void hist_filler(const char *tag="QGSP_INCLXX_EMV_MOM_0.5_pip") { TString inFile = Form("output/data_%s.root",tag); //TString outFile= Form("hists_clust_mult/hist_%s.root",tag); TString outFile= Form("tmp_hist_%s.root",tag); cout << "hist_filler inFile= " << inFile << endl; cout << "hist_filler outFile= " << outFile << endl; gROOT->Macro("$VMCWORKDIR/gconfig/rootlogon.C"); gSystem->Load("libhistfillertask"); FairLogger::GetLogger()->SetLogToFile(kFALSE); FairRunAna* fRun = new FairRunAna(); FairRuntimeDb* rtdb = fRun->GetRuntimeDb(); fRun->SetInputFile(inFile); fRun->SetOutputFile(outFile); HistFillerTask *hft = new HistFillerTask(0.35,0.45); fRun->AddTask(hft); fRun->Init(); fRun->Run(1000,0); }
void MCMonitoring( const UInt_t num_events, const TString base_name, const TString base_path = "." ) { TStopwatch timer; timer.Start(); const TString sim_file = base_path + "/r3bsim." + base_name + ".root"; const TString par_file = base_path + "/r3bpar." + base_name + ".root"; const TString out_file = base_path + "/mcmon." + base_name + ".root"; FairRunAna* run = new FairRunAna(); run->SetInputFile(sim_file); run->SetOutputFile(out_file); ConnectParFileToRuntimeDb(par_file, run->GetRuntimeDb()); run->AddTask(new R3BNeulandMCMon()); run->Init(); run->Run(0, num_events); timer.Stop(); cout << endl; cout << "Macro finished succesfully!" << endl; cout << "Output file writen: " << out_file << endl; cout << "Parameter file writen: " << par_file << endl; cout << "Real time: " << timer.RealTime() << "s, CPU time: " << timer.CpuTime() << "s" << endl; cout << endl; }
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);
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 findHits(TString inputFile="", TString outputFile="", Int_t nEvents = 0) { // ----- Timer -------------------------------------------------------- TStopwatch timer; timer.Start(); // ------------------------------------------------------------------------ // ----- Create analysis run ---------------------------------------- FairRunAna* fRun = new FairRunAna(); fRun->SetInputFile(inputFile); fRun->SetOutputFile(outputFile); // Hit finder R3BCalifaCrystalCal2Hit *hitFinder = new R3BCalifaCrystalCal2Hit(); // Select s438b Demonstrator Geometry hitFinder->SelectGeometryVersion(0x438b); hitFinder->SetAngularWindow(6.0*TMath::Pi()/180.0, 6.0*TMath::Pi()/180.0, 0); fRun->AddTask(hitFinder); fRun->Init(); FairLogger::GetLogger()->SetLogScreenLevel("INFO"); // FairLogger::GetLogger()->SetLogVerbosityLevel("HIGH"); fRun->Run(0,nEvents); delete fRun; // ----- 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; // ------------------------------------------------------------------------ }
radlen() { string version = "TGeant3"; // OR "TGeant3"; TString outFile= Form("radlen_20k_%s.root",version.c_str()); cout << "hist_filler outFile= " << outFile << endl; gROOT->Macro("$VMCWORKDIR/gconfig/rootlogon.C"); gSystem->Load("libradlendata"); FairLogger::GetLogger()->SetLogToFile(kFALSE); FairRunAna* fRun = new FairRunAna(); FairRuntimeDb* rtdb = fRun->GetRuntimeDb(); //fRun->SetInputFile(inFile); //fRun->SetInputFile(Form("sim_complete_20k_upto_%s.root",upto_det.c_str())); //fRun->SetInputFile("sim_complete_upto_GEM_200k_evt.root"); fRun->SetInputFile(Form("output/sim_complete_%s_0.root",version.c_str())); fRun->AddFile(Form("output/sim_complete_%s_1.root",version.c_str())); fRun->AddFile(Form("output/sim_complete_%s_2.root",version.c_str())); fRun->AddFile(Form("output/sim_complete_%s_3.root",version.c_str())); fRun->AddFile(Form("output/sim_complete_%s_4.root",version.c_str())); fRun->SetOutputFile(outFile); RadLenData *rld = new RadLenData(); fRun->AddTask(rld); fRun->Init(); fRun->Run(0,0); }
void global_reco104(Int_t nEvents = 100, // number of events Int_t seed = 555) { gRandom->SetSeed(seed); TString script = TString(gSystem->Getenv("LIT_SCRIPT")); TString parDir = TString(gSystem->Getenv("VMCWORKDIR")) + TString("/parameters"); // Input and output data //TString dir = "/Users/andrey/Development/cbm/d/events/sts_tof/"; // Output directory TString dir = "data/"; // Output directory TString mcFile = dir + "auaumbias4.mc.root"; // MC transport file TString parFile = dir + "auaumbias4.params.root"; // Parameters file TString globalRecoFile = dir + "auaumbias4.global.reco.