d2/d2e/FullModelHadronicProcess_8cc_source.html

 #include "G4HadReentrentException.hh"
 #include "G4ProcessManager.hh"
 #include "G4ParticleTable.hh"

 #include "SimG4Core/CustomPhysics/interface/FullModelHadronicProcess.h"
 #include "SimG4Core/CustomPhysics/interface/G4ProcessHelper.h"
 #include "SimG4Core/CustomPhysics/interface/Decay3Body.h"
 #include "SimG4Core/CustomPhysics/interface/CustomPDGParser.h"
 #include "SimG4Core/CustomPhysics/interface/CustomParticle.h"

 using namespace CLHEP;

 FullModelHadronicProcess::FullModelHadronicProcess(G4ProcessHelper* aHelper, const G4String& processName)
     : G4VDiscreteProcess(processName), theHelper(aHelper) {}

 FullModelHadronicProcess::~FullModelHadronicProcess() {}

 G4bool FullModelHadronicProcess::IsApplicable(const G4ParticleDefinition& aP) {
   return theHelper->ApplicabilityTester(aP);
 }

 G4double FullModelHadronicProcess::GetMicroscopicCrossSection(const G4DynamicParticle* aParticle,
                                                               const G4Element* anElement,
                                                               G4double aTemp) {
   //Get the cross section for this particle/element combination from the ProcessHelper
   G4double InclXsec = theHelper->GetInclusiveCrossSection(aParticle, anElement);
   //  G4cout<<"Returned cross section from helper was: "<<InclXsec/millibarn<<" millibarn"<<G4endl;
   return InclXsec;
 }

 G4double FullModelHadronicProcess::GetMeanFreePath(const G4Track& aTrack, G4double, G4ForceCondition*) {
   G4Material* aMaterial = aTrack.GetMaterial();
   const G4DynamicParticle* aParticle = aTrack.GetDynamicParticle();
   G4double sigma = 0.0;

   G4int nElements = aMaterial->GetNumberOfElements();

   const G4double* theAtomicNumDensityVector = aMaterial->GetAtomicNumDensityVector();
   G4double aTemp = aMaterial->GetTemperature();

   for (G4int i = 0; i < nElements; ++i) {
     G4double xSection = GetMicroscopicCrossSection(aParticle, (*aMaterial->GetElementVector())[i], aTemp);
     sigma += theAtomicNumDensityVector[i] * xSection;
   }
   G4double res = DBL_MAX;
   if (sigma > 0.0) {
     res = 1. / sigma;
   }
   return res;
 }

 G4VParticleChange* FullModelHadronicProcess::PostStepDoIt(const G4Track& aTrack, const G4Step& aStep) {
   //  G4cout<<"**** Entering FullModelHadronicProcess::PostStepDoIt       ******"<<G4endl;
   const G4TouchableHandle& thisTouchable(aTrack.GetTouchableHandle());

   // A little setting up
   aParticleChange.Initialize(aTrack);
   const G4DynamicParticle* IncidentRhadron = aTrack.GetDynamicParticle();
   CustomParticle* CustomIncident = static_cast<CustomParticle*>(IncidentRhadron->GetDefinition());
   const G4ThreeVector& aPosition = aTrack.GetPosition();
   //  G4cout<<"G: "<<aStep.GetStepLength()/cm<<G4endl;
   const G4int theIncidentPDG = IncidentRhadron->GetDefinition()->GetPDGEncoding();
   G4ParticleTable* theParticleTable = G4ParticleTable::GetParticleTable();
   std::vector<G4ParticleDefinition*> theParticleDefinitions;
   G4bool IncidentSurvives = false;
   G4bool TargetSurvives = false;
   G4Nucleus targetNucleus(aTrack.GetMaterial());
   G4ParticleDefinition* outgoingRhadron = nullptr;
   G4ParticleDefinition* outgoingCloud = nullptr;
   G4ParticleDefinition* outgoingTarget = nullptr;

   G4ThreeVector p_0 = IncidentRhadron->GetMomentum();
   G4double e_kin_0 = IncidentRhadron->GetKineticEnergy();
   //  G4cout<<e_kin_0/GeV<<G4endl;

   G4DynamicParticle* cloudParticle = new G4DynamicParticle();
   /*
   if(CustomPDGParser::s_isRMeson(theIncidentPDG))
     G4cout<<"Rmeson"<<G4endl;
   if(CustomPDGParser::s_isRBaryon(theIncidentPDG))
     G4cout<<"Rbaryon"<<G4endl;
   */
   cloudParticle->SetDefinition(CustomIncident->GetCloud());

   if (cloudParticle->GetDefinition() == nullptr) {
     G4cout << "FullModelHadronicProcess::PostStepDoIt  Definition of particle cloud not available!!" << G4endl;
   }
   /*
   G4cout<<"Incoming particle was "<<IncidentRhadron->GetDefinition()->GetParticleName()
   <<". Corresponding cloud is "<<cloudParticle->GetDefinition()->GetParticleName()<<G4endl;
   G4cout<<"Kinetic energy was: "<<IncidentRhadron->GetKineticEnergy()/GeV<<" GeV"<<G4endl;
   */
   double scale = cloudParticle->GetDefinition()->GetPDGMass() / IncidentRhadron->GetDefinition()->GetPDGMass();
   //  G4cout<<"Mass ratio: "<<scale<<G4endl;
   G4LorentzVector cloudMomentum(IncidentRhadron->GetMomentum() * scale, cloudParticle->GetDefinition()->GetPDGMass());
   G4LorentzVector gluinoMomentum(IncidentRhadron->GetMomentum() * (1. - scale),
                                  CustomIncident->GetSpectator()->GetPDGMass());

