#ifndef MARS_MBadPixelsPix #define MARS_MBadPixelsPix #ifndef MARS_MParContainer #include "MParContainer.h" #endif #ifndef ROOT_TArrayI #include #endif class MBadPixelsPix : public MParContainer { private: TArrayI fInfo; public: MBadPixelsPix(const char* name=NULL, const char* title=NULL); enum UnsuitableType_t { kUnsuitableRun = BIT(1), kUnsuitableEvt = BIT(2), kUnsuitable = kUnsuitableRun|kUnsuitableEvt, kUnreliableRun = BIT(3), kUnreliableEvt = BIT(4), kUnreliable = kUnreliableRun|kUnreliableEvt }; static const Int_t fgRunMask; // All types which are not event wise determined // All types are initialized to normal behaviour enum UncalibratedType_t { kHiGainNotFitted = BIT(1), kLoGainNotFitted = BIT(2), kRelTimeNotFitted = BIT(3), kHiGainOscillating = BIT(4), kLoGainOscillating = BIT(5), kRelTimeOscillating = BIT(6), kLoGainSaturation = BIT(7), kChargeIsPedestal = BIT(8), kChargeErrNotValid = BIT(9), kChargeRelErrNotValid = BIT(10), kChargeSigmaNotValid = BIT(11), kMeanTimeInFirstBin = BIT(12), kMeanTimeInLast2Bins = BIT(13), kDeviatingNumPhes = BIT(14), kDeviatingNumPhots = BIT(15), kDeviatingFFactor = BIT(16), kDeviatingTimeResolution = BIT(17), kConversionHiLoNotValid = BIT(18), kHiGainOverFlow = BIT(19), kLoGainOverFlow = BIT(20), kHiLoNotFitted = BIT(21), kHiLoOscillating = BIT(22) }; // This is just a start.. enum HardwareType_t { kHVNotNominal = BIT(1) }; void Reset(); void Clear(Option_t *o=""); void Copy(TObject &object) const { static_cast(object).fInfo = fInfo; } // Setter void SetUnsuitable (UnsuitableType_t typ) { fInfo[0] |= typ; } void SetUncalibrated(UncalibratedType_t typ) { fInfo[1] |= typ; } void SetHardware (HardwareType_t typ) { fInfo[2] |= typ; } // Getter Bool_t IsUnsuitable (UnsuitableType_t typ) const { return fInfo[0]&typ; } Bool_t IsUncalibrated(UncalibratedType_t typ) const { return fInfo[1]&typ; } Bool_t IsHardwareBad (HardwareType_t typ) const { return fInfo[2]&typ; } Bool_t IsUnsuitable() const { return fInfo[0]&kUnsuitable; } Bool_t IsUnreliable() const { return fInfo[0]&kUnreliable; } Bool_t IsOK() const { return fInfo[0]==0; } Bool_t IsBad() const { return fInfo[0]!=0; } Bool_t IsLoGainBad() const { return IsUnsuitable (kUnsuitableRun ) || IsUncalibrated(kLoGainSaturation ) || IsUncalibrated(kConversionHiLoNotValid) || IsUncalibrated(kLoGainOscillating ) ; } Bool_t IsHiGainBad() const { return IsUnsuitable (kUnsuitableRun ) || IsUncalibrated(kHiGainOscillating ) ; } Int_t GetUnsuitableCalLevel() const { if (!IsUnsuitable()) return 0; if (IsUncalibrated( kChargeIsPedestal )) return 1; if (IsUncalibrated( kChargeRelErrNotValid)) return 2; if (IsUncalibrated( kLoGainSaturation )) return 3; if (IsUncalibrated( kMeanTimeInFirstBin )) return 4; if (IsUncalibrated( kMeanTimeInLast2Bins )) return 5; if (IsUncalibrated( kDeviatingNumPhots )) return 6; if (IsUncalibrated( kHiGainOverFlow )) return 7; if (IsUncalibrated( kLoGainOverFlow )) return 8; return 9; } Int_t GetUnreliableCalLevel() const { if (!IsUnreliable() || IsUnsuitable()) return 0; if (IsUncalibrated( kChargeSigmaNotValid )) return 1; if (IsUncalibrated( kDeviatingNumPhes )) return 2; if (IsUncalibrated( kHiGainNotFitted )) return 3; if (IsUncalibrated( kLoGainNotFitted )) return 4; if (IsUncalibrated( kRelTimeNotFitted )) return 5; if (IsUncalibrated( kHiGainOscillating )) return 6; if (IsUncalibrated( kLoGainOscillating )) return 7; if (IsUncalibrated( kRelTimeOscillating )) return 8; if (IsUncalibrated( kDeviatingFFactor )) return 9; return 10; } void Merge(const MBadPixelsPix &pix); const TArrayI &GetInfo() const { return fInfo; } ClassDef(MBadPixelsPix, 1) // Storage Container for bad pixel information of a single pixel }; #endif