[u/mrichter/AliRoot.git] / PWGCF / Correlations / Base / AliUEHistograms.h

#ifndef AliUEHistograms_H
#define AliUEHistograms_H

/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 * See cxx source for full Copyright notice                               */

/* $Id: AliUEHistograms.h 20164 2007-08-14 15:31:50Z morsch $ */

// encapsulates several AliUEHist objects for a full UE analysis plus additional control histograms

#include "TNamed.h"
#include "AliUEHist.h"

class AliVParticle;

class TList;
class TSeqCollection;
class TObjArray;
class TH1F;
class TH2F;
class TH3F;

class AliUEHistograms : public TNamed
{
 public:
  AliUEHistograms(const char* name = "AliUEHistograms", const char* histograms = "123");
  virtual ~AliUEHistograms();
  
  void Fill(Int_t eventType, Float_t zVtx, AliUEHist::CFStep step, AliVParticle* leading, TList* toward, TList* away, TList* min, TList* max);
  void FillCorrelations(Double_t centrality, Float_t zVtx, AliUEHist::CFStep step, TObjArray* particles, TObjArray* mixed = 0, Float_t weight = 1, Bool_t firstTime = kTRUE, Bool_t twoTrackEfficiencyCut = kFALSE, Float_t bSign = 0);
  void Fill(AliVParticle* leadingMC, AliVParticle* leadingReco);
  void FillEvent(Int_t eventType, Int_t step);
  void FillEvent(Double_t centrality, Int_t step);
  void FillTrackingEfficiency(TObjArray* mc, TObjArray* recoPrim, TObjArray* recoAll, Int_t particleType, Double_t centrality = 0);
  
  void TwoTrackEfficiency(TObjArray* tracks, TObjArray* mixed, Float_t bSign);
  
  void CopyReconstructedData(AliUEHistograms* from);
  
  AliUEHist* GetUEHist(Int_t id);
  
  AliUEHist* GetNumberDensitypT() { return fNumberDensitypT; }
  AliUEHist* GetSumpT() { return fSumpT; }
  AliUEHist* GetNumberDensityPhi() { return fNumberDensityPhi; }
  
  void SetNumberDensitypT(AliUEHist* obj) { fNumberDensitypT = obj; }
  void SetSumpT(AliUEHist* obj) { fSumpT = obj; }
  void SetNumberDensityPhi(AliUEHist* obj) { fNumberDensityPhi = obj; }
  
  void SetRunNumber(Long64_t runNumber) { fRunNumber = runNumber; }
  
  TH2F* GetCorrelationpT()  { return fCorrelationpT; }
  TH2F* GetCorrelationEta() { return fCorrelationEta; }
  TH2F* GetCorrelationPhi() { return fCorrelationPhi; }
  TH2F* GetCorrelationR()   { return fCorrelationR; }
  TH2F* GetCorrelationLeading2Phi() { return fCorrelationLeading2Phi; }
  TH2F* GetCorrelationMultiplicity() { return fCorrelationMultiplicity; }
  
  TH2F* GetEventCount()     { return fEventCount; }
  TH3F* GetEventCountDifferential() { return fEventCountDifferential; }
  TH1F* GetVertexContributors() { return fVertexContributors; }
  TH1F* GetCentralityDistribution() { return fCentralityDistribution; }
  Long64_t GetRunNumber() { return fRunNumber; }
  TH3F* GetTwoTrackDistance(Int_t i) { return fTwoTrackDistancePt[i]; }
  
  void Correct(AliUEHistograms* corrections);
  
  void SetEtaRange(Float_t etaMin, Float_t etaMax);
  void SetPtRange(Float_t ptMin, Float_t ptMax);
  void SetZVtxRange(Float_t min, Float_t max);
  void SetContaminationEnhancement(TH1F* hist);
  void SetCombineMinMax(Bool_t flag);
  void SetSelectCharge(Int_t selectCharge) { fSelectCharge = selectCharge; }
  void SetTriggerRestrictEta(Float_t eta) { fTriggerRestrictEta = eta; }
  void SetEtaOrdering(Bool_t flag) { fEtaOrdering = flag; }
  void SetPairCuts(Bool_t conversions, Bool_t resonances) { fCutConversions = conversions; fCutResonances = resonances; }
  
  void ExtendTrackingEfficiency(Bool_t verbose = kFALSE);
  void Reset();

