#include <TChain.h>
#include <TDirectory.h>
#include <TFile.h>
-#include <TH1D.h>
-#include <TH1F.h>
-#include <TH1I.h>
-#include <TH2F.h>
+#include <TH3D.h>
#include <TIterator.h>
#include <TList.h>
#include <TLegend.h>
#include <TParticle.h>
#include <TProfile.h>
#include <TString.h>
+#include <TF1.h>
#include <TTree.h>
#include "AliAODInputHandler.h"
#include "AliCFManager.h"
#include "AliESDEvent.h"
#include "AliESDInputHandler.h"
+#include "AliESDpid.h"
#include "AliESDtrack.h"
+#include "AliESDCentrality.h"
#include "AliLog.h"
#include "AliAnalysisManager.h"
#include "AliMCEvent.h"
#include "AliMCParticle.h"
#include "AliPID.h"
#include "AliStack.h"
+#include "AliTriggerAnalysis.h"
#include "AliVVertex.h"
-#include "AliHFEpid.h"
#include "AliHFEcollection.h"
+#include "AliHFEcontainer.h"
#include "AliHFEcuts.h"
+#include "AliHFEelecbackground.h"
#include "AliHFEmcQA.h"
#include "AliHFEpairs.h"
+#include "AliHFEpid.h"
+#include "AliHFEpidQAmanager.h"
#include "AliHFEpostAnalysis.h"
#include "AliHFEsecVtxs.h"
#include "AliHFEsecVtx.h"
-#include "AliHFEelecbackground.h"
+#include "AliHFEsignalCuts.h"
+#include "AliHFEtaggedTrackAnalysis.h"
#include "AliHFEtools.h"
+#include "AliHFEvarManager.h"
#include "AliAnalysisTaskHFE.h"
+ClassImp(AliAnalysisTaskHFE)
+
//____________________________________________________________
AliAnalysisTaskHFE::AliAnalysisTaskHFE():
AliAnalysisTaskSE("PID efficiency Analysis")
, fQAlevel(0)
- , fPIDdetectors("")
- , fPIDstrategy(0)
, fPlugins(0)
+ , fFillSignalOnly(kTRUE)
+ , fRemovePileUp(kFALSE)
+ , fIdentifiedAsPileUp(kFALSE)
+ , fIdentifiedAsOutInz(kFALSE)
+ , fPassTheEventCut(kFALSE)
+ , fCentralityF(99.0)
+ , fBackGroundFactorsFunction(NULL)
+ , fContainer(NULL)
+ , fVarManager(NULL)
+ , fSignalCuts(NULL)
, fCFM(NULL)
- , fCorrelation(NULL)
- , fPIDperformance(NULL)
- , fSignalToBackgroundMC(NULL)
+ , fTriggerAnalysis(NULL)
, fPID(NULL)
+ , fPIDqa(NULL)
+ , fPIDpreselect(NULL)
, fCuts(NULL)
+ , fTaggedTrackCuts(NULL)
+ , fCutspreselect(NULL)
, fSecVtx(NULL)
, fElecBackGround(NULL)
, fMCQA(NULL)
- , fNEvents(NULL)
- , fNElectronTracksEvent(NULL)
+ , fTaggedTrackAnalysis(NULL)
, fQA(NULL)
, fOutput(NULL)
, fHistMCQA(NULL)
, fHistSECVTX(NULL)
, fHistELECBACKGROUND(NULL)
-// , fQAcoll(0x0)
+ , fQACollection(NULL)
{
//
// Dummy constructor
//
- DefineOutput(1, TH1I::Class());
- DefineOutput(2, TList::Class());
- DefineOutput(3, TList::Class());
-// DefineOutput(4, TList::Class());
-
- // Initialize cuts
- fPID = new AliHFEpid;
}
//____________________________________________________________
AliAnalysisTaskHFE::AliAnalysisTaskHFE(const char * name):
AliAnalysisTaskSE(name)
, fQAlevel(0)
- , fPIDdetectors("")
- , fPIDstrategy(0)
, fPlugins(0)
+ , fFillSignalOnly(kTRUE)
+ , fRemovePileUp(kFALSE)
+ , fIdentifiedAsPileUp(kFALSE)
+ , fIdentifiedAsOutInz(kFALSE)
+ , fPassTheEventCut(kFALSE)
+ , fCentralityF(99.0)
+ , fBackGroundFactorsFunction(NULL)
+ , fContainer(NULL)
+ , fVarManager(NULL)
+ , fSignalCuts(NULL)
, fCFM(NULL)
- , fCorrelation(NULL)
- , fPIDperformance(NULL)
- , fSignalToBackgroundMC(NULL)
+ , fTriggerAnalysis(NULL)
, fPID(NULL)
+ , fPIDqa(NULL)
+ , fPIDpreselect(NULL)
, fCuts(NULL)
+ , fTaggedTrackCuts(NULL)
+ , fCutspreselect(NULL)
, fSecVtx(NULL)
, fElecBackGround(NULL)
, fMCQA(NULL)
- , fNEvents(NULL)
- , fNElectronTracksEvent(NULL)
+ , fTaggedTrackAnalysis(NULL)
, fQA(NULL)
, fOutput(NULL)
, fHistMCQA(NULL)
, fHistSECVTX(NULL)
, fHistELECBACKGROUND(NULL)
-// , fQAcoll(0x0)
+ , fQACollection(0x0)
{
//
// Default constructor
//
- DefineOutput(1, TH1I::Class());
+ DefineOutput(1, TList::Class());
DefineOutput(2, TList::Class());
- DefineOutput(3, TList::Class());
-// DefineOutput(4, TList::Class());
- // Initialize cuts
- fPID = new AliHFEpid;
+ fPID = new AliHFEpid("hfePid");
+ fVarManager = new AliHFEvarManager("hfeVarManager");
}
//____________________________________________________________
AliAnalysisTaskHFE::AliAnalysisTaskHFE(const AliAnalysisTaskHFE &ref):
AliAnalysisTaskSE(ref)
- , fQAlevel(ref.fQAlevel)
- , fPIDdetectors(ref.fPIDdetectors)
- , fPIDstrategy(ref.fPIDstrategy)
- , fPlugins(ref.fPlugins)
- , fCFM(ref.fCFM)
- , fCorrelation(ref.fCorrelation)
- , fPIDperformance(ref.fPIDperformance)
- , fSignalToBackgroundMC(ref.fSignalToBackgroundMC)
- , fPID(ref.fPID)
- , fCuts(ref.fCuts)
- , fSecVtx(ref.fSecVtx)
- , fElecBackGround(ref.fElecBackGround)
- , fMCQA(ref.fMCQA)
- , fNEvents(ref.fNEvents)
- , fNElectronTracksEvent(ref.fNElectronTracksEvent)
- , fQA(ref.fQA)
- , fOutput(ref.fOutput)
- , fHistMCQA(ref.fHistMCQA)
- , fHistSECVTX(ref.fHistSECVTX)
- , fHistELECBACKGROUND(ref.fHistELECBACKGROUND)
-// , fQAcoll(ref.fQAcoll)
+ , fQAlevel(0)
+ , fPlugins(0)
+ , fFillSignalOnly(ref.fFillSignalOnly)
+ , fRemovePileUp(ref.fRemovePileUp)
+ , fIdentifiedAsPileUp(ref.fIdentifiedAsPileUp)
+ , fIdentifiedAsOutInz(ref.fIdentifiedAsOutInz)
+ , fPassTheEventCut(ref.fPassTheEventCut)
+ , fCentralityF(ref.fCentralityF)
+ , fBackGroundFactorsFunction(NULL)
+ , fContainer(NULL)
+ , fVarManager(NULL)
+ , fSignalCuts(NULL)
+ , fCFM(NULL)
+ , fTriggerAnalysis(NULL)
+ , fPID(NULL)
+ , fPIDqa(NULL)
+ , fPIDpreselect(NULL)
+ , fCuts(NULL)
+ , fTaggedTrackCuts(NULL)
+ , fCutspreselect(NULL)
+ , fSecVtx(NULL)
+ , fElecBackGround(NULL)
+ , fMCQA(NULL)
+ , fTaggedTrackAnalysis(NULL)
+ , fQA(NULL)
+ , fOutput(NULL)
+ , fHistMCQA(NULL)
+ , fHistSECVTX(NULL)
+ , fHistELECBACKGROUND(NULL)
+ , fQACollection(NULL)
{
//
// Copy Constructor
//
+ ref.Copy(*this);
}
//____________________________________________________________
//
// Assignment operator
//
- if(this == &ref) return *this;
- AliAnalysisTask::operator=(ref);
- fQAlevel = ref.fQAlevel;
- fPIDdetectors = ref.fPIDdetectors;
- fPIDstrategy = ref.fPIDstrategy;
- fPlugins = ref.fPlugins;
- fCFM = ref.fCFM;
- fCorrelation = ref.fCorrelation;
- fPIDperformance = ref.fPIDperformance;
- fSignalToBackgroundMC = ref.fSignalToBackgroundMC;
- fPID = ref.fPID;
- fCuts = ref.fCuts;
- fSecVtx = ref.fSecVtx;
- fElecBackGround = ref.fElecBackGround;
- fMCQA = ref.fMCQA;
- fNEvents = ref.fNEvents;
- fNElectronTracksEvent = ref.fNElectronTracksEvent;
- fQA = ref.fQA;
- fOutput = ref.fOutput;
- fHistMCQA = ref.fHistMCQA;
- fHistSECVTX = ref.fHistSECVTX;
- fHistELECBACKGROUND = ref.fHistELECBACKGROUND;
-
-// fQAcoll = ref.fQAcoll;
+ if(this == &ref)
+ ref.Copy(*this);
return *this;
}
+//____________________________________________________________
+void AliAnalysisTaskHFE::Copy(TObject &o) const {
+ //
+ // Copy into object o
+ //
+ AliAnalysisTaskHFE &target = dynamic_cast<AliAnalysisTaskHFE &>(o);
+ target.fQAlevel = fQAlevel;
+ target.fPlugins = fPlugins;
+ target.fFillSignalOnly = fFillSignalOnly;
+ target.fRemovePileUp = fRemovePileUp;
+ target.fIdentifiedAsPileUp = fIdentifiedAsPileUp;
+ target.fIdentifiedAsOutInz = fIdentifiedAsOutInz;
+ target.fPassTheEventCut = fPassTheEventCut;
+ target.fCentralityF = fCentralityF;
+ target.fBackGroundFactorsFunction = fBackGroundFactorsFunction;
+ target.fContainer = fContainer;
+ target.fVarManager = fVarManager;
+ target.fSignalCuts = fSignalCuts;
+ target.fCFM = fCFM;
+ target.fTriggerAnalysis = fTriggerAnalysis;
+ target.fPID = fPID;
+ target.fPIDqa = fPIDqa;
+ target.fPIDpreselect = fPIDpreselect;
+ target.fCuts = fCuts;
+ target.fTaggedTrackCuts = fTaggedTrackCuts;
+ target.fCutspreselect = fCutspreselect;
+ target.fSecVtx = fSecVtx;
+ target.fElecBackGround = fElecBackGround;
+ target.fMCQA = fMCQA;
+ target.fTaggedTrackAnalysis = fTaggedTrackAnalysis;
+ target.fQA = fQA;
+ target.fOutput = fOutput;
+ target.fHistMCQA = fHistMCQA;
+ target.fHistSECVTX = fHistSECVTX;
+ target.fHistELECBACKGROUND = fHistELECBACKGROUND;
+ target.fQACollection = fQACollection;
+}
+
