// analisi Bool_t CheckSingle(const char* esdFileName,Bool_t kGRID){ //inizializzo a zero ncluster (di tree T) //for (int ifc=0;ifc<10000;ifc++) ncluster[ifc]=0; // check the content of the ESD AliPIDResponse *pidr = new AliPIDResponse(); // open the ESD file TFile* esdFile = TFile::Open(esdFileName); if (!esdFile || !esdFile->IsOpen()){ Error("CheckESD", "opening ESD file %s failed", esdFileName); return kFALSE; } TString mctrkref(esdFileName); mctrkref.ReplaceAll("AliESDs.root","TrackRefs.root"); TString fgal(esdFileName); fgal.ReplaceAll("AliESDs.root","galice.root"); if(kGRID){ fgal.Insert(0,"alien://"); mctrkref.Insert(0,"alien://"); } TTree *trkref; printf("ESD = %s\n",esdFileName); TFile *ftrkref; if(isMC) ftrkref = TFile::Open(mctrkref.Data()); AliHeader *h = new AliHeader(); TFile *fgalice; if(isMC) fgalice = TFile::Open(fgal.Data()); TTree *tgalice; if(isMC){ tgalice = (TTree *) fgalice->Get("TE"); tgalice->SetBranchAddress("Header",&h); } AliRunLoader* runLoader = NULL; AliRun *gAlice; if(isMC) runLoader = AliRunLoader::Open(fgal.Data()); if(runLoader){ runLoader->LoadgAlice(); gAlice = runLoader->GetAliRun(); if (!gAlice) { Error("CheckESD", "no galice object found"); return kFALSE; } runLoader->LoadKinematics(); runLoader->LoadHeader(); } AliESDEvent * esd = new AliESDEvent; // printf("esd object = %x\n",esd); TTree* tree = (TTree*) esdFile->Get("esdTree"); if (!tree){ Error("CheckESD", "no ESD tree found"); return kFALSE; } esd->ReadFromTree(tree); // crea link tra esd e tree TClonesArray* tofcl; // array dinamico TClonesArray* tofhit; TClonesArray* tofmatch; Int_t nev = tree->GetEntries(); //ogni entries evento Float_t mag; printf("nev = %i\n",nev); //azzero il contatore delle tracce del TTree T //ntracks=0; AliStack* stack=NULL; Int_t trkassociation[1000000]; for(Int_t ie=0;ie < nev;ie++){ if(runLoader){ runLoader->GetEvent(ie); // select simulated primary particles, V0s and cascades stack = runLoader->Stack(); } if(isMC) trkref = (TTree *) ftrkref->Get(Form("Event%i/TreeTR",ie)); tree->GetEvent(ie); if(isMC) tgalice->GetEvent(ie); if(isMC) interactiontime = h->GenEventHeader()->InteractionTime()*1E+12; mag = esd->GetMagneticField(); AliTOFHeader *tofh = esd->GetTOFHeader(); ntofcl = tofh->GetNumberOfTOFclusters(); esd->ConnectTracks(); // Deve essere sempre chiamato dopo aver letto l'evento (non troverebbe l'ESDevent). Scrivo in tutte le tracce l origine dell evento così poi da arrivare ovunque(tipo al cluster e al tempo quindi). //Riempio variabile del tree "T" //nevento=ie; if(! esd->GetVertex()){ esd->ResetStdContent(); continue;// una volta fatto il connect manda un flag ; siccome qua c'era un continue(non si arriva in fondo al ciclo) bisogna resettarlo altrimenti lo trova già attivo. } tofcl = esd->GetESDTOFClusters(); // AliESDTOFCluster *cltof = tofcl->At(i); if(tofcl->GetEntries() == 0){ esd->ResetStdContent(); continue; } tofhit = esd->GetESDTOFHits(); // AliESDTOFHit *hittof = tofhit->At(i); tofmatch = esd->GetESDTOFMatches(); // AliESDTOFHit *mathctof = tofmatch->At(i); // loop over tracks pidr->SetTOFResponse(esd,AliPIDResponse::kTOF_T0); //per recuperare lo start time ("esd", "tipo start time"), tipo cioè o il TOF stesso o il T0 o il best, ovvero la combinazione dei 2 Int_t ntrk = esd->GetNumberOfTracks(); //printf("%i) TPC tracks = %i -- TOF cluster = %i - TOF hit = %i -- matchable info = %i\n",ie,ntrk,tofcl->GetEntries(),tofhit->GetEntries(),tofmatch->GetEntries()); Double_t time[AliPID::kSPECIESC]; if(isMC && stack){// create association trackref printf("nMC track = %i\n",stack->GetNtrack()); for(Int_t ist=0;ist < stack->GetNtrack();ist++){ trkassociation[ist]=-1; } for(Int_t iref=0;iref < trkref->GetEntries();iref++){ trkref->GetEvent(iref); Int_t trkreference = trkref->GetLeaf("TrackReferences.fTrack")->GetValue(); if(trkreference > -1 && trkreference < 1000000){ trkassociation[trkreference] = iref; } } } for (Int_t iTrack = 0; iTrack < ntrk; iTrack++){ AliESDtrack* track = esd->GetTrack(iTrack); // select tracks of selected particles if ((track->GetStatus() & AliESDtrack::kITSrefit) == 0) continue;//almeno un hit nell ITS if (track->GetConstrainedChi2() > 4) continue; //se brutto X^2 if ((track->GetStatus() & AliESDtrack::kTOFout) == 0) continue; //se traccia matchata con tof if(track->GetNumberOfTPCClusters() < 70) continue; Float_t p =track->P(); itrig = 0; timetrig = 0; if(p > 0.9 && p < 1.1){ track->GetIntegratedTimes(time); itrig = iTrack; timetrig = track->GetTOFsignal() - time[2]; iTrack = ntrk; } } printf("real loop, ntrk = %i\n",ntrk); for (Int_t iTrack = 0; iTrack < ntrk; iTrack++){ AliESDtrack* track = esd->GetTrack(iTrack); // select tracks of selected particles if ((track->GetStatus() & AliESDtrack::kITSrefit) == 0) continue;//almeno un hit nell ITS if (track->GetConstrainedChi2() > 4) continue; //se brutto X^2 //if ((track->GetStatus() & AliESDtrack::kTOFout) == 0) continue; //se traccia matchata con tof if(track->GetNumberOfTPCClusters() < 70) continue; TOFout = (track->GetStatus() & AliESDtrack::kTOFout) > 0; track->GetIntegratedTimes(time); Float_t dx = track->GetTOFsignalDx(); //leggo i residui tra traccia e canale tof acceso Float_t dz = track->GetTOFsignalDz(); mism = 0; dedx = track->GetTPCsignal(); Int_t label = TMath::Abs(track->GetLabel()); if(stack){ TParticle *part=stack->Particle(label); pdg = part->GetPdgCode(); } Int_t TOFlabel[3]; track->GetTOFLabel(TOFlabel); // printf("%i %i %i %i\n",label,TOFlabel[0],TOFlabel[1],TOFlabel[2]); ChannelTOF[0] = track->GetTOFCalChannel(); // printf("geant time = %f\n",gtime); //getchar(); // if(TMath::Abs(dx) > 1.25 || TMath::Abs(dz) > 1.75) continue; // is inside the pad //riempio il numro di cludter e impulso trasverso per traccia del TTree T ncluster=track->GetNTOFclusters(); impulso_trasv=track->Pt(); impulso=track->P(); StartTime = pidr->GetTOFResponse().GetStartTime(track->P()); StartTimeRes = pidr->GetTOFResponse().GetStartTimeRes(track->P()); if(track->Pt() > 0.9 && track->Pt() < 1.5){ //impulso non troppo alto per separazione tra particelle Float_t dt = track->GetTOFsignal() - time[2] - pidr->GetTOFResponse().GetStartTime(track->P());//tempo TOF(è lo stesso di Gettime, solo che lo prendo dale tracce)(già calibrato) -ip del PI (posizione 0 e, posizione 1 mu, pos 2 PI, pos 3 K,pos 4 p) -start time Float_t dtKa = track->GetTOFsignal() - time[3] - pidr->GetTOFResponse().GetStartTime(track->P()); Float_t dtPr = track->GetTOFsignal() - time[4] - pidr->GetTOFResponse().GetStartTime(track->P()); hdt->Fill(dt); hdtKa->Fill(dtKa); hdtPr->Fill(dtPr); } charge = track->Charge(); phi = track->Phi(); eta = track->Eta(); GetPositionAtTOF(track,mag,coord); phiExt = TMath::ATan2(coord[1],coord[0]); etaExt = -TMath::Log(TMath::Tan(0.5*TMath::ATan2(sqrt(coord[0]*coord[0]+coord[1]*coord[1]),coord[2]))); for (int i=0;i<(track->GetNTOFclusters());i++){ int idummy=track->GetTOFclusterArray()[i]; AliESDTOFCluster *cl = (AliESDTOFCluster *) tofcl->At(idummy); tempo[i]=cl->GetTime(); tot[i]=cl->GetTOT(); ChannelTOF[i]=cl->GetTOFchannel(); if(i==0){ GetResolutionAtTOF(track,mag,ChannelTOF[i],res); } for(int im=cl->GetNMatchableTracks();im--;){ //o così o da n-1 a 0 //for(int im=cl->GetNMatchableTracks();im>0;im--) non andava bene perchè non prendeva mai lo 0 // if(track->GetNTOFclusters()==2) printf("-- %i) %f %f\n",im,cl->GetLength(im),cl->GetIntegratedTime(2,im)); if(cl->GetTrackIndex(im) == track->GetID()){ exp_time_el[i] = cl->GetIntegratedTime(0,im); // pi = 2 exp_time_mu[i] = cl->GetIntegratedTime(1,im); // pi = 2 exp_time_pi[i] = cl->GetIntegratedTime(2,im); // pi = 2 exp_time_ka[i] = cl->GetIntegratedTime(3,im); // pi = 2 exp_time_pr[i] = cl->GetIntegratedTime(4,im); // pi = 2 L[i] = cl->GetLength(im); // if(track->GetNTOFclusters()==2)printf("%i) %f %f\n",i,L[i],exp_time_pi[i]); DeltaX[i]=cl->GetDx(im); // mettendolo dentro questo if dovrei prendere i residui di una stessa traccia DeltaZ[i]=cl->GetDz(im); } } } //ReMatch(); Int_t jref=0; if(isMC){ if(TOFlabel[0] > -1 && TOFlabel[0] < 1000000){ trkref->GetEvent(trkassociation[TOFlabel[0]]); if(TOFlabel[0] == trkref->GetLeaf("TrackReferences.fTrack")->GetValue()){ // printf("trk -> %i (%i)\n",trkref->GetLeaf("TrackReferences.fTrack")->GetValue(),trkref->GetLeaf("TrackReferences.fTrack")->GetValue(jref)); while(jref > -1 && trkref->GetLeaf("TrackReferences.fTrack")->GetValue(jref) != 0){ //printf("det = %i\n",trkref->GetLeaf("TrackReferences.fDetectorId")->GetValue(jref)); if(trkref->GetLeaf("TrackReferences.fDetectorId")->GetValue(jref) == 4){ gtime=trkref->GetLeaf("TrackReferences.fTime")->GetValue(jref)*1E+12; xgl = trkref->GetLeaf("TrackReferences.fX")->GetValue(jref); ygl = trkref->GetLeaf("TrackReferences.fY")->GetValue(jref); zgl = trkref->GetLeaf("TrackReferences.fZ")->GetValue(jref); MakeTrueRes(); jref = 100; } jref++; } } } } if(TMath::Abs(label) != TOFlabel[0] && stack){ mism=2; while(TOFlabel[0] != -1 && TOFlabel[0] != label){ TOFlabel[0] = stack->Particle(TOFlabel[0])->GetMother(0); } if(label == TOFlabel[0]) mism=1; } //AddDelay(); T->Fill(); //cout<<"riempio il tree "<<endl; //Riempio tree "T" //incremento il contatore delle tracce del TTree T matchate e che superano i tagli //ntracks++; }//end of for(tracks) esd->ResetStdContent(); } //end of for(events) if(runLoader){ runLoader->UnloadHeader(); runLoader->UnloadKinematics(); delete runLoader; } esdFile->Close(); if(isMC) ftrkref->Close(); if(isMC) fgalice->Close(); }
void gen(Int_t nev = 1, const char* genConfig = "$ALICE_ROOT/MUON/macros/genTestConfig.C") { // Load libraries // gSystem->SetIncludePath("-I$ROOTSYS/include -I$ALICE_ROOT/include -I$ALICE_ROOT"); gSystem->Load("liblhapdf"); // Parton density functions gSystem->Load("libEGPythia6"); // TGenerator interface gSystem->Load("libpythia6"); // Pythia gSystem->Load("libAliPythia6"); // ALICE specific implementations AliPDG::AddParticlesToPdgDataBase(); TDatabasePDG::Instance(); // Run loader AliRunLoader* rl = AliRunLoader::Open("galice.root","FASTRUN","recreate"); rl->SetCompressionLevel(2); rl->SetNumberOfEventsPerFile(nev); rl->LoadKinematics("RECREATE"); rl->MakeTree("E"); gAlice->SetRunLoader(rl); // Create