4 /********************************************************************************
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6 * AliLHCData: summary of the LHC related information from LHC DIP. *
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7 * Created from the TMap provided by the AliLHCReader with optional beginning *
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9 * The data are (wrapped in the AliLHCDipValT): *
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10 * made of TimeStamp (double) and array of values *
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12 * Multiple entries for each type of data are possible. To obtaine number of *
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13 * records (with distinct timestamp) for give type od records use: *
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14 * int GetNBunchConfigMeasured(int beam) (with beam=0,1) etc. *
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16 * To get i-th entry, use brec= AliLHCDipValI* GetBunchConfigMeasured(bm,i); *
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17 * Note: exact type of templated AliLHCDipValT pointer depends on the record *
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18 * type, concult getters to know it. *
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20 * Then, once the pointer is obtained, details can be accessed: *
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21 * int nBunches = brec->GetSize(); *
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22 * for (int i=0;i<nBunches;i++) printf("Bunch#%d: %d\n",i,(*brec)[i]); *
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24 * ATTENTION: Bunch RFBucked is NEGATIVE for bunches interacting at IR2 *
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28 * Author: ruben.shahoyan@cern.ch *
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30 ********************************************************************************/
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32 #include "AliLHCDipValT.h"
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33 #include "TObject.h"
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35 //class AliLHCDipValT;
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43 class AliLHCData : public TObject
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46 enum {kStart,kNStor};
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47 enum BeamID_t {kBeam1,kBeam2};
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48 enum Proj_t {kX,kY};
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49 enum Side_t {kLeft,kRight};
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50 enum Collim_t {kTCTVB4L2, kTCTVB4R2, kTCLIA4R2, kNCollimators};
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51 enum ColJaw_t {kGapDn,kGapUp,kLeftDn,kLeftUp,kRightDn,kRightUp,kNJaws};
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52 enum {kMaxBSlots = 3564, kOffsBeam1=346, kOffsBeam2 = 3019};
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53 enum {kMarginSOR = 60*60*24*30, // use margin of 30 days for SOR, when looking for the 1st record
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54 kMarginEOR = 60*15}; // use margin of 15 min for EOR, when looking for the last record
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56 enum {kIntTot,kIntTotAv,kIntBunchAv,
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57 kLumAcqMode,kLumTot,kLumTotErr,kLumBunch,kLumBunchErr,kLumCrossAng,kLumCrossAngErr,
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58 kBunchConf,kFillNum,kBunchLgtNB,kBunchLgt,kBunchLgtFillB,
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59 kRCInjSch,kRCBeta,kRCCrossAng,kRCVang,
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60 kBeamSzAcqMode,kBeamSzSigH,kBeamSzSigV,kBeamSzEmittH,kBeamSzEmittV,kBeamSzSigHErr,kBeamSzSigVErr,
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61 kCollPos,kLumiAlice,kBckgAlice
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67 AliLHCData() : fTMin(0),fTMax(1e10),fFillNumber(0),fData(0),fkFile2Process(0),fkMap2Process(0) {Clear();}
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68 AliLHCData(const TMap* dcsMap, double tmin=0, double tmax=1.e10);
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69 AliLHCData(const Char_t* dcsFile, double tmin=0, double tmax=1.e10);
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70 virtual ~AliLHCData() {}
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72 Bool_t FillData(const TMap* dcsMap, double tmin=0, double tmax=1.e20);
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73 Bool_t FillData(const Char_t* dcsFile, double tmin=0, double tmax=1.e20);
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74 Double_t GetTMin() const {return fTMin;}
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75 Double_t GetTMax() const {return fTMax;}
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76 Int_t GetFillNumber() const {return fFillNumber;}
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77 void SetFillNumber(Int_t fill) {fFillNumber = fill;}
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78 void SetTMin(Double_t t) {fTMin = t<0?0:(t>1e10?1e10:t);}
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79 void SetTMax(Double_t t) {fTMax = t<0?0:(t>1e10?1e10:t);}