//____________________________________________________________
AliAnalysisTaskHFE::~AliAnalysisTaskHFE(){
//
// Destructor
//
if(fPID) delete fPID;
- if(fQA){
- fQA->Clear();
- delete fQA;
- }
- if(fOutput){
- fOutput->Clear();
- delete fOutput;
- }
- if(fHistMCQA){
- fHistMCQA->Clear();
- delete fHistMCQA;
- }
- if(fHistSECVTX){
- fHistSECVTX->Clear();
- delete fHistSECVTX;
- }
- if(fHistELECBACKGROUND){
- fHistELECBACKGROUND->Clear();
- delete fHistELECBACKGROUND;
- }
+ if(fVarManager) delete fVarManager;
+ if(fPIDqa) delete fPIDqa;
+ if(fSignalCuts) delete fSignalCuts;
+ if(fCFM) delete fCFM;
if(fSecVtx) delete fSecVtx;
- if(fElecBackGround) delete fElecBackGround;
if(fMCQA) delete fMCQA;
- if(fNEvents) delete fNEvents;
- if(fCorrelation){
- fCorrelation->Clear();
- delete fCorrelation;
- }
- if(fPIDperformance) delete fPIDperformance;
- if(fSignalToBackgroundMC) delete fSignalToBackgroundMC;
-// if(fQAcoll) delete fQAcoll;
+ if(fElecBackGround) delete fElecBackGround;
+ if(fTriggerAnalysis) delete fTriggerAnalysis;
+ if(fPIDpreselect) delete fPIDpreselect;
+ if(fQA) delete fQA;
+ if(fOutput) delete fOutput;
}
//____________________________________________________________
//
AliDebug(3, "Creating Output Objects");
// Automatic determination of the analysis mode
- AliVEventHandler *inputHandler = AliAnalysisManager::GetAnalysisManager()->GetInputEventHandler();
+ AliVEventHandler *inputHandler = dynamic_cast<AliVEventHandler *>(AliAnalysisManager::GetAnalysisManager()->GetInputEventHandler());
if(!TString(inputHandler->IsA()->GetName()).CompareTo("AliAODInputHandler")){
SetAODAnalysis();
} else {
printf("Analysis Mode: %s Analysis\n", IsAODanalysis() ? "AOD" : "ESD");
printf("MC Data available %s\n", HasMCData() ? "Yes" : "No");
- // example how to use the AliHFEcollection
- //fQAcoll = new AliHFEcollection("fQAcoll", "QA");
- //fQAcoll->CreateTH1F("fNevents", "Number of Events in the Analysis", 2, 0, 2);
- //fQAcoll->CreateProfile("fNtrdclusters", "Number of TRD clusters as function of momentum; p[GeV/c]", 20, 0, 20);
+ // Enable Trigger Analysis
+ fTriggerAnalysis = new AliTriggerAnalysis;
+ fTriggerAnalysis->EnableHistograms();
+ fTriggerAnalysis->SetAnalyzeMC(HasMCData());
- fNEvents = new TH1I("nEvents", "Number of Events in the Analysis", 2, 0, 2); // Number of Events neccessary for the analysis and not a QA histogram
- fNElectronTracksEvent = new TH1I("nElectronTracksEvent", "Number of Electron Candidates", 100, 0, 100);
- // First Step: TRD alone
- if(!fQA) fQA = new TList;
- fQA->AddAt(new TProfile("conr", "Electron PID contamination", 20, 0, 20), 0);
- fQA->AddAt(new TH1F("alpha_rec", "Alpha from reconstructed tracks with TRD hits", 36, -TMath::Pi(), TMath::Pi()), 1);
- fQA->AddAt(new TH1F("alpha_sim", "Alpha from simulated electron tracks", 36, -TMath::Pi(), TMath::Pi()), 2);
- fQA->AddAt(new TH1F("nElectron", "Number of electrons", 100, 0, 100), 3);
- fQA->AddAt(new TProfile("pidquality", "TRD PID quality as function of momentum", 20, 0, 20), 4);
- fQA->AddAt(new TProfile("ntrdclusters", "Number of TRD clusters as function of momentum", 20, 0, 20), 5);
- fQA->AddAt(new TH1F("chi2TRD","#chi2 per TRD cluster", 20, 0, 20), 6);
- fQA->AddAt(new TH1I("mccharge", "MC Charge", 200, -100, 100), 7);
+ // Make lists for Output
+ if(!fQA) fQA = new TList;
+ fQA->SetOwner();
if(!fOutput) fOutput = new TList;
+ fOutput->SetOwner();
+
+ // First Part: Make QA histograms
+ fQACollection = new AliHFEcollection("TaskQA", "QA histos from the Electron Task");
+ fQACollection->CreateTH1F("nElectronTracksEvent", "Number of Electron Candidates", 100, 0, 100);
+ fQACollection->CreateProfile("conr", "Electron PID contamination", 20, 0, 20);
+ fQACollection->CreateTH1F("alpha_rec", "Alpha from reconstructed tracks with TRD hits", 36, -TMath::Pi(), TMath::Pi());
+ fQACollection->CreateTH1F("alpha_sim", "Alpha from simulated electron tracks", 36, -TMath::Pi(), TMath::Pi());
+ fQACollection->CreateTH1F("nElectron", "Number of electrons", 100, 0, 100);
+ fQACollection->CreateProfile("pidquality", "TRD PID quality as function of momentum", 20, 0, 20);
+ fQACollection->CreateProfile("ntrdclusters", "Number of TRD clusters as function of momentum", 20, 0, 20);
+ fQACollection->CreateTH1F("chi2TRD","#chi2 per TRD cluster", 20, 0, 20);
+ fQACollection->CreateTH1F("mccharge", "MC Charge", 200, -100, 100);
+ fQACollection->CreateTH2F("radius", "Production Vertex", 100, 0.0, 5.0, 100, 0.0, 5.0);
+ InitPIDperformanceQA();
+ fQA->Add(fQACollection->GetList());
+
+ // Initialize PID
+ fPID->SetHasMCData(HasMCData());
+ if(!fPID->GetNumberOfPIDdetectors()) fPID->AddDetector("TPC", 0);
+ fPID->InitializePID();
+ if(IsQAOn(kPIDqa)){
+ AliInfo("PID QA switched on");
+ fPIDqa = new AliHFEpidQAmanager;
+ fPIDqa->Initialize(fPID);
+ fQA->Add(fPIDqa->MakeList("HFEpidQA"));
+ }
+
// Initialize correction Framework and Cuts
+ const Int_t kNcutSteps = AliHFEcuts::kNcutStepsMCTrack + AliHFEcuts::kNcutStepsRecTrack + AliHFEcuts::kNcutStepsDETrack;
fCFM = new AliCFManager;
+ fCFM->SetNStepParticle(kNcutSteps);
MakeParticleContainer();
MakeEventContainer();
// Temporary fix: Initialize particle cuts with NULL
- for(Int_t istep = 0; istep < fCFM->GetParticleContainer()->GetNStep(); istep++)
+ for(Int_t istep = 0; istep < kNcutSteps; istep++)
fCFM->SetParticleCutsList(istep, NULL);
if(!fCuts){
AliWarning("Cuts not available. Default cuts will be used");
fCuts->CreateStandardCuts();
}
if(IsAODanalysis()) fCuts->SetAOD();
+ // Make clone for V0 tagging step
fCuts->Initialize(fCFM);
- if(fCuts->IsInDebugMode()) fQA->Add(fCuts->GetQAhistograms());
+ if(fCuts->IsQAOn()) fQA->Add(fCuts->GetQAhistograms());
+ fSignalCuts = new AliHFEsignalCuts("HFEsignalCuts", "HFE MC Signal definition");
+ fVarManager->SetSignalCuts(fSignalCuts);
// add output objects to the List
- fOutput->AddAt(fCFM->GetParticleContainer(), 0);
+ fOutput->AddAt(fContainer, 0);
fOutput->AddAt(fCFM->GetEventContainer(), 1);
- fOutput->AddAt(fCorrelation, 2);
- fOutput->AddAt(fPIDperformance, 3);
- fOutput->AddAt(fSignalToBackgroundMC, 4);
- fOutput->AddAt(fNElectronTracksEvent, 5);
-
- // Initialize PID
- if(IsQAOn(kPIDqa)){
- AliInfo("PID QA switched on");
- //fPID->SetDebugLevel(2);
- fPID->SetQAOn();
- fQA->Add(fPID->GetQAhistograms());
- }
- fPID->SetHasMCData(HasMCData());
- if(!fPIDdetectors.Length() && ! fPIDstrategy) AddPIDdetector("TPC");
- if(fPIDstrategy)
- fPID->InitializePID(Form("Strategy%d", fPIDstrategy));
- else
- fPID->InitializePID(fPIDdetectors.Data()); // Only restrictions to TPC allowed
-
+
// mcQA----------------------------------
if (HasMCData() && IsQAOn(kMCqa)) {
AliInfo("MC QA on");
if(!fMCQA) fMCQA = new AliHFEmcQA;
if(!fHistMCQA) fHistMCQA = new TList();
- fHistMCQA->SetName("MCqa");
- fMCQA->CreateHistograms(AliHFEmcQA::kCharm,0,"mcqa_"); // create histograms for charm
- fMCQA->CreateHistograms(AliHFEmcQA::kBeauty,0,"mcqa_"); // create histograms for beauty
- fMCQA->CreateHistograms(AliHFEmcQA::kCharm,1,"mcqa_barrel_"); // create histograms for charm
- fMCQA->CreateHistograms(AliHFEmcQA::kBeauty,1,"mcqa_barrel_"); // create histograms for beauty
- fMCQA->CreateHistograms(AliHFEmcQA::kCharm,2,"mcqa_unitY_"); // create histograms for charm
- fMCQA->CreateHistograms(AliHFEmcQA::kBeauty,2,"mcqa_unitY_"); // create histograms for beauty
- fMCQA->CreateHistograms(AliHFEmcQA::kCharm,3,"mcqa_reccut_"); // create histograms for charm
- fMCQA->CreateHistograms(AliHFEmcQA::kBeauty,3,"mcqa_reccut_"); // create histograms for beauty
- fMCQA->CreateHistograms(AliHFEmcQA::kCharm,4,"mcqa_recpidcut_"); // create histograms for charm
- fMCQA->CreateHistograms(AliHFEmcQA::kBeauty,4,"mcqa_recpidcut_"); // create histograms for beauty
- TIter next(gDirectory->GetList());
- TObject *obj;
