9 |
#include <TObjArray.h> |
#include <TObjArray.h> |
10 |
#include <TClonesArray.h> |
#include <TClonesArray.h> |
11 |
#include <TRefArray.h> |
#include <TRefArray.h> |
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#include <TRef.h> |
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#include <TrkStruct.h> |
#include <TrkParams.h> |
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#include <TrkLevel1.h> |
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17 |
// z-coordinate of track state-vector reference-plane |
// z-coordinate of track state-vector reference-plane |
18 |
#define ZINI 23.5 |
#define ZINI 23.5 ///< z-coordinate of track state-vector reference-plane. |
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// upper and lower (mechanical) z-coordinate of the tracker |
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//#define ZTRKUP 22.29 |
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//#define ZTRKDW -22.22 |
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19 |
// (mechanical) z-coordinate of the tracker planes |
// (mechanical) z-coordinate of the tracker planes |
20 |
#define ZTRK6 -22.23 |
#define ZTRK6 -22.23 //-22.22 //Aprile 2014... trovata differenza con mech_pos.dat |
21 |
#define ZTRK5 -13.32 |
#define ZTRK5 -13.32 //-13.31 // ...speriamo bene... no comment |
22 |
#define ZTRK4 -4.42 |
#define ZTRK4 -4.42//-4.41 |
23 |
#define ZTRK3 4.48 |
#define ZTRK3 4.48//4.49 |
24 |
#define ZTRK2 13.38 |
#define ZTRK2 13.38//13.39 |
25 |
#define ZTRK1 22.28 |
#define ZTRK1 22.28//22.29 |
26 |
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// magnet cavity dimensions |
27 |
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#define ZMAGNHIGH 21.83 |
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#define ZMAGNLOW -21.83 |
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#define XMAGNHIGH 8.07 |
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#define XMAGNLOW -8.07 |
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#define YMAGNHIGH 6.57 |
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#define YMAGNLOW -6.57 |
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// tof planes |
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#define ZS11 53.74 |
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#define ZS12 53.04 |
36 |
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#define ZS21 23.94 |
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#define ZS22 23.44 |
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#define ZS31 -23.49 |
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#define ZS32 -24.34 |
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// (mechanical) x/y-coordinates of magnet cavity |
// (mechanical) x/y-coordinates of magnet cavity |
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#define XTRKL -8.1 |
/* #define XTRKL -8.1 */ |
43 |
#define XTRKR 8.1 |
/* #define XTRKR 8.1 */ |
44 |
#define YTRKL -6.6 |
/* #define YTRKL -6.6 */ |
45 |
#define YTRKR 6.6 |
/* #define YTRKR 6.6 */ |
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47 |
/** |
/** |
48 |
* \brief Class to describe, by points, a particle trajectory in the apparatus. |
* \brief Class to describe, by points, a particle trajectory in the apparatus. |
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public: |
public: |
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59 |
int npoint; ///< number of evaluated points along the trajectory |
int npoint; ///< number of evaluated points along the trajectory |
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float* x; ///< x coordinates |
float* x; //[npoint] |
61 |
float* y; ///< y coordinates |
float* y; //[npoint] |
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float* z; ///< z coordinates |
float* z; //[npoint] |
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float* thx; ///< x projected angle |
float* thx; //[npoint] |
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float* thy; ///< y projected angle |
float* thy; //[npoint] |
65 |
float* tl; ///< track length |
float* tl; //[npoint] |
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Trajectory(); |
Trajectory(); |
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Trajectory(int n); |
Trajectory(int n); |
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Trajectory(int n, float* pz); |
Trajectory(int n, float* pz); |
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~Trajectory(){Delete();} |
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void Dump(); |
void Dump(); |
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void Delete(); |
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int DoTrack(float* al, float zini); |
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int DoTrack(float* al){ return DoTrack(al,23.5); } |
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int DoTrack2(float* al, float zini); |
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int DoTrack2(float* al){ return DoTrack2(al,23.5); } |
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float GetLength(){float l=0; for(int i=0; i<npoint;i++)l=l+tl[i]; return l;}; |
float GetLength(){float l=0; for(int i=0; i<npoint;i++)l=l+tl[i]; return l;} |
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float GetLength(int,int); |
float GetLength(int,int); |
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83 |
ClassDef(Trajectory,1); |
ClassDef(Trajectory,3); |
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85 |
}; |
}; |
86 |
/** |
/** |
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* A track is defined by the measured coordinates associated to it, the |