stack rl->MakeStack(); AliStack* stack = rl->Stack(); // Header AliHeader* header = rl->GetHeader(); // Create and Initialize Generator gROOT->LoadMacro(genConfig); AliGenerator* gener = genConfig(); // Go to galice.root rl->CdGAFile(); // Forbid some decays. Do it after gener->Init(0, because // the initialization of the generator includes reading of the decay table. // ... // // Event Loop // TStopwatch timer; timer.Start(); for (Int_t iev = 0; iev < nev; iev++) { cout <<"Event number "<< iev << endl; // Initialize event header->Reset(0,iev); rl->SetEventNumber(iev); stack->Reset(); rl->MakeTree("K"); // Generate event stack->Reset(); stack->ConnectTree(rl->TreeK()); gener->Generate(); cout << "Number of particles " << stack->GetNprimary() << endl; // Finish event header->SetNprimary(stack->GetNprimary()); header->SetNtrack(stack->GetNtrack()); // I/O stack->FinishEvent(); header->SetStack(stack); rl->TreeE()->Fill(); rl->WriteKinematics("OVERWRITE"); } // event loop timer.Stop(); timer.Print(); // Termination // Generator gener->FinishRun(); // Write file rl->WriteHeader("OVERWRITE"); gener->Write(); rl->Write(); }
void fastGen(Tune_t tune = kPyTuneCDFA , Float_t energy, Int_t nev = 1, TString process) { // Add all particles to the PDG database AliPDG::AddParticlesToPdgDataBase(); // set the random seed TDatime date; UInt_t seed = date.Get()+gSystem->GetPid(); gRandom->SetSeed(seed); cout<<"Seed for random number generation= "<<seed<<endl; // Runloader AliRunLoader* rl = AliRunLoader::Open("galice.root", "FASTRUN","recreate"); rl->SetCompressionLevel(2); rl->SetNumberOfEventsPerFile(nev); rl->LoadKinematics("RECREATE"); rl->MakeTree("E"); gAlice->SetRunLoader(rl); // Create stack rl->MakeStack(); AliStack* stack = rl->Stack(); // Header AliHeader* header = rl->GetHeader(); // // Create and Initialize Generator AliGenerator *gener = CreateGenerator(tune,energy); gener->Init(); // if nsd switch off single diffraction if ( process == "NSD"){ if(tune != kPhojet) { AliPythia::Instance()-> SetMSUB(92,0); // single diffraction AB-->XB AliPythia::Instance()-> SetMSUB(93,0); // single diffraction AB-->AX } else { cout << "NSD not yet implemented in the phojet case" << endl; exit(1); } } gener->SetStack(stack); // // Event Loop // Int_t iev; for (iev = 0; iev < nev; iev++) { if(!(iev%500)) printf("\n \n Event number %d \n \n", iev); // Initialize event header->Reset(0,iev); rl->SetEventNumber(iev); stack->Reset(); rl->MakeTree("K"); // stack->ConnectTree(); // Generate event gener->Generate(); // Analysis // Int_t npart = stack->GetNprimary(); // printf("Analyse %d Particles\n", npart); // for (Int_t part=0; part<npart; part++) { // TParticle *MPart = stack->Particle(part); // Int_t mpart = MPart->GetPdgCode(); // printf("Particle %d\n", mpart); // } // Finish event header->SetNprimary(stack->GetNprimary()); header->SetNtrack(stack->GetNtrack()); // I/O // stack->FinishEvent(); header->SetStack(stack); rl->TreeE()->Fill(); rl->WriteKinematics("OVERWRITE"); } // event loop // // Termination // Generator gener->FinishRun(); // Write file rl->WriteHeader("OVERWRITE"); gener->Write(); rl->Write(); }
