void dataMC() {
double xmin = 60.0;
double xmax = 160.0;
int nbins = 200;
TCanvas* c = new TCanvas("c", "c", 600, 600);
std::string hfile = "/home/avartak/CMS/HMuMu/CMSSW_8_0_26_patch1/src/HMuMuAnalysis/AnalysisStep/trees/GluGlu_HToMuMu_M125_13TeV_powheg_pythia8/trim.root";
std::string zfile = "/home/avartak/CMS/HMuMu/CMSSW_8_0_26_patch1/src/HMuMuAnalysis/AnalysisStep/trees/DYJetsToLL_M-50_TuneCUETP8M1_13TeV-amcatnloFXFX-pythia8/trim.root";
std::string tfile = "/home/avartak/CMS/HMuMu/CMSSW_8_0_26_patch1/src/HMuMuAnalysis/AnalysisStep/trees/TTJets_Dilept_TuneCUETP8M2T4_13TeV-amcatnloFXFX-pythia8/trim.root";
std::string dfile = "/home/avartak/CMS/HMuMu/CMSSW_8_0_26_patch1/src/HMuMuAnalysis/AnalysisStep/trees/SingleMuon/trim.root";
TFile* fileh = new TFile(hfile.c_str());
TFile* filez = new TFile(zfile.c_str());
TFile* filet = new TFile(tfile.c_str());
TFile* filed = new TFile(dfile.c_str());
TH1F* histh = new TH1F("histh", "", nbins, xmin, xmax);
TH1F* histz = new TH1F("histz", "", nbins, xmin, xmax);
TH1F* histt = new TH1F("histt", "", nbins, xmin, xmax);
TH1F* histd = new TH1F("histd", "", nbins, xmin, xmax);
TTree* treeh = (TTree*)fileh->Get("tree");
TTree* treez = (TTree*)filez->Get("tree");
TTree* treet = (TTree*)filet->Get("tree");
TTree* treed = (TTree*)filed->Get("tree");
treez->Draw("mass>>histz", "(cat > 0) * wgt");
treet->Draw("mass>>histt", "(cat > 0) * wgt");
treed->Draw("mass>>histd", "(cat > 0 && (mass < 120 || mass > 130))");
histz->SetFillColor(kCyan+1);
histt->SetFillColor(kOrange+1);
histz->SetLineWidth(2);
histt->SetLineWidth(2);
histh->SetLineWidth(2);
histz->Add(histt);
histz->Draw("HIST");
histt->Draw("HIST SAME");
histd->Draw("PE SAME");
c->RedrawAxis();
}
void
//HHH_TT_X_notag(bool scaled=true, bool log=true, float min=0.1, float max=-1., string inputfile="root/$HISTFILE", const char* directory="tauTau_$CATEGORY")
HHH_TT_X_notag(bool scaled=true, bool log=true, float min=0.1, float max=-1., string inputfile="root/$HISTFILE", const char* directory="tauTau_$CATEGORY")
{
// defining the common canvas, axes pad styles
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
// determine category tag
const char* category = ""; const char* category_extra = ""; const char* category_extra2 = "";
if(std::string(directory) == std::string("tauTau_2jet0tag")){ category = "#tau_{h}#tau_{h}"; }
if(std::string(directory) == std::string("tauTau_2jet0tag")){ category_extra= "2-jet 0 b-tag"; }
if(std::string(directory) == std::string("tauTau_2jet1tag" )){ category = "#tau_{h}#tau_{h}"; }
if(std::string(directory) == std::string("tauTau_2jet1tag" )){ category_extra= "2-jet 1 b-tag"; }
if(std::string(directory) == std::string("tauTau_2jet2tag" )){ category = "#tau_{h}#tau_{h}"; }
if(std::string(directory) == std::string("tauTau_2jet2tag" )){ category_extra = "2-jet 2 b-tag"; }
const char* dataset;
#ifdef MSSM
if(std::string(inputfile).find("7TeV")!=std::string::npos){dataset = "#scale[1.5]{CMS} h,H,A#rightarrow#tau#tau 4.9 fb^{-1} (7 TeV)";}
if(std::string(inputfile).find("8TeV")!=std::string::npos){
if(std::string(directory).find("btag")!=std::string::npos){
dataset = "#scale[1.5]{CMS} h,H,A#rightarrow#tau#tau 18.3 fb^{-1} (8 TeV)";
}
else{
dataset = "#scale[1.5]{CMS} H#rightarrow hh#rightarrow#tau#tau bb 19.7 fb^{-1} (8 TeV)";
}
}
#else
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "CMS, 19.7 fb^{-1} at 8 TeV";}
#endif
// open example histogram file
TFile* input = new TFile(inputfile.c_str());
#ifdef MSSM
TFile* input2 = new TFile((inputfile+"_$MH_$TANB").c_str());
#endif
TH1F* Fakes = refill((TH1F*)input->Get(TString::Format("%s/QCD" , directory)), "QCD"); InitHist(Fakes, "", "", TColor::GetColor(250,202,255), 1001);
TH1F* EWK1 = refill((TH1F*)input->Get(TString::Format("%s/W" , directory)), "W" ); InitHist(EWK1 , "", "", TColor::GetColor(222,90,106), 1001);
TH1F* EWK2 = refill((TH1F*)input->Get(TString::Format("%s/ZLL" , directory)), "ZLL" ); InitHist(EWK2 , "", "", TColor::GetColor(222,90,106), 1001);
//TH1F* EWK3 = refill((TH1F*)input->Get(TString::Format("%s/ZL" , directory)), "ZL" ); InitHist(EWK3 , "", "", TColor::GetColor(222,90,106), 1001);
TH1F* EWK = refill((TH1F*)input->Get(TString::Format("%s/VV" , directory)), "VV" ); InitHist(EWK , "", "", TColor::GetColor(222,90,106), 1001);
TH1F* ttbar = refill((TH1F*)input->Get(TString::Format("%s/TT" , directory)), "TT" ); InitHist(ttbar, "", "", TColor::GetColor(155,152,204), 1001);
TH1F* Ztt = refill((TH1F*)input->Get(TString::Format("%s/ZTT" , directory)), "ZTT"); InitHist(Ztt , "", "", TColor::GetColor(248,206,104), 1001);
#ifdef MSSM
TH1F* ggHTohhTo2Tau2B = refill((TH1F*)input2->Get(TString::Format("%s/ggHTohhTo2Tau2B$MH" , directory)), "ggHTohhTo2Tau2B"); InitSignal(ggHTohhTo2Tau2B); ggHTohhTo2Tau2B->Scale($TANB*SIGNAL_SCALE);
// if(std::string(directory)=="tauTau_2jet0tag") ggHTohhTo2Tau2B->Scale(4);
/* TH1F* ggH_SM125 = refill((TH1F*)input->Get(TString::Format("%s/ggH_SM125",directory)),"ggH_SM125");InitSignal(ggH_SM125);ggH_SM125->Scale(SIGNAL_SCALE);
TH1F* qqH_SM125 = refill((TH1F*)input->Get(TString::Format("%s/qqH_SM125",directory)),"qqH_SM125");InitSignal(qqH_SM125);qqH_SM125->Scale(SIGNAL_SCALE);
TH1F* VH_SM125 = refill((TH1F*)input->Get(TString::Format("%s/VH_SM125",directory)),"VH_SM125");InitSignal(VH_SM125);VH_SM125->Scale(SIGNAL_SCALE);
TH1F* WHToBB_SM125 = refill((TH1F*)input->Get(TString::Format("%s/WHToBB_SM125",directory)),"WHToBB_SM125");InitSignal(WHToBB_SM125);WHToBB_SM125->Scale(SIGNAL_SCALE);
TH1F* ZHToBB_SM125 = refill((TH1F*)input->Get(TString::Format("%s/ZHToBB_SM125",directory)),"ZHToBB_SM125");InitSignal(ZHToBB_SM125);ZHToBB_SM125->Scale(SIGNAL_SCALE);
*/
/*
TH1F* ggAToZhToLLTauTau = refill((TH1F*)input2->Get(TString::Format("%s/ggAToZhToLLTauTau$MH",directory)),"ggAToZhToLLTauTau"); InitSignal(ggAToZhToLLTauTau);
TH1F* ggAToZhToLLBB = refill((TH1F*)input2->Get(TString::Format("%s/ggAToZhToLLBB$MH",directory)),"ggAToZhToLLBB"); InitSignal(ggAToZhToLLBB);
TH1F* bbH = refill((TH1F*)input2->Get(TString::Format("%s/bbH$MH" , directory)), "bbH"); InitSignal(bbH);
*/
#endif
#ifdef ASIMOV
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs_asimov", directory)), "data", true);
#else
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs", directory)), "data",true);
#endif
InitHist(data, "#bf{m_{H} [GeV]}", "#bf{dN/dm_{H} [1/GeV]}"); InitData(data);
TH1F* ref=(TH1F*)Fakes->Clone("ref");
ref->Add(EWK1 );
ref->Add(EWK2 );
//ref->Add(EWK3 );
ref->Add(EWK );
ref->Add(ttbar);
ref->Add(Ztt );
double unscaled[8];
unscaled[0] = Fakes->Integral();
unscaled[1] = EWK ->Integral();
unscaled[1]+= EWK1 ->Integral();
unscaled[1]+= EWK2 ->Integral();
//unscaled[1]+= EWK3 ->Integral();
unscaled[2] = ttbar->Integral();
unscaled[3] = Ztt ->Integral();
#ifdef MSSM
unscaled[4] = ggHTohhTo2Tau2B ->Integral();
/* unscaled[5] = ggH_SM125->Integral();
unscaled[5]+= qqH_SM125->Integral();
unscaled[5]+= VH_SM125->Integral();
*/
/*
unscaled[5] = ggAToZhToLLTauTau->Integral();
unscaled[6] = ggAToZhToLLBB->Integral();
unscaled[7] = bbH ->Integral();
*/
#endif
if(scaled){
/* Fakes = refill(shape_histos(Fakes, datacard, "QCD"), "QCD");
EWK1 = refill(shape_histos(EWK1, datacard, "W"), "W");
EWK2 = refill(shape_histos(EWK2, datacard, "ZJ"), "ZJ");
EWK = refill(shape_histos(EWK, datacard, "VV"), "VV");
ttbar = refill(shape_histos(ttbar, datacard, "TT"), "TT");
Ztt = refill(shape_histos(Ztt, datacard, "ZTT"), "ZTT");
#ifdef MSSM
