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Cross-Referencing   Geant4
Geant4/processes/hadronic/models/inclxx/utils/include/G4INCLParticle.hh

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Differences between /processes/hadronic/models/inclxx/utils/include/G4INCLParticle.hh (Version 11.3.0) and /processes/hadronic/models/inclxx/utils/include/G4INCLParticle.hh (Version 5.2.p1)

   //                                                   
   // *******************************************    
   // * License and Disclaimer                       
   // *                                              
   // * The  Geant4 software  is  copyright of th    
   // * the Geant4 Collaboration.  It is provided    
   // * conditions of the Geant4 Software License    
   // * LICENSE and available at  http://cern.ch/    
   // * include a list of copyright holders.         
  // *                                              
  // * Neither the authors of this software syst    
  // * institutes,nor the agencies providing fin    
  // * work  make  any representation or  warran    
  // * regarding  this  software system or assum    
  // * use.  Please see the license in the file     
  // * for the full disclaimer and the limitatio    
  // *                                              
  // * This  code  implementation is the result     
  // * technical work of the GEANT4 collaboratio    
  // * By using,  copying,  modifying or  distri    
  // * any work based  on the software)  you  ag    
  // * use  in  resulting  scientific  publicati    
  // * acceptance of all terms of the Geant4 Sof    
  // *******************************************    
  //                                                
  // INCL++ intra-nuclear cascade model             
  // Alain Boudard, CEA-Saclay, France              
  // Joseph Cugnon, University of Liege, Belgium    
  // Jean-Christophe David, CEA-Saclay, France      
  // Pekka Kaitaniemi, CEA-Saclay, France, and H    
  // Sylvie Leray, CEA-Saclay, France               
  // Davide Mancusi, CEA-Saclay, France             
  //                                                
  #define INCLXX_IN_GEANT4_MODE 1                   
                                                    
  #include "globals.hh"                             
                                                    
  /*                                                
   * G4INCLParticle.hh                              
   *                                                
   *  \date Jun 5, 2009                             
   * \author Pekka Kaitaniemi                       
   */                                               
                                                    
  #ifndef PARTICLE_HH_                              
  #define PARTICLE_HH_                              
                                                    
  #include "G4INCLThreeVector.hh"                   
  #include "G4INCLParticleTable.hh"                 
  #include "G4INCLParticleType.hh"                  
  #include "G4INCLParticleSpecies.hh"               
  #include "G4INCLLogger.hh"                        
  #include "G4INCLUnorderedVector.hh"               
  #include "G4INCLAllocationPool.hh"                
  #include <sstream>                                
  #include <string>                                 
                                                    
  namespace G4INCL {                                
                                                    
    class Particle;                                 
                                                    
    class ParticleList : public UnorderedVector<    
      public:                                       
        void rotatePositionAndMomentum(const G4d    
        void rotatePosition(const G4double angle    
        void rotateMomentum(const G4double angle    
        void boost(const ThreeVector &b) const;     
        G4double getParticleListBias() const;       
        std::vector<G4int> getParticleListBiasVe    
    };                                              
                                                    
    typedef ParticleList::const_iterator Particl    
    typedef ParticleList::iterator       Particl    
                                                    
    class Particle {                                
    public:                                         
      Particle();                                   
      Particle(ParticleType t, G4double energy,     
      Particle(ParticleType t, ThreeVector const    
      virtual ~Particle() {}                        
                                                    
      /** \brief Copy constructor                   
       *                                            
       * Does not copy the particle ID.             
       */                                           
      Particle(const Particle &rhs) :               
        theZ(rhs.theZ),                             
        theA(rhs.theA),                             
        theS(rhs.theS),                             
        theParticipantType(rhs.theParticipantTyp    
        theType(rhs.theType),                       
        theEnergy(rhs.theEnergy),                   
        theFrozenEnergy(rhs.theFrozenEnergy),       
        theMomentum(rhs.theMomentum),               
        theFrozenMomentum(rhs.theFrozenMomentum)    
        thePosition(rhs.thePosition),               
        nCollisions(rhs.nCollisions),               
        nDecays(rhs.nDecays),                       
        thePotentialEnergy(rhs.thePotentialEnerg    
       rpCorrelated(rhs.rpCorrelated),             
       uncorrelatedMomentum(rhs.uncorrelatedMom    
       theParticleBias(rhs.theParticleBias),       
       theNKaon(rhs.theNKaon),                     
 #ifdef INCLXX_IN_GEANT4_MODE                      
       theParentResonancePDGCode(rhs.theParentR    
       theParentResonanceID(rhs.theParentResona    
 #endif                                            
       theHelicity(rhs.theHelicity),               
       emissionTime(rhs.emissionTime),             
       outOfWell(rhs.outOfWell),                   
       theMass(rhs.theMass)                        
       {                                           
         if(rhs.thePropagationEnergy == &(rhs.t    
           thePropagationEnergy = &theFrozenEne    
         else                                      
           thePropagationEnergy = &theEnergy;      
         if(rhs.thePropagationMomentum == &(rhs    
           thePropagationMomentum = &theFrozenM    
         else                                      
           thePropagationMomentum = &theMomentu    
         // ID intentionally not copied            
         ID = nextID++;                            
                                                   