- int counter = 0;
- TString objname;
- while ((obj = next.Next())) {
- objname = obj->GetName();
- TObjArray *toks = objname.Tokenize("_");
- if (toks->GetEntriesFast()){
- TObjString *fpart = (TObjString *)(toks->UncheckedAt(0));
- if ((fpart->String()).CompareTo("mcqa") == 0) fHistMCQA->AddAt(obj, counter++);
- }
- }
+ fHistMCQA->SetOwner();
+ fMCQA->CreatDefaultHistograms(fHistMCQA);
fQA->Add(fHistMCQA);
}
// secvtx----------------------------------
if (GetPlugin(kSecVtx)) {
AliInfo("Secondary Vertex Analysis on");
- fSecVtx = new AliHFEsecVtx;
+ if(!fSecVtx) fSecVtx = new AliHFEsecVtx;
fSecVtx->SetHasMCData(HasMCData());
if(!fHistSECVTX) fHistSECVTX = new TList();
+ fHistSECVTX->SetOwner();
fSecVtx->CreateHistograms(fHistSECVTX);
fOutput->Add(fHistSECVTX);
}
fElecBackGround->SetHasMCData(HasMCData());
if(!fHistELECBACKGROUND) fHistELECBACKGROUND = new TList();
+ fHistELECBACKGROUND->SetOwner();
fElecBackGround->CreateHistograms(fHistELECBACKGROUND);
fOutput->Add(fHistELECBACKGROUND);
}
+
+ // tagged tracks
+ if(GetPlugin(kTaggedTrackAnalysis)){
+ AliInfo("Analysis on V0-tagged tracks enabled");
+ fTaggedTrackAnalysis = new AliHFEtaggedTrackAnalysis;
+ fTaggedTrackAnalysis->SetCuts(fTaggedTrackCuts);
+ fTaggedTrackAnalysis->SetPID(fPID);
+ fTaggedTrackAnalysis->InitContainer();
+ fOutput->Add(fTaggedTrackAnalysis->GetContainer());
+ fQA->Add(fTaggedTrackAnalysis->GetPIDQA());
+ fQA->Add(fTaggedTrackAnalysis->GetCutQA());
+ }
+ PrintStatus();
}
//____________________________________________________________
return;
}
- if(HasMCData()) ProcessMC(); // Run the MC loop + MC QA in case MC Data are available
+ if(IsESDanalysis() && HasMCData()){
+ // Protect against missing MC trees
+ AliMCEventHandler *mcH = dynamic_cast<AliMCEventHandler *>(AliAnalysisManager::GetAnalysisManager()->GetMCtruthEventHandler());
+ if(!mcH){
+ AliError("No MC Event Handler available");
+ return;
+ }
+ if(!mcH->InitOk()) return;
+ if(!mcH->TreeK()) return;
+ if(!mcH->TreeTR()) return;
+ }
+
+ // need the centrality for everything (MC also)
+ fCentralityF = 99.0;
+ ReadCentrality();
+
+ // See if pile up and z in the range
+ RejectionPileUpVertexRangeEventCut();
+
+ // Protect agains missing
+ if(HasMCData()){
+ fSignalCuts->SetMCEvent(fMCEvent);
+ ProcessMC(); // Run the MC loop + MC QA in case MC Data are available
+ }
+
+ if(IsAODanalysis()){
+ AliAODpidUtil *aodworkingpid = AliHFEtools::GetDefaultAODPID(HasMCData());
+ fPID->SetAODpid(aodworkingpid);
+ if(fPIDqa) fPIDqa->SetAODpid(aodworkingpid);
+ if(fTaggedTrackAnalysis) fTaggedTrackAnalysis->GetPIDqa()->SetAODpid(aodworkingpid);
+ ProcessAOD();
+ } else {
+ AliESDInputHandler *inH = dynamic_cast<AliESDInputHandler *>(fInputHandler);
+ if(!inH){
+ AliError("No ESD Input handler available");
+ return;
+ }
+ AliESDpid *workingPID = inH->GetESDpid();
+ if(!workingPID){
+ AliDebug(1, "Using default ESD PID");
+ workingPID = AliHFEtools::GetDefaultPID(HasMCData());
+ } else {
+ AliDebug(1, "Using ESD PID from the input handler");
+ }
+ fPID->SetESDpid(workingPID);
+ if(fPIDqa) fPIDqa->SetESDpid(workingPID);
+ if(fTaggedTrackAnalysis) fTaggedTrackAnalysis->GetPIDqa()->SetESDpid(workingPID);
+ if(fPIDpreselect) fPIDpreselect->SetESDpid(workingPID);
- if(IsAODanalysis()) ProcessAOD();
- else ProcessESD();
+ ProcessESD();
+ }
// Done!!!
- PostData(1, fNEvents);
- PostData(2, fOutput);
- PostData(3, fQA);
-// PostData(4, fQAcoll->GetList());
+ PostData(1, fOutput);
+ PostData(2, fQA);
}
//____________________________________________________________
// Terminate not implemented at the moment
//
if(GetPlugin(kPostProcess)){
- fOutput = dynamic_cast<TList *>(GetOutputData(2));
+ fOutput = dynamic_cast<TList *>(GetOutputData(1));
+ fQA = dynamic_cast<TList *>(GetOutputData(2));
if(!fOutput){
AliError("Results not available");
return;
}
+ if(!fQA){
+ AliError("QA output not available");
+ return;
+ }
+ fContainer = dynamic_cast<AliHFEcontainer *>(fOutput->FindObject("trackContainer"));
+ if(!fContainer){
+ AliError("Track container not found");
+ return;
+ }
AliHFEpostAnalysis postanalysis;
- postanalysis.SetResults(fOutput);
- if(HasMCData())postanalysis.DrawMCSignal2Background();
+ postanalysis.SetTaskResults(fContainer);
+ TList *qalist = dynamic_cast<TList *>(fQA->FindObject("list_TaskQA"));
+ if(!qalist){
+ AliError("QA List not found");
+ return;
+ }
+ postanalysis.SetTaskQA(qalist);
+ printf("Running post analysis\n");
+ //if(HasMCData())
+ postanalysis.DrawMCSignal2Background();
postanalysis.DrawEfficiency();
postanalysis.DrawPIDperformance();
postanalysis.DrawCutEfficiency();
}
}
}
+//_______________________________________________________________
+Bool_t AliAnalysisTaskHFE::IsEventInBinZero() {
+ //
+ //
+ //
+
+ //printf("test in IsEventInBinZero\n");
+ if(!fInputEvent){
+ AliError("Reconstructed Event not available");
+ return kFALSE;
+ }
+ // check vertex
+ const AliVVertex *vertex = fInputEvent->GetPrimaryVertex();
+ if(!vertex) return kTRUE;
+ //if(vertex) return kTRUE;
+
+ // check tracks
+ if(fInputEvent->GetNumberOfTracks()<=0) return kTRUE;
+ //if(fInputEvent->GetNumberOfTracks()>0) return kTRUE;
+
+
+ return kFALSE;
+
+}
//____________________________________________________________
void AliAnalysisTaskHFE::ProcessMC(){
//
// In case MC QA is on also MC QA loop is done
//
AliDebug(3, "Processing MC Information");
- Double_t nContrib = 0;
- const AliVVertex *pVertex = fMCEvent->GetPrimaryVertex();
- if(pVertex) nContrib = pVertex->GetNContributors();
- if(!fCFM->CheckEventCuts(AliHFEcuts::kEventStepGenerated, fMCEvent)) return;
- fCFM->GetEventContainer()->Fill(&nContrib,AliHFEcuts::kEventStepGenerated);
+ Double_t eventContainer [3];
+ eventContainer[0] = fMCEvent->GetPrimaryVertex()->GetZ();
+ eventContainer[2] = fCentralityF;
+ if(fCFM->CheckEventCuts(AliHFEcuts::kEventStepGenerated, fMCEvent))
+ fCFM->GetEventContainer()->Fill(eventContainer,AliHFEcuts::kEventStepGenerated);
Int_t nElectrons = 0;
if(IsESDanalysis()){
if (HasMCData() && IsQAOn(kMCqa)) {
AliDebug(2, "Running MC QA");
if(fMCEvent->Stack()){
- fMCQA->SetStack(fMCEvent->Stack());
+ fMCQA->SetMCEvent(fMCEvent);
fMCQA->SetGenEventHeader(fMCEvent->GenEventHeader());
fMCQA->Init();
fMCQA->GetHadronKine(mcpart, AliHFEmcQA::kBeauty);
fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kCharm, AliHFEmcQA::kElectronPDG, 0); // no accept cut
fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kBeauty, AliHFEmcQA::kElectronPDG, 0); // no accept cut
+ fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kOthers, AliHFEmcQA::kElectronPDG, 0); // no accept cut
if (TMath::Abs(mcpart->Eta()) < 0.9) {
fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kCharm, AliHFEmcQA::kElectronPDG, 1); // accept |eta|<0.9
fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kBeauty, AliHFEmcQA::kElectronPDG, 1); // accept |eta|<0.9
+ fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kOthers, AliHFEmcQA::kElectronPDG, 1); // accept |eta|<0.9
}
if (TMath::Abs(AliHFEtools::GetRapidity(mcpart)) < 0.5) {
fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kCharm, AliHFEmcQA::kElectronPDG, 2); // accept |y|<0.5
fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kBeauty, AliHFEmcQA::kElectronPDG, 2); // accept |y|<0.5
+ fMCQA->GetDecayedKine(mcpart, AliHFEmcQA::kOthers, AliHFEmcQA::kElectronPDG, 2); // accept |y|<0.5
}
}
fMCQA->EndOfEventAna(AliHFEmcQA::kCharm);
}
// Run MC loop
AliVParticle *mctrack = NULL;
+ AliDebug(3, Form("Number of Tracks: %d", fMCEvent->GetNumberOfTracks()));
for(Int_t imc = 0; imc <fMCEvent->GetNumberOfTracks(); imc++){
if(!(mctrack = fMCEvent->GetTrack(imc))) continue;
+ AliDebug(4, "Next MC Track");
if(ProcessMCtrack(mctrack)) nElectrons++;
}
// fCFM->CheckEventCuts(AliCFManager::kEvtRecCuts, fESD);