int main(int argc, char* argv[]) { TApplication theApp(srcName.Data(), &argc, argv); //============================================================================= for (int i=0; i<argc; i++) cout << i << ", " << argv[i] << endl; //============================================================================= if (argc<5) return -1; TString sPath = argv[1]; if (sPath.IsNull()) return -1; TString sFile = argv[2]; if (sFile.IsNull()) return -1; TString sJetR = argv[3]; if (sJetR.IsNull()) return -1; TString sSjeR = argv[4]; if (sSjeR.IsNull()) return -1; //============================================================================= sPath.ReplaceAll("#", "/"); //============================================================================= double dJetR = -1.; if (sJetR=="JetR02") dJetR = 0.2; if (sJetR=="JetR03") dJetR = 0.3; if (sJetR=="JetR04") dJetR = 0.4; if (sJetR=="JetR05") dJetR = 0.5; if (dJetR<0.) return -1; cout << "Jet R = " << dJetR << endl; //============================================================================= double dSjeR = -1.; if (sSjeR=="SjeR01") dSjeR = 0.1; if (sSjeR=="SjeR02") dSjeR = 0.2; if (sSjeR=="SjeR03") dSjeR = 0.3; if (sSjeR=="SjeR04") dSjeR = 0.4; if (dSjeR<0.) return -1; cout << "Sub-jet R = " << dSjeR << endl; //============================================================================= const double dJetsPtMin = 0.001; const double dCutEtaMax = 1.6; const double dJetEtaMax = 1.; const double dJetAreaRef = TMath::Pi() * dJetR * dJetR; fastjet::GhostedAreaSpec areaSpc(dCutEtaMax); fastjet::JetDefinition jetsDef(fastjet::antikt_algorithm, dJetR, fastjet::BIpt_scheme, fastjet::Best); //fastjet::AreaDefinition areaDef(fastjet::active_area,areaSpc); fastjet::AreaDefinition areaDef(fastjet::active_area_explicit_ghosts,areaSpc); //fastjet::JetDefinition bkgsDef(fastjet::kt_algorithm, 0.2, fastjet::BIpt_scheme, fastjet::Best); //fastjet::AreaDefinition aBkgDef(fastjet::active_area_explicit_ghosts, areaSpc); fastjet::Selector selectJet = fastjet::SelectorAbsEtaMax(dJetEtaMax); //fastjet::Selector selectRho = fastjet::SelectorAbsEtaMax(dCutEtaMax-0.2); //fastjet::Selector selecHard = fastjet::SelectorNHardest(2); //fastjet::Selector selectBkg = selectRho * (!(selecHard)); //fastjet::JetMedianBackgroundEstimator bkgsEstimator(selectBkg, bkgsDef, aBkgDef); //fastjet::Subtractor bkgSubtractor(&bkgsEstimator); fastjet::JetDefinition subjDef(fastjet::antikt_algorithm, dSjeR, fastjet::BIpt_scheme, fastjet::Best); //============================================================================= std::vector<fastjet::PseudoJet> fjInput; //============================================================================= TList *list = new TList(); TH1D *hPtHat = new TH1D("hPtHat", "", 1000, 0., 1000.); TH1D *hJet = new TH1D("hJet", "", 1000, 0., 1000.); hJet->Sumw2(); list->Add(hJet); TH2D *hJetNsj = new TH2D("hJetNsj", "", 1000, 0., 1000., 101, -0.5, 100.5); hJetNsj->Sumw2(); list->Add(hJetNsj); TH2D *hJetIsj = new TH2D("hJetIsj", "", 1000, 0., 1000., 1000, 0., 1000.); hJetIsj->Sumw2(); list->Add(hJetIsj); TH2D *hJet1sj = new TH2D("hJet1sj", "", 1000, 0., 1000., 1000, 0., 1000.); hJet1sj->Sumw2(); list->Add(hJet1sj); TH2D *hJet2sj = new TH2D("hJet2sj", "", 1000, 0., 1000., 1000, 0., 1000.); hJet2sj->Sumw2(); list->Add(hJet2sj); TH2D *hJetDsj = new TH2D("hJetDsj", "", 1000, 0., 1000., 1000, 0., 1000.); hJetDsj->Sumw2(); list->Add(hJetDsj); TH2D *hJetIsz = new TH2D("hJetIsz", "", 1000, 0., 1000., 120, 0., 1.2); hJetIsz->Sumw2(); list->Add(hJetIsz); TH2D *hJet1sz = new TH2D("hJet1sz", "", 1000, 0., 1000., 120, 0., 1.2); hJet1sz->Sumw2(); list->Add(hJet1sz); TH2D *hJet2sz = new TH2D("hJet2sz", "", 1000, 0., 1000., 120, 0., 1.2); hJet2sz->Sumw2(); list->Add(hJet2sz); TH2D *hJetDsz = new TH2D("hJetDsz", "", 1000, 0., 1000., 120, 0., 1.2); hJetDsz->Sumw2(); list->Add(hJetDsz); //============================================================================= AliRunLoader *rl = AliRunLoader::Open(Form("%s/galice.root",sPath.Data())); if (!rl) return -1; if (rl->LoadHeader()) return -1; if (rl->LoadKinematics("READ")) return -1; //============================================================================= for (Int_t iEvent=0; iEvent<rl->GetNumberOfEvents(); iEvent++) { fjInput.resize(0); if (rl->GetEvent(iEvent)) continue; //============================================================================= AliStack *pStack = rl->Stack(); if (!pStack) continue; AliHeader *pHeader = rl->GetHeader(); if (!pHeader) continue; //============================================================================= AliGenPythiaEventHeader *pHeadPy = (AliGenPythiaEventHeader*)pHeader->GenEventHeader(); if (!pHeadPy) continue; hPtHat->Fill(pHeadPy->GetPtHard()); //============================================================================= for (Int_t i=0; i<pStack->GetNtrack(); i++) if (pStack->IsPhysicalPrimary(i)) { TParticle *pTrk = pStack->Particle(i); if (!pTrk) continue; if (TMath::Abs(pTrk->Eta())>dCutEtaMax) { pTrk = 0; continue; } // TParticlePDG *pPDG = pTrk->GetPDG(); if (!pPDG) { pTrk = 0; continue; } fjInput.push_back(fastjet::PseudoJet(pTrk->Px(), pTrk->Py(), pTrk->Pz(), pTrk->P())); // pPDG = 0; pTrk = 0; } //============================================================================= fastjet::ClusterSequenceArea clustSeq(fjInput, jetsDef, areaDef); std::vector<fastjet::PseudoJet> includJets = clustSeq.inclusive_jets(dJetsPtMin); // std::vector<fastjet::PseudoJet> subtedJets = bkgSubtractor(includJets); std::vector<fastjet::PseudoJet> selectJets = selectJet(includJets); // std::vector<fastjet::PseudoJet> sortedJets = fastjet::sorted_by_pt(selectJets); for (int j=0; j<selectJets.size(); j++) { double dJet = selectJets[j].pt(); hJet->Fill(dJet); //============================================================================= fastjet::Filter trimmer(subjDef, fastjet::SelectorPtFractionMin(0.)); fastjet::PseudoJet trimmdJet = trimmer(selectJets[j]); std::vector<fastjet::PseudoJet> trimmdSj = trimmdJet.pieces(); double nIsj = 0.; double d1sj = -1.; int k1sj = -1; double d2sj = -1.; int k2sj = -1; for (int i=0; i<trimmdSj.size(); i++) { double dIsj = trimmdSj[i].pt(); if (dIsj<0.001) continue; hJetIsj->Fill(dJet, dIsj); hJetIsz->Fill(dJet, dIsj/dJet); if (dIsj>d1sj) { d2sj = d1sj; k2sj = k1sj; d1sj = dIsj; k1sj = i; } else if (dIsj>d2sj) { d2sj = dIsj; k2sj = i; } nIsj += 1.; } hJetNsj->Fill(dJet, nIsj); if (d1sj>0.) { hJet1sj->Fill(dJet, d1sj); hJet1sz->Fill(dJet, d1sj/dJet); } if (d2sj>0.) { hJet2sj->Fill(dJet, d2sj); hJet2sz->Fill(dJet, d2sj/dJet); } if ((d1sj>0.) && (d2sj>0.)) { double dsj = d1sj - d2sj; double dsz = dsj / dJet; hJetDsj->Fill(dJet, dsj); hJetDsz->Fill(dJet, dsz); } } //============================================================================= pStack = 0; pHeadPy = 0; pHeader = 0; } //============================================================================= rl->UnloadgAlice(); rl->UnloadHeader(); rl->UnloadKinematics(); rl->RemoveEventFolder(); //============================================================================= TFile *file = TFile::Open(Form("%s/pyxsec_hists.root",sPath.Data()), "READ"); TList *lXsc = (TList*)file->Get("cFilterList"); file->Close(); TH1D *hWeightSum = (TH1D*)lXsc->FindObject("h1Trials"); hWeightSum->SetName("hWeightSum"); TProfile *hSigmaGen = (TProfile*)lXsc->FindObject("h1Xsec"); hSigmaGen->SetName("hSigmaGen"); //============================================================================= file = TFile::Open(Form("%s.root",sFile.Data()), "NEW"); hPtHat->Write(); hWeightSum->Write(); hSigmaGen->Write(); list->Write(); file->Close(); //============================================================================= cout << "DONE" << endl; //============================================================================= return 0; }
void AliITSVertexerTracksTest2(Int_t evFirst=0,Int_t evLast=0, const Char_t *galiceName="galice.root", const Char_t *trksName="AliITStracksV2.root", const Char_t *vtxName="AliITSVertices.root") { /******************************************************************* * * * Test macro for vertexing in pp using tracks. * * Input file must contain trees with AliITStrackV2 objects. * * Output file can be the same file with the tracks * * or another file. * * If the file galice.root is available, B is taken from there, * * otherwise is can be set here "by hand". * * * * Origin: A.Dainese, Padova [email protected] * *******************************************************************/ // Look for field value in galice.root Double_t field = 0.4; Int_t kDebug = 0; TFile *galice = 0; if(!gSystem->AccessPathName(galiceName,kFileExists)) { galice = new TFile(galiceName); gAlice = (AliRun*)galice->Get("gAlice"); AliMagF *fiel = TGeoGlobalMagField::Instance()->GetField(); field=(Double_t)fiel->SolenoidField()/10.; AliKalmanTrack::SetConvConst(100/0.299792458/field); printf(" B = %3.1f read from gAlice and set\n",field); } else { printf(" File galice.root not found: default 0.4 T being used!\n"); } // Open input and output files TFile *inFile = TFile::Open(trksName); TFile *outFile = TFile::Open(vtxName,"recreate"); // Create vertexer AliITSVertexerTracks *vertexer = new AliITSVertexerTracks(inFile,outFile,field,0.,0.); vertexer->SetDebug(0); vertexer->SetUseThrustFrame(0); vertexer->PrintStatus(); AliITSVertex *vert = 0; // Find vertices for(Int_t i=evFirst; i<=evLast; i++){ if(i%100==0)cout<<"processing event "<<i<<endl; gAlice->GetEvent(i); // The true Z coord. is fetched for comparison AliHeader *header = gAlice->GetHeader(); AliGenEventHeader* genEventHeader = header->GenEventHeader(); TArrayF primaryVertex(3); genEventHeader->PrimaryVertex(primaryVertex); vert = vertexer->FindVertexForCurrentEvent(i); if(kDebug>0){ // Prints the results cout <<"========================================================\n"; cout << "Event number: "<<i<<") Z Vertex:"<<endl; if(vert){ cout<<"FOUND: "<<vert->GetZ()<<"; "<<vert->GetZRes()<<endl; cout <<" True Z position "<<primaryVertex[2]<<endl; cout<<", diff= "<<(primaryVertex[2]-vert->GetZ())*10000.<<endl; } else { cout<<"NOT FOUND "<<endl; } } if(vert){ Double_t pos[3]; for(Int_t kk=0;kk<3;kk++)pos[kk]=(Double_t)primaryVertex[kk]; vert->SetTruePos(pos); vertexer->WriteCurrentVertex(); } } delete vertexer; inFile->Close(); outFile->Close(); delete inFile; delete outFile; galice->Close(); delete galice; return; }