// Macro for running Cbm with Geant3 or Geant4 (M. Al-Turany , D. Bertini) // Modified 22/06/2005 D.Bertini { TStopwatch timer; timer.Start(); gDebug=0; // Load basic libraries gROOT->LoadMacro("$VMCWORKDIR/gconfig/basiclibs.C"); basiclibs(); // Load this example libraries gSystem->Load("libGeoBase"); gSystem->Load("libParBase"); gSystem->Load("libBase"); gSystem->Load("libMCStack"); gSystem->Load("libGen"); gSystem->Load("libField"); gSystem->Load("libPassive"); gSystem->Load("libStt"); gSystem->Load("libMuo"); gSystem->Load("libEmc"); gSystem->Load("libTof"); gSystem->Load("libDrcProp"); gSystem->Load("libDrc"); gSystem->Load("libtpc"); gSystem->Load("libDch"); gSystem->Load("libMvd"); CbmRunSim *fRun = new CbmRunSim(); // set the MC version used // ------------------------ fRun->SetName("TGeant3"); // Choose the Geant Navigation System // fRun->SetGeoModel("G3Native"); fRun->SetOutputFile("testsimu10.root"); // Set Material file Name //----------------------- fRun->SetMaterials("media_pnd.geo"); // Create and add detectors //------------------------- CbmModule *Cave= new PndCave("CAVE"); Cave->SetGeometryFileName("pndcave.geo"); fRun->AddModule(Cave); CbmModule *Magnet= new PndMagnet("MAGNET"); Magnet->SetGeometryFileName("magnet.geo"); fRun->AddModule(Magnet); CbmModule *Pipe= new PndPipe("PIPE"); Pipe->SetGeometryFileName("pipebeamtarget.geo"); fRun->AddModule(Pipe); /* CbmDetector *Stt = new CbmStt("STT",kTRUE); Stt->SetGeometryFileName("stt24.geo"); // 14 = 1 solo 2layer pablo01.geo 3 layers stt24 fRun->AddModule(Stt); */ /* CbmDetector *Stt= new CbmStt("STT", kTRUE); Stt->SetGeometryFileName("straws_axial.geo"); fRun->AddModule(Stt); */ CbmDetector *Tpc = new PndTpcDetector("TPC", kTRUE); Tpc->SetGeometryFileName("tpc.geo"); fRun->AddModule(Tpc); CbmDetector *Mvd = new PndMvdDetector("MVD", kTRUE); Mvd->SetGeometryFileName("MVD14.root"); fRun->AddModule(Mvd); CbmDetector *Emc = new PndEmc("EMC",kTRUE); Emc->SetGeometryFileName("emc_module12345.dat"); fRun->AddModule(Emc); CbmDetector *Tof = new PndTof("TOF",kTRUE); Tof->SetGeometryFileName("tofSciF.geo"); fRun->AddModule(Tof); CbmDetector *Muo = new PndMuo("MUO",kTRUE); Muo->SetGeometryFileName("muon_newmag.geo"); fRun->AddModule(Muo); CbmDetector *Drc = new PndDrc("DIRC", kTRUE); Drc->SetGeometryFileName("dirc.geo"); fRun->AddModule(Drc); CbmDetector *Dch = new PndDchDetector("DCH", kTRUE); Dch->SetGeometryFileName("dch.root"); fRun->AddModule(Dch); // Create and Set Event Generator //------------------------------- CbmPrimaryGenerator* primGen = new CbmPrimaryGenerator(); fRun->SetGenerator(primGen); /* // Box Generator CbmBoxGenerator* boxGen = new CbmBoxGenerator(13, 200); // 13 = muon; 1 = multipl. // boxGen->SetPRange(1.,1.1); // GeV/c boxGen->SetPtRange(1.,1.); // GeV/c boxGen->SetPhiRange(0., 360.); // Azimuth angle range [degree] boxGen->SetThetaRange(0., 90.); // Polar angle in lab system range [degree] boxGen->SetXYZ(0., 