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 TString stsMatBudgetFileName = parDir + "/sts/sts_matbudget_v12b.root"; TString TofGeoPar = "/parameters/tof/par_tof_V12a.txt"; // 10 m version // Directory for output results TString resultDir = "./data/auaumbias104/"; // Reconstruction parameters TString globalTrackingType = "branch"; // Global tracking type TString stsHitProducerType = "real"; // STS hit producer type: real, ideal // Normalization for efficiency Int_t normStsPoints = 4; Int_t normTrdPoints = 0; Int_t normMuchPoints = 0; Int_t normTofPoints = 1; Int_t normTrdHits = 0; Int_t normMuchHits = 0; Int_t normTofHits = 1; 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")); resultDir = TString(gSystem->Getenv("LIT_RESULT_DIR")); } parFileList->Add(&stsDigiFile); Int_t iVerbose = 1; TStopwatch timer; timer.Start(); gROOT->LoadMacro("$VMCWORKDIR/macro/littrack/loadlibs.C"); loadlibs(); gSystem->Load("libHadron"); FairRunAna *run = new FairRunAna(); run->SetInputFile(mcFile); run->SetOutputFile(globalRecoFile); // ----- STS REAL reconstruction ----------------------------------------------- // ----- STS digitizer ------------------------------------------------- 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->SetMaterialBudgetFileName(stsMatBudgetFileName); 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); // ------------------------------------------------------------------------ // ------ TOF hits -------------------------------------------------------- CbmTofHitProducer* tofHitProd = new CbmTofHitProducer("TOF HitProducer", 1); tofHitProd->SetParFileName(std::string(TofGeoPar)); run->AddTask(tofHitProd); // ------------------------------------------------------------------------ // ------ Global track reconstruction ------------------------------------- CbmLitFindGlobalTracks* finder = new CbmLitFindGlobalTracks(); // 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); // ------------------------------------------------------------------------ // ------------------------------------------------------------------------ CbmRichHitProducer* richHitProd = new CbmRichHitProducer(); //run->AddTask(richHitProd); CbmRichReconstruction* richReco = new CbmRichReconstruction(); //run->AddTask(richReco); CbmRichMatchRings* matchRings = new CbmRichMatchRings(); //run->AddTask(matchRings); // ------------------------------------------------------------------------ // ----- Primary vertex finding --------------------------------------- CbmPrimaryVertexFinder* pvFinder = new CbmPVFinderKF(); CbmFindPrimaryVertex* findVertex = new CbmFindPrimaryVertex(pvFinder); run->AddTask(findVertex); // ------------------------------------------------------------------------ // ----- Track finding QA check ------------------------------------ CbmLitTrackingQa* trackingQa = new CbmLitTrackingQa(); trackingQa->SetMinNofPointsSts(normStsPoints); trackingQa->SetMinNofPointsTrd(normTrdPoints); trackingQa->SetMinNofPointsMuch(normMuchPoints); trackingQa->SetMinNofPointsTof(normTofPoints); trackingQa->SetQuota(0.7); trackingQa->SetMinNofHitsTrd(normTrdHits); trackingQa->SetMinNofHitsMuch(normMuchHits); trackingQa->SetMinNofHitsRich(7); trackingQa->SetQuotaRich(0.6); trackingQa->SetVerbose(normTofHits); trackingQa->SetOutputDir(std::string(resultDir)); run->AddTask(trackingQa); // ------------------------------------------------------------------------ CbmLitFitQa* fitQa = new CbmLitFitQa(); fitQa->SetMvdMinNofHits(0); fitQa->SetStsMinNofHits(normStsPoints); fitQa->SetMuchMinNofHits(normMuchPoints); fitQa->SetTrdMinNofHits(normTrdPoints); fitQa->SetOutputDir(std::string(resultDir)); run->AddTask(fitQa); CbmLitClusteringQa* clusteringQa = new CbmLitClusteringQa(); clusteringQa->SetOutputDir(std::string(resultDir)); run->AddTask(clusteringQa); CbmProduceDst *produceDst = new CbmProduceDst(); // in hadron run->AddTask(produceDst); CbmHadronAnalysis *HadronAna = new CbmHadronAnalysis(); // in hadron run->AddTask(HadronAna); // ----- 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 << endl << endl; 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; cout << endl; // ------------------------------------------------------------------------ }
void comparison_cov_firstpar(int nevts=0, TString Path=""){ TDatabasePDG::Instance()-> AddParticle("pbarpSystem","pbarpSystem", 1.9, kFALSE, 0.1, 0,"", 88888); TStopwatch timer; //Output File TString outPath = Path; TString OutputFile = "cov_output.root"; //Input simulation Files TString DigiFile = Path + "digi_complete.root"; TString RecoFile = Path + "reco_complete.root"; 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->AddFriend(DigiFile); RunAna->AddFriend(RecoFile); RunAna->SetOutputFile(OutputFile); RunAna->Init(); // data reader Object PndAnalysis* theAnalysis = new PndAnalysis(); if (nevts==0) nevts = theAnalysis->GetEntries(); RhoCandList piminus, proton; TMatrixD CovPion(5,5); TMatrixD CovProton(5,5); int evt=-1; while (theAnalysis->GetEvent() && ++evt<nevts){ cout << "evt: " << evt << endl; TString PidSelection = "PidAlgoIdealCharged";//"PidAlgoMvd;PidAlgoStt;PidAlgoDrc"; //***Selection with no PID info theAnalysis->FillList(piminus, "PionAllMinus", PidSelection); theAnalysis->FillList(proton, "ProtonAllPlus", PidSelection); //Get piminus for (int j=0; j<piminus.GetLength(); ++j){ bool truth = theAnalysis->McTruthMatch(piminus[j]); if(truth){ TMatrixD piCov(7,7); piCov = piminus[j]->Cov7(); FairTrackParP paramFirst = theAnalysis->GetFirstPar(piminus[j]); double cov[15]; paramFirst.GetCov(cov); for (int i=0; i<15; i++){ if(TMath::Abs(cov[i]<1e-6)) cov[i]=0; } CovPion[0][0] = cov[0]; CovPion[0][1] = cov[1]; CovPion[0][2] = cov[2]; CovPion[0][3] = cov[3]; CovPion[0][4] = cov[4]; CovPion[1][1] = cov[5]; CovPion[1][2] = cov[6]; CovPion[1][3] = cov[7]; CovPion[1][4] = cov[8]; CovPion[2][2] = cov[9]; CovPion[2][3] = cov[10]; CovPion[2][4] = cov[11]; CovPion[3][3] = cov[12]; CovPion[3][4] = cov[13]; CovPion[4][4] = cov[14]; for (int i=0; i<5; i++){ for(int j=0; j<5; j++){ CovPion[j][i]=CovPion[i][j]; } } cout << "Covariance matrix for pion: " << endl; for(int i=0; i<7; i++){ for(int j=0; j<7; j++){ if(TMath::Abs(piCov[i][j])<1e-6) piCov[i][j]=0; } } piCov.Print(); cout << "First Par Covariance matrix for pion: " << endl; CovPion.Print(); } //Get proton for (int j=0; j<proton.GetLength(); ++j){ bool truth = theAnalysis->McTruthMatch(proton[j]); if(truth){ TMatrixD protCov = proton[j]->Cov7(); FairTrackParP paramFirst = theAnalysis->GetFirstPar(proton[j]); double cov[15]; paramFirst.GetCov(cov); for (int i=0; i<15; i++){ if(TMath::Abs(cov[i]<1e-6)) cov[i]=0; } CovProton[0][0] = cov[0]; CovProton[0][1] = cov[1]; CovProton[0][2] = cov[2]; CovProton[0][3] = cov[3]; CovProton[0][4] = cov[4]; CovProton[1][1] = cov[5]; CovProton[1][2] = cov[6]; CovProton[1][3] = cov[7]; CovProton[1][4] = cov[8]; CovProton[2][2] = cov[9]; CovProton[2][3] = cov[10]; CovProton[2][4] = cov[11]; CovProton[3][3] = cov[12]; CovProton[3][4] = cov[13]; CovProton[4][4] = cov[14]; for (int i=0; i<5; i++){ for(int j=0; j<5; j++){ CovProton[j][i]=CovProton[i][j]; } } cout << "Covariance matrix for proton: " << endl; for(int i=0; i<7; i++){ for(int j=0; j<7; j++){ if(TMath::Abs(protCov[i][j])<1e-6) protCov[i][j]=0; } } protCov.Print(); cout << "First Par Covariance matrix for proton: " << endl; CovProton.Print(); } } } } }
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 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 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; // ------------------------------------------------------------------------ }
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; } }
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 run_digi_Fi4() { // ----- Files --------------------------------------------------------------- TString inFile = "sim2.root"; TString parFile = "par2.root"; TString outFile = "hits2.root"; // --------------------------------------------------------------------------- // ----- Timer --------------------------------------------------------------- TStopwatch timer; timer.Start(); // --------------------------------------------------------------------------- // ----- Digitization -------------------------------------------------------- FairRunAna* run = new FairRunAna(); run->SetInputFile(inFile); run->SetOutputFile(outFile); // --------------------------------------------------------------------------- // ----- Connect the Digitization Task --------------------------------------- /*R3BCalifaCrystalCal2Hit* califa_digitizer = new R3BCalifaCrystalCal2Hit(); run->AddTask(califa_digitizer); // mTOF R3BmTofDigitizer* mtof_digitizer = new R3BmTofDigitizer(); run->AddTask(mtof_digitizer); // STaRTrack R3BSTaRTraHitFinder* tra_digitizer = new R3BSTaRTraHitFinder(); run->AddTask(tra_digitizer); // MFI R3BMfiDigitizer* mfi_digitizer = new R3BMfiDigitizer(); run->AddTask(mfi_digitizer); // PSP R3BPspDigitizer* psp_digitizer = new R3BPspDigitizer(); run->AddTask(psp_digitizer);*/ // Fi4,5,6 R3BFi4Digitizer* Fi4_digitizer = new R3BFi4Digitizer(0.001,0.01,1); run->AddTask(Fi4_digitizer); // sfi R3BsfiDigitizer* sfi_digitizer = new R3BsfiDigitizer(0.001,0.01); run->AddTask(sfi_digitizer); // --------------------------------------------------------------------------- // ----- Runtime DataBase info ----------------------------------------------- FairRuntimeDb* rtdb = run->GetRuntimeDb(); FairParRootFileIo* parIo1 = new FairParRootFileIo(); parIo1->open(parFile.Data()); rtdb->setFirstInput(parIo1); rtdb->setOutput(parIo1); rtdb->saveOutput(); // --------------------------------------------------------------------------- // ----- Intialise and run --------------------------------------------------- run->Init(); run->Run(); // --------------------------------------------------------------------------- // ----- Finish -------------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file writen: " << outFile << endl; cout << "Parameter file writen " << parFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << " s" << endl; cout << endl; cout << " Test passed" << endl; cout << " All ok " << endl; cout << " Digitization successful." << endl; // --------------------------------------------------------------------------- RemoveGeoManager(); }
