exampleGB07.cc File Reference

Main program of the GB07 example. More...

#include "G4Types.hh"
#include "G4RunManager.hh"
#include "GB07ActionInitialization.hh"
#include "G4UImanager.hh"
#include "GB07DetectorConstruction.hh"
#include "GB07PrimaryGeneratorAction.hh"
#include "FTFP_BERT.hh"
#include "G4GenericBiasingPhysics.hh"
#include "G4VisExecutive.hh"
#include "G4UIExecutive.hh"

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Functions
int	main (int argc, char **argv)

Detailed Description

Main program of the GB07 example.

Definition in file exampleGB07.cc.

Function Documentation

int main	(	int	argc,
		char **	argv
	)

Definition at line 65 of file exampleGB07.cc.

References PrintUsage().

{
  // Evaluate arguments
  //
  if ( argc > 5 ) {
    PrintUsage();
    return 1;
  }

  G4String macro("");
  G4String onOffBiasing("");
  if ( argc == 2 ) macro = argv[1];
  else
    {
      for ( G4int i=1; i<argc; i=i+2 )
        {
          if      ( G4String(argv[i]) == "-m" ) macro        = argv[i+1];
          else if ( G4String(argv[i]) == "-b" ) onOffBiasing = argv[i+1];
          else
            {
              PrintUsage();
              return 1;
            }
        }
    }

  if ( onOffBiasing == "" ) onOffBiasing = "on";

  // Instantiate G4UIExecutive if interactive mode
  G4UIExecutive* ui = nullptr;
  if ( macro == "" ) {
    ui = new G4UIExecutive(argc, argv);
  }

  // -- Construct the run manager : MT or sequential one
#ifdef G4MULTITHREADED
  G4MTRunManager * runManager = new G4MTRunManager;
  G4cout << "      ********** Run Manager constructed in MT mode ************ " << G4endl;
  // -- Choose 4 threads:
  runManager->SetNumberOfThreads(4);
#else
  G4RunManager * runManager = new G4RunManager;
  G4cout << "      ********** Run Manager constructed in sequential mode ************ " << G4endl;
#endif

  // -- Set mandatory initialization classes
  GB07DetectorConstruction* detector = new GB07DetectorConstruction();
  runManager->SetUserInitialization(detector);
  // -- Select a physics list
  FTFP_BERT* physicsList = new FTFP_BERT;
  // -- And augment it with biasing facilities:
  G4GenericBiasingPhysics* biasingPhysics = new G4GenericBiasingPhysics();
  if ( onOffBiasing == "on" )
    {
      // -- Specify the processes that will be under biasing:
      // ---- Decide to apply the technique to hadronic inelastic interactions:
      std::vector< G4String >
         piPlusProcessesToBias,     piMinusProcessesToBias,
         protonProcessesToBias,  antiProtonProcessesToBias,
        neutronProcessesToBias, antiNeutronProcessesToBias;
      piPlusProcessesToBias     .push_back(         "pi+Inelastic");
      piMinusProcessesToBias    .push_back(         "pi-Inelastic");
      protonProcessesToBias     .push_back(      "protonInelastic");
      antiProtonProcessesToBias .push_back( "anti_protonInelastic");
      neutronProcessesToBias    .push_back(     "neutronInelastic");
      neutronProcessesToBias    .push_back("nCapture"             );
      antiNeutronProcessesToBias.push_back("anti_neutronInelastic");
      biasingPhysics->PhysicsBias("pi+",               piPlusProcessesToBias);
      biasingPhysics->PhysicsBias("pi-",              piMinusProcessesToBias);
      biasingPhysics->PhysicsBias("proton",            protonProcessesToBias);
      biasingPhysics->PhysicsBias("anti_proton",   antiProtonProcessesToBias);
      biasingPhysics->PhysicsBias("neutron",          neutronProcessesToBias);
      biasingPhysics->PhysicsBias("anti_neutron", antiNeutronProcessesToBias);
      // ---- Apply also the technique to some EM processes (producing at least
      // ---- 2 same or 2 particle - anti-particle pairs):
      std::vector< G4String > gammaProcessesToBias,
        electronProcessesToBias, positronProcessesToBias;
      gammaProcessesToBias      .push_back( "conv"            );
      gammaProcessesToBias      .push_back( "photonNuclear"   );
      electronProcessesToBias   .push_back( "electronNuclear" );
      positronProcessesToBias   .push_back( "annihil"         );
      positronProcessesToBias   .push_back( "positronNuclear" );
      biasingPhysics->PhysicsBias("gamma",              gammaProcessesToBias);
      biasingPhysics->PhysicsBias("e-",              electronProcessesToBias);
      biasingPhysics->PhysicsBias("e+",              positronProcessesToBias);
      // ---- And apply it to pi0 decay:
      std::vector< G4String > pi0ProcessesToBias;
      pi0ProcessesToBias        .push_back( "Decay"           );
      biasingPhysics->PhysicsBias("pi0",                  pi0ProcessesToBias);
      // --
      physicsList->RegisterPhysics(biasingPhysics);
      G4cout << "      ********************************************************* " << G4endl;
      G4cout << "      ********** processes are wrapped for biasing ************ " << G4endl;
      G4cout << "      ********************************************************* " << G4endl;
    }
  else
    {
      G4cout << "      ************************************************* " << G4endl;
      G4cout << "      ********** processes are not wrapped ************ " << G4endl;
      G4cout << "      ************************************************* " << G4endl;
    }
  runManager->SetUserInitialization(physicsList);
  // -- Action initialization:
  runManager->SetUserInitialization(new GB07ActionInitialization);

  // Initialize G4 kernel
  runManager->Initialize();

  // Initialize visualization
  G4VisManager* visManager = new G4VisExecutive;
  // G4VisExecutive can take a verbosity argument - see /vis/verbose guidance.
  visManager->Initialize();

  // Get the pointer to the User Interface manager
  G4UImanager* UImanager = G4UImanager::GetUIpointer();

  if ( macro != "" )   // batch mode
    {
      G4String command = "/control/execute ";
      UImanager->ApplyCommand(command+macro);
    }
  else
    {  // interactive mode : define UI session
      UImanager->ApplyCommand("/control/execute vis.mac");
      //      if (ui->IsGUI())
      //        UImanager->ApplyCommand("/control/execute gui.mac");
      ui->SessionStart();
      delete ui;
    }

  delete visManager;
  delete runManager;

  return 0;
}