  AliUEHistograms(const AliUEHistograms &c);
  AliUEHistograms& operator=(const AliUEHistograms& c);
  virtual void Copy(TObject& c) const;

  virtual Long64_t Merge(TCollection* list);
  void Scale(Double_t factor);
  
protected:
  void FillRegion(AliUEHist::Region region, Float_t zVtx, AliUEHist::CFStep step, AliVParticle* leading, TList* list, Int_t multiplicity);
  Int_t CountParticles(TList* list, Float_t ptMin);
  void DeleteContainers();
  Float_t GetInvMassSquared(Float_t pt1, Float_t eta1, Float_t phi1, Float_t pt2, Float_t eta2, Float_t phi2, Float_t m0);
  
  static const Int_t fgkUEHists; // number of histograms

  AliUEHist* fNumberDensitypT;   // d^2N/dphideta vs pT,lead
  AliUEHist* fSumpT;             // d^2 sum(pT)/dphideta vs pT,lead
  AliUEHist* fNumberDensityPhi;  // d^2N/dphideta vs delta phi,lead (in pT,lead bins)
  
  TH2F* fCorrelationpT;         // pT,lead: true vs reco
  TH2F* fCorrelationEta;        // #eta,lead; true vs reco
  TH2F* fCorrelationPhi;        // #phi,lead; true vs reco
  TH2F* fCorrelationR;          // R = sqrt(delta eta^2 + delta phi^2) (true vs reco) vs pT,lead,MC
  TH2F* fCorrelationLeading2Phi;// delta phi (true vs reco) vs pT,lead,MC
  TH2F* fCorrelationMultiplicity; // number of mc particls vs reco particles (for pT > 0.5 GeV/c)
  
  TH2F* fEventCount;            // event count as function of step, (for pp: event type (plus additional step -1 for all events without vertex range even in MC)) (for PbPb: centrality)
  TH3F* fEventCountDifferential;// event count as function of leading pT, step, event type
  
  TH1F* fVertexContributors;    // number of contributors to the vertex
  TH1F* fCentralityDistribution; // distribution of the variable used for centrality selection
  TH2F* fCentralityCorrelation;  // centrality vs multiplicity
  
  TH3F* fITSClusterMap;          // its cluster map vs centrality vs pT
  
  TH3F* fTwoTrackDistancePt[2];    // control histograms for two-track efficiency study: dphi*_min vs deta (0 = before cut, 1 = after cut)
  
  Int_t fSelectCharge;           // (un)like sign selection when building correlations: 0: no selection; 1: unlike sign; 2: like sign
  Float_t fTriggerRestrictEta;   // restrict eta range for trigger particle (default: -1 [off])
  Bool_t fEtaOrdering;           // activate eta ordering to prevent shape distortions. see FillCorrelation for the details
  Bool_t fCutConversions;        // cut on conversions (inv mass)
  Bool_t fCutResonances;         // cut on resonances (inv mass)
  
  Long64_t fRunNumber;           // run number that has been processed
  
  ClassDef(AliUEHistograms, 13)  // underlying event histogram container
};

