void PixelMergeSmallFiles(){ TFile * oFilebDist = new TFile("bDistr2.root", "RECREATE"); TNtuple* SimEventsGlobal = new TNtuple("SimEventGlob", "SimEventGlob", "EvN:b"); TFile * oFileLinks = new TFile("Links2.root", "RECREATE"); TNtuple* LinksGlobal = new TNtuple("LinksGlob", "LinksGlob", "EvN:fedid:linkn:nHits"); char FileInNumber[5]; string FileInPath = "/net/pstore01/d00/scratch/icali/CMSSW_2_1_11/PixelAnalysis/PixelNTuple_hydjet_x2_mb_oldPL_d20081106/"; string FileInNameRoot= "hydjet_x2_mb_oldPL_d20081106_r0"; Float_t j = 0; for(int FileN = 901; FileN <1801; ++FileN){ sprintf(FileInNumber, "%.5d", FileN); string FileInName = FileInPath+FileInNameRoot+FileInNumber+".root"; TFile *iFile = new TFile((const char*)FileInName.c_str()); if(!iFile->IsZombie()){ PixelAnalyzer->cd(); TNtuple *FEDLinks = (TNtuple*)iFile->FindObjectAny("Links"); TNtuple *SimEvents = (TNtuple*)iFile->FindObjectAny("SimEvent"); Float_t FEDEvN, fedid, linkn, nHits; FEDLinks->SetBranchAddress("EventN",&FEDEvN); FEDLinks->SetBranchAddress("fedid",&fedid); FEDLinks->SetBranchAddress("linkn",&linkn); FEDLinks->SetBranchAddress("nHits",&nHits); Long64_t FEDLinkLenght =FEDLinks->GetEntries(); Float_t SimEvN, b; SimEvents->SetBranchAddress("EventN",&SimEvN); SimEvents->SetBranchAddress("mult",&b); Long64_t SimEventLenght =SimEvents->GetEntries(); Long64_t i; for(i=0; i < SimEventLenght; ++i){ SimEvents->GetEntry(i); SimEventsGlobal->Fill(i, b); } Float_t OldEvN= -1; for(i=0; i < FEDLinkLenght; ++i){ FEDLinks->GetEntry(i); if(OldEvN != FEDEvN){ OldEvN= FEDEvN; ++j; } LinksGlobal->Fill(j, fedid, linkn, nHits); } } } oFilebDist->Write(); oFileLinks->Write(); }
void ROCOccupancy(Int_t StartRun, Int_t EndRun){ using namespace std; //string FileRoot = "/home/l_tester/log/bt05r"; string FileInName = "ProcessedData.root"; char RunNumber[6]; Float_t j = 0; for(int RunN = StartRun; RunN <=EndRun; ++RunN){ string FileRoot = "/d00/icali/PixelHwStudies/PSIStuff/log/bt05r"; sprintf(RunNumber, "%.6d", RunN); FileRoot = FileRoot + RunNumber + "/"; FileInName = FileRoot + FileInName; TFile *iFile = new TFile((const char*)FileInName.c_str()); if(!iFile->IsZombie()){ TNtuple *Digis = (TNtuple*)iFile->FindObjectAny("events"); Int_t EvN, roc, ROCHits, MeanPh, NCols; Digis->SetBranchAddress("ROCHits", &ROCHits); Digis->SetBranchAddress("MeanPh", &MeanPh); Digis->SetBranchAddress("roc", &roc); Digis->SetBranchAddress("NCols", &NCols); Digis->SetBranchAddress("EvN", &EvN); Int_t iNTlenght = Digis->GetEntries(); Int_t MaxROCHits =0; for(int i =0 ; i < iNTlenght; ++i){ Digis->GetEntry(i); if(ROCHits > MaxROCHits) MaxROCHits = ROCHits; } cout << "Run: " << RunN << " MaxROCHits: " << MaxROCHits << endl; } } }
void fitBjetJES(int ppPbPb=1, int cbinlo=12, int cbinhi=40){ if(!ppPbPb){ cbinlo=0; cbinhi=40; } gStyle->SetOptTitle(0); gStyle->SetOptStat(0); TFile *fL; if(!ppPbPb)fL=new TFile("histos/ppMC_hiReco_jetTrig_highPurity_JEC.root"); else fL=new TFile("histos/PbPbQCDMC_pt30by3_ipHICalibCentWeight.root"); // these are dummy files for pp TFile *fB=new TFile("histos/PbPbBMC_pt30by3_ipHICalibCentWeight.root"); TFile *fC=new TFile("histos/PbPbCMC_pt30by3_ipHICalibCentWeight.root"); TNtuple *tL = (TNtuple*) fL->Get("nt"); TNtuple *tB = (TNtuple*) fB->Get("nt"); TNtuple *tC = (TNtuple*) fC->Get("nt"); float jtptL, refptL, jtetaL, weightL, refparton_flavorForBL, binL; tL->SetBranchAddress("jtpt",&jtptL); tL->SetBranchAddress("jteta",&jtetaL); tL->SetBranchAddress("refpt",&refptL); tL->SetBranchAddress("weight",&weightL); if(ppPbPb)tL->SetBranchAddress("bin",&binL); tL->SetBranchAddress("refparton_flavorForB",&refparton_flavorForBL); float jtptB, refptB, jtetaB, weightB, refparton_flavorForBB, binB; tB->SetBranchAddress("jtpt",&jtptB); tB->SetBranchAddress("jteta",&jtetaB); tB->SetBranchAddress("refpt",&refptB); tB->SetBranchAddress("weight",&weightB); if(ppPbPb)tB->SetBranchAddress("bin",&binB); tB->SetBranchAddress("refparton_flavorForB",&refparton_flavorForBB); float jtptC, refptC, jtetaC, weightC, refparton_flavorForBC, binC; tC->SetBranchAddress("jtpt",&jtptC); tC->SetBranchAddress("jteta",&jtetaC); tC->SetBranchAddress("refpt",&refptC); tC->SetBranchAddress("weight",&weightC); if(ppPbPb)tC->SetBranchAddress("bin",&binC); tC->SetBranchAddress("refparton_flavorForB",&refparton_flavorForBC); TProfile *hL = new TProfile("hL","hL",250,50,300,0,10); TProfile *hB = new TProfile("hB","hB",250,50,300,0,10); TProfile *hC = new TProfile("hC","hC",250,50,300,0,10); hL->Sumw2(),hB->Sumw2(),hC->Sumw2(); for(int i=0;i<tL->GetEntries();i++){ tL->GetEntry(i); if(!ppPbPb) binL=39; if(fabs(jtetaL)<2 && binL>=cbinlo && binL<cbinhi) hL->Fill(refptL,jtptL/refptL,weightL); if(!ppPbPb){ if(fabs(jtetaL)<2 && binL>=cbinlo && binL<cbinhi && abs(refparton_flavorForBL)==5) hB->Fill(refptL,jtptL/refptL,weightL); if(fabs(jtetaL)<2 && binL>=cbinlo && binL<cbinhi && abs(refparton_flavorForBL)==4) hC->Fill(refptL,jtptL/refptL,weightL); } } if(ppPbPb){ for(int i=0;i<tB->GetEntries();i++){ tB->GetEntry(i); if(fabs(jtetaB)<2 && binB>=cbinlo && binB<cbinhi && abs(refparton_flavorForBB)==5) hB->Fill(refptB,jtptB/refptB,weightB); } for(int i=0;i<tC->GetEntries();i++){ tC->GetEntry(i); if(fabs(jtetaC)<2 && binC>=cbinlo && binC<cbinhi && abs(refparton_flavorForBC)==4) hC->Fill(refptC,jtptC/refptC,weightC); } } hL->SetMinimum(0.); hL->SetLineColor(kBlue); hB->SetLineColor(kRed); hC->SetLineColor(kGreen); hL->SetMarkerColor(kBlue); hB->SetMarkerColor(kRed); hC->SetMarkerColor(kGreen); //hL->SetMarkerStyle(4); //hB->SetMarkerStyle(4); //hC->SetMarkerStyle(4); hL->SetXTitle("genJet p_{T} (GeV/c)"); hL->SetYTitle("<reco p_{T} / gen p_{T} >"); hL->GetXaxis()->SetRangeUser(50.,199.999); hL->GetYaxis()->SetRangeUser(0.5,1.05); TCanvas *c1=new TCanvas("c1","c1",800,600); c1->SetGridx(1); c1->SetGridy(1); hL->Draw("e1"); hB->Draw("e1,same"); hC->Draw("e1,same"); TLegend *leg=new TLegend(0.4,0.15,0.9,0.45); leg->SetBorderSize(0); leg->SetFillStyle(0); if(ppPbPb&&cbinlo==0&&cbinhi==40)leg->SetHeader("Pythia+Hydjet, 0-100%"); leg->AddEntry(hL,"Inclusive jets","pl"); leg->AddEntry(hC,"c-jets","pl"); leg->AddEntry(hB,"b-jets","pl"); leg->Draw(); TCanvas *c2=new TCanvas("c2","c2",1); /* TH1F *hL2 = (TH1F*)hL->Clone("hL2"); TH1F *hB2 = (TH1F*)hB->Clone("hB2"); hL2->Add(hB2,-1); hL2->Draw(); */ TH1F *hcorr = new TH1F("hcorr","hcorr",250,50,300); hcorr->Sumw2(); for(int i=0;i<hL->GetNbinsX();i++){ cout<<" b resp "<<hB->GetBinContent(i+1)<<endl; cout<<" l resp "<<hL->GetBinContent(i+1)<<endl; cout<<" l offset "<<1.-hL->GetBinContent(i+1)<<endl; cout<<" corrected b resp "<<hB->GetBinContent(i+1)+1.-hL->GetBinContent(i+1)<<endl; float jesOffset = 1.-hL->GetBinContent(i+1); hcorr->SetBinContent(i+1,hB->GetBinContent(i+1)+jesOffset); hcorr->SetBinError(i+1,sqrt(hB->GetBinError(i+1)*hB->GetBinError(i+1)+hL->GetBinError(i+1)*hL->GetBinError(i+1))); } hcorr->SetMinimum(0.5); hcorr->SetMaximum(1.1); hcorr->SetLineColor(kRed); hcorr->SetMarkerColor(kRed); hcorr->SetMarkerStyle(4); hcorr->Draw(); TF1 *fCorr = new TF1("fCorr","[0]+[1]*log(x)+[2]*log(x)*log(x)",50,300); fCorr->SetLineWidth(1); fCorr->SetLineColor(kBlue); hcorr->Fit(fCorr); TFile *fout; if(ppPbPb) fout =new TFile(Form("bJEShistos/bJetScale_PbPb_Cent_fineBin_%d_%d.root",cbinlo,cbinhi),"recreate"); else fout =new TFile("bJEShistos/bJetScale_PP_fineBin.root","recreate"); hcorr->Write(); fCorr->Write(); fout->Close(); }
int main(int argc, char* argv[]){ TApplication* a = new TApplication("a", 0, 0); TStyle* style= DrawTools::setStyle(); style->cd(); std::string outputdir = "CalibComparisonPlots/"; std::string mkdir_command = "mkdir -p " + outputdir; system( mkdir_command.c_str() ); std::string runName0 = "BTF_259_20140502-012847_beam"; std::string runName1 = "BTF_259_20140502-012847_beam"; std::string runName2 = "BTF_259_20140502-012847_beam"; std::string runName3 = "BTF_259_20140502-012847_beam"; std::string runName4 = "BTF_259_20140502-012847_beam"; //std::string tag = "default"; std::string tag = "V03"; std::string inputDir = "./CeF3Calibration"; if( argc == 5 ) { std::string runName_str0(argv[1]); runName0 = runName_str0; std::string runName_str1(argv[2]); runName1 = runName_str1; std::string runName_str2(argv[3]); runName2 = runName_str2; std::string tag_str(argv[4]); tag = tag_str; } else if(argc == 7){ std::string runName_str0(argv[1]); runName0 = runName_str0; std::string runName_str1(argv[2]); runName1 = runName_str1; std::string runName_str2(argv[3]); runName2 = runName_str2; std::string runName_str3(argv[4]); runName3 = runName_str3; std::string runName_str4(argv[5]); runName4 = runName_str4; std::string tag_str(argv[6]); tag = tag_str; } else{ std::cout<<"Usage:"<<std::endl; std::cout<<"./calibrateCef3 BTF_XX BTF_XX BTF_XX tag "<<std::endl; exit(12345); } TCanvas* canny = new TCanvas("canny", "",200,200); canny->cd(); ifstream in; float x; int nlines; TNtuple *ntuple = new TNtuple("ntuple","data from .txt file", "x"); double corr0[4]; double corr_uncert0[4]; double corr1[4]; double corr_uncert1[4]; double corr2[4]; double corr_uncert2[4]; double corr3[4]; double corr_uncert3[4]; double corr4[4]; double corr_uncert4[4]; int const ntot = 10; TString openname[ntot] = { Form("%s/constants_%s_%s.txt",inputDir.c_str(),runName0.c_str(), tag.c_str() ), Form("%s/constants_uncert_%s_%s.txt", inputDir.c_str(),runName0.c_str(), tag.c_str()), Form("%s/constants_%s_%s.txt", inputDir.c_str(),runName1.c_str(), tag.c_str()), Form("%s/constants_uncert_%s_%s.txt", inputDir.c_str(),runName1.c_str(), tag.c_str()), Form("%s/constants_%s_%s.txt",inputDir.c_str(), runName2.c_str(), tag.c_str() ),Form("%s/constants_uncert_%s_%s.txt", inputDir.c_str(), runName2.c_str(), tag.c_str() ), Form("%s/constants_%s_%s.txt", inputDir.c_str(), runName3.c_str(), tag.c_str() ), Form("%s/constants_uncert_%s_%s.txt", inputDir.c_str(), runName3.c_str(), tag.c_str() ), Form("%s/constants_%s_%s.txt", inputDir.c_str(), runName4.c_str(), tag.c_str() ),Form("%s/constants_uncert_%s_%s.txt", inputDir.c_str(), runName4.c_str(), tag.c_str() ) }; for(int i=0; i<ntot+1; ++i){ in.open(openname[i-1]); while (nlines<4) { in>>x; if(!in.good()) break; ntuple->Fill(x); nlines++; } in.close(); nlines=0; } ntuple->SetBranchAddress("x",&x); for(int j=0; j<4; ++j){ ntuple->GetEntry(j); corr0[j]= x; ntuple->GetEntry(j+4); corr_uncert0[j]=x; ntuple->GetEntry(j+8); corr1[j]= x; ntuple->GetEntry(j+12); corr_uncert1[j]=x; ntuple->GetEntry(j+16); corr2[j]= x; ntuple->GetEntry(j+20); corr_uncert2[j]=x; if(argc==7){ ntuple->GetEntry(j+24); corr3[j]= x; ntuple->GetEntry(j+28); corr_uncert3[j]=x; ntuple->GetEntry(j+32); corr4[j]= x; ntuple->GetEntry(j+36); corr_uncert4[j]=x; } } double ch0[4] = {-0.1,0.9,1.9,2.9}; double ch1[4]={-0.05,0.95,1.95, 2.95}; double ch2[4] = {0,1,2,3}; double ch3[4] = {0.05,1.05,2.05,3.05}; double ch4[4] ={0.1,1.1,2.1,3.1}; double cherr[4]={0,0,0,0}; TGraphErrors* graf0 = new TGraphErrors(4,ch0,corr0,cherr,corr_uncert0); graf0->SetMarkerStyle(9); graf0->SetMarkerSize(0.5); graf0->SetMarkerColor(kGreen+1); TGraphErrors* graf1 = new TGraphErrors(4,ch1,corr1,cherr,corr_uncert1); graf1->SetMarkerStyle(9); graf1->SetMarkerSize(0.5); graf1->SetMarkerColor(kBlue); TGraphErrors* graf2 = new TGraphErrors(4,ch2,corr2,cherr,corr_uncert2); graf2->SetMarkerStyle(9); graf2->SetMarkerSize(0.5); graf2->SetMarkerColor(kMagenta); TMultiGraph *multi=new TMultiGraph(); multi->Add(graf0); multi->Add(graf1); multi->Add(graf2); TLegend* leg = new TLegend(0.7, 0.7, 0.9, 0.9); if(argc==5){ leg->AddEntry(graf0,"Run 92","P"); leg->AddEntry(graf1,"Run 246","P"); leg->AddEntry(graf2,"Run 259","P"); multi->SetTitle(";Channel Nr.;Correction Factor"); multi->Draw("AP"); multi->GetYaxis()->SetRangeUser(0.975,1.025); multi->GetXaxis()->SetNdivisions(4); } if(argc==7){ graf1->SetMarkerColor(kCyan+1); graf2->SetMarkerColor(kBlue); TGraphErrors* graf3 = new TGraphErrors(4,ch3,corr3,cherr,corr_uncert3); graf3->SetMarkerStyle(9); graf3->SetMarkerSize(0.5); graf3->SetMarkerColor(kViolet-1); TGraphErrors* graf4 = new TGraphErrors(4,ch4,corr4,cherr,corr_uncert4); graf4->SetMarkerStyle(9); graf4->SetMarkerSize(0.5); graf4->SetMarkerColor(kPink+7); multi->Add(graf3); multi->Add(graf4); multi->SetTitle(";Channel Nr.;Correction Factor"); multi->Draw("AP"); leg->AddEntry(graf0,"98.3 MeV","P"); leg->AddEntry(graf1,"147.4 MeV","P"); leg->AddEntry(graf2,"196.5 MeV","P"); leg->AddEntry(graf3,"294.8 MeV","P"); leg->AddEntry(graf4,"491.4 MeV","P"); //multi->GetYaxis()->SetRangeUser(0.9,1.1); multi->GetXaxis()->SetNdivisions(4); } multi->SetTitle(";Channel Nr.;Correction Factor"); multi->Draw("AP"); canny->Update(); leg->SetFillColor(0); leg->Draw("same"); TLine* lin = new TLine(-0.25,1.,3.25,1.); lin->SetLineColor(kRed); lin->Draw(); if(argc==5){canny->SaveAs( Form( "%s/comparison_%s.pdf", outputdir.c_str(), tag.c_str() )); } else if(argc==7){ canny->SaveAs( Form( "%s/comparison_energy_%s.pdf", outputdir.c_str(), tag.c_str() ));} delete canny; return 0; }
int main(int argc, char **argv) { TFile *f; TFile *newf; TNtuple *ntuple; TNtuple *newntuple; TH1F *h1; TF1 *func; TString Metal; TString dataLoc; Int_t dataSL; if(argc < 5 || argc > 6){ std::cout << "The number of arguments is incorrect" << std::endl; return 0; } dataLoc = argv[1]; PHI_MIN = (Double_t) std::stod(argv[2]); PHI_MAX = (Double_t) std::stod(argv[3]); N_PHI = (Int_t) std::stoi(argv[4]); if(argc >= 6) Metal = argv[5]; dataSL = dataLoc.Length(); if(dataLoc(dataSL-1, 1) != "/"){ dataLoc = dataLoc + "/"; } std::cout << "The following settings are being used" << std::endl; std::cout << "Data Directory = " << dataLoc << std::endl; std::cout << PHI_MIN << " < PHI < " << PHI_MAX << ", N_PHI = " << N_PHI << std::endl; if(argc == 6) std::cout << "Running only for Metal "<< Metal << std::endl; else std::cout << "Running all Metals" << std::endl; Float_t Q2, Xb, Zh, Pt, Phi, Val, Err; Float_t A, Ac, Acc; Float_t AErr, AcErr, AccErr; Float_t ChiSQ; Int_t nentries, empty; if(Metal == "") N_METAL = 6; else N_METAL = 1; for(Int_t met = 0; met < N_METAL; met++){ if(Metal == ""){ if(met == 0) Metal = "C"; else if(met == 1) Metal = "Fe"; else if(met == 2) Metal = "Pb"; else if(met == 3) Metal = "D_C"; else if(met == 4) Metal = "D_Fe"; else if(met == 5) Metal = "D_Pb"; } if(dataLoc == "") f = new TFile("../Gen5DimData/" + Metal + "_5_dim_dist.root", "READ"); else f = new TFile(dataLoc + Metal + "_5_dim_dist.root", "READ"); ntuple = (TNtuple*) f->Get("fit_data"); nentries = ntuple->GetEntries(); ntuple->SetBranchAddress("Xb", &Xb); ntuple->SetBranchAddress("Q2", &Q2); ntuple->SetBranchAddress("Xb", &Xb); ntuple->SetBranchAddress("Zh", &Zh); ntuple->SetBranchAddress("Pt", &Pt); ntuple->SetBranchAddress("Phi", &Phi); ntuple->SetBranchAddress("Val", &Val); ntuple->SetBranchAddress("Err", &Err); newntuple = new TNtuple("AAcAcc_data", "AAcAcc_data", "Q2:Xb:Zh:Pt:A:AErr:Ac:AcErr:Acc:AccErr:ChiSQ"); func = new TF1("fit", "[0]+TMath::Cos(x*TMath::Pi()/180)*[1]+TMath::Cos(2*x*TMath::Pi()/180)*[2]"); newf = new TFile(Metal + "newphihist.root", "RECREATE"); newf->cd(); for(Int_t i = 0; i < nentries; i = i + N_PHI){ ntuple->GetEntry(i); h1 = new TH1F((const char*) Form("PhiDist Q2=%.3f Xb=%.3f Zh=%.3f Pt=%.3f", Q2, Xb, Zh, Pt), (const char*) Form("PhiDist Q2=%.3f Xb=%.3f Zh=%.3f Pt=%.3f", Q2, Xb, Zh, Pt), N_PHI, PHI_MIN, PHI_MAX); empty = 0; for(Int_t j = 1; j <= N_PHI; j++){ ntuple->GetEntry(i+j-1); h1->SetBinContent(j, Val); if(h1->GetBinContent(j) == 0) empty++; h1->SetBinError(j, Err*1.04); } if(empty <= (N_PHI - MIN_BIN)){ h1->Fit(func, "q"); h1->Write(); if(func->GetNDF() != 0){ ChiSQ = func->GetChisquare(); A = func->GetParameter(0); AErr = func->GetParError(0); Ac = func->GetParameter(1); AcErr = func->GetParError(1); Acc = func->GetParameter(2); AccErr = func->GetParError(2); newntuple->Fill(Q2, Xb, Zh, Pt, A, AErr, Ac, AcErr, Acc, AccErr, ChiSQ); } } h1->Delete(); } Metal = ""; delete ntuple; newf->cd(); newntuple->Write(); newntuple->Delete(); newf->Close(); delete newf; f->Close(); delete f; } return 0; }
int main( int argc, char* argv[] ) { cout << endl; cout << "\t8888888b. d8b 888 8888888b. 888 888 " << endl; cout << "\t888 Y88b Y8P 888 888 Y88b 888 888 " << endl; cout << "\t888 888 888 888 888 888 888 " << endl; cout << "\t888 d88P 8888b. 88888b. 888 .d88888 888 d88P 888 .d88b. 888888 " << endl; cout << "\t8888888P\" \"88b 888 \"88b 888 d88\" 888 8888888P\" 888 d88\"\"88b 888 " << endl; cout << "\t888 T88b .d888888 888 888 888 888 888 888 888 888 888 888 " << endl; cout << "\t888 T88b 888 888 888 d88P 888 Y88b 888 888 888 Y88..88P Y88b. " << endl; cout << "\t888 T88b \"Y888888 88888P\" 888 \"Y88888 888 888 \"Y88P\" \"Y888 " << endl; cout << "\t 888 " << endl; cout << "\t 888 " << endl; cout << "\t 888 " << endl; cout << endl << endl; cout << "Usage:" << endl; cout << "\t" << argv[0] << "\tSomeFile.root\t" << "phys_param1\tphys_param2\toutput_directory" << endl; cout << endl << "\teg:\t" << argv[0] << "\tLLcontourData.root\tdeltaGamma\tPhi_s\toutputdir"<<endl; cout << endl; cout << "6th (Optional) Option:"<<endl; cout << "\t\t\tCV\t\t(Plot the CV of 'nuisence' Physics Parameters)"<<endl; cout << "\t\t\tRelCV\t\t(Plot the variation in the CV of the 'nuisence' Physics Parameters)"<<endl; cout << "\t\t\tExtraCV\t\t(Plot all of the CV, errors and pulls for each 'nuisence' Physics Parameter)"<<endl; cout << "\t\t\tNOFC\t\t(Don't process FC data in a file if any is there)"<<endl; cout << endl; if( (argc != 5) && (argc != 6) ) exit(-1); // Use UUID based seed from ROOT, just used for unique identification of ROOT objects TRandom3* rand_gen = new TRandom3(0); // Setup the Canvas and such EdStyle* RapidFit_Style = new EdStyle(); RapidFit_Style->SetStyle(); // By Design TString outputdir = argv[4]; TString param1string = argv[2]; TString param2string = argv[3]; // Make OutputDir gSystem->mkdir( outputdir ); // Open the File TFile * input = TFile::Open( argv[1] ); TNtuple* allresults; input->GetObject("RapidFitResult", allresults); if(!allresults){ input->GetObject("RapidFitResult/RapidFitResult",allresults); if(!allresults){ cout << "Couldn't find ntuple RapidFitResult in TFile" << endl; exit(1); } } // Switches for different plotting bool CV_Drift = false; bool Want_Physics_Params=false; bool Want_Extra_Physics_Param_Info=false; bool want_FC = true; bool high_res = true; // False method may only call plot fully once... still in development if( argc == 6 ) { if( string(argv[5]) == "CV" ) Want_Physics_Params = true; if( string(argv[5]) == "RelCV" ) { Want_Physics_Params = true; CV_Drift = true; } if( string(argv[5]) == "ExtraCV" ) { Want_Physics_Params = true; Want_Extra_Physics_Param_Info = true; } if( string(argv[5]) == "NOFC" ) want_FC = false; } // Strings that are universally defined TString Double_Tolerance="0.000001"; TString Fit_Status = "Fit_Status"; TString NLL = "NLL"; TString notgen = "-9999."; TString error_suffix = "_error"; TString value_suffix = "_value"; TString pull_suffix = "_pull"; TString gen_suffix = "_gen"; TString Copy_Option = "fast"; // Strings that are relevent to this plot // This is currently given by the user, but in time we can write an algorithm to determine this TString param1_gen = param1string + gen_suffix; TString param1_val = param1string + value_suffix; TString param1_err = param1string + error_suffix; TString param2_gen = param2string + gen_suffix; TString param2_val = param2string + value_suffix; TString param2_err = param2string + error_suffix; // Get a list of ALL parameters within the file, this is given for free in the algorithms I wrote above // Get a list of all branches in allresults vector<TString> all_parameters = get_branch_names( allresults ); // Get a list of all branches in allresults with '_value' in their name vector<TString> all_parameter_values = filter_names( all_parameters, value_suffix ); vector<TString> all_parameter_errors = filter_names( all_parameters, error_suffix ); vector<TString> all_parameter_pulls = filter_names( all_parameters, pull_suffix ); // Now to read in the Global Minima // Store the Global fit corrdinate and value Float_t nll=0, Global_Best_NLL=0, x_point=0, y_point=0; // Store the value of the 'nuisence' parameters as well Float_t* best_fit_values = new Float_t[all_parameter_values.size()]; // Construct an array to hold the best values for the rest of the parameters Float_t* best_fit_temp_values = new Float_t[all_parameter_values.size()]; allresults->SetBranchAddress(NLL,&nll); // Tell ROOT where to store the values for( unsigned short int i=0; i < all_parameter_values.size(); ++i ) { allresults->SetBranchAddress(all_parameter_values[i],&best_fit_temp_values[i]); } // Actually store the values in resident memory of the program cout << endl << "BEST FIT RESULTS AS DETERMINED FROM THE STANDARD FIT:" << endl; allresults->GetEntry(0); Global_Best_NLL = nll; for( unsigned short int i=0; i < all_parameter_values.size(); ++i ) { cout << all_parameter_values[i] << ":\t" << best_fit_temp_values[i] << endl; best_fit_values[i] = best_fit_temp_values[i]; if( string(all_parameter_values[i].Data()).compare(param1_val.Data()) == 0 ) x_point = best_fit_temp_values[i]; if( string(all_parameter_values[i].Data()).compare(param2_val.Data()) == 0 ) y_point = best_fit_temp_values[i]; } cout << endl; // General Cuts to be applied for various plots // Fit_Status == 3 TString Fit_Cut = "(abs(" + Fit_Status + "-3.0)<"+Double_Tolerance+")"; // param1_gen == notgen && param1_err == 0 TString Param_1_Cut = "(abs(" + param1_gen + "-" + notgen +")<" + Double_Tolerance + ")&&(abs("+ param1_err + "-0.0)<"+ Double_Tolerance + ")"; // param2_gen == notgen && param2_err == 0 TString Param_2_Cut = "(abs(" + param2_gen + "-" + notgen + ")<"+ Double_Tolerance + ")&&(abs(" +param2_err +"-0.0)<" + Double_Tolerance + ")"; // Combine the individual Cuts TString Fit_Cut_String = Param_1_Cut + "&&" + Param_2_Cut + "&&" + Fit_Cut; // Toys have a defined generation Value, Fits to Data DO NOT // param1_gen != notgen TString p1isatoy = "(abs(" + param1_gen + "-" + notgen + ")>" + Double_Tolerance + ")"; // param2_gen != notgen TString p2isatoy = "(abs(" + param2_gen + "-" + notgen + ")>" + Double_Tolerance + ")"; // Combine the individual Cuts TString Toy_Cut_String = p1isatoy + "&&" + p2isatoy; // Check for Toys in the file and wether I should run the FC code allresults->Draw( NLL, Toy_Cut_String, "goff" ); bool Has_Toys = allresults->GetSelectedRows() > 0; cout << endl << "NUMBER OF TOYS IN FILE:\t" << allresults->GetSelectedRows() << endl; if( int(allresults->GetEntries() - allresults->GetSelectedRows()) == 0 ) { cerr << "SERIOUS ERROR:\tSOMETHING HAS REALLY GOTTEN SCREWED UP!" << endl; exit(-3498); } // Fit values for the global fit are now stored in: // // Global_Best_NLL, best_fit_values, x_point, y_point // Tell the user cout << "GLOBAL DATA BEST FIT NLL:\t" << setprecision(10) << Global_Best_NLL << "\tAT:\tX:" << setprecision(10) << x_point << "\tY:\t" <<setprecision(10)<< y_point << endl; // Check wether the minima as defined from the Global fit is the true minima within the phase-space //Check_Minima( allresults, Fit_Cut_String, &Global_Best_NLL, NLL, Double_Tolerance, param1_val, param2_val ); TString NLL_Min; // Of course ROOT doesn't have USEFUL constructors! NLL_Min+=Global_Best_NLL; // Plot the distribution of successfully fitted grid points for the PLL scan // NB: For FC this will likely saturate due to multiple layers of fits cout << endl << "FOUND UNIQUE GRID POINTS, PLOTTING" << endl; LL2D_Grid( allresults, Fit_Cut_String, param1string, param2string, rand_gen, "LL", outputdir ); // Construct a plot string for the NLL plot and plot it // PLL part of Draw_String TString PLL = "(" + NLL + "-" + NLL_Min + ")"; // Gridding part of Draw_String TString Param1_Param2 = ":" + param1_val + ":" + param2_val; // Draw String for PLL TString NLL_DrawString = PLL + Param1_Param2; cout << endl << "PLOTTING NLL VARIATION" << endl; // PLL plot TH2* pllhist=NULL; TGraph2D* pllgraph=NULL; if( high_res ) { pllhist = Plot_From_Cut( allresults, NLL_DrawString, Fit_Cut_String, rand_gen, param1string, param2string ); } else { pllgraph = Plot_From_Cut_lo( allresults, NLL_DrawString, Fit_Cut_String, rand_gen, param1string, param2string ); } // Array storing the addresses of all of the Physics Plots still in memory TH2** All_Physics_Plots = new TH2*[all_parameter_values.size()]; TH2** All_Physics_Errors = new TH2*[all_parameter_values.size()]; TH2** All_Physics_Pulls = new TH2*[all_parameter_values.size()]; // Making use of switch if( Want_Physics_Params ) { // Physics Plots Physics_Plots( all_parameter_values, best_fit_values, allresults, rand_gen, Param1_Param2, CV_Drift, All_Physics_Plots, Fit_Cut_String); cout << endl << "Finalising CV Plots" << endl << endl; Finalize_Physics_Plots( All_Physics_Plots, all_parameter_values, param1string, param2string, outputdir, CV_Drift ); if( Want_Extra_Physics_Param_Info ) { // Physics Plots // // Passing false as Highly unlikely that I will 'ever' want to watch error/pull drift rather than the absolute value Float_t* null_pointer=NULL; Physics_Plots( all_parameter_errors, null_pointer, allresults, rand_gen, Param1_Param2, false, All_Physics_Errors, Fit_Cut_String); Physics_Plots( all_parameter_pulls, null_pointer, allresults, rand_gen, Param1_Param2, false, All_Physics_Pulls, Fit_Cut_String); cout << endl << "Finalising Extra CV Plots" << endl << endl; Finalize_Physics_Plots( All_Physics_Errors, all_parameter_errors, param1string, param2string, outputdir, false ); Finalize_Physics_Plots( All_Physics_Pulls, all_parameter_pulls, param1string, param2string, outputdir, false ); } } TFile* new_FC_Output = NULL; TTree* FC_Output = new TTree( "FC_Output", "FC_Output" );; TH2* FC_Plot = NULL; // Making use of switch if( Has_Toys && want_FC ) { // FC Plot cout << "FOUND TOYS IN FILE, PLOTTING FC" <<endl; TString FC_Tuple_File( outputdir+ "/FC_Tuple.root" ); new_FC_Output = new TFile( FC_Tuple_File, "RECREATE" ); FC_Plot = FC_TOYS( allresults, Fit_Cut_String, param1string, param2string, NLL, Fit_Cut, Global_Best_NLL, FC_Output, Double_Tolerance, rand_gen ); FC_Output->Write(); //LL2D_Grid( FC_Output, Fit_Cut, param1_val, param2_val, rand_gen, "FC" ); } // Contours to be used in plotting int cont_num = 3; double* pllconts = new double[unsigned(cont_num)]; pllconts[0] = 1.15; pllconts[1] = 2.36; pllconts[2] = 3.0;// pllconts[3] = 4.61; double* fcconts = new double[unsigned(cont_num)]; fcconts[0] = 0.68; fcconts[1] = 0.9; fcconts[2] = 0.95;// fcconts[3] = 0.99; double* confs = new double[unsigned(cont_num)]; confs[0] = 68.0; confs[1] = 90.0; confs[2] = 95.0;// confs[3] = 99.0; cout <<endl<< "SAVING GRAPHS" << endl; if( high_res ) { Plot_Styled_Contour( pllhist, cont_num, pllconts, confs, outputdir, "Likelihood Profile" ); } else { //Plot_Styled_Contour2( pllgraph, cont_num, pllconts, confs, outputdir, "Likelihood Profile" ); } if( Has_Toys && want_FC ) // If FC was generated { // Thinking of implementing a PLL Plot for the FC as it's easier to plot that (and looks more impressive) //TH2* FC_PLL = Invert_PLL( FC_Plot ); Plot_Styled_Contour( FC_Plot, cont_num, fcconts, confs, outputdir, "FeldmanCousins Profile" ); //Plot_Styled_Contour( FC_PLL, cont_num, fcconts, confs, outputdir, "FeldmanCousins Profile PLL" ); //TString FC_Tuple_File( outputdir+ "FC_Tuple.root" ); //TFile* new_FC_Output = new TFile( FC_Tuple_File, "RECREATE" ); //FC_Output->Write(); Plot_Both( pllhist, FC_Plot, cont_num, fcconts, pllconts, confs, outputdir ); FC_Stats( FC_Output, param1string, param2string, rand_gen, outputdir ); if( new_FC_Output != NULL ) new_FC_Output->Close(); } return 0; }
//iteration code void iterate(TrkSettings s,int iter, int stepType, bool doCondor, bool testErrors = false) { float pt, eta, phi, weight, centPU, rmin, maxJetPt,trkStatus,pNRec,mpt,mtrkQual,nEv; TFile * histFile; std::string ifPP = ""; if(s.nPb==0) ifPP = "pp_"; if(iter==0) histFile = TFile::Open(Form("%scorrHists_job%d.root",ifPP.c_str(),s.job),"recreate"); else histFile = TFile::Open(Form("%scorrHists_job%d.root",ifPP.c_str(),s.job),"update"); //make needed gen skim if it hasn't been done yet if(iter==0) { TH1D *genPre[20], *mrecoPre[20]; TH2D *genPre2[20], *mrecoPre2[20]; std::cout << "Denominator info not yet calculated; calculating and saving it..." << std::endl; for(int i = 0; i<8; i++) { if(i==6) continue; if(i != 1 && i!=7) { genPre[i] = makeTH1(s,i,"gen"); mrecoPre[i] = makeTH1(s,i,"mreco"); } else { genPre2[i] = makeTH2(s,i,"gen"); mrecoPre2[i]= makeTH2(s,i,"mreco"); } } TFile * skim; if(doCondor) { if(s.reuseSkim) skim = TFile::Open(Form("/mnt/hadoop/cms/store/user/abaty/tracking_Efficiencies/ntuples/%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); else skim = TFile::Open(Form("%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); } else skim = TFile::Open(Form("/export/d00/scratch/abaty/trackingEff/ntuples/%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); //for efficiency std::cout << "Doing Efficiency denominator" << std::endl; TNtuple * gen = (TNtuple*) skim->Get("Gen"); gen->SetBranchAddress("genPt",&pt); gen->SetBranchAddress("genEta",&eta); gen->SetBranchAddress("genPhi",&phi); gen->SetBranchAddress("weight",&weight); gen->SetBranchAddress("centPU",¢PU); gen->SetBranchAddress("rmin",&rmin); gen->SetBranchAddress("jtpt",&maxJetPt); gen->SetBranchAddress("pNRec",&pNRec); gen->SetBranchAddress("nEv",&nEv); for(int i = 0; i<gen->GetEntries(); i++) { gen->GetEntry(i); if(s.doSplit && nEv==1) continue; genPre[0]->Fill(pt,weight); genPre2[1]->Fill(eta,phi,weight); genPre[2]->Fill(centPU,weight); genPre[3]->Fill(maxJetPt,weight); genPre[4]->Fill(eta,weight); genPre[5]->Fill(rmin,weight); genPre2[7]->Fill(eta,pt,weight); } //for fake std::cout << "Doing Fake denominator" << std::endl; TNtuple * reco = (TNtuple*) skim->Get("Reco"); reco->SetBranchAddress("trkPt",&pt); reco->SetBranchAddress("trkEta",&eta); reco->SetBranchAddress("trkPhi",&phi); reco->SetBranchAddress("weight",&weight); reco->SetBranchAddress("centPU",¢PU); reco->SetBranchAddress("rmin",&rmin); reco->SetBranchAddress("jtpt",&maxJetPt); reco->SetBranchAddress("trkStatus",&trkStatus); reco->SetBranchAddress("nEv",&nEv); for(int i = 0; i<reco->GetEntries(); i++) { reco->GetEntry(i); if(s.doSplit && nEv==1) continue; if(trkStatus<-100) continue; mrecoPre[0]->Fill(pt,weight); mrecoPre2[1]->Fill(eta,phi,weight); mrecoPre[2]->Fill(centPU,weight); mrecoPre[3]->Fill(maxJetPt,weight); mrecoPre[4]->Fill(eta,weight); mrecoPre[5]->Fill(rmin,weight); mrecoPre2[7]->Fill(eta,pt,weight); } //Secondary calculation (no iterations) std::cout << "Quickly calculating the Secondary Rate from the reco tree (No further iterations needed)" << std::endl; TH2D * Secondary_Matched = new TH2D("Secondary_Matched",";pt;",s.multiRecoBins.at(s.job/s.nPtBinCoarse),s.ptMin,s.ptMax,24,-2.4,2.4); TH2D * Secondary_Secondaries = new TH2D("Secondary_Secondaries",";pt;",s.multiRecoBins.at(s.job/s.nPtBinCoarse),s.ptMin,s.ptMax,24,-2.4,2.4); for(int i = 0; i<reco->GetEntries(); i++) { reco->GetEntry(i); if(s.doSplit && nEv==1) continue; if(trkStatus>-100) { Secondary_Matched->Fill(pt,eta,weight); if(trkStatus==-99) Secondary_Secondaries->Fill(pt,eta,weight); } } TH2D * Secondary = (TH2D*)Secondary_Secondaries->Clone("SecondaryRate"); Secondary->Divide(Secondary_Matched); Secondary->SetDirectory(histFile); Secondary_Matched->SetDirectory(histFile); Secondary_Secondaries->SetDirectory(histFile); //end