
- bf = GetBalanceFunctionObject("AOD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunShuffling) bfs = GetBalanceFunctionObject("AOD",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunMixing) bfm = GetBalanceFunctionObject("AOD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- }\r
- else if (analysisType=="MC"){\r
- bf = GetBalanceFunctionObject("MC",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunShuffling) bfs = GetBalanceFunctionObject("MC",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunMixing) bfm = GetBalanceFunctionObject("MC",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- }\r
- else if (analysisType=="MCAOD"){\r
- bf = GetBalanceFunctionObject("MCAOD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunShuffling) bfs = GetBalanceFunctionObject("MCAOD",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunMixing) bfm = GetBalanceFunctionObject("MCAOD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- }\r
- else if (analysisType=="MCAODrec"){\r
- bf = GetBalanceFunctionObject("MCAODrec",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunShuffling) bfs = GetBalanceFunctionObject("MCAODrec",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- if(gRunMixing) bfm = GetBalanceFunctionObject("MCAODrec",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);\r
- }\r
- else{\r
- ::Error("AddTaskBF", "analysis type NOT known.");\r
- return NULL;\r
- }\r
-\r
- // Create the task, add it to manager and configure it.\r
- //===========================================================================\r
- AliAnalysisTaskBFPsi *taskBF = new AliAnalysisTaskBFPsi(Form("TaskBFPsi_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()));\r
- \r
- //Event characteristics scheme\r
- taskBF->SetEventClass(fArgEventClass);\r
- if(fArgEventClass == "Multiplicity") {\r
- taskBF->SetMultiplicityRange(centrMin,centrMax);\r
- taskBF->SetMultiplicityEstimator(centralityEstimator);\r
- cout<<"Multiplicity estimator "<<centralityEstimator.Data()<<endl;\r
- }\r
- else if(fArgEventClass == "Centrality") {\r
- if(analysisType == "MC")\r
- taskBF->SetImpactParameterRange(centrMin,centrMax);\r
- else {\r
- taskBF->SetCentralityPercentileRange(centrMin,centrMax);\r
- // centrality estimator (default = V0M)\r
- taskBF->SetCentralityEstimator(centralityEstimator);\r
- cout<<"Centrality estimator "<<centralityEstimator.Data()<<endl;\r
- }\r
- }\r
-\r
- //++++++++++++++++++++++\r
- // Efficiency + Contamination corrections\r
- // If correctionFileName = "", do not use corrections\r
- if(correctionFileName != "")\r
- taskBF->SetInputCorrection(Form("$ALICE_ROOT/PWGCF/EBYE/BalanceFunctions/Corrections/%s",correctionFileName.Data()),nCentralityArrayBinsForCorrection,gCentralityArrayForCorrections);\r
-\r
- //+++++++++++++++++++++\r
-\r
- taskBF->SetAnalysisObject(bf);\r
- if(gRunShuffling) taskBF->SetShufflingObject(bfs);\r
- if(gRunMixing){\r
- taskBF->SetMixingObject(bfm);\r
- taskBF->SetMixingTracks(50000);\r
- if(gRunMixingWithEventPlane){\r
- taskBF->SetMixingWithEventPlane(gRunMixingWithEventPlane);\r
- }\r
- }\r
-\r
- if(analysisType == "ESD") {\r
- AliESDtrackCuts *trackCuts = GetTrackCutsObject(ptMin,ptMax,etaMin,etaMax,maxTPCchi2,DCAxy,DCAz,minNClustersTPC);\r
- taskBF->SetAnalysisCutObject(trackCuts);\r
- if(kUsePID) {\r
- if(kUseBayesianPID)\r
- taskBF->SetUseBayesianPID(gMinAcceptedProbability);\r
- else if(kUseNSigmaPID)\r
