Moving the classes that belong to the following libraries: STEERBase, ESD, CDB, AOD...

[u/mrichter/AliRoot.git] / STEER / STEER / AliLHCData.h

#ifndef ALILHCDATA_H\r
#define ALILHCDATA_H\r
\r
/********************************************************************************\r
*                                                                               *\r
*   AliLHCData: summary of the LHC related information from LHC DIP.            *\r
*   Created from the TMap provided by the AliLHCReader with optional beginning  *\r
*                                                                               *\r
*   The data are (wrapped in the AliLHCDipValT):                                *\r
*   made of TimeStamp (double) and array of values                              *\r
*                                                                               *\r
*   Multiple entries for each type of data are possible. To obtaine number of   *\r
*   records (with distinct timestamp) for give type od records use:             *\r
*   int GetNBunchConfigMeasured(int beam) (with beam=0,1) etc.                  *\r
*                                                                               *\r
*   To get i-th entry, use brec= AliLHCDipValI* GetBunchConfigMeasured(bm,i);   *\r
*   Note: exact type of templated AliLHCDipValT pointer depends on the record   *\r
*   type, concult getters to know it.                                           *\r
*                                                                               *\r
*   Then, once the pointer is obtained, details can be accessed:                *\r
*   int nBunches = brec->GetSize();                                             *\r
*   for (int i=0;i<nBunches;i++) printf("Bunch#%d: %d\n",i,(*brec)[i]);         *\r
*                                                                               *\r
*   ATTENTION: Bunch RFBucked is NEGATIVE for bunches interacting at IR2        *\r
*                                                                               *\r
*                                                                               *\r
*                                                                               *\r
*   Author: ruben.shahoyan@cern.ch                                              *\r
*                                                                               *\r
********************************************************************************/\r
\r
#include "AliLHCDipValT.h"\r
#include "TObject.h"\r
class TObjArray;\r
//class AliLHCDipValT;\r
\r
class AliDCSArray;\r
class TString;\r
class TMap;\r
class AliLHCReader;\r
\r
\r
class AliLHCData : public TObject\r
{\r
 public:\r
  enum          {kStart,kNStor};\r
  enum BeamID_t {kBeam1,kBeam2};\r
  enum Proj_t   {kX,kY};\r
  enum Side_t   {kLeft,kRight};\r
  enum Collim_t {kTCTVB4L2, kTCTVB4R2, kTCLIA4R2, kNCollimators};\r
  enum ColJaw_t {kGapDn,kGapUp,kLeftDn,kLeftUp,kRightDn,kRightUp,kNJaws};\r
  enum          {kMaxBSlots = 3564, kOffsBeam1=346, kOffsBeam2 = 3019};\r
  enum          {kMarginSOR = 60*60*24*30, // use margin of 30 days for SOR, when looking for the 1st record\r
		 kMarginEOR = 60*15};      // use margin of 15 min for EOR, when looking for the last record\r
  //\r
  enum {kIntTot,kIntTotAv,kIntBunchAv,\r
	kLumAcqMode,kLumTot,kLumTotErr,kLumBunch,kLumBunchErr,kLumCrossAng,kLumCrossAngErr,\r
	kBunchConf,kFillNum,kBunchLgtNB,kBunchLgt,kBunchLgtFillB,\r
	kRCInjSch,kRCBeta,kRCCrossAng,kRCVang,\r
	kBeamSzAcqMode,kBeamSzSigH,kBeamSzSigV,kBeamSzEmittH,kBeamSzEmittV,kBeamSzSigHErr,kBeamSzSigVErr,\r
	kCollPos};\r
  //\r
  //le\r
 public:\r
  //\r
 AliLHCData() : fTMin(0),fTMax(1e10),fFillNumber(0),fData(0),fFile2Process(0),fMap2Process(0) {Clear();}\r
  AliLHCData(const TMap*   dcsMap,  double tmin=0, double tmax=1.e10);\r
  AliLHCData(const Char_t* dcsFile, double tmin=0, double tmax=1.e10);\r
  virtual ~AliLHCData() {}\r
  //\r
  Bool_t                FillData(const TMap*   dcsMap,  double tmin=0, double tmax=1.e20);\r
  Bool_t                FillData(const Char_t* dcsFile, double tmin=0, double tmax=1.e20);\r