0., 0.); // mm o cm ?? primGen->AddGenerator(boxGen); */ // proton 2212 pi+ 211 pi- -211 Double_t randx, randy; for (Int_t n =0; n<10; n++){ randx= gRandom->Gaus(0,1); randy= gRandom->Gaus(0,1); CbmParticleGenerator* partGen = new CbmParticleGenerator(2212, 1, 0.3*randx, 0.3*randy, 0.3); primGen->AddGenerator(partGen); } // Ion Generator //CbmIonGenerator *fIongen= new CbmIonGenerator(79, 197,79,1, 0.,0., 25, 0.,0.,-1.); // primGen->AddGenerator(fIongen); // fRun->SetStoreTraj(kTRUE); PndMultiField *fField= new PndMultiField(); PndTransMap *map= new PndTransMap("TransMap", "R"); PndDipoleMap *map1= new PndDipoleMap("DipoleMap", "R"); PndSolenoidMap *map2= new PndSolenoidMap("SolenoidMap", "R"); fField->AddField(map); fField->AddField(map1); fField->AddField(map2); //magnetic field /* PndConstField *fMagField=new PndConstField(); fMagField->SetField(0.,0.,20.); // values are in kG fMagField->SetFieldRegion(-50, 50,-50, 50, -100, 100);// values are in cm (xmin,xmax,ymin,ymax,zmin,zmax) fField->AddField(fMagField); */ fRun->SetField(fField); fRun->Init(); // -Trajectories Visualization // ---------------------------- CbmTrajFilter* trajFilter = CbmTrajFilter::Instance(); // Set cuts for storing the trajectpries trajFilter->SetStepSizeCut(0.01); // 1 cm // trajFilter->SetVertexCut(-2000., -2000., 4., 2000., 2000., 100.); // trajFilter->SetMomentumCutP(10e-3); // p_lab > 10 MeV // trajFilter->SetEnergyCut(0., 1.02); // 0 < Etot < 1.04 GeV trajFilter->SetStorePrimaries(kTRUE); trajFilter->SetStoreSecondaries(kTRUE); // // // Fill the Parameter containers for this run // //------------------------------------------- // CbmRuntimeDb *rtdb=fRun->GetRuntimeDb(); Bool_t kParameterMerged=kTRUE; //if a field is used save the parameters in the RTDB /* PndSolenoidPar* Par1 = (PndSolenoidPar*) rtdb->getContainer("PndSolenoidPar"); if ( map2 ) { Par1->SetParameters(map2); } Par1->setChanged(); Par1->setInputVersion(fRun->GetRunId(),1); PndDipolePar* Par2 = (PndDipolePar*) rtdb->getContainer("PndDipolePar"); if (map1 ) { Par2->SetParameters(map1); } Par2->setInputVersion(fRun->GetRunId(),1); Par2->setChanged(); PndTransPar* Par3 = (PndTransPar*) rtdb->getContainer("PndTransPar"); if (map ) { Par3->SetParameters(map); } Par3->setInputVersion(fRun->GetRunId(),1); Par3->setChanged(); */ PndMultiFieldPar* Par = (PndMultiFieldPar*) rtdb->getContainer("PndMultiFieldPar"); if (fField) { Par->SetParameters(fField); } Par->setInputVersion(fRun->GetRunId(),1); Par->setChanged(); CbmParRootFileIo* output=new CbmParRootFileIo(kParameterMerged); output->open("testparams.root"); rtdb->setOutput(output); rtdb->saveOutput(); rtdb->print(); // Transport nEvents // -----------------1 Int_t nEvents = 2; fRun->Run(nEvents); timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); printf("RealTime=%f seconds, CpuTime=%f seconds\n",rtime,ctime); cout << " Test passed" << endl; cout << " All ok " << endl; exit(0); }