- (dynamic_cast<TH1F *>(fQA->At(3)))->Fill(nElectrons);
+ fQACollection->Fill("nElectron", nElectrons);
}
//____________________________________________________________
// Loop over Tracks, filter according cut steps defined in AliHFEcuts
//
AliDebug(3, "Processing ESD Event");
- Double_t nContrib = fInputEvent->GetPrimaryVertex()->GetNContributors();
- if(!fCFM->CheckEventCuts(AliHFEcuts::kEventStepReconstructed, fInputEvent)) return;
- fCFM->GetEventContainer()->Fill(&nContrib, AliHFEcuts::kEventStepReconstructed);
AliESDEvent *fESD = dynamic_cast<AliESDEvent *>(fInputEvent);
if(!fESD){
AliError("ESD Event required for ESD Analysis")
return;
}
+
+ // Do event Normalization
+ Double_t eventContainer[3];
+ eventContainer[0] = fInputEvent->GetPrimaryVertex()->GetZ();
+ eventContainer[1] = 0.;
+ eventContainer[2] = fCentralityF;
+ if(fTriggerAnalysis->IsOfflineTriggerFired(fESD, AliTriggerAnalysis::kV0AND))
+ eventContainer[1] = 1.;
+
+ //
+ fCFM->GetEventContainer()->Fill(eventContainer, AliHFEcuts::kEventStepRecNoCut);
+
+ //
+ if(fIdentifiedAsPileUp) return;
+ fCFM->GetEventContainer()->Fill(eventContainer, AliHFEcuts::kEventStepRecNoPileUp);
+
+ //
+ if(fIdentifiedAsOutInz) return;
+ fCFM->GetEventContainer()->Fill(eventContainer, AliHFEcuts::kEventStepZRange);
+
+ //
+ if(!fPassTheEventCut) return;
+ fCFM->GetEventContainer()->Fill(eventContainer, AliHFEcuts::kEventStepReconstructed);
+
+
+
+ fContainer->NewEvent();
+
if (GetPlugin(kIsElecBackGround)) {
fElecBackGround->SetEvent(fESD);
}
if(HasMCData()){
if (GetPlugin(kSecVtx)) {
- if(fMCEvent->Stack()) fSecVtx->SetStack(fMCEvent->Stack());
+ fSecVtx->SetMCEvent(fMCEvent);
+ fSecVtx->SetMCQA(fMCQA);
}
if (GetPlugin(kIsElecBackGround)) {
fElecBackGround->SetMCEvent(fMCEvent);
}
}
-
- Double_t container[8];
- memset(container, 0, sizeof(Double_t) * 8);
+ Double_t container[10];
+ memset(container, 0, sizeof(Double_t) * 10);
// container for the output THnSparse
- Double_t dataE[5]; // [pT, eta, Phi, type, 'C' or 'B']
+ Double_t dataE[6]; // [pT, eta, Phi, type, 'C' or 'B']
Int_t nElectronCandidates = 0;
AliESDtrack *track = NULL, *htrack = NULL;
AliMCParticle *mctrack = NULL;
TParticle* mctrack4QA = NULL;
Int_t pid = 0;
- // For double counted tracks
- LabelContainer cont(fESD->GetNumberOfTracks());
- Bool_t alreadyseen = kFALSE;
Bool_t signal = kTRUE;
//
// Loop ESD
//
+ AliDebug(3, Form("Number of Tracks: %d", fESD->GetNumberOfTracks()));
for(Int_t itrack = 0; itrack < fESD->GetNumberOfTracks(); itrack++){
-
+ AliDebug(4, "New ESD track");
track = fESD->GetTrack(itrack);
-
- container[0] = track->Pt();
- container[1] = track->Eta();
- container[2] = track->Phi();
- container[3] = track->Charge();
-
- dataE[0] = track->Pt();
- dataE[1] = track->Eta();
- dataE[2] = track->Phi();
- dataE[3] = track->Charge();
- dataE[4] = -1;
- dataE[5] = -1;
- signal = kTRUE;
+ // fill counts of v0-identified particles
+ Int_t v0pid = -1;
+ if(track->TestBit(BIT(14))) v0pid = AliPID::kElectron;
+ else if(track->TestBit(BIT(15))) v0pid = AliPID::kPion;
+ else if(track->TestBit(BIT(16))) v0pid = AliPID::kProton;
+ // here the tagged track analysis will run
+ if(fTaggedTrackAnalysis && v0pid > -1){
+ AliDebug(1, Form("Track identified as %s", AliPID::ParticleName(v0pid)));
+ fTaggedTrackAnalysis->ProcessTrack(track, v0pid);
+ }
+
+ AliDebug(3, Form("Doing track %d, %p", itrack, track));
+
+ //////////////////////////////////////
+ // preselect
+ /////////////////////////////////////
+ if(fPIDpreselect && fCutspreselect) {
+ if(!PreSelectTrack(track)) continue;
+ }
+ signal = kTRUE;
+
// Fill step without any cut
if(HasMCData()){
// Check if it is electrons near the vertex
if(!(mctrack = dynamic_cast<AliMCParticle *>(fMCEvent->GetTrack(TMath::Abs(track->GetLabel()))))) continue;
- mctrack4QA = mctrack->Particle();//fMCEvent->Stack()->Particle(TMath::Abs(track->GetLabel()));
+ mctrack4QA = mctrack->Particle();
+
+ if(fFillSignalOnly && !fCFM->CheckParticleCuts(AliHFEcuts::kStepMCGenerated, mctrack)) signal = kFALSE;
+ else AliDebug(3, "Signal Electron");
+ }
+ // Cache new Track information inside the var manager
+ fVarManager->NewTrack(track, mctrack, fCentralityF, -1, signal);
- container[4] = mctrack->Pt();
- container[5] = mctrack->Eta();
- container[6] = mctrack->Phi();
- container[7] = mctrack->Charge()/3.;
-
- if(!fCFM->CheckParticleCuts(AliHFEcuts::kStepMCGenerated, mctrack)) signal = kFALSE;
- }
if(signal) {
- alreadyseen = cont.Find(TMath::Abs(track->GetLabel()));
- cont.Append(TMath::Abs(track->GetLabel()));
-
- fCFM->GetParticleContainer()->Fill(&container[4], AliHFEcuts::kStepRecNoCut);
- fCFM->GetParticleContainer()->Fill(&container[0], AliHFEcuts::kStepRecNoCut + 2*AliHFEcuts::kNcutStepsESDtrack);
- if(alreadyseen) {
- fCFM->GetParticleContainer()->Fill(&container[4], AliHFEcuts::kStepRecNoCut + AliHFEcuts::kNcutStepsESDtrack);
- }
+ fVarManager->FillContainer(fContainer, "recTrackContReco", AliHFEcuts::kStepRecNoCut, kFALSE);
+ fVarManager->FillContainer(fContainer, "recTrackContMC", AliHFEcuts::kStepRecNoCut, kTRUE);
}
// RecKine: ITSTPC cuts
- if(!ProcessCutStep(AliHFEcuts::kStepRecKineITSTPC, track, container, signal, alreadyseen)) continue;
+ if(!ProcessCutStep(AliHFEcuts::kStepRecKineITSTPC, track)) continue;
// Check TRD criterions (outside the correction framework)
if(track->GetTRDncls()){
- (dynamic_cast<TH1F *>(fQA->At(6)))->Fill(track->GetTRDchi2()/track->GetTRDncls());
- (dynamic_cast<TH1F *>(fQA->At(1)))->Fill(track->GetAlpha()); // Check the acceptance without tight cuts
- (dynamic_cast<TProfile *>(fQA->At(4)))->Fill(container[0], track->GetTRDpidQuality());
- (dynamic_cast<TProfile *>(fQA->At(5)))->Fill(container[0], track->GetTRDncls());
- //fQAcoll->Fill("fNtrdclusters", container[0], track->GetTRDncls());
+ fQACollection->Fill("chi2TRD", track->GetTRDchi2()/track->GetTRDncls());
+ fQACollection->Fill("alpha_rec", track->GetAlpha());
+ fQACollection->Fill("pidquality", container[0], track->GetTRDpidQuality());
+ fQACollection->Fill("ntrdclusters", container[0], track->GetTRDncls());
}
// RecPrim
- if(!ProcessCutStep(AliHFEcuts::kStepRecPrim, track, container, signal, alreadyseen)) continue;
+ if(!ProcessCutStep(AliHFEcuts::kStepRecPrim, track)) continue;
// HFEcuts: ITS layers cuts
- if(!ProcessCutStep(AliHFEcuts::kStepHFEcutsITS, track, container, signal, alreadyseen)) continue;
-
- // HFEcuts: Nb of tracklets TRD0
- if(!ProcessCutStep(AliHFEcuts::kStepHFEcutsTRD, track, container, signal, alreadyseen)) continue;
- if(signal) {
- // dimensions 3&4&5 : pt,eta,phi (MC)
- ((THnSparseF *)fCorrelation->At(0))->Fill(container);
- }
+ if(!ProcessCutStep(AliHFEcuts::kStepHFEcutsITS, track)) continue;
if(HasMCData() && IsQAOn(kMCqa)) {
// mc qa for after the reconstruction cuts
AliDebug(2, "Running MC QA");
fMCQA->GetDecayedKine(mctrack4QA, AliHFEmcQA::kCharm, AliHFEmcQA::kElectronPDG, 3); // charm
fMCQA->GetDecayedKine(mctrack4QA, AliHFEmcQA::kBeauty, AliHFEmcQA::kElectronPDG, 3); // beauty
- }
+ fMCQA->GetDecayedKine(mctrack4QA, AliHFEmcQA::kOthers, AliHFEmcQA::kElectronPDG, 3); // beauty
+ }
- // track accepted, do PID
- AliHFEpidObject hfetrack;
- hfetrack.fAnalysisType = AliHFEpidObject::kESDanalysis;
- hfetrack.fRecTrack = track;
- if(HasMCData()) hfetrack.fMCtrack = mctrack;
- if(!fPID->IsSelected(&hfetrack)) continue;
- nElectronCandidates++;
+ // HFEcuts: Nb of tracklets TRD0
+ if(!ProcessCutStep(AliHFEcuts::kStepHFEcutsTRD, track)) continue;
if (HasMCData() && IsQAOn(kMCqa)) {
// mc qa for after the reconstruction and pid cuts
AliDebug(2, "Running MC QA");
fMCQA->GetDecayedKine(mctrack4QA, AliHFEmcQA::kCharm, AliHFEmcQA::kElectronPDG, 4); // charm
fMCQA->GetDecayedKine(mctrack4QA, AliHFEmcQA::kBeauty, AliHFEmcQA::kElectronPDG, 4); // beauty