  Double_t              GetTMin()                                    const {return fTMin;}\r
  Double_t              GetTMax()                                    const {return fTMax;}\r
  Int_t                 GetFillNumber()                              const {return fFillNumber;}\r
  void                  SetFillNumber(Int_t fill)                          {fFillNumber = fill;}\r
  void                  SetTMin(Double_t t)                                {fTMin = t<0?0:(t>1e10?1e10:t);}\r
  void                  SetTMax(Double_t t)                                {fTMax = t<0?0:(t>1e10?1e10:t);}\r
  //\r
  virtual void          Print(const Option_t *opt="")                const;\r
  //\r
  Int_t GetNBunchConfigMeasured(int bm)           const {return GoodPairID(bm)?fBunchConfMeas[bm][kNStor]:-1;}\r
  Int_t GetNBunchConfigDeclared(int bm)           const {return GoodPairID(bm)?fBunchConfDecl[bm][kNStor]:-1;}\r
  Int_t GetNBunchLengths(int bm)                  const {return GoodPairID(bm)?fBunchLengths[bm][kNStor]:-1;}\r
  Int_t GetNTotalIntensity(int bm)                const {return GoodPairID(bm)?fIntensTotal[bm][kNStor]:-1;}\r
  Int_t GetNTotalIntensityAv(int bm)              const {return GoodPairID(bm)?fIntensTotalAv[bm][kNStor]:-1;}\r
  Int_t GetNIntensityPerBunch(int bm)             const {return GoodPairID(bm)?fIntensPerBunch[bm][kNStor]:-1;}\r
  Int_t GetNEmittanceH(int bm)                    const {return GoodPairID(bm)?fEmittanceH[bm][kNStor]:-1;}\r
  Int_t GetNEmittanceV(int bm)                    const {return GoodPairID(bm)?fEmittanceV[bm][kNStor]:-1;}\r
  Int_t GetNBeamSigmaH(int bm)                    const {return GoodPairID(bm)?fBeamSigmaH[bm][kNStor]:-1;}\r
  Int_t GetNBeamSigmaV(int bm)                    const {return GoodPairID(bm)?fBeamSigmaV[bm][kNStor]:-1;}\r
  //\r
  Int_t GetNLuminosityTotal(int lr)               const {return GoodPairID(lr)?fLuminTotal[lr][kNStor]:-1;}\r
  Int_t GetNLuminosityPerBunch(int lr)            const {return GoodPairID(lr)?fLuminPerBC[lr][kNStor]:-1;}\r
  Int_t GetNLuminosityAcqMode(int lr)             const {return GoodPairID(lr)?fLuminAcqMode[lr][kNStor]:-1;}\r
  Int_t GetNCrossingAngle(int lr)                 const {return GoodPairID(lr)?fCrossAngle[lr][kNStor]:-1;}\r
  //\r
  Int_t GetNInjectionScheme()                     const {return fRCInjScheme[kNStor];}\r
  Int_t GetNRCBetaStar()                          const {return fRCBeta[kNStor];}\r
  Int_t GetNRCAngleH()                            const {return fRCAngH[kNStor];}\r
  Int_t GetNRCAngleV()                            const {return fRCAngV[kNStor];}\r
  //\r
  Int_t GetNCollimatorJawPos(int coll,int jaw)    const;\r
  //\r
  AliLHCDipValI* GetBunchConfigMeasured(int bm, int i=0)  const;\r
  AliLHCDipValF* GetBunchLengths(int bm, int i=0)         const;\r
  AliLHCDipValI* GetBunchConfigDeclared(int bm, int i=0)  const;\r
  AliLHCDipValF* GetTotalIntensity(int bm, int i=0)       const;\r
  AliLHCDipValF* GetTotalIntensityAv(int bm, int i=0)     const;\r
  AliLHCDipValF* GetIntensityPerBunch(int bm, int i=0)    const;\r
  AliLHCDipValF* GetEmittanceH(int bm, int i=0)           const;\r
  AliLHCDipValF* GetEmittanceV(int bm, int i=0)           const;\r
  AliLHCDipValF* GetBeamSigmaH(int bm, int i=0)           const;\r
  AliLHCDipValF* GetBeamSigmaV(int bm, int i=0)           const;\r
  AliLHCDipValF* GetLuminosityTotal(int lr, int i=0)      const;\r
  AliLHCDipValF* GetLuminosityPerBunch(int lr, int i=0)   const;\r
  AliLHCDipValI* GetLuminosityAcqMode(int lr, int i=0)    const;\r
  AliLHCDipValF* GetCrossAngle(int lr, int i=0)           const;\r
  AliLHCDipValC* GetInjectionScheme(int i=0)              const;\r
  AliLHCDipValF* GetRCBetaStar(int i=0)                   const;\r
  AliLHCDipValF* GetRCAngleH(int i=0)                     const; \r
  AliLHCDipValF* GetRCAngleV(int i=0)                     const; \r
  AliLHCDipValF* GetCollimJawPos(int coll, int jaw, int i=0) const;\r
  //\r
  void           FlagInteractingBunches(const Int_t beam1[2],const Int_t beam2[2]);\r
  TObject*       FindRecValidFor(int start,int nrec, double tstamp) const;\r