void number_of_particles_leaving_GEM_hits_boxgen(TString pre="", int nevts=0, double mom=4.1){ TDatabasePDG::Instance()-> AddParticle("pbarpSystem","pbarpSystem", 1.9, kFALSE, 0.1, 0,"", 88888); TStopwatch timer; if (pre==""){ //Output File TString OutputFile = "test_analysis_output.root"; TString outPath = ""; //Input simulation Files TString inPIDFile = "pid_complete.root"; TString inParFile = "simparams.root"; } else { //Output File TString outPath = pre + "_"; TString OutputFile = pre + "_test_analysis_output.root"; //Input simulation Files TString inPIDFile = pre + "_pid_complete.root"; TString inParFile = pre + "_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 new ntuple and fill them with information ************************************************************************/ //*** create tuples RhoTuple * ntpPiMinus = new RhoTuple("ntpPiMinus", "PiMinus info"); RhoTuple * ntpPiPlus = new RhoTuple("ntpPiPlus", "PiPlus info"); RhoTuple * ntpKaonMinus = new RhoTuple("ntpKaonMinus", "KaonMinus info"); RhoTuple * ntpKaonPlus = new RhoTuple("ntpKaonPlus", "KaonPlus info"); RhoTuple * ntpProton = new RhoTuple("ntpProton", "Proton info"); RhoTuple * ntpAntiProton = new RhoTuple("ntpAntiProton", "Antiproton info"); //Create output file TFile *out = TFile::Open(outPath+"test_output_ana.root","RECREATE"); // data reader Object PndAnalysis* theAnalysis = new PndAnalysis(); if (nevts==0) nevts = theAnalysis->GetEntries(); //RhoCandLists for analysis RhoCandList piplus, piminus, proton, antiproton, kaonminus, kaonplus; RhoCandidate * dummyCand = new RhoCandidate(); //dummy candidate for empty candidate usage double p_m0 = TDatabasePDG::Instance()->GetParticle("proton")->Mass(); TLorentzVector ini (0,0, mom, sqrt(p_m0*p_m0+ mom*mom)+p_m0); TVector3 beamBoost = ini.BoostVector(); PndRhoTupleQA qa(theAnalysis, mom); int evt=-1; while (theAnalysis->GetEvent() && ++evt<nevts){ if ((evt%100)==0) cout << "evt "<< evt <<endl; TString PidSelection = "PidAlgoIdealCharged";//"PidAlgoMvd;PidAlgoStt;PidAlgoDrc"; to change from ideal PID to realistic PID uncomment this! //***Selection with no PID info theAnalysis->FillList(piminus, "PionBestMinus", PidSelection); theAnalysis->FillList(piplus, "PionBestPlus", PidSelection); theAnalysis->FillList(kaonminus, "KaonBestMinus", PidSelection); theAnalysis->FillList(kaonplus, "KaonBestPlus", PidSelection); theAnalysis->FillList(proton, "ProtonBestPlus", PidSelection); theAnalysis->FillList(antiproton, "ProtonBestMinus", PidSelection); //Get piminus information ntpPiMinus->Column("ev", (Float_t) evt); for (int j=0; j<piminus.GetLength(); ++j){ //information about the mother and MCTruth Candidate TLorentzVector l; float costheta = -999.; RhoCandidate * truth = piminus[j]->GetMcTruth(); RhoCandidate * mother; if (truth) mother = truth->TheMother(); int moth = (mother==0x0) ? 88888 : mother->PdgCode(); ntpPiMinus->Column("Mother", (Int_t) moth); bool truthmatch = theAnalysis->McTruthMatch(piminus[j]); ntpPiMinus->Column("MCTruthMatch", (bool) truthmatch); int gemhit = GemHits(piminus[j]); int count = 0; if (moth==88888 && gemhit==1 && truthmatch==1) count=1; ntpPiMinus->Column("GemHit", (int) count, 0); } ntpPiMinus->DumpData(); //Get PiPlus information ntpPiPlus->Column("ev", (int) evt); for (int j=0; j<piplus.GetLength(); ++j){ //information about the mother and MCTruth Candidate TLorentzVector l; float costheta = -999.; RhoCandidate * truth = piplus[j]->GetMcTruth(); RhoCandidate * mother; if (truth) mother = truth->TheMother(); int moth = (mother==0x0) ? 88888 : mother->PdgCode(); ntpPiPlus->Column("Mother", (Int_t) moth); bool truthmatch = theAnalysis->McTruthMatch(piplus[j]); ntpPiPlus->Column("MCTruthMatch", (bool) truthmatch); int gemhit = GemHits(piplus[j]); int count = 0; if (moth==88888 && gemhit==1 && truthmatch==1) count=1; ntpPiPlus->Column("GemHit", (int) count, 0); } ntpPiPlus->DumpData(); ntpKaonMinus->Column("ev", (int) evt); for (int j=0; j<kaonminus.GetLength(); ++j){ //information about the mother and MCTruth Candidate TLorentzVector l; float costheta = -999.; RhoCandidate * truth = kaonminus[j]->GetMcTruth(); RhoCandidate * mother; if (truth) mother = truth->TheMother(); int moth = (mother==0x0) ? 