AliGenerator* Hijing2000()
{
AliGenHijing *gener = (AliGenHijing*) Hijing();
gener->SetJetQuenching(0);
gener->SetPtHardMin (2.3);
return gener;
}
AliGenerator* CocktailSignals() {
comment = comment.Append("Cocktail of various signals");
AliGenCocktail *cocktail = new AliGenCocktail();
// 1) Dummy generation of positive pions, to keep memory of the production vertex
AliGenBox *dummyPionPos = new AliGenBox(20);
dummyPionPos->SetYRange(-0.5, 0.5);
dummyPionPos->SetPtRange(1., 10.);
dummyPionPos->SetPart(211);
cocktail->AddGenerator(dummyPionPos,"dummyPionPos",1);
// 2) Dummy generation of negative pions, to keep memory of the production vertex
AliGenBox *dummyPionNeg = new AliGenBox(20);
dummyPionNeg->SetYRange(-0.5, 0.5);
dummyPionNeg->SetPtRange(1., 10.);
dummyPionNeg->SetPart(-211);
cocktail->AddGenerator(dummyPionNeg,"dummyPionNeg",1);
// 3) Generator for the custom signal
AliGenerator* signalGen = 0x0;
if (signal == kPythia6) signalGen = MbPythia();
else if (signal == kPythiaPerugia0) signalGen = MbPythiaTunePerugia0();
else if (signal == kHijing) signalGen = Hijing();
else if (signal == kHijing2500) signalGen = Hijing2500();
else if (signal == kGenBox) signalGen = GenBox();
else if (signal == kGenMuonLMR) signalGen = GenMuonLMR();
else if (signal == kGenParamJpsi) signalGen = GenParamJpsi();
else if (signal == kGenCorrHF) signalGen = GenCorrHF();
else if (signal == kGenPionKaon) signalGen = GenParamPionKaon();
else if (signal == kPythiaPerugia0BtoJpsi2mu) signalGen = MbPythiaTunePerugia0BtoJpsi2mu();
cocktail->AddGenerator(signalGen, "signal", 1);
cocktail->SetTrackingFlag(1);
return cocktail;
}
// ----------------------------------------------------------------------------
// ----------------------------------------------------------------------------
// ----------------------------------------------------------------------------
void starsim( Int_t nevents=1, Int_t rngSeed=4321 )
{
gROOT->ProcessLine(".L bfc.C");
{
TString simple = "y2012 geant gstar usexgeom agml ";
bfc(0, simple );
}
gSystem->Load( "libVMC.so");
gSystem->Load( "StarGeneratorUtil.so" );
gSystem->Load( "StarGeneratorEvent.so" );
gSystem->Load( "StarGeneratorBase.so" );
gSystem->Load( "libMathMore.so" );
gSystem->Load( "libHijing1_383.so");
gSystem->Load( "libKinematics.so");
gSystem->Load( "xgeometry.so" );
// force gstar load/call
gSystem->Load( "gstar.so" );
command("call gstar");
// Setup RNG seed and map all ROOT TRandom here
StarRandom::seed( rngSeed );
StarRandom::capture();
// Load STAR Particle DataBase and add the hypertriton definitions (as defined in gstar_part.g)
StarParticleData &pdb = StarParticleData::instance();
pdb.AddParticle("HyperTriton", new TParticlePDG( "HyperTriton", "HyperTriton --> He3 pi-", 2.99131, false, 0.0, +3.0, "hypernucleus", +hid(1,1,1), 0, 61054 ));
pdb.AddParticle("AntiHyperTriton", new TParticlePDG( "AntiHyperTriton", "AntiHyperTriton --> He3bar pi+", 2.99131, false, 0.0, -3.0, "hypernucleus", -hid(1,1,1), 0, 61055 ));
//
// Create the primary event generator and insert it
// before the geant maker
//
_primary = new StarPrimaryMaker();
