sim_complete_boxgen_pions(Int_t nEvents = 100, TString pre="", Float_t mom = 6.231552, TString SimEngine ="TGeant3") { //-----User Settings:----------------------------------------------- if(pre == ""){ TString OutputFile ="sim_complete.root"; TString ParOutputfile ="simparams.root"; } else{ TString OutputFile = pre + "_sim_complete.root"; TString ParOutputfile =pre + "_simparams.root"; } TString MediaFile ="media_pnd.geo"; gDebug = 0; TString digiFile = "all.par"; //The emc run the hit producer directly // choose your event generator Bool_t UseEvtGenDirect =kFALSE; Bool_t UseDpm =kFALSE; Bool_t UseFtf =kFALSE; Bool_t UseBoxGenerator =kTRUE; TString evtPdlFile = "evt.pdl"; Double_t BeamMomentum = 0.; // beam momentum ONLY for the scaling of the dipole field. if (UseBoxGenerator) { BeamMomentum =mom; // ** change HERE if you run Box generator } else { BeamMomentum = mom; // for DPM/EvtGen BeamMomentum is always = mom } //------------------------------------------------------------------ TLorentzVector fIni(0, 0, mom, sqrt(mom*mom+9.3827203e-01*9.3827203e-01)+9.3827203e-01); TDatabasePDG::Instance()->AddParticle("pbarpSystem","pbarpSystem",fIni.M(),kFALSE,0.1,0, "",88888); //------------------------------------------------------------------ TStopwatch timer; timer.Start(); gRandom->SetSeed(); // Create the Simulation run manager-------------------------------- FairRunSim *fRun = new FairRunSim(); fRun->SetName(SimEngine.Data() ); fRun->SetOutputFile(OutputFile.Data()); fRun->SetGenerateRunInfo(kFALSE); fRun->SetBeamMom(BeamMomentum); fRun->SetMaterials(MediaFile.Data()); fRun->SetUseFairLinks(kTRUE); FairRuntimeDb *rtdb=fRun->GetRuntimeDb(); // Set the parameters //------------------------------- TString allDigiFile = gSystem->Getenv("VMCWORKDIR"); allDigiFile += "/macro/params/"; allDigiFile += digiFile; //-------Set the parameter output -------------------- FairParAsciiFileIo* parIo1 = new FairParAsciiFileIo(); parIo1->open(allDigiFile.Data(),"in"); rtdb->setFirstInput(parIo1); //---------------------Set Parameter output ---------- Bool_t kParameterMerged=kTRUE; FairParRootFileIo* output=new FairParRootFileIo(kParameterMerged); output->open(ParOutputfile.Data()); rtdb->setOutput(output); // Create and add detectors //------------------------- CAVE ----------------- FairModule *Cave= new PndCave("CAVE"); Cave->SetGeometryFileName("pndcave.geo"); fRun->AddModule(Cave); //------------------------- Magnet ----------------- //FairModule *Magnet= new PndMagnet("MAGNET"); //Magnet->SetGeometryFileName("FullSolenoid_V842.root"); //Magnet->SetGeometryFileName("FullSuperconductingSolenoid_v831.root"); //fRun->AddModule(Magnet); FairModule *Dipole= new PndMagnet("MAGNET"); Dipole->SetGeometryFileName("dipole.geo"); fRun->AddModule(Dipole); //------------------------- Pipe ----------------- FairModule *Pipe= new PndPipe("PIPE"); Pipe->SetGeometryFileName("beampipe_201309.root"); fRun->AddModule(Pipe); //------------------------- STT ----------------- FairDetector *Stt= new PndStt("STT", kTRUE); Stt->SetGeometryFileName("straws_skewed_blocks_35cm_pipe.geo"); fRun->AddModule(Stt); //------------------------- MVD ----------------- FairDetector *Mvd = new PndMvdDetector("MVD", kTRUE); Mvd->SetGeometryFileName("Mvd-2.1_FullVersion.root"); fRun->AddModule(Mvd); //------------------------- GEM ----------------- FairDetector *Gem = new PndGemDetector("GEM", kTRUE); Gem->SetGeometryFileName("gem_3Stations_Tube.root"); fRun->AddModule(Gem); //------------------------- EMC ----------------- PndEmc *Emc = new PndEmc("EMC",kTRUE); Emc->SetGeometryVersion(1); Emc->SetStorageOfData(kFALSE); fRun->AddModule(Emc); //------------------------- SCITIL ----------------- FairDetector *SciT = new PndSciT("SCIT",kTRUE); SciT->SetGeometryFileName("SciTil_201504.root"); fRun->AddModule(SciT); //------------------------- DRC ----------------- PndDrc *Drc = new PndDrc("DIRC", kTRUE); Drc->SetGeometryFileName("dirc_l0_p0_updated.root"); Drc->SetRunCherenkov(kFALSE); fRun->AddModule(Drc); //------------------------- DISC ----------------- PndDsk* Dsk = new PndDsk("DSK", kTRUE); Dsk->SetStoreCerenkovs(kFALSE); Dsk->SetStoreTrackPoints(kFALSE); fRun->AddModule(Dsk); //------------------------- MDT ----------------- PndMdt *Muo = new PndMdt("MDT",kTRUE); Muo->SetBarrel("fast"); Muo->SetEndcap("fast"); Muo->SetMuonFilter("fast"); Muo->SetForward("fast"); Muo->SetMdtMagnet(kTRUE); Muo->SetMdtCoil(kTRUE); Muo->SetMdtMFIron(kTRUE); fRun->AddModule(Muo); //------------------------- FTS ----------------- FairDetector *Fts= new PndFts("FTS", kTRUE); Fts->SetGeometryFileName("fts.geo"); fRun->AddModule(Fts); //------------------------- FTOF ----------------- FairDetector *FTof = new PndFtof("FTOF",kTRUE); FTof->SetGeometryFileName("ftofwall.root"); fRun->AddModule(FTof); //------------------------- RICH ---------------- FairDetector *Rich= new PndRich("RICH",kFALSE); Rich->SetGeometryFileName("rich_v2_shift.geo"); fRun->AddModule(Rich); // Create and Set Event Generator //------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); fRun->SetGenerator(primGen); if(UseBoxGenerator){ // Box Generator FairBoxGenerator* boxGenPiM = new FairBoxGenerator(-211, 1); // 13 = muon; 1 = multipl. boxGenPiM->SetPRange(0., 0.6); // GeV/c boxGenPiM->SetPhiRange(0., 360.); // Azimuth angle range [degree] boxGenPiM->SetThetaRange(0., 70); // Polar angle in lab system range [degree] boxGenPiM->SetXYZ(0., 0., 0.); // cm primGen->AddGenerator(boxGenPiM); FairBoxGenerator* boxGenPiP = new FairBoxGenerator(211, 1); // 13 = muon; 1 = multipl. boxGenPiP->SetPRange(0.,0.6); // GeV/c boxGenPiP->SetPhiRange(0., 360.); // Azimuth angle range [degree] boxGenPiP->SetThetaRange(0., 70); // Polar angle in lab system range [degree] boxGenPiP->SetXYZ(0., 0., 0.); // cm primGen->AddGenerator(boxGenPiP); } if(UseDpm){ PndDpmDirect *Dpm= new PndDpmDirect(mom,1); primGen->AddGenerator(Dpm); } if(UseFtf){ // TString macfile = gSystem->Getenv("VMCWORKDIR"); // macfile += "/pgenerators/FtfEvtGen/PbarP.mac"; // PndFtfDirect *Ftf = new PndFtfDirect(macfile.Data()); PndFtfDirect *Ftf = new PndFtfDirect("anti_proton", "G4_H", 1, "ftfp", mom, 123456); primGen->AddGenerator(Ftf); } if(UseEvtGenDirect){ // TString EvtInput =gSystem->Getenv("VMCWORKDIR"); // EvtInput+="/macro/run/psi2s_Jpsi2pi_Jpsi_mumu.dec"; TString EvtInput="/home/ikp1/puetz/panda/mysimulations/analysis/XiMinus_1820_lambda0_K.dec"; // PndEvtGenDirect *EvtGen = new PndEvtGenDirect("pbarpSystem", EvtInput.Data(), mom); PndEvtGenDirect * EvtGen = new PndEvtGenDirect("pbarpSystem", EvtInput.Data(), mom, -1, "", evtPdlFile.Data()); EvtGen->SetStoreTree(kTRUE); primGen->AddGenerator(EvtGen); } //---------------------Create and Set the Field(s)---------- PndMultiField *fField= new PndMultiField("AUTO"); fRun->SetField(fField); // EMC Hit producer //------------------------------- PndEmcHitProducer* emcHitProd = new PndEmcHitProducer(); fRun->AddTask(emcHitProd); //------------------------- Initialize the RUN ----------------- fRun->Init(); //------------------------- Run the Simulation ----------------- fRun->Run(nEvents); //------------------------- Save the parameters ----------------- rtdb->saveOutput(); //------------------------Print some info and exit---------------- 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); };
void run_sim(Int_t nEvents = 10, TString mcEngine = "TGeant3", Int_t fileId = 0) { TString dir = getenv("VMCWORKDIR"); TString tutdir = dir + "/MQ/9-PixelDetector"; TString tut_geomdir = dir + "/common/geometry"; gSystem->Setenv("GEOMPATH",tut_geomdir.Data()); TString tut_configdir = dir + "/common/gconfig"; gSystem->Setenv("CONFIG_DIR",tut_configdir.Data()); TString partName[] = {"pions","eplus","proton"}; Int_t partPdgC[] = { 211, 11, 2212}; Int_t chosenPart = 0; TString outDir = "./"; // Output file name TString outFile; if ( fileId == 0 ) outFile = Form("%s/pixel_%s.mc.root", outDir.Data(), mcEngine.Data()); else outFile = Form("%s/pixel_%s.mc.f%d.root", outDir.Data(), mcEngine.Data(), fileId); // Parameter file name TString parFile = Form("%s/pixel_%s.params.root", outDir.Data(), mcEngine.Data()); // In general, the following parts need not be touched // ======================================================================== // ---- Debug option ------------------------------------------------- gDebug = 0; // ------------------------------------------------------------------------ // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName(mcEngine); // Transport engine run->SetOutputFile(outFile); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // ------------------------------------------------------------------------ // ----- Create media ------------------------------------------------- run->SetMaterials("media.geo"); // Materials // ------------------------------------------------------------------------ // ----- Create geometry ---------------------------------------------- FairModule* cave= new FairCave("CAVE"); cave->SetGeometryFileName("cave_vacuum.geo"); run->AddModule(cave); Pixel* det = new Pixel("Tut9", kTRUE); det->SetGeometryFileName("pixel.geo"); // det->SetMisalignDetector(kTRUE); run->AddModule(det); // ------------------------------------------------------------------------ // ----- Create PrimaryGenerator -------------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); FairBoxGenerator* boxGen = new FairBoxGenerator(partPdgC[chosenPart], 5); boxGen->SetPRange(1,2); boxGen->SetThetaRange(0,40); boxGen->SetPhiRange(0,360); // boxGen->SetDebug(kTRUE); primGen->AddGenerator(boxGen); run->SetGenerator(primGen); // ------------------------------------------------------------------------ run->SetStoreTraj(kFALSE); // ----- Initialize simulation run ------------------------------------ run->Init(); // ------------------------------------------------------------------------ // ----- Runtime database --------------------------------------------- Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(parFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // ------------------------------------------------------------------------ // ----- Start run ---------------------------------------------------- run->Run(nEvents); run->CreateGeometryFile("geofile_full.root"); // ------------------------------------------------------------------------ // ----- Finish ------------------------------------------------------- cout << endl << endl; // Extract the maximal used memory an add is as Dart measurement // This line is filtered by CTest and the value send to CDash FairSystemInfo sysInfo; Float_t maxMemory=sysInfo.GetMaxMemory(); cout << "<DartMeasurement name=\"MaxMemory\" type=\"numeric/double\">"; cout << maxMemory; cout << "</DartMeasurement>" << endl; timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); Float_t cpuUsage=ctime/rtime; cout << "<DartMeasurement name=\"CpuLoad\" type=\"numeric/double\">"; cout << cpuUsage; cout << "</DartMeasurement>" << endl; cout << endl << endl; cout << "Output file is " << outFile << endl; cout << "Parameter file is " << parFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; cout << "Macro finished successfully." << endl; // ------------------------------------------------------------------------ }