* A track is defined by the measured coordinates associated to it, the |
90 |
* track status vector, plus other quantities. |
* track status vector, plus other quantities. |
91 |
* A track may have an "image", due to the ambiguity in the y view. |
* A track may have an "image", due to the ambiguity in the y view. |
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* |
93 |
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* Cluster flags: xgood[6], ygood[6] |
94 |
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* |
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* xgood/ygood = +/- 0lsccccccc |
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* ccccccc ID (1-7483647) of the included cluster |
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* s sensor number (1,2 - increasing y) |
98 |
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* l ladder number (1,2,3 - increasing x) |
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* +/- does-not/does include bad strips |
100 |
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* |
101 |
*/ |
*/ |
102 |
// ================================================================== |
// ================================================================== |
103 |
class TrkTrack : public TObject { |
class TrkTrack : public TObject { |
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private: |
private: |
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int seqno; ///<stored track sequential number |
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int image; ///<sequential number of track-image |
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107 |
public: |
public: |
108 |
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109 |
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int seqno; ///<stored track sequential number |
110 |
float al[5]; ///<TRACK STATE VECTOR |
int image; ///<sequential number of track-image |
111 |
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112 |
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/*! @brief Track state vector. |
113 |
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* |
114 |
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* This is the track state vector on reference plane defined by #ZINI. |
115 |
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* |
116 |
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* al[0]: X coordinate [cm] |
117 |
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* al[1]: Y coordinate [cm] |
118 |
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* al[2]: sin theta (altitude; theta = 0 is normal incidence) |
119 |
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* al[3]: phi (azimuth; phi = 0 is negative X axis) |
120 |
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* al[4]: deflection (with sign) [1/GV] |
121 |
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* |
122 |
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*/ |
123 |
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float al[5]; |
124 |
float coval[5][5]; ///<covariance matrix |
float coval[5][5]; ///<covariance matrix |
125 |
int xgood[6]; ///<mask of included x planes |
int xgood[6]; ///<cluster id for x-view (0 = view not included in the fit) |
126 |
int ygood[6]; ///<mask of included y planes |
int ygood[6]; ///<cluster id for y-view (0 = view not included in the fit) |
127 |
float xm[6]; ///<measured x coordinates |
float xm[6]; ///<measured x coordinates |
128 |
float ym[6]; ///<measured y coordinates |
float ym[6]; ///<measured y coordinates |
129 |
float zm[6]; ///<measured z coordinates |
float zm[6]; ///<measured z coordinates |
130 |
float resx[6]; ///<spatial resolution on X view |
float resx[6]; ///<spatial resolution on X view |
131 |
float resy[6]; ///<spatial resolution on y view |
float resy[6]; ///<spatial resolution on y view |
132 |
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float tailx[6]; ///<spatial resolution tail on X view |
133 |
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float taily[6]; ///<spatial resolution tail on y view |
134 |
float chi2; ///<chi2 |
float chi2; ///<chi2 |
135 |
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int nstep; ///<n.step |
136 |
float xv[6]; ///<calculated x coordinates |
float xv[6]; ///<calculated x coordinates |
137 |
float yv[6]; ///<calculated y coordinates |
float yv[6]; ///<calculated y coordinates |
138 |
float zv[6]; ///<calculated z coordinates |
float zv[6]; ///<calculated z coordinates |
139 |
float axv[6]; ///<calculated angles (deg) on x view |
float axv[6]; ///<calculated angles (deg) on x view |
140 |
float ayv[6]; ///<calculated angles (deg) on y view |
float ayv[6]; ///<calculated angles (deg) on y view |
141 |
float dedx_x[6]; ///<signal in MIP (scaled to 300 micrometer) |
float dedx_x[6]; ///<dE/dx in MIP (<0 if saturated) |
142 |
float dedx_y[6]; ///<signal in MIP (scaled to 300 micrometer) |
float dedx_y[6]; ///<dE/dx in MIP (<0 if saturated) |
143 |
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int multmaxx[6]; ///<cluster multiplicity and strip of maximum on x view |
144 |
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int multmaxy[6]; ///<cluster multiplicity and strip of maximum on y view |
145 |
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float seedx[6]; ///< seed of the cluster x |
146 |
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float seedy[6]; ///< seed of the cluster y |
147 |
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float xpu[6]; ///< x coordinate in pitch units |
148 |
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float ypu[6]; ///< y coordinate in pitch units |
