[u/mrichter/AliRoot.git] / PWG1 / AliAnalysisTaskV0QA.h

#ifndef AliAnalysisTaskV0QA_h
#define AliAnalysisTaskV0QA_h
//----------------------------------
// Class to check the V0 method efficiency for 
// Author A. Marin   revision 18/10/2009
//----------------------------------

#include "THnSparse.h"
#include "TList.h"
#include "AliPID.h"
#include "AliAnalysisTaskSE.h"
#include "AliAnalysisManager.h"
#include "AliAnalysisDataContainer.h"

class TH1;
class THnSparse;
class TList;
class AliESDEvent;
class AliESD;
class TLorentzVector;
class AliAnalysisManager;
class AliAnalysisDataContainer;
class AliESDtrackCuts;
class AliMCEventHandler;
class AliStack;
class TChain;

class AliAnalysisTaskV0QA : public AliAnalysisTaskSE {
 public:
  //  AliAnalysisTaskV0QA() : AliAnalysisTask(), fESD(0), fChain(0) {}
    AliAnalysisTaskV0QA();
    AliAnalysisTaskV0QA(const char *name);
  
  virtual ~AliAnalysisTaskV0QA();
  
  virtual void   UserCreateOutputObjects();
  virtual void   UserExec(Option_t *option);
  virtual void   Terminate(Option_t *);

  void InspectListOfChargedParticles();
  void InspectListOfV0s();
  void FillHnSparseGamma();
  void FillHnSparseK0();
  void FillHnSparseL();
  void FillHnSparseAL();

  //  void getPID(AliESDtrack *esdTrack, Stat_t &fpid, Stat_t &fweight);


  //  AliESDtrackCuts* fEsdTrackCuts;           // Object containing the parameters of the esd track cuts
  //  void SetESDtrackCuts();


  Int_t GetTPCReference(Int_t label);


 private:


  AliESDEvent *fESD;                // ESD object
  AliStack * fStack;                // The MC Stack
  AliMCEventHandler* fMCtruth;      // The mc info
 
  TChain * fChain;                  // Input chian
  TList * fOutputContainer; // ! output data container

  THnSparse   *fSparseV0;   // THnSparse with Gamma info 
  THnSparse   *fSparseK0;   // THnSparse with K0 info
  THnSparse   *fSparseL;    // THnSparse with L info
  THnSparse   *fSparseAL;   // THnSparse with antiL info

  //////////////////////////////////

  Int_t fnEv;               // Number of event to analyse
  Int_t fgDim;              // Dimension of the THnSparse

  Int_t fnConvGamGeant;     // number of conversions in mc 

  Int_t * fgConvGamGeantIndex; //[fgDim] index of conversions in mc 
  Int_t * feNegConvGamGeantIndex; //[fgDim] index of e- from conversions in mc 
  Int_t * fePosConvGamGeantIndex; //[fgDim] index of e+ from conversions in mc 
  Float_t * feNegConvGamGeantLength; //[fgDim]  length of the e- from conv 
  Float_t * fePosConvGamGeantLength; //[fgDim]  length of the e+ from conv 


  Int_t * feNegConvGamSingleRecIndex; //[fgDim] index of e- from conversions reconstructed single
  Int_t * fePosConvGamSingleRecIndex; //[fgDim] index of e+ from conversions reconstructed single
  Int_t * feNegConvGamV0RecIndex;     //[fgDim] index of e- from conversions reconstructed in V0
  Int_t * fePosConvGamV0RecIndex;     //[fgDim] index of e- from conversions reconstructed in V0
  Int_t * fConvGamV0RecIndexPos;      //[fgDim] index of V0 from conversions reconstructed
  Int_t * fConvGamV0RecIndexNeg;      //[fgDim] index of V0 from conversions reconstructed


