/********************************************************************************
* 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" *
********************************************************************************/
eventDisplay(TString mcEngine="TGeant3")
{
TString inFile = "data/test_" + mcEngine + ".mc.root";
TString parFile = "data/params_" + mcEngine + ".root";
TString outFile = "data/test_" + mcEngine + ".root";
// ----- Reconstruction run -------------------------------------------
FairRunAna *fRun= new FairRunAna();
fRun->SetInputFile(inFile);
fRun->SetOutputFile(outFile);
// ----- Parameter database --------------------------------------------
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
parIo1->open(parFile);
rtdb->setFirstInput(parIo1);
// ------------------------------------------------------------------------
FairEventManager *fMan = new FairEventManager ();
FairMCTracks *Track = new FairMCTracks ("Monte-Carlo Tracks");
FairMCPointDraw *RutherfordPoints = new FairMCPointDraw ("FairRutherfordPoint",kBlue , kFullSquare);
fMan->AddTask(Track);
fMan->AddTask(RutherfordPoints);
fMan->Init();
}
/********************************************************************************
* 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" *
********************************************************************************/
eventDisplay(TString mcEngine="TGeant3")
{
//-----User Settings:-----------------------------------------------
TString InputFile ="data/testrun_" + mcEngine + ".root";
TString ParFile ="data/testparams_" + mcEngine + ".root";
TString OutFile ="data/tst.root";
//------------------------------------------------------------------
// ----- Reconstruction run -------------------------------------------
FairRunAna *fRun= new FairRunAna();
fRun->SetInputFile(InputFile.Data());
fRun->SetOutputFile(OutFile.Data());
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parInput1 = new FairParRootFileIo();
parInput1->open(ParFile.Data());
rtdb->setFirstInput(parInput1);
FairEventManager *fMan= new FairEventManager();
//----------------------Traks and points -------------------------------------
FairMCTracks *Track = new FairMCTracks("Monte-Carlo Tracks");
FairMCPointDraw *TorinoDetectorPoints = new FairMCPointDraw("FairTestDetectorPoint", kRed, kFullSquare);
// FairHitDraw *ToyHits = new FairHitDraw("ToyHit");
fMan->AddTask(Track);
fMan->AddTask(TorinoDetectorPoints);
// fMan->AddTask(ToyHits);
fMan->Init();
}
void califaEventDisplay()
{
FairRunAna *fRun= new FairRunAna();
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
parIo1->open("sim_par.root");
rtdb->setFirstInput(parIo1);
rtdb->print();
fRun->SetInputFile("sim_out.root");
fRun->SetOutputFile("test.root");
R3BEventManager *fMan= new R3BEventManager();
R3BMCTracks *Track = new R3BMCTracks ("Monte-Carlo Tracks");
R3BCaloEventDisplay *CaloEvtVis = new R3BCaloEventDisplay("R3BCaloEventDisplay");
R3BCaloHitEventDisplay *CaloHitEvtVis = new R3BCaloHitEventDisplay("R3BCaloHitEventDisplay");
CaloEvtVis->SelectGeometryVersion(10);
fMan->AddTask(CaloEvtVis);
fMan->AddTask(CaloHitEvtVis);
fMan->AddTask(Track);
fMan->Init();
}
void run_eveTransform_proto()
{
TString dir = getenv("VMCWORKDIR");
TString protomapfile = "proto.map";
TString protomapdir = dir + "/scripts/"+ protomapfile;
FairLogger *fLogger = FairLogger::GetLogger();
fLogger -> SetLogToScreen(kTRUE);
fLogger->SetLogVerbosityLevel("MEDIUM");
FairRunAna *fRun= new FairRunAna();
fRun -> SetInputFile("output_proto.root");
fRun -> SetOutputFile("output_proto.reco_display.root");
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
parIo1->open("param.dummy_proto.root");
rtdb->setFirstInput(parIo1);
FairRootManager* ioman = FairRootManager::Instance();
ATEventManager *eveMan = new ATEventManager();
ATEventDrawTask* eve = new ATEventProtoDrawTask();
eve->SetGeoOption("Prototype"); // Options: "ATTPC" - "Prototype"
eve->SetProtoMap(protomapdir.Data());
eveMan->AddTask(eve);
eveMan->Init();
}
void eventDisplay()
{
//-----User Settings:-----------------------------------------------
TString InputFile ="attpcsim.root";
TString ParFile ="attpcpar.root";
TString OutFile ="attpctest.root";
// ----- Reconstruction run -------------------------------------------
FairRunAna *fRun= new FairRunAna();
fRun->SetInputFile(InputFile.Data());
fRun->SetOutputFile(OutFile.Data());
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parInput1 = new FairParRootFileIo();
parInput1->open(ParFile.Data());
rtdb->setFirstInput(parInput1);
FairEventManager *fMan= new FairEventManager();
//----------------------Traks and points -------------------------------------
FairMCTracks *Track = new FairMCTracks("Monte-Carlo Tracks");
FairMCPointDraw *AtTpcPoints = new FairMCPointDraw("AtTpcPoint", kBlue, kFullSquare);
fMan->AddTask(Track);
fMan->AddTask(AtTpcPoints);
fMan->Init();
}
void run_eve(TString InputDataFile = "output.root",TString OutputDataFile = "output.reco_display.root", TString unpackDir="/Unpack_GETDecoder2/")
{
FairLogger *fLogger = FairLogger::GetLogger();
fLogger -> SetLogToScreen(kTRUE);
fLogger->SetLogVerbosityLevel("MEDIUM");
TString dir = getenv("VMCWORKDIR");
TString geoFile = "ATTPC_v1.1_geomanager.root";
TString InputDataPath = dir + "/macro/"+ unpackDir + InputDataFile;
TString OutputDataPath = dir + "/macro/"+ unpackDir + OutputDataFile;
TString GeoDataPath = dir + "/geometry/" + geoFile;
FairRunAna *fRun= new FairRunAna();
fRun -> SetInputFile(InputDataPath);
fRun -> SetOutputFile(OutputDataPath);
fRun -> SetGeomFile(GeoDataPath);
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
//parIo1->open("param.dummy.root");
rtdb->setFirstInput(parIo1);
FairRootManager* ioman = FairRootManager::Instance();
ATEventManager *eveMan = new ATEventManager();
ATEventDrawTask* eve = new ATEventDrawTask();
eve->Set3DHitStyleBox();
eve->SetMultiHit(100); //Set the maximum number of multihits in the visualization
eve->SetSaveTextData();
eve->UnpackHoughSpace();
eveMan->AddTask(eve);
eveMan->Init();
}
void run(TString runNumber)
{
TStopwatch timer;
timer.Start();
TString dirIn1 = "/Volumes/Data/kresan/s438/data/";
TString dirIn2 = "/Volumes/Data/kresan/s438/tcal/";
TString dirOut = "/Volumes/Data/kresan/s438/digi/";
TString tdiffParName = "tdiff_" + runNumber + ".dat";
TString inputFileName1 = dirIn2 + runNumber + "_tcal.root"; // name of input file
TString parFileName = dirIn1 + "params_" + runNumber + "_raw.root"; // name of parameter file
TString outputFileName = dirOut + runNumber + "_digi.root"; // name of output file
// Create analysis run -------------------------------------------------------
FairRunAna* run = new FairRunAna();
run->SetInputFile(inputFileName1.Data());
run->SetOutputFile(outputFileName.Data());
// ---------------------------------------------------------------------------
// ----- Runtime DataBase info -----------------------------------------------
FairRuntimeDb* rtdb = run->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
parIo1->open(parFileName);
rtdb->setFirstInput(parIo1);
rtdb->setOutput(parIo1);
rtdb->saveOutput();
// ---------------------------------------------------------------------------
// Tdiff calibration ---------------------------------------------------------
R3BLandTdiff* landTdiff = new R3BLandTdiff("LandTdiff", 1);
landTdiff->SetTdiffParName(tdiffParName.Data());
run->AddTask(landTdiff);
// ---------------------------------------------------------------------------
// Analysis ------------------------------------------------------------------
R3BLandAna* landAna = new R3BLandAna("LandAna", 1);
landAna->SetNofBars(100);
run->AddTask(landAna);
// ---------------------------------------------------------------------------
// Initialize ----------------------------------------------------------------
run->Init();
FairLogger::GetLogger()->SetLogScreenLevel("INFO");
// ---------------------------------------------------------------------------
// Run -----------------------------------------------------------------------
run->Run();
// ---------------------------------------------------------------------------
timer.Stop();
Double_t rtime = timer.RealTime();
Double_t ctime = timer.CpuTime();
cout << endl << endl;
cout << "Macro finished succesfully." << endl;
cout << "Output file is " << outputFileName << endl;
cout << "Parameter file is " << parFileName << endl;
cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl << endl;
}
void AnalysisTaskXi(TString pre = "", int nevts=0, double mom=2.7){
TDatabasePDG::Instance()-> AddParticle("pbarpSystem","pbarpSystem", 1.9, kFALSE, 0.1, 0,"", 88888);
//Output File
if (pre==""){
TString Path = "/private/puetz/mysimulations/analysis/pbarp_Xiplus_Ximinus/idealtracking/10000_events/";
TString outPath = Path;
TString OutputFile = outPath + "analysis_output_test.root";
//Input simulation Files
TString inPIDFile = Path + "pid_complete.root";
TString inParFile = Path + "simparams.root";
}
else{
TString Path = pre;
TString outPath = Path + "_test_";
TString OutputFile = Path + "_analysis_output.root";
//Input simulation Files
TString inPIDFile = Path + "_pid_complete.root";
TString inParFile = Path + "_simparams.root";
}
TString PIDParFile = TString( gSystem->Getenv("VMCWORKDIR")) + "/macro/params/all.par";
//Initialization
FairLogger::GetLogger()->SetLogToFile(kFALSE);
FairRunAna* RunAna = new FairRunAna();
FairRuntimeDb* rtdb = RunAna->GetRuntimeDb();
RunAna->SetInputFile(inPIDFile);
//setup parameter database
FairParRootFileIo* parIo = new FairParRootFileIo();
parIo->open(inParFile);
FairParAsciiFileIo* parIoPID = new FairParAsciiFileIo();
parIoPID->open(PIDParFile.Data(),"in");
rtdb->setFirstInput(parIo);
rtdb->setSecondInput(parIoPID);
rtdb->setOutput(parIo);
RunAna->SetOutputFile(OutputFile);
// *** HERE OUR TASK GOES!