#endif
Commit	Line	Data
a75aacd6	1	#ifndef AliUEHistograms_H
	2	#define AliUEHistograms_H
	3
	4	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	5	* See cxx source for full Copyright notice */
	6
	7	/* $Id: AliUEHistograms.h 20164 2007-08-14 15:31:50Z morsch $ */
	8
	9	// encapsulates several AliUEHist objects for a full UE analysis plus additional control histograms
	10
e0331fd9	11	#include "TNamed.h"
a75aacd6	12	#include "AliUEHist.h"
	13
	14	class AliVParticle;
	15
	16	class TList;
bf58cbde	17	class TSeqCollection;
eed401dc	18	class TObjArray;
a75aacd6	19	class TH1F;
	20	class TH2F;
	21	class TH3F;
	22
e0331fd9	23	class AliUEHistograms : public TNamed
a75aacd6	24	{
a75aacd6	25	public:
e0331fd9	26	AliUEHistograms(const char* name = "AliUEHistograms", const char* histograms = "123");
a75aacd6	27	virtual ~AliUEHistograms();
a75aacd6	28
85bfac17	29	void Fill(Int_t eventType, Float_t zVtx, AliUEHist::CFStep step, AliVParticle* leading, TList* toward, TList* away, TList* min, TList* max);
04af8d15	30	void FillCorrelations(Double_t centrality, Float_t zVtx, AliUEHist::CFStep step, TObjArray* particles, TObjArray* mixed = 0, Float_t weight = 1, Bool_t firstTime = kTRUE, Bool_t twoTrackEfficiencyCut = kFALSE, Float_t bSign = 0);
a75aacd6	31	void Fill(AliVParticle* leadingMC, AliVParticle* leadingReco);
a75aacd6	32	void FillEvent(Int_t eventType, Int_t step);
2a910c25	33	void FillEvent(Double_t centrality, Int_t step);
c7245604	34	void FillTrackingEfficiency(TObjArray* mc, TObjArray* recoPrim, TObjArray* recoAll, Int_t particleType, Double_t centrality = 0);
b1831bcb	35
c5c840c5	36	void TwoTrackEfficiency(TObjArray* tracks, TObjArray* mixed, Float_t bSign);
1bba939a	37
b1831bcb	38	void CopyReconstructedData(AliUEHistograms* from);
a75aacd6	39
ada1a03f	40	AliUEHist* GetUEHist(Int_t id);
ada1a03f	41
a75aacd6	42	AliUEHist* GetNumberDensitypT() { return fNumberDensitypT; }
	43	AliUEHist* GetSumpT() { return fSumpT; }
	44	AliUEHist* GetNumberDensityPhi() { return fNumberDensityPhi; }
	45
2a910c25	46	void SetNumberDensitypT(AliUEHist* obj) { fNumberDensitypT = obj; }
	47	void SetSumpT(AliUEHist* obj) { fSumpT = obj; }
	48	void SetNumberDensityPhi(AliUEHist* obj) { fNumberDensityPhi = obj; }
	49
85bfac17	50	void SetRunNumber(Long64_t runNumber) { fRunNumber = runNumber; }
85bfac17	51
a75aacd6	52	TH2F* GetCorrelationpT() { return fCorrelationpT; }
	53	TH2F* GetCorrelationEta() { return fCorrelationEta; }
	54	TH2F* GetCorrelationPhi() { return fCorrelationPhi; }
	55	TH2F* GetCorrelationR() { return fCorrelationR; }
	56	TH2F* GetCorrelationLeading2Phi() { return fCorrelationLeading2Phi; }
	57	TH2F* GetCorrelationMultiplicity() { return fCorrelationMultiplicity; }
	58
	59	TH2F* GetEventCount() { return fEventCount; }
	60	TH3F* GetEventCountDifferential() { return fEventCountDifferential; }
	61	TH1F* GetVertexContributors() { return fVertexContributors; }
bf58cbde	62	TH1F* GetCentralityDistribution() { return fCentralityDistribution; }
85bfac17	63	Long64_t GetRunNumber() { return fRunNumber; }
670e1d49	64	TH3F* GetTwoTrackDistance(Int_t i) { return fTwoTrackDistancePt[i]; }
a75aacd6	65
	66	void Correct(AliUEHistograms* corrections);
	67
	68	void SetEtaRange(Float_t etaMin, Float_t etaMax);
	69	void SetPtRange(Float_t ptMin, Float_t ptMax);
85bfac17	70	void SetZVtxRange(Float_t min, Float_t max);
144bd037	71	void SetContaminationEnhancement(TH1F* hist);
a75aacd6	72	void SetCombineMinMax(Bool_t flag);
