void GetGfxDriverFactoryNames(StringV &ids) { #ifdef WINDOWS_VERSION ids.push_back("D3D9"); #endif #if defined (ANDROID_VERSION) || defined (IOS_VERSION) || defined (WINDOWS_VERSION) || defined(LINUX_VERSION) ids.push_back("OGL"); #endif ids.push_back("Software"); }
// ----------------------------------------------------------------------------- // int qcdBkgdEst_new() { // int nn = 100; // std::vector<float> xx; // std::vector<float> yy; // for ( uint i = 0; i < nn; ++i ) { xx.push_back( i*100. ); } // for ( uint ilumi = 0; ilumi < nn; ++ilumi ) { bool plots = true; // 0 = false (force to gaussian), 1 = true, 2 = for prescales int use_sumw2 = 2; std::string label = ""; //int last_bin = 7; setTDRStyle(); // Misc bool efficiency = false; enum choices { PLOT_NUMERATOR=1, PLOT_DENOMINATOR=2, PLOT_RATIO=5 }; int choice = 5; bool min_max_with_errors = true; bool use_meff = false; double axis_offset = 2.; bool simulation = false; // Some analysis defaults double offset = 0.; //double pt1_default = 100.; //double pt2_default = 100.; //double pt3_default = 50.; //double ht_default = 375. + offset; //double meff_default = ht_default + pt3_default; //double x1_default = pt1_default / meff_default; //double x2_default = pt2_default / meff_default; //double x3_default = pt3_default / meff_default ; //double x3_factor = ( 1. - x3_default ) / ( x3_default ); std::string dir = "/vols/cms04/bainbrid/qcd/stable/SUSY2/results/"; //std::string histo = "HtAfterAlphaT"; //std::string histo = "HtAfterRecHit"; std::string histo = "HtAfterBaby"; std::vector<double> at; at.push_back(0.51); at.push_back(0.52); at.push_back(0.53); at.push_back(0.54); at.push_back(0.55); //at.push_back(0.60); const uint nat = at.size(); std::vector<int> multi; multi.push_back(-2); const uint nmulti = multi.size(); double ht_min = 0.; double ht_max = 0.; int nht = 20; //@@ number of bins std::vector<double> ht; std::vector<double> ht_step; // override histo binning if ( true ) { ht.push_back(275.); ht.push_back(325.); for ( uint iht = 0; iht <= 6; ++iht ) { ht.push_back(375.+iht*100.); } //for ( uint iht = 0; iht <= 8; ++iht ) { ht.push_back(300.+iht*100.); } nht = ht.size() - 1; ht_min = ht.front() + offset; ht_max = ht.back() + offset; } // ----------------------------------------------------------------------------- // ----------------------------------------------------------------------------- // ----------------------------------------------------------------------------- StringVV files; bool test = true; if ( test ) { //std::string trunk = dir + "v02/Ratio__"; //StringV q; q.push_back(trunk+"data.root"); files.push_back(q); //StringV q1; q1.push_back(dir + "v19/Ratio__data.root"); files.push_back(q1); StringV q3; q3.push_back(dir + "v21/Ratio__data.root"); files.push_back(q3); StringV q1; q1.push_back(dir + "v26/Ratio__data_1fb.root"); files.push_back(q1); StringV q2; q2.push_back(dir + "v22/Ratio__data.root"); files.push_back(q2); //StringV q; q.push_back("../python/Ratio_QCDPY.root"); //StringV w(q); w.push_back(trunk+"wjets.root"); //StringV z(q); z.push_back(trunk+"zinv.root"); //StringV tt(q); tt.push_back(trunk+"ttbar.root"); } bool results = false; if ( results ) { std::string trunk = dir + "v08/Ratio__"; StringV q; q.push_back(trunk+"qcdmg.root"); StringV sm(q); sm.push_back(trunk+"wjets.root"); sm.push_back(trunk+"zinv.root"); sm.push_back(trunk+"ttbar.root"); files.push_back(sm); StringV