         theBiasCollisionVector = rhs.theBiasCo    
       }                                           
                                                   
   protected:                                      
     /// \brief Helper method for the assignmen    
     void swap(Particle &rhs) {                    
       std::swap(theZ, rhs.theZ);                  
       std::swap(theA, rhs.theA);                  
       std::swap(theS, rhs.theS);                  
       std::swap(theParticipantType, rhs.thePar    
       std::swap(theType, rhs.theType);            
       if(rhs.thePropagationEnergy == &(rhs.the    
         thePropagationEnergy = &theFrozenEnerg    
       else                                        
         thePropagationEnergy = &theEnergy;        
       std::swap(theEnergy, rhs.theEnergy);        
       std::swap(theFrozenEnergy, rhs.theFrozen    
       if(rhs.thePropagationMomentum == &(rhs.t    
         thePropagationMomentum = &theFrozenMom    
       else                                        
         thePropagationMomentum = &theMomentum;    
       std::swap(theMomentum, rhs.theMomentum);    
       std::swap(theFrozenMomentum, rhs.theFroz    
       std::swap(thePosition, rhs.thePosition);    
       std::swap(nCollisions, rhs.nCollisions);    
       std::swap(nDecays, rhs.nDecays);            
       std::swap(thePotentialEnergy, rhs.thePot    
       // ID intentionally not swapped             
                                                   
 #ifdef INCLXX_IN_GEANT4_MODE                      
       std::swap(theParentResonancePDGCode, rhs    
       std::swap(theParentResonanceID, rhs.theP    
 #endif                                            
                                                   
       std::swap(theHelicity, rhs.theHelicity);    
       std::swap(emissionTime, rhs.emissionTime    
       std::swap(outOfWell, rhs.outOfWell);        
                                                   
       std::swap(theMass, rhs.theMass);            
       std::swap(rpCorrelated, rhs.rpCorrelated    
       std::swap(uncorrelatedMomentum, rhs.unco    
                                                   
       std::swap(theParticleBias, rhs.thePartic    
       std::swap(theBiasCollisionVector, rhs.th    
                                                   
     }                                             
                                                   
   public:                                         
                                                   
     /** \brief Assignment operator                
      *                                            
      * Does not copy the particle ID.             
      */                                           
     Particle &operator=(const Particle &rhs) {    
       Particle temporaryParticle(rhs);            
       swap(temporaryParticle);                    
       return *this;                               
     }                                             
                                                   
     /**                                           
      * Get the particle type.                     
      * @see G4INCL::ParticleType                  
      */                                           
     G4INCL::ParticleType getType() const {        
       return theType;                             
     };                                            
                                                   
     /// \brief Get the particle species           
     virtual G4INCL::ParticleSpecies getSpecies    
       return ParticleSpecies(theType);            
     };                                            
                                                   
     void setType(ParticleType t) {                
       theType = t;                                
       switch(theType)                             
       {                                           
         case DeltaPlusPlus:                       
           theA = 1;                               
           theZ = 2;                               
           theS = 0;                               
           break;                                  
         case Proton:                              
         case DeltaPlus:                           
           theA = 1;                               
           theZ = 1;                               
           theS = 0;                               
           break;                                  
         case Neutron:                             
         case DeltaZero:                           
           theA = 1;                               
           theZ = 0;                               
           theS = 0;                               
           break;                                  
         case DeltaMinus:                          
           theA = 1;                               
           theZ = -1;                              
           theS = 0;                               
           break;                                  
         case PiPlus:                              
           theA = 0;                               
           theZ = 1;                               
           theS = 0;                               
           break;                                  
         case PiZero:                              
         case Eta:                                 
         case Omega:                               
         case EtaPrime:                            
         case Photon:                              
           theA = 0;                               
           theZ = 0;                               
           theS = 0;                               
           break;                                  
         case PiMinus:                             
           theA = 0;                               
           theZ = -1;                              
           theS = 0;                               
           break;                                  
         case Lambda:                              
           theA = 1;                               
           theZ = 0;                               
           theS = -1;                              
           break;                                  
         case SigmaPlus:                           
           theA = 1;                               
           theZ = 1;                               
           theS = -1;                              
           break;                                  
         case SigmaZero:                           
           theA = 1;                               
           theZ = 0;                               
           theS = -1;                              
           break;                                  
         case SigmaMinus:                          
           theA = 1;                               
           theZ = -1;                              
           theS = -1;                              
           break;                                  
         case antiProton:                          
           theA = -1;                              
           theZ = -1;                              
           theS = 0;                               
           break;                                  
         case XiMinus:                             
           theA = 1;                               
           theZ = -1;                              
           theS = -2;                              
           break;                                  
         case XiZero:                              
           theA = 1;                               
           theZ = 0;                               
           theS = -2;                              
           break;                                  
         case antiNeutron:                         
           theA = -1;                              
           theZ = 0;                               
           theS = 0;                               
           break;                                  
         case antiLambda:                          
           theA = -1;                              
           theZ = 0;                               
           theS = 1;                               
           break;                                  
         case antiSigmaMinus:                      
           theA = -1;                              
           theZ = 1;                               
           theS = 1;                               
           break;                                  
         case antiSigmaPlus:                       
           theA = -1;                              
           theZ = -1;                              
           theS = 1;                               
           break;                                  
         case antiSigmaZero:                       
           theA = -1;                              
           theZ = 0;                               
           theS = 1;                               
           break;                                  
         case antiXiMinus:                         
           theA = -1;                              
           theZ = 1;                               
           theS = 2;                               
           break;                                  
         case antiXiZero:                          
           theA = -1;                              
           theZ = 0;                               
           theS = 2;                               
           break;                                  
         case KPlus:                               
           theA = 0;                               
           theZ = 1;                               
           theS = 1;                               
           break;                                  
         case KZero:                               
           theA = 0;                               
           theZ = 0;                               
           theS = 1;                               
           break;                                  
         case KZeroBar:                            
           theA = 0;                               
           theZ = 0;                               
           theS = -1;                              
           break;                                  
         case KShort:                              
           theA = 0;                               
           theZ = 0;                               
 //        theS should not be defined              
           break;                                  
         case KLong:                               
           theA = 0;                               
           theZ = 0;                               
 //        theS should not be defined              
           break;                                  
         case KMinus:                              
           theA = 0;                               
           theZ = -1;                              
           theS = -1;                              
           break;                                  
         case Composite:                           
          // INCL_ERROR("Trying to set particle    
           theA = 0;                               
           theZ = 0;                               
           theS = 0;                               
           break;                                  
         case UnknownParticle:                     
           theA = 0;                               
           theZ = 0;                               
           theS = 0;                               
           INCL_ERROR("Trying to set particle t    
           break;                                  
       }                                           
                                                   
