source: trunk/examples/advanced/hadrontherapy/src/HadrontherapySteppingAction.cc@ 1305

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// HadrontherapyProtonSteppingAction.cc; 
// See more at: http://g4advancedexamples.lngs.infn.it/Examples/hadrontherapy

#include "G4SteppingManager.hh"
#include "G4TrackVector.hh"
#include "HadrontherapySteppingAction.hh"
#include "G4ios.hh"
#include "G4SteppingManager.hh"
#include "G4Track.hh"
#include "G4Step.hh"
#include "G4StepPoint.hh"
#include "G4TrackStatus.hh"
#include "G4TrackVector.hh"
#include "G4ParticleDefinition.hh"
#include "G4ParticleTypes.hh"

#include "HadrontherapyAnalysisManager.hh"

#include "HadrontherapyRunAction.hh"

/////////////////////////////////////////////////////////////////////////////
HadrontherapySteppingAction::HadrontherapySteppingAction( HadrontherapyRunAction *run)
{
  runAction = run;
}

/////////////////////////////////////////////////////////////////////////////
HadrontherapySteppingAction::~HadrontherapySteppingAction()
{
}

/////////////////////////////////////////////////////////////////////////////
void HadrontherapySteppingAction::UserSteppingAction(const G4Step* aStep)
{ 
    if( aStep->GetTrack()->GetVolume()->GetName() == "NewDetectorPhys"){
#ifdef ANALYSIS_USE
      G4ParticleDefinition *def = aStep->GetTrack()->GetDefinition();
      G4double secondaryParticleKineticEnergy =  aStep->GetTrack()->GetKineticEnergy();     
      G4String particleType = def->GetParticleType(); // particle type = nucleus for d, t, He3, alpha, and heavier nuclei
      G4String particleName = def->GetParticleName(); // e.g. for alpha: the name = "alpha" and type = "nucleus"
      if(particleType == "nucleus") {
        G4int A = def->GetBaryonNumber();
        G4double Z = def->GetPDGCharge();
        G4double posX = aStep->GetTrack()->GetPosition().x() / cm;
        G4double posY = aStep->GetTrack()->GetPosition().y() / cm;
        G4double posZ = aStep->GetTrack()->GetPosition().z() / cm;
        G4double energy = secondaryParticleKineticEnergy / A / MeV;

        HadrontherapyAnalysisManager* analysisMgr =  HadrontherapyAnalysisManager::getInstance();   
        analysisMgr->fillFragmentTuple(A, Z, energy, posX, posY, posZ);
      } else if(particleName == "proton") {   // proton (hydrogen-1) is a special case
        G4double posX = aStep->GetTrack()->GetPosition().x() / cm ;
        G4double posY = aStep->GetTrack()->GetPosition().y() / cm ;
        G4double posZ = aStep->GetTrack()->GetPosition().z() / cm ;
        G4double energy = secondaryParticleKineticEnergy * MeV;    // Hydrogen-1: A = 1, Z = 1
        HadrontherapyAnalysisManager::getInstance()->fillFragmentTuple(1, 1.0, energy, posX, posY, posZ);
      }

      G4String secondaryParticleName =  def -> GetParticleName();  
      //G4cout <<"Particle: " << secondaryParticleName << G4endl;
      //G4cout <<"Energy: " << secondaryParticleKineticEnergy << G4endl;
        HadrontherapyAnalysisManager* analysis =  HadrontherapyAnalysisManager::getInstance();   
        //There is a bunch of stuff recorded with the energy 0, something should perhaps be done about this.
        if(secondaryParticleName == "proton") {
          analysis->hydrogenEnergy(secondaryParticleKineticEnergy / MeV);
        }
        if(secondaryParticleName == "deuteron") {
          analysis->hydrogenEnergy((secondaryParticleKineticEnergy/2) / MeV);
        }
        if(secondaryParticleName == "triton") {
          analysis->hydrogenEnergy((secondaryParticleKineticEnergy/3) / MeV);
        }
        if(secondaryParticleName == "alpha") {
          analysis->heliumEnergy((secondaryParticleKineticEnergy/4) / MeV);
        }
        if(secondaryParticleName == "He3"){
          analysis->heliumEnergy((secondaryParticleKineticEnergy/3) / MeV);             
        }
#endif