- }
+ fMCQA->GetDecayedKine(mctrack4QA, AliHFEmcQA::kOthers, AliHFEmcQA::kElectronPDG, 4); // beauty
+ }
+
+ if(HasMCData()){
+ FillProductionVertex(track);
+ }
+
+ // track accepted, do PID
+ AliHFEpidObject hfetrack;
+ hfetrack.SetAnalysisType(AliHFEpidObject::kESDanalysis);
+ hfetrack.SetRecTrack(track);
+ if(HasMCData()) hfetrack.SetMCTrack(mctrack);
+ hfetrack.SetCentrality(fCentralityF);
+ fPID->SetVarManager(fVarManager);
+ if(!fPID->IsSelected(&hfetrack, fContainer, "recTrackCont", fPIDqa)) continue;
+ nElectronCandidates++;
+
+ // Fill Histogram for Hadronic Background
+ if(HasMCData()){
+ if(mctrack && (TMath::Abs(mctrack->Particle()->GetPdgCode()) != 11))
+ fVarManager->FillContainer(fContainer, "hadronicBackground", UInt_t(0), kFALSE);
+ }
// Fill Containers
if(signal) {
- fCFM->GetParticleContainer()->Fill(container, AliHFEcuts::kStepPID + 2*AliHFEcuts::kNcutStepsESDtrack);
- fCFM->GetParticleContainer()->Fill(&container[4], AliHFEcuts::kStepPID);
- if(alreadyseen) {
- fCFM->GetParticleContainer()->Fill(&container[4], (AliHFEcuts::kStepPID + (AliHFEcuts::kNcutStepsESDtrack)));
+ // Apply weight for background contamination
+ if(fBackGroundFactorsFunction) {
+ Double_t weightBackGround = fBackGroundFactorsFunction->Eval(TMath::Abs(track->P()));
+ if(weightBackGround < 0.0) weightBackGround = 0.0;
+ else if(weightBackGround > 1.0) weightBackGround = 1.0;
+ // weightBackGround as special weight
+ fVarManager->FillContainer(fContainer, "hadronicBackground", 1, kFALSE, weightBackGround);
}
- // dimensions 3&4&5 : pt,eta,phi (MC)
- ((THnSparseF *)fCorrelation->At(1))->Fill(container);
+ fVarManager->FillCorrelationMatrix(fContainer->GetCorrelationMatrix("correlationstepafterPID"));
}
- if(GetPlugin(kSecVtx) && fMCEvent->Stack()) {
+ if(GetPlugin(kSecVtx)) {
AliDebug(2, "Running Secondary Vertex Analysis");
- if(track->Pt()>1.0){
- fSecVtx->InitHFEpairs();
- fSecVtx->InitHFEsecvtxs();
- AliESDtrack *htrack = 0x0;
- for(Int_t jtrack = 0; jtrack < fESD->GetNumberOfTracks(); jtrack++){
- htrack = fESD->GetTrack(jtrack);
- if ( itrack == jtrack ) continue; // since it is for tagging single electron, don't need additional condition
- if (htrack->Pt()<1.0) continue;
- if (!fCFM->CheckParticleCuts(AliHFEcuts::kStepRecKineITSTPC, htrack)) continue;
- if (!fCFM->CheckParticleCuts(AliHFEcuts::kStepRecPrim, htrack)) continue;
- fSecVtx->PairAnalysis(track, htrack, jtrack); // e-h pairing
- }
- /*for(int ip=0; ip<fSecVtx->HFEpairs()->GetEntriesFast(); ip++){
- if(HasMCData()){
- AliHFEpairs *pair = (AliHFEpairs*) (fSecVtx->HFEpairs()->UncheckedAt(ip));
- if(!(pair->GetPairCode()>1. && pair->GetPairCode()<4.)) // apply various cuts
- fSecVtx->HFEpairs()->RemoveAt(ip);
- }
- }*/
- fSecVtx->HFEpairs()->Compress();
- fSecVtx->RunSECVTX(track); // secondary vertexing with e,h1,h2,.. tracks
- for(int ip=0; ip<fSecVtx->HFEsecvtxs()->GetEntriesFast(); ip++){
- AliHFEsecVtxs *secvtx=0x0;
- secvtx = (AliHFEsecVtxs*) (fSecVtx->HFEsecvtxs()->UncheckedAt(ip));
- // here you apply cuts, then if it doesn't pass the cut, remove it from the fSecVtx->HFEsecvtxs()
- }
- fSecVtx->DeleteHFEpairs();
- fSecVtx->DeleteHFEsecvtxs();
- }
+ fSecVtx->Process(track);
}
if(HasMCData()){
+ dataE[0] = track->Pt();
+ dataE[1] = track->Eta();
+ dataE[2] = track->Phi();
+ dataE[3] = track->Charge();
+ dataE[4] = -1.;
+ dataE[5] = -1.;
+
// Track selected: distinguish between true and fake
AliDebug(1, Form("Candidate Selected, filling THnSparse, PID: %d\n", mctrack->Particle()->GetPdgCode()));
if((pid = TMath::Abs(mctrack->Particle()->GetPdgCode())) == 11){
- Int_t type = IsSignalElectron(track);
+ Int_t type = 0;
+ if(fSignalCuts->IsCharmElectron(track))
+ type = 1;
+ else if(fSignalCuts->IsBeautyElectron(track))
+ type = 2;
AliDebug(1, Form("Type: %d\n", type));
if(type){
dataE[5] = type; // beauty[1] or charm[2]
// fill the performance THnSparse, if the mc origin could be defined
if(dataE[4] > -1){
AliDebug(1, Form("Entries: [%.3f|%.3f|%.3f|%f|%f|%f]\n", dataE[0],dataE[1],dataE[2],dataE[3],dataE[4],dataE[5]));
- fPIDperformance->Fill(dataE);
+ fQACollection->Fill("PIDperformance", dataE);
}
}
// Electron background analysis
}
} // end of electron background analysis
+ if (GetPlugin(kDEstep)) {
+ // Fill Containers for impact parameter analysis
+ if(!fCFM->CheckParticleCuts(AliHFEcuts::kStepHFEcutsDca + AliHFEcuts::kNcutStepsMCTrack + AliHFEcuts::kNcutStepsRecTrack,track)) continue;
+ if(signal) {
+ fVarManager->FillContainer(fContainer, "recTrackContDEReco", AliHFEcuts::kStepHFEcutsDca, kFALSE);
+ fVarManager->FillContainer(fContainer, "recTrackContDEMC", AliHFEcuts::kStepHFEcutsDca, kTRUE);
+ fVarManager->FillCorrelationMatrix(fContainer->GetCorrelationMatrix("correlationstepafterDE"));
+ }
+ if(HasMCData()){
+ if(mctrack && (TMath::Abs(mctrack->Particle()->GetPdgCode()) != 11))
+ fVarManager->FillContainer(fContainer, "hadronicBackground", 2, kFALSE);
+ }
+ }
+
}
- fNEvents->Fill(1);
- //fQAcoll->Fill("fNevents", 1);
- fNElectronTracksEvent->Fill(nElectronCandidates);
+ fQACollection->Fill("nElectronTracksEvent", nElectronCandidates);
}
//____________________________________________________________
// Function is still in development
//
AliDebug(3, "Processing AOD Event");
- Double_t nContrib = fInputEvent->GetPrimaryVertex()->GetNContributors();
- if(!fCFM->CheckEventCuts(AliHFEcuts::kEventStepReconstructed, fInputEvent)) return;
- fCFM->GetEventContainer()->Fill(&nContrib,AliHFEcuts::kEventStepReconstructed);
+ Double_t eventContainer[2];
+ eventContainer[0] = fInputEvent->GetPrimaryVertex()->GetZ();
+ eventContainer[1] = 1.; // No Information available in AOD analysis, assume all events have V0AND
+
AliAODEvent *fAOD = dynamic_cast<AliAODEvent *>(fInputEvent);
if(!fAOD){
AliError("AOD Event required for AOD Analysis")
- return;
+ return;
}
+
+ //
+ fCFM->GetEventContainer()->Fill(eventContainer, AliHFEcuts::kEventStepRecNoCut);
+
+ //
+ if(fIdentifiedAsPileUp) return;
+ fCFM->GetEventContainer()->Fill(eventContainer, AliHFEcuts::kEventStepRecNoPileUp);
+
+ //
+ if(fIdentifiedAsOutInz) return;
+ fCFM->GetEventContainer()->Fill(eventContainer, AliHFEcuts::kEventStepZRange);
+
+ //
+ if(!fPassTheEventCut) return;
+ fCFM->GetEventContainer()->Fill(eventContainer, AliHFEcuts::kEventStepReconstructed);
+
+ fContainer->NewEvent();
AliAODTrack *track = NULL;
AliAODMCParticle *mctrack = NULL;
- Double_t container[8]; memset(container, 0, sizeof(Double_t) * 8);
Double_t dataE[6]; // [pT, eta, Phi, Charge, type, 'C' or 'B']
Int_t nElectronCandidates = 0;
Int_t pid;
+ Bool_t signal;
for(Int_t itrack = 0; itrack < fAOD->GetNumberOfTracks(); itrack++){
track = fAOD->GetTrack(itrack);
if(!track) continue;
if(track->GetFlags() != 1<<4) continue; // Only process AOD tracks where the HFE is set
- container[0] = track->Pt();
- container[1] = track->Eta();
- container[2] = track->Phi();
- container[3] = track->Charge();
-
- dataE[0] = track->Pt();
- dataE[1] = track->Eta();
- dataE[2] = track->Phi();
- dataE[3] = track->Charge();
- dataE[4] = -1;
- dataE[5] = -1;
-
+ signal = kTRUE;
if(HasMCData()){
+
Int_t label = TMath::Abs(track->GetLabel());
- if(label){
+ if(label)
mctrack = dynamic_cast<AliAODMCParticle *>(fMCEvent->GetTrack(label));
- container[4] = mctrack->Pt();
- container[5] = mctrack->Eta();
- container[6] = mctrack->Phi();
- container[7] = mctrack->Charge();
- }
+ if(fFillSignalOnly && !fCFM->CheckParticleCuts(AliHFEcuts::kStepMCGenerated, mctrack)) signal = kFALSE;
}
+ fVarManager->NewTrack(track, mctrack, fCentralityF, -1, kTRUE);
// track accepted, do PID
AliHFEpidObject hfetrack;
- hfetrack.fAnalysisType = AliHFEpidObject::kAODanalysis;
- hfetrack.fRecTrack = track;
- if(HasMCData()) hfetrack.fMCtrack = mctrack;