   //These two for getting CMS transforms later (histogramming purposes...)
   G4LorentzVector FullRhadron4Momentum = IncidentRhadron->Get4Momentum();
   const G4LorentzVector& Cloud4Momentum = cloudMomentum;

   cloudParticle->Set4Momentum(cloudMomentum);

   G4DynamicParticle* OrgPart = cloudParticle;

   /*
   G4cout<<"Original momentum: "<<IncidentRhadron->Get4Momentum().v().mag()/GeV
   <<" GeV, corresponding to gamma: "
   <<IncidentRhadron->GetTotalEnergy()/IncidentRhadron->GetDefinition()->GetPDGMass()<<G4endl;

   G4cout<<"Cloud momentum: "<<cloudParticle->Get4Momentum().v().mag()/GeV
   <<" GeV, corresponding to gamma: "
   <<cloudParticle->GetTotalEnergy()/cloudParticle->GetDefinition()->GetPDGMass()<<G4endl;
   */

   double E_0 = IncidentRhadron->GetKineticEnergy();
   G4double ek = OrgPart->GetKineticEnergy();
   G4double amas = OrgPart->GetDefinition()->GetPDGMass();
   G4ThreeVector dir = (OrgPart->GetMomentum()).unit();
   G4double tkin = targetNucleus.Cinema(ek);
   ek += tkin;

   // calculate black track energies
   tkin = targetNucleus.EvaporationEffects(ek);
   ek -= tkin;

   if (ek + gluinoMomentum.e() - gluinoMomentum.m() <= 0.1 * MeV || ek <= 0.) {
     //Very rare event...
     G4cout << "Kinetic energy is sick" << G4endl;
     G4cout << "Full R-hadron: " << (ek + gluinoMomentum.e() - gluinoMomentum.m()) / MeV << " MeV" << G4endl;
     G4cout << "Quark system: " << ek / MeV << " MeV" << G4endl;
     aParticleChange.ProposeTrackStatus(fStopButAlive);  // AR_NEWCODE_IMPORT
     return &aParticleChange;
   }
   OrgPart->SetKineticEnergy(ek);
   G4double p = std::sqrt(ek * (ek + 2 * amas));
   OrgPart->SetMomentum(dir * p);

   //Get the final state particles
   G4ParticleDefinition* aTarget;
   ReactionProduct rp = theHelper->GetFinalState(aTrack, aTarget);
   G4bool force2to2 = false;
   //  G4cout<<"Trying to get final state..."<<G4endl;
   while (rp.size() != 2 && force2to2) {
     rp = theHelper->GetFinalState(aTrack, aTarget);
   }
   G4int NumberOfSecondaries = rp.size();
   //  G4cout<<"Multiplicity of selected final state: "<<rp.size()<<G4endl;

   //Getting CMS transforms. Boosting is done at histogram filling
   G4LorentzVector Target4Momentum(0., 0., 0., aTarget->GetPDGMass());

   G4LorentzVector psum_full = FullRhadron4Momentum + Target4Momentum;
   G4LorentzVector psum_cloud = Cloud4Momentum + Target4Momentum;
   G4ThreeVector trafo_full_cms = (-1) * psum_full.boostVector();
   G4ThreeVector trafo_cloud_cms = (-1) * psum_cloud.boostVector();

   // OK Let's make some particles :-)
   // We're not using them for anything yet, I know, but let's make sure the machinery is there
   for (ReactionProduct::iterator it = rp.begin(); it != rp.end(); ++it) {
     G4ParticleDefinition* tempDef = theParticleTable->FindParticle(*it);
     CustomParticle* tempCust = dynamic_cast<CustomParticle*>(tempDef);
     if (tempDef == aTarget)
       TargetSurvives = true;

     //      if (tempDef->GetParticleType()=="rhadron")
     if (tempCust != nullptr) {
       outgoingRhadron = tempDef;
       //Setting outgoing cloud definition
       outgoingCloud = tempCust->GetCloud();
       if (outgoingCloud == nullptr) {
         G4cout << "FullModelHadronicProcess::PostStepDoIt  Definition of outgoing particle cloud not available!"
                << G4endl;
       }
       /*
     G4cout<<"Outgoing Rhadron is: "<<outgoingRhadron->GetParticleName()<<G4endl;
     G4cout<<"Outgoing cloud is: "<<outgoingCloud->GetParticleName()<<G4endl;
       */
     }

     if (tempDef == G4Proton::Proton() || tempDef == G4Neutron::Neutron())
       outgoingTarget = tempDef;
     if (tempCust == nullptr && rp.size() == 2)
       outgoingTarget = tempDef;
     if (tempDef->GetPDGEncoding() == theIncidentPDG) {
       IncidentSurvives = true;
     } else {
       theParticleDefinitions.push_back(tempDef);
     }
   }

   if (outgoingTarget == nullptr)
     outgoingTarget = theParticleTable->FindParticle(rp[1]);