ggH = refill(shape_histos(ggH, datacard, "ggH$MH"), "ggH$MH");
bbH = refill(shape_histos(bbH, datacard, "bbH$MH"), "bbH$MH");
#else
ggH = refill(shape_histos(ggH, datacard, "ggH"), "ggH");
qqH = refill(shape_histos(qqH, datacard, "qqH"), "qqH");
VH = refill(shape_histos(VH, datacard, "VH"), "VH");
#endif
*/
rescale(Fakes, 7);
rescale(EWK1 , 3);
rescale(EWK2 , 4);
//rescale(EWK3 , 5);
rescale(EWK , 6);
rescale(ttbar, 2);
rescale(Ztt , 1);
#ifdef MSSM
rescale(ggHTohhTo2Tau2B , 8);
/*
rescale(ggAToZhToLLTauTau,9);
rescale(ggAToZhToLLBB,10);
rescale(bbH , 11);
*/
#endif
}
TH1F* scales[8];
scales[0] = new TH1F("scales-Fakes", "", 8, 0, 8);
scales[0]->SetBinContent(1, unscaled[0]>0 ? (Fakes->Integral()/unscaled[0]-1.) : 0.);
scales[1] = new TH1F("scales-EWK" , "", 8, 0, 8);
scales[1]->SetBinContent(2, unscaled[1]>0 ? ((EWK ->Integral()
+EWK1 ->Integral()
+EWK2 ->Integral()
//+EWK3 ->Integral()
)/unscaled[1]-1.) : 0.);
scales[2] = new TH1F("scales-ttbar", "", 8, 0, 8);
scales[2]->SetBinContent(3, unscaled[2]>0 ? (ttbar->Integral()/unscaled[2]-1.) : 0.);
scales[3] = new TH1F("scales-Ztt" , "", 8, 0, 8);
scales[3]->SetBinContent(4, unscaled[3]>0 ? (Ztt ->Integral()/unscaled[3]-1.) : 0.);
#ifdef MSSM
scales[4] = new TH1F("scales-ggHTohhTo2Tau2B" , "", 8, 0, 8);
scales[4]->SetBinContent(5, unscaled[4]>0 ? (ggHTohhTo2Tau2B ->Integral()/unscaled[4]-1.) : 0.);
/* scales[5] = new TH1F("scales-sm","",8,0,8);
scales[5]->SetBinContent(6, unscaled[5]>0 ? ((ggH_SM125->Integral()+qqH_SM125->Integral()+VH_SM125->Integral())/unscaled[5]-1.) : 0.);
*/
/*
scales[5] = new TH1F("scales-ggAToZhToLLTauTau" , "", 8, 0, 8);
scales[5]->SetBinContent(6, unscaled[5]>0 ? (ggAToZhToLLTauTau ->Integral()/unscaled[5]-1.) : 0.);
scales[6] = new TH1F("scales-ggAToZhToLLBB" , "", 8, 0, 8);
scales[6]->SetBinContent(7, unscaled[6]>0 ? (ggAToZhToLLBB ->Integral()/unscaled[6]-1.) : 0.);
scales[7] = new TH1F("scales-bbH" , "", 8, 0, 8);
scales[7]->SetBinContent(8, unscaled[7]>0 ? (bbH ->Integral()/unscaled[7]-1.) : 0.);
*/
#endif
//#ifdef MSSM
// qqH_SM125->Add(ggH_SM125);
// VH_SM125->Add(qqH_SM125);
// Fakes->Add(VH_SM125);
//#endif
Fakes->Add(ttbar);
EWK1 ->Add(Fakes);
EWK2 ->Add(Fakes );
//EWK3 ->Add(EWK2 );
//EWK ->Add(EWK3 );
EWK ->Add(EWK2 );
// ttbar->Add(EWK );
Ztt ->Add(EWK);
/*ggH_SM125->Add(qqH_SM125);
ggH_SM125->Add(VH_SM125);
ggH_SM125->Add(ZHToBB_SM125);
ggH_SM125->Add(WHToBB_SM125);
*/
//if(log){
//#ifdef MSSM
// ggH->Add(bbH);
//#else
// qqH->Add(VH );
// ggH->Add(qqH);
//#endif
// }
//else{
//#ifdef MSSM
// bbH->Add(Ztt);
// ggH->Add(bbH);
//#else
// VH ->Add(Ztt);
// qqH->Add(VH );
// ggH->Add(qqH);
//#endif
// }
/*
Mass plot before and after fit
*/
TCanvas *canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
if(log){ canv->SetLogy(1); }
#if defined MSSM
if(!log){ data->GetXaxis()->SetRange(200, data->FindBin(UPPER_EDGE)); } else{ data->GetXaxis()->SetRange(200, data->FindBin(UPPER_EDGE)); };
#else
data->GetXaxis()->SetRange(200, data->FindBin(UPPER_EDGE));
#endif
data->SetNdivisions(505);
data->SetMinimum(min);
data->SetMaximum(max>0 ? max : std::max(std::max(maximum(data, log), maximum(Ztt, log)), maximum(ggHTohhTo2Tau2B, log)));
data->Draw("e");
TH1F* errorBand = (TH1F*)Ztt ->Clone();
errorBand ->SetMarkerSize(0);
errorBand ->SetFillColor(13);
errorBand ->SetFillStyle(3013);
errorBand ->SetLineWidth(1);
for(int idx=0; idx<errorBand->GetNbinsX(); ++idx){
if(errorBand->GetBinContent(idx)>0){
std::cout << "Uncertainties on summed background samples: " << errorBand->GetBinError(idx)/errorBand->GetBinContent(idx) << std::endl;
break;
}
}
if(log){
Ztt ->Draw("histsame");
// ttbar->Draw("histsame");
EWK ->Draw("histsame");
Fakes->Draw("histsame");
ttbar->Draw("histsame");
//#ifdef MSSM
// VH_SM125->Draw("histsame");
//#endif
$DRAW_ERROR
ggHTohhTo2Tau2B ->Draw("histsame");
/* ggH_SM125->SetLineColor(kRed);
ggH_SM125->Draw("histsame");
*/
}
else{
Ztt ->Draw("histsame");
// ttbar->Draw("histsame");
EWK ->Draw("histsame");
Fakes->Draw("histsame");
ttbar->Draw("histsame");
#ifdef MSSM
//VH_SM125->Draw("histsame");
#endif
$DRAW_ERROR
ggHTohhTo2Tau2B ->Draw("histsame");
/*ggH_SM125->SetLineColor(kRed);
ggH_SM125->Draw("histsame");
*/
}
data->Draw("esame");
canv->RedrawAxis();
//CMSPrelim(dataset, "#tau_{h}#tau_{h}", 0.17, 0.835);
CMSPrelim(dataset, "", 0.16, 0.835);
#if defined MSSM
TPaveText* chan = new TPaveText(0.20, 0.74+0.061, 0.32, 0.74+0.161, "tlbrNDC");
if (strcmp(category_extra2,"")!=0) chan = new TPaveText(0.20, 0.69+0.061, 0.32, 0.74+0.161, "tlbrNDC");
#else
TPaveText* chan = new TPaveText(0.52, 0.35, 0.91, 0.55, "tlbrNDC");
#endif
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
chan->AddText(category);
chan->AddText(category_extra);
#if defined MSSM
if (strcmp(category_extra2,"")!=0) chan->AddText(category_extra2);
#else
chan->AddText(category_extra2);
#endif
chan->Draw();
/*
TPaveText* cat = new TPaveText(0.20, 0.71+0.061, 0.32, 0.71+0.161, "NDC");
cat->SetBorderSize( 0 );
cat->SetFillStyle( 0 );
cat->SetTextAlign( 12 );
cat->SetTextSize ( 0.05 );
cat->SetTextColor( 1 );
cat->SetTextFont ( 62 );
cat->AddText(category_extra);
cat->Draw();
TPaveText* cat2 = new TPaveText(0.20, 0.66+0.061, 0.32, 0.66+0.161, "NDC");
cat2->SetBorderSize( 0 );
cat2->SetFillStyle( 0 );
cat2->SetTextAlign( 12 );
cat2->SetTextSize ( 0.05 );
cat2->SetTextColor( 1 );
cat2->SetTextFont ( 62 );
cat2->AddText(category_extra2);
cat2->Draw();
*/
#ifdef MSSM
TPaveText* massA = new TPaveText(0.53, 0.44+0.061, 0.95, 0.44+0.151, "NDC");
massA->SetBorderSize( 0 );
massA->SetFillStyle( 0 );
massA->SetTextAlign( 12 );
massA->SetTextSize ( 0.03 );
massA->SetTextColor( 1 );
massA->SetTextFont ( 62 );
massA->AddText("MSSM m^{h}_{mod+} scenario");
massA->AddText("m_{H}=$MH GeV, tan#beta=$TANB");
massA->Draw();
#endif
#ifdef MSSM
TLegend* leg = new TLegend(0.53, 0.60, 0.95, 0.90);
SetLegendStyle(leg);
leg->AddEntry(ggHTohhTo2Tau2B , TString::Format("%0.f #times H#rightarrowhh#rightarrow#tau#taubb", SIGNAL_SCALE) , "L" );
//leg->AddEntry(ggH_SM125, TString::Format("%0.f #times SM H(125 GeV) #rightarrow #tau#tau/bb", SIGNAL_SCALE), "L");
#endif
#ifdef ASIMOV
leg->AddEntry(data , "sum(bkg) + H(125)" , "LP");
#else
leg->AddEntry(data , "Observed" , "LP");
#endif
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(EWK , "Electroweak" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
/*#ifdef MSSM
leg->AddEntry(VH_SM125, "SM H(125 GeV) #rightarrow #tau#tau", "F" );
#endif
*/
$ERROR_LEGEND
leg->Draw();
/*
Ratio Data over MC
*/
TCanvas *canv0 = MakeCanvas("canv0", "histograms", 600, 400);
canv0->SetGridx();
canv0->SetGridy();
canv0->cd();
TH1F* model = (TH1F*)Ztt ->Clone("model");
TH1F* test1 = (TH1F*)data->Clone("test1");
for(int ibin=0; ibin<test1->GetNbinsX(); ++ibin){
//the small value in case of 0 entries in the model is added to prevent the chis2 test from failing
model->SetBinContent(ibin+1, model->GetBinContent(ibin+1)>0 ? model->GetBinContent(ibin+1)*model->GetBinWidth(ibin+1) : 0.01);
model->SetBinError (ibin+1, CONSERVATIVE_CHI2 ? 0. : model->GetBinError (ibin+1)*model->GetBinWidth(ibin+1));
test1->SetBinContent(ibin+1, test1->GetBinContent(ibin+1)*test1->GetBinWidth(ibin+1));
test1->SetBinError (ibin+1, test1->GetBinError (ibin+1)*test1->GetBinWidth(ibin+1));
}
double chi2prob=0.;
double chi2ndof=0.;
double ksprob=0.;
double ksprobpe=0.;
if(!BLIND_DATA){
chi2prob = test1->Chi2Test (model,"PUW"); std::cout << "chi2prob:" << chi2prob << std::endl;