- //if(!fPID->IsSelected(&hfetrack)) continue; // we will do PID here as soon as possible
- // Particle identified - Fill CF Container
- fCFM->GetParticleContainer()->Fill(container, AliHFEcuts::kStepPID + 2*AliHFEcuts::kNcutStepsESDtrack);
+ hfetrack.SetAnalysisType(AliHFEpidObject::kAODanalysis);
+ hfetrack.SetRecTrack(track);
+ if(HasMCData()) hfetrack.SetMCTrack(mctrack);
+ hfetrack.SetCentrality(fCentralityF);
+ fPID->SetVarManager(fVarManager);
+ if(!fPID->IsSelected(&hfetrack, fContainer, "recTrackCont", fPIDqa)) continue; // we will do PID here as soon as possible
+ // Apply weight for background contamination
+ Double_t weightBackGround = 1.0;
+ if(fBackGroundFactorsFunction) {
+ weightBackGround = fBackGroundFactorsFunction->Eval(TMath::Abs(track->P()));
+ if(weightBackGround < 0.0) weightBackGround = 0.0;
+ }
+ fVarManager->FillContainer(fContainer, "hadronicBackground", 1, kFALSE);
nElectronCandidates++;
if(HasMCData()){
- // Track selected: distinguish between true and fake
+ dataE[0] = track->Pt();
+ dataE[1] = track->Eta();
+ dataE[2] = track->Phi();
+ dataE[3] = track->Charge();
+ dataE[4] = -1;
+ dataE[5] = -1;
+ // Track selected: distinguish between true and fake
AliDebug(1, Form("Candidate Selected, filling THnSparse, PID: %d\n", mctrack->GetPdgCode()));
if((pid = TMath::Abs(mctrack->GetPdgCode())) == 11){
- Int_t type = IsSignalElectron(track);
+
+ Int_t type = 0;
+ if(fSignalCuts->IsCharmElectron(track))
+ type = 1;
+ else if(fSignalCuts->IsBeautyElectron(track))
+ type = 2;
AliDebug(1, Form("Type: %d\n", type));
if(type){
dataE[5] = type; // beauty[1] or charm[2]
// fill the performance THnSparse, if the mc origin could be defined
if(dataE[4] > -1){
AliDebug(1, Form("Entries: [%.3f|%.3f|%.3f|%f|%f|%f]\n", dataE[0],dataE[1],dataE[2],dataE[3],dataE[4],dataE[5]));
- fPIDperformance->Fill(dataE);
+ fQACollection->Fill("PIDperformance", dataE);
}
}
}
- fNEvents->Fill(1);
- fNElectronTracksEvent->Fill(nElectronCandidates);
+ fQACollection->Fill("nElectronTracksEvent", nElectronCandidates);
}
//____________________________________________________________
// Additionally Fill a THnSparse for Signal To Background Studies
// Works for AOD and MC analysis Type
//
- Double_t container[4], signalContainer[6];
- Double_t vertex[3]; // Production vertex cut to mask gammas which are NOT supposed to have hits in the first ITS layer(s)
- if(IsESDanalysis()){
- AliMCParticle *mctrack = dynamic_cast<AliMCParticle *>(track);
- container[0] = mctrack->Pt();
- container[1] = mctrack->Eta();
- container[2] = mctrack->Phi();
- container[3] = mctrack->Charge()/3;
+ fVarManager->NewTrack(track, NULL, -1, kTRUE);
+ Double_t signalContainer[6];
- signalContainer[0] = mctrack->Pt();
- signalContainer[1] = mctrack->Eta();
- signalContainer[2] = mctrack->Phi();
- signalContainer[3] = mctrack->Charge()/3;
+ signalContainer[0] = track->Pt();
+ signalContainer[1] = track->Eta();
+ signalContainer[2] = track->Phi();
+ signalContainer[3] = track->Charge()/3;
+ Double_t vertex[3]; // Production vertex cut to mask gammas which are NOT supposed to have hits in the first ITS layer(s)
+ if(IsESDanalysis()){
+ AliMCParticle *mctrack = dynamic_cast<AliMCParticle *>(track);
vertex[0] = mctrack->Particle()->Vx();
vertex[1] = mctrack->Particle()->Vy();
} else {
AliAODMCParticle *aodmctrack = dynamic_cast<AliAODMCParticle *>(track);
- container[0] = aodmctrack->Pt();
- container[1] = aodmctrack->Eta();
- container[2] = aodmctrack->Phi();
- container[3] = aodmctrack->Charge()/3;
-
- signalContainer[0] = aodmctrack->Pt();
- signalContainer[1] = aodmctrack->Eta();
- signalContainer[2] = aodmctrack->Phi();
- signalContainer[3] = aodmctrack->Charge()/3;
-
aodmctrack->XvYvZv(vertex);
}
+
if(!fCFM->CheckParticleCuts(AliHFEcuts::kStepMCGenerated, track)) return kFALSE;
- TH1 *test = dynamic_cast<TH1I*>(fQA->FindObject("mccharge"));
- test->Fill(signalContainer[3]);
- fCFM->GetParticleContainer()->Fill(container, AliHFEcuts::kStepMCGenerated);
- if((signalContainer[4] = static_cast<Double_t >(IsSignalElectron(track))) > 1e-3) fCFM->GetParticleContainer()->Fill(container, AliHFEcuts::kStepMCsignal);
+ fQACollection->Fill("mccharge", signalContainer[3]);
+ fVarManager->FillContainer(fContainer, "MCTrackCont", AliHFEcuts::kStepMCGenerated, kFALSE);
+ signalContainer[4] = 0;
+ if(fSignalCuts->IsSelected(track)){
+ //fVarManager->FillContainer(fContainer, "MCTrackCont", AliHFEcuts::kStepMCsignal, kFALSE);
+ // Filling of the Signal/Background histogram using the
+ // definition of the codes for charm and beauty as below in
+ // th crearion of the histogram
+ if(fSignalCuts->IsCharmElectron(track))
+ signalContainer[4] = 1;
+ else
+ signalContainer[4] = 2;
+ } else {
+ signalContainer[4] = 0; // (and other background)
+ }
signalContainer[5] = 0;
// apply cut on the sqrt of the production vertex
Double_t radVertex = TMath::Sqrt(vertex[0]*vertex[0] + vertex[1] * vertex[1]);
} else if (radVertex < 7.5){
signalContainer[5] = 2;
}
- fSignalToBackgroundMC->Fill(signalContainer);
- (dynamic_cast<TH1F *>(fQA->At(2)))->Fill(container[2] - TMath::Pi());
- //if(IsESDanalysis()){
- if(!fCFM->CheckParticleCuts(AliHFEcuts::kStepMCInAcceptance, track)) return kFALSE;
- fCFM->GetParticleContainer()->Fill(container, AliHFEcuts::kStepMCInAcceptance);
- //}
+ fQACollection->Fill("SignalToBackgroundMC", signalContainer);
+ fQACollection->Fill("alpha_sim", track->Phi() - TMath::Pi());
+
+ // Step GeneratedZOutNoPileUp
+ if((fIdentifiedAsPileUp) || (fIdentifiedAsOutInz)) return kFALSE;
+ fVarManager->FillContainer(fContainer, "MCTrackCont", AliHFEcuts::kStepMCGeneratedZOutNoPileUp, kFALSE);
+
+ // Step Generated Event Cut
+ if(!fPassTheEventCut) return kFALSE;
+ fVarManager->FillContainer(fContainer, "MCTrackCont", AliHFEcuts::kStepMCGeneratedEventCut, kFALSE);
+
+ if(!fCFM->CheckParticleCuts(AliHFEcuts::kStepMCInAcceptance, track)) return kFALSE;
+ fVarManager->FillContainer(fContainer, "MCTrackCont", AliHFEcuts::kStepMCInAcceptance, kFALSE);
return kTRUE;
}
+//____________________________________________________________
+Bool_t AliAnalysisTaskHFE::PreSelectTrack(AliESDtrack *track) const {
+ //
+ // Preselect tracks
+ //
+
+
+ Bool_t survived = kTRUE;
+
+ if(!fCutspreselect->CheckParticleCuts(AliHFEcuts::kStepRecKineITSTPC, track)) {
+ survived = kFALSE;
+ //printf("Did not pass AliHFEcuts::kStepRecKineITSTPC\n");
+ }
+ //else printf("Pass AliHFEcuts::kStepRecKineITSTPC\n");
+ if(!fCutspreselect->CheckParticleCuts(AliHFEcuts::kStepRecPrim, track)) {
+ survived = kFALSE;
+ //printf("Did not pass AliHFEcuts::kStepRecPrim\n");
+ }
+ //else printf("Pass AliHFEcuts::kStepRecPrim\n");
+ if(!fCutspreselect->CheckParticleCuts(AliHFEcuts::kStepHFEcutsITS, track)) {
+ survived = kFALSE;
+ //printf("Did not pass AliHFEcuts::kStepHFEcutsITS\n");
+ }
+ //else printf("Pass AliHFEcuts::kStepHFEcutsITS\n");
+ if(!fCutspreselect->CheckParticleCuts(AliHFEcuts::kStepHFEcutsTRD, track)) {
+ survived = kFALSE;
+ //printf("Did not pass AliHFEcuts::kStepHFEcutsTRD\n");
+ }
+ //else printf("Pass AliHFEcuts::kStepHFEcutsTRD\n");
+
+ if(survived){
+ // Apply PID
+ AliHFEpidObject hfetrack;
+ hfetrack.SetAnalysisType(AliHFEpidObject::kESDanalysis);
+ hfetrack.SetRecTrack(track);
+ if(!fPIDpreselect->IsSelected(&hfetrack)) {
+ //printf("Did not pass AliHFEcuts::kPID\n");
+ survived = kFALSE;
+ }
+ //else printf("Pass AliHFEcuts::kPID\n");
+ }
+
+ return survived;
+
+}
//____________________________________________________________
void AliAnalysisTaskHFE::MakeEventContainer(){
//
// Create the event container for the correction framework and link it
+ // 1st bin: Vertex z-position
+ // 2nd bin: V0AND decision (normalization to sigma_inel)
+ // 3rd bin: Centrality class (for pp defined as 99.)