{
_primary -> SetFileName( "hijing.starsim.root");
chain -> AddBefore( "geant", _primary );
}
// Setup an event generator
//
Hijing();
//
// Setup single hypertritons
//
HyperTritons();
//
// Initialize primary event generator and all sub makers
//
_primary -> Init();
//
// Setup geometry and set starsim to use agusread for input
//
//geometry("y2012");
command("gkine -4 0");
command("gfile o hijing.starsim.fzd");
//
// Trigger on nevents
//
trig( nevents );
_primary->event()->Print();
// command("gprint kine");
command("call agexit"); // Make sure that STARSIM exits properly
}
// ----------------------------------------------------------------------------
// ----------------------------------------------------------------------------
// ----------------------------------------------------------------------------
void starsim( Int_t nevents=10, Int_t rngSeed=4321 )
{
gROOT->ProcessLine(".L bfc.C");
{
TString simple = "y2014a geant gstar usexgeom agml ";
bfc(0, simple );
}
gSystem->Load( "libVMC.so");
gSystem->Load( "StarGeneratorUtil.so" );
gSystem->Load( "StarGeneratorEvent.so" );
gSystem->Load( "StarGeneratorBase.so" );
gSystem->Load( "libMathMore.so" );
gSystem->Load( "libHijing1_383.so");
gSystem->Load( "libKinematics.so");
gSystem->Load( "xgeometry.so" );
// force gstar load/call
gSystem->Load( "gstar.so" );
command("call gstar");
// Setup RNG seed and map all ROOT TRandom here
StarRandom::seed( rngSeed );
StarRandom::capture();
//
// Create the primary event generator and insert it
// before the geant maker
//
_primary = new StarPrimaryMaker();
{
_primary -> SetFileName( "hijing.starsim.root");
chain -> AddBefore( "geant", _primary );
}
//
// These should be adjusted to your best vertex estimates
//
_primary -> SetVertex( 0., 0., 0. );
_primary -> SetSigma( 0.3, 0.3, 60.0 );
// Setup an event generator
//
Hijing();
//
// Setup single dalitzdecay
//
Dalitzdecay();
//
// Initialize primary event generator and all sub makers
//
_primary -> Init();
//
// Setup geometry and set starsim to use agusread for input
//
command("gkine -4 0");
command("gfile o hijing.starsim.fzd");
//
// Trigger on nevents
//
trig( nevents );
_primary->event()->Print();
// command("gprint kine");
command("call agexit"); // Make sure that STARSIM exits properly
}
void Config()
{
// Get settings from environment variables
ProcessEnvironmentVars();
gRandom->SetSeed(seed);
cerr<<"Seed for random number generation= "<<seed<<endl;
// Libraries required by geant321
#if defined(__CINT__)
gSystem->Load("liblhapdf"); // Parton density functions
gSystem->Load("libEGPythia6"); // TGenerator interface
if (proc == kPythia6 || proc == kPhojet || proc == kDpmjet) {
gSystem->Load("libpythia6"); // Pythia 6.2
gSystem->Load("libAliPythia6"); // ALICE specific implementations
} else if (proc != kHydjet) {
gSystem->Load("libpythia6.4.21"); // Pythia 6.4
gSystem->Load("libAliPythia6"); // ALICE specific implementations
}
if (proc == kHijing || proc == kHijing2000 || proc == kHijing2000HF) {
gSystem->Load("libhijing");
gSystem->Load("libTHijing");
} else if (proc == kHydjet) {