   // A little debug information
   /*
   G4cout<<"The particles coming out of this reaction will be: ";
   for (std::vector<G4DynamicParticle*>::iterator it = theDynamicParticles.begin();
        it != theDynamicParticles.end();
        it++){
     G4cout<< (*it)->GetDefinition()->GetParticleName()<<" ";
   }
   G4cout<<G4endl;
   */
   // If the incident particle survives it is not a "secondary", although
   // it would probably be easier to fStopAndKill the track every time.
   if (IncidentSurvives)
     NumberOfSecondaries--;
   aParticleChange.SetNumberOfSecondaries(NumberOfSecondaries);

   // ADAPTED FROM G4LEPionMinusInelastic::ApplyYourself
   // It is bloody ugly, but such is the way of cut 'n' paste

   // Set up the incident
   // This is where rotation to z-axis is done
   const G4HadProjectile* originalIncident = new G4HadProjectile(*OrgPart);

   //Maybe I need to calculate trafo from R-hadron... Bollocks! Labframe does not move. CMS does.
   G4HadProjectile* org2 = new G4HadProjectile(*OrgPart);
   G4LorentzRotation trans = org2->GetTrafoToLab();
   delete org2;

   // create the target particle

   G4DynamicParticle* originalTarget = new G4DynamicParticle;
   originalTarget->SetDefinition(aTarget);

   G4ReactionProduct targetParticle(aTarget);

   G4ReactionProduct currentParticle(const_cast<G4ParticleDefinition*>(originalIncident->GetDefinition()));
   currentParticle.SetMomentum(originalIncident->Get4Momentum().vect());
   currentParticle.SetKineticEnergy(originalIncident->GetKineticEnergy());

   /*
   G4cout<<"After creation:"<<G4endl;
   G4cout<<"currentParticle: "<<currentParticle.GetMomentum()/GeV<<" GeV vs. "<<OrgPart->Get4Momentum()/GeV<<" GeV"<<G4endl;
   G4cout<<"targetParticle: "<<targetParticle.GetMomentum()/GeV<<" GeV"<<G4endl;
   G4cout<<"Fourmomentum from originalIncident: "<<originalIncident->Get4Momentum()<<" vs "<<OrgPart->Get4Momentum()<<G4endl;
   */

   G4ReactionProduct modifiedOriginal = currentParticle;

   currentParticle.SetSide(1);  // incident always goes in forward hemisphere
   targetParticle.SetSide(-1);  // target always goes in backward hemisphere
   G4bool incidentHasChanged = false;
   if (!IncidentSurvives)
     incidentHasChanged = true;  //I wonder if I am supposed to do this...
   G4bool targetHasChanged = false;
   if (!TargetSurvives)
     targetHasChanged = true;  //Ditto here
   G4bool quasiElastic = false;
   if (rp.size() == 2)
     quasiElastic = true;                                //Oh well...
   G4FastVector<G4ReactionProduct, MYGHADLISTSIZE> vec;  // vec will contain the secondary particles
   G4int vecLen = 0;
   vec.Initialize(0);

   // I hope my understanding of "secondary" is correct here
   // I think that it entails only what is not a surviving incident of target

   for (G4int i = 0; i != NumberOfSecondaries; i++) {
     if (theParticleDefinitions[i] != aTarget && theParticleDefinitions[i] != originalIncident->GetDefinition() &&
         theParticleDefinitions[i] != outgoingRhadron && theParticleDefinitions[i] != outgoingTarget) {
       G4ReactionProduct* pa = new G4ReactionProduct;
       pa->SetDefinition(theParticleDefinitions[i]);
       (G4UniformRand() < 0.5) ? pa->SetSide(-1) : pa->SetSide(1);
       vec.SetElement(vecLen++, pa);
     }
   }

   if (incidentHasChanged)
     currentParticle.SetDefinitionAndUpdateE(outgoingCloud);
   if (incidentHasChanged)
     modifiedOriginal.SetDefinition(
         outgoingCloud);  //Is this correct? It solves the "free energy" checking in ReactionDynamics
   if (targetHasChanged)
     targetParticle.SetDefinitionAndUpdateE(outgoingTarget);

   //  G4cout<<"Calling CalculateMomenta... "<<G4endl;
   /*
   G4cout<<"Current particle starts as: "<<currentParticle.GetDefinition()->GetParticleName()<<G4endl;
   G4cout<<"with momentum: "<<currentParticle.GetMomentum()/GeV<<" GeV"<<G4endl;
   G4cout<<"May be killed?: "<<currentParticle.GetMayBeKilled()<<G4endl;
   */

   CalculateMomenta(vec,
                    vecLen,
                    originalIncident,
                    originalTarget,
                    modifiedOriginal,
                    targetNucleus,
                    currentParticle,
                    targetParticle,
                    incidentHasChanged,
                    targetHasChanged,
                    quasiElastic);

   //  G4cout <<"Cloud loss: "<<(e_temp-currentParticle.GetKineticEnergy())/GeV<<" GeV"<<G4endl;

   G4String cPname = currentParticle.GetDefinition()->GetParticleName();