//
- const Int_t kNvar = 1; // number of variables on the grid: number of tracks per event
- const Double_t kNTrackBound[2] = {-0.5, 200.5};
- const Int_t kNBins = 201;
+ const Int_t kNvar = 3; // number of variables on the grid:
+ Int_t nBins[kNvar] = {120, 2, 20};
+ Double_t binMin[kNvar] = {-30. , 0., 0.};
+ Double_t binMax[kNvar] = {30., 2., 100};
- AliCFContainer *evCont = new AliCFContainer("eventContainer", "Container for events", AliHFEcuts::kNcutStepsEvent, kNvar, &kNBins);
+ AliCFContainer *evCont = new AliCFContainer("eventContainer", "Container for events", AliHFEcuts::kNcutStepsEvent, kNvar, nBins);
- Double_t *trackBins = AliHFEtools::MakeLinearBinning(kNBins, kNTrackBound[0], kNTrackBound[1]);
- evCont->SetBinLimits(0,trackBins);
- delete[] trackBins;
+ Double_t *vertexBins = AliHFEtools::MakeLinearBinning(nBins[0], binMin[0], binMax[0]);
+ Double_t *v0andBins = AliHFEtools::MakeLinearBinning(nBins[1], binMin[1], binMax[1]);
+ evCont->SetBinLimits(0, vertexBins);
+ evCont->SetBinLimits(1, v0andBins);
+ delete[] vertexBins; delete[] v0andBins;
fCFM->SetEventContainer(evCont);
}
// Create the particle container for the correction framework manager and
// link it
//
- const Int_t kNvar = 4 ; //number of variables on the grid:pt,eta, phi, charge
- const Double_t kPtbound[2] = {0.1, 10.};
- const Double_t kEtabound[2] = {-0.8, 0.8};
- const Double_t kPhibound[2] = {0., 2. * TMath::Pi()};
-
- //arrays for the number of bins in each dimension
- Int_t iBin[kNvar];
- iBin[0] = 40; // bins in pt
- iBin[1] = 8; // bins in eta
- iBin[2] = 18; // bins in phi
- iBin[3] = 2; // bins in charge
-
- //arrays for lower bounds :
- Double_t* binEdges[kNvar];
- binEdges[0] = AliHFEtools::MakeLogarithmicBinning(iBin[0], kPtbound[0], kPtbound[1]);
- binEdges[1] = AliHFEtools::MakeLinearBinning(iBin[1], kEtabound[0], kEtabound[1]);
- binEdges[2] = AliHFEtools::MakeLinearBinning(iBin[2], kPhibound[0], kPhibound[1]);
- binEdges[3] = AliHFEtools::MakeLinearBinning(iBin[3], -1.1, 1.1); // Numeric precision
-
- //one "container" for MC
- AliCFContainer* container = new AliCFContainer("trackContainer", "Container for tracks", (AliHFEcuts::kNcutStepsTrack + 2*AliHFEcuts::kNcutStepsESDtrack), kNvar, iBin);
-
- //setting the bin limits
- for(Int_t ivar = 0; ivar < kNvar; ivar++)
- container -> SetBinLimits(ivar, binEdges[ivar]);
- fCFM->SetParticleContainer(container);
-
- //create correlation matrix for unfolding
- Int_t thnDim[2*kNvar];
- for (int k=0; k<kNvar; k++) {
- //first half : reconstructed
- //second half : MC
- thnDim[k] = iBin[k];
- thnDim[k+kNvar] = iBin[k];
- }
-
- if(!fCorrelation) fCorrelation = new TList();
- fCorrelation->SetName("correlation");
-
- THnSparseF *correlation0 = new THnSparseF("correlationstepbeforePID","THnSparse with correlations",2*kNvar,thnDim);
- THnSparseF *correlation1 = new THnSparseF("correlationstepafterPID","THnSparse with correlations",2*kNvar,thnDim);
- for (int k=0; k<kNvar; k++) {
- correlation0->SetBinEdges(k,binEdges[k]);
- correlation0->SetBinEdges(k+kNvar,binEdges[k]);
- correlation1->SetBinEdges(k,binEdges[k]);
- correlation1->SetBinEdges(k+kNvar,binEdges[k]);
- }
- correlation0->Sumw2();
- correlation1->Sumw2();
- fCorrelation->AddAt(correlation0,0);
- fCorrelation->AddAt(correlation1,1);
+ if(!fContainer) fContainer = new AliHFEcontainer("trackContainer");
+ fVarManager->DefineVariables(fContainer);
+
+ // Create Correction Framework containers
+ fContainer->CreateContainer("MCTrackCont", "Track Container filled with MC information", AliHFEcuts::kNcutStepsMCTrack);
+ fContainer->CreateContainer("recTrackContReco", "Track Container filled with MC information", AliHFEcuts::kNcutStepsRecTrack + fPID->GetNumberOfPIDdetectors());
+ fContainer->CreateContainer("recTrackContMC", "Track Container filled with MC information", AliHFEcuts::kNcutStepsRecTrack + fPID->GetNumberOfPIDdetectors());
- // Add a histogram for Fake electrons
- const Int_t nDim=6;
- Int_t nBin[nDim] = {40, 8, 18, 2, 3, 3};
- Double_t* binEdges2[nDim];
-
- //values for bin lower bounds
- for(Int_t ivar = 0; ivar < kNvar; ivar++)
- binEdges2[ivar] = binEdges[ivar];
- binEdges2[4] = AliHFEtools::MakeLinearBinning(nBin[4], 0, nBin[4]);
- binEdges2[5] = AliHFEtools::MakeLinearBinning(nBin[5], 0, nBin[5]);
-
- fPIDperformance = new THnSparseF("PIDperformance", "PID performance; pT [GeV/c]; theta [rad]; phi [rad]; charge; type (0 - not el, 1 - other el, 2 - HF el; flavor (0 - no, 1 - charm, 2 - bottom)", nDim, nBin);
- fPIDperformance->Sumw2();
- fSignalToBackgroundMC = new THnSparseF("SignalToBackgroundMC", "PID performance; pT [GeV/c]; theta [rad]; phi [rad]; charge; flavor (0 - no, 1 - charm, 2 - bottom); ITS Cluster (0 - no, 1 - first (and maybe second), 2 - second)", nDim, nBin);
- fSignalToBackgroundMC->Sumw2();
- for(Int_t idim = 0; idim < nDim; idim++){
- fPIDperformance->SetBinEdges(idim, binEdges2[idim]);
- fSignalToBackgroundMC->SetBinEdges(idim, binEdges2[idim]);
+ fContainer->CreateContainer("hadronicBackground", "Container for Hadronic Background", 3);
+ fContainer->CreateContainer("recTrackContDEReco", "Container for displaced electron analysis with Reco information", 1);
+ fContainer->CreateContainer("recTrackContDEMC", "Container for displaced electron analysis with MC information", 1);
+ fContainer->CreateCorrelationMatrix("correlationstepafterPID","THnSparse with correlations");
+ fContainer->CreateCorrelationMatrix("correlationstepafterDE","THnSparse with correlations");
+
+ // Define the step names
+ for(UInt_t istep = 0; istep < AliHFEcuts::kNcutStepsMCTrack; istep++){
+ fContainer->SetStepTitle("MCTrackCont", AliHFEcuts::MCCutName(istep), istep);
+ }
+ for(UInt_t istep = 0; istep < AliHFEcuts::kNcutStepsRecTrack; istep++){
+ fContainer->SetStepTitle("recTrackContReco", AliHFEcuts::RecoCutName(istep), istep);
+ fContainer->SetStepTitle("recTrackContMC", AliHFEcuts::RecoCutName(istep), istep);
+ }
+ for(UInt_t ipid = 0; ipid < fPID->GetNumberOfPIDdetectors(); ipid++){
+ fContainer->SetStepTitle("recTrackContReco", fPID->SortedDetectorName(ipid), AliHFEcuts::kNcutStepsRecTrack + ipid);
+ fContainer->SetStepTitle("recTrackContMC", fPID->SortedDetectorName(ipid), AliHFEcuts::kNcutStepsRecTrack + ipid);
}
- for(Int_t ivar = 0; ivar < kNvar; ivar++)
- delete binEdges[ivar];
- for(Int_t ivar = kNvar; ivar < nDim; ivar++)
- delete binEdges2[ivar];
}
//____________________________________________________________
-void AliAnalysisTaskHFE::AddPIDdetector(TString detector){
- //
- // Adding PID detector to the task
- //
- if(!fPIDdetectors.Length())
- fPIDdetectors = detector;
- else
- fPIDdetectors += ":" + detector;
+void AliAnalysisTaskHFE::InitPIDperformanceQA(){
+ // Add a histogram for Fake electrons
+ const Int_t nDim=6;
+ Int_t nBin[nDim] = {40, 8, 18, 2, 3, 3};
+ //number of variables on the grid:pt,eta,phi,charge,
+ const Double_t kPtbound[2] = {0.1, 20.};
+ const Double_t kEtabound[2] = {-0.8, 0.8};
+ const Double_t kPhibound[2] = {0., 2. * TMath::Pi()};
+ const Double_t kChargebound[2] = {-1.1, 1.1};
+ const Double_t kAddInf1bound[2] = {0., 3.};
+ const Double_t kAddInf2bound[2] = {0., 3.};
+ Double_t minima[nDim] = {kPtbound[0], kEtabound[0], kPhibound[0], kChargebound[0], kAddInf1bound[0], kAddInf2bound[0]};
+ Double_t maxima[nDim] = {kPtbound[1], kEtabound[1], kPhibound[1], kChargebound[1], kAddInf1bound[1], kAddInf2bound[1]};
+
+ fQACollection->CreateTHnSparse("PIDperformance", "PID performance; pT [GeV/c]; theta [rad]; phi [rad]; charge; type (0 - not el, 1 - other el, 2 - HF el; flavor (0 - no, 1 - charm, 2 - bottom)", nDim, nBin, minima, maxima);
+ fQACollection->CreateTHnSparse("SignalToBackgroundMC", "PID performance; pT [GeV/c]; theta [rad]; phi [rad]; charge; flavor (0 - no, 1 - charm, 2 - bottom); ITS Cluster (0 - no, 1 - first (and maybe second), 2 - second)", nDim, nBin, minima, maxima);
+
+ fQACollection->BinLogAxis("PIDperformance", 0);
+ fQACollection->BinLogAxis("SignalToBackgroundMC", 0);
+ fQACollection->Sumw2("PIDperformance");
+ fQACollection->Sumw2("SignalToBackgroundMC");
}
//____________________________________________________________
printf("\n\tAnalysis Settings\n\t========================================\n\n");
printf("\tSecondary Vertex finding: %s\n", GetPlugin(kSecVtx) ? "YES" : "NO");
printf("\tPrimary Vertex resolution: %s\n", GetPlugin(kPriVtx) ? "YES" : "NO");
+ printf("\tDisplaced electron analysis step: %s\n", GetPlugin(kDEstep) ? "YES" : "NO");
+ printf("\tTagged Track Analysis: %s\n", GetPlugin(kTaggedTrackAnalysis) ? "YES" : "NO");
printf("\n");
printf("\tParticle Identification Detectors:\n");
- TObjArray *detectors = fPIDdetectors.Tokenize(":");
- for(Int_t idet = 0; idet < detectors->GetEntries(); idet++)
- printf("\t\t%s\n", (dynamic_cast<TObjString *>(detectors->At(idet)))->String().Data());
+ fPID->PrintStatus();
printf("\n");
printf("\tQA: \n");
printf("\t\tPID: %s\n", IsQAOn(kPIDqa) ? "YES" : "NO");
- printf("\t\tCUTS: %s\n", (fCuts != NULL && fCuts->IsInDebugMode()) ? "YES" : "NO");
+ printf("\t\tCUTS: %s\n", (fCuts != NULL && fCuts->IsQAOn()) ? "YES" : "NO");
printf("\t\tMC: %s\n", IsQAOn(kMCqa) ? "YES" : "NO");