       if( !isResonance() && t!=Composite )        
         setINCLMass();                            
     }                                             
                                                   
     /**                                           
      * Is this a nucleon?                         
      */                                           
     G4bool isNucleon() const {                    
       if(theType == G4INCL::Proton || theType     
     return true;                                  
       else                                        
     return false;                                 
     };                                            
                                                   
     ParticipantType getParticipantType() const    
       return theParticipantType;                  
     }                                             
                                                   
     void setParticipantType(ParticipantType co    
       theParticipantType = p;                     
     }                                             
                                                   
     G4bool isParticipant() const {                
       return (theParticipantType==Participant)    
     }                                             
                                                   
     G4bool isTargetSpectator() const {            
       return (theParticipantType==TargetSpecta    
     }                                             
                                                   
     G4bool isProjectileSpectator() const {        
       return (theParticipantType==ProjectileSp    
     }                                             
                                                   
     virtual void makeParticipant() {              
       theParticipantType = Participant;           
     }                                             
                                                   
     virtual void makeTargetSpectator() {          
       theParticipantType = TargetSpectator;       
     }                                             
                                                   
     virtual void makeProjectileSpectator() {      
       theParticipantType = ProjectileSpectator    
     }                                             
                                                   
     /** \brief Is this a pion? */                 
     G4bool isPion() const { return (theType ==    
                                                   
     /** \brief Is this an eta? */                 
     G4bool isEta() const { return (theType ==     
                                                   
     /** \brief Is this an omega? */               
     G4bool isOmega() const { return (theType =    
                                                   
     /** \brief Is this an etaprime? */            
     G4bool isEtaPrime() const { return (theTyp    
                                                   
     /** \brief Is this a photon? */               
     G4bool isPhoton() const { return (theType     
                                                   
     /** \brief Is it a resonance? */              
     inline G4bool isResonance() const { return    
                                                   
     /** \brief Is it a Delta? */                  
     inline G4bool isDelta() const {               
       return (theType==DeltaPlusPlus || theTyp    
           theType==DeltaZero || theType==Delta    
                                                   
     /** \brief Is this a Sigma? */                
     G4bool isSigma() const { return (theType =    
                                                   
     /** \brief Is this a Kaon? */                 
     G4bool isKaon() const { return (theType ==    
                                                   
     /** \brief Is this an antiKaon? */            
     G4bool isAntiKaon() const { return (theTyp    
                                                   
     /** \brief Is this a Lambda? */               
     G4bool isLambda() const { return (theType     
                                                   
     /** \brief Is this a Nucleon or a Lambda?     
     G4bool isNucleonorLambda() const { return     
                                                   
     /** \brief Is this an Hyperon? */             
     G4bool isHyperon() const { return (isLambd    
                                                   
     /** \brief Is this a Meson? */                
     G4bool isMeson() const { return (isPion()     
                                                   
     /** \brief Is this a Baryon? */               
     G4bool isBaryon() const { return (isNucleo    
                                                   
     /** \brief Is this a Strange? */              
     G4bool isStrange() const { return (isKaon(    
                                                   
     /** \brief Is this a Xi? */                   
     G4bool isXi() const { return (theType == X    
                                                   
     /** \brief Is this an antinucleon? */         
     G4bool isAntiNucleon() const { return (the    
                                                   
     /** \brief Is this an antiSigma? */           
     G4bool isAntiSigma() const { return (theTy    
                                                   
     /** \brief Is this an antiXi? */              
     G4bool isAntiXi() const { return (theType     
                                                   
     /** \brief Is this an antiLambda? */          
     G4bool isAntiLambda() const { return (theT    
                                                   