   //  if(cPname!="rhadronmesoncloud"&&cPname!="rhadronbaryoncloud")
   //    {
   /*
   G4cout<<"Current particle is now: "<<cPname <<G4endl;
   G4cout<<"with momentum: "<<currentParticle.GetMomentum()/GeV<<" GeV"<<G4endl;
   G4cout<<"and kinetic energy: "<<currentParticle.GetKineticEnergy()/GeV<<" GeV"<<G4endl;
   G4cout<<"May be killed?: "<<currentParticle.GetMayBeKilled()<<G4endl;
   G4cout<<"Modified original is: "<<modifiedOriginal.GetDefinition()->GetParticleName()<<G4endl;
   G4cout<<"with momentum: "<<modifiedOriginal.GetMomentum()/GeV<<" GeV"<<G4endl;
   G4cout<<"and kinetic energy: "<<modifiedOriginal.GetKineticEnergy()/GeV<<" GeV"<<G4endl;
   G4cout<<"May be killed?: "<<modifiedOriginal.GetMayBeKilled()<<G4endl;
   G4cout<<"Target particle is: "<<targetParticle.GetDefinition()->GetParticleName()<<G4endl;
   G4cout<<"with momentum: "<<targetParticle.GetMomentum()/GeV<<" GeV"<<G4endl;
   G4cout<<"and kinetic energy: "<<targetParticle.GetKineticEnergy()/GeV<<" GeV"<<G4endl;
   G4cout<<"May be killed?: "<<targetParticle.GetMayBeKilled()<<G4endl;
   G4cout<<"incidentHasChanged: "<<incidentHasChanged<<G4endl;
   G4cout<<"targetHasChanged: "<<targetHasChanged<<G4endl;
   G4cout<<"Particles in vec:"<<G4endl;
   for(int i=0; i<vecLen; ++i )
     {
       G4cout<< vec[i]->GetDefinition()->GetParticleName()<<G4endl;
     }
   */
   // G4cout<<"Done!"<<G4endl;

   aParticleChange.SetNumberOfSecondaries(vecLen + NumberOfSecondaries);
   G4double e_kin = 0;
   G4LorentzVector cloud_p4_new;  //Cloud 4-momentum in lab after collision
   //  n++;
   //  G4cout << n << G4endl;
   /*
   if(cPname!="rhadronmesoncloud"&&cPname!="rhadronbaryoncloud") {
     G4cout<<"Cloud deleted!!! AAARRRRGGGHHH!!!"<<G4endl;
     G4cout<<"Cloud name: "<<cPname<<G4endl;
     G4cout<<"E_kin_0: "<<e_kin_0/GeV<<" GeV"<<G4endl;
     //    G4cout<<"n: "<<n<<G4endl;
     //    n=0;
   }
   */
   cloud_p4_new.setVectM(currentParticle.GetMomentum(), currentParticle.GetMass());
   cloud_p4_new *= trans;

   G4LorentzVector cloud_p4_old_full = Cloud4Momentum;  //quark system in CMS BEFORE collision
   cloud_p4_old_full.boost(trafo_full_cms);
   G4LorentzVector cloud_p4_old_cloud = Cloud4Momentum;  //quark system in cloud CMS BEFORE collision
   cloud_p4_old_cloud.boost(trafo_cloud_cms);
   G4LorentzVector cloud_p4_full = cloud_p4_new;  //quark system in CMS AFTER collision
   cloud_p4_full.boost(trafo_full_cms);
   G4LorentzVector cloud_p4_cloud = cloud_p4_new;  //quark system in cloud CMS AFTER collision
   cloud_p4_cloud.boost(trafo_cloud_cms);

   G4LorentzVector p_g_cms = gluinoMomentum;  //gluino in CMS BEFORE collision
   p_g_cms.boost(trafo_full_cms);

   double e = cloud_p4_new.e() + gluinoMomentum.e();
   if (outgoingRhadron)
     e += outgoingRhadron->GetPDGMass();
   G4LorentzVector p4_new(cloud_p4_new.v() + gluinoMomentum.v(), e);
   //  G4cout<<"P4-diff: "<<(p4_new-cloud_p4_new-gluinoMomentum)/GeV<<", magnitude: "
   // <<(p4_new-cloud_p4_new-gluinoMomentum).m()/MeV<<" MeV" <<G4endl;

   G4ThreeVector p_new = p4_new.vect();

   aParticleChange.ProposeLocalEnergyDeposit((p4_new - cloud_p4_new - gluinoMomentum).m());

   if (incidentHasChanged) {
     G4DynamicParticle* p0 = new G4DynamicParticle;
     p0->SetDefinition(outgoingRhadron);
     p0->SetMomentum(p_new);

     // May need to run SetDefinitionAndUpdateE here...
     G4Track* Track0 = new G4Track(p0, aTrack.GetGlobalTime(), aPosition);
     Track0->SetTouchableHandle(thisTouchable);
     aParticleChange.AddSecondary(Track0);
     /*
       G4cout<<"Adding a particle "<<p0->GetDefinition()->GetParticleName()<<G4endl;
       G4cout<<"with momentum: "<<p0->GetMomentum()/GeV<<" GeV"<<G4endl;
       G4cout<<"and kinetic energy: "<<p0->GetKineticEnergy()/GeV<<" GeV"<<G4endl;
       */
     if (p0->GetKineticEnergy() > e_kin_0) {
       G4cout << "ALAAAAARM!!! (incident changed from " << IncidentRhadron->GetDefinition()->GetParticleName() << " to "
              << p0->GetDefinition()->GetParticleName() << ")" << G4endl;
       G4cout << "Energy loss: " << (e_kin_0 - p0->GetKineticEnergy()) / GeV << " GeV (should be positive)" << G4endl;
       //Turns out problem is only in 2 -> 3 (Won't fix 2 -> 2 energy deposition)
       if (rp.size() != 3)
         G4cout << "DOUBLE ALAAAAARM!!!" << G4endl;
     } /*else {
     G4cout<<"NO ALAAAAARM!!!"<<G4endl;
     }*/
     if (std::abs(p0->GetKineticEnergy() - e_kin_0) > 100 * GeV) {
       G4cout << "Diff. too big" << G4endl;
     }
     aParticleChange.ProposeTrackStatus(fStopAndKill);
   } else {
     G4double p = p_new.mag();
     if (p > DBL_MIN)
       aParticleChange.ProposeMomentumDirection(p_new.x() / p, p_new.y() / p, p_new.z() / p);
     else
       aParticleChange.ProposeMomentumDirection(1.0, 0.0, 0.0);
   }