c7245604	73	void SetSelectCharge(Int_t selectCharge) { fSelectCharge = selectCharge; }
d38fa455	74	void SetTriggerRestrictEta(Float_t eta) { fTriggerRestrictEta = eta; }
00b6f3c6	75	void SetEtaOrdering(Bool_t flag) { fEtaOrdering = flag; }
b0d56b29	76	void SetPairCuts(Bool_t conversions, Bool_t resonances) { fCutConversions = conversions; fCutResonances = resonances; }
a75aacd6	77
2a910c25	78	void ExtendTrackingEfficiency(Bool_t verbose = kFALSE);
c7245604	79	void Reset();
6f803f6c	80
d1c75d06	81	AliUEHistograms(const AliUEHistograms &c);
a75aacd6	82	AliUEHistograms& operator=(const AliUEHistograms& c);
	83	virtual void Copy(TObject& c) const;
	84
	85	virtual Long64_t Merge(TCollection* list);
c7245604	86	void Scale(Double_t factor);
a75aacd6	87
a75aacd6	88	protected:
85bfac17	89	void FillRegion(AliUEHist::Region region, Float_t zVtx, AliUEHist::CFStep step, AliVParticle* leading, TList* list, Int_t multiplicity);
a75aacd6	90	Int_t CountParticles(TList* list, Float_t ptMin);
b0d56b29	91	void DeleteContainers();
b0d56b29	92	Float_t GetInvMassSquared(Float_t pt1, Float_t eta1, Float_t phi1, Float_t pt2, Float_t eta2, Float_t phi2, Float_t m0);
bf58cbde	93
bf58cbde	94	static const Int_t fgkUEHists; // number of histograms
a75aacd6	95
	96	AliUEHist* fNumberDensitypT; // d^2N/dphideta vs pT,lead
	97	AliUEHist* fSumpT; // d^2 sum(pT)/dphideta vs pT,lead
	98	AliUEHist* fNumberDensityPhi; // d^2N/dphideta vs delta phi,lead (in pT,lead bins)
	99
	100	TH2F* fCorrelationpT; // pT,lead: true vs reco
	101	TH2F* fCorrelationEta; // #eta,lead; true vs reco
	102	TH2F* fCorrelationPhi; // #phi,lead; true vs reco
	103	TH2F* fCorrelationR; // R = sqrt(delta eta^2 + delta phi^2) (true vs reco) vs pT,lead,MC
	104	TH2F* fCorrelationLeading2Phi;// delta phi (true vs reco) vs pT,lead,MC
	105	TH2F* fCorrelationMultiplicity; // number of mc particls vs reco particles (for pT > 0.5 GeV/c)
	106
2a910c25	107	TH2F* fEventCount; // event count as function of step, (for pp: event type (plus additional step -1 for all events without vertex range even in MC)) (for PbPb: centrality)
a75aacd6	108	TH3F* fEventCountDifferential;// event count as function of leading pT, step, event type
	109
	110	TH1F* fVertexContributors; // number of contributors to the vertex
bf58cbde	111	TH1F* fCentralityDistribution; // distribution of the variable used for centrality selection
447d47d8	112	TH2F* fCentralityCorrelation; // centrality vs multiplicity
a75aacd6	113
2a910c25	114	TH3F* fITSClusterMap; // its cluster map vs centrality vs pT
2a910c25	115
670e1d49	116	TH3F* fTwoTrackDistancePt[2]; // control histograms for two-track efficiency study: dphi*_min vs deta (0 = before cut, 1 = after cut)
1bba939a	117
c7245604	118	Int_t fSelectCharge; // (un)like sign selection when building correlations: 0: no selection; 1: unlike sign; 2: like sign
d38fa455	119	Float_t fTriggerRestrictEta; // restrict eta range for trigger particle (default: -1 [off])
00b6f3c6	120	Bool_t fEtaOrdering; // activate eta ordering to prevent shape distortions. see FillCorrelation for the details
b0d56b29	121	Bool_t fCutConversions; // cut on conversions (inv mass)
b0d56b29	122	Bool_t fCutResonances; // cut on resonances (inv mass)
c7245604	123
85bfac17	124	Long64_t fRunNumber; // run number that has been processed
85bfac17	125
00b6f3c6	126	ClassDef(AliUEHistograms, 13) // underlying event histogram container
a75aacd6	127	};
	128
	129	#endif