void fastGen(Int_t nev = 1, char* filename = "gilc.root")
{
IlcPDG::AddParticlesToPdgDataBase();
TDatabasePDG::Instance();
// Run loader
IlcRunLoader* rl = IlcRunLoader::Open("gilc.root","FASTRUN","recreate");
rl->SetCompressionLevel(2);
rl->SetNumberOfEventsPerFile(nev);
rl->LoadKinematics("RECREATE");
rl->MakeTree("E");
gIlc->SetRunLoader(rl);
// Create stack
rl->MakeStack();
IlcStack* stack = rl->Stack();
// Header
IlcHeader* header = rl->GetHeader();
// Create and Initialize Generator
// Example of charm generation taken from Config_PythiaHeavyFlavours.C
IlcGenPythia *gener = new IlcGenPythia(-1);
gener->SetEnergyCMS(14000.);
gener->SetMomentumRange(0,999999);
gener->SetPhiRange(0., 360.);
gener->SetThetaRange(0.,180.);
// gener->SetProcess(kPyCharmppMNR); // Correct Pt distribution, wrong mult
gener->SetProcess(kPyMb); // Correct multiplicity, wrong Pt
gener->SetStrucFunc(kCTEQ4L);
gener->SetPtHard(2.1,-1.0);
gener->SetFeedDownHigherFamily(kFALSE);
gener->SetStack(stack);
gener->Init();
// Go to gilc.root
rl->CdGAFile();
// Forbid some decays. Do it after gener->Init(0, because
// the initialization of the generator includes reading of the decay table.
IlcPythia * py= IlcPythia::Instance();
py->SetMDME(737,1,0); //forbid D*+->D+ + pi0
py->SetMDME(738,1,0);//forbid D*+->D+ + gamma
// Forbid all D0 decays except D0->K- pi+
for(Int_t d=747; d<=762; d++){
py->SetMDME(d,1,0);
}
// decay 763 is D0->K- pi+
for(Int_t d=764; d<=807; d++){
py->SetMDME(d,1,0);
}
//
// Event Loop
//
TStopwatch timer;
timer.Start();
for (Int_t iev = 0; iev < nev; iev++) {
cout <<"Event number "<< iev << endl;
// Initialize event
header->Reset(0,iev);
rl->SetEventNumber(iev);
stack->Reset();
rl->MakeTree("K");
// Generate event
Int_t nprim = 0;
Int_t ntrial = 0;
Int_t ndstar = 0;
//-------------------------------------------------------------------------------------
while(!ndstar) {
// Selection of events with D*
stack->Reset();
stack->ConnectTree(rl->TreeK());
gener->Generate();
ntrial++;
nprim = stack->GetNprimary();
for(Int_t ipart =0; ipart < nprim; ipart++){
TParticle * part = stack->Particle(ipart);
if(part) {
if (TMath::Abs(part->GetPdgCode())== 413) {
TArrayI daughtersId;
GetFinalDecayProducts(ipart,*stack,daughtersId);
Bool_t kineOK = kTRUE;
Double_t thetaMin = TMath::Pi()/4;
Double_t thetaMax = 3*TMath::Pi()/4;
for (Int_t id=1; id<=daughtersId[0]; id++) {
TParticle * daughter = stack->Particle(daughtersId[id]);
if (!daughter) {
kineOK = kFALSE;
break;
}
Double_t theta = daughter->Theta();
if (theta<thetaMin || theta>thetaMax) {
kineOK = kFALSE;
break;
}
}
if (!kineOK) continue;
part->Print();
ndstar++;
}
}
}
}
cout << "Number of particles " << nprim << endl;
cout << "Number of trials " << ntrial << endl;
// Finish event
header->SetNprimary(stack->GetNprimary());
header->SetNtrack(stack->GetNtrack());
// I/O
stack->FinishEvent();
header->SetStack(stack);
rl->TreeE()->Fill();
rl->WriteKinematics("OVERWRITE");
} // event loop
timer.Stop();
timer.Print();
// Termination
// Generator
gener->FinishRun();
// Write file
rl->WriteHeader("OVERWRITE");
gener->Write();
rl->Write();
}
Int_t IlcTARGETGeoPlot (Int_t evesel=0, char *opt="All+ClustersV2", char *filename="gilc.root", Int_t isfastpoints = 0) {
/*******************************************************************
* This macro displays geometrical information related to the
* hits, digits and rec points (or V2 clusters) in TARGET.