chi2ndof = test1->Chi2Test (model,"CHI2/NDFUW"); std::cout << "chi2ndf :" << chi2ndof << std::endl;
ksprob = test1->KolmogorovTest(model); std::cout << "ksprob :" << ksprob << std::endl;
ksprobpe = test1->KolmogorovTest(model,"DX"); std::cout << "ksprobpe:" << ksprobpe << std::endl;
}
std::vector<double> edges;
TH1F* zero = (TH1F*)ref->Clone("zero"); zero->Clear();
TH1F* rat1 = (TH1F*)data->Clone("rat1");
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
rat1->SetBinContent(ibin+1, Ztt->GetBinContent(ibin+1)>0 ? data->GetBinContent(ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
rat1->SetBinError (ibin+1, Ztt->GetBinContent(ibin+1)>0 ? data->GetBinError (ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
zero->SetBinContent(ibin+1, 0.);
zero->SetBinError (ibin+1, Ztt->GetBinContent(ibin+1)>0 ? Ztt ->GetBinError (ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
}
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
if(rat1->GetBinContent(ibin+1)>0){
edges.push_back(TMath::Abs(rat1->GetBinContent(ibin+1)-1.)+TMath::Abs(rat1->GetBinError(ibin+1)));
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
}
}
float range = 0.1;
std::sort(edges.begin(), edges.end());
if(edges.size()>1){
if (edges[edges.size()-2]>0.1) { range = 0.2; }
else if (edges[edges.size()-2]>0.2) { range = 0.5; }
else if (edges[edges.size()-2]>0.5) { range = 1.0; }
else if (edges[edges.size()-2]>1.0) { range = 1.5; }
else if (edges[edges.size()-2]>1.5) { range = 2.0; }
}
rat1->SetLineColor(kBlack);
rat1->SetFillColor(kGray );
rat1->SetMaximum(+range);
rat1->SetMinimum(-range);
rat1->GetYaxis()->CenterTitle();
rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
rat1->GetXaxis()->SetTitle("#bf{m_{H} [GeV]}");
rat1->Draw();
zero->SetFillStyle( 3013);
zero->SetFillColor(kBlack);
zero->SetLineColor(kBlack);
zero->SetMarkerSize(0.1);
zero->Draw("e2histsame");
canv0->RedrawAxis();
TPaveText* stat1 = new TPaveText(0.20, 0.76+0.061, 0.32, 0.76+0.161, "NDC");
stat1->SetBorderSize( 0 );
stat1->SetFillStyle( 0 );
stat1->SetTextAlign( 12 );
stat1->SetTextSize ( 0.05 );
stat1->SetTextColor( 1 );
stat1->SetTextFont ( 62 );
if(!BLIND_DATA){
stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f", chi2ndof, chi2prob));
}
//stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f, P(KS)=%.3f", chi2ndof, chi2prob, ksprob));
stat1->Draw();
/*
Ratio After fit over Prefit
*/
TCanvas *canv1 = MakeCanvas("canv1", "histograms", 600, 400);
canv1->SetGridx();
canv1->SetGridy();
canv1->cd();
edges.clear();
TH1F* rat2 = (TH1F*) Ztt->Clone("rat2");
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
rat2->SetBinContent(ibin+1, ref->GetBinContent(ibin+1)>0 ? Ztt->GetBinContent(ibin+1)/ref->GetBinContent(ibin+1) : 0);
rat2->SetBinError (ibin+1, ref->GetBinContent(ibin+1)>0 ? Ztt->GetBinError (ibin+1)/ref->GetBinContent(ibin+1) : 0);
}
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
if(rat2->GetBinContent(ibin+1)>0){
edges.push_back(TMath::Abs(rat2->GetBinContent(ibin+1)-1.)+TMath::Abs(rat2->GetBinError(ibin+1)));
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat2 ->SetBinContent(ibin+1, rat2->GetBinContent(ibin+1)-1.);
}
}
range = 0.1;
std::sort(edges.begin(), edges.end());
if(edges.size()>1){
if (edges[edges.size()-2]>0.1) { range = 0.2; }
if (edges[edges.size()-2]>0.2) { range = 0.5; }
if (edges[edges.size()-2]>0.5) { range = 1.0; }
if (edges[edges.size()-2]>1.0) { range = 1.5; }
if (edges[edges.size()-2]>1.5) { range = 2.0; }
}
#if defined MSSM
if(!log){ rat2->GetXaxis()->SetRange(200, rat2->FindBin(UPPER_EDGE)); } else{ rat2->GetXaxis()->SetRange(200, rat2->FindBin(UPPER_EDGE)); };
#else
rat2->GetXaxis()->SetRange(200, rat2->FindBin(UPPER_EDGE));
#endif
rat2->SetNdivisions(505);
rat2->SetLineColor(kRed+ 3);
rat2->SetMarkerColor(kRed+3);
rat2->SetMarkerSize(1.1);
rat2->SetMaximum(+range);
rat2->SetMinimum(-range);
rat2->GetYaxis()->SetTitle("#bf{Postfit/Prefit-1}");
rat2->GetYaxis()->CenterTitle();
rat2->GetXaxis()->SetTitle("#bf{m_{H} [GeV]}");
rat2->Draw();
zero->SetFillStyle( 3013);
zero->SetFillColor(kBlack);
zero->SetLineColor(kBlack);
zero->Draw("e2histsame");
canv1->RedrawAxis();
/*
Relative shift per sample
*/
TCanvas *canv2 = MakeCanvas("canv2", "histograms", 600, 400);
canv2->SetGridx();
canv2->SetGridy();
canv2->cd();
InitHist (scales[0], "", "", TColor::GetColor(250,202,255), 1001);
InitHist (scales[1], "", "", TColor::GetColor(222,90,106), 1001);
InitHist (scales[2], "", "", TColor::GetColor(155,152,204), 1001);
InitHist (scales[3], "", "", TColor::GetColor(248,206,104), 1001);
InitHist(scales[4],"","",kGreen+2,1001);
/* InitHist(scales[5],"","",kGreen+2,1001);
InitHist(scales[6],"","",kGreen+2,1001);
InitHist(scales[7],"","",kGreen+2,1001);
*/
scales[0]->Draw();
scales[0]->GetXaxis()->SetBinLabel(1, "#bf{Fakes}");
scales[0]->GetXaxis()->SetBinLabel(2, "#bf{EWK}" );
scales[0]->GetXaxis()->SetBinLabel(3, "#bf{ttbar}");
scales[0]->GetXaxis()->SetBinLabel(4, "#bf{Ztt}" );
#ifdef MSSM
scales[0]->GetXaxis()->SetBinLabel(5, "#bf{ggHTohhTo2tau2B}" );
/*
scales[0]->GetXaxis()->SetBinLabel(6, "#bf{ggAToZhToLLTauTau}");
scales[0]->GetXaxis()->SetBinLabel(7, "#bf{ggAToZhToLLBB}");
scales[0]->GetXaxis()->SetBinLabel(8, "#bf{bbH}" );
*/
#endif
scales[0]->SetMaximum(+0.5);
scales[0]->SetMinimum(-0.5);
scales[0]->GetYaxis()->CenterTitle();
scales[0]->GetYaxis()->SetTitle("#bf{Postfit/Prefit-1}");
scales[1]->Draw("same");
scales[2]->Draw("same");
scales[3]->Draw("same");
scales[4]->Draw("same");
/* scales[5]->Draw("same");
scales[6]->Draw("same");
*/
TH1F* zero_samples = (TH1F*)scales[0]->Clone("zero_samples"); zero_samples->Clear();
zero_samples->SetBinContent(1,0.);
zero_samples->Draw("same");
canv2->RedrawAxis();
/*
prepare output
*/
bool isSevenTeV = std::string(inputfile).find("7TeV")!=std::string::npos;
canv ->Print(TString::Format("%s_%sfit_%s_%s.png" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv ->Print(TString::Format("%s_%sfit_%s_%s.pdf" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv ->Print(TString::Format("%s_%sfit_%s_%s.eps" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
if(!log || FULLPLOTS)
{
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
}
if((!log && scaled) || FULLPLOTS)
{
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
}
TFile* output = new TFile(TString::Format("%s_%sfit_%s_%s.root", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"), "update");
output->cd();
data ->Write("data_obs");
Fakes->Write("Fakes" );
EWK ->Write("EWK" );
ttbar->Write("ttbar" );
Ztt ->Write("Ztt" );
#ifdef MSSM
ggHTohhTo2Tau2B ->Write("ggHTohhTo2Tau2B" );
/*
ggAToZhToLLTauTau->Write("ggAToZhToLLTauTau");
ggAToZhToLLBB->Write("ggAToZhToLLBB");
bbH ->Write("bbH" );
*/
#endif
output->Close();
delete errorBand;
delete model;
delete test1;
delete zero;
delete rat1;
delete rat2;
delete zero_samples;
delete ref;
}
void test()
{
style();
setLogBins(nlogfullimassbins,logfullimassmin,logfullimassmax,logfullimassbins);
float Mhat;
TCanvas* c = new TCanvas("c","c",600,400);
c->SetLogx();
c->SetLogy();
c->Draw();
c->cd();
TLegend* leg = new TLegend(0.6627517,0.6846449,0.7919463,0.8261126,NULL,"brNDC");
leg->SetFillStyle(4000); //will be transparent
leg->SetFillColor(0);
leg->SetTextFont(42);
TFile fLoose("/data/hod/2011/NTUPLE/analysisLocalControl_TightLoose.root", "READ");
TTree* tLoose = (TTree*)fLoose.Get("allCuts/allCuts_tree");
tLoose->SetBranchAddress("Mhat", &Mhat);
Int_t nLoose = tLoose->GetEntries();