sm1(q); sm1.push_back(trunk+"wjets_incl.root"); sm1.push_back(trunk+"zinv.root"); sm1.push_back(trunk+"ttbar.root"); files.push_back(sm1); //StringV lm6(sm); lm6.push_back(trunk+"lm6.root"); files.push_back(lm6); StringV wi(q); wi.push_back(trunk+"wjets_incl.root"); files.push_back(wi); StringV w(q); w.push_back(trunk+"wjets.root"); files.push_back(w); StringV z(q); z.push_back(trunk+"zinv.root"); files.push_back(z); StringV tt(q); tt.push_back(trunk+"ttbar.root"); files.push_back(tt); //StringV t(q); t.push_back(trunk+"top.root"); files.push_back(t); files.push_back(StringV(1,dir+"v08/Ratio__data.root")); // std::string trunk = dir + "v36/Ratio__"; // StringV sm1; // sm1.push_back(trunk+"qcdpy.root"); // //sm1.push_back(trunk+"wjets.root"); // sm1.push_back(trunk+"zinv.root"); // sm1.push_back(trunk+"ttbar.root"); // sm1.push_back(trunk+"top.root"); // trunk = dir + "v37/Ratio__"; // StringV sm2; // sm2.push_back(trunk+"qcdpy.root"); // sm2.push_back(trunk+"wjets.root"); // sm2.push_back(trunk+"zinv.root"); // sm2.push_back(trunk+"ttbar.root"); // trunk = dir + "v40/Ratio__"; // StringV sm3; // sm3.push_back(trunk+"qcdpy.root"); // sm3.push_back(trunk+"wjets.root"); // sm3.push_back(trunk+"zinv.root"); // sm3.push_back(trunk+"ttbar.root"); // files.push_back(sm1); // files.push_back(sm2); // files.push_back(sm3); } const uint nfile = files.size(); std::vector<std::string> his; if ( his.size() < nfile ) { his.resize(nfile,histo); } std::vector<std::string> type; if ( test ) { // type.push_back("1"); // type.push_back("2"); //type.push_back("Data"); type.push_back("HT-aT cross triggers"); type.push_back("HT-MHT cross triggers"); type.push_back("HT prescaled triggers"); //type.push_back("QcdMg"); //type.push_back("Nominal"); //type.push_back("Alternative"); } if ( results ) { //type.push_back("SM + LM6 (Spring11)"); //type.push_back("Spring11"); //type.push_back("Summer11(Wincl)"); //type.push_back("Summer11(W300)"); type.push_back("SM (W+jets HT-binned)"); type.push_back("SM (W+jets inclusive)"); // type.push_back("SM "); type.push_back("Wjets (incl)"); type.push_back("Wjets (HT-binned)"); type.push_back("Zinv "); type.push_back("TTbar"); //type.push_back("Single top "); type.push_back("Data "); } if ( type.size() < nfile ) { type.resize(nfile,"unknown"); } double lumi = 4650.; std::vector<double> lumis; if ( test ) { lumi = 4650; lumis.push_back(100.); //lumis.push_back(100.*lumi/1140.); lumis.push_back(100.); //lumis.push_back(lumi); } if ( results ) { double tmp = 4650.;//xx[ilumi]; lumi = tmp; lumis.push_back(tmp); lumis.push_back(tmp); lumis.push_back(tmp); lumis.push_back(tmp); lumis.push_back(tmp); lumis.push_back(tmp); lumis.push_back(100.); } if ( lumis.size() < nfile ) { lumis.resize(nfile,100.); } // Which file is the data file int data_file = -1; for ( uint itype = 0; itype < nfile; ++itype ) { if ( type[itype] == "data" || type[itype] == "Data" ) { data_file = itype; break; } } // if ( data_file == -1 ) { // data_file = 0; // std::cout << "Problem identifying data file!" << std::endl; // } std::vector<int> style; if ( test ) { style.push_back(20); style.push_back(24); style.push_back(25); } if ( results ) { style.push_back(24); style.push_back(25); style.push_back(26); style.push_back(28); style.push_back(27); style.push_back(30); style.push_back(20); } if ( style.size() < nfile ) { style.resize(nfile,25); } std::vector<double> size; if ( size.size() < nfile ) { size.resize(nfile,1.5); } std::vector<int> col; if ( test ) { col.push_back(1); col.push_back(2); col.push_back(4); } if ( results ) { col.push_back(2); col.push_back(4); col.push_back(6); col.push_back(6); col.push_back(6); col.push_back(6); col.push_back(1); } if ( col.size() < nfile ) { col.resize(nfile,1); } // ----------------------------------------------------------------------------- // ----------------------------------------------------------------------------- // ----------------------------------------------------------------------------- DoubleVVVV numer; resize( numer, nfile, nmulti, nat, nht ); DoubleVVVV numer_errh; resize( numer_errh, nfile, nmulti, nat, nht ); DoubleVVVV numer_errl; resize( numer_errl, nfile, nmulti, nat, nht ); DoubleVVVV denom; resize( denom, nfile, nmulti, nat, nht ); DoubleVVVV denom_errh; resize( denom_errh, nfile, nmulti, nat, nht ); DoubleVVVV denom_errl; resize( denom_errl, nfile, nmulti, nat, nht ); DoubleVVVV ratio; resize( ratio, nfile, nmulti, nat, nht ); DoubleVVVV errh; resize( errh, nfile, nmulti, nat, nht ); DoubleVVVV errl; resize( errl, nfile, nmulti, nat, nht ); IntVVV length; resize( length, nfile, nmulti, nat ); // Min/max values for ratios DoubleVV min; min.resize( nmulti, DoubleV( nat, 0. ) ); DoubleVV max; max.resize( nmulti, DoubleV( nat, 0. ) ); std::cout << " nfile: " << nfile << " nmulti: " << nmulti << " nat: " << nat << " nht: " << nht << " total: " << nfile*nmulti*nat*nht << std::endl; // Init arrays for ( uint imulti = 0; imulti < nmulti; ++imulti ) { for ( uint iat = 0; iat < nat; ++iat ) { for ( uint ifile = 0; ifile < nfile; ++ifile ) { for ( int iht = 0; iht < nht; ++iht ) { numer[ifile][imulti][iat][iht] = 0.; numer_errh[ifile][imulti][iat][iht] = 0.; numer_errl[ifile][imulti][iat][iht] = 0.; denom[ifile][imulti][iat][iht] = 0.; denom_errh[ifile][imulti][iat][iht] = 0.; denom_errl[ifile][imulti][iat][iht] = 0.; ratio[ifile][imulti][iat][iht] = 0.; errh[ifile][imulti][iat][iht] = 0.; errl[ifile][imulti][iat][iht] = 0.; } length[ifile][imulti][iat] = 0; } min[imulti][iat] = 0.; max[imulti][iat] = 0.; } } std::cout << " CALCULATING RATIOS..." << std::endl; calcRatio( nfile, nmulti, nat, nht, his, files, lumis, multi, at, ht, ht_min, ht_max, numer, numer_errh, numer_errl, denom, denom_errh, denom_errl, ratio, errh, errl, length, label, efficiency, use_sumw2, data_file ); ht_step.clear(); for ( int iht = 0; iht < nht; ++iht ) { ht_step.push_back( ht[iht+1] - ht[iht] ); } // std::cout << " size " << ht.size() // << " nbins " << nht // << " htmin " << ht_min // << " htmax " << ht_max // << std::endl; // for ( int iht = 0; iht <= nht; ++iht ) { // std::cout << " ibin " << iht // << " ht " << ht[iht] // << " htstep " << (iht<nht?ht_step[iht]:0.) // << std::endl; // } // // ----------------------------------------------------------------------------- // // ----------------------------------------------------------------------------- // // ----------------------------------------------------------------------------- // Print numbers bool print = true; if (print) { for ( uint ifile = 0; ifile < nfile; ++ifile ) { for ( uint imulti = 0; imulti < nmulti; ++imulti ) { for ( uint iat = 0; iat < nat; ++iat ) { for ( int iht = 0; iht < nht; ++iht ) { double n = numer[ifile][imulti][iat][iht]; double neh = numer_errh[ifile][imulti][iat][iht]; double nel = numer_errl[ifile][imulti][iat][iht]; double d = denom[ifile][imulti][iat][iht]; double deh = denom_errh[ifile][imulti][iat][iht]; double