printf("\n");
}
//____________________________________________________________
-AliAnalysisTaskHFE::LabelContainer::LabelContainer(Int_t capacity):
- fContainer(NULL),
- fBegin(NULL),
- fEnd(NULL),
- fLast(NULL),
- fCurrent(NULL)
-{
- //
- // Default constructor
- //
- fContainer = new Int_t[capacity];
- fBegin = &fContainer[0];
- fEnd = &fContainer[capacity - 1];
- fLast = fCurrent = fBegin;
-}
-
-//____________________________________________________________
-Bool_t AliAnalysisTaskHFE::LabelContainer::Append(Int_t label){
- //
- // Add Label to the container
- //
- if(fLast > fEnd) return kFALSE;
- *fLast++ = label;
- return kTRUE;
-}
-
-//____________________________________________________________
-Bool_t AliAnalysisTaskHFE::LabelContainer::Find(Int_t label) const {
+Bool_t AliAnalysisTaskHFE::FillProductionVertex(const AliVParticle * const track) const{
//
- // Find track in the list of labels
+ // Find the production vertex of the associated MC track
//
- for(Int_t *entry = fBegin; entry <= fLast; entry++)
- if(*entry == label) return kTRUE;
- return kFALSE;
-}
+ if(!fMCEvent) return kFALSE;
+ const AliVParticle *mctrack = NULL;
+ TString objectType = track->IsA()->GetName();
+ if(objectType.CompareTo("AliESDtrack") == 0 || objectType.CompareTo("AliAODTrack") == 0){
+ // Reconstructed track
+ mctrack = fMCEvent->GetTrack(TMath::Abs(track->GetLabel()));
+ } else {
+ // MCParticle
+ mctrack = track;
+ }
-//____________________________________________________________
-Int_t AliAnalysisTaskHFE::LabelContainer::Next(){
- //
- // Mimic iterator
- //
- if(fCurrent > fLast) return -1;
- return *fCurrent++;
-}
+ if(!mctrack) return kFALSE;
-//____________________________________________________________
-Int_t AliAnalysisTaskHFE::IsSignalElectron(AliVParticle *fTrack) const{
- //
- // Checks whether the identified electron track is coming from heavy flavour
- // returns 0 in case of no signal, 1 in case of charm and 2 in case of Bottom
- //
- enum{
- kNoSignal = 0,
- kCharm = 1,
- kBeauty = 2
- };
- TString objname = fTrack->IsA()->GetName();
- Int_t pid = 0;
- if(IsESDanalysis()){
- // ESD Analysis
- AliMCParticle *mctrack = NULL;
- if(!objname.CompareTo("AliESDtrack")){
- AliDebug(2, "Checking signal for ESD track");
- AliESDtrack *esdtrack = dynamic_cast<AliESDtrack *>(fTrack);
- mctrack = dynamic_cast<AliMCParticle *>(fMCEvent->GetTrack(TMath::Abs(esdtrack->GetLabel())));
- }
- else if(!objname.CompareTo("AliMCParticle")){
- AliDebug(2, "Checking signal for MC track");
- mctrack = dynamic_cast<AliMCParticle *>(fTrack);
- }
- else{
- AliError("Input object not supported");
- return kNoSignal;
- }
- if(!mctrack) return kNoSignal;
- TParticle *ecand = mctrack->Particle();
- if(TMath::Abs(ecand->GetPdgCode()) != 11) return kNoSignal; // electron candidate not true electron
- Int_t motherLabel = TMath::Abs(ecand->GetFirstMother());
- AliDebug(3, Form("mother label: %d\n", motherLabel));
- if(!motherLabel) return kNoSignal; // mother track unknown
- AliMCParticle *motherTrack = dynamic_cast<AliMCParticle *>(fMCEvent->GetTrack(motherLabel));
- if(!motherTrack) return kNoSignal;
- TParticle *mparticle = motherTrack->Particle();
- pid = TMath::Abs(mparticle->GetPdgCode());
+ Double_t xv = 0.0;
+ Double_t yv = 0.0;
+
+ if(TString(mctrack->IsA()->GetName()).CompareTo("AliMCParticle") == 0){
+ // case MCParticle
+ xv = (dynamic_cast<const AliMCParticle *>(mctrack)->Xv());
+ yv = (dynamic_cast<const AliMCParticle *>(mctrack)->Yv());
+
} else {
- // AOD Analysis - Different Data handling
- AliAODMCParticle *aodmc = NULL;
- if(!objname.CompareTo("AliAODTrack")){
- AliAODTrack *aodtrack = dynamic_cast<AliAODTrack *>(fTrack);
- Int_t aodlabel = TMath::Abs(aodtrack->GetLabel());
- if(aodlabel >= fMCEvent->GetNumberOfTracks()) return kNoSignal;
- aodmc = dynamic_cast<AliAODMCParticle *>(fMCEvent->GetTrack(aodlabel));
- } else if(!objname.CompareTo("AliAODMCParticle")){
- aodmc = dynamic_cast<AliAODMCParticle *>(fTrack);
- } else{
- AliError("Input object not supported");
- return kNoSignal;
- }
- if(!aodmc) return kNoSignal;
- Int_t motherLabel = TMath::Abs(aodmc->GetMother());
- AliDebug(3, Form("mother label: %d\n", motherLabel));
- if(!motherLabel || motherLabel >= fMCEvent->GetNumberOfTracks()) return kNoSignal;
- AliAODMCParticle *aodmother = dynamic_cast<AliAODMCParticle *>(fMCEvent->GetTrack(motherLabel));
- pid = aodmother->GetPdgCode();
+ // case AODMCParticle
+ xv = (dynamic_cast<const AliAODMCParticle *>(mctrack)->Xv());
+ yv = (dynamic_cast<const AliAODMCParticle *>(mctrack)->Yv());
}
- // From here the two analysis modes go together
- AliDebug(3, Form("PDG code: %d\n", pid));
-
- // identify signal according to Pdg Code
- if((pid % 1000) / 100 == 4) return kCharm; // charmed meson, 3rd position in pdg code == 4
- if(pid / 1000 == 4) return kCharm; // charmed baryon, 4th position in pdg code == 4
- if((pid % 1000) / 100 == 5) return kBeauty; // beauty meson, 3rd position in pdg code == 5
- if(pid / 1000 == 5) return kBeauty; // beauty baryon, 4th position in pdg code == 5
- return kNoSignal;
-}
+ //printf("xv %f, yv %f\n",xv,yv);
+ fQACollection->Fill("radius", TMath::Abs(xv),TMath::Abs(yv));
+
+ return kTRUE;
+
+}
//__________________________________________
void AliAnalysisTaskHFE::SwitchOnPlugin(Int_t plug){
//
case kSecVtx: SETBIT(fPlugins, plug); break;
case kIsElecBackGround: SETBIT(fPlugins, plug); break;
case kPostProcess: SETBIT(fPlugins, plug); break;
+ case kDEstep: SETBIT(fPlugins, plug); break;
+ case kTaggedTrackAnalysis: SETBIT(fPlugins, plug); break;
default: AliError("Unknown Plugin");
};
}
-
//__________________________________________
-Bool_t AliAnalysisTaskHFE::ProcessCutStep(Int_t cutStep, AliVParticle *track, Double_t *container, Bool_t signal, Bool_t alreadyseen){
+Bool_t AliAnalysisTaskHFE::ProcessCutStep(Int_t cutStep, AliVParticle *track){
//
// Check single track cuts for a given cut step
// Fill the particle container
//
- if(!fCFM->CheckParticleCuts(cutStep, track)) return kFALSE;
- if(signal) {
- fCFM->GetParticleContainer()->Fill(container, cutStep + 2*AliHFEcuts::kNcutStepsESDtrack);
- fCFM->GetParticleContainer()->Fill(&container[4], cutStep);
- if(alreadyseen) {
- fCFM->GetParticleContainer()->Fill(&container[4], cutStep + AliHFEcuts::kNcutStepsESDtrack);
- }
+ const Int_t kMCOffset = AliHFEcuts::kNcutStepsMCTrack;
+ if(!fCFM->CheckParticleCuts(cutStep + kMCOffset, track)) return kFALSE;
+ if(fVarManager->IsSignalTrack()) {
+ fVarManager->FillContainer(fContainer, "recTrackContReco", cutStep, kFALSE);
+ fVarManager->FillContainer(fContainer, "recTrackContMC", cutStep, kTRUE);
}
return kTRUE;
}
+//___________________________________________________
+void AliAnalysisTaskHFE::ReadCentrality() {
+ //
+ // Recover the centrality of the event from ESD or AOD
+ //
+ if(IsAODanalysis()){
+
+ AliAODEvent *fAOD = dynamic_cast<AliAODEvent *>(fInputEvent);
+ if(!fAOD){
+ AliError("AOD Event required for AOD Analysis")
+ return;
+ }
+ // Centrality
+ //AliAODCentrality *aodCentrality = fAOD->GetCentrality();
+ //Double_t fCentralityF = aodCentrality->GetCentralityPercentile("V0M");
+ fCentralityF = 99.0; // Fake for the moment
+
+
+ } else {
+
+ AliDebug(3, "Processing ESD Centrality");
+ AliESDEvent *fESD = dynamic_cast<AliESDEvent *>(fInputEvent);
+ if(!fESD){
+ AliError("ESD Event required for ESD Analysis")
+ return;
+ }
+ // Centrality
+ AliESDCentrality *esdCentrality = fESD->GetCentrality();
+ fCentralityF = esdCentrality->GetCentralityPercentile("V0M");
+
+ //printf("centrality %f\n",fCentralityF);
+
+ }
-//__________________________________________
-void AliAnalysisTaskHFE::SetTPCBetheBlochParameters(Double_t *pars){
+}
+//___________________________________________________
+void AliAnalysisTaskHFE::RejectionPileUpVertexRangeEventCut() {
//
- // Set Bethe-Bloch Parameters for TPC PID
+ // Recover the centrality of the event from ESD or AOD
//
- fPID->SetTPCBetheBlochParameters(pars);
+ if(IsAODanalysis()){
+
+ AliAODEvent *fAOD = dynamic_cast<AliAODEvent *>(fInputEvent);
+ if(!fAOD){
+ AliError("AOD Event required for AOD Analysis")
+ return;
+ }
+ // PileUp
+ if(fRemovePileUp && fAOD->IsPileupFromSPD()) fIdentifiedAsPileUp = kTRUE;
+ // Z vertex
+ if(TMath::Abs(fAOD->GetPrimaryVertex()->GetZ()) > fCuts->GetVertexRange()) fIdentifiedAsOutInz = kTRUE;
+ // Event Cut
+ fPassTheEventCut = kTRUE;
+ if(!fCFM->CheckEventCuts(AliHFEcuts::kEventStepReconstructed, fAOD)) fPassTheEventCut = kFALSE;
+
+
+ } else {
+
+ AliDebug(3, "Processing ESD Centrality");
+ AliESDEvent *fESD = dynamic_cast<AliESDEvent *>(fInputEvent);
+ if(!fESD){
+ AliError("ESD Event required for ESD Analysis")
+ return;
+ }
+ // PileUp
+ fIdentifiedAsPileUp = kFALSE;
+ if(fRemovePileUp && fESD->IsPileupFromSPD()) fIdentifiedAsPileUp = kTRUE;
+ // Z vertex
+ fIdentifiedAsOutInz = kFALSE;
+ if(fESD->GetPrimaryVertexTracks()){
+ if(TMath::Abs(fESD->GetPrimaryVertexTracks()->GetZ()) > fCuts->GetVertexRange()) fIdentifiedAsOutInz = kTRUE;
+ }
+ //Event Cut
+ fPassTheEventCut = kTRUE;
+ if(!fCFM->CheckEventCuts(AliHFEcuts::kEventStepReconstructed, fESD)) fPassTheEventCut = kFALSE;
+
+
+ }
+
}