PamVMC_update/include/PamVMCPrimaryGenerator.h

// $Id: PamVMCPrimaryGenerator.h,v 1.0 2007/06/03 

#ifndef PAMVMC_PRIMARY_GENERATOR_H
#define PAMVMC_PRIMARY_GENERATOR_H

#include <iostream>
#include <TVirtualMCApplication.h>
#include <TClonesArray.h>
#include <TVector3.h>
#include <TVector2.h>
#include <TMath.h>
#include <TRandom.h>
#include <TF1.h>
//#include <TObjectTable.h>

#include <PamLevel2.h>

#include "PamRootManager.h"
#include "PamVMC2PiAux.h"
#include "PamVMCPrimaryGF.h"

class TVirtualMCStack;

using std::cout;
using std::endl;
using TMath::Sqrt;

class PamVMCPrimary : public TObject
{

 public:
  
 PamVMCPrimary(): fID(0), fPDG(0), fX0(0.), fY0(0.), fZ0(0.), fTHETA(0.), fPHI(0.), fP0(0.), fGOOD(kFALSE),  fXTOL(-100.), fYTOL(-100.){
    

    for (Int_t j = 0; j<14; j++){ 
      fCR_X[j] = -100.; 
      fCR_Y[j] = -100.;         
    }       
  };    

   virtual ~PamVMCPrimary(){ /*gObjectTable->Remove(this);*/};

  UInt_t fID;
  Int_t fPDG;
  Double_t fX0, fY0, fZ0;
  Double_t fTHETA, fPHI;
  Double_t fP0;
  Bool_t fGOOD;
  Double_t fXTOL, fYTOL;
  Double_t fCR_X [14];
  Double_t fCR_Y [14];
  

  void Clean() { fID=0; fPDG=0; fX0=fY0=fZ0=fTHETA=fPHI=fP0=0.; fGOOD=kFALSE; fXTOL=fYTOL=-100.;
    for (Int_t j = 0; j<14; j++){
      fCR_X[j] = -100.;
      fCR_Y[j] = -100.;      
    }   
    
  }

  void Clear(const Option_t * =""){ this->~PamVMCPrimary(); }

  void Print(const Option_t * ="") const
    { cout<<"PRIMARY particle "<<fID<<"  infromation:"<<endl;
      cout<<"Pdg="<<fPDG<<endl; 
      cout<<"Position: "<<"("<<fX0<<","<<fY0<<","<<fZ0<<")"<<endl;
      cout<<"P0, Theta, Phi: "<<fP0<<","<<fTHETA<<","<<fPHI<<endl;
      cout<<"GOOD Single Track:"<<fGOOD<<endl;
      cout<<"Xtol= "<<fXTOL<<" Ytol= "<<fYTOL<<endl;
      cout<<" Coordinates of acceptance planes crossing:"<<endl;
      for(Int_t i = 0; i< 14; i++){
        cout<<"i="<<i<<" X="<<fCR_X[i]<<" Y="<<fCR_Y[i]<<endl;
      }
    }

  ClassDef(PamVMCPrimary,1);
};

PamVMCPrimary & operator+=(PamVMCPrimary &a, const PamVMCPrimary &b);

class PamVMCPrimaryGenerator : public TObject
{
  public:
    PamVMCPrimaryGenerator(TVirtualMCStack* stack); 
    PamVMCPrimaryGenerator();

    virtual ~PamVMCPrimaryGenerator();

    // methods
    
    void GeneratePrimary();
    // set methods
    void SetParticle(Int_t pdg);
    void SetParticleID(UInt_t id){ fprim.fID = id; };
    void SetPosition(Double_t vx, Double_t vy, Double_t vz) 
         {fprim.fX0=vx; fprim.fY0=vy; fprim.fZ0=vz;};
   
    void SetKinEnergy(Double_t kinEnergy) {fprim.fP0=KinEToMomentum(kinEnergy);};
    void SetRigidity(Double_t rigidity) {fprim.fP0=RigToMomentum(rigidity);};
    void SetMomentum(Double_t momentum) {fprim.fP0=momentum; };

    void SetDirection(Double_t theta, Double_t phi) {fprim.fTHETA=theta; fprim.fPHI=phi; };
    void SetMomentum(Double_t px, Double_t py, Double_t pz);
     