     /** \brief Is this an antiHyperon? */         
     G4bool isAntiHyperon() const { return (isA    
                                                   
     /** \brief Is this an antiBaryon? */          
     G4bool isAntiBaryon() const { return (isAn    
                                                   
     /** \brief Is this an antiNucleon or an an    
     G4bool isAntiNucleonorAntiLambda() const {    
                                                   
     /** \brief Returns the baryon number. */      
     G4int getA() const { return theA; }           
                                                   
     /** \brief Returns the charge number. */      
     G4int getZ() const { return theZ; }           
                                                   
     /** \brief Returns the strangeness number.    
     G4int getS() const { return theS; }           
                                                   
     G4double getBeta() const {                    
       const G4double P = theMomentum.mag();       
       return P/theEnergy;                         
     }                                             
                                                   
     /**                                           
      * Returns a three vector we can give to t    
      *                                            
      * In order to go to the particle rest fra    
      * the boost vector by -1.0.                  
      */                                           
     ThreeVector boostVector() const {             
       return theMomentum / theEnergy;             
     }                                             
                                                   
     /**                                           
      * Boost the particle using a boost vector    
      *                                            
      * Example (go to the particle rest frame)    
      * particle->boost(particle->boostVector()    
      */                                           
     void boost(const ThreeVector &aBoostVector    
       const G4double beta2 = aBoostVector.mag2    
       const G4double gamma = 1.0 / std::sqrt(1    
       const G4double bp = theMomentum.dot(aBoo    
       const G4double alpha = (gamma*gamma)/(1.    
                                                   
       theMomentum = theMomentum + aBoostVector    
       theEnergy = gamma * (theEnergy - bp);       
     }                                             
                                                   
     /** \brief Lorentz-contract the particle p    
      *                                            
      * Apply Lorentz contraction to the positi    
      * direction of the boost vector.             
      *                                            
      * \param aBoostVector the boost vector (v    
      * \param refPos the reference position       
      */                                           
     void lorentzContract(const ThreeVector &aB    
       const G4double beta2 = aBoostVector.mag2    
       const G4double gamma = 1.0 / std::sqrt(1    
       const ThreeVector theRelativePosition =     
       const ThreeVector transversePosition = t    
       const ThreeVector longitudinalPosition =    
                                                   
       thePosition = refPos + transversePositio    
     }                                             
                                                   
     /** \brief Get the cached particle mass. *    
     inline G4double getMass() const { return t    
                                                   
     /** \brief Get the INCL particle mass. */     
     inline G4double getINCLMass() const {         
       switch(theType) {                           
         case Proton:                              
         case Neutron:                             
         case PiPlus:                              
         case PiMinus:                             
         case PiZero:                              
         case Lambda:                              
         case SigmaPlus:                           
         case SigmaZero:                           
         case SigmaMinus:                          
         case antiProton:                          
         case XiZero:                              
         case XiMinus:                             
         case antiNeutron:                         
         case antiLambda:                          
         case antiSigmaPlus:                       
         case antiSigmaZero:                       
         case antiSigmaMinus:                      
         case antiXiZero:                          
         case antiXiMinus:                         
         case KPlus:                               
         case KZero:                               
         case KZeroBar:                            
         case KShort:                              
         case KLong:                               
         case KMinus:                              
         case Eta:                                 
         case Omega:                               
         case EtaPrime:                            
         case Photon:                              
           return ParticleTable::getINCLMass(th    
           break;                                  
                                                   
         case DeltaPlusPlus:                       
         case DeltaPlus:                           
         case DeltaZero:                           
         case DeltaMinus:                          
           return theMass;                         
           break;                                  
                                                   
         case Composite:                           
           return ParticleTable::getINCLMass(th    
           break;                                  
                                                   
         default:                                  
           INCL_ERROR("Particle::getINCLMass: U    
           return 0.0;                             
           break;                                  
       }                                           
     }                                             
                                                   
     /** \brief Get the tabulated particle mass    
     inline virtual G4double getTableMass() con    
       switch(theType) {                           
         case Proton:                              
         case Neutron:                             
         case PiPlus:                              
         case PiMinus:                             
         case PiZero:                              
         case Lambda:                              
         case SigmaPlus:                           
         case SigmaZero:                           
         case SigmaMinus:                          
         case antiProton:                          
         case XiZero:                              
         case XiMinus:                             
         case antiNeutron:                         
         case antiLambda:                          
         case antiSigmaPlus:                       
         case antiSigmaZero:                       
         case antiSigmaMinus:                      
         case antiXiZero:                          
         case antiXiMinus:                         
         case KPlus:                               
         case KZero:                               
         case KZeroBar:                            
         case KShort:                              
         case KLong:                               
         case KMinus:                              
         case Eta:                                 
         case Omega:                               
         case EtaPrime:                            
         case Photon:                              
           return ParticleTable::getTablePartic    
           break;                                  
                                                   
         case DeltaPlusPlus:                       
         case DeltaPlus:                           
         case DeltaZero:                           
         case DeltaMinus:                          
           return theMass;                         
           break;                                  
                                                   
         case Composite:                           
           return ParticleTable::getTableMass(t    
           break;                                  
                                                   
         default:                                  
           INCL_ERROR("Particle::getTableMass:     
           return 0.0;                             
           break;                                  
       }                                           
     }                                             
                                                   