del = denom_errl[ifile][imulti][iat][iht]; double r = ratio[ifile][imulti][iat][iht]; double eh = errh[ifile][imulti][iat][iht]; double el = errl[ifile][imulti][iat][iht]; std::cout //<< " PRINT: " << "" << type[ifile] << "" //<< " njets: " << multi[imulti] << " aT: " << at[iat] << std::fixed << std::setprecision(0) << " HT: " << ht[iht] << std::scientific << std::setprecision(3) << ", pass: "******" + " << neh << " - " << nel // << ",pass," << n // << "," << neh // << "," << nel //<< " (" << ( n > 0. ? sqrt(n)/n : -1. ) << ")" << ", fail: " << d << " + " << deh << " - " << del // << ",fail," << d // << "," << deh // << "," << del //<< " (" << ( d > 0. ? sqrt(d)/d : -1. ) << ")" //<< " R: " << ( d > 0. ? n/d : -1. ) //<< " E: " << ( d > 0. ? sqrt(n*(n/(n+d))*(1-(n/(n+d)))) : -1. ) << ", ratio: " << r << " + " << eh << " - " << el // << ", ratio ," << r // << "," << eh // << "," << el // << " (" << int(( r > 0. ? eh/r : -1. )*100.) << "," // << int(( r > 0. ? el/r : -1. )*100.) << ")" << std::endl; } } } } } // ----------------------------------------------------------------------------- // For Ted bool print_ted = true; if (print_ted) { for ( uint ifile = 0; ifile < nfile; ++ifile ) { for ( uint imulti = 0; imulti < nmulti; ++imulti ) { for ( uint iat = 0; iat < nat; ++iat ) { std::stringstream ted; ted << " sample: \"" << type[ifile] << "\"" << " Multiplicity: " << multi[imulti] << " AlphaT: " << at[iat] << std::endl; ted << "\"had\":\t\t" << float(lumi) << ", #lumi" << std::endl; ted << "\"hadBulk\":\t" << float(lumi) << ", #lumi" << std::endl; // Bulk ted << "\"nHadBulk\":\t("; for ( int iht = 0; iht < nht; ++iht ) { double d = denom[ifile][imulti][iat][iht]; ted << std::setw(9) << std::scientific << std::setprecision(3) << d << ", "; } ted << ")" << std::endl; // Tail ted << "\"nHad\":\t\t("; for ( int iht = 0; iht < nht; ++iht ) { double n = numer[ifile][imulti][iat][iht]; ted << std::setw(9) << std::scientific << std::setprecision(3) << n << ", "; } ted << ")" << std::endl; // Mean HT ted << "self._htMeans = ("; for ( int iht = 0; iht < nht; ++iht ) { ted << std::setw(9) << std::scientific << std::setprecision(3) << ht[iht] << ", "; } ted << ")" << std::endl; std::cout << ted.str() << std::endl; } } } } // ----------------------------------------------------------------------------- if (!plots) return 0; // Variable to plot std::cout << " EXTRACTING VALUES TO PLOT..." << std::endl; double valx[nfile][nmulti][nat][nht]; double errxh[nfile][nmulti][nat][nht]; double errxl[nfile][nmulti][nat][nht]; double valy[nfile][nmulti][nat][nht]; double erryh[nfile][nmulti][nat][nht]; double erryl[nfile][nmulti][nat][nht]; for ( uint ifile = 0; ifile < nfile; ++ifile ) { for ( uint imulti = 0; imulti < nmulti; ++imulti ) { for ( uint iat = 0; iat < nat; ++iat ) { for ( int iht = 0; iht < nht; ++iht ) { valx[ifile][imulti][iat][iht] = 0.; errxh[ifile][imulti][iat][iht] = 0.; errxl[ifile][imulti][iat][iht] = 0.; valy[ifile][imulti][iat][iht] = 0.; erryh[ifile][imulti][iat][iht] = 0.; erryl[ifile][imulti][iat][iht] = 0.; double width = (1.*ht_step[nht-1]) / (1.