Secondary Reco calculation //multiReco calculation (no iterations) std::cout << "Quickly calculating the Multiple Reconstruction Rate from the gen tree (No further iterations needed)" << std::endl; TH1D * MultiGen = new TH1D("MultiGen",";pt;",s.multiRecoBins.at(s.job/s.nPtBinCoarse),s.ptMin,s.ptMax); TH1D * MultiReco = new TH1D("MultiMatchedReco",";pt;",s.multiRecoBins.at(s.job/s.nPtBinCoarse),s.ptMin,s.ptMax); for(int i = 0; i<gen->GetEntries(); i++) { gen->GetEntry(i); if(s.doSplit && nEv==1) continue; if(pNRec>-1) { MultiGen->Fill(pt,weight); if(pNRec>1) MultiReco->Fill(pt,(pNRec-1)*weight); } } TH1D * Multi = (TH1D*)MultiReco->Clone("MultipleRecoRate"); Multi->Divide(MultiGen); Multi->SetDirectory(histFile); MultiReco->SetDirectory(histFile); MultiGen->SetDirectory(histFile); //end Multiple Reco calculation skim->Close(); histFile->Write(); } //redundant for first step, but needed if the gen file was made and saved previously std::cout << "Loading appropriate information for denominator (gen for efficiency, reco for fake)..." << std::endl; TH1D * genHist[20], *recoHist[20]; TH2D * genHist2[20], *recoHist2[20]; genHist[0] = (TH1D*)histFile->Get("gen_pt"); genHist2[1] = (TH2D*)histFile->Get("gen_accept"); genHist[2] = (TH1D*)histFile->Get("gen_centPU"); genHist[3] = (TH1D*)histFile->Get("gen_maxJetPt"); genHist[4] = (TH1D*)histFile->Get("gen_eta"); genHist[5] = (TH1D*)histFile->Get("gen_rmin"); genHist2[7] = (TH2D*)histFile->Get("gen_etaPt"); std::cout << "Efficiency denominator histogram available now." << std::endl; recoHist[0] = (TH1D*)histFile->Get("mreco_pt"); recoHist2[1] = (TH2D*)histFile->Get("mreco_accept"); recoHist[2] = (TH1D*)histFile->Get("mreco_centPU"); recoHist[3] = (TH1D*)histFile->Get("mreco_maxJetPt"); recoHist[4] = (TH1D*)histFile->Get("mreco_eta"); recoHist[5] = (TH1D*)histFile->Get("mreco_rmin"); recoHist2[7] = (TH2D*)histFile->Get("mreco_etaPt"); std::cout << "Fake denominator histogram available now." << std::endl; //************************************************************************************************************ std::cout << "Calculating numerator for efficiency/fake calculation..." << std::endl; TH1D *mrecoHist, *divHist, *frecoHist, *fdivHist; TH2D *mrecoHist2,*divHist2, *frecoHist2, *fdivHist2; //getting old eff histograms to calculate the updated efficiency (the number 30 is arbitrary, increase if more are needed) TH1D * previousEff[30], *previousFake[30]; TH2D * previousEff2[30], *previousFake2[30]; for(int i=0; i<iter; i++) { int type = s.stepOrder.at(i%s.nStep); if(type==0 || type==2 || type==3 || type==4 || type==5) { previousEff[i] = (TH1D*)histFile->Get(Form("eff_step%d",i)); previousFake[i] = (TH1D*)histFile->Get(Form("fake_step%d",i)); } if(type==1 || type==7) { previousEff2[i] = (TH2D*)histFile->Get(Form("eff_step%d",i)); previousFake2[i] = (TH2D*)histFile->Get(Form("fake_step%d",i)); } } //setting up stuff for reading out of skim TH1D * mrecoErr; TH1D * mrecoW; TH2D * mrecoErr2; TH2D * mrecoW2; if(stepType == 0 || stepType==2 || stepType==3 || stepType==4 || stepType==5) { mrecoHist = makeTH1(s,stepType,Form("mreco_eff_step%d",iter)); frecoHist = makeTH1(s,stepType,Form("reco_fake_step%d",iter)); if(testErrors) { mrecoErr = (TH1D*)mrecoHist->Clone("mrecoErr"); mrecoW = (TH1D*)mrecoHist->Clone("mrecoW"); } } if(stepType == 1 || stepType == 7) { mrecoHist2 = makeTH2(s,stepType,Form("mreco_eff_step%d",iter)); frecoHist2 = makeTH2(s,stepType,Form("reco_fake_step%d",iter)); if(testErrors) { mrecoErr2 = (TH2D*)mrecoHist2->Clone("mrecoErr"); mrecoW2 = (TH2D*)mrecoHist2->Clone("mrecoW"); } } TFile * skim; if(doCondor) { if(s.reuseSkim) skim = TFile::Open(Form("/mnt/hadoop/cms/store/user/abaty/tracking_Efficiencies/ntuples/%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); else skim = TFile::Open(Form("%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); } else skim = TFile::Open(Form("/export/d00/scratch/abaty/trackingEff/ntuples/%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); TNtuple * reco = (TNtuple*) skim->Get("Reco"); reco->SetBranchAddress("trkPt",&pt); reco->SetBranchAddress("trkEta",&eta); reco->SetBranchAddress("trkPhi",&phi); reco->SetBranchAddress("weight",&weight); reco->SetBranchAddress("centPU",¢PU); reco->SetBranchAddress("rmin",&rmin); reco->SetBranchAddress("jtpt",&maxJetPt); reco->SetBranchAddress("trkStatus",&trkStatus); reco->SetBranchAddress("nEv",&nEv); //reading out of skim for(int i = 0; i<reco->GetEntries(); i++) { //applying efficiencies from all previous steps float previousFakeCorr = 1; reco->GetEntry(i); if(s.doSplit && nEv==1) continue; //fake part if(iter!=0) { for(int n = 0; n<iter; n++) { int type = s.stepOrder.at(n%s.nStep); if(type==0) previousFakeCorr *= previousFake[n]->GetBinContent(previousFake[n]->FindBin(pt)); if(type==1) previousFakeCorr *= previousFake2[n]->GetBinContent(previousFake2[n]->GetXaxis()->FindBin(eta),previousFake2[n]->GetYaxis()->FindBin(phi)); if(type==2) previousFakeCorr *= previousFake[n]->GetBinContent(previousFake[n]->FindBin(centPU)); if(type==3) previousFakeCorr *= previousFake[n]->GetBinContent(previousFake[n]->FindBin(maxJetPt)); if(type==4) previousFakeCorr *= previousFake[n]->GetBinContent(previousFake[n]->FindBin(eta)); if(type==5) previousFakeCorr *= previousFake[n]->GetBinContent(previousFake[n]->FindBin(rmin)); if(type==7) previousFakeCorr *= previousFake2[n]->GetBinContent(previousFake2[n]->GetXaxis()->FindBin(eta),previousFake2[n]->GetYaxis()->FindBin(pt)); } } if(previousFakeCorr==0) std::cout << "\nWarning!!! A correction is going to infinity. This usually indicates an empty bin somewhere, try using a coarser binning or more events! \n" << std::endl; //filling histograms if(stepType==0) frecoHist->Fill(pt,weight/previousFakeCorr); if(stepType==1) frecoHist2->Fill(eta,phi,weight/previousFakeCorr); if(stepType==2) frecoHist->Fill(centPU,weight/previousFakeCorr); if(stepType==3) frecoHist->Fill(maxJetPt,weight/previousFakeCorr); if(stepType==4) frecoHist->Fill(eta,weight/previousFakeCorr); if(stepType==5) frecoHist->Fill(rmin,weight/previousFakeCorr); if(stepType==7) frecoHist2->Fill(eta,pt,weight/previousFakeCorr); } //eff part TNtuple * gen = (TNtuple*) skim->Get("Gen"); gen->SetBranchAddress("genPt",&pt); gen->SetBranchAddress("genEta",&eta); gen->SetBranchAddress("genPhi",&phi); gen->SetBranchAddress("weight",&weight); gen->SetBranchAddress("centPU",¢PU); gen->SetBranchAddress("rmin",&rmin); gen->SetBranchAddress("jtpt",&maxJetPt); gen->SetBranchAddress("pNRec",&pNRec); gen->SetBranchAddress("mtrkPt",&mpt); gen->SetBranchAddress("mtrkQual",&mtrkQual); gen->SetBranchAddress("nEv",&nEv); //reading out of skim for(int i = 0; i<gen->GetEntries(); i++) { //applying efficiencies from all previous steps float previousEffCorr = 1; float previousEffCorrErr = 0; gen->GetEntry(i); if(s.doSplit && nEv==1) continue; if(mtrkQual<1|| mpt<=0) continue; if(iter!=0) { for(int n = 0; n<iter; n++)//calculating current efficiency correction { int type = s.stepOrder.at(n%s.nStep); if(type==0){ previousEffCorr *= previousEff[n]->GetBinContent(previousEff[n]->FindBin(pt)); if(testErrors) previousEffCorrErr += TMath::Power(previousEff[n]->GetBinError(previousEff[n]->FindBin(pt))/previousEff[n]->GetBinContent(previousEff[n]->FindBin(pt)),2); } if(type==1){ previousEffCorr *= previousEff2[n]->GetBinContent(previousEff2[n]->GetXaxis()->FindBin(eta),previousEff2[n]->GetYaxis()->FindBin(phi)); if(testErrors) previousEffCorrErr += TMath::Power(previousEff2[n]->GetBinError(previousEff2[n]->GetXaxis()->FindBin(eta),previousEff2[n]->GetYaxis()->FindBin(phi))/previousEff2[n]->GetBinContent(previousEff2[n]->GetXaxis()->FindBin(eta),previousEff2[n]->GetYaxis()->FindBin(phi)),2); } if(type==2){ previousEffCorr *= previousEff[n]->GetBinContent(previousEff[n]->FindBin(centPU)); if(testErrors) previousEffCorrErr += TMath::Power(previousEff[n]->GetBinError(previousEff[n]->FindBin(centPU))/previousEff[n]->GetBinContent(previousEff[n]->FindBin(centPU)),2); } if(type==3){ previousEffCorr *= previousEff[n]->GetBinContent(previousEff[n]->FindBin(maxJetPt)); if(testErrors) previousEffCorrErr += TMath::Power(previousEff[n]->GetBinError(previousEff[n]->FindBin(maxJetPt))/previousEff[n]->GetBinContent(previousEff[n]->FindBin(maxJetPt)),2); } if(type==4){ previousEffCorr *= previousEff[n]->GetBinContent(previousEff[n]->FindBin(eta)); if(testErrors) previousEffCorrErr += TMath::Power(previousEff[n]->GetBinError(previousEff[n]->FindBin(eta))/previousEff[n]->GetBinContent(previousEff[n]->FindBin(eta)),2); } if(type==5){ previousEffCorr *= previousEff[n]->GetBinContent(previousEff[n]->FindBin(rmin)); if(testErrors) previousEffCorrErr += TMath::Power(previousEff[n]->GetBinError(previousEff[n]->FindBin(rmin))/previousEff[n]->GetBinContent(previousEff[n]->FindBin(rmin)),2); } if(type==7){ previousEffCorr *= previousEff2[n]->GetBinContent(previousEff2[n]->GetXaxis()->FindBin(eta),previousEff2[n]->GetYaxis()->FindBin(pt)); if(testErrors) previousEffCorrErr += TMath::Power(previousEff2[n]->GetBinError(previousEff2[n]->GetXaxis()->FindBin(eta),previousEff2[n]->GetYaxis()->FindBin(pt))/previousEff2[n]->GetBinContent(previousEff2[n]->GetXaxis()->FindBin(eta),previousEff2[n]->GetYaxis()->FindBin(pt)),2); } } if(testErrors) previousEffCorrErr = previousEffCorrErr/TMath::Power(previousEffCorr,2); } if(previousEffCorr==0) std::cout << "\nWarning!!! A correction is going to infinity. This usually indicates an empty bin somewhere, try using a coarser binning or more events! \n" << std::endl; //filling histograms float var1, var2; if(stepType==0) var1 = pt; if(stepType==1){var1 = eta; var2 = phi;} if(stepType==2) var1 = centPU; if(stepType==3) var1 = maxJetPt; if(stepType==4) var1 = eta; if(stepType==5) var1 = rmin; if(stepType==7){var1 = eta; var2 = pt;} if(stepType!=1 && stepType!