AnalysisTask *anaTask = new AnalysisTask();
anaTask->SetOutPutDir(outPath);
anaTask->SetNEvents(nevts);
anaTask->SetMom(mom);
RunAna->AddTask(anaTask);
RunAna->Init();
RunAna->Run(0.,1.);
exit(0);
eventDisplay()
{
//-----User Settings:-----------------------------------------------
TString SimEngine ="TGeant4";
TString InputFile ="ship.10.0.Pythia8-TGeant4_D.root";
TString ParFile ="ship.params.10.0.Pythia8-TGeant4_D.root";
TString OutFile ="tst.root";
//----Load the default libraries------
gROOT->LoadMacro("$VMCWORKDIR/gconfig/basiclibs.C");
basiclibs();
// ----- Reconstruction run -------------------------------------------
FairRunAna *fRun= new FairRunAna();
fRun->SetInputFile(InputFile.Data());
fRun->SetOutputFile(OutFile.Data());
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parInput1 = new FairParRootFileIo();
parInput1->open(ParFile.Data());
rtdb->setFirstInput(parInput1);
FairEventManager *fMan= new FairEventManager();
//----------------------Tracks and points -------------------------------------
FairMCTracks *Track = new FairMCTracks("Monte-Carlo Tracks");
FairMCPointDraw *VetoPoints = new FairMCPointDraw("vetoPoint", kBlue, kFullDiamond);
FairMCPointDraw *StrawPoints = new FairMCPointDraw("strawtubesPoint", kGreen, kFullCircle);
FairMCPointDraw *EcalPoints = new FairMCPointDraw("EcalPoint", kRed, kFullSquare);
FairMCPointDraw *HcalPoints = new FairMCPointDraw("HcalPoint", kMagenta, kFullSquare);
FairMCPointDraw *MuonPoints = new FairMCPointDraw("muonPoint", kYellow, kFullSquare);
FairMCPointDraw *RpcPoints = new FairMCPointDraw("ShipRpcPoint", kOrange, kFullSquare);
fMan->AddTask(Track);
fMan->AddTask(VetoPoints);
fMan->AddTask(StrawPoints);
fMan->AddTask(EcalPoints);
fMan->AddTask(HcalPoints);
fMan->AddTask(MuonPoints);
fMan->AddTask(RpcPoints);
fMan->Init(1,4,10000);
gGeoManager->GetVolume("rockD")->SetVisibility(0);
gGeoManager->GetVolume("rockS")->SetVisibility(0);
gGeoManager->GetVolume("wire")->SetVisibility(0);
gGeoManager->GetVolume("gas")->SetVisibility(0);
gGeoManager->GetVolume("Ecal")->SetVisibility(1);
gGeoManager->GetVolume("Hcal")->SetVisibility(1);
gGeoManager->GetVolume("Ecal")->SetLineColor(kYellow);
gGeoManager->GetVolume("Hcal")->SetLineColor(kOrange+3);
TEveElement* geoscene = gEve->GetScenes()->FindChild("Geometry scene");
gEve->ElementChanged(geoscene,true,true);
}
void much_ana(Int_t nEvents=1000){
TTree::SetMaxTreeSize(90000000000);
TString script = TString(gSystem->Getenv("LIT_SCRIPT"));
TString parDir = TString(gSystem->Getenv("VMCWORKDIR")) + TString("/parameters");
// Input and output data
TString dir = "events/much_anna_omega_8gev_10k/"; // Output directory
TString mcFile = dir + "mc.0000.root"; // MC transport file
TString parFile = dir + "param.0000.root"; // Parameters file
TString globalRecoFile = dir + "global.reco.0000.root"; // File with reconstructed tracks and hits
TString analysisFile = dir + "analysis.0000.root"; // Output analysis file
TString muchDigiFile = parDir + "/much/much_v12c.digi.root"; // MUCH digi file
if (script == "yes") {
mcFile = TString(gSystem->Getenv("LIT_MC_FILE"));
parFile = TString(gSystem->Getenv("LIT_PAR_FILE"));
globalRecoFile = TString(gSystem->Getenv("LIT_GLOBAL_RECO_FILE"));
analysisFile = TString(gSystem->Getenv("LIT_ANALYSIS_FILE"));
muchDigiFile = TString(gSystem->Getenv("LIT_MUCH_DIGI"));
}
gROOT->LoadMacro("$VMCWORKDIR/gconfig/basiclibs.C");
basiclibs();
gROOT->LoadMacro("$VMCWORKDIR/macro/much/muchlibs.C");
muchlibs();
FairRunAna *fRun= new FairRunAna();
fRun->SetInputFile(mcFile);
fRun->AddFriend(globalRecoFile);
fRun->SetOutputFile(analysisFile);
TString muchDigiFile = gSystem->Getenv("VMCWORKDIR");
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
parIo1->open(parFile);
rtdb->setFirstInput(parIo1);
rtdb->setOutput(parIo1);
rtdb->saveOutput();
// ------------------------------------------------------------------------
CbmKF* kf = new CbmKF();
CbmAnaDimuonAnalysis* ana = new CbmAnaDimuonAnalysis("DimuonAnalysis", muchDigiFile, 1);
ana->SetVerbose(0);
ana->SetStsPointsAccQuota(4);
ana->SetStsTrueHitQuota(0.7);
fRun->AddTask(kf);
fRun->AddTask(ana);
fRun->Init();
fRun->Run(0,nEvents);
}
void ana(int iplab = 0, int itype = 0, int brem = 1, int fid=0, int nevts = 10000) {
gSystem->Load("libanatda");
gSystem->ListLibraries();
//double plab[3] = {5.513, 8., 12.};
//const char *tt[2] = {"pip_pim","jpsi"};
//const char *cbrem[2] = {"raw","brem"};
//TString inPidFile = Form("output/pid/pbar_p_%s_pi0_plab%3.1f_%d.root", tt[itype], plab[iplab], fid);
//TString inParFile = Form("output/par/pbar_p_%s_pi0_plab%3.1f_%d.root", tt[itype], plab[iplab], fid);
//TString outFile = Form("test/ana_%s_%s_plab%3.1f_%d.root", tt[itype], cbrem[brem], plab[iplab], fid);
//cout << "inPidFile= " << inPidFile << endl;
//cout << "inParFile= " << inParFile << endl;
//cout << " tt= " << tt[itype] << " Outfile= " << outFile << endl;
const char *tt[2] = {"pi0pipm_dpm","pi0jpsi"};
const char *cbrem[2] = {"raw","brem"};
const char *dir = Form("/vol0/panda/work/jpsi_pi0/grid.out/tda/%s/runall.%d.%d", tt[itype], iplab, fid);
TString inPidFile = Form("%s/pid_complete.root",dir);
TString inParFile = Form("%s/simparams.root",dir);
TString outFile = Form("%s/ana_%s.root",dir,cbrem[brem]);
cout << "inPidFile= " << inPidFile << endl;
cout << "inParFile= " << inParFile << endl;
cout << "outFile= " << outFile << endl;
// *** initialization
FairLogger::GetLogger()->SetLogToFile(kFALSE);
FairRunAna* fRun = new FairRunAna();
fRun->SetInputFile(inPidFile);
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIO = new FairParRootFileIo();
parIO->open(inParFile);
FairParAsciiFileIo* parIOPid = new FairParAsciiFileIo();
parIOPid->open((TString(gSystem->Getenv("VMCWORKDIR"))+"/macro/params/all.par").Data(),"in");
rtdb->setFirstInput(parIO);
rtdb->setSecondInput(parIOPid);
rtdb->setOutput(parIO);
AnaTda *atda = new AnaTda(iplab, itype, brem);
atda->set_verbosity(0);
fRun->AddTask(atda);
fRun->SetOutputFile(outFile);
fRun->Init();
fRun->Run(0,nevts);
cout << "Done with: " << outFile << endl;
}
void event_display()
{
TString dir = "events/mvd/";
TString mcFile = dir + "mc.0000.root"; // MC transport file
TString parFile = dir + "param.0000.root"; // Parameter file
gROOT->LoadMacro("$VMCWORKDIR/gconfig/basiclibs.C");
basiclibs();
gROOT->LoadMacro("$VMCWORKDIR/macro/littrack/cbmrootlibs.C");
cbmrootlibs();
gSystem->Load("libEve");
gSystem->Load("libEventDisplay");
FairRunAna *run= new FairRunAna();
run->SetInputFile(mcFile);
run->SetOutputFile("test.root");
FairEventManager* eventManager= new FairEventManager();
FairMCTracks* mcTracks = new FairMCTracks("Monte-Carlo Tracks");
FairMCPointDraw* richPoints = new FairMCPointDraw("RichPoint", kOrange, kFullSquare);
FairMCPointDraw* tofPoints = new FairMCPointDraw("TofPoint", kBlue, kFullSquare);
FairMCPointDraw* trdPoints = new FairMCPointDraw("TrdPoint", kTeal, kFullSquare);
FairMCPointDraw* muchPoints = new FairMCPointDraw("MuchPoint", kRed, kFullSquare);
FairMCPointDraw* ecalPoints = new FairMCPointDraw("EcalPoint", kYellow, kFullSquare);
FairMCPointDraw* refPlanePoints = new FairMCPointDraw("RefPlanePoint", kPink, kFullSquare);
FairMCPointDraw* stsPoints = new FairMCPointDraw("StsPoint", kCyan, kFullSquare);
eventManager->AddTask(mcTracks);
eventManager->AddTask(richPoints);
eventManager->AddTask(ecalPoints);
eventManager->AddTask(tofPoints);
eventManager->AddTask(trdPoints);
eventManager->AddTask(muchPoints);
eventManager->AddTask(refPlanePoints);
eventManager->AddTask(stsPoints);
// ----- Parameter database --------------------------------------------
FairRuntimeDb* rtdb = run->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
parIo1->open(parFile.Data());
rtdb->setFirstInput(parIo1);
rtdb->setOutput(parIo1);
rtdb->saveOutput();
// ------------------------------------------------------------------------
eventManager->Init();
}
Int_t calgeo_read()
{
// Create a Runtime Database singleton.
FairRuntimeDb* db = FairRuntimeDb::instance();
// Set the SQL IO as first input
FairParTSQLIo* inp = new FairParTSQLIo();
// Verbosity level
//inp->SetVerbosity(1);
inp->open();
db->setFirstInput(inp);
// Create in memory the relevant container
R3BCaloGeometryPar* par = (R3BCaloGeometryPar*)(db->getContainer("CaloGeometryPar"));
// Create a dummy runID using date in UTC from which
// corresponding parameters will be initialised
ValTimeStamp tStamp(2014,03,21,18,00,00);
UInt_t runId = tStamp.GetSec();
cout << "-I- looking for parameters at runID# " << runId << endl;
cout << "-I- corresponding time in runID (UTC) " << tStamp.Format("iso") << endl;
// Use the generated RunID to initialised the parameter
// using the SQL-based IO input
db->initContainers(runId);
// Get the container after initialisation
// from the RuntimeDB
R3BCaloGeometryPar* par = (R3BCaloGeometryPar*)(db->getContainer("CaloGeometryPar"));
cout << endl;
cout << "-I- Reading Parameter data from SQL Database: \n" << endl;
cout << endl;
par->Print();
cout << endl;
if (db) delete db;
return 0;
}
void run_eve_proto_lite(TString InputDataFile = "output_proto.root",TString OutputDataFile = "output_proto.reco_display.root", TString unpackDir="/Unpack_GETDecoder2/")
{
TString dir = getenv("VMCWORKDIR");
TString protomapfile = "proto.map";
TString protomapdir = dir + "/scripts/"+ protomapfile;
TString geoFile = "ATTPC_Proto_v1.0_geomanager.root";
TString InputDataPath = dir + "/macro/"+ unpackDir + InputDataFile;
TString OutputDataPath = dir + "/macro/"+ unpackDir + OutputDataFile;
TString GeoDataPath = dir + "/geometry/" + geoFile;
FairLogger *fLogger = FairLogger::GetLogger();
fLogger -> SetLogToScreen(kTRUE);
fLogger->SetLogVerbosityLevel("MEDIUM");
FairRunAna *fRun= new FairRunAna();
fRun -> SetInputFile(InputDataPath);
fRun -> SetOutputFile(OutputDataPath);
fRun -> SetGeomFile(GeoDataPath);
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
//parIo1->open("param.dummy_proto.root");
rtdb->setFirstInput(parIo1);
FairRootManager* ioman = FairRootManager::Instance();
ATEventManagerProto *eveMan = new ATEventManagerProto();
ATEventDrawTaskProto* eve = new ATEventDrawTaskProto();
eve->Set3DHitStyleBox();
eve->SetProtoMap(protomapdir.Data());
eveMan->AddTask(eve);
eveMan->Init();
}
/********************************************************************************
* 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" *
********************************************************************************/
Int_t sql_params_read()
{
// Create a Runtime Database singleton.