* There are histograms that are not displayed (i.e. energy
* deposition) but that are saved onto a file (see below)
*
* INPUT arguments:
*
* Int_t evesel: the selected event number. It's =0 by default
*
* Options: Any combination of:
* 1) subdetector name: "SPD", "SDD", "SSD", "All" (default)
* 2) Printouts: "Verbose" Almost everything is printed out:
* it is wise to redirect the output onto a file
* e.g.: .x IlcTARGETGeoPlot.C("All+Verbose") > out.log
* 3) Rec Points option: "Rec" ---> Uses Rec. Points (default)
*
* 4) ClustersV2 option: "ClustersV2" ---->Uses ClustersV2
* otherwise ---->uses hits and digits only
* Examples:
* .x IlcTARGETGeoPlot(); (All subdetectors; no-verbose; no-recpoints)
* .x IlcTARGETGeoPlot("SPD+SSD+Verbose+Rec");
*
* filename: It's "gilc.root" by default.
* isfastpoints: integer. It is set to 0 by defaults. This means that
* slow reconstruction is assumed. If fast recpoint are in
* in use, isfastpoints must be set =1.
*
* OUTPUT: It produces a root file with a list of histograms
*
* WARNING: spatial information for SSD/DIGTARGET is obtained by pairing
* digits on p and n side originating from the same track, when
* possible. This (mis)use of DIGTARGET is tolerated for debugging
* purposes only !!!! The pairing in real life should be done
* starting from info really available...
*
* COMPILATION: this macro can be compiled.
* 1) You need to set your include path with
* gSystem->SetIncludePath("-I- -I$ILC_ROOT/include -I$ILC_ROOT/TARGET -g");
* 3) If you are using root instead of ilcroot you need to
* execute the macro loadlibs.C in advance
* 4) To compile this macro from root (or ilcroot):
* --- .L IlcTARGETGeoPlot.C++
* --- IlcTARGETGeoPlot();
*
* M.Masera 14/05/2001 18:30
* Last rev. 31/05/2004 14:00 (Clusters V2 added) E.C.
********************************************************************/
//Options
TString choice(opt);
Bool_t All = choice.Contains("All");
Bool_t verbose=choice.Contains("Verbose");
Bool_t userec=choice.Contains("Rec");
Bool_t useclustersv2=choice.Contains("ClustersV2");
Int_t retcode=1; //return code
if (gClassTable->GetID("IlcRun") < 0) {
gInterpreter->ExecuteMacro("loadlibs.C");
}
else {
if(gIlc){
delete gIlc->GetRunLoader();
delete gIlc;
gIlc=0;
}
}
IlcRunLoader* rl = IlcRunLoader::Open(filename);
if (rl == 0x0){
cerr<<"IlcTARGETGeoPlot.C : Can not open session RL=NULL"<< endl;
return -1;
}
Int_t retval = rl->LoadgIlc();
if (retval){
cerr<<"IlcTARGETGeoPlot.C : LoadgIlc returned error"<<endl;
return -1;
}
gIlc=rl->GetIlcRun();
retval = rl->LoadHeader();
if (retval){
cerr<<"IlcTARGETGeoPlot.C : LoadHeader returned error"<<endl;
return -1;
}
IlcTARGETLoader* TARGETloader = (IlcTARGETLoader*) rl->GetLoader("TARGETLoader");
if(!TARGETloader){
cerr<<"IlcTARGETGeoPlot.C : TARGET loader not found"<<endl;
return -1;
}
TARGETloader->LoadHits("read");
TARGETloader->LoadDigits("read");
if(isfastpoints==1)TARGETloader->SetRecPointsFileName("TARGET.FastRecPoints.root");
TARGETloader->LoadRecPoints("read");
rl->GetEvent(evesel);
Int_t nparticles = rl->GetHeader()->GetNtrack();