TH1D* hLoose = new TH1D("hLoose","tight-loose vs. tight-tight selection;m_{#mu#mu} TeV;Events",nlogfullimassbins,logfullimassbins);
hLoose->SetLineColor(kRed);
hLoose->SetMarkerColor(kRed);
hLoose->SetMarkerStyle(24);
hLoose->SetMarkerSize(0.8);
hLoose->SetMinimum(1.e-3);
hLoose->SetMaximum(7.e+5);
hLoose->GetXaxis()->SetMoreLogLabels();
hLoose->GetXaxis()->SetNoExponent();
leg->AddEntry(hLoose,"tight-loose","lep");
for(Int_t i=0 ; i<nLoose ; i++)
{
tLoose->GetEntry(i);
hLoose->Fill(Mhat*TeV2GeV);
}
TFile fTight("/data/hod/2011/NTUPLE/analysisLocalControl.root", "READ");
TTree* tTight = (TTree*)fTight.Get("allCuts/allCuts_tree");
tTight->SetBranchAddress("Mhat", &Mhat);
Int_t nTight = tTight->GetEntries();
TH1D* hTight = new TH1D("hTight","tight-loose vs. tight-tight selection;m_{#mu#mu} TeV;Events",nlogfullimassbins,logfullimassbins);
hTight->SetLineColor(kBlack);
hTight->SetMarkerColor(kBlack);
hTight->SetMarkerStyle(24);
hTight->SetMarkerSize(0.8);
hTight->SetMinimum(1.e-3);
hTight->SetMaximum(7.e+5);
hTight->GetXaxis()->SetMoreLogLabels();
hTight->GetXaxis()->SetNoExponent();
leg->AddEntry(hTight,"tight-tight","lep");
for(Int_t i=0 ; i<nTight ; i++)
{
tTight->GetEntry(i);
hTight->Fill(Mhat*TeV2GeV);
}
hTight->Draw("e1x1");
hLoose->Draw("e1x1SAMES");
leg->Draw("SAMES");
c->RedrawAxis();
c->SaveAs("plots/Wjets.png");
}
void
postfit_use(const char* inputfile, const char* analysis = "SM", const char* dataset = "2011+2012", const char* extra="", const char* extra2="", float min=0.1, float max=-1., bool log=true)
{
// defining the common canvas, axes pad styles
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
// switch for MSSM/SM
bool MSSM = std::string(analysis) == std::string("MSSM");
// determine label
if (std::string(dataset) == std::string("2011" )){ dataset = "CMS Preliminary, H#rightarrow#tau#tau, 4.9 fb^{-1} at 7 TeV"; }
if (std::string(dataset) == std::string("2012" )){ dataset = "CMS Preliminary, H#rightarrow#tau#tau, 19.8 fb^{-1} at 8 TeV"; }
if (std::string(dataset) == std::string("2011+2012")){ dataset = "CMS Preliminary, H#rightarrow#tau#tau, 4.9 fb^{-1} at 7 TeV, 19.8 fb^{-1} at 8 TeV"; }
// determine category tag
const char* category_extra = "";
if(std::string(extra2) == std::string("0jet_low" )){ category_extra = "0 jet, low p_{T}"; }
if(std::string(extra2) == std::string("0jet_high" )){ category_extra = "0 jet, high p_{T}"; }
if(std::string(extra2) == std::string("0jet" )){ category_extra = "0 jet"; }
if(std::string(extra2) == std::string("1jet_low" )){ category_extra = "1 jet, low p_{T}"; }
if(std::string(extra2) == std::string("1jet_high" )){ category_extra = "1 jet, high p_{T}"; }
if(std::string(extra2) == std::string("1jet" )){ category_extra = "1 jet"; }
if(std::string(extra2) == std::string("vbf" )){ category_extra = "2 jet (VBF)"; }
if(std::string(extra2) == std::string("nobtag" )){ category_extra = "No B-Tag"; }
if(std::string(extra2) == std::string("btag" )){ category_extra = "B-Tag"; }
TFile* input = new TFile(inputfile);
TH1F* Fakes = refill((TH1F*)input->Get("Fakes" ), "Fakes/QCD");
TH1F* EWK = refill((TH1F*)input->Get("EWK" ), "EWK" );
TH1F* ttbar = refill((TH1F*)input->Get("ttbar" ), "ttbar" );
TH1F* Ztt = refill((TH1F*)input->Get("Ztt" ), "Ztt" );
TH1F* Zmm = refill((TH1F*)input->Get("Zmm" ), "Zmm" );
TH1F* Zee = refill((TH1F*)input->Get("Zee" ), "Zee" );
TH1F* ggH = refill((TH1F*)input->Get("ggH" ), "ggH" );
TH1F* data = (TH1F*)input->Get("data_obs");
// determine channel for etau Z->ee (EWK) will be shown separated from the rest (EWK1)
TH1F* EWK1 = 0;
if(std::string(extra) == std::string("e#tau_{h}")){
EWK1 = refill((TH1F*)input->Get("EWK1"), "EWK1");
}
TH1F* ggH_hww = 0;
if(std::string(extra) == std::string("e#mu") and HWWBG){
ggH_hww= refill((TH1F*)input->Get("ggH_hww" ), "ggH_hww" );
}
TH1F* errorBand = (TH1F*)input->Get("errorBand");
/*
mass plot before and after fit
*/
TCanvas *canv = MakeCanvas("canv", "histograms", 600, 600);
if(log) canv->SetLogy(1);
// reduce the axis range if necessary for linea plots and SM
if(MSSM && !log){ data->GetXaxis()->SetRange(0, data->FindBin(345)); } else{ data->GetXaxis()->SetRange(0, data->FindBin(UPPER_EDGE)); };
if(!MSSM){ data->GetXaxis()->SetRange(0, data->FindBin(345)); }
data->SetNdivisions(505);
data->SetMinimum(min);
if(std::string(extra) == std::string("#mu#mu")){
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(Zmm, log)));
data->Draw("e");
if(log){
Zmm ->Draw("same");
Ztt ->Draw("same");
ttbar->Draw("same");
Fakes->Draw("same");
EWK ->Draw("same");
if(ggH) ggH ->Draw("histsame");
}
}
else if(std::string(extra) == std::string("ee")){
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(Zee, log)));
data->Draw("e");
if(log){
Zee ->Draw("same");
Ztt ->Draw("same");
ttbar->Draw("same");
Fakes->Draw("same");
EWK ->Draw("same");
if(ggH) ggH ->Draw("histsame");
}
}
else if(std::string(extra) == std::string("e#tau_{h}")){
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(Ztt, log)));
data->Draw("e");
if(log){
Ztt ->Draw("same");
ttbar->Draw("same");
EWK ->Draw("same");
EWK1 ->Draw("same");
Fakes->Draw("same");
if(ggH) ggH ->Draw("histsame");
}
else{
if(ggH) ggH ->Draw("histsame");
Ztt ->Draw("same");
ttbar->Draw("same");
EWK ->Draw("same");
EWK1 ->Draw("same");
Fakes->Draw("same");
}
}
else if(std::string(extra) == std::string("e#mu") && HWWBG){
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(ggH_hww, log)));
data->Draw("e");
if(log){
ggH_hww -> Draw("same");
Ztt ->Draw("same");
ttbar->Draw("same");
EWK ->Draw("same");
Fakes->Draw("same");
if(ggH) ggH ->Draw("histsame");
}
else{
if(ggH) ggH ->Draw("histsame");
ggH_hww -> Draw("same");
Ztt ->Draw("same");
ttbar->Draw("same");
EWK ->Draw("same");
Fakes->Draw("same");
}
}
else{
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(Ztt, log)));
data->Draw("e");
if(log){
Ztt ->Draw("same");
ttbar->Draw("same");
EWK ->Draw("same");
Fakes->Draw("same");
if(ggH) ggH ->Draw("histsame");
}
else{
if(ggH) ggH ->Draw("histsame");
Ztt ->Draw("same");
ttbar->Draw("same");
EWK ->Draw("same");
Fakes->Draw("same");
}
}
if(errorBand){
errorBand->Draw("e2same");
}
data->Draw("esame");
canv->RedrawAxis();
//CMSPrelim(dataset, extra, 0.17, 0.835);
CMSPrelim(dataset, "", 0.18, 0.835);
TPaveText* chan = new TPaveText(0.20, 0.74+0.061, 0.32, 0.74+0.161, "NDC");
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
chan->AddText(extra);
chan->Draw();
TPaveText* cat = new TPaveText(0.20, 0.68+0.061, 0.32, 0.68+0.161, "NDC");
cat->SetBorderSize( 0 );
cat->SetFillStyle( 0 );
cat->SetTextAlign( 12 );
cat->SetTextSize ( 0.05 );
cat->SetTextColor( 1 );
cat->SetTextFont ( 62 );
cat->AddText(category_extra);
cat->Draw();
if(MSSM){
float lower_bound = EWK1 ? 0.45 : 0.50;
TPaveText* massA = new TPaveText(0.55, lower_bound+0.061, 0.95, lower_bound+0.161, "NDC");
massA->SetBorderSize( 0 );
massA->SetFillStyle( 0 );
massA->SetTextAlign( 12 );
massA->SetTextSize ( 0.03 );
massA->SetTextColor( 1 );
massA->SetTextFont ( 62 );
massA->AddText("m^{h}_{max} (m_{A}=$MA GeV, tan#beta=$TANB)");
massA->Draw();
}
float lower_bound = EWK1 ? 0.60 : 0.65;
TLegend* leg = new TLegend(MSSM ? 0.55 : 0.50, lower_bound, 0.93, 0.90);
SetLegendStyle(leg);
if(MSSM){
leg->AddEntry(ggH , "#phi#rightarrow#tau#tau", "L" );
}
else{
if(ggH){
if(SIGNAL_SCALE!=1){
leg->AddEntry(ggH , TString::Format("%.0f#timesH(125 GeV)#rightarrow#tau#tau", SIGNAL_SCALE) , "L" );
}
else{
leg->AddEntry(ggH , "H(125 GeV)#rightarrow#tau#tau" , "L" );
}