   // Lambda  
  Int_t fnDecayLGeant;                // number of Lambda in mc 
  Int_t * flDecayLGeantIndex;         //[fgDim] index of Lambda in MC
  Int_t * fpiNegDecayLGeantIndex;     //[fgDim] index of pi- from L in MC
  Int_t * fpPosDecayLGeantIndex;      //[fgDim] index of proton from L in MC 
  Float_t * fpiNegDecayLGeantLength;  //[fgDim] length of the pi- from MC
  Float_t * fpPosDecayLGeantLength;   //[fgDim] length of the proton from MC

  Int_t * fpiNegDecayLSingleRecIndex; //[fgDim] index of pi- from L reconstr. single
  Int_t * fpPosDecayLSingleRecIndex;  //[fgDim] index of proton from L reconstr. single
  Int_t * fpiNegDecayLV0RecIndex;     //[fgDim] index of pi- from L reconstr. V0
  Int_t * fpPosDecayLV0RecIndex;      //[fgDim] index of proton from L reconstr. V0
  Int_t * fDecayLV0RecIndexPos;       //[fgDim] index of pi- from L reconstr. V0
  Int_t * fDecayLV0RecIndexNeg;       //[fgDim] index of proton from L reconstr.


  // AntiLambda
  Int_t fnDecayALGeant;               // number of Lambdabar in mc 
  Int_t * falDecayALGeantIndex;       //[fgDim] index of Lambdabar in MC
  Int_t * fpiPosDecayALGeantIndex;    //[fgDim] index of pi+ from AL in MC
  Int_t * fapNegDecayALGeantIndex;    //[fgDim] index of antiproton from AL in MC
  Float_t * fpiPosDecayALGeantLength; //[fgDim] Length of pi+ in MC 
  Float_t * fapNegDecayALGeantLength; //[fgDim] Length of antiproton in MC 

  Int_t * fpiPosDecayALSingleRecIndex; //[fgDim] index of pi+ from AL reconstr. single
  Int_t * fapNegDecayALSingleRecIndex; //[fgDim] index of antiproton from AL reconstr. single
  Int_t * fpiPosDecayALV0RecIndex;     //[fgDim] index of pi+ from AL reconstr. V0 
  Int_t * fapNegDecayALV0RecIndex;     //[fgDim] index of antiproton from AL reconstr. V0  
  Int_t * fDecayALV0RecIndexPos;       //[fgDim] index of pi+ V0
  Int_t * fDecayALV0RecIndexNeg;       //[fgDim] index of antiproton V0


  // K0S
  Int_t fnDecayK0Geant;                // number of K0s in mc  
  Int_t * fK0DecayK0GeantIndex;        //[fgDim] index of K0S in MC
  Int_t * fpiNegDecayK0GeantIndex;     //[fgDim] index of pi- from K0s in MC
  Int_t * fpiPosDecayK0GeantIndex;     //[fgDim] index of pi+ from K0s in MC
  Float_t * fpiNegDecayK0GeantLength;  //[fgDim] length of the pi- from K0s in MC
  Float_t * fpiPosDecayK0GeantLength;  //[fgDim] length of the pi+ from K0s in MC

  Int_t * fpiNegDecayK0SingleRecIndex;  //[fgDim] index of pi- from K0S reconstr. single
  Int_t * fpiPosDecayK0SingleRecIndex;  //[fgDim] index of pi+ from K0S reconstr. single 
  Int_t * fpiNegDecayK0V0RecIndex;      //[fgDim] index of pi- from K0S reconstr. V0    
  Int_t * fpiPosDecayK0V0RecIndex;      //[fgDim] index of pi+ from K0S reconstr. V0
  Int_t * fDecayK0V0RecIndexPos;        //[fgDim] index of pi+ V0 
  Int_t * fDecayK0V0RecIndexNeg;        //[fgDim] index of pi- V0  

  Int_t fpiPosK0Index;    //      
  Int_t fpiNegK0Index;    //

  
  Int_t fnTracksPrim;    // number of primary tracks contributing to vertex


  Int_t ftpcRefit;    // tpcRefit condition
  Int_t fitsRefit;    // itsRefit condition
  Int_t ftrdRefit;    // trdRefit condition
  Int_t ftrdOut;      // trdOut condition


