class AliCaloRawStreamV3;
class AliCaloAltroMapping;
class AliRawReader;
+class AliCaloRawAnalyzer;
class AliCaloCalibSignal : public TObject {
AliCaloCalibSignal(kDetType detectorType = kPhos); //ctor
virtual ~AliCaloCalibSignal(); //dtor
- // copy ctor, and '=' operator, are not fully tested/debugged yet
- AliCaloCalibSignal(const AliCaloCalibSignal &sig); // copy ctor
- AliCaloCalibSignal& operator = (const AliCaloCalibSignal &source); //!
+private:
+ //Just declare them, avoid compilation warning
+ AliCaloCalibSignal(const AliCaloCalibSignal & /*sig*/); // copy ctor
+ AliCaloCalibSignal& operator = (const AliCaloCalibSignal &/*source*/); // assing operator
+public:
// Event processing methods:
Bool_t ProcessEvent(AliRawReader *rawReader);
Bool_t ProcessEvent(AliCaloRawStreamV3 *in, UInt_t Timestamp); // added header for time info
- Bool_t CheckFractionAboveAmp(const int *AmpVal, int resultArray[]); // check fraction of signals to check for LED events
+ Bool_t CheckFractionAboveAmp(const int *AmpVal, int resultArray[]) const; // check fraction of signals to check for LED events
+ Bool_t CheckLEDRefAboveAmp(const int *AmpVal, int resultArray[]) const; // check if LED Ref is also above cut
// Mapping handling
AliCaloAltroMapping **GetAltroMapping() const { return fMapping; };
void SetAltroMapping(AliCaloAltroMapping **mapp) { fMapping = mapp; };
+ // Fitter / Analyzer
+ Int_t GetFittingAlgorithm() const {return fFittingAlgorithm; }
+ void SetFittingAlgorithm(Int_t val) ;
+ AliCaloRawAnalyzer *GetRawAnalyzer() const { return fRawAnalyzer;}
+
// Parameter/cut handling
void SetParametersFromFile(const char *parameterFile);
void WriteParametersToFile(const char *parameterFile);
int GetNLowGain(int towId) const { return fNLowGain[towId];}; //!
// also for LED reference
- int GetNRef(const int imod, const int istripMod, const int igain) //!
+ int GetNRef(const int imod, const int istripMod, const int igain) const //!
{ int refId = GetRefNum(imod, istripMod, igain); return fNRef[refId];}; //!
int GetNRef(int refId) const { return fNRef[refId];}; //!
double GetReqFractionAboveAmpCutVal() const { return fReqFractionAboveAmpCutVal; }; //!
void SetReqFractionAboveAmp(bool b) { fReqFractionAboveAmp = b; } //!
bool GetReqFractionAboveAmp() const { return fReqFractionAboveAmp; }; //!
+ // also for LED Reference/Mon channels
+ void SetAmpCutLEDRef(double d) { fAmpCutLEDRef = d; } //!
+ double GetAmpCutLEDRef() const { return fAmpCutLEDRef; }; //!
+ void SetReqLEDRefAboveAmpCutVal(bool b) { fReqLEDRefAboveAmpCutVal = b; } //!
+ bool GetReqLEDRefAboveAmpCutVal() const { return fReqLEDRefAboveAmpCutVal; }; //!
// We may select to get averaged info
void SetUseAverage(bool b) { fUseAverage = b; } //!
void SetSecInAverage(int secInAverage) {fSecInAverage = secInAverage;}; // length of the interval that should be used for the average calculation (determines number of bins in TProfile)
int GetSecInAverage() const {return fSecInAverage;}; //!
+ void SetDownscale(int i) {fDownscale = i;}; //!
+ int GetDownscale() const {return fDownscale;}; //!
+
// Info on time since start of run
double GetHour() const { return fHour; }; // time info for current event
double GetCurrentHour() const { return fHour; }; // time info for current event (same as GetHour(), just more explicitly named)
int fModules; //The number of modules
TString fCaloString; // id for which detector type we have
AliCaloAltroMapping **fMapping; //! Altro Mapping object
+ Int_t fFittingAlgorithm; // select the fitting algorithm
+ AliCaloRawAnalyzer *fRawAnalyzer; //! e.g. for sample selection for fits
int fRunNumber; //The run number. Needs to be set by the user.
int fStartTime; // Time of first event
double fReqFractionAboveAmpCutVal; // required fraction that should be above cut
bool fReqFractionAboveAmp; // flag to select if we should do some event selection based on amplitudes
+ double fAmpCutLEDRef; // amplitude cut value for LED reference
+ bool fReqLEDRefAboveAmpCutVal; // flag to select if we should require that signal is also seen in LED Reference/Monitoring channel
+
double fHour; // fraction of hour since beginning of run, for amp vs. time graphs, for current event
double fLatestHour; // largest fraction of hour since beginning of run, for amp vs. time graphs
bool fUseAverage; // flag to average graph points into over a time interval
int fSecInAverage; // time interval for the graph averaging
+ int fDownscale; // to select 1 out every N (fDownscale) events
+
// status counters
int fNEvents; // # events processed
int fNAcceptedEvents; // # events accepted
int fNLowGain[fgkMaxTowers]; // same, for low gain
int fNRef[fgkMaxRefs * 2]; // same, for LED refs; *2 for both gains
- ClassDef(AliCaloCalibSignal, 5) // don't forget to change version if you change class member list..
+ ClassDef(AliCaloCalibSignal, 8) // don't forget to change version if you change class member list..
};