- taskBF->SetUseNSigmaPID(nSigmaMax);\r
- taskBF->SetParticleOfInterest(AliAnalysistaskBFPsi::kProton);\r
- taskBF->SetDetectorUsedForPID(AliAnalysisTaskBFPsi::kTOFpid);\r
- }\r
- }\r
- else if(analysisType == "AOD") {\r
- // pt and eta cut (pt_min, pt_max, eta_min, eta_max)\r
- taskBF->SetAODtrackCutBit(AODfilterBit);\r
- taskBF->SetKinematicsCutsAOD(ptMin,ptMax,etaMin,etaMax);\r
-\r
- // set extra DCA cuts (-1 no extra cut)\r
- taskBF->SetExtraDCACutsAOD(DCAxy,DCAz);\r
-\r
- // set extra TPC chi2 / nr of clusters cut\r
- taskBF->SetExtraTPCCutsAOD(maxTPCchi2, minNClustersTPC);\r
-\r
- // electron rejection (so far only for AOD), <0 --> no rejection\r
- if(sigmaElectronRejection > 0){\r
- if(electronExclusiveRejection) taskBF->SetElectronOnlyRejection(sigmaElectronRejection); // no other particle in nsigma \r
- else taskBF->SetElectronRejection(sigmaElectronRejection); // check only if electrons in nsigma\r
- }\r
- }\r
- else if(analysisType == "MC") {\r
- taskBF->SetKinematicsCutsAOD(ptMin,ptMax,etaMin,etaMax); \r
- taskBF->SetImpactParameterRange(centrMin,centrMax);\r
- }\r
- else if(analysisType == "MCAOD") {\r
- // pt and eta cut (pt_min, pt_max, eta_min, eta_max)\r
- taskBF->SetAODtrackCutBit(AODfilterBit);\r
- taskBF->SetKinematicsCutsAOD(ptMin,ptMax,etaMin,etaMax); \r
- }\r
- else if(analysisType == "MCAODrec") { //++++++++++++++++\r
- // pt and eta cut (pt_min, pt_max, eta_min, eta_max)\r
- taskBF->SetAODtrackCutBit(AODfilterBit);\r
- taskBF->SetKinematicsCutsAOD(ptMin,ptMax,etaMin,etaMax); \r
-\r
- // set extra DCA cuts (-1 no extra cut)\r
- taskBF->SetExtraDCACutsAOD(DCAxy,DCAz);\r
-\r
- // set extra TPC chi2 / nr of clusters cut\r
- taskBF->SetExtraTPCCutsAOD(maxTPCchi2, minNClustersTPC);\r
-\r
- // electron rejection (so far only for AOD), <0 --> no rejection\r
- if(sigmaElectronRejection > 0){\r
- if(electronExclusiveRejection) taskBF->SetElectronOnlyRejection(sigmaElectronRejection); // no other particle in nsigma \r
- else taskBF->SetElectronRejection(sigmaElectronRejection); // check only if electrons in nsigma\r
- }\r
- }//++++++++++++++++\r
-\r
- // offline trigger selection (AliVEvent.h)\r
- // taskBF->UseOfflineTrigger(); // NOT used (selection is done with the AliAnalysisTaskSE::SelectCollisionCandidates()) \r
- // with this only selected events are analyzed (first 2 bins in event QA histogram are the same))\r
- // documentation in https://twiki.cern.ch/twiki/bin/viewauth/ALICE/PWG1EvSelDocumentation\r
- if(bCentralTrigger) taskBF->SelectCollisionCandidates(AliVEvent::kMB | AliVEvent::kCentral | AliVEvent::kSemiCentral);\r
- else taskBF->SelectCollisionCandidates(AliVEvent::kMB);\r
-\r
- // centrality estimator (default = V0M)\r
- taskBF->SetCentralityEstimator(centralityEstimator);\r
- \r
- // vertex cut (x,y,z)\r
- taskBF->SetVertexDiamond(3.,3.,vertexZ);\r
- \r
-\r
-\r
- //bf->PrintAnalysisSettings();\r
- mgr->AddTask(taskBF);\r
- \r
- // Create ONLY the output containers for the data produced by the task.\r
- // Get and connect other common input/output containers via the manager as below\r
- //==============================================================================\r
- TString outputFileName = AliAnalysisManager::GetCommonFileName();\r
- outputFileName += ":PWGCFEbyE.outputBalanceFunctionPsiAnalysis";\r
- AliAnalysisDataContainer *coutQA = mgr->CreateContainer(Form("listQAPsi_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());\r