sim_upto_emc(Int_t nEvents = 20000) { //-----User Settings:----------------------------------------------- TString OutputFile ="sim_complete_20k_upto_emc.root"; TString ParOutputfile ="simparams_20k_upto_emc.root"; TString MediaFile ="media_pnd.geo"; gDebug = 0; TString digiFile = "all.par"; //The emc run the hit producer directly double BeamMomentum =15.0; // ** change HERE if you run Box generator TString SimEngine ="TGeant4"; //------------------------------------------------------------------ TStopwatch timer; timer.Start(); gRandom->SetSeed(); // Create the Simulation run manager-------------------------------- FairRunSim *fRun = new FairRunSim(); fRun->SetName(SimEngine.Data() ); fRun->SetOutputFile(OutputFile.Data()); fRun->SetWriteRunInfoFile(kFALSE); fRun->SetBeamMom(BeamMomentum); fRun->SetMaterials(MediaFile.Data()); fRun->SetRadLenRegister(true); //fRun->SetRadMapRegister(true); //fRun->SetRadGridRegister(true); FairRuntimeDb *rtdb=fRun->GetRuntimeDb(); // Set the parameters //------------------------------- TString allDigiFile = gSystem->Getenv("VMCWORKDIR"); allDigiFile += "/macro/params/"; allDigiFile += digiFile; //-------Set the parameter output -------------------- FairParAsciiFileIo* parIo1 = new FairParAsciiFileIo(); parIo1->open(allDigiFile.Data(),"in"); rtdb->setFirstInput(parIo1); //---------------------Set Parameter output ---------- Bool_t kParameterMerged=kTRUE; FairParRootFileIo* output=new FairParRootFileIo(kParameterMerged); output->open(ParOutputfile.Data()); rtdb->setOutput(output); // Create and add detectors //------------------------- CAVE ----------------- FairModule *Cave= new PndCave("CAVE"); Cave->SetGeometryFileName("pndcave.geo"); fRun->AddModule(Cave); //------------------------- Magnet ----------------- FairModule *Magnet= new PndMagnet("MAGNET"); //Magnet->SetGeometryFileName("FullSolenoid_V842.root"); Magnet->SetGeometryFileName("FullSuperconductingSolenoid_v831.root"); fRun->AddModule(Magnet); FairModule *Dipole= new PndMagnet("MAGNET"); Dipole->SetGeometryFileName("dipole.geo"); fRun->AddModule(Dipole); //------------------------- Pipe ----------------- FairModule *Pipe= new PndPipe("PIPE"); Pipe->SetGeometryFileName("beampipe_201309.root"); fRun->AddModule(Pipe); //------------------------- STT ----------------- FairDetector *Stt= new PndStt("STT", kTRUE); Stt->SetGeometryFileName("straws_skewed_blocks_35cm_pipe.geo"); fRun->AddModule(Stt); //------------------------- MVD ----------------- FairDetector *Mvd = new PndMvdDetector("MVD", kTRUE); Mvd->SetGeometryFileName("Mvd-2.1_FullVersion.root"); fRun->AddModule(Mvd); //------------------------- GEM ----------------- FairDetector *Gem = new PndGemDetector("GEM", kTRUE); Gem->SetGeometryFileName("gem_3Stations.root"); fRun->AddModule(Gem); //------------------------- EMC ----------------- PndEmc *Emc = new PndEmc("EMC",kTRUE); Emc->SetGeometryVersion(1); Emc->SetStorageOfData(kFALSE); fRun->AddModule(Emc); ////------------------------- SCITIL ----------------- //FairDetector *SciT = new PndSciT("SCIT",kTRUE); //SciT->SetGeometryFileName("barrel-SciTil_07022013.root"); //fRun->AddModule(SciT); // ////------------------------- DRC ----------------- //PndDrc *Drc = new PndDrc("DIRC", kTRUE); //Drc->SetGeometryFileName("dirc_l0_p0_updated.root"); //Drc->SetRunCherenkov(kFALSE); //fRun->AddModule(Drc); // ////------------------------- DISC ----------------- //PndDsk* Dsk = new PndDsk("DSK", kTRUE); //Dsk->SetStoreCerenkovs(kFALSE); //Dsk->SetStoreTrackPoints(kFALSE); //fRun->AddModule(Dsk); // ////------------------------- MDT ----------------- //PndMdt *Muo = new PndMdt("MDT",kTRUE); //Muo->SetBarrel("fast"); //Muo->SetEndcap("fast"); //Muo->SetMuonFilter("fast"); //Muo->SetForward("fast"); //Muo->SetMdtMagnet(kTRUE); //Muo->SetMdtMFIron(kTRUE); //fRun->AddModule(Muo); // ////------------------------- FTS ----------------- //FairDetector *Fts= new PndFts("FTS", kTRUE); //Fts->SetGeometryFileName("fts.geo"); //fRun->AddModule(Fts); // ////------------------------- FTOF ----------------- //FairDetector *FTof = new PndFtof("FTOF",kTRUE); //FTof->SetGeometryFileName("ftofwall.root"); //fRun->AddModule(FTof); // ////------------------------- RICH ---------------- //FairDetector *Rich= new PndRich("RICH",kFALSE); //Rich->SetGeometryFileName("rich_v2_shift.geo"); //fRun->AddModule(Rich); // Create and Set Event Generator //------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); fRun->SetGenerator(primGen); FairBoxGenerator* boxGen = new FairBoxGenerator(0, 1); boxGen->SetPRange(2.0,2.0); // GeV/c boxGen->SetPhiRange(0., 360.); // Azimuth angle range [degree] boxGen->SetThetaRange(0., 180.); // Polar angle in lab system range [degree] boxGen->SetXYZ(0., 0., 0.); // cm primGen->AddGenerator(boxGen); //---------------------Create and Set the Field(s)---------- PndMultiField *fField= new PndMultiField("FULL"); fRun->SetField(fField); // EMC Hit producer //------------------------------- PndEmcHitProducer* emcHitProd = new PndEmcHitProducer(); fRun->AddTask(emcHitProd); //------------------------- Initialize the RUN ----------------- fRun->Init(); //------------------------- Run the Simulation ----------------- fRun->Run(nEvents); //------------------------- Save the parameters ----------------- rtdb->saveOutput(); //------------------------Print some info and exit---------------- 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); }
void run_sim(Int_t nEvents = 100, TString mcEngine = "TGeant4") { // Output file name TString outFile ="test.root"; // Parameter file name TString parFile="params.root"; // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName(mcEngine); // Transport engine run->SetOutputFile(new FairRootFileSink(outFile)); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // ------------------------------------------------------------------------ // ----- Create media ------------------------------------------------- run->SetMaterials("media.geo"); // Materials // ------------------------------------------------------------------------ // ----- Create geometry ---------------------------------------------- FairModule* cave= new MyCave("CAVE"); cave->SetGeometryFileName("cave.geo"); run->AddModule(cave); FairModule* magnet = new MyMagnet("Magnet"); run->AddModule(magnet); FairModule* pipe = new MyPipe("Pipe"); run->AddModule(pipe); FairDetector* NewDet = new NewDetector("TestDetector", kTRUE); run->AddModule(NewDet); // ------------------------------------------------------------------------ // ----- Magnetic field ------------------------------------------- // Constant Field MyConstField *fMagField = new MyConstField(); fMagField->SetField(0., 20. ,0. ); // values are in kG fMagField->SetFieldRegion(-200, 200,-200, 200, -200, 200); // values are in cm // (xmin,xmax,ymin,ymax,zmin,zmax) run->SetField(fMagField); // -------------------------------------------------------------------- // ----- Create PrimaryGenerator -------------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); // Add a box generator also to the run FairBoxGenerator* boxGen = new FairBoxGenerator(13, 5); // 13 = muon; 1 = multipl. boxGen->SetPRange(20,25); // 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.); // cm primGen->AddGenerator(boxGen); run->SetGenerator(primGen); // ------------------------------------------------------------------------ //---Store the visualiztion info of the tracks, this make the output file very large!! //--- Use it only to display but not for production! run->SetStoreTraj(kTRUE); // ----- Initialize simulation run ------------------------------------ run->Init(); // ------------------------------------------------------------------------ // ----- Runtime database --------------------------------------------- Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(parFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // ------------------------------------------------------------------------ // ----- Start run ---------------------------------------------------- run->Run(nEvents); //You can export your ROOT geometry ot a separate file run->CreateGeometryFile("geofile_full.root"); // ------------------------------------------------------------------------ // ----- Finish ------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file is " << outFile << endl; cout << "Parameter file is " << parFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; // ------------------------------------------------------------------------ }
/******************************************************************************** * Copyright (C) 2014 GSI Helmholtzzentrum fuer Schwerionenforschung GmbH * * * * This software is distributed under the terms of the * * GNU Lesser General Public Licence version 3 (LGPL) version 3, * * copied verbatim in the file "LICENSE" * ********************************************************************************/ void run_sim(Int_t nEvents=100, TString mcEngine="TGeant3") { TStopwatch timer; timer.Start(); gDebug=0; // Use non default gconfig and geometry directories TString dir = getenv("VMCWORKDIR"); TString tutdir = dir + "/Tutorial6"; TString ex_geomdir = dir + "/geometry"; gSystem->Setenv("GEOMPATH",ex_geomdir.Data()); TString ex_configdir = dir + "/gconfig"; gSystem->Setenv("CONFIG_DIR",ex_configdir.Data()); // create Instance of Run Manager class FairRunSim *fRun = new FairRunSim(); // set the MC version used // ------------------------ fRun->SetName(mcEngine); TString outfile = "data/testrun_"; outfile = outfile + mcEngine + ".root"; TString outparam = "data/testparams_"; outparam = outparam + mcEngine + ".root"; fRun->SetOutputFile(outfile); // ----- Magnetic field ------------------------------------------- // Constant Field FairConstField *fMagField = new FairConstField(); fMagField->SetField(0., 10. ,0. ); // values are in kG fMagField->SetFieldRegion(-50, 50,-50, 50, 350, 450);// values are in cm (xmin,xmax,ymin,ymax,zmin,zmax) fRun->SetField(fMagField); // -------------------------------------------------------------------- // Set Material file Name //----------------------- fRun->SetMaterials("media.geo"); // Create and add detectors //------------------------- FairModule *Cave= new FairCave("CAVE"); Cave->SetGeometryFileName("cave.geo"); fRun->AddModule(Cave); FairModule *Magnet= new FairMagnet("MAGNET"); Magnet->SetGeometryFileName("magnet.geo"); fRun->AddModule(Magnet); FairDetector *Torino= new FairTestDetector("TORINO", kTRUE); Torino->SetGeometryFileName("torino.geo"); fRun->AddModule(Torino); // Create and Set Event Generator //------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); fRun->SetGenerator(primGen); // Box Generator FairBoxGenerator* boxGen = new FairBoxGenerator(2212, 10); // 13 = muon; 1 = multipl. boxGen->SetPRange(2., 2.); // GeV/c //setPRange vs setPtRange boxGen->SetPhiRange(0, 360); // Azimuth angle range [degree] boxGen->SetThetaRange(3, 10); // Polar angle in lab system range [degree] boxGen->SetCosTheta();//uniform generation on all the solid angle(default) // boxGen->SetXYZ(0., 0.37, 0.); primGen->AddGenerator(boxGen); fRun->SetStoreTraj(kTRUE); fRun->Init(); // -Trajectories Visualization (TGeoManager Only ) // ----------------------------------------------- // Set cuts for storing the trajectpries /* FairTrajFilter* trajFilter = FairTrajFilter::Instance(); 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 //------------------------------------------- FairRuntimeDb *rtdb=fRun->GetRuntimeDb(); Bool_t kParameterMerged=kTRUE; FairParRootFileIo* output=new FairParRootFileIo(kParameterMerged); output->open(outparam); rtdb->setOutput(output); rtdb->saveOutput(); rtdb->print(); // Transport nEvents // ----------------- // Int_t nEvents = 1; fRun->Run(nEvents); TString geoFile = tutdir + "/data/geofile_full.root"; fRun->CreateGeometryFile(geoFile.Data()); timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); printf("RealTime=%f seconds, CpuTime=%f seconds\n",rtime,ctime); cout << "Macro finished successfully." << endl; }