IlcTARGET *TARGET = (IlcTARGET*)gIlc->GetModule("TARGET");
TARGET->SetTreeAddress();
if(verbose) {
cout<<" "<<endl<<" "<<endl;
cout<<"******* Event processing started *******"<<endl;
cout<<"In the following, hits with 'StatusEntering' flag active"<<endl;
cout<<"will not be processed"<<endl;
cout << "Number of particles= " << nparticles <<endl;
}
// HTARGET
TTree *TH = TARGETloader->TreeH();
Stat_t ntracks = TH->GetEntries();
if(verbose)cout<<"Number of primary tracks= "<<ntracks<<endl;
// TARGET
Int_t nmodules;
TARGET->InitModules(-1,nmodules);
cout<<"Number of TARGET modules= "<<nmodules<<endl;
cout<<"Filling modules... It takes a while, now. Please be patient"<<endl;
TARGET->FillModules(0,0,nmodules," "," ");
cout<<"TARGET modules .... DONE!"<<endl;
IlcTARGETDetTypeRec* detTypeRec = new IlcTARGETDetTypeRec(TARGETloader);
detTypeRec->SetDefaults();
// DIGTARGET
TTree *TD = TARGETloader->TreeD();
//RECPOINTS (V2 clusters)
TTree *TR = TARGETloader->TreeR();
TClonesArray *TARGETrec = detTypeRec->RecPoints();
TBranch *branch = 0;
if(userec && TR && TARGETrec){
if(isfastpoints==1){
branch = TARGETloader->TreeR()->GetBranch("TARGETRecPointsF");
cout<<"using fast points\n";
}
else {
branch = TARGETloader->TreeR()->GetBranch("TARGETRecPoints");
}
if(branch)branch->SetAddress(&TARGETrec);
}
if(userec && (!TR || !TARGETrec || !branch)){
userec = kFALSE;
cout<<"\n ======================================================= \n";
cout<<"WARNING: there are no RECPOINTS on this file ! \n";
cout<<"======================================================= \n \n";
}
if(useclustersv2 && TR && TARGETrec){
branch = TARGETloader->TreeR()->GetBranch("TARGETRecPoints");
if(branch)branch->SetAddress(&TARGETrec);
}
if(useclustersv2 && (!TR || !TARGETrec || !branch)){
useclustersv2 = kFALSE;
cout<<"\n ======================================================= \n";
cout<<"WARNING: there are no CLUSTERSV2 on this file ! \n";
cout<<"======================================================= \n \n";
}
//local variables
Int_t mod; //module number
Int_t nbytes = 0;
Double_t pos[3]; // Global position of the current module
Float_t ragdet; // Radius of detector (x y plane)
Int_t first; // first module
Int_t last; // last module
Int_t nrecp; //number of RecPoints for a given module
//List of histograms
TObjArray histos(26,0); // contains the pointers to the histograms
// Book histograms SPD
TH2F *rspd = new TH2F("rspd","Radii of digits - SPD",50,-10.,10.,50,-10.,10.);
TH2F *rhspd = new TH2F("rhspd","Radii of hits - SPD",50,-10.,10.,50,-10.,10.);
TH2F *rmspd = new TH2F("rmspd","Radii of SPD modules",50,-10.,10.,50,-10.,10.);
TH1F *zspd = new TH1F("zspd","Z of digits - SPD",100,-30.,30.);
TH1F *zhspd = new TH1F("zhspd","Z of hits - SPD",100,-30.,30.);
TH1F *zmspd = new TH1F("zmspd","Z of SPD modules",100,-30,30.);
Char_t title1[50]="";
Char_t title2[50]="";
if(userec){
sprintf(title1,"Radii of recpoints - %s","SPD");
sprintf(title2,"Z of recpoints - %s","SPD");
}
if(useclustersv2){
sprintf(title1,"Radii of clustersV2 - %s","SPD");
sprintf(title2,"Z of clustersV2 - %s","SPD");
}