88888 : mother->PdgCode(); ntpKaonMinus->Column("Mother", (Int_t) moth); bool truthmatch = theAnalysis->McTruthMatch(kaonminus[j]); ntpKaonMinus->Column("MCTruthMatch", (bool) truthmatch); int gemhit = GemHits(kaonminus[j]); int count = 0; if (moth==88888 && gemhit==1 && truthmatch==1) count=1; ntpKaonMinus->Column("GemHit", (int) count, 0); } ntpKaonMinus->DumpData(); ntpKaonPlus->Column("ev", (int) evt); for (int j=0; j<kaonplus.GetLength(); ++j){ //information about the mother and MCTruth Candidate TLorentzVector l; float costheta = -999.; RhoCandidate * truth = kaonplus[j]->GetMcTruth(); RhoCandidate * mother; if (truth) mother = truth->TheMother(); int moth = (mother==0x0) ? 88888 : mother->PdgCode(); ntpKaonPlus->Column("Mother", (Int_t) moth); bool truthmatch = theAnalysis->McTruthMatch(kaonplus[j]); ntpKaonPlus->Column("MCTruthMatch", (bool) truthmatch); int gemhit = GemHits(kaonplus[j]); int count = 0; if (moth==88888 && gemhit==1 && truthmatch==1) count=1; ntpKaonPlus->Column("GemHit", (int) count, 0); } ntpKaonPlus->DumpData(); // Get Proton information ntpProton->Column("ev", (int) evt); for (int j=0; j<proton.GetLength(); ++j){ //information about the mother and MCTruth Candidate TLorentzVector l; float costheta = -999.; RhoCandidate * truth = proton[j]->GetMcTruth(); RhoCandidate * mother; if (truth) mother = truth->TheMother(); int moth = (mother==0x0) ? 88888 : mother->PdgCode(); ntpProton->Column("Mother", (Int_t) moth); bool truthmatch = theAnalysis->McTruthMatch(proton[j]); ntpProton->Column("MCTruthMatch", (bool) truthmatch); int gemhit = GemHits(proton[j]); int count = 0; if (moth==88888 && gemhit==1 && truthmatch==1) count=1; ntpProton->Column("GemHit", (int) count, 0); } ntpProton->DumpData(); // Get Antiproton ntpAntiProton->Column("ev", (int) evt); for (int j=0; j<antiproton.GetLength(); ++j){ //information about the mother and MCTruth Candidate TLorentzVector l; float costheta = -999.; RhoCandidate * truth = antiproton[j]->GetMcTruth(); RhoCandidate * mother; if (truth) mother = truth->TheMother(); int moth = (mother==0x0) ? 88888 : mother->PdgCode(); ntpAntiProton->Column("Mother", (Int_t) moth); bool truthmatch = theAnalysis->McTruthMatch(antiproton[j]); ntpAntiProton->Column("MCTruthMatch", (bool) truthmatch); int gemhit = GemHits(antiproton[j]); int count = 0; if (moth==88888 && gemhit==1 && truthmatch==1) count=1; ntpAntiProton->Column("GemHit", (int) count, 0); } ntpAntiProton->DumpData(); } //Write output out->cd(); ntpPiMinus ->GetInternalTree()->Write(); ntpPiPlus->GetInternalTree()->Write(); ntpKaonMinus ->GetInternalTree()->Write(); ntpKaonPlus->GetInternalTree()->Write(); ntpProton->GetInternalTree()->Write(); ntpAntiProton->GetInternalTree()->Write(); out->Save(); timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout<<"Macro finisched successfully."<<endl; cout<<"Realtime: "<<rtime<<" s, CPU time: "<<ctime<<" s"<<endl; cout<<endl; exit(0); }
void run(TString runNumber) { TStopwatch timer; timer.Start(); const Int_t nModules = 200; TString dirIn1 = "/Volumes/Data/kresan/s438/data/"; TString dirIn2 = "/Volumes/Data/kresan/s438/tcal/"; TString dirOut = "/Volumes/Data/kresan/s438/tcal/"; TString inputFileName1 = dirIn1 + runNumber + "_tcal.root"; // name of input file TString inputFileName2 = dirIn2 + runNumber + "_tcal_1.root"; // name of input file TString parFileName = dirIn1 + "params_" + runNumber + "_tcal.root"; // name of parameter file TString outputFileName = dirOut + runNumber + "_tcal_temp.root"; // name of output file // Create analysis run ------------------------------------------------------- Int_t nFiles; if (0 == runNumber.CompareTo("r122")) { nFiles = 22; } else if (0 == runNumber.CompareTo("r126")) { nFiles = 2; } // Create analysis run ------------------------------------------------------- FairRunAna* run = new FairRunAna(); run->SetInputFile(inputFileName1.Data()); run->AddFriend(inputFileName2.Data()); for (Int_t i = 1; i < nFiles; i++) { inputFileName1 = dirIn1 + runNumber + "_tcal_"; inputFileName1 += i; inputFileName1 += ".root"; run->AddFile(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); // Set the SQL IO as second input FairParTSQLIo* inp = new FairParTSQLIo(); inp->SetVerbosity(1); inp->open(); rtdb->setFirstInput(inp); rtdb->saveOutput(); // --------------------------------------------------------------------------- // Time