FairRuntimeDb* db = FairRuntimeDb::instance();
// Set the SQL IO as first input
FairParTSQLIo* inp = new FairParTSQLIo();
// Verbosity level
inp->SetVerbosity(1);
inp->open();
db->setFirstInput(inp);
// Create the container via the factory if not already created
FairDbTutPar* p1 = (FairDbTutPar*)(db->getContainer("TUTParDefault"));
FairDbTutPar* p2 = (FairDbTutPar*)(db->getContainer("TUTParAlternative"));
// Create a dummy runID using date in UTC from which
// corresponding parameters will be initialised
ValTimeStamp tStamp(2015,02,20,10,10,10);
UInt_t runId = tStamp.GetSec();
cout << "-I- looking for parameters at runID# " << runId << endl;
cout << "-I- corresponding time in runID (UTC) " << tStamp.Format("iso") << endl;
// Use the generated RunID to initialised the parameter
// using the SQL-based IO input
db->initContainers(runId);
// Get the container after initialisation
// from the RuntimeDB
FairDbTutPar* pp1 = (FairDbTutPar*)(db->getContainer("TUTParDefault"));
FairDbTutPar* pp2 = (FairDbTutPar*)(db->getContainer("TUTParAlternative"));
cout << endl;
cout << "-I- Reading Parameter data from SQL Database: \n" << endl;
cout << endl;
pp1->Print();
pp2->Print();
cout << endl;
if (db) delete db;
return 0;
}
r3bevtvis()
{
// ----- Reconstruction run -------------------------------------------
FairRunAna *fRun= new FairRunAna();
TFile* file = new TFile("r3bpar.root");
file->Get("FairBaseParSet");
// ----- Runtime database ---------------------------------------------
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIn = new FairParRootFileIo();
parIn->open("r3bpar.root");
rtdb->print();
fRun->SetInputFile("r3bsim.root");
fRun->SetOutputFile("test.root");
//fRun->LoadGeometry();
R3BEventManager *fMan= new R3BEventManager();
R3BMCTracks *Track = new R3BMCTracks ("Monte-Carlo Tracks");
fMan->AddTask(Track);
fMan->Init();
}
Int_t califa_test()
{
// Create a Runtime Database singleton.
FairRuntimeDb* db = FairRuntimeDb::instance();
// Create in memory the relevant container
R3BCaloCalPar* par = (R3BCaloCalPar*)(db->getContainer("CaloCalPar"));
// Set the SQL IO as first input
FairParAsciiFileIo* inp = new FairParAsciiFileIo();
TString filename ="ducals.par";
inp->open(filename.Data(),"in");
db->setFirstInput(inp);
// Generate a unique RunID
FairRunIdGenerator runID;
UInt_t runId = runID.generateId();
db->initContainers(runId);
// Get the container after initialisation
// from the RuntimeDB
R3BCaloCalPar* par = (R3BCaloCalPar*)(db->getContainer("CaloCalPar"));
// Dump the Parameters
cout << endl;
cout << "-I- Reading Parameter data from Ascii File: \n" << filename.Data() << endl;
cout << endl;
par->Print();
cout << endl;
// Convert in ROOT format
par->setChanged();
Bool_t kParameterMerged = kTRUE;
FairParRootFileIo* parOut = new FairParRootFileIo(kParameterMerged);
parOut->open("califa_cal_par.root");
db->setOutput(parOut);
db->saveOutput();
db->print();
// ------------------------------------------------------------------------
if (db) delete db;
return 0;
}
eventDisplay()
{
//-----User Settings:-----------------------------------------------
TString InputFile ="test.root";
TString ParFile ="params.root";
TString OutFile ="tst.root";
// ----- Reconstruction run -------------------------------------------
FairRunAna *fRun= new FairRunAna();
fRun->SetInputFile(InputFile.Data());
fRun->SetOutputFile(OutFile.Data());
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parInput1 = new FairParRootFileIo();
parInput1->open(ParFile.Data());
rtdb->setFirstInput(parInput1);
FairEventManager *fMan= new FairEventManager();
//----------------------Traks and points -------------------------------------
FairMCTracks *Track = new FairMCTracks("Monte-Carlo Tracks");
FairMCPointDraw *VxdDetectorPoints = new FairMCPointDraw("FccVxdPoint", kBlue, kFullSquare);
FairMCPointDraw *SitDetectorPoints = new FairMCPointDraw("FccSitPoint", kGreen, kFullSquare);
FairMCPointDraw *TpcDetectorPoints = new FairMCPointDraw("FccTpcPoint", kRed, kFullSquare);
FairMCPointDraw *HcalDetectorPoints = new FairMCPointDraw("FccHcalPoint", kMagenta, kFullSquare);
fMan->AddTask(Track);
fMan->AddTask(VxdDetectorPoints);
fMan->AddTask(SitDetectorPoints);
fMan->AddTask(TpcDetectorPoints);
fMan->AddTask(HcalDetectorPoints);
fMan->Init();
}
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;
// ------------------------------------------------------------------------
}
void run_trac_its(Int_t nEvents = 10, TString mcEngine = "TGeant3"){
// Initialize logger
FairLogger *logger = FairLogger::GetLogger();
logger->SetLogVerbosityLevel("LOW");
logger->SetLogScreenLevel("INFO");
// Input and output file name
std::stringstream inputfile, outputfile, paramfile;
inputfile << "AliceO2_" << mcEngine << ".clus_" << nEvents << "_event.root";
paramfile << "AliceO2_" << mcEngine << ".params_" << nEvents << ".root";
outputfile << "AliceO2_" << mcEngine << ".trac_" << nEvents << "_event.root";
// Setup timer
TStopwatch timer;
// Setup FairRoot analysis manager
FairRunAna * fRun = new FairRunAna();
FairFileSource *fFileSource = new FairFileSource(inputfile.str().c_str());
fRun->SetSource(fFileSource);
fRun->SetOutputFile(outputfile.str().c_str());
// Setup Runtime DB
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parInput1 = new FairParRootFileIo();
parInput1->open(paramfile.str().c_str());
rtdb->setFirstInput(parInput1);
// Setup tracker
// To run with n threads call AliceO2::ITS::CookedTrackerTask(n)
AliceO2::ITS::CookedTrackerTask *trac = new AliceO2::ITS::CookedTrackerTask;
fRun->AddTask(trac);
fRun->Init();
AliceO2::Field::MagneticField* fld = (AliceO2::Field::MagneticField*)fRun->GetField();
if (!fld) {
std::cout << "Failed to get field instance from FairRunAna" << std::endl;
return;
}
trac->setBz(fld->solenoidField()); //in kG
timer.Start();
fRun->Run();
std::cout << std::endl << std::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();
std::cout << "<DartMeasurement name=\"MaxMemory\" type=\"numeric/double\">";
std::cout << maxMemory;
std::cout << "</DartMeasurement>" << std::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 << "Macro finished succesfully." << endl;
std::cout << endl << std::endl;
std::cout << "Output file is " << outputfile.str() << std::endl;
//std::cout << "Parameter file is " << parFile << std::endl;
std::cout << "Real time " << rtime << " s, CPU time " << ctime
<< "s" << endl << endl;
}
void sts_reco( Int_t nEvents = 1, Int_t iVerbose = 0){
TString inFile = "data/mc_sector.root";
TString outFile = "data/sts_sector.root";
TString parFile = "data/params.root";
TString stsFile = "sts_v11a.digi.par";
gROOT->LoadMacro("$VMCWORKDIR/gconfig/basiclibs.C");
basiclibs();
gROOT->LoadMacro("$VMCWORKDIR/macro/much/muchlibs.C");
muchlibs();
FairRunAna *fRun= new FairRunAna();
fRun->SetInputFile(inFile);
fRun->SetOutputFile(outFile);
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parInput1 = new FairParRootFileIo();
FairParAsciiFileIo* parInput2 = new FairParAsciiFileIo();
parInput1->open(parFile.Data());
parInput2->open(Form("%s/parameters/sts/%s",gSystem->Getenv("VMCWORKDIR"),stsFile.Data()),"in");
rtdb->setFirstInput(parInput1);
rtdb->setSecondInput(parInput2);
Double_t threshold = 4;
Double_t noiseWidth = 0.01;
Int_t nofBits = 20;
Double_t minStep = 0.01;
Double_t StripDeadTime = 0.1;
CbmStsDigitize* stsDigitize = new CbmStsDigitize("STS Digitiser", iVerbose);
stsDigitize->SetRealisticResponse();
stsDigitize->SetFrontThreshold (threshold);
stsDigitize->SetBackThreshold (threshold);
stsDigitize->SetFrontNoiseWidth(noiseWidth);
stsDigitize->SetBackNoiseWidth (noiseWidth);
stsDigitize->SetFrontNofBits (nofBits);
stsDigitize->SetBackNofBits (nofBits);
stsDigitize->SetFrontMinStep (minStep);
stsDigitize->SetBackMinStep (minStep);
stsDigitize->SetStripDeadTime (StripDeadTime);
fRun->AddTask(stsDigitize);
FairTask* stsClusterFinder = new CbmStsClusterFinder("STS Cluster Finder",iVerbose);
fRun->AddTask(stsClusterFinder);
FairTask* stsFindHits = new CbmStsFindHits("STS Hit Finder", iVerbose);
fRun->AddTask(stsFindHits);
FairTask* stsMatchHits = new CbmStsMatchHits("STS Hit Matcher", iVerbose);
fRun->AddTask(stsMatchHits);
// --- STS track finding ------------------------------------------------
CbmKF* kalman = new CbmKF();
fRun->AddTask(kalman);
CbmL1* l1 = new CbmL1();
fRun->AddTask(l1);
CbmStsTrackFinder* stsTrackFinder = new CbmL1StsTrackFinder();
FairTask* stsFindTracks = new CbmStsFindTracks(iVerbose, stsTrackFinder);
fRun->AddTask(stsFindTracks);
CbmStsMatchTracks* stsMatchTracks = new CbmStsMatchTracks(iVerbose);
fRun->AddTask(stsMatchTracks);
CbmStsTrackFitter* stsTrackFitter = new CbmStsKFTrackFitter();
FairTask* stsFitTracks = new CbmStsFitTracks(stsTrackFitter, iVerbose);
fRun->AddTask(stsFitTracks);
CbmPrimaryVertexFinder* pvFinder = new CbmPVFinderKF();
CbmFindPrimaryVertex* pvFindTask = new CbmFindPrimaryVertex(pvFinder);
fRun->AddTask(pvFindTask);
fRun->Init();
fRun->Run(0,nEvents);
}
void califaAna_batch(Int_t nEvents=1, Int_t fGeoVer=1, Double_t fThres=0.000050,
Double_t fExpRes=5., Double_t fDelPolar=3.2, Double_t fDelAzimuthal=3.2) {
cout << "Running califaAna_batch with arguments:" <<endl;
cout << "Number of events: " << nEvents <<endl;
cout << "CALIFA geo version: " << fGeoVer <<endl;
cout << "Threshold: " << fThres <<endl<<endl;
cout << "Experimental resolution: " << fExpRes <<endl<<endl;
// In general, the following parts need not be touched
// ========================================================================
// ---- Debug option -------------------------------------------------
gDebug = 0;
// ------------------------------------------------------------------------
// ----- Timer --------------------------------------------------------
TStopwatch timer;
timer.Start();
// ------------------------------------------------------------------------
// ----- Create analysis run ----------------------------------------
FairRunAna* fRun = new FairRunAna();
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
parIo1->open("r3bpar.root");
rtdb->setFirstInput(parIo1);
rtdb->print();
fRun->SetInputFile("r3bsim.root");
fRun->SetOutputFile("califaAna.root");
// ----- Analysis routines for CALIFA
R3BCaloHitFinder* caloHF = new R3BCaloHitFinder();
//Selecting the geometry version
// 0- CALIFA 5.0, including BARREL and ENDCAP.