gSystem->Load("libTUHKMgen");
} else if (proc == kDpmjet) {
gSystem->Load("libdpmjet");
gSystem->Load("libTDPMjet");
}
gSystem->Load("libgeant321");
#endif
new TGeant3TGeo("C++ Interface to Geant3");
//=======================================================================
// Create the output file
AliRunLoader* rl=0x0;
cout<<"Config.C: Creating Run Loader ..."<<endl;
rl = AliRunLoader::Open("galice.root",
AliConfig::GetDefaultEventFolderName(),
"recreate");
if (rl == 0x0)
{
gAlice->Fatal("Config.C","Can not instatiate the Run Loader");
return;
}
rl->SetCompressionLevel(2);
rl->SetNumberOfEventsPerFile(1000);
gAlice->SetRunLoader(rl);
// gAlice->SetGeometryFromFile("geometry.root");
// gAlice->SetGeometryFromCDB();
// Set the trigger configuration
AliSimulation::Instance()->SetTriggerConfig(pprTrigConfName[strig]);
cout<<"Trigger configuration is set to "<<pprTrigConfName[strig]<<endl;
//
//=======================================================================
// ************* STEERING parameters FOR ALICE SIMULATION **************
// --- Specify event type to be tracked through the ALICE setup
// --- All positions are in cm, angles in degrees, and P and E in GeV
gMC->SetProcess("DCAY",1);
gMC->SetProcess("PAIR",1);
gMC->SetProcess("COMP",1);
gMC->SetProcess("PHOT",1);
gMC->SetProcess("PFIS",0);
gMC->SetProcess("DRAY",0);
gMC->SetProcess("ANNI",1);
gMC->SetProcess("BREM",1);
gMC->SetProcess("MUNU",1);
gMC->SetProcess("CKOV",1);
gMC->SetProcess("HADR",1);
gMC->SetProcess("LOSS",2);
gMC->SetProcess("MULS",1);
gMC->SetProcess("RAYL",1);
Float_t cut = 1.e-3; // 1MeV cut by default
Float_t tofmax = 1.e10;
gMC->SetCut("CUTGAM", cut);
gMC->SetCut("CUTELE", cut);
gMC->SetCut("CUTNEU", cut);
gMC->SetCut("CUTHAD", cut);
gMC->SetCut("CUTMUO", cut);
gMC->SetCut("BCUTE", cut);
gMC->SetCut("BCUTM", cut);
gMC->SetCut("DCUTE", cut);
gMC->SetCut("DCUTM", cut);
gMC->SetCut("PPCUTM", cut);
gMC->SetCut("TOFMAX", tofmax);
// RANDOM SELECTION OF ONE OF THE SIX GENERATION TYPES
//
Int_t typeHF = -1;
Float_t randHF = gRandom->Rndm();
if(randHF<0.2) {
typeHF=0;
} else if (randHF>=0.2 && randHF<0.4) {
typeHF=1;
} else if (randHF>=0.4 && randHF<0.6) {
typeHF=2;
} else if (randHF>=0.6 && randHF<0.8) {
typeHF=3;
} else if (randHF>=0.8 && randHF<0.9) {
typeHF=4;
} else {
typeHF=5;
}
//======================//
// Set External decayer //
//======================//
if (proc != kHydjet) {
TVirtualMCDecayer* decayer = new AliDecayerPythia();
if(proc == kHijing2000HF && (typeHF==0 || typeHF==1)) {
decayer->SetForceDecay(kHadronicD);
} else {
decayer->SetForceDecay(kAll);
}
decayer->Init();
gMC->SetExternalDecayer(decayer);
}
//=========================//
// Generator Configuration //
//=========================//
AliGenerator* gener = 0x0;
if (proc == kPythia6) {
gener = MbPythia();
} else if (proc == kPythia6D6T) {
gener = MbPythiaTuneD6T();
} else if (proc == kPythia6ATLAS) {
gener = MbPythiaTuneATLAS();
} else if (proc == kPythiaPerugia0) {
gener = MbPythiaTunePerugia0();
} else if (proc == kPythia6ATLAS_Flat) {
gener = MbPythiaTuneATLAS_Flat();