  AliLHCDipValI* GetBunchConfigMeasured(int beam,double tstamp)  const;\r
  AliLHCDipValI* GetBunchConfigDeclared(int beam,double tstamp)  const;\r
  Int_t          GetNInteractingBunchesMeasured(int i=0)         const;\r
  Int_t          GetNInteractingBunchesDeclared(int i=0)         const;\r
  Int_t          IsPilotPresent(int i=0)                         const;\r
  //\r
  // return array with beginning [0] and number of records for corresponding info (in the fData)\r
  const Int_t* GetOffsBunchConfigMeasured(int bm)         const {return GoodPairID(bm)?fBunchConfMeas[bm]:0;}\r
  const Int_t* GetOffsBunchConfigDeclared(int bm)         const {return GoodPairID(bm)?fBunchConfDecl[bm]:0;}\r
  const Int_t* GetOffsBunchLengths(int bm)                const {return GoodPairID(bm)?fBunchLengths[bm]:0;}\r
  const Int_t* GetOffsTotalIntensity(int bm)              const {return GoodPairID(bm)?fIntensTotal[bm]:0;}\r
  const Int_t* GetOffsTotalIntensityAv(int bm)            const {return GoodPairID(bm)?fIntensTotalAv[bm]:0;}\r
  const Int_t* GetOffsIntensityPerBunch(int bm)           const {return GoodPairID(bm)?fIntensPerBunch[bm]:0;}\r
  const Int_t* GetOffsEmittanceH(int bm)                  const {return GoodPairID(bm)?fEmittanceH[bm]:0;}\r
  const Int_t* GetOffsEmittanceV(int bm)                  const {return GoodPairID(bm)?fEmittanceV[bm]:0;}\r
  const Int_t* GetOffsBeamSigmaH(int bm)                  const {return GoodPairID(bm)?fBeamSigmaH[bm]:0;}\r
  const Int_t* GetOffsBeamSigmaV(int bm)                  const {return GoodPairID(bm)?fBeamSigmaV[bm]:0;}\r
  //\r
  const Int_t* GetOffsLuminosityTotal(int lr)             const {return GoodPairID(lr)?fLuminTotal[lr]:0;}\r
  const Int_t* GetOffsLuminosityPerBunch(int lr)          const {return GoodPairID(lr)?fLuminPerBC[lr]:0;}\r
  const Int_t* GetOffsLuminosityAcqMode(int lr)           const {return GoodPairID(lr)?fLuminAcqMode[lr]:0;}\r
  const Int_t* GetOffsCrossingAngle(int lr)               const {return GoodPairID(lr)?fCrossAngle[lr]:0;}\r
  //\r
  const Int_t* GetOffsInjectionScheme()                   const {return fRCInjScheme;}\r
  const Int_t* GetOffsRCBetaStar()                        const {return fRCBeta;}\r
  const Int_t* GetOffsRCAngleH()                          const {return fRCAngH;}\r
  const Int_t* GetOffsRCAngleV()                          const {return fRCAngV;}\r
  //\r
  const Int_t* GetOffsCollimatorJawPos(int coll,int jaw)  const;\r
  //\r
  const TObjArray&  GetData()                             const {return fData;}\r
  //\r
  // analysis methods\r
  Int_t GetMeanIntensity(int beamID, Double_t &colliding, Double_t &noncolliding, const TObjArray* bcmasks=0) const;\r
  static Int_t GetBCId(int bucket, int beamID)                  {return (TMath::Abs(bucket)/10 + (beamID==0 ? kOffsBeam1:kOffsBeam2))%kMaxBSlots;}\r
  //\r
 protected:\r
  //\r
  Bool_t                FillData(double tmin=0, double tmax=1.e20);\r
  virtual void          Clear(const Option_t *opt="");\r
  void                  PrintAux(Bool_t full,const Int_t refs[2],const Option_t *opt="") const;\r
  TObjArray*            GetDCSEntry(const char* key,int &entry,int &last,double tmin,double tmax) const;\r
  Int_t                 FillScalarRecord(  int refs[2], const char* rec, const char* recErr=0);\r
  Int_t                 FillBunchConfig(   int refs[2], const char* rec);\r
  Int_t                 FillStringRecord(  int refs[2], const char* rec);\r
  Int_t                 FillAcqMode(       int refs[2], const char* rec);\r
  Int_t                 FillBunchInfo(     int refs[2], const char* rec,int ibm, Bool_t inRealSlots);\r
  Int_t                 FillBCLuminosities(int refs[2], const char* rec, const char* recErr, Int_t useBeam);\r
  //\r
  Int_t                 ExtractInt(AliDCSArray* dcsArray,Int_t el)    const;\r
  Double_t              ExtractDouble(AliDCSArray* dcsArray,Int_t el) const;\r
  TString&              ExtractString(AliDCSArray* dcsArray)          const;\r
 AliLHCData(const AliLHCData& src) : TObject(src),fTMin(0),fTMax(0),fFillNumber(0),fData(0),fFile2Process(0),fMap2Process(0) { /*dummy*/ }\r