// 1- CALIFA 7.05, only BARREL
// 2- CALIFA 7.07, only BARREL
// 3- CALIFA 7.09, only BARREL (ongoing work)
// 4- CALIFA 7.17, only ENDCAP (in CsI[Tl])
// 5- CALIFA 7.07+7.17,
// 6- CALIFA 7.09+7.17, (ongoing work)
// 10- CALIFA 8.11, only BARREL (ongoing work)
// ...
caloHF->SelectGeometryVersion(fGeoVer);
//caloHF->SelectGeometryVersion(10);
caloHF->SetDetectionThreshold(fThres); //50 KeV [fThres in GeV]
caloHF->SetExperimentalResolution(fExpRes); //5% at 1 MeV
caloHF->SetAngularWindow(fDelPolar,fDelAzimuthal); //[0.25 around 14.3 degrees, 3.2 for the complete calorimeter]
fRun->AddTask(caloHF);
fRun->Init();
fRun->Run(0, nEvents);
// ----- Finish -------------------------------------------------------
timer.Stop();
Double_t rtime = timer.RealTime();
Double_t ctime = timer.CpuTime();
cout << endl << endl;
cout << "Macro finished succesfully." << endl;
cout << "Real time " << rtime << " s, CPU time " << ctime << " s" << endl;
cout << endl;
// ------------------------------------------------------------------------
}
void run_sim()
{
TString transport = "TGeant4";
Bool_t userPList = kFALSE; // option for TGeant4
TString outFile = "sim.root";
TString parFile = "par.root";
Bool_t magnet = kTRUE;
Float_t fieldScale = -0.68;
TString generator1 = "box";
TString generator2 = "ascii";
TString generator3 = "r3b";
TString generator = generator1;
TString inputFile = "";
Int_t nEvents = 1;
Bool_t storeTrajectories = kTRUE;
Int_t randomSeed = 335566; // 0 for time-dependent random numbers
// Target type
TString target1 = "LeadTarget";
TString target2 = "Para";
TString target3 = "Para45";
TString target4 = "LiH";
TString targetType = target4;
// ------------------------------------------------------------------------
// Stable part ------------------------------------------------------------
TString dir = getenv("VMCWORKDIR");
// ---- Debug option -------------------------------------------------
gDebug = 0;
// ----- Timer --------------------------------------------------------
TStopwatch timer;
timer.Start();
// ----- Create simulation run ----------------------------------------
FairRunSim* run = new FairRunSim();
run->SetName(transport); // Transport engine
run->SetOutputFile(outFile.Data()); // Output file
FairRuntimeDb* rtdb = run->GetRuntimeDb();
// R3B Special Physics List in G4 case
if ((userPList == kTRUE) && (transport.CompareTo("TGeant4") == 0))
{
run->SetUserConfig("g4R3bConfig.C");
run->SetUserCuts("SetCuts.C");
}
// ----- Create media -------------------------------------------------
run->SetMaterials("media_r3b.geo"); // Materials
// ----- Create R3B geometry --------------------------------------------
// R3B Cave definition
FairModule* cave = new R3BCave("CAVE");
cave->SetGeometryFileName("r3b_cave.geo");
run->AddModule(cave);
// To skip the detector comment out the line with: run->AddModule(...
// Target
run->AddModule(new R3BTarget(targetType, "target_" + targetType + ".geo.root"));
// GLAD
//run->AddModule(new R3BGladMagnet("glad_v17_flange.geo.root")); // GLAD should not be moved or rotated
// PSP
run->AddModule(new R3BPsp("psp_v13a.geo.root", {}, -221., -89., 94.1));
// R3B SiTracker Cooling definition
//run->AddModule(new R3BVacVesselCool(targetType, "vacvessel_v14a.geo.root"));
// STaRTrack
//run->AddModule(new R3BSTaRTra("startra_v16-300_2layers.geo.root", { 0., 0., 20. }));
// CALIFA
R3BCalifa* califa = new R3BCalifa("califa_10_v8.11.geo.root");
califa->SelectGeometryVersion(10);
// Selecting the Non-uniformity of the crystals (1 means +-1% max deviation)
califa->SetNonUniformity(1.0);
//run->AddModule(califa);
// Tof
//run->AddModule(new R3BTof("tof_v17a.geo.root", { -417.359574, 2.400000, 960.777114 }, { "", -90., +31., 90. }));
// mTof
run->AddModule(new R3BmTof("mtof_v17a.geo.root", { -155.824045, 0.523976, 761.870346 }, { "", -90., +16.7, 90. }));
// MFI
//run->AddModule(new R3BMfi("mfi_v17a.geo.root", { -63.82, 0., 520.25 }, { "", 90., +13.5, 90. })); // s412
// NeuLAND
// run->AddModule(new R3BNeuland("neuland_test.geo.root", { 0., 0., 1400. + 12 * 5. }));
// ----- Create R3B magnetic field ----------------------------------------
// NB: <D.B>
// If the Global Position of the Magnet is changed
// the Field Map has to be transformed accordingly
R3BGladFieldMap* magField = new R3BGladFieldMap("R3BGladMap");
magField->SetScale(fieldScale);
if (magnet == kTRUE)
{
run->SetField(magField);
}
else
{
run->SetField(NULL);
}
// ----- Create PrimaryGenerator --------------------------------------
// 1 - Create the Main API class for the Generator
FairPrimaryGenerator* primGen = new FairPrimaryGenerator();
if (generator.CompareTo("box") == 0)
{
FairIonGenerator* boxGen = new FairIonGenerator(50, 128, 50, 1, 0., 0., 1.3, 0., 0., 0.);
primGen->AddGenerator(boxGen);
}
if (generator.CompareTo("ascii") == 0)
{
R3BAsciiGenerator* gen = new R3BAsciiGenerator((dir + "/input/" + inputFile).Data());
primGen->AddGenerator(gen);
}
run->SetGenerator(primGen);
run->SetStoreTraj(storeTrajectories);
FairLogger::GetLogger()->SetLogVerbosityLevel("LOW");
FairLogger::GetLogger()->SetLogScreenLevel("INFO");
// ----- Initialize simulation run ------------------------------------
run->Init();
TVirtualMC::GetMC()->SetRandom(new TRandom3(randomSeed));
// ------ Increase nb of step for CALO
Int_t nSteps = -15000;
TVirtualMC::GetMC()->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;
// Snap a picture of the geometry
// If this crashes, set "OpenGL.SavePicturesViaFBO: no" in your .rootrc
/*gStyle->SetCanvasPreferGL(kTRUE);
gGeoManager->GetTopVolume()->Draw("ogl");
TGLViewer* v = (TGLViewer*)gPad->GetViewer3D();
v->SetStyle(TGLRnrCtx::kOutline);
v->RequestDraw();
v->SavePicture("run_sim-side.png");
v->SetPerspectiveCamera(TGLViewer::kCameraPerspXOZ, 25., 0, 0, -90. * TMath::DegToRad(), 0. * TMath::DegToRad());
v->SavePicture("run_sim-top.png");*/
}
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;
// ------------------------------------------------------------------------
}
void r3blandreco(Int_t nNeutrons, Int_t beamE, Int_t Erel)
{
Int_t d;
if(Erel == 100){
d = 35;
}
else{
d = 14;
}
// ----- Files ---------------------------------------------------------------
char strDir[] = ".";
char str[100];
char str2[100];
sprintf(str, "%1dAMeV.%1dn.%1dkeV.%1dm.root", beamE,nNeutrons, Erel, d);
sprintf(str2, "%1dAMeV.%1dkeV.%1dm", beamE, Erel, d);
TString inFile = TString(strDir) + "/r3bsim." + TString(str);
TString digiFile = TString(strDir) + "/r3bcalibr." + TString(str);
TString parFile = TString(strDir) + "/r3bpar." + TString(str);
TString calibrFile = TString(strDir) + "/r3bcalibr." + TString(str2) + ".txt";
TString outFile = TString(strDir) + "/r3breco." + TString(str);
// ---------------------------------------------------------------------------
// ----- Timer ---------------------------------------------------------------
TStopwatch timer;
timer.Start();
// ---------------------------------------------------------------------------
// ----- Digitization --------------------------------------------------------
FairRunAna *fRun= new FairRunAna();
fRun->SetInputFile(inFile);
fRun->AddFriend(digiFile);
fRun->SetOutputFile(outFile);
// ---------------------------------------------------------------------------
// ---------------------------------------------------------------------------
Double_t beamEnergy;
Double_t beamBeta;
if(200 == beamE) {
beamEnergy=200.;
beamBeta=0.5676881;
} else if(600 == beamE) {
beamEnergy=600.;
beamBeta=0.7937626;
} else if(1000 == beamE) {
beamEnergy=1000.;
beamBeta=0.8760237;
}
// ---------------------------------------------------------------------------
// ----- Connect the Tracking Task -------------------------------------------
R3BNeutronTracker2D* tracker = new R3BNeutronTracker2D();
tracker->UseBeam(beamEnergy, beamBeta);
tracker->ReadCalibrFile(calibrFile.Data());
fRun->AddTask(tracker);
// ---------------------------------------------------------------------------
// ----- Runtime DataBase info -----------------------------------------------
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
parIo1->open(parFile.Data());
rtdb->setFirstInput(parIo1);
rtdb->setOutput(parIo1);
rtdb->saveOutput();
// ---------------------------------------------------------------------------
// ----- Number of events to process -----------------------------------------
Int_t nEvents = 10000;
// ---------------------------------------------------------------------------
// ----- Intialise and run ---------------------------------------------------
fRun->Init();
fRun->Run(0, 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 writen: " << outFile << endl;
cout << "Parameter file writen " << parFile << endl;
cout << "Real time " << rtime << " s, CPU time " << ctime << " s" << endl;
cout << endl;
// ---------------------------------------------------------------------------
}
void tut_ana_mclist(int nevts=0)
{
// *** some variables
int i=0,j=0, k=0, l=0;
TString OutFile="output.root";
// *** the files coming from the simulation
TString inPidFile = "pid_complete.root"; // this file contains the PndPidCandidates and McTruth
TString inParFile = "simparams.root";
gStyle->SetOptFit(1011);
// *** PID table with selection thresholds; can be modified by the user
TString pidParFile = TString(gSystem->Getenv("VMCWORKDIR"))+"/macro/params/all.par";
// *** initialization
FairLogger::GetLogger()->SetLogToFile(kFALSE);
FairRunAna* fRun = new FairRunAna();
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
fRun->SetInputFile(inPidFile);
// *** setup parameter database
FairParRootFileIo* parIO = new FairParRootFileIo();
parIO->open(inParFile);
FairParAsciiFileIo* parIOPid = new FairParAsciiFileIo();
parIOPid->open(pidParFile.Data(),"in");
rtdb->setFirstInput(parIO);
rtdb->setSecondInput(parIOPid);
rtdb->setOutput(parIO);
fRun->SetOutputFile(OutFile);
fRun->Init();
//
// Now the analysis stuff comes...