} else if (proc == kPhojet) {
gener = MbPhojet();
} else if (proc == kHijing) {
gener = Hijing();
} else if (proc == kHijing2000) {
gener = Hijing2000();
} else if (proc == kHijing2000HF) {
gener = Hijing2000HF(typeHF);
} else if (proc == kHydjet) {
gener = Hydjet();
} else if (proc == kDpmjet) {
gener = Dpmjet();
}
//
//
// Size of the interaction diamond
// Longitudinal
Float_t sigmaz = 5.4 / TMath::Sqrt(2.); // [cm]
//
// Transverse
Float_t betast = 3.5; // beta* [m]
Float_t eps = 3.75e-6; // emittance [m]
Float_t gamma = energy / 2.0 / 0.938272; // relativistic gamma [1]
Float_t sigmaxy = TMath::Sqrt(eps * betast / gamma) / TMath::Sqrt(2.) * 100.; // [cm]
printf("\n \n Diamond size x-y: %10.3e z: %10.3e\n \n", sigmaxy, sigmaz);
gener->SetSigma(sigmaxy, sigmaxy, sigmaz); // Sigma in (X,Y,Z) (cm) on IP position
gener->SetVertexSmear(kPerEvent);
gener->Init();
printf("\n \n Comment: %s \n \n", comment.Data());
//
// FIELD
//
TGeoGlobalMagField::Instance()->SetField(new AliMagF("Maps","Maps", -1., -1., AliMagF::k5kG,
AliMagF::kBeamTypeAA, 1380.));
rl->CdGAFile();
Int_t iABSO = 1;
Int_t iACORDE= 0;
Int_t iDIPO = 1;
Int_t iEMCAL = 1;
Int_t iFMD = 1;
Int_t iFRAME = 1;
Int_t iHALL = 1;
Int_t iITS = 1;
Int_t iMAG = 1;
Int_t iMUON = 1;
Int_t iPHOS = 1;
Int_t iPIPE = 1;
Int_t iPMD = 1;
Int_t iHMPID = 1;
Int_t iSHIL = 1;
Int_t iT0 = 1;
Int_t iTOF = 1;
Int_t iTPC = 1;
Int_t iTRD = 1;
Int_t iVZERO = 1;
Int_t iZDC = 1;
//=================== Alice BODY parameters =============================
AliBODY *BODY = new AliBODY("BODY", "Alice envelop");
if (iMAG)
{
//=================== MAG parameters ============================
// --- Start with Magnet since detector layouts may be depending ---
// --- on the selected Magnet dimensions ---
AliMAG *MAG = new AliMAG("MAG", "Magnet");
}
if (iABSO)
{
//=================== ABSO parameters ============================
AliABSO *ABSO = new AliABSOv3("ABSO", "Muon Absorber");
}
if (iDIPO)
{
//=================== DIPO parameters ============================
AliDIPO *DIPO = new AliDIPOv3("DIPO", "Dipole version 3");
}
if (iHALL)
{
//=================== HALL parameters ============================
AliHALL *HALL = new AliHALLv3("HALL", "Alice Hall");
}
if (iFRAME)
{
//=================== FRAME parameters ============================
AliFRAMEv2 *FRAME = new AliFRAMEv2("FRAME", "Space Frame");
FRAME->SetHoles(1);
}
if (iSHIL)
{
//=================== SHIL parameters ============================
AliSHIL *SHIL = new AliSHILv3("SHIL", "Shielding Version 3");
}
if (iPIPE)
{
//=================== PIPE parameters ============================
AliPIPE *PIPE = new AliPIPEv3("PIPE", "Beam Pipe");
}
if (iITS)
{
//=================== ITS parameters ============================
AliITS *ITS = new AliITSv11Hybrid("ITS","ITS v11Hybrid");
}
if (iTPC)
{
//============================ TPC parameters =====================
AliTPC *TPC = new AliTPCv2("TPC", "Default");
}
if (iTOF) {
//=================== TOF parameters ============================
AliTOF *TOF = new AliTOFv6T0("TOF", "normal TOF");
}
if (iHMPID)
{
//=================== HMPID parameters ===========================