     /** \brief Get the real particle mass. */     
     inline G4double getRealMass() const {         
       switch(theType) {                           
         case Proton:                              
         case Neutron:                             
         case PiPlus:                              
         case PiMinus:                             
         case PiZero:                              
         case Lambda:                              
         case SigmaPlus:                           
         case SigmaZero:                           
         case SigmaMinus:                          
         case antiProton:                          
         case XiZero:                              
         case XiMinus:                             
         case antiNeutron:                         
         case antiLambda:                          
         case antiSigmaPlus:                       
         case antiSigmaZero:                       
         case antiSigmaMinus:                      
         case antiXiZero:                          
         case antiXiMinus:                         
         case KPlus:                               
         case KZero:                               
         case KZeroBar:                            
         case KShort:                              
         case KLong:                               
         case KMinus:                              
         case Eta:                                 
         case Omega:                               
         case EtaPrime:                            
         case Photon:                              
           return ParticleTable::getRealMass(th    
           break;                                  
                                                   
         case DeltaPlusPlus:                       
         case DeltaPlus:                           
         case DeltaZero:                           
         case DeltaMinus:                          
           return theMass;                         
           break;                                  
                                                   
         case Composite:                           
           return ParticleTable::getRealMass(th    
           break;                                  
                                                   
         default:                                  
           INCL_ERROR("Particle::getRealMass: U    
           return 0.0;                             
           break;                                  
       }                                           
     }                                             
                                                   
     /// \brief Set the mass of the Particle to    
     void setRealMass() { setMass(getRealMass()    
                                                   
     /// \brief Set the mass of the Particle to    
     void setTableMass() { setMass(getTableMass    
                                                   
     /// \brief Set the mass of the Particle to    
     void setINCLMass() { setMass(getINCLMass()    
                                                   
     /**\brief Computes correction on the emiss    
      *                                            
      * Computes the correction that must be ap    
      * order to obtain the correct Q-value for    
      * nucleus. For absorption, the correction    
      * the value returned by this function.       
      *                                            
      * \param AParent the mass number of the e    
      * \param ZParent the charge number of the    
      * \return the correction                     
      */                                           
     G4double getEmissionQValueCorrection(const    
       const G4int SParent = 0;                    
       const G4int ADaughter = AParent - theA;     
       const G4int ZDaughter = ZParent - theZ;     
       const G4int SDaughter = 0;                  
                                                   
       // Note the minus sign here                 
       G4double theQValue;                         
       if(isCluster())                             
         theQValue = -ParticleTable::getTableQV    
       else {                                      
         const G4double massTableParent = Parti    
         const G4double massTableDaughter = Par    
         const G4double massTableParticle = get    
         theQValue = massTableParent - massTabl    
       }                                           
                                                   
       const G4double massINCLParent = Particle    
       const G4double massINCLDaughter = Partic    
       const G4double massINCLParticle = getINC    
                                                   
       // The rhs corresponds to the INCL Q-val    
       return theQValue - (massINCLParent-massI    
     }                                             
                                                   
     G4double getEmissionPbarQvalueCorrection(c    
       G4int SParent = 0;                          
       G4int SDaughter = 0;                        
       G4int ADaughter = AParent - 1;              
       G4int ZDaughter;                            
       G4bool isProton = Victim;                   
       if(isProton){     //proton is annihilate    
         ZDaughter = ZParent - 1;                  
       }                                           
       else {       //neutron is annihilated       
         ZDaughter = ZParent;                      
       }                                           
                                                   
       G4double theQValue; //same procedure as     
                                                   
       const G4double massTableParent = Particl    
       const G4double massTableDaughter = Parti    
       const G4double massTableParticle = getTa    
       theQValue = massTableParent - massTableD    
                                                   
       const G4double massINCLParent = Particle    
       const G4double massINCLDaughter = Partic    
       const G4double massINCLParticle = getINC    
                                                   
       return theQValue - (massINCLParent-massI    
     }                                             
                                                   
     /**\brief Computes correction on the trans    
      *                                            
      * Computes the correction that must be ap    
      * order to obtain the correct Q-value for    
      * nucleus to another.                        
      *                                            
      * Assumes that the receving nucleus is IN    
      * INCL separation energy.                    
      *                                            
      * \param AFrom the mass number of the don    
      * \param ZFrom the charge number of the d    
      * \param ATo the mass number of the recei    
      * \param ZTo the charge number of the rec    
      * \return the correction                     
      */                                           
     G4double getTransferQValueCorrection(const    
       const G4int SFrom = 0;                      
       const G4int STo = 0;                        
       const G4int AFromDaughter = AFrom - theA    
       const G4int ZFromDaughter = ZFrom - theZ    
       const G4int SFromDaughter = 0;              
       const G4int AToDaughter = ATo + theA;       
       const G4int ZToDaughter = ZTo + theZ;       
       const G4int SToDaughter = 0;                
       const G4double theQValue = ParticleTable    
                                                   
       const G4double massINCLTo = ParticleTabl    
       const G4double massINCLToDaughter = Part    
       /* Note that here we have to use the tab    
        * cannot use theMass, because at this s    
        * still off-shell; and we cannot use ge    
        * violations of global energy conservat    
        */                                         
       const G4double massINCLParticle = getTab    
                                                   