*ht_step[iht]); //std::cout << " iht " << iht << " width " << width << std::endl; if ( choice == PLOT_NUMERATOR ) { valx[ifile][imulti][iat][iht] = ht[iht] + ht_step[iht]/2. + axis_offset*ifile; errxh[ifile][imulti][iat][iht] = ht_step[iht]/2. + axis_offset*ifile; errxl[ifile][imulti][iat][iht] = ht_step[iht]/2. - axis_offset*ifile; valy[ifile][imulti][iat][iht] = numer[ifile][imulti][iat][iht] * width; erryh[ifile][imulti][iat][iht] = numer_errh[ifile][imulti][iat][iht] * width; erryl[ifile][imulti][iat][iht] = numer_errl[ifile][imulti][iat][iht] * width; } else if ( choice == PLOT_DENOMINATOR ) { valx[ifile][imulti][iat][iht] = ht[iht] + ht_step[iht]/2. + axis_offset*ifile; errxh[ifile][imulti][iat][iht] = ht_step[iht]/2. + axis_offset*ifile; errxl[ifile][imulti][iat][iht] = ht_step[iht]/2. - axis_offset*ifile; valy[ifile][imulti][iat][iht] = denom[ifile][imulti][iat][iht] * width; erryh[ifile][imulti][iat][iht] = denom_errh[ifile][imulti][iat][iht] * width; erryl[ifile][imulti][iat][iht] = denom_errl[ifile][imulti][iat][iht] * width; } else if ( choice == PLOT_RATIO ) { //if ( iht < length[ifile][imulti][iat] ) { valx[ifile][imulti][iat][iht] = ht[iht] + ht_step[iht]/2. + axis_offset*ifile; errxh[ifile][imulti][iat][iht] = ht_step[iht]/2. + axis_offset*ifile; errxl[ifile][imulti][iat][iht] = ht_step[iht]/2. - axis_offset*ifile; valy[ifile][imulti][iat][iht] = ratio[ifile][imulti][iat][iht]; erryh[ifile][imulti][iat][iht] = errh[ifile][imulti][iat][iht]; erryl[ifile][imulti][iat][iht] = errl[ifile][imulti][iat][iht]; //} } } } } } if ( choice == PLOT_NUMERATOR ) { std::cout << "Plotting numerator..." << std::endl; } else if ( choice == PLOT_DENOMINATOR ) { std::cout << "Plotting denominator..." << std::endl; } else if ( choice == PLOT_RATIO ) { std::cout << "Plotting ratio..." << std::endl; } else { std::cout << "Plotting unknown!!..." << std::endl; } // ----------------------------------------------------------------------------- // Calculate min and max values for y-axis (ratio) for ( uint imulti = 0; imulti < nmulti; ++imulti ) { for ( uint iat = 0; iat < nat; ++iat ) { min[imulti][iat] = 1.e12; max[imulti][iat] = 1.e-12; for ( uint ifile = 0; ifile < nfile; ++ifile ) { for ( int iht = 0; iht < nht; ++iht ) { if ( ht[iht] < ht_min && ht[iht] > ht_max ) { continue; } double ymin = valy[ifile][imulti][iat][iht] - erryl[ifile][imulti][iat][iht]; double ymax = valy[ifile][imulti][iat][iht] + erryh[ifile][imulti][iat][iht]; if ( valy[ifile][imulti][iat][iht] > 0. && valy[ifile][imulti][iat][iht] < min[imulti][iat] ) { if ( min_max_with_errors && ymin > 0. && ymin < min[imulti][iat] ) { min[imulti][iat] = ymin; } else { min[imulti][iat] = valy[ifile][imulti][iat][iht]; } } if ( valy[ifile][imulti][iat][iht] > 0. && valy[ifile][imulti][iat][iht] > max[imulti][iat] ) { if ( min_max_with_errors && ymax > 0. && ymax > max[imulti][iat] ) { max[imulti][iat] = ymax; } else { max[imulti][iat] = valy[ifile][imulti][iat][iht]; } } } } } } if (false) { for ( uint ifile = 0; ifile < nfile; ++ifile ) { for ( uint imulti = 0; imulti < nmulti; ++imulti ) { for ( uint iat = 0; iat < nat; ++iat ) { std::cout << " sample:\"" << type[ifile] << "\"" << " multi: " << multi[imulti] << " aT:" << at[iat] << " min:" << min[imulti][iat] << " max:" << max[imulti][iat] << std::endl; } } } } if (false) { for ( uint ifile = 0; ifile < nfile; ++ifile ) { for ( uint imulti = 0; imulti < nmulti; ++imulti ) { for ( uint iat = 0; iat < nat; ++iat ) { std::cout << " PLOTTING:" << " sample:\"" << type[ifile] << "\"" << " multi: " << multi[imulti] << " aT:" << at[iat] << " valy: " << valy[ifile][imulti][iat] << " erryh: " << erryh[ifile][imulti][iat] << " erryl: " << erryl[ifile][imulti][iat] << std::endl; } } } } // ----------------------------------------------------------------------------- // Check