//
// *** the data reader object
PndAnalysis* theAnalysis = new PndAnalysis();
if (nevts==0) nevts= theAnalysis->GetEntries();
// *** RhoCandLists for the analysis
RhoCandList mctruth;
// ***
// the event loop
// ***
while (theAnalysis->GetEvent() && i++<nevts)
{
cout<<"****** Evt " << i << endl;
// *** the MC Truth objects
theAnalysis->FillList(mctruth,"McTruth");
//
// Print MC Truth list with mother-daughter relations
//
for (j=0;j<mctruth.GetLength();++j)
{
RhoCandidate *mcmother = mctruth[j]->TheMother();
int muid = -1;
if (mcmother) muid = mcmother->GetTrackNumber();
cout << "Track "<< mctruth[j]->GetTrackNumber()<<" (PDG:"<<mctruth[j]->PdgCode() <<") has mother "<<muid;
if (mctruth[j]->NDaughters()>0) cout <<" and daughter(s) ";
for (k=0;k<mctruth[j]->NDaughters();++k) cout <<mctruth[j]->Daughter(k)->GetTrackNumber()<<" ";
cout<<endl;
}
cout <<endl;
}
}
// Macro created 20/09/2006 by S.Spataro
// It creates a geant simulation file for emc
run_sim_tpc_dpm(Int_t nEvents=10, Float_t mom = 3.6772, Int_t mode =1, UInt_t seed=0){
gRandom->SetSeed(seed);
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");
rootlogon();
TString digiFile = "all.par";
TString parFile = "dpm_params_tpc.root";
TString mcMode = "TGeant3";
FairRunSim *fRun = new FairRunSim();
// set the MC version used
// ------------------------
fRun->SetName(mcMode);
fRun->SetOutputFile("dpm_points_tpc.root");
// Set the parameters
//-------------------------------
TString allDigiFile = gSystem->Getenv("VMCWORKDIR");
allDigiFile += "/macro/params/";
allDigiFile += digiFile;
FairRuntimeDb* rtdb = fRun->GetRuntimeDb();
FairParAsciiFileIo* parIo1 = new FairParAsciiFileIo();
parIo1->open(allDigiFile.Data(),"in");
rtdb->setFirstInput(parIo1);
Bool_t kParameterMerged=kTRUE;
FairParRootFileIo* output=new FairParRootFileIo(kParameterMerged);
output->open(parFile);
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);
FairModule *Magnet= new PndMagnet("MAGNET");
//Magnet->SetGeometryFileName("FullSolenoid_V842.root");
Magnet->SetGeometryFileName("FullSuperconductingSolenoid_v831.root");
fRun->AddModule(Magnet);
FairModule *Pipe= new PndPipe("PIPE");
fRun->AddModule(Pipe);
PndTpcDetector *Tpc = new PndTpcDetector("TPC", kTRUE);
Tpc->SetGeometryFileName("TPC_V1.1.root"); //new ROOT geometry
if(mcMode=="TGeant3") Tpc->SetAliMC();
fRun->AddModule(Tpc);
FairDetector *Mvd = new PndMvdDetector("MVD", kTRUE);
Mvd->SetGeometryFileName("Mvd-2.1_FullVersion.root");
fRun->AddModule(Mvd);
PndEmc *Emc = new PndEmc("EMC",kFALSE);
Emc->SetGeometryVersion(19);
Emc->SetStorageOfData(kFALSE);
fRun->AddModule(Emc);
//PndMdt *Muo = new PndMdt("MDT",kTRUE);
//Muo->SetMdtMagnet(kTRUE);
// Muo->SetMdtMFIron(kFALSE);
//Muo->SetMdtCoil(kTRUE);
//Muo->SetBarrel("muon_TS_barrel_strip_v1_noGeo.root");
//Muo->SetEndcap("muon_TS_endcap_strip_v1_noGeo.root");
//Muo->SetForward("muon_Forward_strip_v1_noGeo.root");
//Muo->SetMuonFilter("muon_MuonFilter_strip_v1_noGeo.root");
//fRun->AddModule(Muo);
FairDetector *Gem = new PndGemDetector("GEM", kTRUE);
Gem->SetGeometryFileName("gem_3Stations.root");
fRun->AddModule(Gem);
PndDsk* Dsk = new PndDsk("DSK", kFALSE);
Dsk->SetGeometryFileName("dsk.root");
Dsk->SetStoreCerenkovs(kFALSE);
Dsk->SetStoreTrackPoints(kFALSE);
fRun->AddModule(Dsk);
PndDrc *Drc = new PndDrc("DIRC", kFALSE);
Drc->SetGeometryFileName("dirc_l0_p0.root");
Drc->SetRunCherenkov(kFALSE); // for fast sim Cherenkov -> kFALSE
fRun->AddModule(Drc);
// Create and Set Event Generator
//-------------------------------
FairPrimaryGenerator* primGen = new FairPrimaryGenerator();
primGen->SetTarget(0., 0.5/2.355);
primGen->SmearVertexZ(kTRUE);
primGen->SmearGausVertexZ(kTRUE);
primGen->SetBeam(0., 0., 0.1, 0.1);
primGen->SmearVertexXY(kTRUE);
fRun->SetGenerator(primGen);
PndDpmDirect *dpmGen = new PndDpmDirect(mom,mode, gRandom->GetSeed());
primGen->AddGenerator(dpmGen);
// Create and Set Magnetic Field
//-------------------------------
fRun->SetBeamMom(mom);
PndMultiField *fField= new PndMultiField("FULL");
fRun->SetField(fField);
/**Initialize the session*/
fRun->Init();
rtdb->setOutput(output);
rtdb->saveOutput();
rtdb->print();
// Transport nEvents
// -----------------
fRun->Run(nEvents);
timer.Stop();
Double_t rtime = timer.RealTime();
Double_t ctime = timer.CpuTime();
printf("RealTime=%f seconds, CpuTime=%f seconds\n",rtime,ctime);
}
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 analysis_pbarp_Xi_test(int nevts=0){
TDatabasePDG::Instance()-> AddParticle("pbarpSystem","pbarpSystem", 1.9, kFALSE, 0.1, 0,"", 88888);
TStopwatch timer;
//Output File
TString Path = "/private/puetz/mysimulations/analysis/pbarp_Xiplus_Ximinus/idealtracking/10000_events/";
TString outPath = Path;
TString OutputFile = outPath + "analysis_output_test.root";
//Input simulation Files
TString inPIDFile = Path + "pid_complete.root";
TString inParFile = Path + "simparams.root";
TString PIDParFile = TString( gSystem->Getenv("VMCWORKDIR")) + "/macro/params/all.par";
//Initialization
FairLogger::GetLogger()->SetLogToFile(kFALSE);
FairRunAna* RunAna = new FairRunAna();
FairRuntimeDb* rtdb = RunAna->GetRuntimeDb();
RunAna->SetInputFile(inPIDFile);
//setup parameter database
FairParRootFileIo* parIo = new FairParRootFileIo();
parIo->open(inParFile);
FairParAsciiFileIo* parIoPID = new FairParAsciiFileIo();
parIoPID->open(PIDParFile.Data(),"in");
rtdb->setFirstInput(parIo);
rtdb->setSecondInput(parIoPID);
rtdb->setOutput(parIo);
RunAna->SetOutputFile(OutputFile);
RunAna->Init();
//*** create tuples
RhoTuple * ntpMC = new RhoTuple("ntpMC", "MCTruth info");
RhoTuple * ntpPiMinus = new RhoTuple("ntpPiMinus", "PiMinus info");
RhoTuple * ntpPiPlus = new RhoTuple("ntpPiPlus", "PiPlus info");
RhoTuple * ntpProton = new RhoTuple("ntpProton", "Proton info");
RhoTuple * ntpAntiProton = new RhoTuple("ntpAntiProton", "Antiproton info");
RhoTuple * ntpLambda0 = new RhoTuple("ntpLambda0", "Lambda0 info");
RhoTuple * ntpAntiLambda0 = new RhoTuple("ntpAntiLambda0", "AntiLambda0 info");
RhoTuple * ntpXiMinus = new RhoTuple("ntpXiMinus", "XiMinus info");
RhoTuple * ntpXiPlus = new RhoTuple("ntpXiPlus", "XiPlus info");
RhoTuple * ntpXiSys = new RhoTuple("ntpXiSys", "XiMinus XiPlus system info");
//Create output file
TFile *out = TFile::Open(outPath+"output_ana_test.root","RECREATE");
// data reader Object
PndAnalysis* theAnalysis = new PndAnalysis();
if (nevts==0) nevts = theAnalysis->GetEntries();
//RhoCandLists for analysis
RhoCandList piplus, piminus, lambda0, antiLambda0, proton, antiProton, xiplus, ximinus, xiSys;
RhoCandList NotCombinedPiMinus, CombinedPiMinus, CombinedPiPlus, NotCombinedPiPlus;
RhoCandList SelectedProton, SelectedAntiProton, SelectedPiMinus, SelectedPiPlus;
RhoCandList Lambda0Fit, AntiLambda0Fit, XiMinusFit, XiPlusFit;
RhoCandList mclist, all;
//Dummy RhoCandidate
RhoCandidate * dummyCand = new RhoCandidate();
//***Mass selector
double m0_lambda0= TDatabasePDG::Instance()->GetParticle("Lambda0")->Mass();
cout<<"Mass of Lambda0: "<<m0_lambda0<<endl;
RhoMassParticleSelector * lambdaMassSelector = new RhoMassParticleSelector("lambda0", m0_lambda0, 0.3);
double m0_Xi = TDatabasePDG::Instance()->GetParticle("Xi-")->Mass();
cout<<"Mass of Xi-: "<<m0_Xi<<endl;
RhoMassParticleSelector * xiMassSelector = new RhoMassParticleSelector("Xi-", m0_Xi, 0.3);
double m0_pbarpsystem = TDatabasePDG::Instance()->GetParticle("pbarpSystem")->Mass();
double pbarmom = 2.7;
double p_m0 = TDatabasePDG::Instance()->GetParticle("proton")->Mass();
TLorentzVector ini (0,0, pbarmom, sqrt(p_m0*p_m0+ pbarmom*pbarmom)+p_m0);
TVector3 beamBoost = ini.BoostVector();
PndRhoTupleQA qa(theAnalysis, pbarmom);
int evt=-1;
int index=0;
while (theAnalysis->GetEvent() && ++evt<nevts){
if ((evt%100)==0) cout << "evt "<< evt <<endl;
cout << "Running event " << evt << endl;
//***get MC list and store info
theAnalysis->FillList(mclist, "McTruth");
qa.qaMcList("", mclist, ntpMC);
ntpMC->DumpData();
//if you want to print the hole MCTree uncomment the following
/*
for (int j=0;j<mclist.GetLength();++j)
{
RhoCandidate *mcmother = mclist[j]->TheMother(); // mother of mc particle
int muid = (mcmother==0x0) ? -1 : mcmother->GetTrackNumber(); // track ID of mother, if existing
cout << "Track "<< mclist[j]->GetTrackNumber()<<" (PDG:"<<mclist[j]->PdgCode() <<") has mother "<<muid;
if (mclist[j]->NDaughters()>0) cout <<" and daughter(s) ";
for (k=0;k<mclist[j]->NDaughters();++k) cout <<mclist[j]->Daughter(k)->GetTrackNumber()<<" ";
cout<<endl;
}*/
//***Setup event shape object
TString PidSelection = "PidAlgoIdealCharged";//"PidAlgoMvd;PidAlgoStt;PidAlgoDrc";
theAnalysis->FillList(all, "All", PidSelection);
PndEventShape evsh(all, ini, 0.05, 0.1);