       // The rhs corresponds to the INCL Q-val    
       return theQValue - (massINCLToDaughter-m    
     }                                             
                                                   
     /**\brief Computes correction on the emiss    
      *                                            
      * Computes the correction that must be ap    
      * order to obtain the correct Q-value for    
      * nucleus. For absorption, the correction    
      * the value returned by this function.       
      *                                            
      * \param AParent the mass number of the e    
      * \param ZParent the charge number of the    
      * \param SParent the strangess number of     
      * \return the correction                     
      */                                           
     G4double getEmissionQValueCorrection(const    
       const G4int ADaughter = AParent - theA;     
       const G4int ZDaughter = ZParent - theZ;     
       const G4int SDaughter = SParent - theS;     
                                                   
       // Note the minus sign here                 
       G4double theQValue;                         
       if(isCluster())                             
         theQValue = -ParticleTable::getTableQV    
       else {                                      
         const G4double massTableParent = Parti    
         const G4double massTableDaughter = Par    
         const G4double massTableParticle = get    
         theQValue = massTableParent - massTabl    
       }                                           
                                                   
       const G4double massINCLParent = Particle    
       const G4double massINCLDaughter = Partic    
       const G4double massINCLParticle = getINC    
                                                   
       // The rhs corresponds to the INCL Q-val    
       return theQValue - (massINCLParent-massI    
     }                                             
                                                   
     /**\brief Computes correction on the trans    
      *                                            
      * Computes the correction that must be ap    
      * order to obtain the correct Q-value for    
      * nucleus to another.                        
      *                                            
      * Assumes that the receving nucleus is IN    
      * INCL separation energy.                    
      *                                            
      * \param AFrom the mass number of the don    
      * \param ZFrom the charge number of the d    
      * \param SFrom the strangess number of th    
      * \param ATo the mass number of the recei    
      * \param ZTo the charge number of the rec    
      * \param STo the strangess number of the     
      * \return the correction                     
      */                                           
     G4double getTransferQValueCorrection(const    
       const G4int AFromDaughter = AFrom - theA    
       const G4int ZFromDaughter = ZFrom - theZ    
       const G4int SFromDaughter = SFrom - theS    
       const G4int AToDaughter = ATo + theA;       
       const G4int ZToDaughter = ZTo + theZ;       
       const G4int SToDaughter = STo + theS;       
       const G4double theQValue = ParticleTable    
                                                   
       const G4double massINCLTo = ParticleTabl    
       const G4double massINCLToDaughter = Part    
       /* Note that here we have to use the tab    
        * cannot use theMass, because at this s    
        * still off-shell; and we cannot use ge    
        * violations of global energy conservat    
        */                                         
       const G4double massINCLParticle = getTab    
                                                   
       // The rhs corresponds to the INCL Q-val    
       return theQValue - (massINCLToDaughter-m    
     }                                             
                                                   
                                                   
                                                   
     /** \brief Get the the particle invariant     
      *                                            
      * Uses the relativistic invariant            
      * \f[ m = \sqrt{E^2 - {\vec p}^2}\f]         
      **/                                          
     G4double getInvariantMass() const {           
       const G4double mass = std::pow(theEnergy    
       if(mass < 0.0) {                            
         INCL_ERROR("E*E - p*p is negative." <<    
         return 0.0;                               
       } else {                                    
         return std::sqrt(mass);                   
       }                                           
     };                                            
                                                   
     /// \brief Get the particle kinetic energy    
     inline G4double getKineticEnergy() const {    
                                                   
     /// \brief Get the particle potential ener    
     inline G4double getPotentialEnergy() const    
                                                   
     /// \brief Set the particle potential ener    
     inline void setPotentialEnergy(G4double v)    
                                                   
     /**                                           
      * Get the energy of the particle in MeV.     
      */                                           
     G4double getEnergy() const                    
     {                                             
       return theEnergy;                           
     };                                            
                                                   
     /**                                           
      * Set the mass of the particle in MeV/c^2    
      */                                           
     void setMass(G4double mass)                   
     {                                             
       this->theMass = mass;                       
     }                                             
                                                   
     /**                                           
      * Set the energy of the particle in MeV.     
      */                                           
     void setEnergy(G4double energy)               
     {                                             
       this->theEnergy = energy;                   
     };                                            
                                                   
     /**                                           
      * Get the momentum vector.                   
      */                                           
     const G4INCL::ThreeVector &getMomentum() c    
     {                                             
       return theMomentum;                         
     };                                            
                                                   
     /** Get the angular momentum w.r.t. the or    
     virtual G4INCL::ThreeVector getAngularMome    
     {                                             
       return thePosition.vector(theMomentum);     
     };                                            
                                                   
     /**                                           
      * Set the momentum vector.                   
      */                                           
     virtual void setMomentum(const G4INCL::Thr    
     {                                             
       this->theMomentum = momentum;               
     };                                            
                                                   