=7){ mrecoHist->Fill(var1,weight/previousEffCorr); if(testErrors){ mrecoErr->Fill(var1,weight*weight*previousEffCorrErr); mrecoW->Fill(var1,weight); } } else{ mrecoHist2->Fill(var1,var2,weight/previousEffCorr); if(testErrors){ mrecoErr2->Fill(var1,var2,weight*weight*previousEffCorrErr); mrecoW2->Fill(var1,var2,weight); } } } skim->Close(); //saving reco and efficiencies/fake rates std::cout << "Calculating updated Efficiency/Fake Rate and saving histograms" << std::endl; histFile->cd(); if(stepType==0 || stepType == 2 || stepType == 3 || stepType==4 || stepType==5) { if(testErrors) { mrecoErr->Divide(mrecoW); mrecoErr->Divide(mrecoW); for(int i = 1 ; i<mrecoErr->GetSize()-1; i++) mrecoHist->SetBinError(i,TMath::Power(mrecoErr->GetBinContent(i),0.5)); } divHist = (TH1D*)mrecoHist->Clone(Form("eff_step%d",iter)); divHist->Divide(genHist[stepType]); mrecoHist->Write(); divHist->Write(); fdivHist = (TH1D*)frecoHist->Clone(Form("fake_step%d",iter)); fdivHist->Divide(recoHist[stepType]); frecoHist->Write(); fdivHist->Write(); } if(stepType==1 || stepType==7) { if(testErrors) { mrecoErr2->Divide(mrecoW2); mrecoErr2->Divide(mrecoW2); for(int i = 1 ; i<mrecoErr2->GetNbinsX()+1; i++) for(int j = 1; j<mrecoErr2->GetNbinsY()+1; j++) mrecoHist2->SetBinError(i,j,TMath::Power(mrecoErr2->GetBinContent(i,j),0.5)); } divHist2 = (TH2D*)mrecoHist2->Clone(Form("eff_step%d",iter)); divHist2->Divide(genHist2[stepType]); mrecoHist2->Write(); divHist2->Write(); fdivHist2 = (TH2D*)frecoHist2->Clone(Form("fake_step%d",iter)); fdivHist2->Divide(recoHist2[stepType]); frecoHist2->Write(); fdivHist2->Write(); } //********************************************************************************************* //********************************************************************************************* //Only executed on last step before exiting program if(iter>=s.nStep*s.fullIterations && s.terminateStep==stepType) { //writing final correction tables (consolidating multiple steps of the same variable) //once again 10 is an arbitrary number, increase if needed... std::cout << "Consolidating into final histograms by multiplying out efficiencies/fake rates per variable" << std::endl; TH1D * finalEff[10], *finalFake[10]; TH2D * finalEff2[10], *finalFake2[10]; for(int i=0; i<s.nStep; i++) { int type = s.stepOrder.at(i%s.nStep); if(type == 0 || type==2 || type==3 || type==4 || type==5) { finalEff[i] = (TH1D*)previousEff[i]->Clone(Form("finalEff_type%d",i)); finalFake[i] = (TH1D*)previousFake[i]->Clone(Form("finalFake_type%d",i)); } if(type == 1 || type==7) { finalEff2[i] = (TH2D*)previousEff2[i]->Clone(Form("finalEff_type%d",i)); finalFake2[i] = (TH2D*)previousFake2[i]->Clone(Form("finalFake_type%d",i)); } } for(int n = s.nStep; n<iter; n++) { int type2 = s.stepOrder.at(n%s.nStep); if(type2==0 || type2==2 || type2==3 || type2==4 || type2==5) { finalEff[n%s.nStep]->Multiply(previousEff[n]); finalFake[n%s.nStep]->Multiply(previousFake[n]); } if(type2==1 || type2==7) { finalEff2[n%s.nStep]->Multiply(previousEff2[n]); finalFake2[n%s.nStep]->Multiply(previousFake2[n]); } } if(stepType == 0 || stepType==2 || stepType==3 || stepType==4 || stepType==5) { finalEff[iter%s.nStep]->Multiply((TH1D*)histFile->Get(Form("eff_step%d",iter))); finalFake[iter%s.nStep]->Multiply((TH1D*)histFile->Get(Form("fake_step%d",iter))); } if(stepType == 1 || stepType == 7) { finalEff2[iter%s.nStep]->Multiply((TH2D*)histFile->Get(Form("eff_step%d",iter))); finalFake2[iter%s.nStep]->Multiply((TH2D*)histFile->Get(Form("fake_step%d",iter))); } for(int i=0; i<s.nStep; i++) { int type = s.stepOrder.at(i%s.nStep); if(type == 0 || type==2 || type==3 || type==4 || type == 5){ finalEff[i]->Write(); finalFake[i]->Write();} if(type == 1 || type == 7){ finalEff2[i]->Write(); finalFake2[i]->Write();} } //******************************************************************************************************* //writing calculating final closures in each variable checked after applying corrections std::cout << "Calculating Final Closures..." << std::endl; TH1D * finalEffClosure[10], *finalFakeClosure[10]; TH2D * finalEffClosure2[10], *finalFakeClosure2[10]; for(int i=0; i<8; i++) { int type = i; if(type==0 || type==2 || type==3 || type==4 || type==5) { finalEffClosure[i] = (TH1D*)genHist[i]->Clone(Form("finalEffClosure_var%d",i)); finalFakeClosure[i] = (TH1D*)recoHist[i]->Clone(Form("finalFakeClosure_var%d",i)); finalEffClosure[i]->Reset(); finalFakeClosure[i]->Reset(); } if(type==1 || type==7) { finalEffClosure2[i] = (TH2D*)genHist2[i]->Clone(Form("finalEffClosure_var%d",i)); finalFakeClosure2[i] = (TH2D*)recoHist2[i]->Clone(Form("finalFakeClosure_var%d",i)); finalEffClosure2[i]->Reset(); finalFakeClosure2[i]->Reset(); } } if(doCondor) { if(s.reuseSkim) skim = TFile::Open(Form("/mnt/hadoop/cms/store/user/abaty/tracking_Efficiencies/ntuples/%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); else skim = TFile::Open(Form("%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); } else skim = TFile::Open(Form("/export/d00/scratch/abaty/trackingEff/ntuples/%strackSkim_job%d.root",ifPP.c_str(),s.job),"read"); reco = (TNtuple*) skim->Get("Reco"); reco->SetBranchAddress("trkPt",&pt); reco->SetBranchAddress("trkEta",&eta); reco->SetBranchAddress("trkPhi",&phi); reco->SetBranchAddress("weight",&weight); reco->SetBranchAddress("centPU",¢PU); reco->SetBranchAddress("rmin",&rmin); reco->SetBranchAddress("jtpt",&maxJetPt); reco->SetBranchAddress("trkStatus",&trkStatus); reco->SetBranchAddress("nEv",&nEv); //reading out of skim for(int i = 0; i<reco->GetEntries(); i++) { //applying efficiencies from all previous steps float previousFakeCorr = 1; reco->GetEntry(i); if(s.doSplit && nEv==1) continue; for(int n=0; n<s.nStep; n++)//getting correction { int type = s.stepOrder.at(n%s.nStep); if(type==0) previousFakeCorr *= finalFake[n]->GetBinContent(finalFake[n]->FindBin(pt)); if(type==1) previousFakeCorr *= finalFake2[n]->GetBinContent(finalFake2[n]->GetXaxis()->FindBin(eta),finalFake2[n]->GetYaxis()->FindBin(phi)); if(type==2) previousFakeCorr *= finalFake[n]->GetBinContent(finalFake[n]->FindBin(centPU)); if(type==3) previousFakeCorr *= finalFake[n]->GetBinContent(finalFake[n]->FindBin(maxJetPt)); if(type==4) previousFakeCorr *= finalFake[n]->GetBinContent(finalFake[n]->FindBin(eta)); if(type==5) previousFakeCorr *= finalFake[n]->GetBinContent(finalFake[n]->FindBin(rmin)); if(type==7) previousFakeCorr *= finalFake2[n]->GetBinContent(finalFake2[n]->GetXaxis()->FindBin(eta),finalFake2[n]->GetYaxis()->FindBin(pt)); } if(previousFakeCorr<1) previousFakeCorr==1; finalFakeClosure[0]->Fill(pt,weight/previousFakeCorr); finalFakeClosure2[1]->Fill(eta,phi,weight/previousFakeCorr); finalFakeClosure[2]->Fill(centPU,weight/previousFakeCorr); finalFakeClosure[3]->Fill(maxJetPt,weight/previousFakeCorr); finalFakeClosure[4]->Fill(eta,weight/previousFakeCorr); finalFakeClosure[5]->Fill(rmin,weight/previousFakeCorr); finalFakeClosure2[7]->Fill(eta,pt,weight/previousFakeCorr); } gen = (TNtuple*) skim->Get("Gen"); gen->SetBranchAddress("genPt",&pt); gen->SetBranchAddress("genEta",&eta); gen->SetBranchAddress("genPhi",&phi); gen->SetBranchAddress("weight",&weight); gen->SetBranchAddress("centPU",¢PU); gen->SetBranchAddress("rmin",&rmin); gen->SetBranchAddress("jtpt",&maxJetPt); gen->SetBranchAddress("pNRec",&pNRec); gen->SetBranchAddress("mtrkPt",&mpt); gen->SetBranchAddress("mtrkQual",&mtrkQual); gen->SetBranchAddress("nEv",&nEv); //reading out of skim for(int i = 0; i<gen->GetEntries(); i++) { //applying efficiencies from all previous steps float previousEffCorr = 1; gen->GetEntry(i); if(s.doSplit && nEv==1) continue; if(mtrkQual<1 || mpt<=0) continue; for(int n=0; n<s.nStep; n++)//getting correction { int type = s.stepOrder.at(n%s.nStep); if(type==0) previousEffCorr *= finalEff[n]->GetBinContent(finalEff[n]->FindBin(pt)); if(type==1) previousEffCorr *= finalEff2[n]->GetBinContent(finalEff2[n]->GetXaxis()->FindBin(eta),finalEff2[n]->GetYaxis()->FindBin(phi)); if(type==2) previousEffCorr *= finalEff[n]->GetBinContent(finalEff[n]->FindBin(centPU)); if(type==3) previousEffCorr *= finalEff[n]->GetBinContent(finalEff[n]->FindBin(maxJetPt)); if(type==4) previousEffCorr *= finalEff[n]->GetBinContent(finalEff[n]->FindBin(eta)); if(type==5) previousEffCorr *= finalEff[n]->GetBinContent(finalEff[n]->FindBin(rmin)); if(type==7) previousEffCorr *= finalEff2[n]->GetBinContent(finalEff2[n]->GetXaxis()->FindBin(eta), finalEff2[n]->GetYaxis()->FindBin(pt)); } if(previousEffCorr>1) previousEffCorr==1; finalEffClosure[0]->Fill(pt,weight/previousEffCorr); finalEffClosure2[1]->Fill(eta,phi,weight/previousEffCorr); finalEffClosure[2]->Fill(centPU,weight/previousEffCorr); finalEffClosure[3]->Fill(maxJetPt,weight/previousEffCorr); finalEffClosure[4]->Fill(eta,weight/previousEffCorr); finalEffClosure[5]->Fill(rmin,weight/previousEffCorr); finalEffClosure2[7]->Fill(eta,pt,weight/previousEffCorr); } histFile->cd(); for(int i=0; i<8; i++) { if(i==6) continue; if(i!=1 && i!=7) { finalFakeClosure[i]->Divide(recoHist[i]); finalEffClosure[i]->Divide(genHist[i]); finalFakeClosure[i]->Write(); finalEffClosure[i]->Write(); } else { finalFakeClosure2[i]->Divide(recoHist2[i]); finalEffClosure2[i]->Divide(genHist2[i]); finalFakeClosure2[i]->Write(); finalEffClosure2[i]->Write(); } } std::cout << "Calculating Final Closures..." << std::endl; } histFile->Close(); std::cout << "Finished with iteration \n" << std::endl; return; }