149 |
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150 |
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float xGF[14]; ///<calculated x coordinates on GF reference planes |
151 |
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float yGF[14]; ///<calculated y coordinates on GF reference planes |
152 |
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153 |
TrkTrack(); |
TrkTrack(); |
154 |
TrkTrack(const TrkTrack&); |
TrkTrack(const TrkTrack&); |
155 |
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156 |
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~TrkTrack(){ Delete(); } |
157 |
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158 |
void Dump(); |
void Dump(); |
159 |
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void Clear(); |
160 |
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void Clear(Option_t *option){Clear();} |
161 |
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void Delete(); |
162 |
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void Copy(TrkTrack&); |
163 |
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// void Set(); |
164 |
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165 |
Int_t GetSeqNo(){return seqno;} ///< Returns the track sequential number |
Int_t GetSeqNo(){return seqno;} ///< Returns the track sequential number |
166 |
Int_t GetImageSeqNo(){return image;} ///< Returns the track image sequential number |
Int_t GetImageSeqNo(){return image;} ///< Returns the track image sequential number |
167 |
Bool_t HasImage(){return !(image==-1);} ///< Returns true if the track has an image |
Bool_t HasImage(){return !(image==-1);} ///< Returns true if the track has an image |
168 |
int DoTrack(Trajectory* t); ///< Evaluates the trajectory in the apparatus. |
int DoTrack(Trajectory* t); ///< Evaluates the trajectory in the apparatus. |
169 |
int DoTrack2(Trajectory* t); ///< Evaluates the trajectory in the apparatus. |
int DoTrack2(Trajectory* t); ///< Evaluates the trajectory in the apparatus. |
170 |
float BdL(){return 0;}; ///< Evaluates the integral of B*dL along the track. |
float BdL(){return 0;} ///< Evaluates the integral of B*dL along the track. |
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Int_t GetNX(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=xgood[i]; return n;}; |
Int_t GetNX(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)XGood(i); return n;} |
172 |
Int_t GetNY(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=ygood[i]; return n;}; |
Int_t GetNY(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)YGood(i); return n;} |
173 |
Int_t GetNtot(){return GetNX()+GetNY();}; |
Int_t GetNXY(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)YGood(i)*XGood(i); return n;} |
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Int_t GetNtot(){return GetNX()+GetNY();} |
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Int_t GetNhit() ; |
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Float_t GetRigidity(); |
Float_t GetRigidity(); |
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Float_t GetDeflection(); |
Float_t GetDeflection(); |
178 |
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Bool_t IsSaturated(int,int); |
179 |
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Bool_t IsSaturated(int); |
180 |
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Bool_t IsSaturated(); |
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Bool_t IsBad(int,int); |
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Float_t GetDEDX(); |
Float_t GetDEDX(); |
183 |
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Float_t GetDEDX(int ip); |
184 |
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Float_t GetDEDX(int ip,int iv); |
185 |
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Int_t GetLeverArmXY(); |
186 |
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Int_t GetLeverArmX(); |
187 |
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Int_t GetLeverArmY(); |
188 |
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Float_t GetChi2X(); |
189 |
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Float_t GetChi2Y(); |
190 |
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Float_t GetLnLX(); |
191 |
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Float_t GetLnLY(); |
192 |
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TrkTrack* GetTrkTrack(){return this;}; |
Float_t GetEffectiveAngle(int ip, int iv); |
194 |
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195 |
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void SetMeasure(double *xmeas, double *ymeas, double *zmeas); |
196 |
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void SetResolution(double *rx, double *ry); |
197 |
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void SetTail(double *tx, double *ty, double factor); |
198 |
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void SetStudentParam(int flag); |
199 |
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void SetGood(int *xg, int *yg); |
200 |
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void LoadField(TString s); |
201 |
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void Fit(double pfixed, int& fail, int iprint, int froml1); |
202 |
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void Fit(double pfixed, int& fail, int iprint){ Fit(pfixed,fail,iprint,0); } |
203 |
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void FitReset(); |
204 |
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void SetTrackingMode(int trackmode); |
205 |
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void SetPrecisionFactor(double fact); |