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81 virtual void Print(const Option_t *opt="") const;
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82 TGraph* ExportGraph(Int_t *coord, Int_t elID=0) const;
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84 Int_t GetNBunchConfigMeasured(int bm) const {return GoodPairID(bm)?fBunchConfMeas[bm][kNStor]:-1;}
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85 Int_t GetNBunchConfigDeclared(int bm) const {return GoodPairID(bm)?fBunchConfDecl[bm][kNStor]:-1;}
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86 Int_t GetNBunchLengths(int bm) const {return GoodPairID(bm)?fBunchLengths[bm][kNStor]:-1;}
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87 Int_t GetNTotalIntensity(int bm) const {return GoodPairID(bm)?fIntensTotal[bm][kNStor]:-1;}
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88 Int_t GetNTotalIntensityAv(int bm) const {return GoodPairID(bm)?fIntensTotalAv[bm][kNStor]:-1;}
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89 Int_t GetNIntensityPerBunch(int bm) const {return GoodPairID(bm)?fIntensPerBunch[bm][kNStor]:-1;}
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90 Int_t GetNEmittanceH(int bm) const {return GoodPairID(bm)?fEmittanceH[bm][kNStor]:-1;}
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91 Int_t GetNEmittanceV(int bm) const {return GoodPairID(bm)?fEmittanceV[bm][kNStor]:-1;}
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92 Int_t GetNBeamSigmaH(int bm) const {return GoodPairID(bm)?fBeamSigmaH[bm][kNStor]:-1;}
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93 Int_t GetNBeamSigmaV(int bm) const {return GoodPairID(bm)?fBeamSigmaV[bm][kNStor]:-1;}
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95 Int_t GetNLuminosityTotal(int lr) const {return GoodPairID(lr)?fLuminTotal[lr][kNStor]:-1;}
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96 Int_t GetNLuminosityPerBunch(int lr) const {return GoodPairID(lr)?fLuminPerBC[lr][kNStor]:-1;}
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97 Int_t GetNLuminosityAcqMode(int lr) const {return GoodPairID(lr)?fLuminAcqMode[lr][kNStor]:-1;}
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98 Int_t GetNCrossingAngle(int lr) const {return GoodPairID(lr)?fCrossAngle[lr][kNStor]:-1;}
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100 Int_t GetNInjectionScheme() const {return fRCInjScheme[kNStor];}
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101 Int_t GetNRCBetaStar() const {return fRCBeta[kNStor];}
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102 Int_t GetNRCAngleH() const {return fRCAngH[kNStor];}
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103 Int_t GetNRCAngleV() const {return fRCAngV[kNStor];}
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105 Int_t GetNLumiAlice() const {return fLumiAlice[kNStor];}
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106 Int_t GetNBckgAlice() const {return fBckgAlice[kNStor];}
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108 Int_t GetNCollimatorJawPos(int coll,int jaw) const;
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110 AliLHCDipValI* GetBunchConfigMeasured(int bm, int i=0) const;
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111 AliLHCDipValF* GetBunchLengths(int bm, int i=0) const;
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112 AliLHCDipValI* GetBunchConfigDeclared(int bm, int i=0) const;
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113 AliLHCDipValF* GetTotalIntensity(int bm, int i=0) const;
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114 AliLHCDipValF* GetTotalIntensityAv(int bm, int i=0) const;
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115 AliLHCDipValF* GetIntensityPerBunch(int bm, int i=0) const;
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116 AliLHCDipValF* GetEmittanceH(int bm, int i=0) const;
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117 AliLHCDipValF* GetEmittanceV(int bm, int i=0) const;
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118 AliLHCDipValF* GetBeamSigmaH(int bm, int i=0) const;
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119 AliLHCDipValF* GetBeamSigmaV(int bm, int i=0) const;
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120 AliLHCDipValF* GetLuminosityTotal(int lr, int i=0) const;
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121 AliLHCDipValF* GetLuminosityPerBunch(int lr, int i=0) const;
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122 AliLHCDipValI* GetLuminosityAcqMode(int lr, int i=0) const;
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123 AliLHCDipValF* GetCrossAngle(int lr, int i=0) const;
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124 AliLHCDipValC* GetInjectionScheme(int i=0) const;
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125 AliLHCDipValF* GetRCBetaStar(int i=0) const;
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126 AliLHCDipValF* GetRCAngleH(int i=0) const;
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127 AliLHCDipValF* GetRCAngleV(int i=0) const;
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128 AliLHCDipValF* GetCollimJawPos(int coll, int jaw, int i=0) const;
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130 AliLHCDipValF* GetLumiAliceRecord(int i=0) const;
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131 AliLHCDipValF* GetBckgAliceRecord(int i=0) const;