float n3HeSim(int nev_=0, float rfsf_phi_=300, int sev=0) { // commandline option '-var=val' to change any global for (int i=1; i<gApplication->Argc(); ++i) { TString opt(gApplication->Argv(i)); if ((opt[0]=='-' || opt[0]=='+') && opt.Contains("=")) gROOT->ProcessLine(opt=opt.Append(";").Strip(TString::kLeading,'-')); } if (nev_) nev = nev_; if (rfsf_phi_!=0) rfsf_phi=rfsf_phi_/360.; TFile* f = new TFile("/home/siplu/GIT/n3He_Soft/Github/Simulation/data/mcstas.root"); TNtuple* ntp = (TNtuple*)f->Get("mcstas"); // set up ntuple BRANCH(l); BRANCH(pol); BRANCH(p5); BRANCH(p6); BRANCH(t6); BRANCH(x6); BRANCH(y6); BRANCH(vx6); BRANCH(vy6); BRANCH(vz6); float chop[4]; TBranch* b_chop[4]; for (int j=0;j<nch;++j) { b_chop[j]=ntp->GetBranch(vch[j]); ntp->SetBranchAddress(vch[j],&chop[j]); } // precalculate track projections float dwc = lwc/nz; // WC parameters float da = 2./na, a0=-1+da/2; // polar [cos(theta)] integration float db = 2*PI/nb, b0=-PI+db/2; // azimuthal [phi] integration float cxyz[3], &cx=cxyz[0],&cy=cxyz[1],&cz=cxyz[2]; // projection cosines float ccz[NDIV], ccx[NDIV][NDIV], ccy[NDIV][NDIV], as; // cached values float aa=a0; for (int ia=0; ia<na; ++ia, aa+=da) { ccz[ia]=aa; if (ccz[ia]==0) ccz[ia]=1e-11; as=sqrt(1-aa*aa); float bb=b0; for (int ib=0; ib<nb; ++ib, bb+=db) { ccx[ia][ib]=as*cos(bb); if (ccx[ia][ib]==0) ccx[ia][ib]=1e-11; ccy[ia][ib]=as*sin(bb); if (ccy[ia][ib]==0) ccy[ia][ib]=1e-11; } } // cumulative beta distribution for (int i=0;i<nbet;++i) beta_int[i+1]=beta_int[i]+beta_pt[i]; // initialize WC response matrices double n5 = 0; // pre-polarizer neutrons double N[NTOF]={0}; // chopped neutrons at end of SMpol double P2N[NTOF]={0}; // " * P^2 double WN[NTOF]={0}; // captures in 3He target double BN[NTOF][nwc]={{0}}; // N_i = N beta_i = \sum{n_i} ions double GBN[NTOF][nwc]={{0}}; // M_i = N_i gamma_i = \sum{n_i gamma} double D2N[NTOF][nwc][nwc]={{{0}}}; // delta^2 N_ij = covariance double GW[NTOF][nwc]={{0}}; // weight of each element // loop over events, fill "n","p2n" histograms, wc response matrices if (ntp->GetEntries()<nev) nev=ntp->GetEntries(); for (int iev=sev;iev<sev+nev;++iev) { if (verbose && cnt) { // :........:.... if (iev%(50*cnt)==0) cout<<endl<<" :"<<flush; else if (iev%(10*cnt)==0) cout<<":"<<flush; else if (iev%cnt==0) cout<<"."<<flush; } // read variables ntp->GetEntry(iev); hl5.Fill(l,p5*1.4/2*60); n5 += p5; hl6.Fill(l,p6*1.4/2*60); // polarizer float tx = 1; //Transmission b_pol->GetEntry(iev); if (pol!=pol) pol=0; //nan // choppers for (int j=0;j<nch;++j) { float chw = chop[j]-ch_phi[j]; if (chw<0) chw += 360; if (chw>ch_open[j]) { tx=0; break; } } if (tx==0) continue; hlc.Fill(l,p6*1.4/2*60); // RFSF, averaged over spin sequence float t_sf = (t6+(zsf-z6)/vz6)*freq; static const float spin_seq_ave[]={1, -0.5, 0, 0.5, -1, 0.5, 0, -0.5}; if (psf==1 && (t_sf<rfsf_phi || t_sf>rfsf_phi+dsf)) continue; if (t_sf!=0) { if (dsf<0) { pol*= spin_seq_ave[int(fabs(t_sf-rfsf_phi-0.5)+0.5)%8]; pol*=(1-cos(k_rfsf/vz6/(fmod(t_sf-rfsf_phi+10,1)+rfsf_phi)))/2.; } else { if (t_sf<rfsf_phi || t_sf>rfsf_phi+dsf) pol*=psf; } } hls.Fill(l,p6*1.4/2*60); // fill histograms for N,P2N float dtev=(zwc-z6)/vz6, tev=fmod((t6+dtev)*freq, 1); int it((tev*ntof+1)-1); assert(it>=0 && it<ntof); float n = p6 * tx; N [it] += n; P2N[it] += n * pol*pol; // collimator float xx=x6+vx6*(zwc-z6)/vz6; if (xcol>0 && fabs(xx)>xcol/2) continue; float yy=y6+vy6*(zwc-z6)/vz6; if (ycol>0 && fabs(yy)>ycol/2) continue; hlx.Fill(l,p6*1.4/2*60); // simulate ion chamber response float zev=dwc/2.; for (int iz=0; iz<nz; ++iz, zev+=dwc) { dtev=(zev+zwc-z6)/vz6; tev=fmod((t6+dtev)*freq, 1); it = int(tev*ntof+1)-1; assert(it>=0 && it<ntof); float xev=x6+vx6*dtev, yev=y6+vy6*dtev; float rhosig=rho3*ksig*l; // attenuation const and weight float wza = (exp(-rhosig*zev)-exp(-rhosig*(zev+dwc)))*da/2*db/2/PI; for (int ia=0; ia<na; ++ia) { cz=ccz[ia]; for (int ib=0; ib<nb; ++ib) { cx=ccx[ia][ib]; cy=ccy[ia][ib]; float d1=d1r, d2=d2r, d1t,d2t; // ionization range // restrict ionization to active volume of wc if (cz>0) d1t=(z1w-zev)/cz, d2t=(z2w-zev)/cz; else d1t=(z2w-zev)/cz, d2t=(z1w-zev)/cz; if (d1<d1t) d1=d1t; if (d2>d2t) d2=d2t; if (cx>0) d1t=(x1w-xev)/cx, d2t=(x2w-xev)/cx; else d1t=(x2w-xev)/cx, d2t=(x1w-xev)/cx; if (d1<d1t) d1=d1t; if (d2>d2t) d2=d2t; if (cy>0) d1t=(y1w-yev)/cy, d2t=(y2w-yev)/cy; else d1t=(y2w-yev)/cy, d2t=(y1w-yev)/cy; if (d1<d1t) d1=d1t; if (d2>d2t) d2=d2t; if (d2<d1) continue; // not in active volume // iterate over ionized cells float beta1, beta0=beta_fn(d1); float wz=(z0w-zev)/cz, dwz=dzw/cz; int jz((d1-wz)/dwz), djz=1; if (jz==nwz) --jz; wz+=dwz*jz; if (cz>0) wz+=dwz; else dwz*=-1, djz*=-1; float wx=(x0w-xev)/cx, dwx=dxw/cx; int jx((d1-wx)/dwx), djx=1; if (jx==nwx) --jx; wx+=dwx*jx; if (cx>0) wx+=dwx; else dwx*=-1, djx*=-1; int k=0; assert(0<=jz&&jz<nwz && 0<=jx&&jx<nwx); while (0<=jz&&jz<nwz && 0<=jx&&jx<nwx) { kzx[k] = jz*nwx + jx; if (d2<=wz && d2<=wx) { kbeta[k++]=beta_fn(d2)-beta0; break; } if (wz<wx) { beta1=beta_fn(wz); jz+=djz; d1=wz; wz+=dwz; } else { beta1=beta_fn(wx); jx+=djx; d1=wx; wx+=dwx; } kbeta[k++]=beta1-beta0; beta0=beta1; } // tabulate ion response WN[it] += n*wza; for (int i=0;i<k;++i) { float ni= n*wza*kbeta[i]; BN [it][kzx[i]] += ni; GBN[it][kzx[i]] += ni*cxyz[geom_xyz]; for (int j=0;j<k;++j) { D2N[it][kzx[i]][kzx[j]] += ni*kbeta[j]; } } } } } } f->Close(); // calculate FOM=p2n, projection; draw both double N_tot=0, P2N_tot=0, WN_tot=0, xd2a_tot=0; for (int it=0;it<ntof;++it) { TMatrixDSym mat(nwc, &**D2N[it]); if (verbose>3 && ntof==1) { cout<<"\n delta^2 N_ij :\n"; mat.Print(); } // for (int i=0;i<nwc;++i) for (int j=0;j<nwc;++j) if (i!=j) mat(i,j)=0; mat.Invert(); if (verbose>3 && ntof==1) { cout<<"\n delta^-2 N_ij :\n"; mat.Print(); } double xd2a=0; for (int i=0;i<nwc;++i) { for (int j=0;j<nwc;++j) { GW[it][i] += GBN[it][i]*GBN[it][j]*mat(i,j); } xd2a += GW[it][i]; } N_tot += N[it]; P2N_tot+= P2N[it]; WN_tot += WN[it]; xd2a_tot += xd2a; if (verbose > 2) { printf("\n beta_i:"); for (int i=0;i<nwc;++i) { if (!(i%nwx)) printf("\n "); printf(" %9.5g",BN[it][i]/N[it]); } printf("\n\n gamma_i:"); for (int i=0;i<nwc;++i) { if (!(i%nwx)) printf("\n "); printf(" %9.5g",GBN[it][i]/BN[it][i]); } printf("\n\n weight_i:"); for (int i=0;i<nwc;++i) { if (!(i%nwx)) printf("\n "); printf(" %9.5g",GW[it][i]); } printf("\n\n"); } if (verbose > 4) { printf("\n\n beta_i:"); for (int j=0;j<nwc;++j) { printf(" %9.5g",BN[it][j]/N[it]); } printf("\n\n beta_ij:"); for (int i=0;i<nwc;++i) { printf("\n "); for (int j=0;j<nwc;++j) { printf(" %9.5g", D2N[it][i][j]/N[it]); } } } if (verbose>1 && ntof>1) { cout<<" N = "<< N[it] <<endl; cout<<" <P^2> = "<< P2N[it] / N[it] <<endl; cout<<" <W> = "<< WN[it] / N[it] <<endl; cout<<" delta^-2 A = "<< xd2a*P2N[it]/N[it] <<endl; cout<<" sigma_d = "<< sqrt(N[it] / xd2a) <<endl<<endl<<endl; } } cout<<"All TOF bins combined"<<endl; cout<<" N0 = "<< n5 <<endl; cout<<" N = "<< N_tot <<endl; cout<<" <P^2> = "<< P2N_tot/N_tot <<endl; cout<<" <W> = "<< WN_tot / N_tot <<endl; cout<<" delta^-2 A = "<< xd2a_tot*P2N_tot/N_tot <<endl; cout<<" sigma_d = "<< sqrt(N_tot / xd2a_tot) <<endl; return sqrt(N_tot / xd2a_tot); }
void fragmentEnergyDistributionDifferentAngles() { gStyle->SetOptStat(0000000000); //remove the for this graphs totally redundant statbox // gROOT->SetStyle("clearRetro"); TString pDepth, fragment, Znum, normToOneAtZeroAngle; cout << "Enter phantom depth (eg. 27.9, see experimentalData directory for choices): "; cin >> pDepth; TString simulationDataPath = "IAEA_" + pDepth + ".root"; TString dir = gSystem->UnixPathName(gInterpreter->GetCurrentMacroName()); dir.ReplaceAll("basic.C",""); dir.ReplaceAll("/./","/"); ifstream in; in.open(Form("experimentalData/iaeaBenchmark/fragmentEnergySpctra279mmWater0deg.dat",dir.Data())); Float_t f1,f2,f3, f4,f5,f6; Int_t nlines = 0; TFile *f = new TFile("fragmentEnergyWithAngularDistribution.root","RECREATE"); TNtuple *ntuple = new TNtuple("ntuple","Data from ascii file","Energy:He:B:H:Li:Be"); Char_t DATAFLAG[4]; Int_t NDATA; Char_t n1[6], n2[2], n3[2], n4[2], n5[2], n6[2]; in >> DATAFLAG >> NDATA ; // Read EXFOR line: 'DATA 6' in >> n1 >> n2 >> n3 >> n4 >> n5 >> n6; // Read column titles: 'Energy He B [...]' cout <<n1<<" "<<n2<<" "<<n3<<" "<<n4<<" "<<n5<<" "<<n6<<"\n"; while (1) { in >> f1 >> f2 >> f3 >>f4 >> f5 >> f6; if (!in.good()) break; if (nlines < 500 ) printf("%f %0.2f %0.2f %0.2f %0.2f %0.2f \n",f1,f2,f3,f4,f5,f6); ntuple->Fill(f1,f2,f3,f4,f5,f6); nlines++; } //Let's pull in the simulation-data TFile *MCData = TFile::Open("IAEA_200000.root"); TNtuple *fragments = (TNtuple*) MCData->Get("fragmentNtuple"); //Block bellow pulls out the simulation's metadata from the metadata ntuple. TNtuple *metadata = (TNtuple*) MCData->Get("metaData"); Float_t events, detectorDistance,waterThickness,beamEnergy,energyError,phantomCenterDistance; metadata->SetBranchAddress("events",&events); metadata->SetBranchAddress("waterThickness",&waterThickness); metadata->SetBranchAddress("detectorDistance",&detectorDistance); metadata->SetBranchAddress("beamEnergy",&beamEnergy); metadata->SetBranchAddress("energyError",&energyError); metadata->SetBranchAddress("phantomCenterDistance",&phantomCenterDistance); metadata->GetEntry(0); //there is just one row to consider. //good to keep for ref. G4 might give weird units due to change. metadata->Scan(); std::cout << "Recieved metadata-row: " << events << " " << detectorDistance << " " << waterThickness << " " << beamEnergy << " " << energyError << " " << phantomCenterDistance; //A lot of hardcoded histograms, ugly Double_t binAmount = 50.0; //casting from int failed somehow, so in float temporarily, fixme Double_t maxEnergy = 450.0; Double_t binWidth = maxEnergy / binAmount; TH1F *hist1 = new TH1F("hist1", "", binAmount, 0.0, maxEnergy); TH1F *hist2 = new TH1F("hist2", "", binAmount, 0.0, maxEnergy); TH1F *hist3 = new TH1F("hist3", "", binAmount, 0.0, maxEnergy); TH1F *hist4 = new TH1F("hist4", "", binAmount, 0.0, maxEnergy); TH1F *hist5 = new TH1F("hist5", "", binAmount, 0.0, maxEnergy); TH1F *hist6 = new TH1F("hist6", "", binAmount, 0.0, maxEnergy); TH1F *hist7 = new TH1F("hist7", "", binAmount, 0.0, maxEnergy); TH1F *hist8 = new TH1F("hist8", "", binAmount, 0.0, maxEnergy); TH1F *hist9 = new TH1F("hist9", "", binAmount, 0.0, maxEnergy); for(int k = 1; k <= 6; k++){ TString Znum = Form("%i", k); hist1->SetTitle("Z=" + Znum); //ALL UNITS ARE cm! Double_t detectorSideLength = 4; //40mm, as e.haettner H1 detector Double_t scatteringDistance = detectorDistance - phantomCenterDistance; //temporarily hard-coded, should be distance from target-center to detector Double_t degrees; //< actually radians Double_t r, rMin, rMax, deltaOmega, normFloat; TString rMinString, rMaxString, normString; TString same = ""; TString histName; TCanvas *c3 = new TCanvas("histograms", "Distribution (at different angles)"); int i = 0; //so that the degree steps can be varied to unevenly spaced values separate counter is used std::cout << "The following numbers also make it possible to make number of fragments comparison to the graph in A1 of E.Haettner\n"; for(Double_t j = 0.0; j <= 8.0; j=j+1.0){ i++; degrees = j * TMath::DegToRad(); //std::cout << "plotting for Z = " << Znum << " at " << j << " degrees\n"; //Distance from straight beam at the requested angle r = scatteringDistance * TMath::Tan(degrees); //now the "detector is rotated around all possible perpendicularlynangle values to beamline". //This forms an annulus with rMin and RMax as otuer and inner radiuses //Notice this will give a bit of approximation at small angles where at 0 degrees this gives a round sensor. Double_t deltaPhi = TMath::ATan((TMath::Cos(degrees)*detectorSideLength)/(2*scatteringDistance)); rMin = TMath::Max(0.0,r - (detectorSideLength/(2*TMath::Cos(degrees)))); rMax = rMin + ((detectorSideLength*TMath::Sin(degrees))/TMath::Tan((TMath::Pi()/2) - degrees - deltaPhi)) + (detectorSideLength*TMath::Cos(degrees)); rMinString = Form("%f", rMin); rMaxString = Form("%f", rMax); //normalization of the bins. deltaPhi = degrees - TMath::ATan(TMath::Tan(degrees) - detectorSideLength/(2*scatteringDistance)); // this should be around arctan(detectorsidelength/sd) if(j != 0.0){ deltaOmega = 2*TMath::Pi()*(TMath::Cos(TMath::Max(0.0,degrees-deltaPhi)) - TMath::Cos(degrees+deltaPhi)); }else{ deltaOmega = 4 * TMath::ASin(pow(detectorSideLength,2.0) / (4*pow(scatteringDistance,2) + pow(detectorSideLength,2)) ); } normFloat = deltaOmega * events * binWidth; normString = Form("/%f", normFloat); // The following is veryvery ugly relies on a bunch of hardcoded histograms because other solutions did not work histName = Form("hist%i", i); if(j != 0.0){ fragments->Project(histName,"energy", "(Z == " + Znum + " && energy > 0 && sqrt(posY^2 + posZ^2) < " + rMaxString + "&& sqrt(posY*posY + posZ*posZ) > " + rMinString + ")" + normString); }else{ fragments->Project(histName,"energy", "(Z == " + Znum + " && energy > 0 && posZ < " + rMaxString + "&& posY < " + rMaxString + " && posY > 0 && posZ > 0)" + normString); } int numEntries = fragments->GetEntries("(Z == " + Znum + " && energy > 0 && sqrt(posY^2 + posZ^2) < " + rMaxString + "&& sqrt(posY*posY + posZ*posZ) > " + rMinString + ")"); std::cout << "\nj: "<< numEntries/(deltaOmega * events) << " entries for " << j; } //the ugly hardcoded histograms being plotted //0 degrees hist1->SetLineColor(kBlue); hist1->Draw(); //1 degree hist2->SetLineColor(kGreen); hist2->Draw("same"); //add "same" when also plotting 0 degrees //2 degrees hist3->SetLineColor(kRed); hist3->Draw("same"); //3 degrees //hist4->SetLineColor(kGreen + 5); //hist4->Draw("same"); //4 degrees hist5->SetLineColor(kGreen + 3); //gives a darker shade of green hist5->Draw("same"); //5 degrees //hist6->SetLineColor(kRed); //hist6->Draw("same"); //6 degrees hist7->SetLineColor(kRed); hist7->Draw("same"); //7 degrees //hist8->SetLineColor(kRed); //hist8->Draw("same"); //8 degrees //hist9->SetLineColor(kRed); //hist9->Draw("same"); // Legends for the data leg = new TLegend(0.9,0.7,1,1); //coordinates are fractions leg->SetHeader("Angles"); leg->AddEntry(hist1,"0","l"); leg->AddEntry(hist2,"1","l"); leg->AddEntry(hist3,"2","l"); leg->AddEntry(hist5,"4","l"); leg->AddEntry(hist7,"6","l"); leg->Draw(); c3->SaveAs("AEDistrib" + Znum + ".png"); } in.close(); f->Write(); }
void DoTDeriMax1090Correction(TString SpectrumFileInput = "/lustre/miifs05/scratch/him-specf/hyp/steinen/COSYBeamtestAna/COSYnewMogon/June2014/COSYJune2014Dataset11_200,100,0,5339_SR1.root", TString FitFileInput = "/lustre/miifs05/scratch/him-specf/hyp/steinen/COSYBeamtestAna/COSYnewMogon/Fit/FitCOSYJune2014Dataset11_200,100,0,5339_SR1.root") { TH2D *hSpectrumTDeriMax1090_EnergyChannel; TH2D *hSpectrumTDeriMax1090Rel_EnergyChannel; TH2D *hSpectrumT1090_EnergyChannelCorr1; TNtuple *DataNTuple; TFile *SpectrumInput = new TFile(SpectrumFileInput.Data()); hSpectrumTDeriMax1090_EnergyChannel = (TH2D*) SpectrumInput->Get("Histograms/Energy_DeriMaxT90/Energy_DeriMaxT90_01"); hSpectrumTDeriMax1090_EnergyChannel->SetDirectory(0); hSpectrumTDeriMax1090Rel_EnergyChannel = (TH2D*) SpectrumInput->Get("Histograms/Energy_DeriMaxT90Rel/Energy_DeriMaxT90Rel_01"); hSpectrumTDeriMax1090Rel_EnergyChannel->SetDirectory(0); hSpectrumT1090_EnergyChannelCorr1 = (TH2D*) SpectrumInput->Get("Histograms/EnergyRt1090/EnergyRt1090CorrectionRt_01"); hSpectrumT1090_EnergyChannelCorr1->SetDirectory(0); SpectrumInput->Close(); //hSpectrumTDeriMax1090_EnergyChannel->Draw("colz"); TFile *FitInput = new TFile(FitFileInput.Data(),"Update"); DataNTuple = (TNtuple*)FitInput->Get("DataNTuple"); DataNTuple->Scan(); Int_t entries = (Int_t)DataNTuple->GetEntries(); cout<<"Number of Entries: "<<entries<< endl; const int entriesArrayValue =entries; TF1 *FitFunc[entriesArrayValue]; float Energy=0; float ChannelPeakPos=0; float ChannelRangeMin=0; float ChannelRangeMax=0; DataNTuple->SetBranchAddress("Energy",&Energy); DataNTuple->SetBranchAddress("ChannelPeakPos",&ChannelPeakPos); DataNTuple->SetBranchAddress("ChannelRangeMin",&ChannelRangeMin); DataNTuple->SetBranchAddress("ChannelRangeMax",&ChannelRangeMax); TCanvas* can=new TCanvas(); gPad->SetLogz(); hSpectrumTDeriMax1090_EnergyChannel->GetXaxis()->SetRangeUser(-30,250); hSpectrumTDeriMax1090Rel_EnergyChannel->GetXaxis()->SetRangeUser(-0.1,0.95); for (Int_t ki=0;ki<entries;ki++) { DataNTuple->GetEntry(ki); //if (int(Energy) == 1332) //if (int(Energy) == 510) //if (ki == entries-1) { cout << ChannelRangeMin << " " << ChannelRangeMax << endl; //first correction via TDeriMaxT90Rel hSpectrumTDeriMax1090_EnergyChannel->GetYaxis()->SetRangeUser(ChannelRangeMin,ChannelRangeMax); hSpectrumTDeriMax1090Rel_EnergyChannel->GetYaxis()->SetRangeUser(ChannelRangeMin,ChannelRangeMax); //TF1* FitFuncSlices = new TF1("FitFuncSlices","gaus(0)+pol0(3)",ChannelRangeMin,ChannelRangeMax); //FitFuncSlices->SetParameters(1000,ChannelPeakPos-10,4,10); //FitFuncSlices->SetParLimits(1,ChannelRangeMin,ChannelRangeMax); //FitFuncSlices->SetParLimits(2,0,10); //FitFuncSlices->SetParLimits(3,0,100); //gDirectory->ls(); TH1D *hSpectrumTDeriMax1090Rel_EnergyChannel_MaxPosManually=new TH1D("hSpectrumTDeriMax1090Rel_EnergyChannel_MaxPosManually","",hSpectrumTDeriMax1090Rel_EnergyChannel->GetNbinsX(),-0.3,1.3); //cout <<hSpectrumTDeriMax1090_EnergyChannel_MaxPos->GetEntries()<< endl; for(int binX = hSpectrumTDeriMax1090Rel_EnergyChannel->GetXaxis()->FindBin(-0.1);binX <= hSpectrumTDeriMax1090Rel_EnergyChannel->GetXaxis()->FindBin(0.90);binX++) { cout << "binx " << binX << endl; TH1D *hProfileY =hSpectrumTDeriMax1090Rel_EnergyChannel->ProjectionY("_py",binX,binX); double MaxValue=hProfileY->GetBinCenter(hProfileY->GetMaximumBin()); TF1* FitFuncSlices = new TF1("FitFuncSlices","gaus(0)+[3]",MaxValue-20,MaxValue+20); TF1* FitFuncGausSlices = new TF1("FitFuncGausSlices","gaus(0)",MaxValue-20,MaxValue+20); FitFuncGausSlices->SetParameters(hProfileY->GetBinContent(hProfileY->GetMaximumBin()),MaxValue,4); hProfileY->Fit(FitFuncGausSlices,"RNQ"); FitFuncSlices->SetParameters(FitFuncGausSlices->GetParameter(0),FitFuncGausSlices->GetParameter(1),FitFuncGausSlices->GetParameter(2),10); FitFuncSlices->SetParLimits(0,0,10000); FitFuncSlices->SetParLimits(1,MaxValue-10,MaxValue+10); FitFuncSlices->SetParLimits(2,0,10); FitFuncSlices->SetParLimits(3,0,100); hProfileY->Fit(FitFuncSlices,"RNQ"); cout <<MaxValue<<" " << FitFuncSlices->GetParameter(1) << " " << FitFuncSlices->GetParError(1) <<endl; hSpectrumTDeriMax1090Rel_EnergyChannel_MaxPosManually->SetBinContent(binX, FitFuncSlices->GetParameter(1)); hSpectrumTDeriMax1090Rel_EnergyChannel_MaxPosManually->SetBinError(binX, FitFuncSlices->GetParError(1)); } hSpectrumTDeriMax1090Rel_EnergyChannel_MaxPosManually->GetYaxis()->SetRangeUser(ChannelPeakPos-100,ChannelPeakPos+50); hSpectrumTDeriMax1090Rel_EnergyChannel_MaxPosManually->GetXaxis()->SetRangeUser(-0.05,0.9); TF1 * funcCorrConst = new TF1("funcCorrConst","pol0",-0.03,0.03); funcCorrConst->SetLineColor(kRed); TF1 * funcCorrPol = new TF1("funcCorrPol",PolPiecewise,-0.05,0.9,6); funcCorrPol->SetLineColor(kBlue); funcCorrPol->SetParameter(0,0.04); funcCorrPol->SetParameter(1,ChannelPeakPos); hSpectrumTDeriMax1090Rel_EnergyChannel_MaxPosManually->Fit(funcCorrConst,"R"); hSpectrumTDeriMax1090Rel_EnergyChannel_MaxPosManually->Fit(funcCorrPol,"R+"); TCanvas* can2=new TCanvas(); gPad->SetLogz(); hSpectrumTDeriMax1090Rel_EnergyChannel->Draw("colz"); funcCorrPol->DrawCopy("same"); for(int i = 7;i>0;i--) funcCorrPol->SetParameter(i,funcCorrPol->GetParameter(i)/funcCorrPol->GetParameter(1)); funcCorrPol->Print(); char buf[20]; sprintf(buf, "funcCorrNorm_%d",ki); funcCorrPol->Write(buf,TObject::kOverwrite); funcCorrConst->Delete(); funcCorrPol->Delete(); //second correction via T1090 (after first) hSpectrumT1090_EnergyChannelCorr1->GetYaxis()->SetRangeUser(ChannelRangeMin,ChannelRangeMax); //TF1* FitFuncSlices = new TF1("FitFuncSlices","gaus(0)+pol0(3)",ChannelRangeMin,ChannelRangeMax); //FitFuncSlices->SetParameters(1000,ChannelPeakPos-10,4,10); //FitFuncSlices->SetParLimits(1,ChannelRangeMin,ChannelRangeMax); //FitFuncSlices->SetParLimits(2,0,10); //FitFuncSlices->SetParLimits(3,0,100); //gDirectory->ls(); TH1D *hSpectrumT1090_EnergyChannelCorr1_MaxPosManually=new TH1D("hSpectrumT1090_EnergyChannelCorr1_MaxPosManually","",hSpectrumT1090_EnergyChannelCorr1->GetNbinsX(),0,1000); //cout <<hSpectrumTDeriMax1090_EnergyChannel_MaxPos->GetEntries()<< endl; for(int binX = hSpectrumT1090_EnergyChannelCorr1->GetXaxis()->FindBin(30);binX <= hSpectrumT1090_EnergyChannelCorr1->GetXaxis()->FindBin(500);binX++) { cout << "binx " << binX << endl; TH1D *hProfileY =hSpectrumT1090_EnergyChannelCorr1->ProjectionY("_py",binX,binX); //hProfileY->Draw(); //return 0; double MaxValue=hProfileY->GetBinCenter(hProfileY->GetMaximumBin()); FitFuncSlices = new TF1("FitFuncSlices","gaus(0)+[3]",MaxValue-20,MaxValue+20); FitFuncGausSlices = new TF1("FitFuncGausSlices","gaus(0)",MaxValue-20,MaxValue+20); FitFuncGausSlices->SetParameters(hProfileY->GetBinContent(hProfileY->GetMaximumBin()),MaxValue,4); hProfileY->Fit(FitFuncGausSlices,"RNQ"); FitFuncSlices->SetParameters(FitFuncGausSlices->GetParameter(0),FitFuncGausSlices->GetParameter(1),FitFuncGausSlices->GetParameter(2),10); FitFuncSlices->SetParLimits(0,0,10000); FitFuncSlices->SetParLimits(1,MaxValue-10,MaxValue+10); FitFuncSlices->SetParLimits(2,0,10); FitFuncSlices->SetParLimits(3,0,100); hProfileY->Fit(FitFuncSlices,"RNQ"); cout <<MaxValue<<" " << FitFuncSlices->GetParameter(1) << " " << FitFuncSlices->GetParError(1) <<endl; hSpectrumT1090_EnergyChannelCorr1_MaxPosManually->SetBinContent(binX, FitFuncSlices->GetParameter(1)); hSpectrumT1090_EnergyChannelCorr1_MaxPosManually->SetBinError(binX, FitFuncSlices->GetParError(1)); } hSpectrumT1090_EnergyChannelCorr1_MaxPosManually->GetYaxis()->SetRangeUser(ChannelPeakPos-100,ChannelPeakPos+50); hSpectrumT1090_EnergyChannelCorr1_MaxPosManually->GetXaxis()->SetRangeUser(30,500); new TCanvas(); hSpectrumT1090_EnergyChannelCorr1_MaxPosManually->Draw(); TF1 * funcCorrConst = new TF1("funcCorrConst","pol0",50,350); funcCorrConst->SetLineColor(kRed); TF1 * funcCorrPol = new TF1("funcCorrPol","pol6",50,300); funcCorrPol->SetLineColor(kBlue); funcCorrPol->SetParameter(0,0.04); funcCorrPol->SetParameter(1,ChannelPeakPos); hSpectrumT1090_EnergyChannelCorr1_MaxPosManually->Fit(funcCorrConst,"R"); hSpectrumT1090_EnergyChannelCorr1_MaxPosManually->Fit(funcCorrPol,"R+"); TCanvas* can2=new TCanvas(); gPad->SetLogz(); hSpectrumT1090_EnergyChannelCorr1->Draw("colz"); funcCorrPol->DrawCopy("same"); for(int i = 7;i>=0;i--) funcCorrPol->SetParameter(i,funcCorrPol->GetParameter(i)/funcCorrConst->GetParameter(0)); funcCorrPol->Print(); char buf[20]; sprintf(buf, "funcCorr2Norm_%d",ki); funcCorrPol->Write(buf,TObject::kOverwrite); funcCorrConst->Delete(); funcCorrPol->Delete(); //return 0; } } //can->ls(); gDirectory->Delete("ncCorrPol;1"); FitInput->ls(); //TCanvas* can3=new TCanvas(); //hSpectrumTDeriMax1090_EnergyChannel->ProfileX()->Draw(); //hSpectrumTDeriMax1090Rel_EnergyChannel->ProfileX()->Draw(); //hSpectrumTDeriMax1090Rel_EnergyChannel->Fit("pol3"); FitInput->Close(); }