calibration ---------------------------------------------------------- R3BLandTcal* landTcal = new R3BLandTcal("LandTcal", 1); landTcal->SetNofModules(nModules, 40); run->AddTask(landTcal); R3BLosTcal* losTcal = new R3BLosTcal("LosTcal", 1); losTcal->SetNofModules(20); run->AddTask(losTcal); // --------------------------------------------------------------------------- // Initialize ---------------------------------------------------------------- run->Init(); FairLogger::GetLogger()->SetLogScreenLevel("INFO"); // --------------------------------------------------------------------------- // Run ----------------------------------------------------------------------- run->Run(0, 100000); // --------------------------------------------------------------------------- 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 run_digi_tpc(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 << ".tpc.mc_" << nEvents << "_event.root"; paramfile << "AliceO2_" << mcEngine << ".tpc.params_" << nEvents << ".root"; outputfile << "AliceO2_" << mcEngine << ".tpc.digi_" << 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); // TGeoManager::Import("geofile_full.root"); // Setup digitizer AliceO2::ITS::DigitizerTask *digi = new AliceO2::ITS::DigitizerTask; fRun->AddTask(digi); AliceO2::TPC::DigitizerTask *digiTPC = new AliceO2::TPC::DigitizerTask; fRun->AddTask(digiTPC); fRun->Init(); 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; std::cout << "Macro finished succesfully." << std::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 ana_complete(int nevts=0) { TDatabasePDG::Instance()->AddParticle("pbarpSystem","pbarpSystem",1.9,kFALSE,0.1,0,"",88888); TStopwatch fTimer; // *** some variables int i=0,j=0, k=0, l=0; gStyle->SetOptFit(1011); // *** the output file for FairRunAna TString OutFile="output.root"; // *** the files coming from the simulation TString inPidFile = "psi2s_jpsi2pi_jpsi_mumu_pid.root"; // this file contains the PndPidCandidates and McTruth TString inParFile = "psi2s_jpsi2pi_jpsi_mumu_par.root"; // *** PID table with selection thresholds; can be modified by the user TString pidParFile = TString(gSystem->Getenv("VMCWORKDIR"))+"/macro/params/all_day1.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(); // *** create an output file for all histograms TFile *out = TFile::Open("output_ana.root","RECREATE"); // *** create some histograms TH1F *hmomtrk = new TH1F("hmomtrk","track momentum (all)",200,0,5); TH1F *hthttrk = new TH1F("hthttrk","track theta (all)",200,0,3.1415); TH1F *hjpsim_all = new TH1F("hjpsim_all","J/#psi mass (all)",200,0,4.5); TH1F *hpsim_all = new TH1F("hpsim_all","#psi(2S) mass (all)",200,0,5); TH1F *hjpsim_lpid = new TH1F("hjpsim_lpid","J/#psi mass (loose pid)",200,0,4.5); TH1F *hpsim_lpid = new TH1F("hpsim_lpid","#psi(2S) mass (loose pid)",200,0,5); TH1F *hjpsim_tpid = new TH1F("hjpsim_tpid","J/#psi mass (tight pid)",200,0,4.5); TH1F *hpsim_tpid = new TH1F("hpsim_tpid","#psi(2S) mass (tight pid)",200,0,5); TH1F *hjpsim_trpid = new TH1F("hjpsim_trpid","J/#psi mass (true pid)",200,0,4.5); TH1F *hpsim_trpid = new TH1F("hpsim_trpid","#psi(2S) mass (true pid)",200,0,5); TH1F *hjpsim_ftm = new TH1F("hjpsim_ftm","J/#psi mass (full truth match)",200,0,4.5); TH1F *hpsim_ftm = new TH1F("hpsim_ftm","#psi(2S) mass (full truth match)",200,0,5); TH1F *hjpsim_nm = new TH1F("hjpsim_nm","J/#psi mass (no truth match)",200,0,4.5); TH1F *hpsim_nm = new TH1F("hpsim_nm","#psi(2S) mass (no truth match)",200,0,5); TH1F *hjpsim_diff = new TH1F("hjpsim_diff","J/#psi mass diff to truth",100,-2,2); TH1F *hpsim_diff = new TH1F("hpsim_diff","#psi(2S) mass diff to truth",100,-2,2); TH1F *hjpsim_vf = new TH1F("hjpsim_vf","J/#psi mass (vertex fit)",200,0,4.5); TH1F *hjpsim_4cf = new TH1F("hjpsim_4cf","J/#psi mass (4C fit)",200,0,4.5); TH1F *hjpsim_mcf = new TH1F("hjpsim_mcf","J/#psi mass (mass constraint fit)",200,0,4.5); TH1F *hjpsi_chi2_vf = new TH1F("hjpsi_chi2_vf", "J/#psi: #chi^{2} vertex fit",100,0,10); TH1F *hpsi_chi2_4c = new TH1F("hpsi_chi2_4c", "#psi(2S): #chi^{2} 4C fit",100,0,250); TH1F *hjpsi_chi2_mf = new TH1F("hjpsi_chi2_mf", "J/#psi: #chi^{2} mass fit",100,0,10); TH1F *hjpsi_prob_vf = new TH1F("hjpsi_prob_vf", "J/#psi: Prob vertex fit",100,0,1); TH1F *hpsi_prob_4c = new TH1F("hpsi_prob_4c", "#psi(2S): Prob 4C fit",100,0,1); TH1F *hjpsi_prob_mf = new TH1F("hjpsi_prob_mf", "J/#psi: Prob mass fit",100,0,1); TH2F *hvpos = new TH2F("hvpos","(x,y) projection of fitted decay vertex",100,-2,2,100,-2,2); // // Now the analysis stuff comes... // // *** the data reader object PndAnalysis* theAnalysis = new PndAnalysis(); if (nevts==0) nevts= theAnalysis->GetEntries(); // *** RhoCandLists for the analysis RhoCandList chrg, muplus, muminus, piplus, piminus, jpsi, psi2s; // *** Mass selector for the jpsi cands double m0_jpsi = TDatabasePDG::Instance()->GetParticle("J/psi")->Mass(); // Get nominal PDG mass of the J/psi RhoMassParticleSelector *jpsiMassSel=new RhoMassParticleSelector("jpsi",m0_jpsi,1.0); // *** the lorentz vector of the initial psi(2S) TLorentzVector ini(0, 0, 6.231552, 7.240065); // *** // the event loop // *** int cntdbltrk=0, cntdblmc=0, cntdblboth=0, cnttrk=0, cnt_dbl_jpsi=0, cnt_dbl_psip=0; while (theAnalysis->GetEvent() && i++<nevts) { if ((i%100)==0) cout<<"evt " << i << endl; // *** Select with no PID info ('All'); type and mass are set theAnalysis->FillList(chrg, "Charged"); theAnalysis->FillList(muplus, "MuonAllPlus"); theAnalysis->FillList(muminus, "MuonAllMinus"); theAnalysis->FillList(piplus, "PionAllPlus"); theAnalysis->FillList(piminus, "PionAllMinus"); // *** momentum and theta histograms for (j=0;j<muplus.GetLength();++j) { hmomtrk->Fill(muplus[j]->P()); hthttrk->Fill(muplus[j]->P4().Theta()); } for (j=0;j<muminus.GetLength();++j) { hmomtrk->Fill(muminus[j]->P()); hthttrk->Fill(muminus[j]->P4().Theta()); } cnttrk += chrg.GetLength(); int n1, n2, n3; countDoubles(chrg,n1,n2,n3); cntdbltrk += n1; cntdblmc += n2; cntdblboth += n3; // *** combinatorics for J/psi -> mu+ mu- jpsi.Combine(muplus, muminus); // *** // *** do the TRUTH MATCH for jpsi // *** jpsi.SetType(443); int nm = 0; for (j=0;j<jpsi.GetLength();++j) { hjpsim_all->Fill( jpsi[j]->M() ); if (theAnalysis->McTruthMatch(jpsi[j])) { nm++; hjpsim_ftm->Fill( jpsi[j]->M() ); hjpsim_diff->Fill( jpsi[j]->GetMcTruth()->M() - jpsi[j]->M() ); } else hjpsim_nm->Fill( jpsi[j]->M() ); } if (nm>1) cnt_dbl_jpsi++; // *** // *** do VERTEX FIT (J/psi) // *** for (j=0;j<jpsi.GetLength();++j) { PndKinVtxFitter vtxfitter(jpsi[j]); // instantiate a vertex fitter vtxfitter.Fit(); double chi2_vtx = vtxfitter.GetChi2(); // access chi2 of fit double prob_vtx = vtxfitter.GetProb(); // access probability of fit hjpsi_chi2_vf->Fill(chi2_vtx); hjpsi_prob_vf->Fill(prob_vtx); if ( prob_vtx > 0.01 ) // when good enough, fill some histos { RhoCandidate *jfit = jpsi[j]->GetFit(); // access the fitted cand TVector3 jVtx=jfit->Pos(); // and the decay vertex position hjpsim_vf->Fill(jfit->M()); hvpos->Fill(jVtx.X(),jVtx.Y()); } } // *** some rough mass selection jpsi.Select(jpsiMassSel); // *** combinatorics for psi(2S) -> J/psi pi+ pi- psi2s.Combine(jpsi, piplus, piminus); // *** // *** do the TRUTH MATCH for psi(2S) // *** psi2s.SetType(88888); nm = 0; for (j=0;j<psi2s.GetLength();++j) { hpsim_all->Fill( psi2s[j]->M() ); if (theAnalysis->McTruthMatch(psi2s[j])) { nm++; hpsim_ftm->Fill( psi2s[j]->M() ); hpsim_diff->Fill( psi2s[j]->GetMcTruth()->M() - psi2s[j]->M() ); } else hpsim_nm->Fill( psi2s[j]->M() ); } if (nm>1) cnt_dbl_psip++; // *** // *** do 4C FIT (initial psi(2S) system) // *** for (j=0;j<psi2s.GetLength();++j) { PndKinFitter fitter(psi2s[j]); // instantiate the kin fitter in psi(2S) fitter.Add4MomConstraint(ini); // set 4 constraint fitter.Fit(); // do fit double chi2_4c = fitter.GetChi2(); // get chi2 of fit double prob_4c = fitter.GetProb(); // access probability of fit hpsi_chi2_4c->Fill(chi2_4c); hpsi_prob_4c->Fill(prob_4c); if ( prob_4c > 0.01 ) // when good enough, fill some histo { RhoCandidate *jfit = psi2s[j]->Daughter(0)->GetFit(); // get fitted J/psi hjpsim_4cf->Fill(jfit->M()); } } // *** // *** do MASS CONSTRAINT FIT (J/psi) // *** for (j=0;j<jpsi.GetLength();++j) { PndKinFitter mfitter(jpsi[j]); // instantiate the PndKinFitter in psi(2S) mfitter.AddMassConstraint(m0_jpsi); // add the mass constraint mfitter.Fit(); // do fit double chi2_m = mfitter.GetChi2(); // get chi2 of fit double prob_m = mfitter.GetProb(); // access probability of fit hjpsi_chi2_mf->Fill(chi2_m); hjpsi_prob_mf->Fill(prob_m); if ( prob_m > 0.01 ) // when good enough, fill some histo { RhoCandidate *jfit = jpsi[j]->GetFit(); // access the fitted cand hjpsim_mcf->Fill(jfit->M()); } } // *** // *** TRUE PID combinatorics // *** // *** do MC truth match for PID type SelectTruePid(theAnalysis, muplus); SelectTruePid(theAnalysis, muminus); SelectTruePid(theAnalysis, piplus); SelectTruePid(theAnalysis, piminus); // *** all combinatorics again with true PID jpsi.Combine(muplus, muminus); for (j=0;j<jpsi.GetLength();++j) hjpsim_trpid->Fill( jpsi[j]->M() ); jpsi.Select(jpsiMassSel); psi2s.Combine(jpsi, piplus, piminus); for (j=0;j<psi2s.GetLength();++j) hpsim_trpid->Fill( psi2s[j]->M() ); // *** // *** LOOSE PID combinatorics // *** // *** and again