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133 Float_t GetLumiAlice(Double_t tstamp) const;
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134 Float_t GetBckgAlice(Double_t tstamp) const;
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136 Float_t GetLumiInstAlice(Double_t tstamp) const;
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137 Float_t GetBckgInstAlice(Double_t tstamp) const;
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139 void FlagInteractingBunches(const Int_t beam1[2],const Int_t beam2[2]);
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140 TObject* FindRecValidFor(int start,int nrec, double tstamp) const;
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141 Int_t FindEntryValidFor(int start,int nrec, double tstamp) const;
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142 AliLHCDipValI* GetBunchConfigMeasured(int beam,double tstamp) const;
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143 AliLHCDipValI* GetBunchConfigDeclared(int beam,double tstamp) const;
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144 Int_t GetNInteractingBunchesMeasured(int i=0) const;
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145 Int_t GetNInteractingBunchesDeclared(int i=0) const;
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146 Int_t IsPilotPresent(int i=0) const;
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148 // return array with beginning [0] and number of records for corresponding info (in the fData)
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149 const Int_t* GetOffsBunchConfigMeasured(int bm) const {return GoodPairID(bm)?fBunchConfMeas[bm]:0;}
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150 const Int_t* GetOffsBunchConfigDeclared(int bm) const {return GoodPairID(bm)?fBunchConfDecl[bm]:0;}
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151 const Int_t* GetOffsBunchLengths(int bm) const {return GoodPairID(bm)?fBunchLengths[bm]:0;}
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152 const Int_t* GetOffsTotalIntensity(int bm) const {return GoodPairID(bm)?fIntensTotal[bm]:0;}
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153 const Int_t* GetOffsTotalIntensityAv(int bm) const {return GoodPairID(bm)?fIntensTotalAv[bm]:0;}
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154 const Int_t* GetOffsIntensityPerBunch(int bm) const {return GoodPairID(bm)?fIntensPerBunch[bm]:0;}
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155 const Int_t* GetOffsEmittanceH(int bm) const {return GoodPairID(bm)?fEmittanceH[bm]:0;}
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156 const Int_t* GetOffsEmittanceV(int bm) const {return GoodPairID(bm)?fEmittanceV[bm]:0;}
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157 const Int_t* GetOffsBeamSigmaH(int bm) const {return GoodPairID(bm)?fBeamSigmaH[bm]:0;}
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158 const Int_t* GetOffsBeamSigmaV(int bm) const {return GoodPairID(bm)?fBeamSigmaV[bm]:0;}
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160 const Int_t* GetOffsLuminosityTotal(int lr) const {return GoodPairID(lr)?fLuminTotal[lr]:0;}
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161 const Int_t* GetOffsLuminosityPerBunch(int lr) const {return GoodPairID(lr)?fLuminPerBC[lr]:0;}
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162 const Int_t* GetOffsLuminosityAcqMode(int lr) const {return GoodPairID(lr)?fLuminAcqMode[lr]:0;}
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163 const Int_t* GetOffsCrossingAngle(int lr) const {return GoodPairID(lr)?fCrossAngle[lr]:0;}
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165 const Int_t* GetOffsInjectionScheme() const {return fRCInjScheme;}
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166 const Int_t* GetOffsRCBetaStar() const {return fRCBeta;}
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167 const Int_t* GetOffsRCAngleH() const {return fRCAngH;}
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168 const Int_t* GetOffsRCAngleV() const {return fRCAngV;}
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169 const Int_t* GetOffsLumiAlice() const {return fLumiAlice;}
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170 const Int_t* GetOffsBckgAlice() const {return fBckgAlice;}
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172 const Int_t* GetOffsCollimatorJawPos(int coll,int jaw) const;
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174 const TObjArray& GetData() const {return fData;}
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176 // analysis methods
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177 Int_t GetMeanIntensity(int beamID, Double_t &colliding, Double_t &noncolliding, const TObjArray* bcmasks=0) const;
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178 static Int_t GetBCId(int bucket, int beamID) {return (TMath::Abs(bucket)/10 + (beamID==0 ? kOffsBeam1:kOffsBeam2))%kMaxBSlots;}
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180 // for retrofitting, these methods has to be public
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181 void FillLumiAlice(Int_t nrec, Int_t* time, Double_t* val);
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182 void FillBckgAlice(Int_t nrec, Int_t* time, Double_t* val);
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187 Bool_t FillData(double tmin=0, double tmax=1.e20);