TH2F *rrspd = new TH2F("rrspd",title1,50,-10.,10.,50,-10.,10.);
TH1F *zrspd = new TH1F("zrspd",title2,100,-30.,30.);
TH1F *enespd = new TH1F("enespd","Energy deposition SPD (KeV)",100,0.,1000.);
histos.AddLast(rspd); // 0
histos.AddLast(rhspd); // 1
histos.AddLast(rmspd); // 2
histos.AddLast(zspd); // 3
histos.AddLast(zhspd); // 4
histos.AddLast(zmspd); // 5
histos.AddLast(rrspd); // 6
histos.AddLast(zrspd); // 7
histos.AddLast(enespd); // 8
// Book histograms SDD
TH2F *rsdd = new TH2F("rsdd","Radii of digits - SDD",50,-40.,40.,50,-40.,40.);
TH2F *rhsdd = new TH2F("rhsdd","Radii of hits - SDD",50,-40.,40.,50,-40.,40.);
TH2F *rmsdd = new TH2F("rmsdd","Radii of SDD modules",50,-40.,40.,50,-40.,40.);
TH1F *zsdd = new TH1F("zsdd","Z of digits - SDD",100,-40.,40.);
TH1F *zhsdd = new TH1F("zhsdd","Z of hits - SDD",100,-40.,40.);
TH1F *zmsdd = new TH1F("zmsdd","Z of SDD modules",100,-40,40.);
Char_t title3[50];
Char_t title4[50];
if(userec){
sprintf(title3,"Radii of recpoints - %s","SDD");
sprintf(title4,"Z of recpoints - %s","SDD");
}
if(useclustersv2){
sprintf(title3,"Radii of clustersV2 - %s","SDD");
sprintf(title4,"Z of clustersV2 - %s","SDD");
}
TH2F *rrsdd = new TH2F("rrsdd",title3,50,-40.,40.,50,-40.,40.);
TH1F *zrsdd = new TH1F("zrsdd",title4,100,-40.,40.);
TH1F *enesdd = new TH1F("enesdd","Energy deposition SDD (KeV)",100,0.,1000.);
histos.AddLast(rsdd); // 9
histos.AddLast(rhsdd); // 10
histos.AddLast(rmsdd); // 11
histos.AddLast(zsdd); // 12
histos.AddLast(zhsdd); // 13
histos.AddLast(zmsdd); // 14
histos.AddLast(rrsdd); // 15
histos.AddLast(zrsdd); // 16
histos.AddLast(enesdd); // 17
// Book histogram SSD
TH2F *rssd = new TH2F("rssd","Radii of digits - SSD",50,-50.,50.,50,-50.,50.);
TH2F *rhssd = new TH2F("rhssd","Radii of hits - SSD",50,-50.,50.,50,-50.,50.);
TH2F *rmssd = new TH2F("rmssd","Radii of SSD modules",50,-50.,50.,50,-50.,50.);
TH1F *zssd = new TH1F("zssd","Z of digits - SSD",100,-70.,70.);
TH1F *zhssd = new TH1F("zhssd","Z of hits - SSD",100,-70.,70.);
TH1F *zmssd = new TH1F("zmssd","Z of SSD modules",100,-70,70.);
Char_t title5[50];
Char_t title6[50];
if(userec){
sprintf(title5,"Radii of recpoints - %s","SSD");
sprintf(title6,"Z of recpoints - %s","SSD");
}
if(useclustersv2){
sprintf(title5,"Radii of clustersV2 - %s","SSD");
sprintf(title6,"Z of clustersV2 - %s","SSD");
}
TH2F *rrssd = new TH2F("rrssd",title5,50,-50.,50.,50,-50.,50.);
TH1F *zrssd = new TH1F("zrssd",title6,100,-70.,70.);
TH1F *enessd = new TH1F("enessd","Energy deposition SSD (KeV)",100,0.,1000.);
histos.AddLast(rssd); // 18
histos.AddLast(rhssd); // 19
histos.AddLast(rmssd); // 20
histos.AddLast(zssd); // 21
histos.AddLast(zhssd); // 22
histos.AddLast(zmssd); // 23
histos.AddLast(rrssd); // 24
histos.AddLast(zrssd); // 25
histos.AddLast(enessd); // 26
//
// Loop on subdetectors
//
IlcTARGETgeom *geom = TARGET->GetTARGETgeom();
TString detna; // subdetector name
for(Int_t subd=0;subd<3;subd++){
if(All || (choice.Contains("SPD") && subd==0) || (choice.Contains("SDD") && subd==1) || (choice.Contains("SSD") && subd==2)){
// Prepare array for the digits