number of pt and ht bins are the same std::cout << " CREATING PLOTS..." << std::endl; std::vector<double> rat; std::vector<float> fits; for ( uint imulti = 0; imulti < nmulti; ++imulti ) { for ( uint iat = 0; iat < nat; ++iat ) { std::string name; if ( choice == PLOT_NUMERATOR ) { name = "Pass"; } else if ( choice == PLOT_DENOMINATOR ) { if ( efficiency ) { name = "Total"; } else { name = "Fail"; } } else if ( choice == PLOT_RATIO ) { if ( efficiency ) { name = "Eff"; } else { name = "Ratio"; } } else { name = "Unknown"; } std::stringstream ss_canvas; ss_canvas << "Multi"; if ( multi[imulti] >= 0 ) { ss_canvas << multi[imulti]; } else { ss_canvas << abs(multi[imulti]) << "Incl"; } ss_canvas << "_AlphaT" << at[iat]; gStyle->SetOptFit(111); TCanvas* canvas = 0; TLegend* legend = 0; TLatex* prelim = 0; TLatex* lumitxt = 0; TMultiGraph* mg = 0; canvas = new TCanvas(TString(name+"_"+ss_canvas.str()), TString(name+"_"+ss_canvas.str()),800,600); canvas->SetFillColor(0); canvas->SetLineColor(0); canvas->SetLeftMargin(0.17); legend = new TLegend( 0.65, 0.7-(nfile*0.04), 0.85, 0.7, NULL, "brNDC" ); legend->SetTextSize(0.035); legend->SetFillColor(0); legend->SetLineColor(0); legend->SetShadowColor(0); if (!simulation) { prelim = new TLatex( 0.20, 0.88, "#scale[0.8]{CMS preliminary 2011}" ); } else { prelim = new TLatex( 0.20, 0.88, "#scale[0.8]{CMS simulation 2011}" ); } prelim->SetTextSize(0.035); prelim->SetNDC(); std::stringstream ssl; ssl << "#scale[0.8]{#int L dt = " << std::setprecision(3) << lumi/1000. << " fb^{-1}, #sqrt{s} = 7 TeV}"; lumitxt = new TLatex( 0.68, 0.88, ssl.str().c_str() ); lumitxt->SetTextSize(0.035); lumitxt->SetNDC(); mg = new TMultiGraph(); std::stringstream ss_axis; if ( choice == PLOT_NUMERATOR ) { ss_axis << "N(#alpha_{T}>" << at[iat] << ") / " << ht_step[nht-1] << " GeV"; } else if ( choice == PLOT_DENOMINATOR ) { if ( efficiency ) { ss_axis << "Total"; } else { ss_axis << "N(#alpha_{T}<" << at[iat] << ") / " << ht_step[nht-1] << " GeV"; } } else if ( choice == PLOT_RATIO ) { if ( !efficiency ) { //ss_axis << "R_{#alpha_{T}}(" << at[iat] << ")"; if ( iat+1 < nat ) { ss_axis << "N(" << at[iat] << "<#alpha_{T}<" << at[iat+1] << ") / N(#alpha_{T}<" << at[iat] << ")"; } else { ss_axis << "N(#alpha_{T}>" << at[iat] << ") / N(#alpha_{T}<" << at[iat] << ")"; } } else { ss_axis << "#varepsilon(#alpha_{T}=" << at[iat] << ")"; } } else { ss_axis << "a.u."; } std::stringstream ss_flat; std::stringstream ss_line; std::stringstream ss_expo; for ( uint ifile = 0; ifile < nfile; ++ifile ) { std::stringstream ss_histo; ss_histo << name << "_" << type[ifile] << "_" << ss_canvas.str(); gStyle->SetOptFit(0); TGraphAsymmErrors* gr = new TGraphAsymmErrors(nht, valx[ifile][imulti][iat], valy[ifile][imulti][iat], errxh[ifile][imulti][iat], errxl[ifile][imulti][iat], erryl[ifile][imulti][iat], erryh[ifile][imulti][iat]); // Fitting if (true) { TGraphAsymmErrors* tmp_gr = new TGraphAsymmErrors(*gr); //tmp_gr->Fit("pol0","Q0","",valx[ifile][imulti][iat][0]-1.e-6,valx[ifile][imulti][iat][last_bin]+1.e-6); tmp_gr->Fit("pol0","Q0","",ht_min-1.e-6,ht_max+1.e-6); TF1* fit_c = (TF1*)tmp_gr->FindObject("pol0"); if ( fit_c ) { if ( ifile == 0 ) { ss_flat << "Constant (y=A):" << std::endl; } ss_flat << "" << type[ifile] << " " << std::setprecision(3) << fit_c->GetChisquare() << "/" << std::setprecision(0) << fit_c->GetNDF() << " (" << std::setprecision(3) << fit_c->GetProb() << ") " << std::endl << "" << type[ifile] << " " << std::scientific << std::setprecision(3) << "A: " << fit_c->GetParameter(0) << " +/- " << fit_c->GetParError(0) << std::endl; //yy.push_back( fit_c->GetProb() ); //@@ ADDED if ( (int)ifile == data_file ) { fits.push_back( fit_c->GetProb() ); } //rat.push_back( fit_c->GetParameter(0) ); } else { //yy.push_back( 0. ); //@@ ADDED std::cout << " NULL PTR! " << std::endl; } //tmp_gr->Fit("pol1","Q0","",valx[ifile][imulti][iat][0]-1.e-6,valx[ifile][imulti][iat][last_bin]+1.e-6); tmp_gr->Fit("pol1","Q0","",ht_min-1.e-6,ht_max+1.e-6); TF1* fit_l = (TF1*)tmp_gr->FindObject("pol1"); if ( fit_l ) { if ( ifile == 0 ) { ss_line << "Linear (y=A+Bx):" << std::endl; } ss_line << "" << type[ifile] << " " << std::setprecision(3) << fit_l->GetChisquare() << "/" << std::setprecision(0) << fit_l->GetNDF() << " (" << std::setprecision(3) << fit_l->GetProb() << ") " << std::endl << "" << type[ifile] << " " << std::scientific << std::setprecision(3) << "A: " << fit_l->GetParameter(0) << " +/- " << fit_l->GetParError(0) << " B: " << fit_l->GetParameter(1) << " +/- " << fit_l->GetParError(1) << std::endl; if ( (int)ifile == data_file ) { fits.push_back( fit_l->GetProb() ); } //rat.push_back( fit_l->GetParameter(0) ); } else { std::cout << " NULL PTR! " << std::endl; } //tmp_gr->Fit("expo","Q0","",valx[ifile][imulti][iat][0]-1.e-6,valx[ifile][imulti][iat][last_bin]+1.e-6); //TF1* fit_e = new TF1("expo+expo", tmp_gr->FindObject("expo"); //tmp_gr->Fit("expo","Q0","",ht_min-1.e-6,ht_max+1.e-6); tmp_gr->Fit("expo","Q0","",325.-1.e-6,675.+1.e-6); TF1* fit_e = (TF1*)tmp_gr->FindObject("expo"); if ( fit_e ) { if ( ifile == 0 ) { ss_expo << "Exponential (y=e^{A+kx}):" << std::endl; } ss_expo << "" << type[ifile] << " " << std::fixed << std::setprecision(3) << fit_e->GetChisquare() << "/" << std::setprecision(0) << fit_e->GetNDF() << " (" << std::setprecision(3) << fit_e->GetProb() << ") " << std::endl << "" << type[ifile] << " " << std::scientific << std::setprecision(3) << "A: " << fit_e->GetParameter(0) << " +/- " << fit_e->GetParError(0) << " k: " << fit_e->GetParameter(1) << " +/- " << fit_e->GetParError(1) << std::endl; if ( (int)ifile == data_file ) { fits.push_back( fit_e->GetProb() ); } rat.push_back( fit_e->GetParameter(1) ); } else { std::cout << " NULL PTR! " << std::endl; } //if (tmp_gr) delete tmp_gr; } for ( int ii = 0; ii < nht; ++ii ) { double x = 0.; double y = 0.; gr->GetPoint(ii,x,y); //if ( y == 0. ) { gr->SetPointEYhigh(ii,0.); gr->SetPointEYlow(ii,0.); } if (false) { std::cout << " sample:\"" << type[ifile] << "\"" << " multi: " << multi[imulti] << " aT:" << at[iat] << " HT:" << ht[ii] << " ARRAY x: " << valx[ifile][imulti][iat][ii] << " y: " << valy[ifile][imulti][iat][ii] << " + " << erryh[ifile][imulti][iat][ii] << " - " << erryl[ifile][imulti][iat][ii] << " HISTO x: " << x << " y: " << y << " + " << gr->GetErrorYhigh(ii) << " - " << gr->GetErrorYlow(ii) << std::endl; } } if ( nfile - ifile == 1 ) { //std::cout << ss_flat.str() << std::endl; //std::cout << ss_line.str() << std::endl; std::cout << ss_expo.str() << std::endl; } mg->Add(gr,"p"); std::stringstream ss_legend; ss_legend << type[ifile]; legend->AddEntry( gr, TString(ss_legend.str()), "p" ); gr->SetTitle(TString(ss_legend.str())); gr->SetMarkerStyle(style[ifile]); gr->SetMarkerSize(size[ifile]); gr->SetMarkerColor(col[ifile]); gr->SetLineColor(col[ifile]); } // ifile