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188 virtual void Clear(const Option_t *opt="");
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189 void PrintAux(Bool_t full,const Int_t refs[2],const Option_t *opt="") const;
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190 TObjArray* GetDCSEntry(const char* key,int &entry,int &last,double tmin,double tmax) const;
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191 Int_t FillScalarRecord( int refs[2], const char* rec, const char* recErr=0, Double_t maxAbsVal=1.e30);
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192 Int_t FillBunchConfig( int refs[2], const char* rec);
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193 Int_t FillStringRecord( int refs[2], const char* rec);
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194 Int_t FillAcqMode( int refs[2], const char* rec);
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195 Int_t FillBunchInfo( int refs[2], const char* rec,int ibm, Bool_t inRealSlots, Double_t maxAbsVal=1.e30);
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196 Int_t FillBCLuminosities(int refs[2], const char* rec, const char* recErr, Int_t useBeam, Double_t maxAbsVal=1.e30);
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198 Int_t ExtractInt(AliDCSArray* dcsArray,Int_t el) const;
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199 Double_t ExtractDouble(AliDCSArray* dcsArray,Int_t el) const;
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200 TString& ExtractString(AliDCSArray* dcsArray) const;
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201 AliLHCData(const AliLHCData& src) : TObject(src),fTMin(0),fTMax(0),fFillNumber(0),fData(0),fkFile2Process(0),fkMap2Process(0) { /*dummy*/ }
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202 AliLHCData& operator=(const AliLHCData& ) { /*dummy*/ return *this;}
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203 Int_t TimeDifference(double v1,double v2,double tol=0.9) const;
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204 Bool_t IzZero(double val, double tol=1e-16) const {return TMath::Abs(val)<tol;}
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205 Bool_t GoodPairID(int beam) const;
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209 Double_t fTMin; // selection timeMin
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210 Double_t fTMax; // selection timeMax
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211 Int_t fFillNumber; // fill number : kFillNum
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213 //---------------- Last index gives: 0 - beginning of the records in fData, 1 - number of records
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215 // infrormation from RunControl
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216 Int_t fRCInjScheme[2]; // active injection scheme : String |kRCInjScheme
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217 Int_t fRCBeta[2]; // target beta : Float |kRCBeta
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218 Int_t fRCAngH[2]; // horisontal angle : Float |kRCCrossAng
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219 Int_t fRCAngV[2]; // vertical angle : Float |kRCVang
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220 Int_t fBunchConfDecl[2][2]; // declared beam configuration : Float |kBunchConf
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222 // measured information
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223 Int_t fBunchConfMeas[2][2]; // measured beam configuration : Int |kBunchLgtFillB
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224 Int_t fBunchLengths[2][2]; // measured beam lenghts : Float |kBunchLgt
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225 Int_t fIntensTotal[2][2]; // total beam intensities : Float |kIntTot
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226 Int_t fIntensTotalAv[2][2]; // total beam intensities from bunch averages : Float |kIntTotAv
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227 Int_t fIntensPerBunch[2][2]; // bunch-by-bunch intensities : Float |kIntBunchAv
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229 Int_t fCrossAngle[2][2]; // crossing angle at IP2 and its error : Float |kLimCrossAng, kLumCrossAngErr
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230 Int_t fEmittanceH[2][2]; // beam H emittances : Float |kBeamSzEmittH
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231 Int_t fEmittanceV[2][2]; // beam V emittances : Float |kBeamSzEmittV
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232 Int_t fBeamSigmaH[2][2]; // beam H sigma and error : Float |kBeamSzSigH,kBeamSzSigHErr
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233 Int_t fBeamSigmaV[2][2]; // beam V sigma and error : Float |kBeamSzSigV,kBeamSzSigVErr
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235 Int_t fLuminTotal[2][2]; // total luminosity at IP2 and its error : Float |kLumTot, kLumTotErr
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236 Int_t fLuminPerBC[2][2]; // luminosity at IP2 for each BC and its error : Float |kLumBunch,kLumBunchErr
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237 Int_t fLuminAcqMode[2][2]; // luminosity acquisition mode : Int |kLumAcqMode
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239 // here we will store the luminosity and the background measured by Alice. We store the value integrated from the start of fill.