   //    return G4VDiscreteProcess::PostStepDoIt( aTrack, aStep);
   if (targetParticle.GetMass() > 0.0)  // targetParticle can be eliminated in TwoBody
   {
     G4DynamicParticle* p1 = new G4DynamicParticle;
     p1->SetDefinition(targetParticle.GetDefinition());
     //G4cout<<"Target secondary: "<<targetParticle.GetDefinition()->GetParticleName()<<G4endl;
     G4ThreeVector momentum = targetParticle.GetMomentum();
     momentum = momentum.rotate(cache, what);
     p1->SetMomentum(momentum);
     p1->SetMomentum((trans * p1->Get4Momentum()).vect());
     G4Track* Track1 = new G4Track(p1, aTrack.GetGlobalTime(), aPosition);
     Track1->SetTouchableHandle(thisTouchable);
     aParticleChange.AddSecondary(Track1);
   }
   G4DynamicParticle* pa;
   /*
     G4cout<<"vecLen: "<<vecLen<<G4endl;
     G4cout<<"#sec's: "<<aParticleChange.GetNumberOfSecondaries()<<G4endl;
   */

   for (int i = 0; i < vecLen; ++i) {
     pa = new G4DynamicParticle();
     pa->SetDefinition(vec[i]->GetDefinition());
     pa->SetMomentum(vec[i]->GetMomentum());
     pa->Set4Momentum(trans * (pa->Get4Momentum()));
     G4ThreeVector pvec = pa->GetMomentum();
     G4Track* Trackn = new G4Track(pa, aTrack.GetGlobalTime(), aPosition);
     Trackn->SetTouchableHandle(thisTouchable);
     aParticleChange.AddSecondary(Trackn);

     delete vec[i];
   }

   // Histogram filling
   const G4DynamicParticle* theRhadron = FindRhadron(&aParticleChange);

   if (theRhadron != nullptr || IncidentSurvives) {
     double E_new;
     if (IncidentSurvives) {
       E_new = e_kin;
     } else {
       E_new = theRhadron->GetKineticEnergy();
       if (CustomPDGParser::s_isRMeson(theRhadron->GetDefinition()->GetPDGEncoding()) !=
               CustomPDGParser::s_isRMeson(theIncidentPDG) ||
           CustomPDGParser::s_isMesonino(theRhadron->GetDefinition()->GetPDGEncoding()) !=
               CustomPDGParser::s_isMesonino(theIncidentPDG)) {
         G4cout << "Rm: " << CustomPDGParser::s_isRMeson(theRhadron->GetDefinition()->GetPDGEncoding())
                << " vs: " << CustomPDGParser::s_isRMeson(theIncidentPDG) << G4endl;
         G4cout << "Sm: " << CustomPDGParser::s_isMesonino(theRhadron->GetDefinition()->GetPDGEncoding())
                << " vs: " << CustomPDGParser::s_isMesonino(theIncidentPDG) << G4endl;
       }
     }

     //Calculating relevant scattering angles.
     G4LorentzVector p4_old_full = FullRhadron4Momentum;  //R-hadron in CMS BEFORE collision
     p4_old_full.boost(trafo_full_cms);
     G4LorentzVector p4_old_cloud = FullRhadron4Momentum;  //R-hadron in cloud CMS BEFORE collision
     p4_old_cloud.boost(trafo_cloud_cms);
     G4LorentzVector p4_full = p4_new;  //R-hadron in CMS AFTER collision
     //      G4cout<<p4_full.v()/GeV<<G4endl;
     p4_full = p4_full.boost(trafo_full_cms);
     // G4cout<<p4_full.m()<<" / "<<(cloud_p4_new+gluinoMomentum).boost(trafo_full_cms).m()<<G4endl;
     G4LorentzVector p4_cloud = p4_new;  //R-hadron in cloud CMS AFTER collision
     p4_cloud.boost(trafo_cloud_cms);

     G4double AbsDeltaE = E_0 - E_new;
     //      G4cout <<"Energy loss: "<<AbsDeltaE/GeV<<G4endl;
     if (AbsDeltaE > 10 * GeV) {
       G4cout << "Energy loss larger than 10 GeV..." << G4endl;
       G4cout << "E_0: " << E_0 / GeV << " GeV" << G4endl;
       G4cout << "E_new: " << E_new / GeV << " GeV" << G4endl;
       G4cout << "Gamma: " << IncidentRhadron->GetTotalEnergy() / IncidentRhadron->GetDefinition()->GetPDGMass()
              << G4endl;
       G4cout << "x: " << aPosition.x() / cm << " cm" << G4endl;
     }
   }
   delete originalIncident;
   delete originalTarget;
   //  aParticleChange.DumpInfo();
   //  G4cout << "Exiting FullModelHadronicProcess::PostStepDoIt"<<G4endl;