- AliAnalysisDataContainer *coutBF = mgr->CreateContainer(Form("listBFPsi_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());\r
- if(gRunShuffling) AliAnalysisDataContainer *coutBFS = mgr->CreateContainer(Form("listBFPsiShuffled_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());\r
- if(gRunMixing) AliAnalysisDataContainer *coutBFM = mgr->CreateContainer(Form("listBFPsiMixed_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());\r
- if(kUsePID || sigmaElectronRejection > 0) AliAnalysisDataContainer *coutQAPID = mgr->CreateContainer(Form("listQAPIDPsi_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());\r
-\r
- mgr->ConnectInput(taskBF, 0, mgr->GetCommonInputContainer());\r
- mgr->ConnectOutput(taskBF, 1, coutQA);\r
- mgr->ConnectOutput(taskBF, 2, coutBF);\r
- if(gRunShuffling) mgr->ConnectOutput(taskBF, 3, coutBFS);\r
- if(gRunMixing) mgr->ConnectOutput(taskBF, 4, coutBFM);\r
- if((kUsePID && analysisType == "ESD")||sigmaElectronRejection > 0) mgr->ConnectOutput(taskBF, 5, coutQAPID);\r
-\r
- return taskBF;\r
-}\r
+// now in options
+//=============================================//
+//const char* centralityEstimator = "V0M";
+//const char* centralityEstimator = "CL1";
+//const char* centralityEstimator = "TRK";
+//=============================================//
+//Bool_t gRunShuffling = kFALSE;
+//Bool_t gRunShuffling = kTRUE;
+//=============================================//
+
+//PID config
+Bool_t kUseNSigmaPID = kTRUE;
+Double_t nSigmaMax = 3.0;
+Bool_t kUseBayesianPID = kFALSE;
+Double_t gMinAcceptedProbability = 0.7;
+
+//_________________________________________________________//
+AliAnalysisTaskBFPsi *AddTaskBalancePsiCentralityTrain(Double_t centrMin=0.,
+ Double_t centrMax=100.,
+ Bool_t gRunShuffling=kFALSE,
+ Bool_t gRunMixing=kTRUE,
+ Bool_t gRunMixingWithEventPlane=kFALSE,
+ TString centralityEstimator="V0M",
+ Double_t vertexZ=10.,
+ Double_t DCAxy=-1,
+ Double_t DCAz=-1,
+ Double_t ptMin=0.3,
+ Double_t ptMax=1.5,
+ Double_t etaMin=-0.8,
+ Double_t etaMax=0.8,
+ Double_t maxTPCchi2 = -1,
+ Int_t minNClustersTPC = -1,
+ Bool_t kUsePID = kTRUE,
+ Bool_t bResonancesCut = kTRUE,
+ Bool_t bHBTcut = kTRUE,
+ Double_t HBTCutValue = 0.02,
+ Bool_t bConversionCut = kTRUE,
+ Double_t invMassForConversionCut = 0.04,
+ Bool_t bMomentumDifferenceCut = kTRUE,
+ Double_t fQCutMin = 0.0,
+ Int_t AODfilterBit = 128,
+ Bool_t bCentralTrigger = kFALSE,
+ TString fileNameBase="AnalysisResults",
+ TString dirNameExtra="",
+ TString fArgEventClass="Centrality",
+ TString analysisTypeUser="AOD",
+ Bool_t bVertexBinning=kTRUE,
+ Double_t sigmaElectronRejection=3,
+ Bool_t electronExclusiveRejection=kFALSE,
+ TString correctionFileName = "",
+ Int_t nCentralityArrayBinsForCorrection,
+ Double_t *gCentralityArrayForCorrections) {
+ // Creates a balance function analysis task and adds it to the analysis manager.
+ // Get the pointer to the existing analysis manager via the static access method.
+ TString outputFileName(fileNameBase);
+ outputFileName.Append(".root");
+
+ //===========================================================================
+ AliAnalysisManager *mgr = AliAnalysisManager::GetAnalysisManager();
+ if (!mgr) {
+ ::Error("AddTaskBF", "No analysis manager to connect to.");
+ return NULL;
+ }
+
+ // Check the analysis type using the event handlers connected to the analysis manager.