void r3ball_batch(Int_t nEvents = 1, TObjArray& fDetList, TString Target = "LeadTarget", Bool_t fVis=kFALSE, TString fMC="TGeant3", TString fGenerator="box", Bool_t fUserPList= kFALSE, Bool_t fR3BMagnet= kTRUE, Double_t fEnergyP=1.0, Int_t fMult=1, Int_t fGeoVer=5, Double_t fNonUni=1.0 ) { TString dir = getenv("VMCWORKDIR"); TString r3bdir = dir + "/macros"; TString r3b_geomdir = dir + "/geometry"; gSystem->Setenv("GEOMPATH",r3b_geomdir.Data()); TString r3b_confdir = dir + "gconfig"; gSystem->Setenv("CONFIG_DIR",r3b_confdir.Data()); // Output files TString OutFile = "r3bsim.root"; TString ParFile = "r3bpar.root"; // In general, the following parts need not be touched // ======================================================================== // ---- Debug option ------------------------------------------------- gDebug = 0; // ------------------------------------------------------------------------ // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName(fMC.Data()); // Transport engine run->SetOutputFile(OutFile.Data()); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // R3B Special Physics List in G4 case if ( (fUserPList == kTRUE ) && (fMC.CompareTo("TGeant4") == 0) ){ run->SetUserConfig("g4R3bConfig.C"); run->SetUserCuts("SetR3BCuts.C"); } // ----- Create media ------------------------------------------------- run->SetMaterials("media_r3b.geo"); // Materials // Magnetic field map type Int_t fFieldMap = 0; // Global Transformations //- Two ways for a Volume Rotation are supported //-- 1) Global Rotation (Euler Angles definition) //-- This represent the composition of : first a rotation about Z axis with //-- angle phi, then a rotation with theta about the rotated X axis, and //-- finally a rotation with psi about the new Z axis. Double_t phi,theta,psi; //-- 2) Rotation in Ref. Frame of the Volume //-- Rotation is Using Local Ref. Frame axis angles Double_t thetaX,thetaY,thetaZ; //- Global Translation Lab. frame. Double_t tx,ty,tz; // - Polar angular limits Double_t minTheta=35., maxTheta=55.; // ----- Create R3B geometry -------------------------------------------- //R3B Cave definition FairModule* cave= new R3BCave("CAVE"); cave->SetGeometryFileName("r3b_cave.geo"); run->AddModule(cave); //R3B Target definition if (fDetList.FindObject("TARGET") ) { R3BModule* target= new R3BTarget(Target.Data()); // Global Lab. Rotation phi = 0.0; // (deg) theta = 0.0; // (deg) psi = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) //target->SetRotAnglesEuler(phi,theta,psi); target->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); target->SetTranslation(tx,ty,tz); run->AddModule(target); } //R3B Magnet definition if (fDetList.FindObject("ALADIN") ) { fFieldMap = 0; R3BModule* mag = new R3BMagnet("AladinMagnet"); mag->SetGeometryFileName("aladin_v13a.geo.root"); run->AddModule(mag); } //R3B Magnet definition if (fDetList.FindObject("GLAD") ) { fFieldMap = 1; R3BModule* mag = new R3BGladMagnet("GladMagnet"); // Global position of the Module phi = 0.0; // (deg) theta = 0.0; // (deg) psi = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) //mag->SetRotAnglesEuler(phi,theta,psi); mag->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); mag->SetTranslation(tx,ty,tz); run->AddModule(mag); } if (fDetList.FindObject("CRYSTALBALL") ) { //R3B Crystal Calorimeter R3BDetector* xball = new R3BXBall("XBall", kTRUE); xball->SetGeometryFileName("cal_v13a.geo.root"); run->AddModule(xball); } if (fDetList.FindObject("CALIFA") ) { // CALIFA Calorimeter R3BDetector* calo = new R3BCalo("Califa", kTRUE); ((R3BCalo *)calo)->SelectGeometryVersion(10); //Selecting the Non-uniformity of the crystals (1 means +-1% max deviation) ((R3BCalo *)calo)->SetNonUniformity(1.0); calo->SetGeometryFileName("califa_v13_811.geo.root"); run->AddModule(calo); } // Tracker if (fDetList.FindObject("TRACKER") ) { R3BDetector* tra = new R3BTra("Tracker", kTRUE); // Global position of the Module phi = 0.0; // (deg) theta = 0.0; // (deg) psi = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) //tra->SetRotAnglesEuler(phi,theta,psi); tra->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); tra->SetTranslation(tx,ty,tz); // User defined Energy CutOff Double_t fCutOffSi = 1.0e-06; // Cut-Off -> 10KeV only in Si ((R3BTra*) tra)->SetEnergyCutOff(fCutOffSi); run->AddModule(tra); } // DCH drift chambers if (fDetList.FindObject("DCH") ) { R3BDetector* dch = new R3BDch("Dch", kTRUE); ((R3BDch*) dch )->SetHeliumBag(kTRUE); // Global position of the Module phi = 0.0; // (deg) theta = 0.0; // (deg) psi = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) //dch->SetRotAnglesEuler(phi,theta,psi); dch->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); dch->SetTranslation(tx,ty,tz); run->AddModule(dch); } // Tof if (fDetList.FindObject("TOF") ) { R3BDetector* tof = new R3BTof("Tof", kTRUE); // Global position of the Module thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) tof->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); tof->SetTranslation(tx,ty,tz); // User defined Energy CutOff Double_t fCutOffSci = 1.0e-05; // Cut-Off -> 10.KeV only in Sci. ((R3BTof*) tof)->SetEnergyCutOff(fCutOffSci); run->AddModule(tof); } // mTof if (fDetList.FindObject("MTOF") ) { R3BDetector* mTof = new R3BmTof("mTof", kTRUE); // Global position of the Module phi = 0.0; // (deg) theta = 0.0; // (deg) psi = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) //mTof->SetRotAnglesEuler(phi,theta,psi); mTof->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); mTof->SetTranslation(tx,ty,tz); // User defined Energy CutOff Double_t fCutOffSci = 1.0e-05; // Cut-Off -> 10.KeV only in Sci. ((R3BmTof*) mTof)->SetEnergyCutOff(fCutOffSci); run->AddModule(mTof); } // GFI detector if (fDetList.FindObject("GFI") ) { R3BDetector* gfi = new R3BGfi("Gfi", kTRUE); // Global position of the Module phi = 0.0; // (deg) theta = 0.0; // (deg) psi = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) gfi->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); gfi->SetTranslation(tx,ty,tz); // User defined Energy CutOff Double_t fCutOffSci = 1.0e-05; // Cut-Off -> 10.KeV only in Sci. ((R3BGfi*) gfi)->SetEnergyCutOff(fCutOffSci); run->AddModule(gfi); } // Land Detector if (fDetList.FindObject("LAND") ) { R3BDetector* land = new R3BLand("Land", kTRUE); land->SetGeometryFileName("land_v12a_10m.geo.root"); run->AddModule(land); } // Chimera if (fDetList.FindObject("CHIMERA") ) { R3BDetector* chim = new R3BChimera("Chimera", kTRUE); chim->SetGeometryFileName("chimera.root"); // Global position of the Module thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) chim->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); chim->SetTranslation(tx,ty,tz); // User defined Energy CutOff //Double_t fCutOffSci = 1.0e-05; // Cut-Off -> 10.KeV only in Sci. //((R3BChimera*) chim)->SetEnergyCutOff(fCutOffSci); run->AddModule(chim); } // Luminosity detector if (fDetList.FindObject("LUMON") ) { R3BDetector* lumon = new ELILuMon("LuMon", kTRUE); //lumon->SetGeometryFileName("lumon.root"); // Global position of the Module thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 200.0; // (cm) lumon->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); lumon->SetTranslation(tx,ty,tz); // User defined Energy CutOff //Double_t fCutOffSci = 1.0e-05; // Cut-Off -> 10.KeV only in Sci. //((ELILuMon*) lumon)->SetEnergyCutOff(fCutOffSci); run->AddModule(lumon); } // ----- Create R3B magnetic field ---------------------------------------- Int_t typeOfMagneticField = 0; Int_t fieldScale = 1; Bool_t fVerbose = kFALSE; //NB: <D.B> // If the Global Position of the Magnet is changed // the Field Map has to be transformed accordingly if (fFieldMap == 0) { R3BFieldMap* magField = new R3BFieldMap(typeOfMagneticField,fVerbose); magField->SetPosition(0., 0., 0.); magField->SetScale(fieldScale); if ( fR3BMagnet == kTRUE ) { run->SetField(magField); } else { run->SetField(NULL); } } else if(fFieldMap == 1){ R3BGladFieldMap* magField = new R3BGladFieldMap("R3BGladMap"); magField->SetPosition(0., 0., +350-119.94); magField->SetScale(fieldScale); if ( fR3BMagnet == kTRUE ) { run->SetField(magField); } else { run->SetField(NULL); } } //! end of field map section // ----- Create PrimaryGenerator -------------------------------------- // 1 - Create the Main API class for the Generator FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); if (fGenerator.CompareTo("box") == 0 ) { // 2- Define the BOX generator Double_t pdgId=211; // pion beam Double_t theta1= 0.; // polar angle distribution Double_t theta2= 7.; Double_t momentum=.8; // 10 GeV/c FairBoxGenerator* boxGen = new FairBoxGenerator(pdgId, 50); boxGen->SetThetaRange ( theta1, theta2); boxGen->SetPRange (momentum,momentum*2.); boxGen->SetPhiRange (0.,360.); boxGen->SetXYZ(0.0,0.0,-1.5); // add the box generator primGen->AddGenerator(boxGen); } if (fGenerator.CompareTo("gammas") == 0 ) { // 2- Define the CALIFA Test gamma generator Double_t pdgId=22; // 22 for gamma emission, 2212 for proton emission Double_t theta1=minTheta; // polar angle distribution: lower edge Double_t theta2=maxTheta; // polar angle distribution: upper edge Double_t momentum=fEnergyP; // GeV/c //Double_t momentum=0.808065; // 0.808065 GeV/c (300MeV Kin Energy for protons) //Double_t momentum=0.31016124; // 0.31016124 GeV/c (50MeV Kin Energy for protons) //Double_t momentum=0.4442972; // 0.4442972 GeV/c (100MeV Kin Energy for protons) //Double_t momentum=0.5509999; // 0.5509999 GeV/c (150MeV Kin Energy for protons) //Double_t momentum=0.64405; // 0.64405 GeV/c (200MeV Kin Energy for protons) Int_t multiplicity = fMult; R3BCALIFATestGenerator* gammasGen = new R3BCALIFATestGenerator(pdgId, multiplicity); gammasGen->SetThetaRange(theta1,theta2); gammasGen->SetCosTheta(); gammasGen->SetPRange(momentum,momentum); gammasGen->SetPhiRange(0.,360.); gammasGen->SetBoxXYZ(-0.1,0.1,-0.1,0.1,-0.1,0.1); gammasGen->SetLorentzBoost(0.8197505718204776); //beta=0.81975 for 700 A MeV // add the gamma generator primGen->AddGenerator(gammasGen); } if (fGenerator.CompareTo("r3b") == 0 ) { R3BSpecificGenerator *pR3bGen = new R3BSpecificGenerator(); // R3bGen properties pR3bGen->SetBeamInteractionFlag("off"); pR3bGen->SetBeamInteractionFlag("off"); pR3bGen->SetRndmFlag("off"); pR3bGen->SetRndmEneFlag("off"); pR3bGen->SetBoostFlag("off"); pR3bGen->SetReactionFlag("on"); pR3bGen->SetGammasFlag("off"); pR3bGen->SetDecaySchemeFlag("off"); pR3bGen->SetDissociationFlag("off"); pR3bGen->SetBackTrackingFlag("off"); pR3bGen->SetSimEmittanceFlag("off"); // R3bGen Parameters pR3bGen->SetBeamEnergy(1.); // Beam Energy in GeV pR3bGen->SetSigmaBeamEnergy(1.e-03); // Sigma(Ebeam) GeV pR3bGen->SetParticleDefinition(2212); // Use Particle Pdg Code pR3bGen->SetEnergyPrim(0.3); // Particle Energy in MeV Int_t fMultiplicity = 50; pR3bGen->SetNumberOfParticles(fMultiplicity); // Mult. // Reaction type // 1: "Elas" // 2: "iso" // 3: "Trans" pR3bGen->SetReactionType("Elas"); // Target type // 1: "LeadTarget" // 2: "Parafin0Deg" // 3: "Parafin45Deg" // 4: "LiH" pR3bGen->SetTargetType(Target.Data()); Double_t thickness = (0.11/2.)