     /**                                           
      * Set the position vector.                   
      */                                           
     const G4INCL::ThreeVector &getPosition() c    
     {                                             
       return thePosition;                         
     };                                            
                                                   
     virtual void setPosition(const G4INCL::Thr    
     {                                             
       this->thePosition = position;               
     };                                            
                                                   
     G4double getHelicity() { return theHelicit    
     void setHelicity(G4double h) { theHelicity    
                                                   
     void propagate(G4double step) {               
       thePosition += ((*thePropagationMomentum    
     };                                            
                                                   
     /** \brief Return the number of collisions    
     G4int getNumberOfCollisions() const { retu    
                                                   
     /** \brief Set the number of collisions un    
     void setNumberOfCollisions(G4int n) { nCol    
                                                   
     /** \brief Increment the number of collisi    
     void incrementNumberOfCollisions() { nColl    
                                                   
     /** \brief Return the number of decays und    
     G4int getNumberOfDecays() const { return n    
                                                   
     /** \brief Set the number of decays underg    
     void setNumberOfDecays(G4int n) { nDecays     
                                                   
     /** \brief Increment the number of decays     
     void incrementNumberOfDecays() { nDecays++    
                                                   
     /** \brief Mark the particle as out of its    
      *                                            
      * This flag is used to control pions crea    
      * in delta decay. The pion potential chec    
      * true (necessary in order to correctly e    
      * Nucleus::applyFinalState() method uses     
      * avatars should be generated for the par    
      */                                           
     void setOutOfWell() { outOfWell = true; }     
                                                  
     /// \brief Check if the particle is out o    
     G4bool isOutOfWell() const { return outOf    
                                                  
     void setEmissionTime(G4double t) { emissi    
     G4double getEmissionTime() { return emiss    
                                                  
     /** \brief Transverse component of the po    
     ThreeVector getTransversePosition() const    
       return thePosition - getLongitudinalPos    
     }                                            
                                                  
     /** \brief Longitudinal component of the     
     ThreeVector getLongitudinalPosition() con    
       return *thePropagationMomentum * (thePo    
     }                                            
                                                  
     /** \brief Rescale the momentum to match     
     const ThreeVector &adjustMomentumFromEner    
                                                  
     /** \brief Recompute the energy to match     
     G4double adjustEnergyFromMomentum();         
                                                  
     G4bool isCluster() const {                   
       return (theType == Composite);             
     }                                            
                                                  
     /// \brief Set the frozen particle moment    
     void setFrozenMomentum(const ThreeVector     
                                                  
     /// \brief Set the frozen particle moment    
     void setFrozenEnergy(const G4double energ    
                                                  
     /// \brief Get the frozen particle moment    
     ThreeVector getFrozenMomentum() const { r    
                                                  
     /// \brief Get the frozen particle moment    
     G4double getFrozenEnergy() const { return    
                                                  
     /// \brief Get the propagation velocity o    
     ThreeVector getPropagationVelocity() cons    
                                                  
     /** \brief Freeze particle propagation       
      *                                           
      * Make the particle use theFrozenMomentu    
      * propagation. The normal state can be r    
      * thawPropagation() method.                 
      */                                          
     void freezePropagation() {                   
       thePropagationMomentum = &theFrozenMome    
       thePropagationEnergy = &theFrozenEnergy    
     }                                            
                                                  
     /** \brief Unfreeze particle propagation     
      *                                           
      * Make the particle use theMomentum and     
      * this method to restore the normal prop    
      * freezePropagation() method has been ca    
      */                                          
     void thawPropagation() {                     
       thePropagationMomentum = &theMomentum;     
       thePropagationEnergy = &theEnergy;         
     }                                            
                                                  
     /** \brief Rotate the particle position a    
      *                                           
      * \param angle the rotation angle           
      * \param axis a unit vector representing    
      */                                          
     virtual void rotatePositionAndMomentum(co    
       rotatePosition(angle, axis);               
       rotateMomentum(angle, axis);               
     }                                            
                                                  
     /** \brief Rotate the particle position      
      *                                           
      * \param angle the rotation angle           
      * \param axis a unit vector representing    
      */                                          
     virtual void rotatePosition(const G4doubl    
       thePosition.rotate(angle, axis);           
     }                                            
                                                  
     /** \brief Rotate the particle momentum      
      *                                           
      * \param angle the rotation angle           
      * \param axis a unit vector representing    
      */                                          
     virtual void rotateMomentum(const G4doubl    
       theMomentum.rotate(angle, axis);           
       theFrozenMomentum.rotate(angle, axis);     
     }                                            
                                                  
     std::string print() const {                  
       std::stringstream ss;                      
       ss << "Particle (ID = " << ID << ") typ    
       ss << ParticleTable::getName(theType);     
       ss << '\n'                                 
         << "   energy = " << theEnergy << '\n    
         << "   momentum = "                      
         << theMomentum.print()                   
         << '\n'                                  
         << "   position = "                      
         << thePosition.print()                   
         << '\n';                                 
       return ss.str();                           
     };                                           
                                                  
     std::string dump() const {                   
       std::stringstream ss;                      
       ss << "(particle " << ID << " ";           
       ss << ParticleTable::getName(theType);     
       ss << '\n'                                 
         << thePosition.dump()                    
         << '\n'                                  
         << theMomentum.dump()                    
         << '\n'                                  
         << theEnergy << ")" << '\n';             
       return ss.str();                           
     };                                           
                                                  
     long getID() const { return ID; };           
                                                  