  AliLHCData& operator=(const AliLHCData& ) { /*dummy*/ return *this;}\r
  Int_t                 TimeDifference(double v1,double v2,double tol=0.9) const;\r
  Bool_t                IzZero(double val, double tol=1e-16)         const {return TMath::Abs(val)<tol;}\r
  Bool_t                GoodPairID(int beam)                         const;\r
  //\r
 protected:\r
  //\r
  Double_t        fTMin;                              // selection timeMin\r
  Double_t        fTMax;                              // selection timeMax\r
  Int_t           fFillNumber;                        // fill number           : kFillNum\r
  //\r
  //---------------- Last index gives: 0 - beginning of the records in fData, 1 - number of records\r
  //\r
  //              infrormation from RunControl\r
  Int_t           fRCInjScheme[2];                    // active injection scheme                       : String |kRCInjScheme\r
  Int_t           fRCBeta[2];                         // target beta                                   : Float  |kRCBeta\r
  Int_t           fRCAngH[2];                         // horisontal angle                              : Float  |kRCCrossAng\r
  Int_t           fRCAngV[2];                         // vertical angle                                : Float  |kRCVang\r
  Int_t           fBunchConfDecl[2][2];               // declared beam configuration                   : Float  |kBunchConf                \r
  //\r
  //              measured information\r
  Int_t           fBunchConfMeas[2][2];               // measured beam configuration                   : Int    |kBunchLgtFillB\r
  Int_t           fBunchLengths[2][2];                // measured beam lenghts                         : Float  |kBunchLgt\r
  Int_t           fIntensTotal[2][2];                 // total beam intensities                        : Float  |kIntTot\r
  Int_t           fIntensTotalAv[2][2];               // total beam intensities from bunch averages    : Float  |kIntTotAv\r
  Int_t           fIntensPerBunch[2][2];              // bunch-by-bunch intensities                    : Float  |kIntBunchAv\r
  //\r
  Int_t           fCrossAngle[2][2];                  // crossing angle   at IP2 and its error         : Float  |kLimCrossAng, kLumCrossAngErr\r
  Int_t           fEmittanceH[2][2];                  // beam H emittances                             : Float  |kBeamSzEmittH\r
  Int_t           fEmittanceV[2][2];                  // beam V emittances                             : Float  |kBeamSzEmittV\r
  Int_t           fBeamSigmaH[2][2];                  // beam H sigma and error                        : Float  |kBeamSzSigH,kBeamSzSigHErr\r
  Int_t           fBeamSigmaV[2][2];                  // beam V sigma and error                        : Float  |kBeamSzSigV,kBeamSzSigVErr\r
  //\r
  Int_t           fLuminTotal[2][2];                  // total luminosity at IP2 and its error         : Float  |kLumTot, kLumTotErr\r
  Int_t           fLuminPerBC[2][2];                  // luminosity at IP2 for each BC and its error   : Float  |kLumBunch,kLumBunchErr\r
  Int_t           fLuminAcqMode[2][2];                // luminosity acquisition mode                   : Int    | kLumAcqMode\r
  //\r
  Int_t           fCollimators[kNCollimators][kNJaws][2];// collimator jaws positions                  : Float  |kCollPos\r
  //\r
  TObjArray       fData;                              // single storage for various records\r
  //\r
  static const Char_t *fgkDCSNames[];                 // beam related DCS names to extract\r
  static const Char_t *fgkDCSColNames[];              // collimators to extract\r
  static const Char_t *fgkDCSColJaws[];               // names of collimator pieces\r
  //\r
 private:\r
  // non-persistent objects used at the filling time\r
  const Char_t*   fFile2Process;                      //! name of DCS file\r
  const TMap*     fMap2Process;                       //! DCS map to process \r
\r
  ClassDef(AliLHCData,1)\r
};\r
\r
\r
//_____________________________________________________________________________\r
inline Int_t AliLHCData::GetNCollimatorJawPos(int coll,int jaw) const {// get n records\r