    // gen methods

    void GenPosition(Double_t xmin, Double_t xmax, Double_t ymin, Double_t ymax, Double_t zmin, Double_t zmax){
      SetPosition(frandom->Uniform(xmin,xmax),frandom->Uniform(ymin,ymax),frandom->Uniform(zmin,zmax)); }
    
    void GenDirection(Double_t thetamin, Double_t thetamax, Double_t phimin, Double_t phimax){
      Double_t theta = TMath::ASin(Sqrt( frandom->Uniform( TMath::ASin(thetamin), TMath::ASin(thetamax))));
      Double_t phi = TMath::TwoPi() * frandom->Uniform( phimin, phimax );
      SetDirection(theta, phi);
    }
    
    void GenPosAng(TVector3 &pos, TVector2 &ang) { f2PiAux->GenPosAng(pos,ang); }
    
    void Gen2PiPosAng(){
      TVector3 pos;
      TVector2 ang;
      GenPosAng(pos,ang);
      SetPosition( pos.X(), pos.Y(), pos.Z() );
      SetDirection( ang.X(), ang.Y() );
    }
    
    void ExtrapolateTrajectory(){      //Added by V. Formato on 2012/06/19
      Float_t zin[TrkParams::nGF];
      for (Int_t igf=0; igf<TrkParams::nGF; igf++) zin[igf]=TrkParams::zGF[igf];
      Trajectory* t = new Trajectory(TrkParams::nGF,zin);
      Float_t al[5];
      al[0] = fprim.fX0;
      al[1] = fprim.fY0;
      al[2] = sin(fprim.fTHETA);
      al[3] = fprim.fPHI;
      al[4] = fcharge/fprim.fP0;

      t->DoTrack(al, fprim.fZ0 - 13.05 - 10.639 - 2.97 - 22.57);
      //      t->DoTrack(al, fprim.fZ0);

      for(Int_t igf=0; igf<NGF; igf++){
        fprim.fCR_X[igf] = t->x[igf];
        fprim.fCR_Y[igf] = t->y[igf];
      }

      delete t;

    }

    Bool_t ToBeSimulated(){

      float *xmin = TrkParams::xGF_min;
      float *xmax = TrkParams::xGF_max;
      float *ymin = TrkParams::yGF_min;
      float *ymax = TrkParams::yGF_max;
      
      for(Int_t i=0; i<NGF; i++){
        if( !((xmin[i]<fprim.fCR_X[i])&&(fprim.fCR_X[i]<xmax[i])) ) return kFALSE;
        if( !((ymin[i]<fprim.fCR_Y[i])&&(fprim.fCR_Y[i]<ymax[i])) ) return kFALSE;
      }

      return kTRUE;
    }
    

    //flat spectra generator
    void GenSpe(Double_t PEmin, Double_t PEmax, Bool_t isEnergy=kFALSE); 
    //power law spectra, gamma - differential spectral index
    void GenSpe(Double_t PEmin, Double_t PEmax, Double_t gamma, Bool_t isEnergy=kFALSE); 
    void GenSpe_Flat(Double_t PEmin, Double_t PEmax, Double_t gamma, Bool_t isEnergy=kFALSE); 
    void GenSpe_3par(Double_t PEmin, Double_t PEmax, Double_t a, Double_t b, Double_t c);
    void GenSphericalPhiThe(); // cecilia // flusso istropo // sets phi the
    void GenSphPhiThe(Double_t xmin, Double_t xmax, Double_t ymin, Double_t ymax, 
                      Double_t zmin, Double_t zmax); // flusso isotropo entro S2 S3
    //                                                  sets position and phi the
    

    // get methods
    Int_t GetParticleID(){ return fprim.fID; };
    Int_t GetParticle(){ return fprim.fPDG; };
    void  GetPositon(TVector3 & v){ v.SetXYZ(fprim.fX0,fprim.fY0,fprim.fZ0); };
    void  GetPosition(Double_t & X0, Double_t & Y0,Double_t & Z0)
          {X0=fprim.fX0; Y0=fprim.fY0; Z0=fprim.fZ0;};

    Double_t GetKinEnergy() { return MomentumToKinE(fprim.fP0); };
    Double_t GetRigidity() { return MomentumToRig(fprim.fP0); };
    Double_t GetMomentum() { return fprim.fP0; };
    
    Double_t Get2PiArea() { return f2PiAux->GetArea(); };

    void GetDirection(TVector2 & v) {v.Set(fprim.fTHETA,fprim.fPHI);}
    void GetDirection(Double_t &theta, Double_t & phi) { theta = fprim.fTHETA; phi = fprim.fPHI;}
    