206 |
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void SetStepMin(int istepmin); |
207 |
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void SetDeltaB(int id, double db); |
208 |
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209 |
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Bool_t IsInsideCavity(float); |
210 |
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Bool_t IsInsideCavity(){ return IsInsideCavity(0.); } |
211 |
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Bool_t IsInsideAcceptance(float); |
212 |
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Bool_t IsInsideAcceptance(){ return IsInsideAcceptance(0.); } |
213 |
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Bool_t IsInsideGFSurface(const char*,float); |
214 |
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Bool_t IsInsideGFSurface(const char* surf){ return IsInsideGFSurface(surf,0.); } |
215 |
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216 |
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Bool_t EvaluateClusterPositions(); |
217 |
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218 |
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void FillMiniStruct(cMini2track&); |
219 |
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void SetFromMiniStruct(cMini2track*); |
220 |
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void FillMiniStruct(){ extern cMini2track track_; FillMiniStruct(track_); }; |
221 |
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void SetFromMiniStruct(){extern cMini2track track_; SetFromMiniStruct(&track_);}; |
222 |
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223 |
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Int_t GetClusterX_ID(int ip); |
224 |
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Int_t GetClusterY_ID(int ip); |
225 |
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Int_t GetLadder(int ip); |
226 |
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Int_t GetSensor(int ip); |
227 |
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Bool_t XGood(int ip){ return GetClusterX_ID(ip)!=-1; } |
228 |
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Bool_t YGood(int ip){ return GetClusterY_ID(ip)!=-1; } |
229 |
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void ResetXGood(int ip){ xgood[ip]=0; } |
230 |
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void ResetYGood(int ip){ ygood[ip]=0; } |
231 |
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/* void SetXGood(int ip, int clid, int is); */ |
232 |
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/* void SetYGood(int ip, int clid, int is); */ |
233 |
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void SetXGood(int ip, int clid, int il, int is, bool bad); |
234 |
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void SetYGood(int ip, int clid, int il, int is, bool bad); |
235 |
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void SetXGood(int ip, int clid, int il, int is){ SetXGood(ip,clid,il,is,false); } |
236 |
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void SetYGood(int ip, int clid, int il, int is){ SetYGood(ip,clid,il,is,false); } |
237 |
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238 |
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239 |
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Bool_t BadClusterX(int ip){ return IsBad(ip,0); } |
240 |
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Bool_t BadClusterY(int ip){ return IsBad(ip,1); } |
241 |
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242 |
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Bool_t SaturatedClusterX(int ip){ return IsSaturated(ip,0); } |
243 |
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Bool_t SaturatedClusterY(int ip){ return IsSaturated(ip,1); } |
244 |
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245 |
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Int_t GetClusterX_Multiplicity(int ip){ return (Int_t)(multmaxx[ip]/10000); } |
246 |
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Int_t GetClusterY_Multiplicity(int ip){ return (Int_t)(multmaxy[ip]/10000); } |
247 |
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Int_t GetClusterX_MaxStrip(int ip){ return (Int_t)(multmaxx[ip]%10000); } |
248 |
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Int_t GetClusterY_MaxStrip(int ip){ return (Int_t)(multmaxy[ip]%10000); } |
249 |
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Float_t GetClusterX_Seed(int ip){ return seedx[ip]; } |
250 |
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Float_t GetClusterY_Seed(int ip){ return seedy[ip]; } |
251 |
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/* Float_t GetClusterX_oordinatePU(int ip); */ |
252 |
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/* Float_t GetClusterY_CoordinatePU(int ip); */ |
253 |
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254 |
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Float_t GetYav(); |
255 |
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Float_t GetXav(); |
256 |
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Float_t GetZav(); |
257 |
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258 |
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Int_t GetNColumns(); |
259 |
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260 |
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Float_t GetDEDX_max(int ip, int iv); |
261 |
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Float_t GetDEDX_max(int iv){ return GetDEDX_max(-1,iv); } |
262 |
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Float_t GetDEDX_max(){ return GetDEDX_max(-1,-1); } |