  return (coll>=0&&coll<kNCollimators&&jaw>=0&&jaw<kNJaws)? fCollimators[coll][jaw][kNStor]:0;\r
}\r
\r
inline const Int_t* AliLHCData::GetOffsCollimatorJawPos(int coll,int jaw)  const { // offset array\r
  return (coll>=0&&coll<kNCollimators&&jaw>=0&&jaw<kNJaws)? fCollimators[coll][jaw]:0;\r
}\r
\r
inline AliLHCDipValI* AliLHCData::GetBunchConfigMeasured(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fBunchConfMeas[bm][kNStor]) ? (AliLHCDipValI*)fData[fBunchConfMeas[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetBunchLengths(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fBunchLengths[bm][kNStor]) ? (AliLHCDipValF*)fData[fBunchLengths[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValI* AliLHCData::GetBunchConfigDeclared(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fBunchConfDecl[bm][kNStor]) ? (AliLHCDipValI*)fData[fBunchConfDecl[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetTotalIntensity(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fIntensTotal[bm][kNStor]) ? (AliLHCDipValF*)fData[fIntensTotal[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetTotalIntensityAv(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fIntensTotalAv[bm][kNStor]) ? (AliLHCDipValF*)fData[fIntensTotalAv[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetIntensityPerBunch(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fIntensPerBunch[bm][kNStor]) ? (AliLHCDipValF*)fData[fIntensPerBunch[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetEmittanceH(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fEmittanceH[bm][kNStor]) ? (AliLHCDipValF*)fData[fEmittanceH[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetEmittanceV(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fEmittanceV[bm][kNStor]) ? (AliLHCDipValF*)fData[fEmittanceV[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetBeamSigmaH(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fBeamSigmaH[bm][kNStor]) ? (AliLHCDipValF*)fData[fBeamSigmaH[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetBeamSigmaV(int bm, int i) const { // get record\r
  return (GoodPairID(bm) && i>=0 && i<fBeamSigmaV[bm][kNStor]) ? (AliLHCDipValF*)fData[fBeamSigmaV[bm][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetLuminosityTotal(int lr, int i) const { // get record\r
  return (GoodPairID(lr) && i>=0 && i<fLuminTotal[lr][kNStor]) ? (AliLHCDipValF*)fData[fLuminTotal[lr][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetLuminosityPerBunch(int lr, int i) const { // get record\r
  return (GoodPairID(lr) && i>=0 && i<fLuminPerBC[lr][kNStor]) ? (AliLHCDipValF*)fData[fLuminPerBC[lr][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValI* AliLHCData::GetLuminosityAcqMode(int lr, int i) const { // get record\r
  return (GoodPairID(lr) && i>=0 && i<fLuminAcqMode[lr][kNStor]) ? (AliLHCDipValI*)fData[fLuminAcqMode[lr][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetCrossAngle(int lr, int i) const { // get record\r
  return (GoodPairID(lr) && i>=0 && i<fCrossAngle[lr][kNStor]) ? (AliLHCDipValF*)fData[fCrossAngle[lr][kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValC* AliLHCData::GetInjectionScheme(int i) const { // get record\r
  return (i>=0 && i<fRCInjScheme[kNStor]) ? (AliLHCDipValC*)fData[fRCInjScheme[kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetRCBetaStar(int i) const { // get record\r
  return (i>=0 && i<fRCBeta[kNStor]) ? (AliLHCDipValF*)fData[fRCBeta[kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetRCAngleH(int i) const { // get record\r
  return (i>=0 && i<fRCAngH[kNStor]) ? (AliLHCDipValF*)fData[fRCAngH[kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetRCAngleV(int i) const { // get record\r
  return (i>=0 && i<fRCAngV[kNStor]) ? (AliLHCDipValF*)fData[fRCAngV[kStart]+i]:0;\r
}\r
\r
inline AliLHCDipValF* AliLHCData::GetCollimJawPos(int coll, int jaw, int i) const { // get record\r
  return (coll>=0 && coll<kNCollimators && jaw>=0 && jaw<kNJaws && \r
	  i>=0 && i<fCollimators[coll][jaw][kNStor]) ? (AliLHCDipValF*)fData[fCollimators[coll][jaw][kStart]+i]:0;\r
}\r
\r
\r
#endif\r