void TakeDataAnalyzer(Int_t RunN){ //Int_t RunN = 4591; //string FileRoot = "/d00/icali/PixelHwStudies/PSIStuff/log/bt05r"; string FileRoot = "/home/l_tester/log/bt05r"; string FileInName = "thistos.root"; string FileOutName = "ProcessedData.root"; char RunNumber[6]; sprintf(RunNumber, "%.6d", RunN); FileRoot = FileRoot + RunNumber + "/"; FileInName = FileRoot + FileInName; FileOutName = FileRoot + FileOutName; TFile *iFile = new TFile((const char*)FileInName.c_str()); TNtuple *Digis = (TNtuple*)iFile->FindObjectAny("events"); Int_t EvN, row, col, roc, ph; Float_t vcal; Digis->SetBranchAddress("row", &row); Digis->SetBranchAddress("col", &col); Digis->SetBranchAddress("roc", &roc); Digis->SetBranchAddress("ph", &ph); Digis->SetBranchAddress("vcal", &vcal); Digis->SetBranchAddress("eventNr", &EvN); Int_t iNTlenght = Digis->GetEntries(); TFile *oFile = new TFile((const char*)FileOutName.c_str(), "RECREATE"); TNtuple *Multiplicity = new TNtuple("ModMult", "ModMult", "EvN:roc:NModHits:NROCHits:NRows:NCols:MeanPh:MeanPhPuls",10000000); //******************Calculating Number of Events************** Digis->GetEntry(iNTlenght -1); std::cout << " MaxEvent " << EvN << std::endl; //*****************Creating Multiplicity NTuple*************** ModuleMultiplicity ModMult; Int_t OldEvN = 1; for(Int_t i =0; i< iNTlenght; ++i){ Digis->GetEntry(i); if(OldEvN != EvN ||( i == iNTlenght -1) ){ for(Int_t j=0; j < 16; ++j){ Float_t NModHits = ModMult.ModMultiplicity(); Float_t NROCHits = ModMult.ROCMultiplicity(j); Float_t NRows = ModMult.NumberOfRows(j); Float_t NCols = ModMult.NumberOfColumns(j); Float_t MeanPh = ModMult.MeanPh(j); Float_t MeanPhPuls = ModMult.MeanPhPuls(j); if(NROCHits >0) Multiplicity->Fill(EvN-1, j,NModHits ,NROCHits ,NRows ,NCols ,MeanPh, MeanPhPuls); } ModMult.Clean(); OldEvN = EvN; } bool SelPixel = 0; if(row ==5 && col ==5)SelPixel = 1; if(roc>-1&&col>-1)ModMult.Add(roc, row, col, ph, SelPixel); } oFile->Write(); oFile->Close(); }
void jettrigger() { TFile *f = new TFile("jettrig.root"); TNtuple *nt = (TNtuple *)f->Get("nt"); //Declaration of leaves types Float_t pt; Float_t eta; Float_t phi; Float_t mass; Float_t jt40; Float_t jt60; Float_t jt80; Float_t jt100; Float_t pscl40; Float_t pscl60; Float_t pscl80; Float_t pscl100; // Set branch addresses. nt->SetBranchAddress("pt",&pt); nt->SetBranchAddress("eta",&eta); nt->SetBranchAddress("phi",&phi); nt->SetBranchAddress("mass",&mass); nt->SetBranchAddress("jt40",&jt40); nt->SetBranchAddress("jt60",&jt60); nt->SetBranchAddress("jt80",&jt80); nt->SetBranchAddress("jt100",&jt100); nt->SetBranchAddress("pscl40",&pscl40); nt->SetBranchAddress("pscl60",&pscl60); nt->SetBranchAddress("pscl80",&pscl80); nt->SetBranchAddress("pscl100",&pscl100); TFile *fout = new TFile("jettrig_withweight.root","recreate"); TNtuple *ntout = new TNtuple("ntweight","ntweight","pt:eta:phi:mass:jt40:jt60:jt80:jt100:pscl40:pscl60:pscl80:weightJet:weight12003"); //TTree *ntout=new TTree("ntweight","ntweight"); ntout->SetDirectory(fout); /* ntout->Branch("pt",&pt); ntout->Branch("eta",&eta); ntout->Branch("phi",&phi); ntout->Branch("mass",&mass); ntout->Branch("jt40",&jt40); ntout->Branch("jt60",&jt60); ntout->Branch("jt80",&jt80); ntout->Branch("jt100",&jt100); ntout->Branch("pscl40",&pscl40); ntout->Branch("pscl60",&pscl60); ntout->Branch("pscl80",&pscl80); ntout->Branch("pscl100",&pscl100); ntout->Branch("weight",&weight); */ Long64_t nentries = nt->GetEntries(); cout<<nentries<<endl; int oneperc = nentries/100; Long64_t nbytes = 0; //#ifndef __CINT__ //#pragma omp parallel for ordered schedule(dynamic) //#endif for (Long64_t i=0; i<nentries;i++) { nbytes += nt->GetEntry(i); if (i % oneperc == 0) cout<<"\r"<<i/oneperc<<"% "<<flush; float weightJet = 0, weight12003 = 0; if (jt40 && !jt60 && !jt80 && !jt100) weight12003 = 1/pscl40; if (jt60 && !jt80 && !jt100) weight12003 = 1; if (jt80 && !jt100) weight12003 = 1; if (jt100) weight12003 = 1; if (jt40 && pt>40 && pt<60) weightJet = pscl40; if (jt60 && pt>60 && pt<80) weightJet = pscl60; if (jt80 && pt>80 && pt<100) weightJet = pscl80; if (jt100 && pt>100) weightJet = pscl100; //#ifndef __CINT__ //#pragma omp ordered //#endif ntout->Fill(pt,eta,phi,mass,jt40,jt60,jt80,jt100,pscl40,pscl60,pscl80,weightJet,weight12003); } cout<<endl; cout<<ntout->GetEntries()<<endl; ntout->Write(); fout->Close(); f->Close(); f = new TFile("jettrig_withweight.root"); nt = (TNtuple *)f->Get("ntweight"); cout<<nt->GetEntries()<<endl; f->Close(); }
void fragmentYieldsPlot() { gStyle->SetOptStat(0000000000); //remove the for this graphs totally redundant statbox int ZNumGiven; cout << "Enter fragment Z-number (eg. 1): "; cin >> ZNumGiven; TCanvas *c1 = new TCanvas("fragmentYieldsPlot", "Total yield of fragments zero to ten degrees as function of depth"); TString fragmentNameChoices[6] = {"H","He","Li","Be","B","C"}; TString fragmentName = fragmentNameChoices[ZNumGiven-1]; std::cout << fragmentName << endl; TH1F* dummyHisto = new TH1F("dummyHisto", fragmentName + " yields 0-10 degrees" ,100, 0.0,40); //Dummyhisto fix for missing TNtuple methods. dummyHisto->SetXTitle("Depth (cm)"); dummyHisto->SetYTitle("N/N0"); ifstream in; TString experimentalDataPath = "experimentalData/iaeaBenchmark/yields/TDK" + fragmentName + ".dat"; ifstream in; //Pull in ascii/exfor-style data in.open(experimentalDataPath); Float_t f1,f2; Int_t nlines = 0; TFile *f = new TFile("fragmentAngularDistribution.root","RECREATE"); TNtuple *ntuple = new TNtuple("ntuple","Data from ascii file","x:y"); Char_t DATAFLAG[4]; Int_t NDATA; Char_t n1[15], n2[15]; in >> DATAFLAG >> NDATA ; // Read EXFOR line: 'DATA 6' in >> n1 >> n2; // Read column titles: 'Energy He B [...]' cout <<n1<<" "<<n2<<"\n"; while (1) { in >> f1 >> f2; if (!in.good()) break; if (nlines < 500 ) printf("%f %f\n",f1,f2); ntuple->Fill(f1,f2); nlines++; } std::cout << "Imported " << nlines << " lines from data-file" << endl; TNtuple *simData = new TNtuple("ntuple","Data from ascii file","depth:H:He:Li:Be:B:C"); // gROOT->SetStyle("clearRetro"); //this will be used as base for pulling the experimental data TString dir = gSystem->UnixPathName(gInterpreter->GetCurrentMacroName()); dir.ReplaceAll("fragmentAngularDistribution.C",""); dir.ReplaceAll("/./","/"); ifstream in; simData->Fill(0.0,0.0,0.0,0.0,0.0,0.0,1.0); for(int j = 1; j <= 40;j=j=j+1){ TString pDepth, fragment, Znum, normToOneAtZeroAngle; pDepth = Form("%i",j); /* cout << "Enter phantom depth (eg. 27.9, see experimentalData directory for choices): "; cin >> pDepth; */ TString simulationDataPath = "IAEA_" + pDepth + ".root"; //Let's pull in the simulation-data //TFile *MCData = TFile::Open("IAEA_" + pDepth + ".root"); TFile *MCData = TFile::Open(simulationDataPath); TNtuple *fragments = (TNtuple*) MCData->Get("fragmentNtuple"); //Block bellow pulls out the simulation's metadata from the metadata ntuple. TNtuple *metadata = (TNtuple*) MCData->Get("metaData"); Float_t events, detectorDistance,waterThickness,beamEnergy,energyError,phantomCenterDistance; metadata->SetBranchAddress("events",&events); metadata->SetBranchAddress("waterThickness",&waterThickness); metadata->SetBranchAddress("detectorDistance",&detectorDistance); metadata->SetBranchAddress("beamEnergy",&beamEnergy); metadata->SetBranchAddress("energyError",&energyError); metadata->SetBranchAddress("phantomCenterDistance",&phantomCenterDistance); metadata->GetEntry(0); //there is just one row to consider. //ALL UNITS ARE cm! Double_t scatteringDistance = detectorDistance - phantomCenterDistance; //temporarily hard-coded, should be distance from target-center to detector Double_t degrees = 10.0; Double_t r, rMin, rMax, graphMaximum = 0.0; Double_t norming = events*.999; TString rMinString; TString rMaxString; rMinString = "0.00"; rMaxString = Form("%f", scatteringDistance*TMath::ATan(degrees*TMath::DegToRad())); Double_t H = ((Double_t*) fragments->GetEntries("(Z == " + TString::Format("%i",1) + " && sqrt(posY^2 + posZ^2) < " + rMaxString + "&& sqrt(posY*posY + posZ*posZ) > " + rMinString + ")")) / norming; Double_t He = ((Double_t*) fragments->GetEntries("(Z == " + TString::Format("%i",2) + " && sqrt(posY^2 + posZ^2) < " + rMaxString + "&& sqrt(posY*posY + posZ*posZ) > " + rMinString + ")")) / norming; Double_t Li = ((Double_t*) fragments->GetEntries("(Z == " + TString::Format("%i",3) + " && sqrt(posY^2 + posZ^2) < " + rMaxString + "&& sqrt(posY*posY + posZ*posZ) > " + rMinString + ")")) / norming; Double_t Be = ((Double_t*) fragments->GetEntries("(Z == " + TString::Format("%i",4) + " && sqrt(posY^2 + posZ^2) < " + rMaxString + "&& sqrt(posY*posY + posZ*posZ) > " + rMinString + ")")) / norming; Double_t B = ((Double_t*) fragments->GetEntries("(Z == " + TString::Format("%i",5) + " && sqrt(posY^2 + posZ^2) < " + rMaxString + "&& sqrt(posY*posY + posZ*posZ) > " + rMinString + ")")) / norming; Double_t C = ((Double_t*) fragments->GetEntries("(Z == " + TString::Format("%i",6) + " && sqrt(posY^2 + posZ^2) < " + rMaxString + "&& sqrt(posY*posY + posZ*posZ) > " + rMinString + ")")) / norming; simData->Fill(waterThickness,H,He,Li,Be,B,C); } simData->Scan(); simData->SetMarkerStyle(2); //filled dot simData->SetMarkerColor(kBlue); graphMaximum = TMath::Max(graphMaximum, simData->GetMaximum(fragmentName)); graphMaximum = TMath::Max(graphMaximum, ntuple->GetMaximum("y")); dummyHisto->SetMaximum(graphMaximum + .05*graphMaximum); dummyHisto->Draw(); simData->Draw(fragmentName + ":depth","","p,same"); ntuple->SetMarkerStyle(22); //triangle ntuple->SetMarkerColor(kRed); ntuple->Draw("y:x","","p,same"); c1->SaveAs("fragmentYieldsFor" + fragmentName + ".png"); }