    Bool_t Getgood(){ return fprim.fGOOD; };

    void GetTol(Double_t& xtol, Double_t& ytol){ xtol=fprim.fXTOL; ytol=fprim.fYTOL; };

    void GetCR_GF(Double_t& xcr, Double_t& ycr, Int_t id_GF){
      if(id_GF<14){
        xcr=fprim.fCR_X[id_GF]; 
        ycr=fprim.fCR_Y[id_GF];
      }
    }
    
    Int_t GetNgood(){ return fngood; }

    //initialize random
    void SetRandom(TRandom* random){
      frandom = random;
      f2PiAux->SetRandom(random);
    }

    //work with collection of primaries

    void Register(){
      PamRootManager::Instance()->
        Register("PRIM","TClonesArray", &fprimColl);
    }

    void ClearPrimCol(){
      fevno=0;
      (*fprimColl).Clear("C");
    }
    //all methods to operate with PamVMCPrimaryGF object
    //after each step of primary
    void SetZeroStep(Double_t z_curr, Double_t x_curr, Double_t y_curr){
      fzprev = z_curr;
      fxprev = x_curr;
      fyprev = y_curr;
    }
    void CheckCrossing(Double_t z_curr, Double_t x_curr, Double_t y_curr){
      fpgf->CheckCrossing(fzprev,fxprev,fyprev, z_curr, x_curr, y_curr);
      SetZeroStep(z_curr,x_curr, y_curr);
    }
    //after last step of primary
    void CheckInsideAcceptance(){
      //      for(Int_t i = 0; i<NGF; i++) fprim.fCR_X[i] = fprim.fCR_Y[i] = fprim.fXTOL = fprim.fYTOL = -100.; //zeroing
      fprim.fGOOD = fpgf->IsInsideAcceptance(fprim.fCR_X, fprim.fCR_Y, fprim.fXTOL, fprim.fYTOL);
      fpgf->Clear();
      if(fprim.fGOOD) fngood++;
      //Here I'm getting what I have in collection and asume that I have only 1 primary here
      //If I wish to launch more in 1 event I need change this stuff
      PamVMCPrimary* tmp = (PamVMCPrimary*)fprimColl->At(0);
      if(tmp) *tmp = fprim;
    }

    Double_t MomentumToKinE(Double_t P0);
    Double_t KinEToMomentum(Double_t E0);
    Double_t MomentumToRig(Double_t P0) { return TMath::Abs(P0/fcharge); };
    Double_t RigToMomentum(Double_t R0){ return TMath::Abs(R0*fcharge); };
    Double_t function3par(Double_t xx, Double_t a, Double_t b, Double_t c){return  5.*pow((xx + b * exp(-c * sqrt(xx))),-a);};

  private:
    // methods
    
  
    // data members
    TVirtualMCStack*  fStack;
    Int_t             fevno;
    Int_t             fngood; //particles inside nominal acceptance
    PamVMCPrimary     fprim;
    Double_t          fmass;
    Double_t          fcharge;
    Double_t          fxprev, fyprev, fzprev; // coordinates of primary on prev. step
    TClonesArray*     fprimColl; 
    TRandom*          frandom; // Class is not a owner of this object
    TF1*              ftheta; // To generate sherical distributhin in theta-angle
    PamVMC2PiAux*     f2PiAux; //2 Pi generator aux stuff
    PamVMCPrimaryGF*  fpgf;  // Object which
    

  ClassDef(PamVMCPrimaryGenerator,1)  //PamVMCPrimaryGenerator
};

// inline functions


inline Double_t PamVMCPrimaryGenerator::MomentumToKinE(Double_t P0)
{ return  Sqrt(P0*P0+fmass*fmass)-fmass; }

inline Double_t PamVMCPrimaryGenerator::KinEToMomentum(Double_t E0)
{ return  Sqrt(E0*E0+2.*E0*fmass); }