AliHMPID *HMPID = new AliHMPIDv3("HMPID", "normal HMPID");
}
if (iZDC)
{
//=================== ZDC parameters ============================
AliZDC *ZDC = new AliZDCv3("ZDC", "normal ZDC");
ZDC->SetSpectatorsTrack();
ZDC->SetLumiLength(0.);
}
if (iTRD)
{
//=================== TRD parameters ============================
AliTRD *TRD = new AliTRDv1("TRD", "TRD slow simulator");
AliTRDgeometry *geoTRD = TRD->GetGeometry();
// Partial geometry: modules at 0,1,7,8,9,16,17
// starting at 3h in positive direction
geoTRD->SetSMstatus(2,0);
geoTRD->SetSMstatus(3,0);
geoTRD->SetSMstatus(4,0);
geoTRD->SetSMstatus(5,0);
geoTRD->SetSMstatus(6,0);
geoTRD->SetSMstatus(11,0);
geoTRD->SetSMstatus(12,0);
geoTRD->SetSMstatus(13,0);
geoTRD->SetSMstatus(14,0);
geoTRD->SetSMstatus(15,0);
geoTRD->SetSMstatus(16,0);
}
if (iFMD)
{
//=================== FMD parameters ============================
AliFMD *FMD = new AliFMDv1("FMD", "normal FMD");
}
if (iMUON)
{
//=================== MUON parameters ===========================
// New MUONv1 version (geometry defined via builders)
AliMUON *MUON = new AliMUONv1("MUON", "default");
// activate trigger efficiency by cells
MUON->SetTriggerEffCells(1); // not needed if raw masks
}
if (iPHOS)
{
//=================== PHOS parameters ===========================
AliPHOS *PHOS = new AliPHOSv1("PHOS", "noCPV_Modules123");
}
if (iPMD)
{
//=================== PMD parameters ============================
AliPMD *PMD = new AliPMDv1("PMD", "normal PMD");
}
if (iT0)
{
//=================== T0 parameters ============================
AliT0 *T0 = new AliT0v1("T0", "T0 Detector");
}
if (iEMCAL)
{
//=================== EMCAL parameters ============================
AliEMCAL *EMCAL = new AliEMCALv2("EMCAL", "EMCAL_FIRSTYEAR");
}
if (iACORDE)
{
//=================== ACORDE parameters ============================
AliACORDE *ACORDE = new AliACORDEv1("ACORDE", "normal ACORDE");
}
if (iVZERO)
{
//=================== ACORDE parameters ============================
AliVZERO *VZERO = new AliVZEROv7("VZERO", "normal VZERO");
}
}
void Config() {
// AliLog::SetClassDebugLevel("AliMFT", 1);
LoadLibs();
new TGeant3TGeo("C++ Interface to Geant3");
// Create the output file
AliRunLoader* rl=0x0;
printf("Config.C: Creating Run Loader ...");
rl = AliRunLoader::Open("galice.root", AliConfig::GetDefaultEventFolderName(), "recreate");
if (rl == 0x0) {
gAlice->Fatal("Config.C","Can not instatiate the Run Loader");
return;
}
rl->SetCompressionLevel(2);
rl->SetNumberOfEventsPerFile(1000);
gAlice->SetRunLoader(rl);
// ************* STEERING parameters FOR ALICE SIMULATION **************
// --- Specify event type to be tracked through the ALICE setup
// --- All positions are in cm, angles in degrees, and P and E in GeV
gMC->SetProcess("DCAY",1);
gMC->SetProcess("PAIR",1);
gMC->SetProcess("COMP",1);
gMC->SetProcess("PHOT",1);
gMC->SetProcess("PFIS",0);
gMC->SetProcess("DRAY",0);
gMC->SetProcess("ANNI",1);
gMC->SetProcess("BREM",1);
gMC->SetProcess("MUNU",1);
gMC->SetProcess("CKOV",1);
gMC->SetProcess("HADR",1);
gMC->SetProcess("LOSS",2);