        aStep->GetTrack()->SetTrackStatus(fKillTrackAndSecondaries);
    }

  // Electromagnetic and hadronic processes of primary particles in the phantom
  //setting phantomPhys correctly will break something here fixme
  if ((aStep -> GetTrack() -> GetTrackID() == 1) &&
    (aStep -> GetTrack() -> GetVolume() -> GetName() == "PhantomPhys") &&
    (aStep -> GetPostStepPoint() -> GetProcessDefinedStep() != NULL))
            {
              G4String process = aStep -> GetPostStepPoint() -> 
                GetProcessDefinedStep() -> GetProcessName();
 
              if ((process == "Transportation") || (process == "StepLimiter")) {;}
              else {
                if ((process == "msc") || (process == "hLowEIoni") || (process == "hIoni")) 
                  { 
                    runAction -> AddEMProcess();
                  } 
                else  
                 {
                   runAction -> AddHadronicProcess();

                   if ( (process != "LElastic") && (process != "ProtonInelastic") && (process != "hElastic") )
                     G4cout << "Warning! Unknown proton process: "<< process << G4endl;
                 }
              }         
            }

 // Retrieve information about the secondaries originated in the phantom

 G4SteppingManager*  steppingManager = fpSteppingManager;
  
  // check if it is alive
  //if(theTrack-> GetTrackStatus() == fAlive) { return; }

  // Retrieve the secondary particles
  G4TrackVector* fSecondary = steppingManager -> GetfSecondary();
     
  for(size_t lp1=0;lp1<(*fSecondary).size(); lp1++)
    { 
      G4String volumeName = (*fSecondary)[lp1] -> GetVolume() -> GetName(); 
 
      if (volumeName == "phantomPhys")
        {
#ifdef ANALYSIS_USE   
          G4String secondaryParticleName =  (*fSecondary)[lp1]->GetDefinition() -> GetParticleName();  
          G4double secondaryParticleKineticEnergy =  (*fSecondary)[lp1] -> GetKineticEnergy();     

          HadrontherapyAnalysisManager* analysis =  HadrontherapyAnalysisManager::getInstance();   
        
          if (secondaryParticleName == "e-")
            analysis -> electronEnergyDistribution(secondaryParticleKineticEnergy/MeV);
                    
          if (secondaryParticleName == "gamma")
            analysis -> gammaEnergyDistribution(secondaryParticleKineticEnergy/MeV);

          if (secondaryParticleName == "deuteron")
            analysis -> deuteronEnergyDistribution(secondaryParticleKineticEnergy/MeV);
       
          if (secondaryParticleName == "triton")
            analysis -> tritonEnergyDistribution(secondaryParticleKineticEnergy/MeV);
           
          if (secondaryParticleName == "alpha")
            analysis -> alphaEnergyDistribution(secondaryParticleKineticEnergy/MeV);
        
          G4double z = (*fSecondary)[lp1]-> GetDynamicParticle() -> GetDefinition() -> GetPDGCharge();
          if (z > 0.)
            {      
              G4int a = (*fSecondary)[lp1]-> GetDynamicParticle() -> GetDefinition() -> GetBaryonNumber();
              G4int electronOccupancy = (*fSecondary)[lp1] ->  GetDynamicParticle() -> GetTotalOccupancy(); 
              
              // If a generic ion is originated in the detector, its baryonic number, PDG charge, 
              // total number of electrons in the orbitals are stored in a ntuple 
              analysis -> genericIonInformation(a, z, electronOccupancy, secondaryParticleKineticEnergy/MeV);
            }
#endif
        }
    }
}