   //clear interaction length
   ClearNumberOfInteractionLengthLeft();

   return &aParticleChange;
 }

 void FullModelHadronicProcess::CalculateMomenta(
     G4FastVector<G4ReactionProduct, MYGHADLISTSIZE>& vec,
     G4int& vecLen,
     const G4HadProjectile* originalIncident,  // the original incident particle
     const G4DynamicParticle* originalTarget,
     G4ReactionProduct& modifiedOriginal,  // Fermi motion and evap. effects included
     G4Nucleus& targetNucleus,
     G4ReactionProduct& currentParticle,
     G4ReactionProduct& targetParticle,
     G4bool& incidentHasChanged,
     G4bool& targetHasChanged,
     G4bool quasiElastic) {
   FullModelReactionDynamics theReactionDynamics;

   cache = 0;
   what = originalIncident->Get4Momentum().vect();

   if (quasiElastic) {
     //      G4cout<<"We are calling TwoBody..."<<G4endl;
     theReactionDynamics.TwoBody(
         vec, vecLen, modifiedOriginal, originalTarget, currentParticle, targetParticle, targetNucleus, targetHasChanged);

     return;
   }

   //If ProduceStrangeParticlePairs is commented out, let's cut this one as well
   G4ReactionProduct leadingStrangeParticle;
   G4bool leadFlag = MarkLeadingStrangeParticle(currentParticle, targetParticle, leadingStrangeParticle);

   //
   // Note: the number of secondaries can be reduced in GenerateXandPt and TwoCluster
   //
   G4bool finishedGenXPt = false;
   G4bool annihilation = false;
   if (originalIncident->GetDefinition()->GetPDGEncoding() < 0 && currentParticle.GetMass() == 0.0 &&
       targetParticle.GetMass() == 0.0) {
     // original was an anti-particle and annihilation has taken place
     annihilation = true;
     G4double ekcor = 1.0;
     G4double ek = originalIncident->GetKineticEnergy();
     G4double ekOrg = ek;

     const G4double tarmas = originalTarget->GetDefinition()->GetPDGMass();
     if (ek > 1.0 * GeV)
       ekcor = 1. / (ek / GeV);
     const G4double atomicWeight = G4double(targetNucleus.GetN_asInt());
     ek = 2 * tarmas + ek * (1. + ekcor / atomicWeight);

     G4double tkin = targetNucleus.Cinema(ek);
     //ek += tkin;
     ekOrg += tkin;
     modifiedOriginal.SetKineticEnergy(ekOrg);
   }

   const G4double twsup[] = {1.0, 0.7, 0.5, 0.3, 0.2, 0.1};
   G4double rand1 = G4UniformRand();
   G4double rand2 = G4UniformRand();
   if ((annihilation || (vecLen >= 6) || (modifiedOriginal.GetKineticEnergy() / GeV >= 1.0)) &&
       (((originalIncident->GetDefinition() == G4KaonPlus::KaonPlus()) ||
         (originalIncident->GetDefinition() == G4KaonMinus::KaonMinus()) ||
         (originalIncident->GetDefinition() == G4KaonZeroLong::KaonZeroLong()) ||
         (originalIncident->GetDefinition() == G4KaonZeroShort::KaonZeroShort())) &&
        ((rand1 < 0.5) || (rand2 > twsup[vecLen]))))
     finishedGenXPt = theReactionDynamics.GenerateXandPt(vec,
                                                         vecLen,
                                                         modifiedOriginal,
                                                         originalIncident,
                                                         currentParticle,
                                                         targetParticle,
                                                         targetNucleus,
                                                         incidentHasChanged,
                                                         targetHasChanged,
                                                         leadFlag,
                                                         leadingStrangeParticle);
   if (finishedGenXPt) {
     Rotate(vec, vecLen);
     return;
   }

   G4bool finishedTwoClu = false;
   if (modifiedOriginal.GetTotalMomentum() / MeV < 1.0) {
     for (G4int i = 0; i < vecLen; i++)
       delete vec[i];
     vecLen = 0;
   } else {
     theReactionDynamics.SuppressChargedPions(vec,
                                              vecLen,
                                              modifiedOriginal,
                                              currentParticle,
                                              targetParticle,
                                              targetNucleus,
                                              incidentHasChanged,
                                              targetHasChanged);

     try {
       finishedTwoClu = theReactionDynamics.TwoCluster(vec,
                                                       vecLen,
                                                       modifiedOriginal,
                                                       originalIncident,
                                                       currentParticle,
                                                       targetParticle,
                                                       targetNucleus,
                                                       incidentHasChanged,
                                                       targetHasChanged,
                                                       leadFlag,
                                                       leadingStrangeParticle);
     } catch (G4HadReentrentException& aC) {
       aC.Report(G4cout);
       throw G4HadReentrentException(__FILE__, __LINE__, "Failing to calculate momenta");
     }
   }
   if (finishedTwoClu) {
     Rotate(vec, vecLen);
     return;
   }