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240 // the inst. value can be obtained as its derivative
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241 Int_t fLumiAlice[2]; // luminosity measured by Alice : Float |kLumiAlice
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242 Int_t fBckgAlice[2]; // background measured by Alice : Float |kLumiAlice
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244 Int_t fCollimators[kNCollimators][kNJaws][2];// collimator jaws positions : Float |kCollPos
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246 TObjArray fData; // single storage for various records
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248 static const Char_t *fgkDCSNames[]; // beam related DCS names to extract
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249 static const Char_t *fgkDCSColNames[]; // collimators to extract
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250 static const Char_t *fgkDCSColJaws[]; // names of collimator pieces
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253 // non-persistent objects used at the filling time
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254 const Char_t* fkFile2Process; //! name of DCS file
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255 const TMap* fkMap2Process; //! DCS map to process
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257 ClassDef(AliLHCData,3)
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261 //_____________________________________________________________________________
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262 inline Int_t AliLHCData::GetNCollimatorJawPos(int coll,int jaw) const {// get n records
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263 return (coll>=0&&coll<kNCollimators&&jaw>=0&&jaw<kNJaws)? fCollimators[coll][jaw][kNStor]:0;
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266 inline const Int_t* AliLHCData::GetOffsCollimatorJawPos(int coll,int jaw) const { // offset array
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267 return (coll>=0&&coll<kNCollimators&&jaw>=0&&jaw<kNJaws)? fCollimators[coll][jaw]:0;
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270 inline AliLHCDipValI* AliLHCData::GetBunchConfigMeasured(int bm, int i) const { // get record
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271 return (GoodPairID(bm) && i>=0 && i<fBunchConfMeas[bm][kNStor]) ? (AliLHCDipValI*)fData[fBunchConfMeas[bm][kStart]+i]:0;
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274 inline AliLHCDipValF* AliLHCData::GetBunchLengths(int bm, int i) const { // get record
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275 return (GoodPairID(bm) && i>=0 && i<fBunchLengths[bm][kNStor]) ? (AliLHCDipValF*)fData[fBunchLengths[bm][kStart]+i]:0;
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278 inline AliLHCDipValI* AliLHCData::GetBunchConfigDeclared(int bm, int i) const { // get record
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279 return (GoodPairID(bm) && i>=0 && i<fBunchConfDecl[bm][kNStor]) ? (AliLHCDipValI*)fData[fBunchConfDecl[bm][kStart]+i]:0;
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282 inline AliLHCDipValF* AliLHCData::GetTotalIntensity(int bm, int i) const { // get record
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283 return (GoodPairID(bm) && i>=0 && i<fIntensTotal[bm][kNStor]) ? (AliLHCDipValF*)fData[fIntensTotal[bm][kStart]+i]:0;
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286 inline AliLHCDipValF* AliLHCData::GetTotalIntensityAv(int bm, int i) const { // get record
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287 return (GoodPairID(bm) && i>=0 && i<fIntensTotalAv[bm][kNStor]) ? (AliLHCDipValF*)fData[fIntensTotalAv[bm][kStart]+i]:0;
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290 inline AliLHCDipValF* AliLHCData::GetIntensityPerBunch(int bm, int i) const { // get record
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291 return (GoodPairID(bm) && i>=0 && i<fIntensPerBunch[bm][kNStor]) ? (AliLHCDipValF*)fData[fIntensPerBunch[bm][kStart]+i]:0;
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294 inline AliLHCDipValF* AliLHCData::GetEmittanceH(int bm, int i) const { // get record
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295 return (GoodPairID(bm) && i>=0 && i<fEmittanceH[bm][kNStor]) ? (AliLHCDipValF*)fData[fEmittanceH[bm][kStart]+i]:0;
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298 inline AliLHCDipValF* AliLHCData::GetEmittanceV(int bm, int i) const { // get record
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299 return (GoodPairID(bm) && i>=0 && i<fEmittanceV[bm][kNStor]) ? (AliLHCDipValF*)fData[fEmittanceV[bm][kStart]+i]:0;
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302 inline AliLHCDipValF* AliLHCData::GetBeamSigmaH(int bm, int i) const { // get record
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303 return (GoodPairID(bm) && i>=0 && i<fBeamSigmaH[bm][kNStor]) ? (AliLHCDipValF*)fData[fBeamSigmaH[bm][kStart]+i]:0;
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306 inline AliLHCDipValF* AliLHCData::GetBeamSigmaV(int bm, int i) const { // get record