  //Double_t fprobabilityPos[AliPID::kSPECIES];
  //Double_t fprobabilityNeg[AliPID::kSPECIES];

  Int_t    fDim;        // number of dimensions THnSparse
  Double_t * fValueL;   //[fDim] values to THnSparse for L
  Double_t * fValueAL;  //[fDim] values to THnSparse for AL
  Double_t * fValueK0;  //[fDim] values to THnSparse for K0
  Double_t * fValueV0;  //[fDim] values to THnSparse for Gamma

  Double_t * fxminV0;   //[fDim] min value to THnSparse
  Double_t * fxmaxV0;   //[fDim] max value to THnSparse
  Int_t    * fbinsV0;   //[fDim] number of bins to THnSparse
  Int_t	 fCentralityC;  // centrality


  TObjArray* fRefTPC;   // references for the tpc
  int fLabelsTPC[100000]; // labels for the tpc


  TClonesArray *fclRefsN;  // negative references for the tpc
  TClonesArray *fclRefsP;  // positive references for the tpc

  // MC variables

  AliAnalysisTaskV0QA (const AliAnalysisTaskV0QA & v0QA );
  AliAnalysisTaskV0QA & operator=(const AliAnalysisTaskV0QA & v0QA);


  ClassDef(AliAnalysisTaskV0QA, 1); // example of analysis
};


