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483b0559 | 1 | #ifndef ALIEMCALCLUSTERIZER_H |
2 | #define ALIEMCALCLUSTERIZER_H | |
3 | /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * | |
4 | * See cxx source for full Copyright notice */ | |
5 | ||
6 | /* $Id$ */ | |
7 | ||
8 | //_________________________________________________________________________ | |
9 | // Base class for the clusterization algorithm (pure abstract) | |
10 | //*-- Author: Yves Schutz (SUBATECH) & Dmitri Peressounko (SUBATECH & Kurchatov Institute) | |
8d0210ea | 11 | // |
12 | // Clusterization mother class. Contains common methods/data members of different | |
13 | // clusterizers. GCB 2010 | |
14 | //_________________________________________________________________________ | |
15 | ||
483b0559 | 16 | // --- ROOT system --- |
9cd23da3 | 17 | #include <TObject.h> |
18 | #include <TClonesArray.h> | |
c47157cd | 19 | class TTree; |
05a92d59 | 20 | |
483b0559 | 21 | // --- AliRoot header files --- |
9cd23da3 | 22 | #include "AliLog.h" |
ac084be7 | 23 | class AliEMCALGeometry; |
24 | class AliEMCALCalibData; | |
25 | class AliCaloCalibPedestal; | |
26 | class AliEMCALRecParam; | |
0d0d6b98 | 27 | #include "AliEMCALUnfolding.h" |
483b0559 | 28 | |
c47157cd | 29 | class AliEMCALClusterizer : public TObject { |
483b0559 | 30 | |
31 | public: | |
32 | ||
ac084be7 | 33 | AliEMCALClusterizer(); |
ac084be7 | 34 | AliEMCALClusterizer(AliEMCALGeometry *geometry); |
35 | AliEMCALClusterizer(AliEMCALGeometry *geometry, AliEMCALCalibData *calib, AliCaloCalibPedestal *pedestal); | |
8d0210ea | 36 | virtual ~AliEMCALClusterizer(); |
37 | ||
38 | // main methods | |
39 | ||
40 | virtual void DeleteDigits(); | |
41 | virtual void DeleteRecPoints(); | |
483b0559 | 42 | |
c47157cd | 43 | virtual void Digits2Clusters(Option_t *option) = 0; |
483b0559 | 44 | |
783153ff | 45 | virtual void Calibrate(Float_t & amp, Float_t & time, const Int_t cellId); |
ac084be7 | 46 | virtual void Init(); |
47 | virtual void InitParameters(); | |
48 | virtual void InitParameters(const AliEMCALRecParam* recParam); | |
ee08edde | 49 | |
9cd23da3 | 50 | virtual void Print (Option_t *option) const ; |
8d0210ea | 51 | virtual void PrintRecPoints(Option_t *option); |
52 | virtual void PrintRecoInfo(); | |
53 | ||
9cd23da3 | 54 | virtual const char *Version() const { Warning("Version", "Not Defined"); |
55 | return 0 ; } | |
8d0210ea | 56 | |
57 | //Getters-Setters | |
58 | ||
59 | virtual void SetInput (TTree *digitsTree ); | |
60 | virtual void SetOutput(TTree *clustersTree); | |
61 | ||
62 | virtual void GetCalibrationParameters(void); | |
63 | virtual void GetCaloCalibPedestal(void); | |
64 | virtual void SetCalibrationParameters(AliEMCALCalibData *calib) { fCalibData = calib; } | |
65 | virtual void SetCaloCalibPedestal(AliCaloCalibPedestal *caped) { fCaloPed = caped; } | |
ee08edde | 66 | |
8d0210ea | 67 | virtual Float_t GetTimeMin() const { return fTimeMin; } |
68 | virtual Float_t GetTimeMax() const { return fTimeMax; } | |
69 | virtual Float_t GetTimeCut() const { return fTimeCut; } | |
70 | virtual Float_t GetECAClusteringThreshold() const { return fECAClusteringThreshold; } | |
71 | virtual Float_t GetECALocalMaxCut() const { return fECALocMaxCut; } | |
72 | virtual Float_t GetECALogWeight() const { return fECAW0; } | |
73 | virtual Float_t GetMinECut() const { return fMinECut; } | |
74 | ||
9cd23da3 | 75 | virtual void SetTimeMin(Float_t t) { fTimeMin = t; } |
76 | virtual void SetTimeMax(Float_t t) { fTimeMax = t; } | |
77 | virtual void SetTimeCut(Float_t t) { fTimeCut = t; } | |
8d0210ea | 78 | virtual void SetECAClusteringThreshold(Float_t th) { fECAClusteringThreshold = th; } |
79 | virtual void SetMinECut(Float_t mine) { fMinECut = mine; } | |
80 | virtual void SetECALocalMaxCut(Float_t cut) { fECALocMaxCut = cut; } | |
81 | virtual void SetECALogWeight(Float_t w) { fECAW0 = w; } | |
0d0d6b98 | 82 | |
83 | //Unfolding | |
65bec413 | 84 | |
8d0210ea | 85 | virtual void SetUnfolding(Bool_t toUnfold = kTRUE ) { fToUnfold = toUnfold; } |