#endif //PAMVMC_PRIMARY_GENERATOR_H

1	formato	1.1	// $Id: PamVMCPrimaryGenerator.h,v 1.0 2007/06/03
2
3			#ifndef PAMVMC_PRIMARY_GENERATOR_H
4			#define PAMVMC_PRIMARY_GENERATOR_H
5
6			#include <iostream>
7			#include <TVirtualMCApplication.h>
8			#include <TClonesArray.h>
9			#include <TVector3.h>
10			#include <TVector2.h>
11			#include <TMath.h>
12			#include <TRandom.h>
13			#include <TF1.h>
14			//#include <TObjectTable.h>
15
16			#include <PamLevel2.h>
17
18			#include "PamRootManager.h"
19			#include "PamVMC2PiAux.h"
20			#include "PamVMCPrimaryGF.h"
21
22			class TVirtualMCStack;
23
24			using std::cout;
25			using std::endl;
26			using TMath::Sqrt;
27
28			class PamVMCPrimary : public TObject
29			{
30
31			public:
32
33			PamVMCPrimary(): fID(0), fPDG(0), fX0(0.), fY0(0.), fZ0(0.), fTHETA(0.), fPHI(0.), fP0(0.), fGOOD(kFALSE), fXTOL(-100.), fYTOL(-100.){
34
35
36			for (Int_t j = 0; j<14; j++){
37			fCR_X[j] = -100.;
38			fCR_Y[j] = -100.;
39			}
40			};
41
42			virtual ~PamVMCPrimary(){ /gObjectTable->Remove(this);/};
43
44			UInt_t fID;
45			Int_t fPDG;
46			Double_t fX0, fY0, fZ0;
47			Double_t fTHETA, fPHI;
48			Double_t fP0;
49			Bool_t fGOOD;
50			Double_t fXTOL, fYTOL;
51			Double_t fCR_X [14];
52			Double_t fCR_Y [14];
53
54
55			void Clean() { fID=0; fPDG=0; fX0=fY0=fZ0=fTHETA=fPHI=fP0=0.; fGOOD=kFALSE; fXTOL=fYTOL=-100.;
56			for (Int_t j = 0; j<14; j++){
57			fCR_X[j] = -100.;
58			fCR_Y[j] = -100.;
59			}
60
61			}
62
63			void Clear(const Option_t * =""){ this->~PamVMCPrimary(); }
64
65			void Print(const Option_t * ="") const
66			{ cout<<"PRIMARY particle "<<fID<<" infromation:"<<endl;
67			cout<<"Pdg="<<fPDG<<endl;
68			cout<<"Position: "<<"("<<fX0<<","<<fY0<<","<<fZ0<<")"<<endl;
69			cout<<"P0, Theta, Phi: "<<fP0<<","<<fTHETA<<","<<fPHI<<endl;
70			cout<<"GOOD Single Track:"<<fGOOD<<endl;
71			cout<<"Xtol= "<<fXTOL<<" Ytol= "<<fYTOL<<endl;
72			cout<<" Coordinates of acceptance planes crossing:"<<endl;
73			for(Int_t i = 0; i< 14; i++){
74			cout<<"i="<<i<<" X="<<fCR_X[i]<<" Y="<<fCR_Y[i]<<endl;
75			}
76			}
77
78			ClassDef(PamVMCPrimary,1);
79			};
80
81			PamVMCPrimary & operator+=(PamVMCPrimary &a, const PamVMCPrimary &b);
82
83			class PamVMCPrimaryGenerator : public TObject
84			{
85			public:
86			PamVMCPrimaryGenerator(TVirtualMCStack* stack);
87			PamVMCPrimaryGenerator();
88
89			virtual ~PamVMCPrimaryGenerator();
90
91			// methods
92
93			void GeneratePrimary();
94			// set methods
95			void SetParticle(Int_t pdg);
96			void SetParticleID(UInt_t id){ fprim.fID = id; };
97			void SetPosition(Double_t vx, Double_t vy, Double_t vz)
98			{fprim.fX0=vx; fprim.fY0=vy; fprim.fZ0=vz;};
99
100			void SetKinEnergy(Double_t kinEnergy) {fprim.fP0=KinEToMomentum(kinEnergy);};
101			void SetRigidity(Double_t rigidity) {fprim.fP0=RigToMomentum(rigidity);};
102			void SetMomentum(Double_t momentum) {fprim.fP0=momentum; };
103
104			void SetDirection(Double_t theta, Double_t phi) {fprim.fTHETA=theta; fprim.fPHI=phi; };
105			void SetMomentum(Double_t px, Double_t py, Double_t pz);
106
107			// gen methods
108
109			void GenPosition(Double_t xmin, Double_t xmax, Double_t ymin, Double_t ymax, Double_t zmin, Double_t zmax){
