void SwitchOnFillAsymmetryHisto() { fFillAsymmetryHisto = kTRUE ; }
void SwitchOffFillAsymmetryHisto() { fFillAsymmetryHisto = kFALSE ; }
+ void SwitchOnFillOriginHisto() { fFillOriginHisto = kTRUE ; }
+ void SwitchOffFillOriginHisto() { fFillOriginHisto = kFALSE ; }
//MC analysis related methods
Bool_t fFillSSCombinations; // Do invariant mass for different combination of shower shape clusters
Bool_t fFillAngleHisto; // Fill histograms with pair opening angle
Bool_t fFillAsymmetryHisto; // Fill histograms with asymmetry vs pt
+ Bool_t fFillOriginHisto; // Fill histograms depending on their origin
//Histograms
//MC analysis histograms
//Pi0 Acceptance
- TH1F * fhPrimPi0Pt ; //! Spectrum of Primary
- TH1F * fhPrimPi0AccPt ; //! Spectrum of primary with accepted daughters
+ TH1F * fhPrimPi0E ; //! Spectrum of Primary
+ TH1F * fhPrimPi0Pt ; //! Spectrum of Primary
+ TH1F * fhPrimPi0AccE ; //! Spectrum of primary with accepted daughters
+ TH1F * fhPrimPi0AccPt ; //! Spectrum of primary with accepted daughters
TH2F * fhPrimPi0Y ; //! Rapidity distribution of primary particles vs pT
TH2F * fhPrimPi0AccY ; //! Rapidity distribution of primary with accepted daughters vs pT
TH2F * fhPrimPi0Phi ; //! Azimutal distribution of primary particles vs pT
TH2F * fhPrimPi0AccPhi; //! Azimutal distribution of primary with accepted daughters vs pT
TH2F * fhPrimPi0OpeningAngle ; //! Opening angle of pair versus pair energy, primaries
- TH2F * fhPrimPi0CosOpeningAngle ; //! Cosinus of opening angle of pair version pair energy, primaries
+ TH2F * fhPrimPi0OpeningAngleAsym ; //! Opening angle of pair versus pair E asymmetry, pi0 primaries
+ TH2F * fhPrimPi0CosOpeningAngle ; //! Cosinus of opening angle of pair version pair energy, pi0 primaries
+ TH2F * fhPrimPi0PtCentrality ; //! primary pi0 reconstructed centrality vs pT
+ TH2F * fhPrimPi0PtEventPlane ; //! primary pi0 reconstructed event plane vs pT
+ TH2F * fhPrimPi0AccPtCentrality ; //! primary pi0 with accepted daughters reconstructed centrality vs pT
+ TH2F * fhPrimPi0AccPtEventPlane ; //! primary pi0 with accepted daughters reconstructed event plane vs pT
+
//Eta acceptance
- TH1F * fhPrimEtaPt ; //! Spectrum of Primary
- TH1F * fhPrimEtaAccPt ; //! Spectrum of primary with accepted daughters
+ TH1F * fhPrimEtaE ; //! Spectrum of Primary
+ TH1F * fhPrimEtaPt ; //! Spectrum of Primary
+ TH1F * fhPrimEtaAccE ; //! Spectrum of primary with accepted daughters
+ TH1F * fhPrimEtaAccPt ; //! Spectrum of primary with accepted daughters
TH2F * fhPrimEtaY ; //! Rapidity distribution of primary particles vs pT
TH2F * fhPrimEtaAccY ; //! Rapidity distribution of primary with accepted daughters vs pT
TH2F * fhPrimEtaPhi ; //! Azimutal distribution of primary particles vs pT
TH2F * fhPrimEtaAccPhi; //! Azimutal distribution of primary with accepted daughters vs pT
+ TH2F * fhPrimEtaOpeningAngle ; //! Opening angle of pair versus pair energy, eta primaries
+ TH2F * fhPrimEtaOpeningAngleAsym ; //! Opening angle of pair versus pair E asymmetry, eta primaries
+ TH2F * fhPrimEtaCosOpeningAngle ; //! Cosinus of opening angle of pair version pair energy, eta primaries
+ TH2F * fhPrimEtaPtCentrality ; //! primary eta reconstructed centrality vs pT
+ TH2F * fhPrimEtaPtEventPlane ; //! primary eta reconstructed event plane vs pT
+ TH2F * fhPrimEtaAccPtCentrality ; //! primary eta with accepted daughters reconstructed centrality vs pT
+ TH2F * fhPrimEtaAccPtEventPlane ; //! primary eta with accepted daughters reconstructed event plane vs pT
// Primaries origin
TH2F * fhPrimPi0PtOrigin ; //! Spectrum of generated pi0 vs mother
AliAnaPi0( const AliAnaPi0 & api0) ; // cpy ctor
AliAnaPi0 & operator = (const AliAnaPi0 & api0) ; // cpy assignment
- ClassDef(AliAnaPi0,23)
+ ClassDef(AliAnaPi0,24)
} ;