mg->Draw("a"); mg->GetXaxis()->SetTitle(label.c_str()); if (!use_meff) mg->GetXaxis()->SetTitle("H_{T} (GeV)"); else mg->GetXaxis()->SetTitle("M_{eff} (GeV)"); mg->GetYaxis()->SetTitle(TString(ss_axis.str())); mg->GetYaxis()->SetTitleOffset(1.3); mg->GetXaxis()->SetRangeUser(ht_min+offset,ht_max+offset); mg->GetYaxis()->SetRangeUser(min[imulti][iat]/2.0,max[imulti][iat]*1.2); //else mg->GetYaxis()->SetRangeUser(0.,0.12e-3); //mg->GetYaxis()->SetNoExponent(true); //mg->GetXaxis()->SetRangeUser(250,450.); //mg->GetYaxis()->SetRangeUser(0.,25.e-6); //mg->GetYaxis()->SetRangeUser(0.,0.05e-3); //mg->GetYaxis()->SetRangeUser(0.,0.04e-3); canvas->SetLogy(); //if (choice==1) mg->GetYaxis()->SetRangeUser(0.1,1.e4); //else if (choice==2) mg->GetYaxis()->SetRangeUser(0.1,1.e8); legend->Draw("same"); //prelim->Draw("same"); //lumitxt->Draw("same"); canvas->Update(); std::stringstream ss_text; ss_text << "#alpha_{T} = " << at[iat]; TLatex* text = new TLatex(0.5,0.92,TString(ss_text.str())); text->SetNDC(kTRUE); text->SetTextSize(0.04); //text->Draw(); //canvas->SaveAs(TString(name+"_"+ss_canvas.str()+".C")); //canvas->SaveAs(TString(name+"_"+ss_canvas.str()+".png")); //canvas->SaveAs(TString(name+"_"+ss_canvas.str()+".pdf")); //if (canvas) delete canvas; } // iat } // imulti int index = 0; std::vector<float> cuts; std::vector<float>::const_iterator ifit = fits.begin(); std::vector<float>::const_iterator jfit = fits.end(); for ( ; ifit != jfit; ++ifit ) { cuts.push_back(at[index]); index++; } //if ( !fits.empty() ) qcd(cuts,fits); // Draw RaT if ( false && !rat.empty() ) { bool plot_ratio = false; setTDRStyle(); gStyle->SetOptStat("emr"); TCanvas* c2 = new TCanvas("RaTvsEwkComposition","RaTvsEwkComposition"); c2->SetFillColor(0); c2->SetLineColor(0); TH1D* diff = 0; if ( !plot_ratio ) { diff = new TH1D("RaTvsEwkComposition","",1000,0.,1e-3); //diff = new TH1D("RaTvsEwkComposition","",1000,-20.,0.); for ( uint ifile = 0; ifile < nfile; ++ifile ) { std::cout << "sample: " << type[ifile] << " fit: " << rat[ifile] << std::endl; diff->Fill( rat[ifile], 1. ); } } else { diff = new TH1D("RaTvsEwkComposition","",200,0.6,1.4); for ( uint ifile = 1; ifile < nfile; ++ifile ) { std::cout << "sample: " << type[ifile] << " nominal: " << rat[0] << " ratio: " << rat[ifile]/rat[0] << std::endl; diff->Fill( rat[ifile]/rat[0], 1. ); } } c2->cd(); c2->SetRightMargin(0.12); c2->SetBottomMargin(0.15); diff->Draw("h"); if (!plot_ratio) diff->GetXaxis()->SetTitle("Best fit value"); else { //diff->GetXaxis()->SetTitle("Best fit value relative to nominal"); diff->GetXaxis()->SetTitle("R_{#alpha_{T}}^{(#pm15%)} / R_{#alpha_{T}}^{(nominal)}"); diff->GetXaxis()->SetTitleOffset(1.1); } diff->GetYaxis()->SetTitle("Number of tests with #pm15%"); if (!plot_ratio) c2->SaveAs("RaTvsEwkComposition.pdf"); else c2->SaveAs("RaTvsEwkComposition_ratio.pdf"); } // } // yy.resize(xx.size(),0.); // TCanvas* c1 = new TCanvas(); // TGraph* gr = new TGraph(nn, &(xx.front()), &(yy.front()) ); // c1->cd(); // gr->Draw("ap"); // //gr->SetBorderSize(0); // gr->SetTitle("Fit range: 325 < HT < 985"); // gr->GetXaxis()->SetTitle("Integrated Lumi (pb^{-1})"); // gr->GetYaxis()->SetTitle("p-value"); // c1->SaveAs("tmp.C"); // delete c1; // std::cout << std::endl; // for ( uint i = 0; i < nn; ++i ) { std::cout << xx[i] << std::endl; } // std::cout << std::endl; // for ( uint i = 0; i < nn; ++i ) { std::cout << yy[i] << std::endl; } // std::cout << std::endl; return 0; }