/** * \file inc/CaloLevel1.h * \author Emiliano Mocchiutti */ #ifndef CaloLevel1_h #define CaloLevel1_h // // default position used only in CaloStrip for the moment // // // old param // //#define CTX 121.1 //#define CTY 122.6 //#define CTZ -263.1 // // new param // //#define CTX 121.2 //#define CTY 122.9 //#define CTZ -263.1 // // new param using em showers (E. Taddei paramters) // #define CTX 120.6 #define CTY 122.3 #define CTZ -263.1 // // Mechanical positions (used with option --use-standard-alig) // #define MECHCTX 120.5 #define MECHCTY 121.5 #define MECHCTZ -261.81 // // just for testing purpose // //#define MECHCTX 0. //#define MECHCTY 0. //#define MECHCTZ -263.1 // #include #include #include #include #include #include #include #include #include // extern "C" int millim_(Int_t *, Float_t *); struct shift { Float_t shift; }; // /** * \brief Calorimeter level1 class * * This class contains level1 calorimeter variables * **/ class CaloLevel1 : public TObject { private: public: // Int_t istrip; ///< total number of strip hit // // Number of strip with energy > emip and their value coded with view plane and strip number: // view x[y] plane PP strip SS with energy mmmm.iip = +[-] ( PP*10^6 + SS*10^4 + mmmm.iip ) // TArrayI estrip; ///< MIP values for each strip with energy > emin coded with view plane and strip number. NOTICE: precision is limited to the 5 most significative ciphers // CaloLevel1* GetCaloLevel1(){return this;}; ///< returns pointer to this object // // Float_t GetEstrip(Int_t view, Int_t plane, Int_t strip); ///< returns saved MIP value for the indicated strip. Float_t DecodeEstrip(Int_t entry, Int_t &view, Int_t &plane, Int_t &strip); ///< returns saved MIP value for the entry number "entry" of the TArrayI. Float_t DecodeEstrip(Int_t entry, Int_t &view, Int_t &plane, Int_t &strip, Bool_t &saturated); ///< returns saved MIP value for the entry number "entry" of the TArrayI. Float_t qtotpl(Int_t nplane); ///< Returns energy released on plane nplane (where 0<= nplane <= 43, 0 = 1Y, 1 = 1X, 2 = 2Y, 3 = 2X, etc. etc.). Float_t qtotpl(Int_t view, Int_t plane); ///< Returns energy released on view "view" (0 = X, 1 = Y) and plane "plane" ( 0 <= plane <= 21 ). Float_t qtotpl(Int_t nplane, Bool_t &saturation); ///< Returns energy released on plane nplane (where 0<= nplane <= 43, 0 = 1Y, 1 = 1X, 2 = 2Y, 3 = 2X, etc. etc.). Float_t qtotpl(Int_t view, Int_t plane, Bool_t &saturation); ///< Returns energy released on view "view" (0 = X, 1 = Y) and plane "plane" ( 0 <= plane <= 21 ). // void Clear(Option_t *t=""); // Float_t GetXalig(){printf(" Obsolete! Use CaloStrip class instead\n");return CTX;}; ///< return X alignement paramenter Float_t GetYalig(){printf(" Obsolete! Use CaloStrip class instead\n");return CTY;}; ///< return Y alignement paramenter Float_t GetZalig(){printf(" Obsolete! Use CaloStrip class instead\n");return CTZ;}; ///< return Z alignement paramenter // CaloLevel1(); ///< Constructor. // ClassDef(CaloLevel1,1); }; /** * \brief Calorimeter strip class, needed to perform operation on a strip level, for example to retrieve the position of the strips or to retrieve the closest strip to a cerain position * */ class CaloStrip : public TObject { private: CaloLevel1 *c1; //< pointer to level1 object Float_t fE; //< energy in mip of the strip Float_t fX; //< X position in cm of the strip Float_t fY; //< Y position in cm of the strip Float_t fZ; //< Z position in cm of the strip Int_t fView; ///< view [1-2] Int_t fPlane; ///< plane [1-22] Int_t fStrip; ///< strip [1-96] Bool_t ismech; ///< true = using mechanical alignement, false using experimental alignement parameters static Float_t UXal; ///< used X alignement parameter static Float_t UYal; ///< used Y alignement parameter static Float_t UZal; ///< used Z alignement parameter static Bool_t paramload; // public: // // METHODS // CaloStrip(); ///< Default Constructor. // CaloStrip(Bool_t usemechanicalalignement); ///< Default Constructor. // CaloStrip(CaloLevel1 *c1); ///< Constructor. // CaloStrip(CaloLevel1 *c1, Bool_t usemechanicalalignement); ///< Constructor. // Float_t GetE(){return fE;}; ///< Get energy in MIP for setted strip // Float_t GetX(){return fX;}; ///< Get X strip position Float_t GetY(){return fY;}; ///< Get Y strip position Float_t GetZ(){return fZ;}; /// Get Z strip position // Float_t GetXalig(){ return UXal;}; ///< return X alignement paramenter Float_t GetYalig(){ return UYal;}; ///< return Y alignement paramenter Float_t GetZalig(){ return UZal;}; ///< return Z alignement paramenter // Int_t GetView(){return (fView-1);}; ///< Get strip view [0-1] Int_t GetPlane(){return (fPlane-1);}; ///< Get strip plane [0-21] Int_t GetStrip(){return (fStrip-1);}; ///< Get strip number [0-95] // void Set(Int_t view, Int_t plane, Int_t strip); ///< Set strip giving view [0-1], plane [0-22] and number [0-95] // void Set(Float_t X, Float_t Y, Float_t Z); ///< Set strip giving position in PAMELA ref sys [cm] // void UseMechanicalAlig(){ ismech = true; UXal = MECHCTX; UYal = MECHCTY; UZal = MECHCTZ;}; ///< Tells CaloStrip to use mechanical alignement parameters void UseStandardAlig(); ///< Tells CaloStrip to use default parameters it will find querying the DB. If connection fails uses parameters hard-coded in this file void SetAlig(Float_t XALIG, Float_t YALIG, Float_t ZALIG){ ismech = false; UXal = XALIG; UYal = YALIG; UZal = ZALIG;};///< User defined alignement parameters Bool_t IsMechanicalAlig(){return ismech;}; ///< True is using mechanical alignement parameters, false otherwise // void Clear(Option_t *t=""); ///< clear variables // CaloStrip* GetCaloStrip(){return this;}; ///< returns pointer to this object // ClassDef(CaloStrip,2); // }; #endif