//***Selection with no PID info
theAnalysis->FillList(piminus, "PionAllMinus", PidSelection);
// theAnalysis->FillList(NotCombinedPiMinus, "PionAllMinus", PidSelection);
// theAnalysis->FillList(NotCombinedPiPlus, "PionAllPlus", PidSelection);
theAnalysis->FillList(piplus, "PionAllPlus", PidSelection);
theAnalysis->FillList(proton, "ProtonAllPlus", PidSelection);
theAnalysis->FillList(antiProton, "ProtonAllMinus", PidSelection);
for (int pip=0; pip<piplus.GetLength(); ++pip){
ntpPiPlus->Column("ev", (Float_t) evt);
ntpPiPlus->Column("cand", (Float_t) pip);
ntpPiPlus->Column("ncand", (Float_t) piplus.GetLength());
ntpPiPlus->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(piplus[pip]));
qa.qaP4("PiPlus_", piplus[pip]->P4(), ntpPiPlus);
qa.qaCand("PiPlus_", piplus[pip], ntpPiPlus);
jenny::numberOfHitsInSubdetector("PiPlus_", piplus[pip], ntpPiPlus);
jenny::tagNHits("PiPlus_", piplus[pip], ntpPiPlus);
int tag = jenny::tagHits(piplus[pip]);
RhoCandidate * mother_pip = piplus[pip]->GetMcTruth()->TheMother();
int moth_pip = (0x0==mother_pip)? 88888 : mother_pip->PdgCode();
ntpPiPlus->Column("Mother", (Float_t) moth_pip);
ntpPiPlus->Column("PiPlus_CosTheta", (Float_t) piplus[pip]->GetMomentum().CosTheta());
qa.qaP4("PiPlus_MC_", piplus[pip]->GetMcTruth()->P4(), ntpPiPlus);
qa.qaCand("PiPlus_MC_", piplus[pip]->GetMcTruth(), ntpPiPlus);
ntpPiPlus->Column("PiPlus_MC_CosTheta", (Float_t) piplus[pip]->GetMcTruth()->GetMomentum().CosTheta());
if(tag==1){
SelectedPiPlus.Append(piplus[pip]);
NotCombinedPiPlus.Append(piplus[pip]);
}
ntpPiPlus->DumpData();
}
for (int pim=0; pim<piminus.GetLength(); ++pim){
ntpPiMinus->Column("ev", (Float_t) evt);
ntpPiMinus->Column("cand", (Float_t) pim);
ntpPiMinus->Column("ncand", (Float_t) piminus.GetLength());
ntpPiMinus->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(piminus[pim]));
qa.qaP4("piminus_", piminus[pim]->P4(), ntpPiMinus);
qa.qaCand("piminus_", piminus[pim], ntpPiMinus);
jenny::numberOfHitsInSubdetector("piminus_", piminus[pim], ntpPiMinus);
jenny::tagNHits("piminus_", piminus[pim], ntpPiMinus);
int tag = jenny::tagHits(piminus[pim]);
RhoCandidate * mother_pim = piminus[pim]->GetMcTruth()->TheMother();
int moth_pim = (0x0==mother_pim)? 88888 : mother_pim->PdgCode();
ntpPiMinus->Column("Mother", (Float_t) moth_pim);
ntpPiMinus->Column("PiMinus_CosTheta", (Float_t) piminus[pim]->GetMomentum().CosTheta());
qa.qaP4("piminus_MC_", piminus[pim]->GetMcTruth()->P4(), ntpPiMinus);
qa.qaCand("piminus_MC_", piminus[pim]->GetMcTruth(), ntpPiMinus);
ntpPiMinus->Column("piminus_MC_CosTheta", (Float_t) piminus[pim]->GetMcTruth()->GetMomentum().CosTheta());
ntpPiMinus->DumpData();
if(tag==1){
SelectedPiMinus.Append(piminus[pim]);
NotCombinedPiMinus.Append(piminus[pim]);
}
}
for (int prot=0; prot<proton.GetLength(); ++prot){
ntpProton->Column("ev", (Float_t) evt);
ntpProton->Column("cand", (Float_t) prot);
ntpProton->Column("ncand", (Float_t) proton.GetLength());
ntpProton->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(proton[prot]));
qa.qaP4("proton_", proton[prot]->P4(), ntpProton);
qa.qaCand("proton_", proton[prot], ntpProton);
jenny::numberOfHitsInSubdetector("proton_", proton[prot], ntpProton);
// jenny::tagNHits("proton_", proton[prot], ntpProton);
int tag = jenny::tagHits(proton[prot]);
RhoCandidate * mother_prot = proton[prot]->GetMcTruth()->TheMother();
int moth_prot = (0x0==mother_prot)? 88888 : mother_prot->PdgCode();
ntpProton->Column("Mother", (Float_t) moth_prot);
ntpProton->Column("proton_CosTheta", (Float_t) proton[prot]->GetMomentum().CosTheta());
qa.qaP4("proton_MC_", proton[prot]->GetMcTruth()->P4(), ntpProton);
qa.qaCand("proton_", proton[prot]->GetMcTruth(), ntpProton);
ntpProton->Column("proton_MC_CosTheta", (Float_t) proton[prot]->GetMcTruth()->GetMomentum().CosTheta());
ntpProton->DumpData();
if(tag==1) SelectedProton.Append(proton[prot]);
}
for (int aProt=0; aProt<antiProton.GetLength(); ++aProt){
ntpAntiProton->Column("ev", (Float_t) evt);
ntpAntiProton->Column("cand", (Float_t) aProt);
ntpAntiProton->Column("ncand", (Float_t) antiProton.GetLength());
ntpAntiProton->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(antiProton[aProt]));
qa.qaP4("antiProton_", antiProton[aProt]->P4(), ntpAntiProton);
qa.qaCand("antiProton_", antiProton[aProt], ntpAntiProton);
jenny::numberOfHitsInSubdetector("antiProton_", antiProton[aProt], ntpAntiProton);
// jenny::tagNHits("antiProton_", antiProton[aProt], ntpAntiProton);
int tag = jenny::tagHits(antiProton[aProt]);
RhoCandidate * mother_aProt = antiProton[aProt]->GetMcTruth()->TheMother();
int moth_aProt = (0x0==mother_aProt)? 88888 : mother_aProt->PdgCode();
ntpAntiProton->Column("Mother", (Float_t) moth_aProt);
ntpAntiProton->Column("antiProton_CosTheta", (Float_t) antiProton[aProt]->GetMomentum().CosTheta());
qa.qaP4("antiProton_MC_", antiProton[aProt]->GetMcTruth()->P4(), ntpAntiProton);
qa.qaCand("antiProton_", antiProton[aProt]->GetMcTruth(), ntpAntiProton);
ntpAntiProton->Column("antiProton_MC_CosTheta", (Float_t) antiProton[aProt]->GetMcTruth()->GetMomentum().CosTheta());
ntpAntiProton->DumpData();
if(tag==1) SelectedAntiProton.Append(antiProton[aProt]);
}
//***Lambda0 -> PiMinus + Proton
lambda0.Combine(SelectedPiMinus,SelectedProton);
lambda0.Select(lambdaMassSelector);
lambda0.SetType(kl0);
std::map<int,int> bestVtxFitLambda0, bestMassFitLambda0;
bestVtxFitLambda0 = jenny::VertexQaIndex(&lambda0);
bestMassFitLambda0 = jenny::MassFitQaIndex(&lambda0, m0_lambda0);
for (int j=0; j<lambda0.GetLength(); ++j){
//general info about event
ntpLambda0->Column("ev", (Float_t) evt);
ntpLambda0->Column("cand", (Float_t) j);
ntpLambda0->Column("ncand", (Float_t) lambda0.GetLength());
ntpLambda0->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(lambda0[j]));
ntpLambda0->Column("Lambda0_Pdg", (Float_t) lambda0[j]->PdgCode());
RhoCandidate * mother = lambda0[j]->TheMother();
int moth = (mother==0x0) ? 88888 : mother->PdgCode();
ntpLambda0->Column("Mother", (Float_t) moth);
qa.qaP4("Lambda0_", lambda0[j]->P4(), ntpLambda0);
qa.qaComp("Lambda0_", lambda0[j], ntpLambda0);
// do vertex fit
PndKinVtxFitter vertexfitterLambda0 (lambda0[j]);
vertexfitterLambda0.Fit();
RhoCandidate * lambda0Fit = lambda0[j]->GetFit();
// store info of vertex fit
qa.qaFitter("VtxFit_", &vertexfitterLambda0, ntpLambda0);
ntpLambda0->Column("VtxFit_HowGood", (Int_t) bestVtxFitLambda0[j]);
qa.qaVtx("VtxFit_", lambda0Fit, ntpLambda0);
// differenz to MCTruth
qa.qaMcDiff("fvtxMcDiff_", lambda0Fit, ntpLambda0);
// do mass fit
PndKinFitter massFitterLambda0(lambda0Fit);
massFitterLambda0.AddMassConstraint(m0_lambda0);
massFitterLambda0.Fit();
RhoCandidate * lambda0Fit_mass = lambda0Fit->GetFit();
qa.qaFitter("MassFit_", &massFitterLambda0, ntpLambda0);
ntpLambda0->Column("MassFit_HowGood", (Int_t) bestMassFitLambda0[j]);
RhoCandidate * truth = lambda0[j]->GetMcTruth();
RhoCandidate * truthDaughter = lambda0[j]->Daughter(0)->GetMcTruth();
TLorentzVector l;
TVector3 dl;
if(0x0 != truth){
l = truth->P4();
qa.qaVtx("McTruth_", truth, ntpLambda0);
dl = truth->Daughter(0)->Pos();
}
else{
qa.qaVtx("McTruth_", dummyCand, ntpLambda0);
}
jenny::qaP3("McTruth_", dl, ntpLambda0);
qa.qaP4("McTruth_", l, ntpLambda0);
//*** use for Xi only bestChi2Cand
if (bestVtxFitLambda0[j]==1 && bestMassFitLambda0[j]>0){
Lambda0Fit.Append(lambda0Fit);
jenny::CombinedList(lambda0Fit, &CombinedPiMinus, -211);
}
//***information of boosted particle
lambda0Fit->Boost(-beamBoost);
qa.qaComp("boost_", lambda0Fit, ntpLambda0);
ntpLambda0->DumpData();
}
jenny::GetNotCombinedList(CombinedPiMinus, &NotCombinedPiMinus);
// Lambda0Fit.Cleanup();
CombinedPiMinus.Cleanup();
SelectedPiMinus.Cleanup();
SelectedProton.Cleanup();
// NotCombinedPiMinus.Cleanup();
bestVtxFitLambda0.clear();
bestMassFitLambda0.clear();
//***AntiLambda0 -> PiPlus + AntiProton
antiLambda0.Combine(SelectedPiPlus,SelectedAntiProton);
antiLambda0.Select(lambdaMassSelector);
antiLambda0.SetType(kal0);
std::map<int,int> bestVtxFitAntiLambda0, bestMassFitAntiLambda0;
bestVtxFitAntiLambda0 = jenny::VertexQaIndex(&antiLambda0);
bestMassFitAntiLambda0 = jenny::MassFitQaIndex(&antiLambda0, m0_lambda0);
for (int j=0; j<antiLambda0.GetLength(); ++j){
//general info about event
ntpAntiLambda0->Column("ev", (Float_t) evt);
ntpAntiLambda0->Column("cand", (Float_t) j);
ntpAntiLambda0->Column("ncand", (Float_t) antiLambda0.GetLength());
ntpAntiLambda0->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(antiLambda0[j]));
ntpAntiLambda0->Column("AntiLambda0_Pdg", (Float_t) antiLambda0[j]->PdgCode());
RhoCandidate * mother = antiLambda0[j]->TheMother();
int moth = (mother==0x0) ? 88888 : mother->PdgCode();
