G4VPreCompoundFragment.icc

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//
//
// by V. Lara
//
// Modif (03 September 2008) by J. M. Quesada for external choice of inverse 
// cross section option 
// JMQ (06 September 2008) Also external choice has been added for:
//                      - superimposed Coulomb barrier (if useSICB=true) 
// 23.08.2010 V.Ivanchenko general cleanup, move constructor and destructor 
//            the source, make GetReactionProduct() and IsItPossible inlined
 
inline G4bool G4VPreCompoundFragment::
IsItPossible(const G4Fragment & aFragment) const
{
  G4int pplus = aFragment.GetNumberOfCharged();
  G4int pneut = aFragment.GetNumberOfParticles()-pplus;
  return ((pneut >= theA - theZ) && (pplus >= theZ) && (theMaxKinEnergy > 0));
}
 
inline 
G4ReactionProduct * G4VPreCompoundFragment::GetReactionProduct() const
{
  G4ReactionProduct * theReactionProduct =
    new G4ReactionProduct(particle);
  theReactionProduct->SetMomentum(GetMomentum().vect());
  theReactionProduct->SetTotalEnergy(GetMomentum().e());
  return theReactionProduct;
}
 
inline G4int G4VPreCompoundFragment::GetA() const 
{ 
  return theA;
}
 
inline G4int G4VPreCompoundFragment::GetZ() const 
{ 
  return theZ;
}
 
inline G4int G4VPreCompoundFragment::GetRestA() const 
{ 
  return theResA;
}
    
inline G4int G4VPreCompoundFragment::GetRestZ() const 
{ 
  return theResZ;
}
    
inline G4double G4VPreCompoundFragment::GetBindingEnergy() const 
{
  return theBindingEnergy;
}
 
inline G4double G4VPreCompoundFragment::GetEnergyThreshold() const 
{ 
  return theMaxKinEnergy - theCoulombBarrier;
}
    
inline G4double G4VPreCompoundFragment::GetEmissionProbability() const 
{ 
  return theEmissionProbability;
}
 
inline G4double G4VPreCompoundFragment::GetNuclearMass(void) const 
{
  return theMass;
}
 
inline G4double G4VPreCompoundFragment::GetRestNuclearMass() const 
{
  return theResMass;
}
 
inline 
const G4LorentzVector& G4VPreCompoundFragment::GetMomentum() const 
{ 
  return theMomentum;
}
    
inline 
void G4VPreCompoundFragment::SetMomentum(const G4LorentzVector & value) 
{ 
  theMomentum = value;
}
 
inline void G4VPreCompoundFragment::SetOPTxs(G4int opt)
{
  OPTxs=opt;
}
 
inline void G4VPreCompoundFragment::UseSICB(G4bool use)
{
  useSICB=use;
}