+ //===========================================================================
+ if (!mgr->GetInputEventHandler()) {
+ ::Error("AddTaskBF", "This task requires an input event handler");
+ return NULL;
+ }
+ TString analysisType = mgr->GetInputEventHandler()->GetDataType(); // can be "ESD" or "AOD"
+ if(dynamic_cast<AliMCEventHandler*> (AliAnalysisManager::GetAnalysisManager()->GetMCtruthEventHandler())) analysisType = "MC";
+
+ // to set the analysis type manually
+ if(analysisTypeUser != ""){
+ analysisType = analysisTypeUser;
+ ::Info("AddTaskBF",Form("Analysis Type manually set to %s",analysisType.Data()));
+ }
+
+ // for local changed BF configuration
+ //gROOT->LoadMacro("./configBalanceFunctionPsiAnalysis.C");
+ gROOT->LoadMacro("$ALICE_ROOT/PWGCF/EBYE/macros/configBalanceFunctionPsiAnalysis.C");
+ AliBalancePsi *bf = 0; // Balance Function object
+ AliBalancePsi *bfs = 0; // shuffled Balance function object
+ AliBalancePsi *bfm = 0; // mixing Balance function object
+
+ //maximum Delta eta range
+ Double_t deltaEtaMax=TMath::Abs(etaMax-etaMin);
+
+ if (analysisType=="ESD"){
+ bf = GetBalanceFunctionObject("ESD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunShuffling) bfs = GetBalanceFunctionObject("ESD",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunMixing) bfm = GetBalanceFunctionObject("ESD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ }
+ else if (analysisType=="AOD"){
+ bf = GetBalanceFunctionObject("AOD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunShuffling) bfs = GetBalanceFunctionObject("AOD",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunMixing) bfm = GetBalanceFunctionObject("AOD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ }
+ else if (analysisType=="MC"){
+ bf = GetBalanceFunctionObject("MC",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunShuffling) bfs = GetBalanceFunctionObject("MC",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunMixing) bfm = GetBalanceFunctionObject("MC",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ }
+ else if (analysisType=="MCAOD"){
+ bf = GetBalanceFunctionObject("MCAOD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunShuffling) bfs = GetBalanceFunctionObject("MCAOD",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunMixing) bfm = GetBalanceFunctionObject("MCAOD",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ }
+ else if (analysisType=="MCAODrec"){
+ bf = GetBalanceFunctionObject("MCAODrec",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunShuffling) bfs = GetBalanceFunctionObject("MCAODrec",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunMixing) bfm = GetBalanceFunctionObject("MCAODrec",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ }
+ else if (analysisType=="AODnano"){
+ bf = GetBalanceFunctionObject("AODnano",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunShuffling) bfs = GetBalanceFunctionObject("AODnano",centralityEstimator,centrMin,centrMax,kTRUE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ if(gRunMixing) bfm = GetBalanceFunctionObject("AODnano",centralityEstimator,centrMin,centrMax,kFALSE,bResonancesCut,bHBTcut,HBTCutValue,bConversionCut,invMassForConversionCut,bMomentumDifferenceCut,fQCutMin,fArgEventClass,deltaEtaMax,bVertexBinning);
+ }
+ else{
+ ::Error("AddTaskBF", "analysis type NOT known.");
+ return NULL;
+ }
+
+ // Create the task, add it to manager and configure it.