263 |
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Float_t GetDEDX_min(int ip, int iv); |
264 |
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Float_t GetDEDX_min(int iv){ return GetDEDX_min(-1,iv); } |
265 |
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Float_t GetDEDX_min(){ return GetDEDX_min(-1,-1); } |
266 |
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267 |
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Float_t GetResidual_max(int ip, int iv); |
268 |
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Float_t GetResidual_max(int iv){ return GetResidual_max(-1,iv); } |
269 |
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Float_t GetResidual_max(){ return GetResidual_max(-1,-1); } |
270 |
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Float_t GetResidual_av(int ip, int iv); |
271 |
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Float_t GetResidual_av(int iv){ return GetResidual_av(-1,iv); } |
272 |
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Float_t GetResidual_av(){ return GetResidual_av(-1,-1); } |
273 |
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274 |
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Int_t GetClusterX_Multiplicity_max(); |
275 |
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Int_t GetClusterX_Multiplicity_min(); |
276 |
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Int_t GetClusterY_Multiplicity_max(); |
277 |
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Int_t GetClusterY_Multiplicity_min(); |
278 |
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279 |
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Float_t GetClusterX_Seed_min(); |
280 |
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Float_t GetClusterY_Seed_min(); |
281 |
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282 |
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TrkTrack* GetTrkTrack(){return this;} |
283 |
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284 |
friend class TrkLevel2; |
friend class TrkLevel2; |
285 |
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286 |
ClassDef(TrkTrack,1); |
ClassDef(TrkTrack,5); |
287 |
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288 |
}; |
}; |
289 |
/** |
/** |
294 |
class TrkSinglet : public TObject { |
class TrkSinglet : public TObject { |
295 |
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296 |
private: |
private: |
297 |
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298 |
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299 |
public: |
public: |
300 |
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301 |
int plane; ///<plane |
int plane; ///<plane |
302 |
float coord[2]; ///<coordinate (on sensor 1 and 2) |
float coord[2]; ///<coordinate (on sensor 1 and 2) |
303 |
float sgnl; ///<cluster signal in MIP |
float sgnl; ///<cluster signal in MIP (<0 if saturated) |
304 |
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int multmax; ///<cluster multiplicity and strip of maximum |
305 |
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306 |
TrkSinglet(); |
TrkSinglet(); |
307 |
TrkSinglet(const TrkSinglet&); |
TrkSinglet(const TrkSinglet&); |
308 |
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~TrkSinglet(){Delete();} |
309 |
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310 |
void Dump(); |
void Dump(); |
311 |
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void Clear(); |
312 |
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void Clear(Option_t *option){Clear();} |
313 |
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void Delete(){Clear();}; |
314 |
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Float_t GetSignal(){return fabs(sgnl);} |
315 |
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Bool_t IsSaturated(){return (sgnl<0); } |
316 |
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317 |
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Bool_t IsBad() { return multmax<=0; } |
318 |
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Int_t GetCluster_Multiplicity(){ return (Int_t)(abs(multmax)/10000); } |
319 |
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Int_t GetCluster_MaxStrip() { return (Int_t)(abs(multmax)%10000); } |
320 |
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321 |
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322 |
friend class TrkLevel2; |
friend class TrkLevel2; |
323 |
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324 |
ClassDef(TrkSinglet,1); |
ClassDef(TrkSinglet,4); |
325 |
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326 |
}; |
}; |
327 |
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335 |
* Each track may have an "image", due to the ambiguity on the Y view, which is stored also. |
* Each track may have an "image", due to the ambiguity on the Y view, which is stored also. |
336 |
* Thus, the number of stored tracks ( ntrk() ) differs from the number of "physical" tracks ( GetNTracks() ). |
* Thus, the number of stored tracks ( ntrk() ) differs from the number of "physical" tracks ( GetNTracks() ). |
337 |
* Proper methods allow to sort tracks and select the physical ones ( GetTracks() ). |
* Proper methods allow to sort tracks and select the physical ones ( GetTracks() ). |
338 |
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* |
339 |
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* The event status indicates the processing status of data from each DSP, according to the following |
340 |
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* notation: |
341 |
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* |