110			SetPosition(frandom->Uniform(xmin,xmax),frandom->Uniform(ymin,ymax),frandom->Uniform(zmin,zmax)); }
111
112			void GenDirection(Double_t thetamin, Double_t thetamax, Double_t phimin, Double_t phimax){
113			Double_t theta = TMath::ASin(Sqrt( frandom->Uniform( TMath::ASin(thetamin), TMath::ASin(thetamax))));
114			Double_t phi = TMath::TwoPi() * frandom->Uniform( phimin, phimax );
115			SetDirection(theta, phi);
116			}
117
118			void GenPosAng(TVector3 &pos, TVector2 &ang) { f2PiAux->GenPosAng(pos,ang); }
119
120			void Gen2PiPosAng(){
121			TVector3 pos;
122			TVector2 ang;
123			GenPosAng(pos,ang);
124			SetPosition( pos.X(), pos.Y(), pos.Z() );
125			SetDirection( ang.X(), ang.Y() );
126			}
127
128			void ExtrapolateTrajectory(){ //Added by V. Formato on 2012/06/19
129			Float_t zin[TrkParams::nGF];
130			for (Int_t igf=0; igf<TrkParams::nGF; igf++) zin[igf]=TrkParams::zGF[igf];
131			Trajectory* t = new Trajectory(TrkParams::nGF,zin);
132			Float_t al[5];
133			al[0] = fprim.fX0;
134			al[1] = fprim.fY0;
135			al[2] = sin(fprim.fTHETA);
136			al[3] = fprim.fPHI;
137			al[4] = fcharge/fprim.fP0;
138
139			t->DoTrack(al, fprim.fZ0 - 13.05 - 10.639 - 2.97 - 22.57);
140			// t->DoTrack(al, fprim.fZ0);
141
142			for(Int_t igf=0; igf<NGF; igf++){
143			fprim.fCR_X[igf] = t->x[igf];
144			fprim.fCR_Y[igf] = t->y[igf];
145			}
146
147			delete t;
148
149			}
150
151			Bool_t ToBeSimulated(){
152
153			float *xmin = TrkParams::xGF_min;
154			float *xmax = TrkParams::xGF_max;
155			float *ymin = TrkParams::yGF_min;
156			float *ymax = TrkParams::yGF_max;
157
158			for(Int_t i=0; i<NGF; i++){
159			if( !((xmin[i]<fprim.fCR_X[i])&&(fprim.fCR_X[i]<xmax[i])) ) return kFALSE;
160			if( !((ymin[i]<fprim.fCR_Y[i])&&(fprim.fCR_Y[i]<ymax[i])) ) return kFALSE;
161			}
162
163			return kTRUE;
164			}
165
166
167			//flat spectra generator
168			void GenSpe(Double_t PEmin, Double_t PEmax, Bool_t isEnergy=kFALSE);
169			//power law spectra, gamma - differential spectral index
170			void GenSpe(Double_t PEmin, Double_t PEmax, Double_t gamma, Bool_t isEnergy=kFALSE);
171			void GenSpe_Flat(Double_t PEmin, Double_t PEmax, Double_t gamma, Bool_t isEnergy=kFALSE);
172			void GenSpe_3par(Double_t PEmin, Double_t PEmax, Double_t a, Double_t b, Double_t c);
173			void GenSphericalPhiThe(); // cecilia // flusso istropo // sets phi the
174			void GenSphPhiThe(Double_t xmin, Double_t xmax, Double_t ymin, Double_t ymax,
175			Double_t zmin, Double_t zmax); // flusso isotropo entro S2 S3
176			// sets position and phi the
177
178
179			// get methods
180			Int_t GetParticleID(){ return fprim.fID; };
181			Int_t GetParticle(){ return fprim.fPDG; };
182			void GetPositon(TVector3 & v){ v.SetXYZ(fprim.fX0,fprim.fY0,fprim.fZ0); };
183			void GetPosition(Double_t & X0, Double_t & Y0,Double_t & Z0)
184			{X0=fprim.fX0; Y0=fprim.fY0; Z0=fprim.fZ0;};
185
186			Double_t GetKinEnergy() { return MomentumToKinE(fprim.fP0); };
187			Double_t GetRigidity() { return MomentumToRig(fprim.fP0); };
188			Double_t GetMomentum() { return fprim.fP0; };
189
190			Double_t Get2PiArea() { return f2PiAux->GetArea(); };
191
192			void GetDirection(TVector2 & v) {v.Set(fprim.fTHETA,fprim.fPHI);}