TClonesArray *TARGETdigits = TARGET->DigitsAddress(subd);
Bool_t usedigits = kTRUE;
if(!TARGETdigits){
usedigits = kFALSE;
cout<<"\n ======================================================= \n";
cout<<"WARNING: there are no DIGTARGET on this file ! \n";
cout<<"======================================================= \n \n";
}
// Get segmentation model
if(subd==0)detna="SPD";
if(subd==1)detna="SDD";
if(subd==2)detna="SSD";
IlcTARGETsegmentation *seg=(IlcTARGETsegmentation*)detTypeRec->GetSegmentationModel(subd);
// Loop on modules
first = geom->GetStartDet(subd);
last = geom->GetLastDet(subd);
if(verbose){
cout<<" "<<endl<<"-------------------------------------"<<endl;
cout<<"Start processing subdetector "<<detna<<endl;
cout<<detna<<" first module "<<first<<endl;
cout<<detna<<" last module "<<last<<endl;
cout<<" "<<endl<<" "<<endl;
}
for (mod=first; mod<=last; mod++){
geom->GetTrans(mod,pos); // position of the module in the MRS
ragdet=sqrt(pos[0]*pos[0]+pos[1]*pos[1]);
// The following 2 histos are a check of the geometry
TH2F *bidi = (TH2F*)histos.At(2+subd*9);
TH1F *uni = (TH1F*)histos.At(5+subd*9);
bidi->Fill(pos[0],pos[1]);
uni->Fill(pos[2]);
if(verbose){
cout<<"=========================================================\n";
cout<<detna<<" module="<<mod<<endl;
cout<<"Mod. coordinates: "<<pos[0]<<", "<<pos[1]<<", ";
cout<<pos[2]<<" Radius "<<ragdet<<endl;
}
// Hits
GetHitsCoor(TARGET,mod,histos,subd,verbose);
//RecPoints
if(userec){
detTypeRec->ResetRecPoints();
branch->GetEvent(mod);
TH2F *bidi=(TH2F*)histos.At(6+subd*9);
TH1F *uni=(TH1F*)histos.At(7+subd*9);
nrecp=GetRecCoor(geom,TARGETrec,mod,bidi,uni,verbose);
}
if(useclustersv2){
detTypeRec->ResetRecPoints();
branch->GetEvent(mod);
TH2F *bidi=(TH2F*)histos.At(6+subd*9);
TH1F *uni=(TH1F*)histos.At(7+subd*9);
nrecp=GetClusCoor(geom,TARGETrec,mod,bidi,uni,verbose);
}
// Digits
if(usedigits){
detTypeRec->ResetDigits();
nbytes += TD->GetEvent(mod);
GetDigits(seg,geom,TARGETdigits,subd,mod,verbose,histos);
}
} // End of loop on the modules
TH1F *h1tmp;
TH2F *h2tmp;
// Plot the histograms
TCanvas *current=0; // current Canvas (1--> SPD, 2---> SDD, 3---> SSD)
if(subd==0){
// Prepare canvas 1
TCanvas *c1 = new TCanvas("c1","SPD",10,10,600,900);
c1->Divide(2,3);
current=c1;
}
if(subd==1){
// Prepare canvas 2
TCanvas *c2 = new TCanvas("c2","SDD",40,40,600,900);
c2->Divide(2,3);
current=c2;
}
if(subd==2){
// Prepare canvas 3
TCanvas *c3 = new TCanvas("c3","SSD",70,70,600,900);
c3->Divide(2,3);
current=c3;
}
current->cd(1);
h2tmp = (TH2F*)histos.At(9*subd);
h2tmp->Draw();
current->cd(2);
h1tmp=(TH1F*)histos.At(3+subd*9);
h1tmp->Draw();
current->cd(3);
h2tmp=(TH2F*)histos.At(1+9*subd);
h2tmp->Draw();
current->cd(4);
h1tmp=(TH1F*)histos.At(4+subd*9);
h1tmp->Draw();
if(userec || useclustersv2){
current->cd(5);
h2tmp=(TH2F*)histos.At(6+9*subd);
h2tmp->Draw();
current->cd(6);
h1tmp=(TH1F*)histos.At(7+subd*9);
h1tmp->Draw();
}
else {
current->cd(5);
h2tmp=(TH2F*)histos.At(2+9*subd);
h2tmp->Draw();
current->cd(6);
h2tmp=(TH2F*)histos.At(5+9*subd);
h2tmp->Draw();
}
} // if(All.....