ntpAntiLambda0->Column("Mother", (Float_t) moth);
qa.qaP4("AntiLambda0_", antiLambda0[j]->P4(), ntpAntiLambda0);
qa.qaComp("AntiLambda0_", antiLambda0[j], ntpAntiLambda0);
// do vertex fit
PndKinVtxFitter vertexfitterAntiLambda0 (antiLambda0[j]);
vertexfitterAntiLambda0.Fit();
RhoCandidate * antiLambda0Fit = antiLambda0[j]->GetFit();
// store info of vertex fit
qa.qaFitter("VtxFit_", &vertexfitterAntiLambda0, ntpAntiLambda0);
qa.qaVtx("VtxFit_", antiLambda0Fit, ntpAntiLambda0);
ntpAntiLambda0->Column("VtxFit_HowGood", (Int_t) bestVtxFitAntiLambda0[j]);
// do mass fit
PndKinFitter massFitterAntiLambda0(antiLambda0Fit);
massFitterAntiLambda0.AddMassConstraint(m0_lambda0);
massFitterAntiLambda0.Fit();
RhoCandidate * antiLambda0Fit_mass = antiLambda0Fit->GetFit();
qa.qaFitter("MassFit_", &massFitterAntiLambda0, ntpAntiLambda0);
ntpAntiLambda0->Column("MassFit_HowGood", (Int_t) bestMassFitAntiLambda0[j]);
RhoCandidate * truth = antiLambda0[j]->GetMcTruth();
TLorentzVector l;
if(0x0 != truth){
l = truth->P4();
qa.qaVtx("MCTruth_", truth, ntpAntiLambda0);
}
else{
qa.qaVtx("McTruth_", dummyCand, ntpAntiLambda0);
}
qa.qaP4("MCTruth_", l, ntpAntiLambda0);
//***information of boosted particle
antiLambda0Fit->Boost(-beamBoost);
qa.qaComp("boost_", antiLambda0Fit, ntpAntiLambda0);
if(bestVtxFitAntiLambda0[j]==1 && bestMassFitAntiLambda0[j]>0){
AntiLambda0Fit.Append(antiLambda0Fit);
jenny::CombinedList(antiLambda0Fit, &CombinedPiPlus, 211);
}
ntpAntiLambda0->DumpData();
}
jenny::GetNotCombinedList(CombinedPiPlus, &NotCombinedPiPlus);
CombinedPiPlus.Cleanup();
SelectedPiPlus.Cleanup();
SelectedAntiProton.Cleanup();
bestVtxFitAntiLambda0.clear();
bestMassFitAntiLambda0.clear();
//*** Xi- -> Lambda0 + Pi-
ximinus.Combine(Lambda0Fit, NotCombinedPiMinus);
ximinus.Select(xiMassSelector);
ximinus.SetType(kXim);
std::map<int,int> BestVtxFitXiMinus, BestMassFitXiMinus;
BestVtxFitXiMinus = jenny::VertexQaIndex(&ximinus);
BestMassFitXiMinus = jenny::MassFitQaIndex(&ximinus, m0_Xi);
for (int j=0; j<ximinus.GetLength(); ++j){
//general info about event
ntpXiMinus->Column("ev", (Float_t) evt);
ntpXiMinus->Column("cand", (Float_t) j);
ntpXiMinus->Column("ncand", (Float_t) ximinus.GetLength());
ntpXiMinus->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(ximinus[j]));
ntpXiMinus->Column("XiMinus_Pdg", (Float_t) ximinus[j]->PdgCode());
RhoCandidate * mother = ximinus[j]->TheMother();
int moth = (mother==0x0) ? 88888 : mother->PdgCode();
ntpXiMinus->Column("Mother", (Float_t) moth);
qa.qaP4("XiMinus_", ximinus[j]->P4(), ntpXiMinus);
qa.qaComp("XiMinus_", ximinus[j], ntpXiMinus);
qa.qaPoca("XiMinus_", ximinus[j], ntpXiMinus);
// do vertex-fit
PndKinVtxFitter vertexfitterXiMinus (ximinus[j]);
vertexfitterXiMinus.Fit();
RhoCandidate * ximinusFit = ximinus[j]->GetFit();
// store info of vertex-fit
qa.qaFitter("VtxFit_", &vertexfitterXiMinus, ntpXiMinus);
ntpXiMinus->Column("VtxFit_HowGood", (Int_t) BestVtxFitXiMinus[j]);
qa.qaVtx("VtxFit_", ximinusFit, ntpXiMinus);
// qa.Cand("VtxFit_", ximinusFit, ntpXiMinus);
// difference to MCTruth
qa.qaMcDiff("VtxFit_", ximinusFit, ntpXiMinus);
// do mass fit
PndKinFitter massFitterXiMinus(ximinusFit);
massFitterXiMinus.AddMassConstraint(m0_lambda0);
massFitterXiMinus.Fit();
RhoCandidate * ximinusFit_mass = ximinusFit->GetFit();
qa.qaFitter("MassFit_", &massFitterXiMinus, ntpXiMinus);
ntpXiMinus->Column("MassFit_HowGood", (Int_t) BestMassFitXiMinus[j]);
qa.qaMcDiff("MassFit_", ximinusFit_mass, ntpXiMinus);
RhoCandidate * truth = ximinus[j]->GetMcTruth();
TLorentzVector l;
if(0x0 != truth){
l = truth->P4();
qa.qaVtx("MCTruth_", truth, ntpXiMinus);
}
else{
qa.qaVtx("MCTruth_", dummyCand, ntpXiMinus);
}
qa.qaP4("MCTruth_", l, ntpXiMinus);
if (BestVtxFitXiMinus[j]==1 && BestMassFitXiMinus[j]>0){
XiMinusFit.Append(ximinusFit);
}
//***information of boosted particle
ximinusFit->Boost(-beamBoost);
qa.qaComp("boost_", ximinusFit, ntpXiMinus);
ntpXiMinus->DumpData();
}
Lambda0Fit.Cleanup();
NotCombinedPiMinus.Cleanup();
BestVtxFitXiMinus.clear();
BestMassFitXiMinus.clear();
//*** Xi+ -> AntiLambda0 + Pi+
xiplus.Combine(AntiLambda0Fit,piplus);
xiplus.Select(xiMassSelector);
xiplus.SetType(kaXip);
std::map<int,int> BestVtxFitXiPlus, BestMassFitXiPlus;
BestVtxFitXiPlus = jenny::VertexQaIndex(&xiplus);
BestMassFitXiPlus = jenny::MassFitQaIndex(&xiplus, m0_Xi);
for (int j=0; j<xiplus.GetLength(); ++j){
//general info about event
ntpXiPlus->Column("ev", (Float_t) evt);
ntpXiPlus->Column("cand", (Float_t) j);
ntpXiPlus->Column("ncand", (Float_t) xiplus.GetLength());
ntpXiPlus->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(xiplus[j]));
RhoCandidate * mother = xiplus[j]->TheMother();
int moth = (mother==0x0) ? 88888 : mother->PdgCode();
ntpXiPlus->Column("Mother", (Float_t) moth);
qa.qaP4("Xiplus_", xiplus[j]->P4(), ntpXiPlus);
qa.qaComp("Xiplus_", xiplus[j], ntpXiPlus);
// int tag = 0;
// int dtag[2] = {0,0};
//
// for (int dau=0; dau<xiplus[j]->NDaughters(); dau++){
//
// RhoCandidate * daughter = xiplus[j]->Daughter(dau);
// if(daughter->IsComposite()){
// int dtag1 = jenny::tagHits(daughter->Daughter(0));
// int dtag2 = jenny::tagHits(daughter->Daughter(1));
// if(dtag1==1 && dtag2==1) dtag[dau]=1;
// }
// else{
// dtag[dau] = jenny::tagHits(daughter);
// }
// }
//
// if(dtag[0]==1 && dtag[1]==1) tag=1;
//
// ntpXiPlus->Column("XiPlus_HitTag", (Int_t) tag);
//******** do vertex-fit
PndKinVtxFitter vertexfitterxiplus (xiplus[j]);
vertexfitterxiplus.Fit();
RhoCandidate * xiplusFit = xiplus[j]->GetFit();
// store info of vertex-fit
qa.qaFitter("VtxFit_", &vertexfitterxiplus, ntpXiPlus);
ntpXiPlus->Column("VtxFit_HowGood", (Int_t) BestVtxFitXiPlus[j]);
qa.qaVtx("VtxFit_", xiplusFit, ntpXiPlus);
// difference to MCTruth
qa.qaMcDiff("VtxFit_", xiplusFit, ntpXiPlus);
//****** do mass fit
PndKinFitter massFitterxiplus(xiplusFit);
massFitterxiplus.AddMassConstraint(m0_lambda0);
massFitterxiplus.Fit();
RhoCandidate * xiplusFit_mass = xiplusFit->GetFit();
qa.qaFitter("MassFit_", &massFitterxiplus, ntpXiPlus);
ntpXiPlus->Column("MassFit_HowGood", (float) BestMassFitXiPlus[j]);
qa.qaVtx("MassFit_", xiplusFit_mass, ntpXiPlus);
qa.qaMcDiff("MassFit_", xiplusFit_mass, ntpXiPlus);
RhoCandidate * truth = xiplus[j]->GetMcTruth();
TLorentzVector l;
if(0x0 != truth){
l = truth->P4();
qa.qaVtx("MCTruth_", truth, ntpXiPlus);
}
else{
qa.qaVtx("MCTruth_", dummyCand, ntpXiPlus);
}
qa.qaP4("MCTruth_", l, ntpXiPlus);
if(BestVtxFitXiPlus[j]==1 && BestMassFitXiPlus[j]>0){
XiPlusFit.Append(xiplusFit);
}
//***information of boosted particle
xiplusFit->Boost(-beamBoost);
qa.qaComp("boost_", xiplusFit, ntpXiPlus);
ntpXiPlus->DumpData();
}
AntiLambda0Fit.Cleanup();
// BestCandAntiLambda0.Cleanup();
BestVtxFitXiPlus.clear();
BestMassFitXiPlus.clear();
//******* Xi+ Xi- System*****************************
xiSys.Combine(XiPlusFit, XiMinusFit);
xiSys.SetType(88888);
for (int syscand=0; syscand<xiSys.GetLength(); ++syscand){
ntpXiSys->Column("ev", (Float_t) evt);
ntpXiSys->Column("cand", (Float_t) j);
ntpXiSys->Column("ncand", (Float_t) ximinus.GetLength());
ntpXiSys->Column("McTruthMatch", (bool) theAnalysis->McTruthMatch(xiSys[syscand]));
RhoCandidate * mother = xiSys[syscand]->TheMother();
int moth = (mother==0x0) ? 88888 : mother->PdgCode();
ntpXiSys->Column("Mother", (Float_t) moth);
qa.qaP4("XiSys_", xiSys[syscand]->P4(), ntpXiSys);
qa.qaComp("XiSys_", xiSys[syscand], ntpXiSys);
qa.qaPoca("XiSys_", xiSys[syscand], ntpXiSys);
RhoCandidate * truth = xiSys[syscand]->GetMcTruth();
TLorentzVector l;
if (truth != 0x0){
// qa.qaComp("McTruth_", truth, ntpXiSys);
qa.qaVtx("McTruth_", truth, ntpXiSys);
l = truth->P4();
}
else{
// qa.qaComp("McTruth_", dummyCand, ntpXiSys);
qa.qaVtx("McTruth_", dummyCand, ntpXiSys);
}
qa.qaP4("McTruth_", l, ntpXiSys);
//4C-Fitter
PndKinFitter fitter4c (xiSys[syscand]);
fitter4c.Add4MomConstraint(ini);
fitter4c.Fit();
RhoCandidate * xiSysFit4c = xiSys[syscand]->GetFit();
qa.qaFitter("4CFit_", &fitter4c, ntpXiSys);
qa.qaComp("4cFit_", xiSysFit4c, ntpXiSys);
qa.qaVtx("4CFit_", xiSysFit4c, ntpXiSys);
ntpXiSys->DumpData();
}
XiMinusFit.Cleanup();
XiPlusFit.Cleanup();
}
//Write output
out->cd();
ntpMC -> GetInternalTree()->Write();
ntpPiMinus ->GetInternalTree()->Write();
ntpPiPlus->GetInternalTree()->Write();
ntpProton->GetInternalTree()->Write();
ntpAntiProton->GetInternalTree()->Write();
ntpLambda0->GetInternalTree()->Write();
ntpAntiLambda0->GetInternalTree()->Write();
ntpXiMinus->GetInternalTree()->Write();
ntpXiPlus->GetInternalTree()->Write();
ntpXiSys->GetInternalTree()->Write();
out->Save();
timer.Stop();
Double_t rtime = timer.RealTime();
Double_t ctime = timer.CpuTime();
cout<<endl<<endl;