342 |
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* LSB --> 0 missing packet |
343 |
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* 1 CRC error |
344 |
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* 2 on-line software alarm (latch-up, timeout ecc...) |
345 |
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* 3 jump in the trigger counter |
346 |
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* 4 decode error |
347 |
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* 5 n.clusters > maximum number (level1 processing) |
348 |
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* 6 |
349 |
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* 7 |
350 |
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* 8 n.clusters > maximum value (level2 processing) |
351 |
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* 9 n.couples per plane > maximum values (vector dimention) |
352 |
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* 10 n.doublets > maximum values |
353 |
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* 11 n.triplets > maximum values |
354 |
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* 12 n.yz-clouds > maximum values |
355 |
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* 13 n.xz-clouds > maximum values |
356 |
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* 14 n.candidate-tracks > maximum values |
357 |
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* 15 n.couples per plane > maximum values (for Hough transform) |
358 |
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* MSB --> 16 |
359 |
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* |
360 |
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* |
361 |
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* For all data processed before June 2007 the event status was coded according to |
362 |
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* a different rule: |
363 |
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* |
364 |
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* Status of level1 processing |
365 |
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* 0 -- OK |
366 |
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* 1 -- missing packet |
367 |
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* 2 -- 1 CRC error |
368 |
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* 3 -- 2 on-line software alarm (latch-up flags asserted or n.transmitted-words = 0) |
369 |
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* 4 -- 3 jump in the trigger counter |
370 |
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* 10 -- 4 decode error |
371 |
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* 11 -- 5 n.clusters > maximum number (for level1 processing) |
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* Status of level2 processing |
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* 21 -- 0 n.clusters > maximum value (for level2 processing) |
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* 22 -- 1 n.couples per plane > maximum values (vector dimention) |
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* 23 -- 2 n.doublets > maximum values |
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* 24 -- 3 n.triplets > maximum values |
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* 25 -- 4 n.yz-clouds > maximum values |
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* 26 -- 5 n.xz-clouds > maximum values |
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* 27 -- 6 n.candidate-tracks > maximum values |
380 |
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* 28 -- 7 n.couples per plane > maximum values (for Hough transform) |
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* |
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* |
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*/ |
*/ |
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class TrkLevel2 : public TObject { |
class TrkLevel2 : public TObject { |
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private: |
private: |
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// TRefArray *PhysicalTrack; ///< physical tracks (no image) - |
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public: |
public: |
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Int_t good2; |
Int_t good[12]; ///< event status |
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Int_t crc[12]; |
UInt_t VKmask[12]; ///< Viking-chip mask |
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UInt_t VKflag[12]; ///< Viking-chip flag |
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TClonesArray *Track; ///< fitted tracks |
TClonesArray *Track; ///< fitted tracks |
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TClonesArray *SingletX; ///< x singlets |
TClonesArray *SingletX; ///< x singlets |
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TrkLevel2(); |
TrkLevel2(); |
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// TrkLevel2(cTrkLevel2 *); |
// TrkLevel2(cTrkLevel2 *); |
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~TrkLevel2(){Delete();} |
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void Clear(); |
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void Clear(Option_t *option){Clear();} |
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void Delete(); |
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void Set(); |
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int UnpackError(){ for(int i=0; i<12; i++)if(!StatusCheck(i,0x12))return 1; return 0;} |
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int ntrk() {return Track->GetEntries();} ///< number of stored track |