/10.; // cm pR3bGen->SetTargetHalfThicknessPara(thickness); // cm pR3bGen->SetTargetThicknessLiH(3.5); // cm pR3bGen->SetTargetRadius(1.); // cm pR3bGen->SetSigmaXInEmittance(1.); //cm pR3bGen->SetSigmaXPrimeInEmittance(0.0001); //cm // Dump the User settings pR3bGen->PrintParameters(); primGen->AddGenerator(pR3bGen); } run->SetGenerator(primGen); //-------Set visualisation flag to true------------------------------------ if (fVis==kTRUE){ run->SetStoreTraj(kTRUE); }else{ run->SetStoreTraj(kFALSE); } // ----- Initialize simulation run ------------------------------------ run->Init(); // ------ Increase nb of step for CALO Int_t nSteps = -15000; gMC->SetMaxNStep(nSteps); // ----- Runtime database --------------------------------------------- Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(ParFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // ----- Start run ---------------------------------------------------- if (nEvents>0) run->Run(nEvents); // ----- Finish ------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file is " << OutFile << endl; cout << "Parameter file is " << ParFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; // ------------------------------------------------------------------------ cout << " Test passed" << endl; cout << " All ok " << endl; }
void run_tutorial4(Int_t nEvents = 10) { TString dir = getenv("VMCWORKDIR"); TString tutdir = dir + "/Tutorial4"; TString tut_geomdir = dir + "/geometry"; gSystem->Setenv("GEOMPATH",tut_geomdir.Data()); TString tut_configdir = dir + "/Tutorial4/macros/gconfig"; gSystem->Setenv("CONFIG_DIR",tut_configdir.Data()); Double_t momentum = 2.; Double_t theta = 2.; TString outDir = "./"; // Output file name TString outFile ="data/testrun.root"; TString parFile ="data/testparams.root"; TList *parFileList = new TList(); TString workDir = gSystem->Getenv("VMCWORKDIR"); paramDir = workDir + "/Tutorial4/macros/parameters/"; TObjString tutDetDigiFile = paramDir + "example.par"; parFileList->Add(&tutDetDigiFile); // In general, the following parts need not be touched // ======================================================================== // ---- Debug option ------------------------------------------------- gDebug = 0; // ------------------------------------------------------------------------ // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ //Does not work with automatic loading pf libraries. The info is not in the rootmap file // gLogger->SetLogScreenLevel("INFO"); // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName("TGeant3"); // Transport engine run->SetOutputFile(outFile); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // ------------------------------------------------------------------------ // ----- Create media ------------------------------------------------- run->SetMaterials("media.geo"); // Materials // ------------------------------------------------------------------------ // ----- Create geometry ---------------------------------------------- FairModule* cave= new FairCave("CAVE"); cave->SetGeometryFileName("cave_vacuum.geo"); run->AddModule(cave); FairTutorialDet4* tutdet = new FairTutorialDet4("TUTDET", kTRUE); tutdet->SetGeometryFileName("tutorial4.root"); tutdet->SetModifyGeometry(kTRUE); run->AddModule(tutdet); // ------------------------------------------------------------------------ // ----- Create PrimaryGenerator -------------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); FairBoxGenerator* boxGen = new FairBoxGenerator(2212, 1); boxGen->SetThetaRange ( theta, theta+0.1); // boxGen->SetThetaRange ( 0., 0.); boxGen->SetPRange (momentum,momentum+0.01); boxGen->SetPhiRange (0.,360.); boxGen->SetBoxXYZ (-20.,-20.,20.,20., 0.); // boxGen->SetBoxXYZ (0.,0.,0.,0., 0.); // boxGen->SetDebug(kTRUE); primGen->AddGenerator(boxGen); run->SetGenerator(primGen); // ------------------------------------------------------------------------ // ----- Initialize simulation run ------------------------------------ run->SetStoreTraj(kTRUE); // ----- Runtime database --------------------------------------------- Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); FairParAsciiFileIo* parIn = new FairParAsciiFileIo(); parOut->open(parFile.Data()); parIn->open(parFileList, "in"); rtdb->setFirstInput(parIn); rtdb->setOutput(parOut); // ------------------------------------------------------------------------ run->Init(); // -Trajectories Visualization (TGeoManager Only ) // ----------------------------------------------- // Set cuts for storing the trajectpries /* FairTrajFilter* trajFilter = FairTrajFilter::Instance(); 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); */ // ------------------------------------------------------------------------ // ----- Start run ---------------------------------------------------- run->Run(nEvents); run->CreateGeometryFile("data/geofile_full.root"); // ------------------------------------------------------------------------ rtdb->saveOutput(); rtdb->print(); delete run; // ----- Finish ------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file is " << outFile << endl; cout << "Parameter file is " << parFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; // ------------------------------------------------------------------------ cout << " Test passed" << endl; cout << " All ok " << endl; }
/******************************************************************************** * Copyright (C) 2014 GSI Helmholtzzentrum fuer Schwerionenforschung GmbH * * * * This software is distributed under the terms of the * * GNU Lesser General Public Licence version 3 (LGPL) version 3, * * copied verbatim in the file "LICENSE" * ********************************************************************************/ void run_tutorial1_mesh(Int_t nEvents = 10, TString mcEngine = "TGeant3") { TString dir = getenv("VMCWORKDIR"); TString tutdir = dir + "/Tutorial1"; TString tut_geomdir = dir + "/geometry"; gSystem->Setenv("GEOMPATH",tut_geomdir.Data()); TString tut_configdir = dir + "/gconfig"; gSystem->Setenv("CONFIG_DIR",tut_configdir.Data()); TString partName[] = {"pions","eplus","proton"}; Int_t partPdgC[] = { 211, 11, 2212}; Int_t chosenPart = 0; Double_t momentum = 2.; Double_t theta = 0.; TString outDir = "./"; // Output file name TString outFile = Form("%s/tutorial1_mesh%s_%s.mc_p%1.3f_t%1.0f_n%d.root", outDir.Data(), mcEngine.Data(), partName[chosenPart].Data(), momentum, theta, nEvents); // Parameter file name TString parFile = Form("%s/tutorial1_mesh%s_%s.params_p%1.3f_t%1.0f_n%d.root", outDir.Data(), mcEngine.Data(), partName[chosenPart].Data(), momentum, theta, nEvents); // In general, the following parts need not be touched // ======================================================================== // ---- Debug option ------------------------------------------------- gDebug = 0; // ------------------------------------------------------------------------ // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName(mcEngine); // Transport engine run->SetOutputFile(outFile); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // ------------------------------------------------------------------------ // ----- Create media ------------------------------------------------- run->SetMaterials("media.geo"); // Materials // ------------------------------------------------------------------------ // ----- Create geometry ---------------------------------------------- FairModule* cave= new FairCave("CAVE"); cave->SetGeometryFileName("cave_vacuum.geo"); run->AddModule(cave); FairDetector* tutdet = new FairTutorialDet1("TUTDET", kTRUE); tutdet->SetGeometryFileName("double_sector.geo"); run->AddModule(tutdet); // ------------------------------------------------------------------------ // ----- Create PrimaryGenerator -------------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); FairBoxGenerator* boxGen = new FairBoxGenerator(partPdgC[chosenPart], 1); boxGen->SetThetaRange ( theta, theta+0.01); boxGen->SetPRange (momentum,momentum+0.01); boxGen->SetPhiRange (0.,360.); boxGen->SetDebug(kTRUE); primGen->AddGenerator(boxGen); run->SetGenerator(primGen); // ------------------------------------------------------------------------ run->SetStoreTraj(kFALSE); // to store particle trajectories run->SetRadGridRegister(kTRUE); // activate RadGridManager // define two example meshs for dosimetry FairMesh* aMesh1 = new FairMesh("test1"); aMesh1->SetX(-40,40,200); aMesh1->SetY(-40,40,200); aMesh1->SetZ(5.2,5.4,1); FairMesh* aMesh2 = new FairMesh("test2"); aMesh2->SetX(-20,20,20); aMesh2->SetY(-20,20,20); aMesh2->SetZ(-5.0,5.0,1); aMesh1->print(); aMesh2->print(); run->AddMesh( aMesh1 ); run->AddMesh( aMesh2 ); // ----- Initialize simulation run ------------------------------------ run->Init(); // ------------------------------------------------------------------------ // ----- Runtime database --------------------------------------------- Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(parFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // ------------------------------------------------------------------------ // ----- Start run ---------------------------------------------------- run->Run(nEvents); // ------------------------------------------------------------------------ // ----- Finish ------------------------------------------------------- cout << endl << endl; // Extract the maximal used memory an add is as Dart measurement // This line is filtered by CTest and the value send to CDash FairSystemInfo sysInfo; Float_t maxMemory=sysInfo.GetMaxMemory(); cout << "<DartMeasurement name=\"MaxMemory\" type=\"numeric/double\">"; cout << maxMemory; cout << "</DartMeasurement>" << endl; timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); Float_t cpuUsage=ctime/rtime; cout << "<DartMeasurement name=\"CpuLoad\" type=\"numeric/double\">"; cout << cpuUsage; cout << "</DartMeasurement>" << endl; cout << endl << endl; cout << "Output file is " << outFile << endl; cout << "Parameter file is " << parFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; cout << "Macro finished successfully." << endl; // ------------------------------------------------------------------------ }