86 | virtual void SetSSPars (Int_t ipar, Double_t par) { fSSPars[ipar] = par; } | |
87 | virtual void SetPar5 (Int_t ipar, Double_t par) { fPar5 [ipar] = par; } | |
88 | virtual void SetPar6 (Int_t ipar, Double_t par) { fPar6 [ipar] = par; } | |
89 | virtual void InitClusterUnfolding() { | |
71332f0e | 90 | fClusterUnfolding=new AliEMCALUnfolding(fGeom,fECALocMaxCut,fSSPars,fPar5,fPar6); |
91 | fClusterUnfolding->SetThreshold(fMinECut); } | |
ac084be7 | 92 | |
d464daf4 | 93 | //NxN (only used in NxN clusterizer) |
94 | ||
9cd23da3 | 95 | virtual void SetNRowDiff(Int_t ) { ; } |
96 | virtual void SetNColDiff(Int_t ) { ; } | |
97 | virtual void SetEnergyGrad(Bool_t ) { ; } | |
d464daf4 | 98 | |
9cd23da3 | 99 | virtual Int_t GetNRowDiff() const { return -1 ; } |
100 | virtual Int_t GetNColDiff() const { return -1 ; } | |
101 | virtual Bool_t GetEnergyGrad() const { return -1 ; } | |
d464daf4 | 102 | |
ac084be7 | 103 | // add for clusterizing task |
c47157cd | 104 | |
9cd23da3 | 105 | virtual void SetDigitsArr(TClonesArray *arr) { fDigitsArr = arr ; } |
106 | virtual TClonesArray *GetDigits() { if (!fDigitsArr) | |
107 | fDigitsArr = new TClonesArray("AliEMCALDigit",12000); | |
108 | return fDigitsArr ; } | |
109 | virtual const TObjArray *GetRecPoints() const { return fRecPoints ; } | |
110 | void SetInputCalibrated(Bool_t val); | |
111 | void SetJustClusters (Bool_t val); | |
8d0210ea | 112 | |
c828bc97 | 113 | |
839828a6 | 114 | protected: |
483b0559 | 115 | |
0e7c6655 | 116 | virtual void MakeClusters() = 0; |
b1324a01 | 117 | |
8d0210ea | 118 | Bool_t fIsInputCalibrated; // to enable reclusterization from ESD cells |
119 | Bool_t fJustClusters; // false for standard reco | |
120 | TClonesArray *fDigitsArr; // array with EMCAL digits | |
121 | TTree *fTreeR; // tree with output clusters | |
122 | TObjArray *fRecPoints; // array with EMCAL clusters | |
ee08edde | 123 | |
8d0210ea | 124 | AliEMCALGeometry *fGeom; //!pointer to geometry for utilities |
125 | AliEMCALCalibData *fCalibData; //!calibration database if aval | |
126 | AliCaloCalibPedestal *fCaloPed; //!tower status map if aval | |
ee08edde | 127 | |
8d0210ea | 128 | Float_t fADCchannelECA; // width of one ADC channel for EC section (GeV) |
129 | Float_t fADCpedestalECA; // pedestal of ADC for EC section (GeV) | |
130 | Float_t fTimeECA; // calibration parameter for channels time | |
783153ff | 131 | |
8d0210ea | 132 | Float_t fTimeMin; // minimum time of physical signal in a cell/digit |
133 | Float_t fTimeMax; // maximum time of physical signal in a cell/digit | |
134 | Float_t fTimeCut; // maximum time difference between the digits inside EMC cluster | |
ee08edde | 135 | |
8d0210ea | 136 | Bool_t fDefaultInit; //!says if the task was created by defaut ctor (only parameters are initialized) |
137 | Bool_t fToUnfold; // says if unfolding should be performed | |
138 | Int_t fNumberOfECAClusters; // number of clusters found in EC section | |
ee08edde | 139 | |
8d0210ea | 140 | Float_t fECAClusteringThreshold; // minimum energy to seed a EC digit in a cluster |
141 | Float_t fECALocMaxCut; // minimum energy difference to distinguish local maxima in a cluster | |
142 | Float_t fECAW0; // logarithmic weight for the cluster center of gravity calculation | |
143 | Float_t fMinECut; // minimum energy for a digit to be a member of a cluster | |
ee08edde | 144 | |
ac084be7 | 145 | AliEMCALUnfolding *fClusterUnfolding; //!pointer to unfolding object |
146 | Double_t fSSPars[8]; // shower shape parameters | |
147 | Double_t fPar5[3]; // shower shape parameter 5 | |
148 | Double_t fPar6[3]; // shower shape parameter 6 | |
65bec413 | 149 | |
ac084be7 | 150 | private: |
9cd23da3 | 151 | AliEMCALClusterizer( const AliEMCALClusterizer &); |
c47157cd | 152 | AliEMCALClusterizer & operator = (const AliEMCALClusterizer &); |
ee08edde | 153 | |
783153ff | 154 | ClassDef(AliEMCALClusterizer,7) // Clusterization algorithm class |
9cd23da3 | 155 | |
ac084be7 | 156 | }; |
483b0559 | 157 | #endif // AliEMCALCLUSTERIZER_H |