} // end of loop on subdetectors
// Save the histograms
TFile *fh = new TFile("IlcTARGETGeoPlot.root","recreate");
// The list is written to file as a single entry
TList *lihi = new TList();
// copy the pointers to the histograms to a TList object.
// The histograms concerning recpoints are not copied if
// 'userec' is false.
for(Int_t i=0;i<histos.GetEntriesFast();i++){
if(choice.Contains("All") || (choice.Contains("SPD") && i<8) || (choice.Contains("SDD") && i>7 && i<16) || (choice.Contains("SSD") && i>15)){
if(!(!userec && ((i+2)%9==0 || (i+1)%9==0)))lihi->Add(histos.At(i));
}
}
lihi->Write("Histograms TARGET hits+digits+recpoints",TObject::kSingleKey);
fh->Close();
return retcode;
}
void gen(Int_t nev = 1, char* filename = "gilc.root")
{
// Load libraries
// gSystem->SetIncludePath("-I$ROOTSYS/include -I$ILC_ROOT/include -I$ILC_ROOT");
gSystem->Load("liblhapdf.so"); // Parton density functions
gSystem->Load("libEGPythia6.so"); // TGenerator interface
gSystem->Load("libpythia6.so"); // Pythia
gSystem->Load("libIlcPythia6.so"); // ILC specific implementations
IlcPDG::AddParticlesToPdgDataBase();
TDatabasePDG::Instance();
// Run loader
IlcRunLoader* rl = IlcRunLoader::Open("gilc.root","FASTRUN","recreate");
rl->SetCompressionLevel(2);
rl->SetNumberOfEventsPerFile(nev);
rl->LoadKinematics("RECREATE");
rl->MakeTree("E");
gIlc->SetRunLoader(rl);
// Create stack
rl->MakeStack();
IlcStack* stack = rl->Stack();
// Header
IlcHeader* header = rl->GetHeader();
// Create and Initialize Generator
gROOT->LoadMacro("$ILC_ROOT/test/vmctest/ppbench/genPPbenchConfig.C");
IlcGenerator* gener = genPPbenchConfig();
// Go to gilc.root
rl->CdGAFile();
// Forbid some decays. Do it after gener->Init(0, because
// the initialization of the generator includes reading of the decay table.
// ...