emc_complete(Int_t nEvents = 10, Float_t mom = 1., Int_t charge = 1, TString phys_list, Bool_t full_panda, TString out_dat, TString out_par){ TStopwatch timer; timer.Start(); gDebug=0; // Load basic libraries // If it does not work, please check the path of the libs and put it by hands gROOT->LoadMacro("$VMCWORKDIR/gconfig/rootlogon.C"); gROOT->LoadMacro("$VMCWORKDIR/gconfig/basiclibs.C"); rootlogon(); basiclibs(); //gSystem->ListLibraries(); FairRunSim *fRun = new FairRunSim(); // set the MC version used // ------------------------ Bool_t G3 = strncmp(phys_list.Data(),"G3_",3)==0; cout << "Setting up MC engine to " << (G3?"TGeant3":"TGeant4") << " with " << (full_panda?"full PANDA":"EMCal only")<< endl; fRun->SetName(G3?"TGeant3":"TGeant4"); fRun->SetOutputFile(out_dat); /**Get the run time data base for this session and set the needed input*/ FairRuntimeDb* rtdb = fRun->GetRuntimeDb(); /**Set the digitization parameters */ TString emcDigiFile = gSystem->Getenv("VMCWORKDIR"); emcDigiFile += "/macro/params/emc.par"; FairParAsciiFileIo* parIo1 = new FairParAsciiFileIo(); parIo1->open(emcDigiFile.Data(),"in"); rtdb->setFirstInput(parIo1); /**Parameters created for this simulation goes to the out put*/ Bool_t kParameterMerged=kTRUE; FairParRootFileIo* output=new FairParRootFileIo(kParameterMerged); output->open(out_par); rtdb->setOutput(output); // Set Material file Name //----------------------- fRun->SetMaterials("media_pnd.geo"); // Create and add detectors //------------------------- FairModule *Cave= new PndCave("CAVE"); Cave->SetGeometryFileName("pndcave.geo"); fRun->AddModule(Cave); if (full_panda) { //------------------------- Magnet ----------------- FairModule *Magnet= new PndMagnet("MAGNET"); //Magnet->SetGeometryFileName("FullSolenoid_V842.root"); Magnet->SetGeometryFileName("FullSuperconductingSolenoid_v831.root"); fRun->AddModule(Magnet); FairModule *Dipole= new PndMagnet("MAGNET"); Dipole->SetGeometryFileName("dipole.geo"); fRun->AddModule(Dipole); //------------------------- Pipe ----------------- FairModule *Pipe= new PndPipe("PIPE"); Pipe->SetGeometryFileName("beampipe_201112.root"); fRun->AddModule(Pipe); //------------------------- STT ----------------- FairDetector *Stt= new PndStt("STT", kTRUE); Stt->SetGeometryFileName("straws_skewed_blocks_35cm_pipe.geo"); fRun->AddModule(Stt); //------------------------- MVD ----------------- FairDetector *Mvd = new PndMvdDetector("MVD", kTRUE); Mvd->SetGeometryFileName("Mvd-2.1_FullVersion.root"); fRun->AddModule(Mvd); //------------------------- GEM ----------------- FairDetector *Gem = new PndGemDetector("GEM", kTRUE); Gem->SetGeometryFileName("gem_3Stations.root"); fRun->AddModule(Gem); } //------------------------- EMC ----------------- PndEmc *Emc = new PndEmc("EMC",kTRUE); Emc->SetGeometryVersion(1); Emc->SetStorageOfData(kFALSE); fRun->AddModule(Emc); if (full_panda) { //------------------------- SCITIL ----------------- FairDetector *SciT = new PndSciT("SCIT",kTRUE); SciT->SetGeometryFileName("barrel-SciTil_07022013.root"); fRun->AddModule(SciT); //------------------------- DRC ----------------- PndDrc *Drc = new PndDrc("DIRC", kTRUE); Drc->SetGeometryFileName("dirc_l0_p0_updated.root"); Drc->SetRunCherenkov(kFALSE); fRun->AddModule(Drc); //------------------------- DISC ----------------- PndDsk* Dsk = new PndDsk("DSK", kTRUE); Dsk->SetStoreCerenkovs(kFALSE); Dsk->SetStoreTrackPoints(kFALSE); fRun->AddModule(Dsk); //------------------------- MDT ----------------- PndMdt *Muo = new PndMdt("MDT",kTRUE); Muo->SetBarrel("fast"); Muo->SetEndcap("fast"); Muo->SetMuonFilter("fast"); Muo->SetForward("fast"); Muo->SetMdtMagnet(kTRUE); Muo->SetMdtMFIron(kTRUE); fRun->AddModule(Muo); //------------------------- FTS ----------------- FairDetector *Fts= new PndFts("FTS", kTRUE); Fts->SetGeometryFileName("fts.geo"); fRun->AddModule(Fts); //------------------------- FTOF ----------------- FairDetector *FTof = new PndFtof("FTOF",kTRUE); FTof->SetGeometryFileName("ftofwall.root"); fRun->AddModule(FTof); //------------------------- RICH ---------------- FairDetector *Rich= new PndRich("RICH",kFALSE); Rich->SetGeometryFileName("rich_v2.geo"); fRun->AddModule(Rich); } // Create and Set Event Generator //------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); fRun->SetGenerator(primGen); // Box Generator. first number: PDG particle code: 2nd number: particle multiplicity per event FairBoxGenerator* boxGen = new FairBoxGenerator(charge*211, 1); // 13 = muon // 1 = multipl. // 211 = pi+ // -211 = pi- boxGen->SetPRange(mom,mom); // GeV/c // boxGen->SetPtRange(1.,1.); // GeV/c boxGen->SetPhiRange(0., 360.); // Azimuth angle range [degree] boxGen->SetThetaRange(85., 95.); // Polar angle in lab system range [degree] - restrict to small rapidity boxGen->SetXYZ(0., 0., 0.); // vertex coordinates [mm] primGen->AddGenerator(boxGen); fRun->SetStoreTraj(kTRUE); // to store particle trajectories fRun->SetBeamMom(15); //---------------------Create and Set the Field(s)---------- PndMultiField *fField= new PndMultiField("FULL"); fRun->SetField(fField); //----------- Add Hit producer task to the simulation ------ PndEmcHitProducer* emcHitProd = new PndEmcHitProducer(); emcHitProd->SetStorageOfData(kFALSE); fRun->AddTask(emcHitProd); PndEmcHitsToWaveform* emcHitsToWaveform= new PndEmcHitsToWaveform(0); PndEmcWaveformToDigi* emcWaveformToDigi=new PndEmcWaveformToDigi(0); //emcHitsToWaveform->SetStorageOfData(kFALSE); //emcWaveformToDigi->SetStorageOfData(kFALSE); fRun->AddTask(emcHitsToWaveform); // full digitization fRun->AddTask(emcWaveformToDigi); // full digitization PndEmcMakeCluster* emcMakeCluster= new PndEmcMakeCluster(0); //emcMakeCluster->SetStorageOfData(kFALSE); fRun->AddTask(emcMakeCluster); PndEmcHdrFiller* emcHdrFiller = new PndEmcHdrFiller(); fRun->AddTask(emcHdrFiller); // ECM header PndEmcMakeBump* emcMakeBump= new PndEmcMakeBump(); //emcMakeBump->SetStorageOfData(kFALSE); fRun->AddTask(emcMakeBump); PndEmcMakeRecoHit* emcMakeRecoHit= new PndEmcMakeRecoHit(); fRun->AddTask(emcMakeRecoHit); /**Initialize the session*/ fRun->Init(); PndEmcMapper *emcMap = PndEmcMapper::Init(1); /**After initialization now we can save the field parameters */ PndMultiFieldPar* Par = (PndMultiFieldPar*) rtdb->getContainer("PndMultiFieldPar"); if (fField) { Par->SetParameters(fField); } Par->setInputVersion(fRun->GetRunId(),1); Par->setChanged(); /**All parameters are initialized and ready to be saved*/ rtdb->saveOutput(); rtdb->print(); // Transport nEvents // ----------------- fRun->Run(nEvents); timer.Stop(); printf("RealTime=%f seconds, CpuTime=%f seconds\n",timer.RealTime(),timer.CpuTime()); }
void r3ball(Int_t nEvents = 1, TMap* fDetList = NULL, TString Target = "LeadTarget", Bool_t fVis = kFALSE, TString fMC = "TGeant3", TString fGenerator = "box", Bool_t fUserPList = kFALSE, Bool_t fR3BMagnet = kTRUE, Double_t fMeasCurrent = 2000., TString OutFile = "r3bsim.root", TString ParFile = "r3bpar.root", TString InFile = "evt_gen.dat") { TString dir = getenv("VMCWORKDIR"); TString r3bdir = dir + "/macros"; TString r3b_geomdir = dir + "/geometry"; gSystem->Setenv("GEOMPATH",r3b_geomdir.Data()); TString r3b_confdir = dir + "gconfig"; gSystem->Setenv("CONFIG_DIR",r3b_confdir.Data()); // In general, the following parts need not be touched // ======================================================================== // ---- Debug option ------------------------------------------------- gDebug = 0; // ------------------------------------------------------------------------ // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName(fMC.Data()); // Transport engine run->SetOutputFile(OutFile.Data()); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // R3B Special Physics List in G4 case if ( (fUserPList == kTRUE ) && (fMC.CompareTo("TGeant4") == 0)) { run->SetUserConfig("g4R3bConfig.C"); run->SetUserCuts("SetR3BCuts.C"); } // ----- Create media ------------------------------------------------- run->SetMaterials("media_r3b.geo"); // Materials // Magnetic field map type Int_t fFieldMap = 0; // Global Transformations //- Two ways for a Volume Rotation are supported //-- 1) Global Rotation (Euler Angles definition) //-- This represent the composition of : first a rotation about Z axis with //-- angle phi, then a rotation with theta about the rotated X axis, and //-- finally a rotation with psi about the new Z axis. Double_t phi,theta,psi; //-- 2) Rotation in Ref. Frame of the Volume //-- Rotation is Using Local Ref. Frame axis angles Double_t thetaX,thetaY,thetaZ; //- Global Translation Lab. frame. Double_t tx,ty,tz; // ----- Create R3B geometry -------------------------------------------- //R3B Cave definition FairModule* cave= new R3BCave("CAVE"); cave->SetGeometryFileName("r3b_cave.geo"); run->AddModule(cave); //R3B Target definition if (fDetList->FindObject("TARGET") ) { R3BModule* target= new R3BTarget(Target.Data()); target->SetGeometryFileName(((TObjString*)fDetList->GetValue("TARGET"))->GetString().Data()); run->AddModule(target); } //R3B SiTracker Cooling definition if (fDetList->FindObject("VACVESSELCOOL") ) { R3BModule* vesselcool= new R3BVacVesselCool(Target.Data()); vesselcool->SetGeometryFileName(((TObjString*)fDetList->GetValue("VACVESSELCOOL"))->GetString().Data()); run->AddModule(vesselcool); } //R3B Magnet definition if (fDetList->FindObject("ALADIN") ) { fFieldMap = 0; R3BModule* mag = new R3BMagnet("AladinMagnet"); mag->SetGeometryFileName(((TObjString*)fDetList->GetValue("ALADIN"))->GetString().Data()); run->AddModule(mag); } //R3B Magnet definition if (fDetList->FindObject("GLAD") ) { fFieldMap = 1; R3BModule* mag = new R3BGladMagnet("GladMagnet"); mag->SetGeometryFileName(((TObjString*)fDetList->GetValue("GLAD"))->GetString().Data()); run->AddModule(mag); } if (fDetList->FindObject("CRYSTALBALL") ) { //R3B Crystal Calorimeter R3BDetector* xball = new R3BXBall("XBall", kTRUE); xball->SetGeometryFileName(((TObjString*)fDetList->GetValue("CRYSTALBALL"))->GetString().Data()); run->AddModule(xball); } if (fDetList->FindObject("CALIFA") ) { // CALIFA Calorimeter R3BDetector* calo = new R3BCalo("Califa", kTRUE); ((R3BCalo *)calo)->SelectGeometryVersion(10); //Selecting the Non-uniformity of the crystals (1 means +-1% max deviation) ((R3BCalo *)calo)->SetNonUniformity(1.0); calo->SetGeometryFileName(((TObjString*)fDetList->GetValue("CALIFA"))->GetString().Data()); run->AddModule(calo); } // Tracker if (fDetList->FindObject("TRACKER") ) { R3BDetector* tra = new R3BTra("Tracker", kTRUE); tra->SetGeometryFileName(((TObjString*)fDetList->GetValue("TRACKER"))->GetString().Data()); tra->SetEnergyCut(1e-4); run->AddModule(tra); } // STaRTrack if (fDetList->FindObject("STaRTrack") ) { R3BDetector* tra = new R3BSTaRTra("STaRTrack", kTRUE); tra->SetGeometryFileName(((TObjString*)fDetList->GetValue("STaRTrack"))->GetString().Data()); run->AddModule(tra); } // DCH drift chambers if (fDetList->FindObject("DCH") ) { R3BDetector* dch = new R3BDch("Dch", kTRUE); dch->SetGeometryFileName(((TObjString*)fDetList->GetValue("DCH"))->GetString().Data()); run->AddModule(dch); } // Tof