}
}
leg->AddEntry(data , "observed" , "LP");
if(std::string(extra) == std::string("#mu#mu")){
leg->AddEntry(Zmm , "Z#rightarrow#mu#mu" , "F" );
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
leg->AddEntry(EWK , "electroweak" , "F" );
}
else if(std::string(extra) == std::string("ee")){
leg->AddEntry(Zee , "Z#rightarrowee" , "F" );
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
leg->AddEntry(EWK , "electroweak" , "F" );
}
else if(std::string(extra) == std::string("e#tau_{h}")){
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(EWK , "Z#rightarrow ee" , "F" );
leg->AddEntry(EWK1 , "electroweak" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
}
else if(std::string(extra) == std::string("e#mu") && HWWBG){
leg->AddEntry(ggH_hww , "H(125 GeV)#rightarrowWW" , "F" );
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
leg->AddEntry(EWK , "electroweak" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
}
else{
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
leg->AddEntry(EWK , "electroweak" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
}
if(errorBand){
leg->AddEntry(errorBand, "bkg. uncertainty" , "F" );
}
leg->Draw();
/*
prepare output
*/
std::string newName = std::string(inputfile).substr(0, std::string(inputfile).find(".root"));
canv->Print(TString::Format("%s.png", newName.c_str()));
canv->Print(TString::Format("%s.pdf", newName.c_str()));
canv->Print(TString::Format("%s.eps", newName.c_str()));
/*
Ratio Data over MC
*/
TCanvas *canv0 = MakeCanvas("canv0", "histograms", 600, 400);
canv0->SetGridx();
canv0->SetGridy();
canv0->cd();
TH1F* model;
if(CONSERVATIVE_CHI2){
if(std::string(extra) == std::string("#mu#mu")){
model = (TH1F*)Zmm ->Clone("model");
}
else if(std::string(extra) == std::string("ee")){
model = (TH1F*)Zee ->Clone("model");
}
else if(std::string(extra) == std::string("e#mu") && HWWBG){
model = (TH1F*)ggH_hww ->Clone("model");
}
else{
model = (TH1F*)Ztt ->Clone("model");
}
}
else{
model = (TH1F*)errorBand->Clone("model");
}
TH1F* test1 = (TH1F*)data->Clone("test1");
for(int ibin=0; ibin<test1->GetNbinsX(); ++ibin){
//the small value in case of 0 entries in the model is added to prevent the chis2 test from failing
model->SetBinContent(ibin+1, model->GetBinContent(ibin+1)>0 ? model->GetBinContent(ibin+1)*model->GetBinWidth(ibin+1) : 0.01);
model->SetBinError (ibin+1, CONSERVATIVE_CHI2 ? 0. : model->GetBinError (ibin+1)*model->GetBinWidth(ibin+1));
test1->SetBinContent(ibin+1, test1->GetBinContent(ibin+1)*test1->GetBinWidth(ibin+1));
test1->SetBinError (ibin+1, test1->GetBinError (ibin+1)*test1->GetBinWidth(ibin+1));
}
double chi2prob = test1->Chi2Test (model,"PUW"); std::cout << "chi2prob:" << chi2prob << std::endl;
double chi2ndof = test1->Chi2Test (model,"CHI2/NDFUW"); std::cout << "chi2ndf :" << chi2ndof << std::endl;
double ksprob = test1->KolmogorovTest(model); std::cout << "ksprob :" << ksprob << std::endl;
double ksprobpe = test1->KolmogorovTest(model,"DX"); std::cout << "ksprobpe:" << ksprobpe << std::endl;
std::vector<double> edges;
TH1F* zero = (TH1F*)Ztt->Clone("zero"); zero->Clear();
TH1F* rat1 = (TH1F*)data->Clone("rat");
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
rat1->SetBinContent(ibin+1, errorBand->GetBinContent(ibin+1)>0 ? data->GetBinContent(ibin+1)/errorBand->GetBinContent(ibin+1) : 0);
rat1->SetBinError (ibin+1, errorBand->GetBinContent(ibin+1)>0 ? data->GetBinError (ibin+1)/errorBand->GetBinContent(ibin+1) : 0);
zero->SetBinContent(ibin+1, 0.);
zero->SetBinError (ibin+1, errorBand->GetBinContent(ibin+1)>0 ? errorBand ->GetBinError (ibin+1)/errorBand->GetBinContent(ibin+1) : 0);
}
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
if(rat1->GetBinContent(ibin+1)>0){
edges.push_back(TMath::Abs(rat1->GetBinContent(ibin+1)-1.)+TMath::Abs(rat1->GetBinError(ibin+1)));
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
}
zero->SetBinContent(ibin+1, 0.);
}
float range = 0.1;
std::sort(edges.begin(), edges.end());
if (edges[edges.size()-2]>0.1) { range = 0.2; }
if (edges[edges.size()-2]>0.2) { range = 0.5; }
if (edges[edges.size()-2]>0.5) { range = 1.0; }
if (edges[edges.size()-2]>1.0) { range = 1.5; }
if (edges[edges.size()-2]>1.5) { range = 2.0; }
rat1->SetLineColor(kBlack);
rat1->SetFillColor(kGray );
rat1->SetMaximum(+range);
rat1->SetMinimum(-range);
rat1->GetYaxis()->CenterTitle();
rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
if((std::string(extra) == std::string("#mu#mu") || std::string(extra) == std::string("ee")) && !MSSM){
rat1->GetXaxis()->SetTitle("#bf{D}");
}
else{
rat1->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
}
rat1->Draw();
zero->SetFillStyle( 3013);
zero->SetFillColor(kBlack);
zero->SetLineColor(kBlack);
zero->SetMarkerSize(0.1);
zero->Draw("e2histsame");
canv0->RedrawAxis();
TPaveText* stat1 = new TPaveText(0.20, 0.76+0.061, 0.32, 0.76+0.161, "NDC");
stat1->SetBorderSize( 0 );
stat1->SetFillStyle( 0 );
stat1->SetTextAlign( 12 );
stat1->SetTextSize ( 0.05 );
stat1->SetTextColor( 1 );
stat1->SetTextFont ( 62 );
stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f", chi2ndof, chi2prob));
//stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f, P(KS)=%.3f", chi2ndof, chi2prob, ksprob));
stat1->Draw();
/*
prepare output
*/
newName = std::string(inputfile).substr(0, std::string(inputfile).find(".root")) + "_datamc";
canv0->Print(TString::Format("%s.png", newName.c_str()));
canv0->Print(TString::Format("%s.pdf", newName.c_str()));
canv0->Print(TString::Format("%s.eps", newName.c_str()));
}
void massPlot(double lumi=-1., double maxInstLumi=-1.) {
setTDRStyle();
//tdrGrid(false, tdrStyle);
writeExtraText = true;
//extraText = "Preliminary Simulation";
//lumi_8TeV = "";
int iPeriod = 2; // 1=7TeV, 2=8TeV, 3=7+8TeV, 7=7+8+13TeV
//int iPos=0;
int iPos=11;
//int iPos=22;
if (lumi<0)
lumi=LUMI;
if (maxInstLumi<0)
maxInstLumi=MAXINSTLUMI;
DifferentXSLimitPlots plots(lumi);
//mchamp index 0 is used, corresponds to 0th mass point = 100 GeV
plots.calculateCrossSections(0,0,0,39,9);
// three points on counting expt curve
//TGraph* g_obs_gluino = plots.getMassLimitGluino();
TGraph* g_gluino = plots.getExpMassLimitGluino();
//TGraph* g_obs_stop = plots.getMassLimitStop();
TGraph* g_stop = plots.getExpMassLimitStop();
TGraph* g_obs_mchamp = plots.getMassLimitMchamp();
TGraph* g_mchamp = plots.getExpMassLimitMchamp();
//TGraphAsymmErrors* g_expGluino_1sig = plots.getExpMassLimitGluino1Sig();
//TGraphAsymmErrors* g_expGluino_2sig = plots.getExpMassLimitGluino2Sig();
//TGraphAsymmErrors* g_expStop_1sig = plots.getExpMassLimitStop1Sig();
//TGraphAsymmErrors* g_expStop_2sig = plots.getExpMassLimitStop2Sig();
TGraphAsymmErrors* g_exp_1sig = plots.getExpMassLimitMchamp1Sig();
TGraphAsymmErrors* g_exp_2sig = plots.getExpMassLimitMchamp2Sig();
// one point from lifetime fit
TGraph* g_tpg = plots.getMassLimitGluinoTP();
TGraph* g_tps = plots.getMassLimitStopTP();
// theory prediction
TGraph* g_thGluino = plots.getGluinoTheory();
TGraph* g_thStop = plots.getStopTheory();
TGraph* g_thMchamp = plots.getMchampTheory();
TCanvas* canvas = new TCanvas("canvas","",10,10,575,500);
Double_t x[10], yMinus[10], x2[10], y[10], yPlus[10], z[10];
cout<<"MCHAMP LIMITS ARE: "<<endl;
for(Int_t i=0; i<g_mchamp->GetN(); i++){
g_mchamp->GetPoint(i, x[i], y[i]);
yPlus[i] = g_exp_1sig->GetErrorYhigh(i);
yMinus[i] = g_exp_1sig->GetErrorYlow(i);
g_obs_mchamp->GetPoint(i, x2[i], z[i]);