int ntrk() {return Track->GetEntries();} ///< number of stored track |
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int nclsx(){return SingletX->GetEntries();} ///< number of x singlets |
int nclsx(){return SingletX->GetEntries();} ///< number of x singlets |
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int nclsy(){return SingletY->GetEntries();} ///< number of y singlets |
int nclsy(){return SingletY->GetEntries();} ///< number of y singlets |
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void Dump(); |
void Dump(); |
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void SetFromLevel2Struct(cTrkLevel2 *); |
void SetFromLevel2Struct(cTrkLevel2 *, TrkLevel1 *); |
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void SetFromLevel2Struct(cTrkLevel2 *s2){ SetFromLevel2Struct(s2, NULL); } |
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void SetFromLevel2Struct(TrkLevel1 *l1) { SetFromLevel2Struct(&level2event_, l1); } |
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void SetFromLevel2Struct() { SetFromLevel2Struct(&level2event_); } |
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void GetLevel2Struct(cTrkLevel2 *) const; |
void GetLevel2Struct(cTrkLevel2 *) const; |
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void Clear(); |
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void LoadField(TString); |
void LoadField(TString); |
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float GetBX(float* v){return TrkParams::GetBX(v);} ///< Bx (kGauss) |
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float GetBY(float* v){return TrkParams::GetBY(v);} ///< By (kGauss) |
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float GetBZ(float* v){return TrkParams::GetBZ(v);} ///< Bz (kGauss) |
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Float_t GetZTrk(Int_t); |
Float_t GetZTrk(Int_t); |
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Float_t GetXTrkLeft(){return XTRKL;}; |
Float_t GetXTrkLeft(){return XMAGNLOW;} |
424 |
Float_t GetXTrkRight(){return XTRKR;}; |
Float_t GetXTrkRight(){return XMAGNHIGH;} |
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Float_t GetYTrkLeft(){return YTRKL;}; |
Float_t GetYTrkLeft(){return YMAGNLOW;} |
426 |
Float_t GetYTrkRight(){return YTRKR;}; |
Float_t GetYTrkRight(){return YMAGNHIGH;} |
427 |
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428 |
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Bool_t IsMaskedVK(int,int); |
429 |
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Bool_t GetVKMask(int,int); |
430 |
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Bool_t GetVKFlag(int,int); |
431 |
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TrkSinglet *GetSingletX(int); |
TrkSinglet *GetSingletX(int); |
433 |
TrkSinglet *GetSingletY(int); |
TrkSinglet *GetSingletY(int); |
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TrkTrack *GetStoredTrack(int i); |
TrkTrack *GetStoredTrack(int i); |
436 |
Int_t GetSeqNo(Int_t i) {return (((TrkTrack *)Track->At(i))->seqno);}; ///< Returns track sequential number |
Int_t GetSeqNo(Int_t i) {return (((TrkTrack *)Track->At(i))->seqno);} ///< Returns track sequential number |
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// TClonesArray *GetTracks_Chi2Sorted(); |
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// TClonesArray *GetTracks_NFitSorted(); |
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// TClonesArray *GetTracks(); |
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TRefArray *GetTracks_NFitSorted(); |
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TRefArray *GetTracks(){return this->GetTracks_NFitSorted();}; |
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// int GetNTracks(){return this->GetTracks()->GetEntries();} |
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Int_t GetNTracks(); |
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TrkTrack* GetTrack(int i); |
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TrkTrack* GetTrackImage(int i); |
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437 |
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438 |
TrkLevel2* GetTrkLevel2(){return this;} |
TRefArray *GetTracks_NFitSorted(); |
439 |
TClonesArray* GetTrackArray(){return Track;};///< returns pointer to the track array |
TRefArray *GetTracks(){return this->GetTracks_NFitSorted();} |
440 |
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441 |
ClassDef(TrkLevel2,1); |
Int_t GetNTracks(); |
442 |
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TrkTrack* GetTrack(int i); |
443 |
}; |
TrkTrack* GetTrackImage(int i); |
444 |
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445 |
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TrkLevel2* GetTrkLevel2(){return this;} |
446 |
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TClonesArray* GetTrackArray(){return Track;}///< returns pointer to the track array |
447 |
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TClonesArray** GetPointerToTrackArray(){return &Track;}///< returns pointer to pointer to the track array |
448 |
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void StatusDump(int view); |
449 |
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Bool_t StatusCheck(int view, int flagmask); |
450 |
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451 |
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ClassDef(TrkLevel2,3); |
452 |
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453 |
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}; |
454 |
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455 |
#endif |
#endif |