#endif
Commit	Line	Data
	1	#ifndef AliAnalysisTaskV0QA_h
	2	#define AliAnalysisTaskV0QA_h
	3	//----------------------------------
	4	// Class to check the V0 method efficiency for
	5	// Author A. Marin revision 18/10/2009
	6	//----------------------------------
	7
	8	#include "THnSparse.h"
	9	#include "TList.h"
	10	#include "AliPID.h"
	11	#include "AliAnalysisTaskSE.h"
	12	#include "AliAnalysisManager.h"
	13	#include "AliAnalysisDataContainer.h"
	14
	15	class TH1;
	16	class THnSparse;
	17	class TList;
	18	class AliESDEvent;
	19	class AliESD;
	20	class TLorentzVector;
	21	class AliAnalysisManager;
	22	class AliAnalysisDataContainer;
	23	class AliESDtrackCuts;
	24	class AliMCEventHandler;
	25	class AliStack;
	26	class TChain;
	27
	28	class AliAnalysisTaskV0QA : public AliAnalysisTaskSE {
	29	public:
	30	// AliAnalysisTaskV0QA() : AliAnalysisTask(), fESD(0), fChain(0) {}
	31	AliAnalysisTaskV0QA();
	32	AliAnalysisTaskV0QA(const char *name);
	33
	34	virtual ~AliAnalysisTaskV0QA();
	35
	36	virtual void UserCreateOutputObjects();
	37	virtual void UserExec(Option_t *option);
	38	virtual void Terminate(Option_t *);
	39
	40	void InspectListOfChargedParticles();
	41	void InspectListOfV0s();
	42	void FillHnSparseGamma();
	43	void FillHnSparseK0();
	44	void FillHnSparseL();
	45	void FillHnSparseAL();
	46
	47	// void getPID(AliESDtrack *esdTrack, Stat_t &fpid, Stat_t &fweight);
	48
	49
	50	// AliESDtrackCuts* fEsdTrackCuts; // Object containing the parameters of the esd track cuts
	51	// void SetESDtrackCuts();
	52
	53
	54
	55
	56	Int_t GetTPCReference(Int_t label);
	57
	58
	59
	60
	61	private:
	62
	63
	64
	65	AliESDEvent *fESD; // ESD object
	66	AliStack * fStack; // The MC Stack
	67	AliMCEventHandler* fMCtruth; // The mc info
	68
	69	TChain * fChain; // Input chian
	70	TList * fOutputContainer; // ! output data container
	71
	72	THnSparse *fSparseV0; // THnSparse with Gamma info
	73	THnSparse *fSparseK0; // THnSparse with K0 info
	74	THnSparse *fSparseL; // THnSparse with L info
	75	THnSparse *fSparseAL; // THnSparse with antiL info
	76
	77	//////////////////////////////////
	78
	79	Int_t fnEv; // Number of event to analyse
	80	Int_t fgDim; // Dimension of the THnSparse
	81
	82	Int_t fnConvGamGeant; // number of conversions in mc
	83
	84	Int_t * fgConvGamGeantIndex; //[fgDim] index of conversions in mc
	85	Int_t * feNegConvGamGeantIndex; //[fgDim] index of e- from conversions in mc
	86	Int_t * fePosConvGamGeantIndex; //[fgDim] index of e+ from conversions in mc
	87	Float_t * feNegConvGamGeantLength; //[fgDim] length of the e- from conv
	88	Float_t * fePosConvGamGeantLength; //[fgDim] length of the e+ from conv
	89
	90
	91	Int_t * feNegConvGamSingleRecIndex; //[fgDim] index of e- from conversions reconstructed single
	92	Int_t * fePosConvGamSingleRecIndex; //[fgDim] index of e+ from conversions reconstructed single
	93	Int_t * feNegConvGamV0RecIndex; //[fgDim] index of e- from conversions reconstructed in V0
	94	Int_t * fePosConvGamV0RecIndex; //[fgDim] index of e- from conversions reconstructed in V0
	95	Int_t * fConvGamV0RecIndexPos; //[fgDim] index of V0 from conversions reconstructed
	96	Int_t * fConvGamV0RecIndexNeg; //[fgDim] index of V0 from conversions reconstructed
	97
	98
	99
	100	// Lambda
	101	Int_t fnDecayLGeant; // number of Lambda in mc
	102	Int_t * flDecayLGeantIndex; //[fgDim] index of Lambda in MC
	103	Int_t * fpiNegDecayLGeantIndex; //[fgDim] index of pi- from L in MC
	104	Int_t * fpPosDecayLGeantIndex; //[fgDim] index of proton from L in MC
	105	Float_t * fpiNegDecayLGeantLength; //[fgDim] length of the pi- from MC
	106	Float_t * fpPosDecayLGeantLength; //[fgDim] length of the proton from MC
	107
	108	Int_t * fpiNegDecayLSingleRecIndex; //[fgDim] index of pi- from L reconstr. single