cout<<" mass is: "<<x[i]<<", expected limit is: "<<y[i]<<", expected +1 sigma is: "<<yPlus[i]<<", expected -1 sigma is: "<<yMinus[i]<<", observed limit is: "<<z[i]<<endl;
}
//canvas->SetGrid();
canvas->SetLogy();
TH1 * h;
//h = canvas->DrawFrame(100., 1e-5, 1500., 1e6); //2DSA gluios and stops
h = canvas->DrawFrame(100., 1e-5, 1000., 1e3); //2DSA
//h = canvas->DrawFrame(100., 1e-5, 1000., 1e4); //1DSA
//h->SetTitle(";m [GeV];#sigma [pb]");
h->SetTitle(";m_{mchamp} [GeV];#sigma(pp #rightarrow mchamp mchamp) [pb]");
//h->SetTitle(";m_{mchamp} [GeV];#sigma(pp #rightarrow mch mch) #times BF(mch #rightarrow #mu#mu) [pb]");
//h->SetTitle("Beamgap Expt;m_{#tilde{g}} [GeV/c^{2}]; #sigma(pp #rightarrow #tilde{g}#tilde{g}) #times BR(#tilde{g} #rightarrow g#tilde{#chi}^{0}) [pb]");
// not covered region
TBox* nc = new TBox(100., .1, 150., 5e2);
nc->SetFillStyle(3354);
nc->SetFillColor(kRed-4);
//nc->Draw();
/*
// details
//TPaveText* blurb = new TPaveText(305., 1.e1, 550., 4.5e2);
TPaveText* blurb = new TPaveText(0.25, 0.70, 0.50, 0.92, "NDC");
blurb->AddText("CMS Preliminary 2012");
std::stringstream label;
label<<"#int L dt = 19.7 fb^{-1}";
blurb->AddText(label.str().c_str());
label.str("");
double peakInstLumi=maxInstLumi;
int exponent=30;
while (peakInstLumi>10) {
peakInstLumi/=10.;
++exponent;
}
//label<<"L^{max}_{inst} = "<<peakInstLumi<<" x 10^{"<<exponent<<"} cm^{-2}s^{-1}";
//blurb->AddText(label.str().c_str());
//label.str("");
label << "#sqrt{s} = " << ENERGY << " TeV";
blurb->AddText(label.str().c_str());
//blurb->AddText("m_{#tilde{g}} - m_{#tilde{#chi}^{0}} = 100 GeV/c^{2}");
//blurb->AddText("m_{#tilde{t}} - m_{#tilde{#chi}^{0}} = 180 GeV/c^{2}");
blurb->SetTextFont(42);
blurb->SetBorderSize(0);
blurb->SetFillColor(0);
blurb->SetShadowColor(0);
blurb->SetTextAlign(12);
blurb->SetTextSize(0.033);
*/
// legend
TBox *legbg = new TBox(600., 1.e1, 900., 4e2);
//legbg->Draw();
//TLegend *leg = new TLegend(600., 1.e1, 900., 4e2,"95% C.L. Limits","");
//TLegend* leg = new TLegend(0.67, 0.70, 0.82, 0.92,"95% CL Limits:","NDC");
/////////TLegend* leg = new TLegend(0.52, 0.70, 0.77, 0.92,"95% CL Limits:","NDC");
TLegend* leg = new TLegend(0.45, 0.70, 0.70, 0.92,"95% CL Limits:","NDC");
leg->SetTextSize(0.033);
leg->SetBorderSize(0);
leg->SetTextFont(42);
leg->SetFillColor(0);
leg->AddEntry(g_obs_mchamp, "Observed, 10 #mus - 1000 s", "lp");
leg->AddEntry(g_mchamp, "Expected, 10 #mus - 1000 s", "l");
leg->AddEntry(g_exp_1sig, "Expected #pm1#sigma, 10 #mus - 1000 s", "lf");
leg->AddEntry(g_exp_2sig, "Expected #pm2#sigma, 10 #mus - 1000 s", "lf");
leg->AddEntry(g_thMchamp, "LO Prediction", "l");
/*
leg->AddEntry(g_gluino, "Expected Gluino Limit, 10 #mus - 1000 s", "l");
leg->AddEntry(g_thGluino, "Gluino LO Prediction", "l");
leg->AddEntry(g_stop, "Expected Stop Limit, 10 #mus - 1000 s", "l");
leg->AddEntry(g_thStop, "Stop LO Prediction", "l");
*/
//leg->AddEntry(g_thGluino, "NLO+NLL #tilde{g}", "l");
//leg->AddEntry(g_gluino, "Obs.: 10 #mus - 1000 s Counting Exp. (#tilde{g})", "l");
//leg->AddEntry(g_tpg, "Obs.: 10 #mus Timing Profile (#tilde{g})", "l");
//leg->AddEntry(g_thStop, "NLO+NLL #tilde{t}", "l");
//leg->AddEntry(g_stop, "Obs.: 10 #mus - 1000 s Counting Exp. (#tilde{t})", "l");
//leg->AddEntry(g_tps, "Obs.: 10 #mus Timing Profile (#tilde{t})", "l");
//leg->AddEntry(graph_em, "Obs.: 10 #mus - 1000 s Counting Exp. (EM only)", "l");
// leg->AddEntry(graph1, "Obs.: 570 ns Counting Exp.", "l");
leg->Draw();
/*
// gluino curves
g_gluino->SetLineColor(kBlue);
g_gluino->SetLineStyle(2);
g_gluino->SetLineWidth(3);
g_gluino->Draw("l");
g_tpg->SetLineColor(kBlue);
g_tpg->SetLineStyle(3);
g_tpg->SetLineWidth(3);
//g_tpg->Draw("l");
// theory line
g_thGluino->SetLineColor(kGreen);
g_thGluino->SetLineStyle(1);
g_thGluino->SetLineWidth(2);
g_thGluino->SetFillStyle(3001);
g_thGluino->SetFillColor(kGreen-4);
g_thGluino->Draw("l3");
// stop curves
g_stop->SetLineColor(kRed);
g_stop->SetLineStyle(2);
g_stop->SetLineWidth(2);
g_stop->Draw("l");
g_tps->SetLineColor(kRed);
g_tps->SetLineStyle(3);
g_tps->SetLineWidth(3);
//g_tps->Draw("l");
g_thStop->SetLineColor(kOrange);
g_thStop->SetLineStyle(1);
g_thStop->SetLineWidth(2);
g_thStop->SetFillStyle(3001);
g_thStop->SetFillColor(kOrange-4);
g_thStop->Draw("l3");
*/
// mchamp curves
// 2 sigma band
g_exp_2sig->SetLineColor(0);
g_exp_2sig->SetLineStyle(0);
g_exp_2sig->SetLineWidth(0);
g_exp_2sig->SetFillColor(kYellow);
g_exp_2sig->SetFillStyle(1001);
g_exp_2sig->Draw("3");
// 1 sigma band
// g_exp_1sig->SetLineColor(8);
g_exp_1sig->SetLineColor(0);
g_exp_1sig->SetLineStyle(0);
g_exp_1sig->SetLineWidth(0);
// g_exp_1sig->SetFillColor(8);
g_exp_1sig->SetFillColor(kGreen);
g_exp_1sig->SetFillStyle(1001);
// g_exp_1sig->SetFillStyle(3005);
g_exp_1sig->Draw("3");
// g_exp_1sig->Draw("lX");
g_obs_mchamp->SetLineStyle(1);
g_obs_mchamp->SetLineWidth(2);
g_obs_mchamp->SetMarkerStyle(20);
g_obs_mchamp->SetMarkerSize(1);
g_obs_mchamp->Draw("pl");
//g_mchamp->SetLineColor(kBlue);
g_mchamp->SetLineStyle(2);
//g_mchamp->SetLineStyle(1);
g_mchamp->SetLineWidth(3);
g_mchamp->SetMarkerStyle(20);
g_mchamp->SetMarkerSize(1);
g_mchamp->Draw("l");
// theory line
g_thMchamp->SetLineColor(kRed);
g_thMchamp->SetLineStyle(1);
g_thMchamp->SetLineWidth(2);
g_thMchamp->SetFillStyle(3001);
g_thMchamp->SetFillColor(kRed-4);
g_thMchamp->Draw("l3");
// theory line label
TLatex* th = new TLatex(480., 4., "NLO+NLL #tilde{g}");
th->SetTextColor(kBlue);
th->SetTextFont(42);
th->SetTextSize(0.035);
//th->Draw();
TLatex* ths = new TLatex(330., 2., "NLO+NLL #tilde{t}");
ths->SetTextColor(kRed);
ths->SetTextFont(42);
ths->SetTextSize(0.035);
//ths->Draw();
TLatex* thm = new TLatex(480., 4., "NLO+NLL mchamp");
//thm->SetTextColor(kBlue);
thm->SetTextFont(42);
thm->SetTextSize(0.035);
//thm->Draw();
// not explored label
TText* ne = new TText(125., .2, "Not Sensitive");
ne->SetTextColor(kRed+1);
ne->SetTextFont(42);
ne->SetTextAngle(90);
ne->SetTextSize(0.035);
//ne->Draw();
//blurb->Draw();
canvas->RedrawAxis();
CMS_lumi(canvas, iPeriod, iPos);
canvas->Print("massLimit.pdf");
canvas->Print("massLimit.png");
canvas->Print("massLimit.C");
plots.calculateIntercepts();
TFile* fnew = new TFile("histos.root", "recreate");
fnew->cd();
g_obs_mchamp->Write();
g_mchamp->Write();
g_thMchamp->Write();
}
void toyMC(int nsteps = 1e6) {
Float_t LA = 9.2;
Float_t LB = 10.3;
Float_t SF = 492./LB;
Float_t eSF = TMath::Sqrt(23.*23.+19.7*19.7)/LB;
// Float_t OF = 358./LA;
// Float_t eOF = 27./LA;
Float_t OF = 358./LB;
Float_t eOF = 31./LB;
Float_t SigB = 188.+238-414;
TH1F* hSig = new TH1F("hSig ; SF-R_{SF/OF}#timesOF ; ","Signal component",600,-100.,500.);
hSig->SetLineColor(kRed+2);
TRandom3* ran = new TRandom3();
for ( int i=0; i<nsteps; ++i ) {
Float_t nBSF = ran->Gaus(SF*LB,eSF*LB);
Float_t nBOF = ran->Gaus(OF*LB,eOF*LB);
Float_t rsfof = ran->Gaus(1.0,0.05);
hSig->Fill(nBSF-nBOF*rsfof);
}
TCanvas* mycan = new TCanvas("mycan","",100,10,900,600);
mycan->SetLogy();
TH1F* hSigNorm = hSig->DrawNormalized("");
hSigNorm->SetMinimum(1e-5);
hSigNorm->Draw();
// Find 95% CL range
float integral = 0;
int binStart = -1;
while ( integral <= 0.025 ) {
++binStart;
integral += hSigNorm->GetBinContent(binStart);
}
std::cout << integral << " up to " << hSigNorm->GetBinCenter(binStart) << std::endl;
integral = 0;
int binEnd = hSigNorm->GetNbinsX()+2;
while ( integral <= 0.025 ) {
--binEnd;
integral += hSigNorm->GetBinContent(binEnd);
}
std::cout << integral << " up to " << hSigNorm->GetBinCenter(binEnd) << std::endl;