+ //===========================================================================
+ AliAnalysisTaskBFPsi *taskBF = new AliAnalysisTaskBFPsi(Form("TaskBFPsi_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()));
+
+ //Event characteristics scheme
+ taskBF->SetEventClass(fArgEventClass);
+ //taskBF->SetCustomBinning("centralityVertex:0,80");
+ //taskBF->SetCustomBinning("multiplicity:0,260");
+
+ if(fArgEventClass == "Multiplicity") {
+ taskBF->SetMultiplicityRange(centrMin,centrMax);
+ taskBF->SetMultiplicityEstimator(centralityEstimator);
+ cout<<"Multiplicity estimator "<<centralityEstimator.Data()<<endl;
+ }
+ else if(fArgEventClass == "Centrality") {
+ if(analysisType == "MC")
+ taskBF->SetImpactParameterRange(centrMin,centrMax);
+ else {
+ taskBF->SetCentralityPercentileRange(centrMin,centrMax);
+ // centrality estimator (default = V0M)
+ taskBF->SetCentralityEstimator(centralityEstimator);
+ cout<<"Centrality estimator "<<centralityEstimator.Data()<<endl;
+ }
+ }
+
+ //++++++++++++++++++++++
+ // Efficiency + Contamination corrections
+ // If correctionFileName = "", do not use corrections
+ if(correctionFileName != "")
+ taskBF->SetInputCorrection(Form("$ALICE_ROOT/PWGCF/EBYE/BalanceFunctions/Corrections/%s",correctionFileName.Data()),nCentralityArrayBinsForCorrection,gCentralityArrayForCorrections);
+
+ //+++++++++++++++++++++
+
+ taskBF->SetAnalysisObject(bf);
+ if(gRunShuffling) taskBF->SetShufflingObject(bfs);
+ if(gRunMixing){
+ taskBF->SetMixingObject(bfm);
+ taskBF->SetMixingTracks(50000);
+ if(gRunMixingWithEventPlane){
+ taskBF->SetMixingWithEventPlane(gRunMixingWithEventPlane);
+ }
+ }
+
+ if(analysisType == "ESD") {
+ AliESDtrackCuts *trackCuts = GetTrackCutsObject(ptMin,ptMax,etaMin,etaMax,maxTPCchi2,DCAxy,DCAz,minNClustersTPC);
+ taskBF->SetAnalysisCutObject(trackCuts);
+ if(kUsePID) {
+ if(kUseBayesianPID)
+ taskBF->SetUseBayesianPID(gMinAcceptedProbability);
+ else if(kUseNSigmaPID)
+ taskBF->SetUseNSigmaPID(nSigmaMax);
+ taskBF->SetParticleOfInterest(AliAnalysisTaskBFPsi::kPion);
+ taskBF->SetDetectorUsedForPID(AliAnalysisTaskBFPsi::kTOFpid);
+ }
+ }
+ else if(analysisType == "AOD" || analysisType == "AODnano") {
+ // pt and eta cut (pt_min, pt_max, eta_min, eta_max)
+ taskBF->SetAODtrackCutBit(AODfilterBit);
+ taskBF->SetKinematicsCutsAOD(ptMin,ptMax,etaMin,etaMax);
+
+ // set extra DCA cuts (-1 no extra cut)
+ taskBF->SetExtraDCACutsAOD(DCAxy,DCAz);
+
+ // set extra TPC chi2 / nr of clusters cut
+ taskBF->SetExtraTPCCutsAOD(maxTPCchi2, minNClustersTPC);
+
+ // electron rejection (so far only for AOD), <0 --> no rejection
+ if(sigmaElectronRejection > 0){
+ if(electronExclusiveRejection) taskBF->SetElectronOnlyRejection(sigmaElectronRejection); // no other particle in nsigma
+ else taskBF->SetElectronRejection(sigmaElectronRejection); // check only if electrons in nsigma
+ }
+
+ //++++++++++++++++//
+ if(kUsePID) {
+ if(kUseBayesianPID)
+ taskBF->SetUseBayesianPID(gMinAcceptedProbability);
+ else if(kUseNSigmaPID)
+ taskBF->SetUseNSigmaPID(nSigmaMax);
+ taskBF->SetParticleOfInterest(AliAnalysisTaskBFPsi::kKaon);
+ taskBF->SetDetectorUsedForPID(AliAnalysisTaskBFPsi::kTPCTOF); //TOFpid,TPCpid
+ }
+ //++++++++++++++++//
+
+ }
+ else if(analysisType == "MC") {
+ taskBF->SetKinematicsCutsAOD(ptMin,ptMax,etaMin,etaMax);
+ }
+ else if(analysisType == "MCAOD") {
+ // pt and eta cut (pt_min, pt_max, eta_min, eta_max)
+ taskBF->SetAODtrackCutBit(AODfilterBit);