with PidAlgoMvd;PidAlgoStt;PidAlgoDrc and loose selection theAnalysis->FillList(muplus, "MuonLoosePlus", "PidAlgoMvd;PidAlgoStt;PidAlgoDrc;PidAlgoMdtHardCuts"); theAnalysis->FillList(muminus, "MuonLooseMinus", "PidAlgoMvd;PidAlgoStt;PidAlgoDrc;PidAlgoMdtHardCuts"); theAnalysis->FillList(piplus, "PionLoosePlus", "PidAlgoMvd;PidAlgoStt;PidAlgoDrc"); theAnalysis->FillList(piminus, "PionLooseMinus", "PidAlgoMvd;PidAlgoStt;PidAlgoDrc"); jpsi.Combine(muplus, muminus); for (j=0;j<jpsi.GetLength();++j) hjpsim_lpid->Fill( jpsi[j]->M() ); jpsi.Select(jpsiMassSel); psi2s.Combine(jpsi, piplus, piminus); for (j=0;j<psi2s.GetLength();++j) hpsim_lpid->Fill( psi2s[j]->M() ); // *** // *** TIGHT PID combinatorics // *** // *** and again with PidAlgoMvd;PidAlgoStt and tight selection theAnalysis->FillList(muplus, "MuonTightPlus", "PidAlgoMdtHardCuts"); theAnalysis->FillList(muminus, "MuonTightMinus", "PidAlgoMdtHardCuts"); theAnalysis->FillList(piplus, "PionLoosePlus", "PidAlgoMvd;PidAlgoStt;PidAlgoDrc"); theAnalysis->FillList(piminus, "PionLooseMinus", "PidAlgoMvd;PidAlgoStt;PidAlgoDrc"); jpsi.Combine(muplus, muminus); for (j=0;j<jpsi.GetLength();++j) hjpsim_tpid->Fill( jpsi[j]->M() ); jpsi.Select(jpsiMassSel); psi2s.Combine(jpsi, piplus, piminus); for (j=0;j<psi2s.GetLength();++j) hpsim_tpid->Fill( psi2s[j]->M() ); } // *** write out all the histos out->cd(); hmomtrk->Write(); hthttrk->Write(); hjpsim_all->Write(); hpsim_all->Write(); hjpsim_lpid->Write(); hpsim_lpid->Write(); hjpsim_tpid->Write(); hpsim_tpid->Write(); hjpsim_trpid->Write(); hpsim_trpid->Write(); hjpsim_ftm->Write(); hpsim_ftm->Write(); hjpsim_nm->Write(); hpsim_nm->Write(); hpsim_diff->Write(); hjpsim_diff->Write(); hjpsim_vf->Write(); hjpsim_4cf->Write(); hjpsim_mcf->Write(); hjpsi_chi2_vf->Write(); hpsi_chi2_4c->Write(); hjpsi_chi2_mf->Write(); hjpsi_prob_vf->Write(); hpsi_prob_4c->Write(); hjpsi_prob_mf->Write(); hvpos->Write(); out->Save(); // 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; fTimer.Stop(); Double_t rtime = fTimer.RealTime(); Double_t ctime = fTimer.CpuTime(); Float_t cpuUsage=ctime/rtime; cout << "<DartMeasurement name=\"CpuLoad\" type=\"numeric/double\">"; cout << cpuUsage; cout << "</DartMeasurement>" << endl; cout << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << "s" << endl; cout << "CPU usage " << cpuUsage*100. << "%" << endl; cout << "Max Memory " << maxMemory << " MB" << endl; cout << "Macro finished successfully." << endl; exit(0); }
void run_digi_dTof() { // ----- Files --------------------------------------------------------------- TString inFile = "sim.root"; TString parFile = "par.root"; TString outFile = "r3bhits_dTof.root"; // --------------------------------------------------------------------------- // ----- Timer --------------------------------------------------------------- TStopwatch timer; timer.Start(); // --------------------------------------------------------------------------- // ----- Digitization -------------------------------------------------------- FairRunAna* run = new FairRunAna(); run->SetInputFile(inFile); run->SetOutputFile(outFile); // --------------------------------------------------------------------------- // dTOF R3BdTofDigitizer* dtof_digitizer = new R3BdTofDigitizer(); run->AddTask(dtof_digitizer); dtof_digitizer->SetSigma_y( 1. ); dtof_digitizer->SetSigma_t( 0.03 ); dtof_digitizer->SetSigma_ELoss( 0.014 ); //0.0015 // --------------------------------------------------------------------------- // ----- Runtime DataBase info ----------------------------------------------- FairRuntimeDb* rtdb = run->GetRuntimeDb(); FairParRootFileIo* parIo1 = new FairParRootFileIo(); parIo1->open(parFile.Data()); rtdb->setFirstInput(parIo1); rtdb->setOutput(parIo1); rtdb->saveOutput(); // --------------------------------------------------------------------------- // ----- Intialise and run --------------------------------------------------- run->Init(); run->Run(); // --------------------------------------------------------------------------- // ----- Finish -------------------------------------------------------------- timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); cout << endl << endl; cout << "Macro finished succesfully." << endl; cout << "Output file writen: " << outFile << endl; cout << "Parameter file writen " << parFile << endl; cout << "Real time " << rtime << " s, CPU time " << ctime << " s" << endl; cout << endl; cout << " Test passed" << endl; cout << " All ok " << endl; cout << " Digitization successful." << endl; // --------------------------------------------------------------------------- RemoveGeoManager(); }