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307 return (GoodPairID(bm) && i>=0 && i<fBeamSigmaV[bm][kNStor]) ? (AliLHCDipValF*)fData[fBeamSigmaV[bm][kStart]+i]:0;
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310 inline AliLHCDipValF* AliLHCData::GetLuminosityTotal(int lr, int i) const { // get record
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311 return (GoodPairID(lr) && i>=0 && i<fLuminTotal[lr][kNStor]) ? (AliLHCDipValF*)fData[fLuminTotal[lr][kStart]+i]:0;
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314 inline AliLHCDipValF* AliLHCData::GetLuminosityPerBunch(int lr, int i) const { // get record
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315 return (GoodPairID(lr) && i>=0 && i<fLuminPerBC[lr][kNStor]) ? (AliLHCDipValF*)fData[fLuminPerBC[lr][kStart]+i]:0;
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318 inline AliLHCDipValI* AliLHCData::GetLuminosityAcqMode(int lr, int i) const { // get record
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319 return (GoodPairID(lr) && i>=0 && i<fLuminAcqMode[lr][kNStor]) ? (AliLHCDipValI*)fData[fLuminAcqMode[lr][kStart]+i]:0;
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322 inline AliLHCDipValF* AliLHCData::GetCrossAngle(int lr, int i) const { // get record
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323 return (GoodPairID(lr) && i>=0 && i<fCrossAngle[lr][kNStor]) ? (AliLHCDipValF*)fData[fCrossAngle[lr][kStart]+i]:0;
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326 inline AliLHCDipValC* AliLHCData::GetInjectionScheme(int i) const { // get record
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327 return (i>=0 && i<fRCInjScheme[kNStor]) ? (AliLHCDipValC*)fData[fRCInjScheme[kStart]+i]:0;
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330 inline AliLHCDipValF* AliLHCData::GetRCBetaStar(int i) const { // get record
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331 return (i>=0 && i<fRCBeta[kNStor]) ? (AliLHCDipValF*)fData[fRCBeta[kStart]+i]:0;
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334 inline AliLHCDipValF* AliLHCData::GetRCAngleH(int i) const { // get record
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335 return (i>=0 && i<fRCAngH[kNStor]) ? (AliLHCDipValF*)fData[fRCAngH[kStart]+i]:0;
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338 inline AliLHCDipValF* AliLHCData::GetRCAngleV(int i) const { // get record
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339 return (i>=0 && i<fRCAngV[kNStor]) ? (AliLHCDipValF*)fData[fRCAngV[kStart]+i]:0;
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342 inline AliLHCDipValF* AliLHCData::GetCollimJawPos(int coll, int jaw, int i) const { // get record
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343 return (coll>=0 && coll<kNCollimators && jaw>=0 && jaw<kNJaws &&
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344 i>=0 && i<fCollimators[coll][jaw][kNStor]) ? (AliLHCDipValF*)fData[fCollimators[coll][jaw][kStart]+i]:0;
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347 inline AliLHCDipValF* AliLHCData::GetLumiAliceRecord(int i) const { // get record on integrated luminosity
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348 return (i>=0 && i<fLumiAlice[kNStor]) ? (AliLHCDipValF*)fData[fLumiAlice[kStart]+i]:0;
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351 inline AliLHCDipValF* AliLHCData::GetBckgAliceRecord(int i) const { // get record on integrated background
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352 return (i>=0 && i<fBckgAlice[kNStor]) ? (AliLHCDipValF*)fData[fBckgAlice[kStart]+i]:0;
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355 inline Float_t AliLHCData::GetLumiAlice(Double_t tStamp) const { // get closest in time value on integrated luminosity
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356 int idx = FindEntryValidFor(fLumiAlice[kStart],fLumiAlice[kNStor],tStamp);
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357 return idx<0 ? -1 : ((AliLHCDipValF*)fData[fLumiAlice[kStart]+idx])->GetValue();
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360 inline Float_t AliLHCData::GetBckgAlice(Double_t tStamp) const { // get closest in time value on integrated bckg
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361 int idx = FindEntryValidFor(fBckgAlice[kStart],fBckgAlice[kNStor],tStamp);
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362 return idx<0 ? -1 : ((AliLHCDipValF*)fData[fBckgAlice[kStart]+idx])->GetValue();
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365 inline Int_t AliLHCData::FindEntryValidFor(int start,int nrec, double tstamp) const
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367 // find index of record within this limits valid for given tstamp (i.e. the last one before or equal to tstamp)
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369 for (idx=0;idx<nrec;idx++) {
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370 if (TimeDifference(tstamp,((AliLHCDipValI*)fData[start+idx])->GetTimeStamp())<=0) break;
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372 return (idx<nrec) ? idx : nrec-1;
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git://git.uio.no / u / mrichter / AliRoot.git / blob