// Draw 95% CL
TBox* range95 = new TBox(hSigNorm->GetBinCenter(binStart),hSigNorm->GetMinimum(),hSigNorm->GetBinCenter(binEnd),1.2*hSigNorm->GetMaximum());
range95->SetFillColor(kBlue-9);
range95->SetFillStyle(1000);
range95->SetLineColor(range95->GetFillColor());
range95->Draw();
hSigNorm->SetTitle("hSigNorm; \"S\" #equiv SF - R_{SF/OF}#timesOF ; pdf");
hSigNorm->Draw("same");
std::cout << "Integrating from 0 to " << SigB << ": " << std::endl;
std::cout << hSigNorm->Integral(0,hSigNorm->FindBin(SigB)) <<std::endl;
TLegend* legend = new TLegend(0.6,0.7,0.95,0.9,"","brNDC");
legend->SetBorderSize(0);
legend->AddEntry(hSigNorm,"Expected \"S\" for block B","l");
legend->AddEntry(range95,"95% region","f");
legend->Draw();
mycan->RedrawAxis();
mycan->SaveAs("toyMCexp.pdf");
TArrow* a = new TArrow(SigB,hSigNorm->GetMaximum(),SigB,hSigNorm->GetMinimum()*1.1,0.02);
a->SetLineColor(kBlue+2);
a->Draw();
TLegend* legend2 = new TLegend(0.6,0.6,0.95,0.7,"","brNDC");
legend2->SetBorderSize(0);
legend2->AddEntry(a,"Observed (p-value 0.6%)","l");
legend2->Draw();
mycan->SaveAs("toyMC.pdf");
}
void
//HTT_ET_X(bool scaled=true, bool log=true, float min=0.1, float max=-1., string inputfile="root/$HISTFILE", const char* directory="eleTau_$CATEGORY")
HTT_ET_X(bool scaled=true, bool log=true, float min=0.1, float max=-1., TString datacard="htt_et_1_7TeV", string inputfile="root/$HISTFILE", const char* directory="eleTau_$CATEGORY")
{
// defining the common canvas, axes pad styles
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
// determine category tag
const char* category = ""; const char* category_extra = ""; const char* category_extra2 = "";
if(std::string(directory) == std::string("eleTau_0jet_low" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_0jet_low" )){ category_extra = "0-jet low p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_0jet_medium" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_0jet_medium" )){ category_extra = "0-jet low p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_0jet_high" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_0jet_high" )){ category_extra = "0-jet high p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_1jet_medium" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_1jet_medium" )){ category_extra = "1-jet low p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_1jet_high_lowhiggs" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_1jet_high_lowhiggs" )){ category_extra= "1-jet high p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_1jet_high_mediumhiggs")){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_1jet_high_mediumhiggs")){ category_extra= "1-jet high p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_1jet_high_mediumhiggs")){ category_extra2= "boosted"; }
if(std::string(directory) == std::string("eleTau_vbf" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_vbf" )){ category_extra = "VBF tag"; }
if(std::string(directory) == std::string("eleTau_vbf_loose" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_vbf_loose" )){ category_extra = "Loose VBF tag"; }
if(std::string(directory) == std::string("eleTau_vbf_tight" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_vbf_tight" )){ category_extra = "Tight VBF tag"; }
if(std::string(directory) == std::string("eleTau_nobtag" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_nobtag" )){ category_extra = "no b-tag"; }
if(std::string(directory) == std::string("eleTau_btag" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_btag" )){ category_extra = "b-tag"; }
if(std::string(directory) == std::string("eleTau_nobtag_low" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_nobtag_low" )){ category_extra = "no b-tag"; }
if(std::string(directory) == std::string("eleTau_nobtag_low" )){ category_extra2 = "low p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_nobtag_medium" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_nobtag_medium" )){ category_extra = "no b-tag"; }
if(std::string(directory) == std::string("eleTau_nobtag_medium" )){ category_extra2 = "medium p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_nobtag_high" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_nobtag_high" )){ category_extra = "no b-tag"; }
if(std::string(directory) == std::string("eleTau_nobtag_high" )){ category_extra2 = "high p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_btag_low" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_btag_low" )){ category_extra = "b-tag"; }
if(std::string(directory) == std::string("eleTau_btag_low" )){ category_extra2 = "low p_{T}^{#tau_{h}}"; }
if(std::string(directory) == std::string("eleTau_btag_high" )){ category = "e#tau_{h}"; }
if(std::string(directory) == std::string("eleTau_btag_high" )){ category_extra = "b-tag"; }
if(std::string(directory) == std::string("eleTau_btag_high" )){ category_extra2 = "high p_{T}^{#tau_{h}}"; }
const char* dataset;
#ifdef MSSM
if(std::string(inputfile).find("7TeV")!=std::string::npos){dataset = "#scale[1.5]{CMS} h,H,A#rightarrow#tau#tau 4.9 fb^{-1} (7 TeV)";}
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "#scale[1.5]{CMS} h,H,A#rightarrow#tau#tau 19.7 fb^{-1} (8 TeV)";}
#else
if(std::string(inputfile).find("7TeV")!=std::string::npos){dataset = "CMS, 4.9 fb^{-1} at 7 TeV";}
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "CMS, 19.7 fb^{-1} at 8 TeV";}
#endif
TFile* input = new TFile(inputfile.c_str());
#ifdef MSSM
TFile* input2 = new TFile((inputfile+"_$MA_$TANB").c_str());
#endif
TH1F* Fakes = refill((TH1F*)input->Get(TString::Format("%s/QCD" , directory)), "QCD"); InitHist(Fakes, "", "", TColor::GetColor(250,202,255), 1001);
TH1F* EWK0 = refill((TH1F*)input->Get(TString::Format("%s/VV" , directory)), "VV" ); InitHist(EWK0 , "", "", TColor::GetColor(222,90,106), 1001);
TH1F* EWK1 = refill((TH1F*)input->Get(TString::Format("%s/W" , directory)), "W" ); InitHist(EWK1 , "", "", TColor::GetColor(222,90,106), 1001);
#ifdef EXTRA_SAMPLES
TH1F* EWK2 = refill((TH1F*)input->Get(TString::Format("%s/ZJ" , directory)), "ZJ" ); InitHist(EWK2 , "", "", TColor::GetColor(100,182,232), 1001);
TH1F* EWK = refill((TH1F*)input->Get(TString::Format("%s/ZL" , directory)), "ZL" ); InitHist(EWK , "", "", TColor::GetColor(100,182,232), 1001);
#else
TH1F* EWK = refill((TH1F*)input->Get(TString::Format("%s/ZLL" , directory)), "ZLL"); InitHist(EWK , "", "", TColor::GetColor(100,182,232), 1001);
#endif
TH1F* ttbar = refill((TH1F*)input->Get(TString::Format("%s/TT" , directory)), "TT" ); InitHist(ttbar, "", "", TColor::GetColor(155,152,204), 1001);
TH1F* Ztt = refill((TH1F*)input->Get(TString::Format("%s/ZTT" , directory)), "ZTT"); InitHist(Ztt , "", "", TColor::GetColor(248,206,104), 1001);
#ifdef MSSM
TH1F* ggH = refill((TH1F*)input2->Get(TString::Format("%s/ggH$MA" , directory)), "ggH"); InitSignal(ggH); ggH->Scale($TANB);
TH1F* bbH = refill((TH1F*)input2->Get(TString::Format("%s/bbH$MA" , directory)), "bbH"); InitSignal(bbH); bbH->Scale($TANB);
#else
#ifndef DROP_SIGNAL
TH1F* ggH = refill((TH1F*)input->Get(TString::Format("%s/ggH125" , directory)), "ggH"); InitSignal(ggH); ggH->Scale(SIGNAL_SCALE);
TH1F* qqH = refill((TH1F*)input->Get(TString::Format("%s/qqH125" , directory)), "qqH"); InitSignal(qqH); qqH->Scale(SIGNAL_SCALE);
TH1F* VH = refill((TH1F*)input->Get(TString::Format("%s/VH125" , directory)), "VH" ); InitSignal(VH ); VH ->Scale(SIGNAL_SCALE);
#endif
#endif
#ifdef ASIMOV