   //
   // PNBlackTrackEnergy is the kinetic energy available for
   //   proton/neutron black track particles [was enp(1) in fortran code]
   // DTABlackTrackEnergy is the kinetic energy available for
   //   deuteron/triton/alpha particles      [was enp(3) in fortran code]
   // the atomic weight of the target nucleus is >= 1.5            AND
   //   neither the incident nor the target particles have changed  AND
   //     there is no kinetic energy available for either proton/neutron
   //     or for deuteron/triton/alpha black track particles
   // For diffraction scattering on heavy nuclei use elastic routines instead

   theReactionDynamics.TwoBody(
       vec, vecLen, modifiedOriginal, originalTarget, currentParticle, targetParticle, targetNucleus, targetHasChanged);
 }

 G4bool FullModelHadronicProcess::MarkLeadingStrangeParticle(const G4ReactionProduct& currentParticle,
                                                             const G4ReactionProduct& targetParticle,
                                                             G4ReactionProduct& leadParticle) {
   // the following was in GenerateXandPt and TwoCluster
   // add a parameter to the GenerateXandPt function telling it about the strange particle
   //
   // assumes that the original particle was a strange particle
   //
   G4bool lead = false;
   if ((currentParticle.GetMass() >= G4KaonPlus::KaonPlus()->GetPDGMass()) &&
       (currentParticle.GetDefinition() != G4Proton::Proton()) &&
       (currentParticle.GetDefinition() != G4Neutron::Neutron())) {
     lead = true;
     leadParticle = currentParticle;  //  set lead to the incident particle
   } else if ((targetParticle.GetMass() >= G4KaonPlus::KaonPlus()->GetPDGMass()) &&
              (targetParticle.GetDefinition() != G4Proton::Proton()) &&
              (targetParticle.GetDefinition() != G4Neutron::Neutron())) {
     lead = true;
     leadParticle = targetParticle;  //   set lead to the target particle
   }
   return lead;
 }

 void FullModelHadronicProcess::Rotate(G4FastVector<G4ReactionProduct, MYGHADLISTSIZE>& vec, G4int& vecLen) {
   G4double rotation = 2. * pi * G4UniformRand();
   cache = rotation;
   G4int i;
   for (i = 0; i < vecLen; ++i) {
     G4ThreeVector momentum = vec[i]->GetMomentum();
     momentum = momentum.rotate(rotation, what);
     vec[i]->SetMomentum(momentum);
   }
 }

 const G4DynamicParticle* FullModelHadronicProcess::FindRhadron(G4ParticleChange* aParticleChange) {
   G4int nsec = aParticleChange->GetNumberOfSecondaries();
   if (nsec == 0)
     return nullptr;
   int i = 0;
   G4bool found = false;
   while (i != nsec && !found) {
     //    G4cout<<"Checking "<<aParticleChange->GetSecondary(i)->GetDynamicParticle()->GetDefinition()->GetParticleName()<<G4endl;
     //    if (aParticleChange->GetSecondary(i)->GetDynamicParticle()->GetDefinition()->GetParticleType()=="rhadron") found = true;
     if (dynamic_cast<CustomParticle*>(aParticleChange->GetSecondary(i)->GetDynamicParticle()->GetDefinition()) !=
         nullptr)
       found = true;
     i++;
   }
   i--;
   if (found)
     return aParticleChange->GetSecondary(i)->GetDynamicParticle();
   return nullptr;
 }
GeV
const double GeV
Definition: MathUtil.h:16

Scenarios_cff.scale
scale
Definition: Scenarios_cff.py:2186

mps_fire.i
i
Definition: mps_fire.py:338

CustomParticle
Definition: CustomParticle.h:11

AlCaHLTBitMon_ParallelJobs.p
p
Definition: AlCaHLTBitMon_ParallelJobs.py:153

FullModelHadronicProcess::cache
G4double cache
Definition: FullModelHadronicProcess.h:61

FullModelHadronicProcess::MarkLeadingStrangeParticle
G4bool MarkLeadingStrangeParticle(const G4ReactionProduct &currentParticle, const G4ReactionProduct &targetParticle, G4ReactionProduct &leadParticle)
Definition: FullModelHadronicProcess.cc:622

G4ProcessHelper::ApplicabilityTester
G4bool ApplicabilityTester(const G4ParticleDefinition &aPart)
Definition: G4ProcessHelper.cc:109

FullModelReactionDynamics::TwoBody
void TwoBody(G4FastVector< G4ReactionProduct, MYGHADLISTSIZE > &vec, G4int &vecLen, G4ReactionProduct &modifiedOriginal, const G4DynamicParticle *originalTarget, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, const G4Nucleus &targetNucleus, G4bool &targetHasChanged)
Definition: FullModelReactionDynamics.cc:2069

FullModelHadronicProcess::what
G4ThreeVector what
Definition: FullModelHadronicProcess.h:62

csvLumiCalc.unit
unit
Definition: csvLumiCalc.py:47

CustomParticle::GetCloud
G4ParticleDefinition * GetCloud()
Definition: CustomParticle.h:44

G4ProcessHelper
Definition: G4ProcessHelper.h:26

FullModelHadronicProcess::PostStepDoIt
G4VParticleChange * PostStepDoIt(const G4Track &aTrack, const G4Step &aStep) override
Definition: FullModelHadronicProcess.cc:52

AnalysisDataFormats_SUSYBSMObjects::pa
susybsm::HSCParticle pa
Definition: classes.h:8

idealTransformation.rotation
dictionary rotation
Definition: idealTransformation.py:1

MillePedeFileConverter_cfg.e
e
Definition: MillePedeFileConverter_cfg.py:37

CustomPDGParser::s_isRMeson
static bool s_isRMeson(int pdg)
Definition: CustomPDGParser.cc:46