+ taskBF->SetKinematicsCutsAOD(ptMin,ptMax,etaMin,etaMax);
+ }
+ else if(analysisType == "MCAODrec") { //++++++++++++++++
+ // pt and eta cut (pt_min, pt_max, eta_min, eta_max)
+ taskBF->SetAODtrackCutBit(AODfilterBit);
+ taskBF->SetKinematicsCutsAOD(ptMin,ptMax,etaMin,etaMax);
+
+ // set extra DCA cuts (-1 no extra cut)
+ taskBF->SetExtraDCACutsAOD(DCAxy,DCAz);
+
+ // set extra TPC chi2 / nr of clusters cut
+ taskBF->SetExtraTPCCutsAOD(maxTPCchi2, minNClustersTPC);
+
+ // electron rejection (so far only for AOD), <0 --> no rejection
+ if(sigmaElectronRejection > 0){
+ if(electronExclusiveRejection) taskBF->SetElectronOnlyRejection(sigmaElectronRejection); // no other particle in nsigma
+ else taskBF->SetElectronRejection(sigmaElectronRejection); // check only if electrons in nsigma
+ }
+ }//++++++++++++++++
+
+ // offline trigger selection (AliVEvent.h)
+ // taskBF->UseOfflineTrigger(); // NOT used (selection is done with the AliAnalysisTaskSE::SelectCollisionCandidates())
+ // with this only selected events are analyzed (first 2 bins in event QA histogram are the same))
+ // documentation in https://twiki.cern.ch/twiki/bin/viewauth/ALICE/PWG1EvSelDocumentation
+ if(bCentralTrigger) taskBF->SelectCollisionCandidates(AliVEvent::kMB | AliVEvent::kCentral | AliVEvent::kSemiCentral);
+ else taskBF->SelectCollisionCandidates(AliVEvent::kMB);
+
+ // centrality estimator (default = V0M)
+ taskBF->SetCentralityEstimator(centralityEstimator);
+
+ // vertex cut (x,y,z)
+ taskBF->SetVertexDiamond(3.,3.,vertexZ);
+
+
+
+ //bf->PrintAnalysisSettings();
+ mgr->AddTask(taskBF);
+
+ // Create ONLY the output containers for the data produced by the task.
+ // Get and connect other common input/output containers via the manager as below
+ //==============================================================================
+ TString outputFileName = AliAnalysisManager::GetCommonFileName();
+ outputFileName += ":PWGCFEbyE.outputBalanceFunctionPsiAnalysis";
+ AliAnalysisDataContainer *coutQA = mgr->CreateContainer(Form("listQAPsi_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());
+ AliAnalysisDataContainer *coutBF = mgr->CreateContainer(Form("listBFPsi_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());
+ if(gRunShuffling) AliAnalysisDataContainer *coutBFS = mgr->CreateContainer(Form("listBFPsiShuffled_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());
+ if(gRunMixing) AliAnalysisDataContainer *coutBFM = mgr->CreateContainer(Form("listBFPsiMixed_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());
+ if(kUsePID || sigmaElectronRejection > 0) AliAnalysisDataContainer *coutQAPID = mgr->CreateContainer(Form("listQAPIDPsi_%.0f-%.0f_Bit%d_%s%s",centrMin,centrMax,AODfilterBit,centralityEstimator.Data(),dirNameExtra.Data()), TList::Class(),AliAnalysisManager::kOutputContainer,outputFileName.Data());
+
+ mgr->ConnectInput(taskBF, 0, mgr->GetCommonInputContainer());
+ mgr->ConnectOutput(taskBF, 1, coutQA);
+ mgr->ConnectOutput(taskBF, 2, coutBF);
+ if(gRunShuffling) mgr->ConnectOutput(taskBF, 3, coutBFS);
+ if(gRunMixing) mgr->ConnectOutput(taskBF, 4, coutBFM);
+ if(kUsePID||sigmaElectronRejection > 0) mgr->ConnectOutput(taskBF, 5, coutQAPID);
+ //if((kUsePID && analysisType == "AOD")||sigmaElectronRejection > 0) mgr->ConnectOutput(taskBF, 5, coutQAPID);
+ //if((kUsePID && analysisType == "ESD")||sigmaElectronRejection > 0) mgr->ConnectOutput(taskBF, 5, coutQAPID);
+
+ return taskBF;
+}