//
// Event Loop
//
TStopwatch timer;
timer.Start();
for (Int_t iev = 0; iev < nev; iev++) {
cout <<"Event number "<< iev << endl;
// Initialize event
header->Reset(0,iev);
rl->SetEventNumber(iev);
stack->Reset();
rl->MakeTree("K");
// Generate event
stack->Reset();
stack->ConnectTree(rl->TreeK());
gener->Generate();
cout << "Number of particles " << stack->GetNprimary() << endl;
// Finish event
header->SetNprimary(stack->GetNprimary());
header->SetNtrack(stack->GetNtrack());
// I/O
stack->FinishEvent();
header->SetStack(stack);
rl->TreeE()->Fill();
rl->WriteKinematics("OVERWRITE");
} // event loop
timer.Stop();
timer.Print();
// Termination
// Generator
gener->FinishRun();
// Write file
rl->WriteHeader("OVERWRITE");
gener->Write();
rl->Write();
}
void fastGenPA(Int_t nev = 1, char* filename = "gilc.root")
{
// Runloader
IlcRunLoader* rl = IlcRunLoader::Open("gilc.root", "FASTRUN", "recreate");
rl->SetCompressionLevel(2);
rl->SetNumberOfEventsPerFile(10000);
rl->LoadKinematics("RECREATE");
rl->MakeTree("E");
gIlc->SetRunLoader(rl);
// Create stack
rl->MakeStack();
IlcStack* stack = rl->Stack();
// Header
IlcHeader* header = rl->GetHeader();
// Create and Initialize Generator
IlcGenerator *gener = CreateGenerator();
gener->Init();
gener->SetStack(stack);
//
// Event Loop
//
Int_t iev;
for (iev = 0; iev < nev; iev++) {
printf("\n \n Event number %d \n \n", iev);
// Initialize event
header->Reset(0,iev);
rl->SetEventNumber(iev);
stack->Reset();
rl->MakeTree("K");
// Generate event
gener->Generate();
// Analysis
Int_t npart = stack->GetNprimary();
printf("Analyse %d Particles\n", npart);
for (Int_t part=0; part<npart; part++) {
TParticle *MPart = stack->Particle(part);
Int_t mpart = MPart->GetPdgCode();
}
// Finish event
header->SetNprimary(stack->GetNprimary());
header->SetNtrack(stack->GetNtrack());
// I/O
//
stack->FinishEvent();
header->SetStack(stack);
rl->TreeE()->Fill();
rl->WriteKinematics("OVERWRITE");
} // event loop
//
// Termination
// Generator
gener->FinishRun();
// Write file
rl->WriteHeader("OVERWRITE");
gener->Write();
rl->Write();
}
void fastGen(Int_t nev = 1, char* filename = "gilc.root")
{
// Run loader
IlcRunLoader* rl = IlcRunLoader::Open("gilc.root","FASTRUN","recreate");
rl->SetCompressionLevel(2);
rl->SetNumberOfEventsPerFile(nev);
rl->LoadKinematics("RECREATE");
rl->MakeTree("E");
gIlc->SetRunLoader(rl);
// Create stack
rl->MakeStack();
IlcStack* stack = rl->Stack();
// Header
IlcHeader* header = rl->GetHeader();
// Generator
IlcGenPythia *gener = new IlcGenPythia(-1);
gener->SetMomentumRange(0,999999);
gener->SetProcess(kPyMb);
gener->SetEnergyCMS(14000.);
gener->SetThetaRange(45, 135);
gener->SetPtRange(0., 1000.);
gener->SetStack(stack);
gener->Init();
rl->CdGAFile();
//
// Event Loop
//
for (Int_t iev = 0; iev < nev; iev++) {
// Initialize event
header->Reset(0,iev);
rl->SetEventNumber(iev);
stack->Reset();
rl->MakeTree("K");
// Generate event
Int_t nprim = 0;
Int_t ntrial = 0;
Int_t minmult = 1000;
while(nprim<minmult) {
// Selection of events with multiplicity
// bigger than "minmult"
stack->Reset();
gener->Generate();
ntrial++;
nprim = stack->GetNprimary();
}
cout << "Number of particles " << nprim << endl;
cout << "Number of trials " << ntrial << endl;
// Finish event
header->SetNprimary(stack->GetNprimary());
header->SetNtrack(stack->GetNtrack());
// I/O
stack->FinishEvent();
header->SetStack(stack);
rl->TreeE()->Fill();
rl->WriteKinematics("OVERWRITE");
} // event loop
// Termination
// Generator
gener->FinishRun();
// Stack
stack->FinishRun();
// Write file
rl->WriteHeader("OVERWRITE");
gener->Write();
rl->Write();
}