if (fDetList->FindObject("TOF") ) { R3BDetector* tof = new R3BTof("Tof", kTRUE); tof->SetGeometryFileName(((TObjString*)fDetList->GetValue("TOF"))->GetString().Data()); run->AddModule(tof); } // mTof if (fDetList->FindObject("MTOF") ) { R3BDetector* mTof = new R3BmTof("mTof", kTRUE); mTof->SetGeometryFileName(((TObjString*)fDetList->GetValue("MTOF"))->GetString().Data()); run->AddModule(mTof); } // dTof if (fDetList->FindObject("DTOF") ) { R3BDetector* dTof = new R3BdTof("dTof", kTRUE); dTof->SetGeometryFileName(((TObjString*)fDetList->GetValue("DTOF"))->GetString().Data()); run->AddModule(dTof); } // GFI detector if (fDetList->FindObject("GFI") ) { R3BDetector* gfi = new R3BGfi("Gfi", kTRUE); gfi->SetGeometryFileName(((TObjString*)fDetList->GetValue("GFI"))->GetString().Data()); run->AddModule(gfi); } // Land Detector if (fDetList->FindObject("LAND") ) { R3BDetector* land = new R3BLand("Land", kTRUE); land->SetVerboseLevel(1); land->SetGeometryFileName(((TObjString*)fDetList->GetValue("LAND"))->GetString().Data()); run->AddModule(land); } // NeuLand Scintillator Detector if(fDetList->FindObject("SCINTNEULAND")) { R3BDetector* land = new R3BLand("Land", kTRUE); land->SetVerboseLevel(1); land->SetGeometryFileName(((TObjString*)fDetList->GetValue("SCINTNEULAND"))->GetString().Data()); run->AddModule(land); } // MFI Detector if(fDetList->FindObject("MFI")) { R3BDetector* mfi = new R3BMfi("Mfi", kTRUE); mfi->SetGeometryFileName(((TObjString*)fDetList->GetValue("MFI"))->GetString().Data()); run->AddModule(mfi); } // PSP Detector if(fDetList->FindObject("PSP")) { R3BDetector* psp = new R3BPsp("Psp", kTRUE); psp->SetGeometryFileName(((TObjString*)fDetList->GetValue("PSP"))->GetString().Data()); run->AddModule(psp); } // Luminosity detector if (fDetList->FindObject("LUMON") ) { R3BDetector* lumon = new ELILuMon("LuMon", kTRUE); lumon->SetGeometryFileName(((TObjString*)fDetList->GetValue("LUMON"))->GetString().Data()); run->AddModule(lumon); } // ----- Create R3B magnetic field ---------------------------------------- Int_t typeOfMagneticField = 0; Int_t fieldScale = 1; Bool_t fVerbose = kFALSE; //NB: <D.B> // If the Global Position of the Magnet is changed // the Field Map has to be transformed accordingly FairField *magField = NULL; if (fFieldMap == 0) { magField = new R3BAladinFieldMap("AladinMaps"); ((R3BAladinFieldMap*)magField)->SetCurrent(fMeasCurrent); ((R3BAladinFieldMap*)magField)->SetScale(fieldScale); if ( fR3BMagnet == kTRUE ) { run->SetField(magField); } else { run->SetField(NULL); } } else if(fFieldMap == 1){ magField = new R3BGladFieldMap("R3BGladMap"); ((R3BGladFieldMap*)magField)->SetPosition(0., 0., +350-119.94); ((R3BGladFieldMap*)magField)->SetScale(fieldScale); if ( fR3BMagnet == kTRUE ) { run->SetField(magField); } else { run->SetField(NULL); } } //! end of field map section // ----- Create PrimaryGenerator -------------------------------------- // 1 - Create the Main API class for the Generator FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); if (fGenerator.CompareTo("box") == 0 ) { // 2- Define the BOX generator Int_t pdgId = 211; // pion beam Double32_t theta1 = 0.; // polar angle distribution Double32_t theta2 = 7.; Double32_t momentum = 0.8; FairBoxGenerator* boxGen = new FairBoxGenerator(pdgId, 50); boxGen->SetThetaRange(theta1, theta2); boxGen->SetPRange(momentum, momentum*2.); boxGen->SetPhiRange(0, 360); boxGen->SetXYZ(0.0, 0.0, -1.5); // boxGen->SetXYZ(0.0, 0.0, -300.); // add the box generator primGen->AddGenerator(boxGen); } if (fGenerator.CompareTo("ascii") == 0 ) { R3BAsciiGenerator* gen = new R3BAsciiGenerator((dir+"/input/"+InFile).Data()); primGen->AddGenerator(gen); } if (fGenerator.CompareTo("r3b") == 0 ) { R3BSpecificGenerator *pR3bGen = new R3BSpecificGenerator(); // R3bGen properties pR3bGen->SetBeamInteractionFlag("off"); pR3bGen->SetBeamInteractionFlag("off"); pR3bGen->SetRndmFlag("off"); pR3bGen->SetRndmEneFlag("off"); pR3bGen->SetBoostFlag("off"); pR3bGen->SetReactionFlag("on"); pR3bGen->SetGammasFlag("off"); pR3bGen->SetDecaySchemeFlag("off"); pR3bGen->SetDissociationFlag("off"); pR3bGen->SetBackTrackingFlag("off"); pR3bGen->SetSimEmittanceFlag("off"); // R3bGen Parameters pR3bGen->SetBeamEnergy(1.); // Beam Energy in GeV pR3bGen->SetSigmaBeamEnergy(1.e-03); // Sigma(Ebeam) GeV pR3bGen->SetParticleDefinition(2212); // Use Particle Pdg Code pR3bGen->SetEnergyPrim(0.3); // Particle Energy in MeV Int_t fMultiplicity = 50; pR3bGen->SetNumberOfParticles(fMultiplicity); // Mult. // Reaction type // 1: "Elas" // 2: "iso" // 3: "Trans" pR3bGen->SetReactionType("Elas"); // Target type // 1: "LeadTarget" // 2: "Parafin0Deg" // 3: "Parafin45Deg" // 4: "LiH" pR3bGen->SetTargetType(Target.Data()); Double_t thickness = (0.11/2.)/10.; // cm pR3bGen->SetTargetHalfThicknessPara(thickness); // cm pR3bGen->SetTargetThicknessLiH(3.5); // cm pR3bGen->SetTargetRadius(1.); // cm pR3bGen->SetSigmaXInEmittance(1.); //cm pR3bGen->SetSigmaXPrimeInEmittance(0.0001); //cm // Dump the User settings pR3bGen->PrintParameters(); primGen->AddGenerator(pR3bGen); } run->SetGenerator(primGen); //-------Set visualisation flag to true------------------------------------ run->SetStoreTraj(fVis); FairLogger::GetLogger()->SetLogVerbosityLevel("LOW"); // ----- Initialize simulation run ------------------------------------ run->Init(); // ------ Increase nb of step for CALO Int_t nSteps = -15000; gMC->SetMaxNStep(nSteps); // ----- Runtime database --------------------------------------------- R3BFieldPar* fieldPar = (R3BFieldPar*) rtdb->getContainer("R3BFieldPar"); if(NULL != magField) { fieldPar->SetParameters(magField); fieldPar->setChanged(); } Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(ParFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // ----- Start run ---------------------------------------------------- if(nEvents > 0) { run->Run(nEvents); } // ----- Finish ------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file is " << OutFile << endl; cout << "Parameter file is " << ParFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; // ------------------------------------------------------------------------ cout << " Test passed" << endl; cout << " All ok " << endl; }
void run_sim_tpc(Int_t nEvents = 10, TString mcEngine = "TGeant3") { TString dir = getenv("VMCWORKDIR"); TString geom_dir = dir + "/Detectors/Geometry/"; gSystem->Setenv("GEOMPATH",geom_dir.Data()); TString tut_configdir = dir + "/Detectors/gconfig"; gSystem->Setenv("CONFIG_DIR",tut_configdir.Data()); // Output file name char fileout[100]; sprintf(fileout, "AliceO2_%s.tpc.mc_%i_event.root", mcEngine.Data(), nEvents); TString outFile = fileout; // Parameter file name char filepar[100]; sprintf(filepar, "AliceO2_%s.tpc.params_%i.root", mcEngine.Data(), nEvents); TString parFile = filepar; // In general, the following parts need not be touched // Debug option gDebug = 0; // Timer TStopwatch timer; timer.Start(); // Create simulation run FairRunSim* run = new FairRunSim(); run->SetName(mcEngine); // Transport engine run->SetOutputFile(outFile); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // Create media run->SetMaterials("media.geo"); // Materials // Create geometry AliceO2::Passive::Cave* cave = new AliceO2::Passive::Cave("CAVE"); cave->SetGeometryFileName("cave.geo"); run->AddModule(cave); // ===| Add TPC |============================================================ AliceO2::TPC::Detector* tpc = new AliceO2::TPC::Detector("TPC", kTRUE); tpc->SetGeoFileName("TPCGeometry.root"); run->AddModule(tpc); // Create PrimaryGenerator FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); FairBoxGenerator* boxGen = new FairBoxGenerator(2212, 1); /*protons*/ //boxGen->SetThetaRange(0.0, 90.0); boxGen->SetEtaRange(-0.9,0.9); boxGen->SetPRange(100, 100.01); boxGen->SetPhiRange(0., 360.); boxGen->SetDebug(kTRUE); primGen->AddGenerator(boxGen); run->SetGenerator(primGen); // store track trajectories // run->SetStoreTraj(kTRUE); // Initialize simulation run run->Init(); // Runtime database Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(parFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // Start run run->Run(nEvents); // run->CreateGeometryFile("geofile_full.root"); // Finish timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file is " << outFile << endl; cout << "Parameter file is " << parFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; }
void simall(Int_t nEvents = 1, TObjArray& fDetList, Bool_t fVis=kFALSE, TString fMC="TGeant3", TString fGenerator="mygenerator", Bool_t fUserPList= kFALSE ) { TString dir = getenv("VMCWORKDIR"); TString simdir = dir + "/macros"; TString sim_geomdir = dir + "/geometry"; gSystem->Setenv("GEOMPATH",sim_geomdir.Data()); TString sim_confdir = dir + "gconfig"; gSystem->Setenv("CONFIG_DIR",sim_confdir.Data()); // Output files TString OutFile = "simout.root"; TString ParFile = "simpar.root"; // In general, the following parts need not be touched // ======================================================================== // ---- Debug option ------------------------------------------------- gDebug = 0; // ------------------------------------------------------------------------ // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ---- Load libraries ------------------------------------------------- gROOT->LoadMacro("$VMCWORKDIR/gconfig/basiclibs.C"); basiclibs(); gSystem->Load("libGenVector"); gSystem->Load("libGeoBase"); gSystem->Load("libFairDB"); gSystem->Load("libParBase"); gSystem->Load("libBase"); gSystem->Load("libMCStack"); gSystem->Load("libField"); gSystem->Load("libGen"); //---- Load specific libraries --------------------------------------- gSystem->Load("libEnsarbase"); gSystem->Load("libEnsarGen"); gSystem->Load("libEnsarData"); gSystem->Load("libEnsarMyDet"); // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName(fMC.Data()); // Transport engine run->SetOutputFile(OutFile.Data()); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // R3B Special Physics List in G4 case if ( (fUserPList == kTRUE ) && (fMC.CompareTo("TGeant4") == 0) ){ run->SetUserConfig("g4Config.C"); run->SetUserCuts("SetCuts.C"); } // ----- Create media ------------------------------------------------- //run->SetMaterials("media_r3b.geo"); // Materials // Magnetic field map type // Int_t fFieldMap = 0; // Global Transformations //- Two ways for a Volume Rotation are supported //-- 1) Global Rotation (Euler Angles definition) //-- This represent the composition of : first a rotation about Z axis with //-- angle phi, then a rotation with theta about the rotated X axis, and //-- finally a rotation with psi about the new Z axis. Double_t phi,theta,psi; //-- 2) Rotation in Ref. Frame of the Volume //-- Rotation is Using Local Ref. Frame axis angles Double_t thetaX,thetaY,thetaZ; //- Global Translation Lab. frame. Double_t tx,ty,tz; // ----- Create geometry -------------------------------------------- if (fDetList.FindObject("MYDET") ) { //My Detector definition EnsarDetector* mydet = new EnsarMyDet("MyDet", kTRUE); // Global position of the Module phi = 0.0; // (deg) theta = 0.0; // (deg) psi = 0.0; // (deg) // Rotation in Ref. Frame. thetaX = 0.0; // (deg) thetaY = 0.0; // (deg) thetaZ = 0.0; // (deg) // Global translation in Lab tx = 0.0; // (cm) ty = 0.0; // (cm) tz = 0.0; // (cm) mydet->SetRotAnglesXYZ(thetaX,thetaY,thetaZ); mydet->SetTranslation(tx,ty,tz); run->AddModule(mydet); } // ----- Create PrimaryGenerator -------------------------------------- // 1 - Create the Main API class for the Generator FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); if (fGenerator.CompareTo("mygenerator") == 0 ) { // 2- Define the generator Double_t pdgId=211; // pion beam Double_t theta1= 0.; // polar angle distribution Double_t theta2= 7.; Double_t momentum=.8; // 10 GeV/c Int_t multiplicity = 50; // multiplicity (nb particles per event) FairBoxGenerator* boxGen = new FairBoxGenerator(pdgId,multiplicity); boxGen->SetThetaRange ( theta1, theta2); boxGen->SetPRange (momentum,momentum*2.); boxGen->SetPhiRange (0.,360.); boxGen->SetXYZ(0.0,0.0,-1.5); // add the box generator primGen->AddGenerator(boxGen); } run->SetGenerator(primGen); //-------Set visualisation flag to true------------------------------------ if (fVis==kTRUE){ run->SetStoreTraj(kTRUE); }else{ run->SetStoreTraj(kFALSE); } // ----- Initialize simulation run ------------------------------------ run->Init(); // ------ Increase nb of step Int_t nSteps = -15000; gMC->SetMaxNStep(nSteps); // ----- Runtime database --------------------------------------------- Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(ParFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // ----- Start run ---------------------------------------------------- if (nEvents>0) run->Run(nEvents); // ----- Finish ------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file is " << OutFile << endl; cout << "Parameter file is " << ParFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; // ------------------------------------------------------------------------ cout << " Test passed" << endl; cout << " All ok " << endl; }
/******************************************************************************** * Copyright (C) 2014 GSI Helmholtzzentrum fuer Schwerionenforschung GmbH * * * * This software is distributed under the terms of the * * GNU Lesser General Public Licence version 3 (LGPL) version 3, * * copied verbatim in the file "LICENSE" * ********************************************************************************/ void run_tutorial1(Int_t nEvents = 10, TString mcEngine = "TGeant3") { TString dir = getenv("VMCWORKDIR"); TString tutdir = dir + "/Tutorial1"; TString tut_geomdir = dir + "/geometry"; gSystem->Setenv("GEOMPATH",tut_geomdir.Data()); TString tut_configdir = dir + "/gconfig"; gSystem->Setenv("CONFIG_DIR",tut_configdir.Data()); TString partName[] = {"pions","eplus","proton"}; Int_t partPdgC[] = { 211, 11, 2212}; Int_t chosenPart = 0; Double_t momentum = 2.; Double_t theta = 0.; TString outDir = "./"; // Output file name TString outFile = Form("%s/tutorial1_%s_%s.mc_p%1.3f_t%1.0f_n%d.root", outDir.Data(), mcEngine.Data(), partName[chosenPart].Data(), momentum, theta, nEvents); // Parameter file name TString parFile = Form("%s/tutorial1_%s_%s.params_p%1.3f_t%1.0f_n%d.root", outDir.Data(), mcEngine.Data(), partName[chosenPart].Data(), momentum, theta, nEvents); // In general, the following parts need not be touched // ======================================================================== // ---- Debug option ------------------------------------------------- gDebug = 0; // ------------------------------------------------------------------------ // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName(mcEngine); // Transport engine run->SetOutputFile(outFile); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); // ------------------------------------------------------------------------ // ----- Create media ------------------------------------------------- run->SetMaterials("media.geo"); // Materials // ------------------------------------------------------------------------ // ----- Create geometry ---------------------------------------------- FairModule* cave= new FairCave("CAVE"); cave->SetGeometryFileName("cave_vacuum.geo"); run->AddModule(cave); FairDetector* tutdet = new FairTutorialDet1("TUTDET", kTRUE); tutdet->SetGeometryFileName("double_sector.geo"); run->AddModule(tutdet); // ------------------------------------------------------------------------ // ----- Create PrimaryGenerator -------------------------------------- FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); FairBoxGenerator* boxGen = new FairBoxGenerator(partPdgC[chosenPart], 1); boxGen->SetThetaRange ( theta, theta+0.01); boxGen->SetPRange (momentum,momentum+0.01); boxGen->SetPhiRange (0.,360.); boxGen->SetDebug(kTRUE); primGen->AddGenerator(boxGen); run->SetGenerator(primGen); // ------------------------------------------------------------------------ // ----- Initialize simulation run ------------------------------------ run->Init(); // ------------------------------------------------------------------------ // ----- Runtime database --------------------------------------------- Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(parFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // ------------------------------------------------------------------------ // ----- Start run ---------------------------------------------------- run->Run(nEvents); run->CreateGeometryFile("geofile_full.root"); // ------------------------------------------------------------------------ // ----- Finish ------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file is " << outFile << endl; cout << "Parameter file is " << parFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; // ------------------------------------------------------------------------ }
void r3ball(Int_t nEvents = 1, TMap& fDetList, TString Target = "LeadTarget", Bool_t fVis = kFALSE, TString fMC = "TGeant3", TString fGenerator = "box", Bool_t fUserPList = kFALSE, Bool_t fR3BMagnet = kTRUE, Bool_t fCalifaHitFinder = kFALSE, Bool_t fStarTrackHitFinder = kFALSE, Double_t fMeasCurrent = 2000., TString OutFile = "r3bsim.root", TString ParFile = "r3bpar.root", TString InFile = "evt_gen.dat", double energy1, double energy2) { TString dir = getenv("VMCWORKDIR"); TString r3bdir = dir + "/macros"; TString r3b_geomdir = dir + "/geometry"; gSystem->Setenv("GEOMPATH",r3b_geomdir.Data()); TString r3b_confdir = dir + "gconfig"; gSystem->Setenv("CONFIG_DIR",r3b_confdir.Data()); // In general, the following parts need not be touched // ======================================================================== // ---- Debug option ------------------------------------------------- gDebug = 0; // ------------------------------------------------------------------------ // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ----- Create simulation run ---------------------------------------- FairRunSim* run = new FairRunSim(); run->SetName(fMC.Data()); // Transport engine run->SetOutputFile(OutFile.Data()); // Output file FairRuntimeDb* rtdb = run->GetRuntimeDb(); FairLogger::GetLogger()->SetLogScreenLevel("DEBUG"); // R3B Special Physics List in G4 case if ( (fUserPList == kTRUE ) && (fMC.CompareTo("TGeant4") == 0) ){ run->SetUserConfig("g4R3bConfig.C"); run->SetUserCuts("SetCuts.C"); } // ----- Create media ------------------------------------------------- run->SetMaterials("media_r3b.geo"); // Materials // Magnetic field map type Int_t fFieldMap = 0; // Global Transformations //- Two ways for a Volume Rotation are supported //-- 1) Global Rotation (Euler Angles definition) //-- This represent the composition of : first a rotation about Z axis with //-- angle phi, then a rotation with theta about the rotated X axis, and //-- finally a rotation with psi about the new Z axis. Double_t phi,theta,psi; //-- 2) Rotation in Ref. Frame of the Volume //-- Rotation is Using Local Ref. Frame axis angles Double_t thetaX,thetaY,thetaZ; //- Global Translation Lab. frame. Double_t tx,ty,tz; // ----- Create R3B geometry -------------------------------------------- //R3B Cave definition FairModule* cave= new R3BCave("CAVE"); cave->SetGeometryFileName("r3b_cave.geo"); run->AddModule(cave); //R3B Target definition if (fDetList.FindObject("TARGET") ) { R3BModule* target= new R3BTarget(Target.Data()); target->SetGeometryFileName(((TObjString*)fDetList.GetValue("TARGET"))->GetString().Data()); run->AddModule(target); } //R3B SiTracker Cooling definition if (fDetList.FindObject("VACVESSELCOOL") ) { R3BModule* vesselcool= new R3BVacVesselCool(Target.Data()); vesselcool->SetGeometryFileName(((TObjString*)fDetList.GetValue("VACVESSELCOOL"))->GetString().Data()); run->AddModule(vesselcool); } //R3B Magnet definition if (fDetList.FindObject("ALADIN") ) { fFieldMap = 0; R3BModule* mag = new R3BMagnet("AladinMagnet"); mag->SetGeometryFileName(((TObjString*)fDetList.GetValue("ALADIN"))->GetString().Data()); run->AddModule(mag); } //R3B Magnet definition if (fDetList.FindObject("GLAD") ) { fFieldMap = 1; R3BModule* mag = new R3BGladMagnet("GladMagnet", ((TObjString*)fDetList->GetValue("GLAD"))->GetString(), "GLAD Magnet"); run->AddModule(mag); } if (fDetList.FindObject("CRYSTALBALL") ) { //R3B Crystal Calorimeter R3BDetector* xball = new R3BXBall("XBall", kTRUE); xball->SetGeometryFileName(((TObjString*)fDetList.GetValue("CRYSTALBALL"))->GetString().Data()); run->AddModule(xball); } if (fDetList.FindObject("CALIFA") ) { // CALIFA Calorimeter R3BDetector* califa = new R3BCalifa("Califa", kTRUE); // ((R3BCalifa *)califa)->SelectGeometryVersion(0x438b); ((R3BCalifa *)califa)->SelectGeometryVersion(17); //Selecting the Non-uniformity of the crystals (1 means +-1% max deviation) ((R3BCalifa *)califa)->SetNonUniformity(.0); califa->SetGeometryFileName(((TObjString*)fDetList.GetValue("CALIFA"))->GetString().Data()); run->AddModule(califa); } // Tracker if (fDetList.FindObject("TRACKER") ) { R3BDetector* tra = new R3BTra("Tracker", kTRUE); tra->SetGeometryFileName(((TObjString*)fDetList.GetValue("TRACKER"))->GetString().Data()); run->AddModule(tra); } // STaRTrack if (fDetList.FindObject("STaRTrack") ) { R3BDetector* tra = new R3BSTaRTra("STaRTrack", kTRUE); tra->SetGeometryFileName(((TObjString*)fDetList.GetValue("STaRTrack"))->GetString().Data()); run->AddModule(tra); } // DCH drift chambers if (fDetList.FindObject("DCH") ) { R3BDetector* dch = new R3BDch("Dch", kTRUE); dch->SetGeometryFileName(((TObjString*)fDetList.GetValue("DCH"))->GetString().Data()); run->AddModule(dch); } // Tof if (fDetList.FindObject("TOF") ) { R3BDetector* tof = new R3BTof("Tof", kTRUE); tof->SetGeometryFileName(((TObjString*)fDetList.GetValue("TOF"))->GetString().Data()); run->AddModule(tof); } // mTof if (fDetList.FindObject("MTOF") ) { R3BDetector* mTof = new R3BmTof("mTof", kTRUE); mTof->SetGeometryFileName(((TObjString*)fDetList.GetValue("MTOF"))->GetString().Data()); run->AddModule(mTof); } // GFI detector if (fDetList.FindObject("GFI") ) { R3BDetector* gfi = new R3BGfi("Gfi", kTRUE); gfi->SetGeometryFileName(((TObjString*)fDetList.GetValue("GFI"))->GetString().Data()); run->AddModule(gfi); } // Land Detector