     /**                                          
      * Return a NULL pointer                     
      */                                          
     ParticleList const *getParticles() const     
       INCL_WARN("Particle::getParticles() met    
       return 0;                                  
     }                                            
                                                  
     /** \brief Return the reflection momentum    
      *                                           
      * The reflection momentum is used by cal    
      * the radius of the sphere where the nuc    
      * introduce fuzzy r-p correlations.         
      */                                          
     G4double getReflectionMomentum() const {     
       if(rpCorrelated)                           
         return theMomentum.mag();                
       else                                       
         return uncorrelatedMomentum;             
     }                                            
                                                  
     /// \brief Set the uncorrelated momentum     
     void setUncorrelatedMomentum(const G4doub    
                                                  
     /// \brief Make the particle follow a str    
     void rpCorrelate() { rpCorrelated = true;    
                                                  
     /// \brief Make the particle not follow a    
     void rpDecorrelate() { rpCorrelated = fal    
                                                  
     /// \brief Get the cosine of the angle be    
     G4double getCosRPAngle() const {             
       const G4double norm = thePosition.mag2(    
       if(norm>0.)                                
         return thePosition.dot(*thePropagatio    
       else                                       
         return 1.;                               
     }                                            
                                                  
     /// \brief General bias vector function      
     static G4double getTotalBias();              
     static void setINCLBiasVector(std::vector    
     static void FillINCLBiasVector(G4double n    
     static G4double getBiasFromVector(std::ve    
                                                  
     static std::vector<G4int> MergeVectorBias    
     static std::vector<G4int> MergeVectorBias    
                                                  
     /// \brief Get the particle bias.            
     G4double getParticleBias() const { return    
                                                  
     /// \brief Set the particle bias.            
     void setParticleBias(G4double ParticleBia    
                                                  
     /// \brief Get the vector list of biased     
     std::vector<G4int> getBiasCollisionVector    
                                                  
     /// \brief Set the vector list of biased     
     void setBiasCollisionVector(std::vector<G    
     this->theBiasCollisionVector = BiasCollis    
     this->setParticleBias(Particle::getBiasFr    
     }                                            
                                                  
     /** \brief Number of Kaon inside de nucle    
      *                                           
      * Put in the Particle class in order to     
      * "correct" mass of composit particle.      
      *                                           
      */                                          
                                                  
     G4int getNumberOfKaon() const { return th    
     void setNumberOfKaon(const G4int NK) { th    
                                                  
 #ifdef INCLXX_IN_GEANT4_MODE                     
     G4int getParentResonancePDGCode() const {    
     void setParentResonancePDGCode(const G4in    
     G4int getParentResonanceID() const { retu    
     void setParentResonanceID(const G4int par    
 #endif                                           
                                                  
   public:                                        
     /** \brief Time ordered vector of all bia    
      *                                           
      * /!\ Caution /!\                           
      * methods Assotiated to G4VectorCache<T>    
      * Push_back(…),                           
      * operator[],                               
      * Begin(),                                  
      * End(),                                    
      * Clear(),                                  
      * Size() and                                
      * Pop_back()                                
      *                                           
      */                                          
 #ifdef INCLXX_IN_GEANT4_MODE                     
       static std::vector<G4double> INCLBiasVe    
       //static G4VectorCache<G4double> INCLBi    
 #else                                            
       static G4ThreadLocal std::vector<G4doub    
       //static G4VectorCache<G4double> INCLBi    
 #endif                                           
     static G4ThreadLocal G4int nextBiasedColl    
                                                  
   protected:                                     
     G4int theZ, theA, theS;                      
     ParticipantType theParticipantType;          
     G4INCL::ParticleType theType;                
     G4double theEnergy;                          
     G4double *thePropagationEnergy;              
     G4double theFrozenEnergy;                    
     G4INCL::ThreeVector theMomentum;             
     G4INCL::ThreeVector *thePropagationMoment    
     G4INCL::ThreeVector theFrozenMomentum;       
     G4INCL::ThreeVector thePosition;             
     G4int nCollisions;                           
     G4int nDecays;                               
     G4double thePotentialEnergy;                 
     long ID;                                     
                                                  
     G4bool rpCorrelated;                         
     G4double uncorrelatedMomentum;               
                                                  
     G4double theParticleBias;                    
     /// \brief The number of Kaons inside the    
     G4int theNKaon;                              
                                                  
 #ifdef INCLXX_IN_GEANT4_MODE                     
     G4int theParentResonancePDGCode;             
     G4int theParentResonanceID;                  
 #endif                                           
                                                  
   private:                                       
     G4double theHelicity;                        
     G4double emissionTime;                       
     G4bool outOfWell;                            
                                                  
     /// \brief Time ordered vector of all bia    
     std::vector<G4int> theBiasCollisionVector    
                                                  
     G4double theMass;                            
     static G4ThreadLocal long nextID;            
                                                  
     INCL_DECLARE_ALLOCATION_POOL(Particle)       
   };                                             
 }                                                
                                                  
 #endif /* PARTICLE_HH_ */