gMC->SetProcess("MULS",1);
gMC->SetProcess("RAYL",1);
Float_t cut = 1.e-3; // 1MeV cut by default
Float_t tofmax = 1.e10;
gMC->SetCut("CUTGAM", cut);
gMC->SetCut("CUTELE", cut);
gMC->SetCut("CUTNEU", cut);
gMC->SetCut("CUTHAD", cut);
gMC->SetCut("CUTMUO", cut);
gMC->SetCut("BCUTE", cut);
gMC->SetCut("BCUTM", cut);
gMC->SetCut("DCUTE", cut);
gMC->SetCut("DCUTM", cut);
gMC->SetCut("PPCUTM", cut);
gMC->SetCut("TOFMAX", tofmax);
TVirtualMCDecayer *decayer = new AliDecayerPythia();
decayer->SetForceDecay(kAll);
decayer->Init();
gMC->SetExternalDecayer(decayer);
// Generator
AliGenerator* gener = 0x0;
if (proc == kPythia6) gener = MbPythia();
else if (proc == kPythiaPerugia0) gener = MbPythiaTunePerugia0();
else if (proc == kHijing) gener = Hijing();
else if (proc == kHijing2500) gener = Hijing2500();
else if (proc == kHijing2500Cocktail) gener = Hijing2500Cocktail();
else if (proc == kGenBox) gener = GenBox();
else if (proc == kGenMuonLMR) gener = GenMuonLMR();
else if (proc == kGenParamJpsi) gener = GenParamJpsi();
else if (proc == kGenCorrHF) gener = GenCorrHF();
else if (proc == kGenPionKaon) gener = GenParamPionKaon();
else if (proc == kPythiaPerugia0BtoJpsi2mu) gener = MbPythiaTunePerugia0BtoJpsi2mu();
else if (proc == kCocktailSignals) gener = CocktailSignals();
// Size of the interaction diamond
Float_t sigmaz = 5.4 / TMath::Sqrt(2.); // [cm]
Float_t betast = 3.5; // beta* [m]
Float_t eps = 3.75e-6; // emittance [m]
Float_t gamma = energy / 2.0 / 0.938272; // relativistic gamma [1]
Float_t sigmaxy = TMath::Sqrt(eps * betast / gamma) / TMath::Sqrt(2.) * 100.; // [cm]
printf("\n \n Diamond size x-y: %10.3e z: %10.3e\n \n", sigmaxy, sigmaz);
gener->SetOrigin(0,0,0);
gener->SetSigma(sigmaxy, sigmaxy, sigmaz); // Sigma in (X,Y,Z) (cm) on IP position
gener->SetVertexSmear(kPerEvent);
gener->Init();
printf("\n \n Comment: %s \n \n", comment.Data());
// TGeoGlobalMagField::Instance()->SetField(new AliMagF("Maps","Maps", -1., -1., AliMagF::k5kG, AliMagF::kBeamTypeAA, 2750.));
TGeoGlobalMagField::Instance()->SetField(new AliMagF("Maps","Maps", -1., -1., AliMagF::k5kG, AliMagF::kBeamTypepp, 7000.));
rl->CdGAFile();
// Detector Setup
Int_t iABSO = 1;
Int_t iDIPO = 1;
Int_t iHALL = 1;
Int_t iMUON = 1;
Int_t iPIPE = 1;
Int_t iSHIL = 1;
Int_t iT0 = 0;
Int_t iVZERO = 1;
Int_t iMFT = 1;
Int_t iACORDE= 0;
Int_t iEMCAL = 0;
Int_t iFMD = 0;
Int_t iFRAME = 0;
Int_t iITS = 0;
Int_t iMAG = 1;
Int_t iPHOS = 0;
Int_t iPMD = 0;
Int_t iHMPID = 0;
Int_t iTOF = 0;
Int_t iTPC = 0;
Int_t iTRD = 0;
Int_t iZDC = 0;
AliBODY *BODY = new AliBODY("BODY", "Alice envelop");
if (iMAG) AliMAG *MAG = new AliMAG("MAG", "Magnet");
if (iABSO) AliABSO *ABSO = new AliABSOv3("ABSO", "Muon Absorber");
if (iDIPO) AliDIPO *DIPO = new AliDIPOv3("DIPO", "Dipole version 3");
if (iHALL) AliHALL *HALL = new AliHALLv3("HALL", "Alice Hall");
if (iSHIL) AliSHIL *SHIL = new AliSHILv3("SHIL", "Shielding Version 3");
if (iITS) gROOT->ProcessLine(".x $ALICE_ROOT/ITS/UPGRADE/testITSU/CreateITSU.C");
if (iTPC) AliTPC *TPC = new AliTPCv2("TPC", "Default");
if (iTOF) AliTOF *TOF = new AliTOFv6T0("TOF", "normal TOF");