FullModelHadronicProcess::GetMicroscopicCrossSection
virtual G4double GetMicroscopicCrossSection(const G4DynamicParticle *aParticle, const G4Element *anElement, G4double aTemp)
Definition: FullModelHadronicProcess.cc:22

runEdmFileComparison.found
found
Definition: runEdmFileComparison.py:165

res
Definition: Electron.h:6

ReactionProduct
std::vector< G4int > ReactionProduct
Definition: G4ProcessHelper.h:16

pi
const Double_t pi
Definition: trackSplitPlot.h:36

CLHEP
Definition: CocoaGlobals.h:27

MeV
const double MeV

ecalTB2006H4_GenSimDigiReco_cfg.G4cout
G4cout
Definition: ecalTB2006H4_GenSimDigiReco_cfg.py:303

CustomPDGParser::s_isMesonino
static bool s_isMesonino(int pdg)
Definition: CustomPDGParser.cc:51

FullModelReactionDynamics
Definition: FullModelReactionDynamics.h:23

FullModelHadronicProcess::GetMeanFreePath
G4double GetMeanFreePath(const G4Track &aTrack, G4double, G4ForceCondition *) override
Definition: FullModelHadronicProcess.cc:31

mathSSE::sqrt
T sqrt(T t)
Definition: SSEVec.h:18

FullModelHadronicProcess::~FullModelHadronicProcess
~FullModelHadronicProcess() override
Definition: FullModelHadronicProcess.cc:16

funct::abs
Abs< T >::type abs(const T &t)
Definition: Abs.h:22

G4ProcessHelper.h

G4ProcessHelper::GetFinalState
ReactionProduct GetFinalState(const G4Track &aTrack, G4ParticleDefinition *&aTarget)
Definition: G4ProcessHelper.cc:187

FullModelReactionDynamics::TwoCluster
G4bool TwoCluster(G4FastVector< G4ReactionProduct, MYGHADLISTSIZE > &vec, G4int &vecLen, G4ReactionProduct &modifiedOriginal, const G4HadProjectile *originalIncident, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, const G4Nucleus &targetNucleus, G4bool &incidentHasChanged, G4bool &targetHasChanged, G4bool leadFlag, G4ReactionProduct &leadingStrangeParticle)
Definition: FullModelReactionDynamics.cc:1288

CustomPDGParser.h

G4ProcessHelper::GetInclusiveCrossSection
G4double GetInclusiveCrossSection(const G4DynamicParticle *aParticle, const G4Element *anElement)
Definition: G4ProcessHelper.cc:116

CustomParticle::GetSpectator
G4ParticleDefinition * GetSpectator()
Definition: CustomParticle.h:46

modifiedElectrons_cfi.processName
processName
Definition: modifiedElectrons_cfi.py:5

FullModelReactionDynamics::GenerateXandPt
G4bool GenerateXandPt(G4FastVector< G4ReactionProduct, MYGHADLISTSIZE > &vec, G4int &vecLen, G4ReactionProduct &modifiedOriginal, const G4HadProjectile *originalIncident, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, const G4Nucleus &targetNucleus, G4bool &incidentHasChanged, G4bool &targetHasChanged, G4bool leadFlag, G4ReactionProduct &leadingStrangeParticle)
Definition: FullModelReactionDynamics.cc:62

Decay3Body.h

FullModelHadronicProcess::CalculateMomenta
void CalculateMomenta(G4FastVector< G4ReactionProduct, MYGHADLISTSIZE > &vec, G4int &vecLen, const G4HadProjectile *originalIncident, const G4DynamicParticle *originalTarget, G4ReactionProduct &modifiedOriginal, G4Nucleus &targetNucleus, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, G4bool &incidentHasChanged, G4bool &targetHasChanged, G4bool quasiElastic)
Definition: FullModelHadronicProcess.cc:491

funct::m
m
Definition: Factorize.h:56

FullModelHadronicProcess::FullModelHadronicProcess
FullModelHadronicProcess(G4ProcessHelper *aHelper, const G4String &processName="FullModelHadronicProcess")
Definition: FullModelHadronicProcess.cc:13

FullModelHadronicProcess::theHelper
G4ProcessHelper * theHelper
Definition: FullModelHadronicProcess.h:59

p1
double p1[4]
Definition: TauolaWrapper.h:89

CustomParticle.h

FullModelReactionDynamics::SuppressChargedPions
void SuppressChargedPions(G4FastVector< G4ReactionProduct, MYGHADLISTSIZE > &vec, G4int &vecLen, const G4ReactionProduct &modifiedOriginal, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, const G4Nucleus &targetNucleus, G4bool &incidentHasChanged, G4bool &targetHasChanged)
Definition: FullModelReactionDynamics.cc:1235

FullModelHadronicProcess::Rotate
void Rotate(G4FastVector< G4ReactionProduct, MYGHADLISTSIZE > &vec, G4int &vecLen)
Definition: FullModelHadronicProcess.cc:645

FullModelHadronicProcess::FindRhadron
const G4DynamicParticle * FindRhadron(G4ParticleChange *)
Definition: FullModelHadronicProcess.cc:656

dir
dbl *** dir
Definition: mlp_gen.cc:35

FullModelHadronicProcess::IsApplicable
G4bool IsApplicable(const G4ParticleDefinition &aP) override
Definition: FullModelHadronicProcess.cc:18

FullModelHadronicProcess.h