	109	Int_t * fpPosDecayLSingleRecIndex; //[fgDim] index of proton from L reconstr. single
	110	Int_t * fpiNegDecayLV0RecIndex; //[fgDim] index of pi- from L reconstr. V0
	111	Int_t * fpPosDecayLV0RecIndex; //[fgDim] index of proton from L reconstr. V0
	112	Int_t * fDecayLV0RecIndexPos; //[fgDim] index of pi- from L reconstr. V0
	113	Int_t * fDecayLV0RecIndexNeg; //[fgDim] index of proton from L reconstr.
	114
	115
	116	// AntiLambda
	117	Int_t fnDecayALGeant; // number of Lambdabar in mc
	118	Int_t * falDecayALGeantIndex; //[fgDim] index of Lambdabar in MC
	119	Int_t * fpiPosDecayALGeantIndex; //[fgDim] index of pi+ from AL in MC
	120	Int_t * fapNegDecayALGeantIndex; //[fgDim] index of antiproton from AL in MC
	121	Float_t * fpiPosDecayALGeantLength; //[fgDim] Length of pi+ in MC
	122	Float_t * fapNegDecayALGeantLength; //[fgDim] Length of antiproton in MC
	123
	124	Int_t * fpiPosDecayALSingleRecIndex; //[fgDim] index of pi+ from AL reconstr. single
	125	Int_t * fapNegDecayALSingleRecIndex; //[fgDim] index of antiproton from AL reconstr. single
	126	Int_t * fpiPosDecayALV0RecIndex; //[fgDim] index of pi+ from AL reconstr. V0
	127	Int_t * fapNegDecayALV0RecIndex; //[fgDim] index of antiproton from AL reconstr. V0
	128	Int_t * fDecayALV0RecIndexPos; //[fgDim] index of pi+ V0
	129	Int_t * fDecayALV0RecIndexNeg; //[fgDim] index of antiproton V0
	130
	131
	132	// K0S
	133	Int_t fnDecayK0Geant; // number of K0s in mc
	134	Int_t * fK0DecayK0GeantIndex; //[fgDim] index of K0S in MC
	135	Int_t * fpiNegDecayK0GeantIndex; //[fgDim] index of pi- from K0s in MC
	136	Int_t * fpiPosDecayK0GeantIndex; //[fgDim] index of pi+ from K0s in MC
	137	Float_t * fpiNegDecayK0GeantLength; //[fgDim] length of the pi- from K0s in MC
	138	Float_t * fpiPosDecayK0GeantLength; //[fgDim] length of the pi+ from K0s in MC
	139
	140	Int_t * fpiNegDecayK0SingleRecIndex; //[fgDim] index of pi- from K0S reconstr. single
	141	Int_t * fpiPosDecayK0SingleRecIndex; //[fgDim] index of pi+ from K0S reconstr. single
	142	Int_t * fpiNegDecayK0V0RecIndex; //[fgDim] index of pi- from K0S reconstr. V0
	143	Int_t * fpiPosDecayK0V0RecIndex; //[fgDim] index of pi+ from K0S reconstr. V0
	144	Int_t * fDecayK0V0RecIndexPos; //[fgDim] index of pi+ V0
	145	Int_t * fDecayK0V0RecIndexNeg; //[fgDim] index of pi- V0
	146
	147	Int_t fpiPosK0Index; //
	148	Int_t fpiNegK0Index; //
	149
	150
	151	Int_t fnTracksPrim; // number of primary tracks contributing to vertex
	152
	153
	154	Int_t ftpcRefit; // tpcRefit condition
	155	Int_t fitsRefit; // itsRefit condition
	156	Int_t ftrdRefit; // trdRefit condition
	157	Int_t ftrdOut; // trdOut condition
	158
	159
	160
	161
	162	//Double_t fprobabilityPos[AliPID::kSPECIES];
	163	//Double_t fprobabilityNeg[AliPID::kSPECIES];
	164
	165	Int_t fDim; // number of dimensions THnSparse
	166	Double_t * fValueL; //[fDim] values to THnSparse for L
	167	Double_t * fValueAL; //[fDim] values to THnSparse for AL
	168	Double_t * fValueK0; //[fDim] values to THnSparse for K0
	169	Double_t * fValueV0; //[fDim] values to THnSparse for Gamma
	170
	171	Double_t * fxminV0; //[fDim] min value to THnSparse
	172	Double_t * fxmaxV0; //[fDim] max value to THnSparse
	173	Int_t * fbinsV0; //[fDim] number of bins to THnSparse
	174	Int_t fCentralityC; // centrality
	175
	176
	177
	178	TObjArray* fRefTPC; // references for the tpc
	179	int fLabelsTPC[100000]; // labels for the tpc
	180
	181
	182	TClonesArray *fclRefsN; // negative references for the tpc
	183	TClonesArray *fclRefsP; // positive references for the tpc
	184
	185	// MC variables
	186
	187	AliAnalysisTaskV0QA (const AliAnalysisTaskV0QA & v0QA );
	188	AliAnalysisTaskV0QA & operator=(const AliAnalysisTaskV0QA & v0QA);
	189
	190
	191
	192	ClassDef(AliAnalysisTaskV0QA, 1); // example of analysis
	193	};
	194
	195
	196	#endif