if (fDetList.FindObject("LAND") ) { R3BDetector* land = new R3BLand("Land", kTRUE); land->SetVerboseLevel(1); land->SetGeometryFileName(((TObjString*)fDetList.GetValue("LAND"))->GetString().Data()); run->AddModule(land); } // NeuLand Scintillator Detector if(fDetList.FindObject("SCINTNEULAND")) { R3BDetector* land = new R3BLand("Land", kTRUE); land->SetVerboseLevel(1); land->SetGeometryFileName(((TObjString*)fDetList.GetValue("SCINTNEULAND"))->GetString().Data()); run->AddModule(land); } // MFI Detector if(fDetList.FindObject("MFI")) { R3BDetector* mfi = new R3BMfi("Mfi", kTRUE); mfi->SetGeometryFileName(((TObjString*)fDetList.GetValue("MFI"))->GetString().Data()); run->AddModule(mfi); } // PSP Detector if(fDetList.FindObject("PSP")) { R3BDetector* psp = new R3BPsp("Psp", kTRUE); psp->SetGeometryFileName(((TObjString*)fDetList.GetValue("PSP"))->GetString().Data()); run->AddModule(psp); } // Luminosity detector if (fDetList.FindObject("LUMON") ) { R3BDetector* lumon = new ELILuMon("LuMon", kTRUE); lumon->SetGeometryFileName(((TObjString*)fDetList.GetValue("LUMON"))->GetString().Data()); run->AddModule(lumon); } // ----- Create R3B magnetic field ---------------------------------------- Int_t typeOfMagneticField = 0; Int_t fieldScale = 1; Bool_t fVerbose = kFALSE; //NB: <D.B> // If the Global Position of the Magnet is changed // the Field Map has to be transformed accordingly if (fFieldMap == 0) { R3BAladinFieldMap* magField = new R3BAladinFieldMap("AladinMaps"); magField->SetCurrent(fMeasCurrent); magField->SetScale(fieldScale); if ( fR3BMagnet == kTRUE ) { run->SetField(magField); } else { run->SetField(NULL); } } else if(fFieldMap == 1){ R3BGladFieldMap* magField = new R3BGladFieldMap("R3BGladMap"); magField->SetScale(fieldScale); if ( fR3BMagnet == kTRUE ) { run->SetField(magField); } else { run->SetField(NULL); } } //! end of field map section // ----- Create PrimaryGenerator -------------------------------------- // 1 - Create the Main API class for the Generator FairPrimaryGenerator* primGen = new FairPrimaryGenerator(); if (fGenerator.CompareTo("ion") == 0 ) { // R3B Ion Generator Int_t z = 30; // Atomic number Int_t a = 65; // Mass number Int_t q = 0; // Charge State Int_t m = 1; // Multiplicity Double_t px = 40./a; // X-Momentum / per nucleon!!!!!! Double_t py = 600./a; // Y-Momentum / per nucleon!!!!!! Double_t pz = 0.01/a; // Z-Momentum / per nucleon!!!!!! R3BIonGenerator* ionGen = new R3BIonGenerator(z,a,q,m,px,py,pz); ionGen->SetSpotRadius(1,1,0); // add the ion generator primGen->AddGenerator(ionGen); } if (fGenerator.CompareTo("ascii") == 0 ) { R3BAsciiGenerator* gen = new R3BAsciiGenerator((dir+"/input/"+InFile).Data()); primGen->AddGenerator(gen); } if (fGenerator.CompareTo("box") == 0 ) { // 2- Define the BOX generator Double_t pdgId=2212; // proton beam Double_t theta1= 25.; // polar angle distribution //Double_t theta2= 7.; Double_t theta2= 66.; // Double_t momentum=1.09008; // 500 MeV/c // Double_t momentum=0.4445834; // 100 MeV/c Double_t momentum1=TMath::Sqrt(energy1*energy1 + 2*energy1*0.938272046); Double_t momentum2=TMath::Sqrt(energy2*energy2 + 2*energy2*0.938272046); FairBoxGenerator* boxGen = new FairBoxGenerator(pdgId, 1); boxGen->SetThetaRange ( theta1, theta2); boxGen->SetPRange (momentum1,momentum2); boxGen->SetPhiRange (0,360.); //boxGen->SetXYZ(0.0,0.0,-1.5); boxGen->SetXYZ(0.0,0.0,0.0); boxGen->SetDebug(kFALSE); // add the box generator primGen->AddGenerator(boxGen); //primGen->SetTarget(0.25, 0.5); //primGen->SmearVertexZ(kTRUE); } if (fGenerator.CompareTo("gammas") == 0 ) { // 2- Define the CALIFA Test gamma generator //Double_t pdgId=22; // gamma emission Double_t pdgId=2212; // proton emission Double_t theta1= 10.; // polar angle distribution Double_t theta2= 40.; //Double_t theta2= 90.; //Double_t momentum=0.002; // 0.010 GeV/c = 10 MeV/c Double_t momentumI=0.002; // 0.010 GeV/c = 10 MeV/c Double_t momentumF=0.002; // 0.010 GeV/c = 10 MeV/c //Double_t momentumF=0.808065; // 0.808065 GeV/c (300MeV Kin Energy for protons) //Double_t momentumI=0.31016124; // 0.31016124 GeV/c (50MeV Kin Energy for protons) //Double_t momentum=0.4442972; // 0.4442972 GeV/c (100MeV Kin Energy for protons) //Double_t momentum=0.5509999; // 0.5509999 GeV/c (150MeV Kin Energy for protons) //Double_t momentumI=0.64405; // 0.64405 GeV/c (200MeV Kin Energy for protons) Int_t multiplicity = 1; R3BCALIFATestGenerator* gammasGen = new R3BCALIFATestGenerator(pdgId, multiplicity); gammasGen->SetThetaRange (theta1, theta2); gammasGen->SetCosTheta(); gammasGen->SetPRange(momentumI,momentumF); gammasGen->SetPhiRange(-180.,180.); //gammasGen->SetXYZ(0.0,0.0,-1.5); //gammasGen->SetXYZ(0.0,0.0,0); gammasGen->SetBoxXYZ(-0.1,0.1,-0.1,0.1,-0.1,0.1); //gammasGen->SetLorentzBoost(0.8197505718204776); //beta=0.81975 for 700 A MeV // add the gamma generator primGen->AddGenerator(gammasGen); } if (fGenerator.CompareTo("r3b") == 0 ) { R3BSpecificGenerator *pR3bGen = new R3BSpecificGenerator(); // R3bGen properties pR3bGen->SetBeamInteractionFlag("off"); pR3bGen->SetRndmFlag("off"); pR3bGen->SetRndmEneFlag("off"); pR3bGen->SetBoostFlag("off"); pR3bGen->SetReactionFlag("on"); pR3bGen->SetGammasFlag("off"); pR3bGen->SetDecaySchemeFlag("off"); pR3bGen->SetDissociationFlag("off"); pR3bGen->SetBackTrackingFlag("off"); pR3bGen->SetSimEmittanceFlag("off"); // R3bGen Parameters pR3bGen->SetBeamEnergy(1.); // Beam Energy in GeV pR3bGen->SetSigmaBeamEnergy(1.e-03); // Sigma(Ebeam) GeV pR3bGen->SetParticleDefinition(2212); // Use Particle Pdg Code pR3bGen->SetEnergyPrim(0.3); // Particle Energy in MeV Int_t fMultiplicity = 50; pR3bGen->SetNumberOfParticles(fMultiplicity); // Mult. // Reaction type // 1: "Elas" // 2: "iso" // 3: "Trans" pR3bGen->SetReactionType("Elas"); // Target type // 1: "LeadTarget" // 2: "Parafin0Deg" // 3: "Parafin45Deg" // 4: "LiH" pR3bGen->SetTargetType(Target.Data()); Double_t thickness = (0.11/2.)/10.; // cm pR3bGen->SetTargetHalfThicknessPara(thickness); // cm pR3bGen->SetTargetThicknessLiH(3.5); // cm pR3bGen->SetTargetRadius(1.); // cm pR3bGen->SetSigmaXInEmittance(1.); //cm pR3bGen->SetSigmaXPrimeInEmittance(0.0001); //cm // Dump the User settings pR3bGen->PrintParameters(); primGen->AddGenerator(pR3bGen); } if (fGenerator.CompareTo("p2p") == 0 ) { R3Bp2pGenerator* gen = new R3Bp2pGenerator(("/lustre/nyx/fairgsi/mwinkel/r3broot/input/p2p/build/" + InFile).Data()); primGen->AddGenerator(gen); #if 0 // Coincident gammas R3BGammaGenerator *gammaGen = new R3BGammaGenerator(); gammaGen->SetEnergyLevel(0, 0.); gammaGen->SetEnergyLevel(1, 3E-3); gammaGen->SetEnergyLevel(2, 4E-3); gammaGen->SetBranchingRatio(2, 1, 0.5); gammaGen->SetBranchingRatio(2, 0, 0.5); gammaGen->SetBranchingRatio(1, 0, 1.); gammaGen->SetInitialLevel(2); gammaGen->SetLorentzBoost(TVector3(0, 0, 0.777792)); primGen->AddGenerator(gammaGen); #endif } run->SetGenerator(primGen); //-------Set visualisation flag to true------------------------------------ run->SetStoreTraj(fVis); FairLogger::GetLogger()->SetLogVerbosityLevel("LOW"); // ----- Initialize CalifaHitFinder task (CrystalCal to Hit) ------------------------------------ if(fCalifaHitFinder) { R3BCalifaCrystalCal2Hit* califaHF = new R3BCalifaCrystalCal2Hit(); califaHF->SetClusteringAlgorithm(1,0); califaHF->SetDetectionThreshold(0.000050);//50 KeV califaHF->SetExperimentalResolution(6.); //percent @ 1 MeV //califaHF->SetComponentResolution(.25); //sigma = 0.5 MeV califaHF->SetPhoswichResolution(3.,5.); //percent @ 1 MeV for LaBr and LaCl califaHF->SelectGeometryVersion(17); califaHF->SetAngularWindow(0.25,0.25); //[0.25 around 14.3 degrees, 3.2 for the complete calorimeter] run->AddTask(califaHF); } // ----- Initialize StarTrackHitfinder task ------------------------------------ if(fStarTrackHitFinder) { R3BSTaRTraHitFinder* trackHF = new R3BSTaRTraHitFinder(); //trackHF->SetClusteringAlgorithm(1,0); trackHF->SetDetectionThreshold(0.000050); //50 KeV trackHF->SetExperimentalResolution(0.); //trackHF->SetAngularWindow(0.15,0.15); //[0.25 around 14.3 degrees, 3.2 for the complete calorimeter] run->AddTask(trackHF); } // ----- Initialize simulation run ------------------------------------ run->Init(); // ------ Increase nb of step for CALO Int_t nSteps = 150000; TVirtualMC::GetMC()->SetMaxNStep(nSteps); // ----- Runtime database --------------------------------------------- R3BFieldPar* fieldPar = (R3BFieldPar*) rtdb->getContainer("R3BFieldPar"); fieldPar->SetParameters(magField); fieldPar->setChanged(); Bool_t kParameterMerged = kTRUE; FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged); parOut->open(ParFile.Data()); rtdb->setOutput(parOut); rtdb->saveOutput(); rtdb->print(); // ----- Start run ---------------------------------------------------- if(nEvents > 0) { run->Run(nEvents); } // ----- Finish ------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file is " << OutFile << endl; cout << "Parameter file is " << ParFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl; // ------------------------------------------------------------------------ cout << " Test passed" << endl; cout << " All ok " << endl; }
void Step0_R3BNeulandSim( const UInt_t particle_id, const UInt_t num_events, const Double_t momentum, const TString base_name, const TString base_path = "." ) { TStopwatch timer; timer.Start(); // System paths const TString working_directory = getenv("VMCWORKDIR"); gSystem->Setenv("GEOMPATH", working_directory + "/geometry"); gSystem->Setenv("CONFIG_DIR", working_directory + "/gconfig"); // Output files const TString out_file = base_path + "/sim." + base_name + ".root"; const TString par_file = base_path + "/par." + base_name + ".root"; // Basic simulation setup FairRunSim *run = new FairRunSim(); run->SetName("TGeant3"); run->SetOutputFile(out_file); run->SetMaterials("media_r3b.geo"); // Geometry: Cave FairModule *cave = new R3BCave("CAVE"); cave->SetGeometryFileName("r3b_cave.geo"); run->AddModule(cave); // Geometry: Neuland R3BDetector *land = new R3BLand("Land", kTRUE); land->SetVerboseLevel(0); land->SetGeometryFileName("neuland_v12a_14m.geo.root"); run->AddModule(land); // Primary particle generator FairBoxGenerator *boxGen = new FairBoxGenerator(particle_id); boxGen->SetThetaRange(0., 1.); boxGen->SetPhiRange(0., 360.); boxGen->SetPRange(momentum, momentum); boxGen->SetXYZ(0., 0., 0.); boxGen->SetDebug(1); FairPrimaryGenerator *primGen = new FairPrimaryGenerator(); primGen->AddGenerator(boxGen); run->SetGenerator(primGen); // Further setup options and initialization FairLogger::GetLogger()->SetLogVerbosityLevel("LOW"); run->SetStoreTraj(kTRUE); run->Init(); // Connect runtime parameter file FairParRootFileIo *par_file_io = new FairParRootFileIo(kTRUE); par_file_io->open(par_file); FairRuntimeDb *rtdb = run->GetRuntimeDb(); rtdb->setOutput(par_file_io); rtdb->saveOutput(); // Simulate run->Run(num_events); // Report timer.Stop(); cout << "Macro finished succesfully." << endl; cout << "Output file is " << out_file << endl; cout << "Parameter file is " << par_file << endl; cout << "Real time " << timer.RealTime() << " s, CPU time " << timer.CpuTime() << "s" << endl << endl; }