cout<<"Macro finisched successfully."<<endl;
cout<<"Realtime: "<<rtime<<" s, CPU time: "<<ctime<<" s"<<endl;
cout<<endl;
exit(0);
}
void global_reco(Int_t nEvents = 100, Int_t seed = 555)
{
gRandom->SetSeed(seed);
TTree::SetMaxTreeSize(90000000000);
TString script = TString(gSystem->Getenv("LIT_SCRIPT"));
TString parDir = TString(gSystem->Getenv("VMCWORKDIR")) + TString("/parameters");
// Input and output data
TString dir = "events/much_anna_omega_8gev_10k/"; // Output directory
TString mcFile = dir + "mc.0000.root"; // MC transport file
TString parFile = dir + "param.0000.root"; // Parameters file
TString globalRecoFile = dir + "global.reco.0000.root"; // Output file with reconstructed tracks and hits
// Digi files
TList* parFileList = new TList();
TObjString stsDigiFile = parDir + "/sts/sts_v12b_std.digi.par"; // STS digi file
TObjString trdDigiFile = parDir + "/trd/trd_v13g.digi.par"; // TRD digi file
TString muchDigiFile = parDir + "/much/much_v12c.digi.root"; // MUCH digi file
TString stsMatBudgetFile = parDir + "/sts/sts_matbudget_v12b.root";
TObjString tofDigiFile = parDir + "/tof/tof_v13b.digi.par";// TOF digi file
// Reconstruction parameters
TString globalTrackingType = "nn"; // Global tracking type
TString trdHitProducerType = "smearing"; // TRD hit producer type: smearing, digi, clustering
TString muchHitProducerType = "advanced"; // MUCH hit producer type: simple, advanced
if (script == "yes") {
mcFile = TString(gSystem->Getenv("LIT_MC_FILE"));
parFile = TString(gSystem->Getenv("LIT_PAR_FILE"));
globalRecoFile = TString(gSystem->Getenv("LIT_GLOBAL_RECO_FILE"));
stsDigiFile = TString(gSystem->Getenv("LIT_STS_DIGI"));
trdDigiFile = TString(gSystem->Getenv("LIT_TRD_DIGI"));
muchDigiFile = TString(gSystem->Getenv("LIT_MUCH_DIGI"));
tofDigiFile = TString(gSystem->Getenv("LIT_TOF_DIGI"));
stsMatBudgetFile = TString(gSystem->Getenv("LIT_STS_MAT_BUDGET_FILE"));
}
parFileList->Add(&stsDigiFile);
parFileList->Add(&trdDigiFile);
parFileList->Add(&tofDigiFile);
Int_t iVerbose = 1;
TStopwatch timer;
timer.Start();
gROOT->LoadMacro("$VMCWORKDIR/macro/littrack/loadlibs.C");
loadlibs();
FairRunAna *run = new FairRunAna();
run->SetInputFile(mcFile);
run->SetOutputFile(globalRecoFile);
// ----- STS -------------------------------------------------
Double_t threshold = 4;
Double_t noiseWidth = 0.01;
Int_t nofBits = 12;
Double_t ElectronsPerAdc = 10.;
Double_t StripDeadTime = 0.1;
CbmStsDigitize* stsDigitize = new CbmStsDigitize("STS Digitiser", iVerbose);
stsDigitize->SetRealisticResponse();
stsDigitize->SetFrontThreshold(threshold);
stsDigitize->SetBackThreshold(threshold);
stsDigitize->SetFrontNoiseWidth(noiseWidth);
stsDigitize->SetBackNoiseWidth(noiseWidth);
stsDigitize->SetFrontNofBits(nofBits);
stsDigitize->SetBackNofBits(nofBits);
stsDigitize->SetFrontNofElPerAdc(ElectronsPerAdc);
stsDigitize->SetBackNofElPerAdc(ElectronsPerAdc);
stsDigitize->SetStripDeadTime(StripDeadTime);
run->AddTask(stsDigitize);
FairTask* stsClusterFinder = new CbmStsClusterFinder("STS Cluster Finder",iVerbose);
run->AddTask(stsClusterFinder);
FairTask* stsFindHits = new CbmStsFindHits("STS Hit Finder", iVerbose);
run->AddTask(stsFindHits);
FairTask* stsMatchHits = new CbmStsMatchHits("STS Hit Matcher", iVerbose);
run->AddTask(stsMatchHits);
FairTask* kalman = new CbmKF();
run->AddTask(kalman);
CbmL1* l1 = new CbmL1();
//l1->SetExtrapolateToTheEndOfSTS(true);
l1->SetMaterialBudgetFileName(stsMatBudgetFile);
run->AddTask(l1);
CbmStsTrackFinder* trackFinder = new CbmL1StsTrackFinder();
FairTask* findTracks = new CbmStsFindTracks(iVerbose, trackFinder);
run->AddTask(findTracks);
FairTask* stsMatchTracks = new CbmStsMatchTracks("STSMatchTracks", iVerbose);
run->AddTask(stsMatchTracks);
// ------------------------------------------------------------------------
if (IsMuch(parFile)) {
// -------- MUCH digitization ------------
CbmMuchDigitizeGem* digitize = new CbmMuchDigitizeGem(muchDigiFile.Data());
if (muchHitProducerType == "simple") {
digitize->SetAlgorithm(0);
} else if (muchHitProducerType == "advanced") {
digitize->SetAlgorithm(1);
}
run->AddTask(digitize);
CbmMuchFindHitsGem* findHits = new CbmMuchFindHitsGem(muchDigiFile.Data());
run->AddTask(findHits);
CbmMuchDigitizeStraws* strawDigitize = new CbmMuchDigitizeStraws("MuchDigitizeStraws", muchDigiFile.Data(), iVerbose);
run->AddTask(strawDigitize);
CbmMuchFindHitsStraws* strawFindHits = new CbmMuchFindHitsStraws("MuchFindHitsStraws", muchDigiFile.Data(), iVerbose);
strawFindHits->SetMerge(1);
run->AddTask(strawFindHits);
// -----------------------------------------------------------------
}
if (IsTrd(parFile)) {
// ----- TRD reconstruction-----------------------------------------
// Update of the values for the radiator F.U. 17.08.07
Int_t trdNFoils = 130; // number of polyetylene foils
Float_t trdDFoils = 0.0013; // thickness of 1 foil [cm]
Float_t trdDGap = 0.02; // thickness of gap between foils [cm]
Bool_t simpleTR = kTRUE; // use fast and simple version for TR production
CbmTrdRadiator *radiator = new CbmTrdRadiator(simpleTR, trdNFoils, trdDFoils, trdDGap);
if (trdHitProducerType == "smearing") {
CbmTrdHitProducerSmearing* trdHitProd = new CbmTrdHitProducerSmearing(radiator);
trdHitProd->SetUseDigiPar(false);
run->AddTask(trdHitProd);
} else if (trdHitProducerType == "digi") {
CbmTrdDigitizer* trdDigitizer = new CbmTrdDigitizer(radiator);
run->AddTask(trdDigitizer);
CbmTrdHitProducerDigi* trdHitProd = new CbmTrdHitProducerDigi();
run->AddTask(trdHitProd);
} else if (trdHitProducerType == "clustering") {
// ----- TRD clustering -----
CbmTrdDigitizerPRF* trdClustering = new CbmTrdDigitizerPRF("TRD Clusterizer", "TRD task", radiator, false, true);
run->AddTask(trdClustering);
CbmTrdClusterFinderFast* trdClusterfindingfast = new CbmTrdClusterFinderFast(true, true, false, 5.0e-7);
run->AddTask(trdClusterfindingfast);
CbmTrdHitProducerCluster* trdClusterHitProducer = new CbmTrdHitProducerCluster();
run->AddTask(trdClusterHitProducer);
// ----- End TRD Clustering -----
}
// ------------------------------------------------------------------------
}
if (IsTof(parFile)) {
// ------ TOF hits --------------------------------------------------------
CbmTofHitProducerNew* tofHitProd = new CbmTofHitProducerNew("TOF HitProducerNew",iVerbose);
tofHitProd->SetInitFromAscii(kFALSE);
run->AddTask(tofHitProd);
// ------------------------------------------------------------------------
}
// ------ Global track reconstruction -------------------------------------
CbmLitFindGlobalTracks* finder = new CbmLitFindGlobalTracks();
//CbmLitFindGlobalTracksParallel* finder = new CbmLitFindGlobalTracksParallel();
// Tracking method to be used
// "branch" - branching tracking
// "nn" - nearest neighbor tracking
// "nn_parallel" - nearest neighbor parallel tracking
finder->SetTrackingType(std::string(globalTrackingType));
// Hit-to-track merger method to be used
// "nearest_hit" - assigns nearest hit to the track
finder->SetMergerType("nearest_hit");
run->AddTask(finder);
if (IsTrd(parFile)) {
CbmTrdMatchTracks* trdMatchTracks = new CbmTrdMatchTracks();
run->AddTask(trdMatchTracks);
}
if (IsMuch(parFile)) {
CbmMuchMatchTracks* muchMatchTracks = new CbmMuchMatchTracks();
run->AddTask(muchMatchTracks);
}
// ----- Primary vertex finding --------------------------------------
CbmPrimaryVertexFinder* pvFinder = new CbmPVFinderKF();
CbmFindPrimaryVertex* findVertex = new CbmFindPrimaryVertex(pvFinder);
run->AddTask(findVertex);
// -----------------------------------------------------------------------
// ----- Parameter database --------------------------------------------
FairRuntimeDb* rtdb = run->GetRuntimeDb();
FairParRootFileIo* parIo1 = new FairParRootFileIo();
FairParAsciiFileIo* parIo2 = new FairParAsciiFileIo();
parIo1->open(parFile.Data());
parIo2->open(parFileList, "in");
rtdb->setFirstInput(parIo1);
rtdb->setSecondInput(parIo2);
rtdb->setOutput(parIo1);
rtdb->saveOutput();
// ------------------------------------------------------------------------
// ----- Initialize and run --------------------------------------------
run->Init();
run->Run(0, nEvents);
// ------------------------------------------------------------------------
// ----- Finish -------------------------------------------------------
timer.Stop();
cout << "Macro finished successfully." << endl;
cout << "Test passed"<< endl;
cout << " All ok " << endl;
cout << "Output file is " << globalRecoFile << endl;
cout << "Parameter file is " << parFile << endl;
cout << "Real time " << timer.RealTime() << " s, CPU time " << timer.CpuTime() << " s" << endl;
// ------------------------------------------------------------------------
}