if (iHMPID) AliHMPID *HMPID = new AliHMPIDv3("HMPID", "normal HMPID");
if (iFMD) AliFMD *FMD = new AliFMDv1("FMD", "normal FMD");
if (iPHOS) AliPHOS *PHOS = new AliPHOSv1("PHOS", "noCPV_Modules123");
if (iPMD) AliPMD *PMD = new AliPMDv1("PMD", "normal PMD");
if (iT0) AliT0 *T0 = new AliT0v1("T0", "T0 Detector");
if (iEMCAL) AliEMCAL *EMCAL = new AliEMCALv2("EMCAL", "EMCAL_FIRSTYEARV1");
if (iACORDE) AliACORDE *ACORDE = new AliACORDEv1("ACORDE", "normal ACORDE");
if (iVZERO) AliVZERO *VZERO = new AliVZEROv7("VZERO", "normal VZERO");
if (iFRAME) {
AliFRAMEv2 *FRAME = new AliFRAMEv2("FRAME", "Space Frame");
FRAME->SetHoles(1);
}
if (iPIPE) {
// AliPIPE *PIPE = new AliPIPEv3("PIPE", "Beam Pipe");
AliPIPE *PIPE = new AliPIPEv4("PIPE", "Beam Pipe");
}
if (iZDC) {
AliZDC *ZDC = new AliZDCv3("ZDC", "normal ZDC");
ZDC->SetSpectatorsTrack();
ZDC->SetLumiLength(0.);
}
if (iTRD) {
AliTRD *TRD = new AliTRDv1("TRD", "TRD slow simulator");
}
if (iMUON) {
AliMUON *MUON = new AliMUONv1("MUON", "default");
MUON->SetTriggerEffCells(1); // not needed if raw masks
Char_t* digitstore="AliMUONDigitStoreV2S";
MUON->SetDigitStoreClassName(digitstore);
}
if (iMFT) {
AliMFT *MFT = new AliMFT("MFT", "normal MFT");
}
TIter next(gAlice->Modules());
AliModule *detector;
printf("gAlice->Modules:\n");
while((detector = (AliModule*)next())) printf("%s\n",detector->GetName());
}
// ----------------------------------------------------------------------------
// ----------------------------------------------------------------------------
// ----------------------------------------------------------------------------
void starsim( Int_t nevents=50, Int_t rngSeed=1234 )
{
gROOT->ProcessLine(".L bfc.C");
{
TString simple = "y2012 geant gstar usexgeom agml ";
//TString full = "tpcrs TpxRaw y2010a MakeEvent ITTF NoSvtIt NoSsdIt Idst IAna l0 ftpc Sti Tree logger genvtx tpcDB TpcHitMover TpxClu pmd bbcSim tofsim tags emcY2 EEfs evout IdTruth geantout -dstout big fzin MiniMcMk clearmem";
// TString full = "y2012 geant gstar tpcrs genvtx tpcDb tpxclu dedx event sdt20120224 ";
bfc(0, simple );
}
gSystem->Load( "libVMC.so");
gSystem->Load( "StarGeneratorUtil.so" );
gSystem->Load( "StarGeneratorEvent.so" );
gSystem->Load( "StarGeneratorBase.so" );
gSystem->Load( "libMathMore.so" );
gSystem->Load( "libHijing1_383.so");
gSystem->Load( "xgeometry.so" );
// Setup RNG seed and map all ROOT TRandom here
StarRandom::seed( rngSeed );
StarRandom::capture();
//
// Create the primary event generator and insert it
// before the geant maker
//
primary = new StarPrimaryMaker();
{
primary -> SetFileName( "hijing.starsim.root");
chain -> AddBefore( "geant", primary );
}
//
// Setup an event generator
//
Hijing();
//
// Initialize primary event generator and all sub makers
//
primary -> Init();
//
// Setup geometry and set starsim to use agusread for input
//
//geometry("y2012");
command("gkine -4 0");
command("gfile o hijing.starsim.fzd");
//
// Trigger on nevents
//
trig( nevents );
command("gprint kine");
// command("call agexit"); // Make sure that STARSIM exits properly
}