193			void GetDirection(Double_t &theta, Double_t & phi) { theta = fprim.fTHETA; phi = fprim.fPHI;}
194
195			Bool_t Getgood(){ return fprim.fGOOD; };
196
197			void GetTol(Double_t& xtol, Double_t& ytol){ xtol=fprim.fXTOL; ytol=fprim.fYTOL; };
198
199			void GetCR_GF(Double_t& xcr, Double_t& ycr, Int_t id_GF){
200			if(id_GF<14){
201			xcr=fprim.fCR_X[id_GF];
202			ycr=fprim.fCR_Y[id_GF];
203			}
204			}
205
206			Int_t GetNgood(){ return fngood; }
207
208			//initialize random
209			void SetRandom(TRandom* random){
210			frandom = random;
211			f2PiAux->SetRandom(random);
212			}
213
214			//work with collection of primaries
215
216			void Register(){
217			PamRootManager::Instance()->
218			Register("PRIM","TClonesArray", &fprimColl);
219			}
220
221			void ClearPrimCol(){
222			fevno=0;
223			(*fprimColl).Clear("C");
224			}
225			//all methods to operate with PamVMCPrimaryGF object
226			//after each step of primary
227			void SetZeroStep(Double_t z_curr, Double_t x_curr, Double_t y_curr){
228			fzprev = z_curr;
229			fxprev = x_curr;
230			fyprev = y_curr;
231			}
232			void CheckCrossing(Double_t z_curr, Double_t x_curr, Double_t y_curr){
233			fpgf->CheckCrossing(fzprev,fxprev,fyprev, z_curr, x_curr, y_curr);
234			SetZeroStep(z_curr,x_curr, y_curr);
235			}
236			//after last step of primary
237			void CheckInsideAcceptance(){
238			// for(Int_t i = 0; i<NGF; i++) fprim.fCR_X[i] = fprim.fCR_Y[i] = fprim.fXTOL = fprim.fYTOL = -100.; //zeroing
239			fprim.fGOOD = fpgf->IsInsideAcceptance(fprim.fCR_X, fprim.fCR_Y, fprim.fXTOL, fprim.fYTOL);
240			fpgf->Clear();
241			if(fprim.fGOOD) fngood++;
242			//Here I'm getting what I have in collection and asume that I have only 1 primary here
243			//If I wish to launch more in 1 event I need change this stuff
244			PamVMCPrimary* tmp = (PamVMCPrimary*)fprimColl->At(0);
245			if(tmp) *tmp = fprim;
246			}
247
248			Double_t MomentumToKinE(Double_t P0);
249			Double_t KinEToMomentum(Double_t E0);
250			Double_t MomentumToRig(Double_t P0) { return TMath::Abs(P0/fcharge); };
251			Double_t RigToMomentum(Double_t R0){ return TMath::Abs(R0*fcharge); };
252			Double_t function3par(Double_t xx, Double_t a, Double_t b, Double_t c){return 5.pow((xx + b exp(-c * sqrt(xx))),-a);};
253
254			private:
255			// methods
256
257
258
259			// data members
260			TVirtualMCStack* fStack;
261			Int_t fevno;
262			Int_t fngood; //particles inside nominal acceptance
263			PamVMCPrimary fprim;
264			Double_t fmass;
265			Double_t fcharge;
266			Double_t fxprev, fyprev, fzprev; // coordinates of primary on prev. step
267			TClonesArray* fprimColl;
268			TRandom* frandom; // Class is not a owner of this object
269			TF1* ftheta; // To generate sherical distributhin in theta-angle
270			PamVMC2PiAux* f2PiAux; //2 Pi generator aux stuff
271			PamVMCPrimaryGF* fpgf; // Object which
272
273
274			ClassDef(PamVMCPrimaryGenerator,1) //PamVMCPrimaryGenerator
275			};
276
277			// inline functions
278
279
280			inline Double_t PamVMCPrimaryGenerator::MomentumToKinE(Double_t P0)
281			{ return Sqrt(P0P0+fmassfmass)-fmass; }
282
283			inline Double_t PamVMCPrimaryGenerator::KinEToMomentum(Double_t E0)
284			{ return Sqrt(E0E0+2.E0*fmass); }
285
286			#endif //PAMVMC_PRIMARY_GENERATOR_H
287