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs_asimov", directory)), "data", true);
#else
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs", directory)), "data", true);
#endif
InitHist(data, "#bf{m_{#tau#tau} [GeV]}", "#bf{dN/dm_{#tau#tau} [1/GeV]}"); InitData(data);
TH1F* ref=(TH1F*)Fakes->Clone("ref");
ref->Add(EWK0 );
ref->Add(EWK1 );
#ifdef EXTRA_SAMPLES
ref->Add(EWK2 );
#endif
ref->Add(EWK );
ref->Add(ttbar);
ref->Add(Ztt );
double unscaled[7];
unscaled[0] = Fakes->Integral();
unscaled[1] = EWK ->Integral();
unscaled[1]+= EWK0 ->Integral();
unscaled[1]+= EWK1 ->Integral();
#ifdef EXTRA_SAMPLES
unscaled[1]+= EWK2 ->Integral();
#endif
unscaled[2] = ttbar->Integral();
unscaled[3] = Ztt ->Integral();
#ifdef MSSM
unscaled[4] = ggH ->Integral();
unscaled[5] = bbH ->Integral();
unscaled[6] = 0;
#else
#ifndef DROP_SIGNAL
unscaled[4] = ggH ->Integral();
unscaled[5] = qqH ->Integral();
unscaled[6] = VH ->Integral();
#endif
#endif
if(scaled){
/* Fakes = refill(shape_histos(Fakes, datacard, "QCD"), "QCD");
EWK0 = refill(shape_histos(EWK0, datacard, "VV"), "VV");
EWK1 = refill(shape_histos(EWK1, datacard, "W"), "W");
#ifdef EXTRA_SAMPLES
EWK2 = refill(shape_histos(EWK2, datacard, "ZJ"), "ZJ");
EWK = refill(shape_histos(EWK, datacard, "ZL"), "ZL");
#else
// EWK = refill(shape_histos(EWK, datacard, "ZLL"), "ZLL");
#endif
ttbar = refill(shape_histos(ttbar, datacard, "TT"), "TT");
Ztt = refill(shape_histos(Ztt, datacard, "ZTT"), "ZTT");
#ifdef MSSM
ggH = refill(shape_histos(ggH, datacard, "ggH$MA"), "ggH$MA");
bbH = refill(shape_histos(bbH, datacard, "bbH$MA"), "bbH$MA");
#else
#ifndef DROP_SIGNAL
ggH = refill(shape_histos(ggH, datacard, "ggH"), "ggH");
qqH = refill(shape_histos(qqH, datacard, "qqH"), "qqH");
VH = refill(shape_histos(VH, datacard, "VH"), "VH");
#endif
#endif
*/
rescale(Fakes, 7);
rescale(EWK0 , 6);
rescale(EWK1 , 3);
#ifdef EXTRA_SAMPLES
rescale(EWK2 , 4);
rescale(EWK , 5);
#else
rescale(EWK , 4);
#endif
rescale(ttbar, 2);
rescale(Ztt , 1);
#ifdef MSSM
rescale(ggH , 8);
rescale(bbH , 9);
#else
#ifndef DROP_SIGNAL
rescale(ggH , 8);
rescale(qqH , 9);
rescale(VH ,10);
#endif
#endif
}
TH1F* scales[7];
scales[0] = new TH1F("scales-Fakes", "", 7, 0, 7);
scales[0]->SetBinContent(1, unscaled[0]>0 ? (Fakes->Integral()/unscaled[0]-1.) : 0.);
scales[1] = new TH1F("scales-EWK" , "", 7, 0, 7);
scales[1]->SetBinContent(2, unscaled[1]>0 ? ((EWK ->Integral()
+EWK0 ->Integral()
+EWK1 ->Integral()
#ifdef EXTRA_SAMPLES
+EWK2 ->Integral()
#endif
)/unscaled[1]-1.) : 0.);
scales[2] = new TH1F("scales-ttbar", "", 7, 0, 7);
scales[2]->SetBinContent(3, unscaled[2]>0 ? (ttbar->Integral()/unscaled[2]-1.) : 0.);
scales[3] = new TH1F("scales-Ztt" , "", 7, 0, 7);
scales[3]->SetBinContent(4, unscaled[3]>0 ? (Ztt ->Integral()/unscaled[3]-1.) : 0.);
#ifdef MSSM
scales[4] = new TH1F("scales-ggH" , "", 7, 0, 7);
scales[4]->SetBinContent(5, unscaled[4]>0 ? (ggH ->Integral()/unscaled[4]-1.) : 0.);
scales[5] = new TH1F("scales-bbH" , "", 7, 0, 7);
scales[5]->SetBinContent(6, unscaled[5]>0 ? (bbH ->Integral()/unscaled[5]-1.) : 0.);
scales[6] = new TH1F("scales-NONE" , "", 7, 0, 7);
scales[6]->SetBinContent(7, 0.);
#else
#ifndef DROP_SIGNAL
scales[4] = new TH1F("scales-ggH" , "", 7, 0, 7);
scales[4]->SetBinContent(5, unscaled[4]>0 ? (ggH ->Integral()/unscaled[4]-1.) : 0.);
scales[5] = new TH1F("scales-qqH" , "", 7, 0, 7);
scales[5]->SetBinContent(6, unscaled[5]>0 ? (qqH ->Integral()/unscaled[5]-1.) : 0.);
scales[6] = new TH1F("scales-VH" , "", 7, 0, 7);
scales[6]->SetBinContent(7, unscaled[6]>0 ? (VH ->Integral()/unscaled[6]-1.) : 0.);
#endif
#endif
EWK0 ->Add(Fakes);
EWK1 ->Add(EWK0 );
#ifdef EXTRA_SAMPLES
EWK2 ->Add(EWK1 );
EWK ->Add(EWK2 );
#else
EWK ->Add(EWK1 );
#endif
ttbar->Add(EWK );
Ztt ->Add(ttbar);
if(log){
#ifdef MSSM
ggH ->Add(bbH);
#else
#ifndef DROP_SIGNAL
qqH ->Add(VH );
ggH ->Add(qqH);
#endif
#endif
}
else{
#ifdef MSSM
bbH ->Add(Ztt);
ggH ->Add(bbH);
#else
#ifndef DROP_SIGNAL
VH ->Add(Ztt);
qqH ->Add(VH );
ggH ->Add(qqH);
#endif
#endif
}
/*
Mass plot before and after fit
*/
TCanvas *canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
if(log){ canv->SetLogy(1); }
#if defined MSSM
if(!log){ data->GetXaxis()->SetRange(0, data->FindBin(345)); } else{ data->GetXaxis()->SetRange(0, data->FindBin(UPPER_EDGE)); };
#else
data->GetXaxis()->SetRange(0, data->FindBin(345));
#endif
data->SetNdivisions(505);
data->SetMinimum(min);
#ifndef DROP_SIGNAL
data->SetMaximum(max>0 ? max : std::max(std::max(maximum(data, log), maximum(Ztt, log)), maximum(ggH, log)));
#else
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(Ztt, log)));
#endif
data->Draw("e");
TH1F* errorBand = (TH1F*)Ztt ->Clone("errorBand");
errorBand ->SetMarkerSize(0);
errorBand ->SetFillColor(13);
errorBand ->SetFillStyle(3013);
errorBand ->SetLineWidth(1);
for(int idx=0; idx<errorBand->GetNbinsX(); ++idx){
if(errorBand->GetBinContent(idx)>0){
std::cout << "Uncertainties on summed background samples: " << errorBand->GetBinError(idx)/errorBand->GetBinContent(idx) << std::endl;
break;
}
}
if(log){
Ztt ->Draw("histsame");
ttbar->Draw("histsame");
EWK ->Draw("histsame");
EWK1 ->Draw("histsame");
Fakes->Draw("histsame");
$DRAW_ERROR
#ifndef DROP_SIGNAL
ggH ->Draw("histsame");
#endif
}
else{
#ifndef DROP_SIGNAL
ggH ->Draw("histsame");
#endif
Ztt ->Draw("histsame");
ttbar->Draw("histsame");
EWK ->Draw("histsame");
EWK1 ->Draw("histsame");
Fakes->Draw("histsame");
$DRAW_ERROR
}
data->Draw("esame");
canv->RedrawAxis();
//CMSPrelim(dataset, "#tau_{e}#tau_{h}", 0.17, 0.835);
CMSPrelim(dataset, "", 0.16, 0.835);
#if defined MSSM
TPaveText* chan = new TPaveText(0.20, 0.74+0.061, 0.32, 0.74+0.161, "tlbrNDC");
if (category_extra2!="") chan = new TPaveText(0.20, 0.69+0.061, 0.32, 0.74+0.161, "tlbrNDC");
#else
TPaveText* chan = new TPaveText(0.52, 0.35, 0.91, 0.55, "tlbrNDC");
#endif
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
chan->AddText(category);
chan->AddText(category_extra);
#if defined MSSM
if (category_extra2!="") chan->AddText(category_extra2);
#else
chan->AddText(category_extra2);
#endif
chan->Draw();
/* TPaveText* cat = new TPaveText(0.20, 0.71+0.061, 0.32, 0.71+0.161, "NDC");
cat->SetBorderSize( 0 );
cat->SetFillStyle( 0 );
cat->SetTextAlign( 12 );
cat->SetTextSize ( 0.05 );
cat->SetTextColor( 1 );
cat->SetTextFont ( 62 );
cat->AddText(category_extra);
cat->Draw();
TPaveText* cat2 = new TPaveText(0.20, 0.66+0.061, 0.32, 0.66+0.161, "NDC");
cat2->SetBorderSize( 0 );
cat2->SetFillStyle( 0 );
cat2->SetTextAlign( 12 );
cat2->SetTextSize ( 0.05 );
cat2->SetTextColor( 1 );
cat2->SetTextFont ( 62 );
cat2->AddText(category_extra2);
cat2->Draw();
*/
#ifdef MSSM
TPaveText* massA = new TPaveText(0.53, 0.44+0.061, 0.95, 0.44+0.151, "NDC");
massA->SetBorderSize( 0 );
massA->SetFillStyle( 0 );
massA->SetTextAlign( 12 );
massA->SetTextSize ( 0.03 );
massA->SetTextColor( 1 );
massA->SetTextFont ( 62 );
massA->AddText("MSSM m^{h}_{max} scenario");
massA->AddText("m_{A}=$MA GeV, tan#beta=$TANB");
massA->Draw();
#endif
#ifdef MSSM
TLegend* leg = new TLegend(0.53, 0.60, 0.95, 0.90);
SetLegendStyle(leg);
leg->AddEntry(ggH , "h,A,H#rightarrow#tau#tau" , "L" );
#else
TLegend* leg = new TLegend(0.52, 0.58, 0.92, 0.89);
SetLegendStyle(leg);
#ifndef DROP_SIGNAL
if(SIGNAL_SCALE!=1){
leg->AddEntry(ggH , TString::Format("%.0f#timesH(125 GeV)#rightarrow#tau#tau", SIGNAL_SCALE) , "L" );
}
else{
leg->AddEntry(ggH , "SM H(125 GeV)#rightarrow#tau#tau" , "L" );
}
#endif
#endif
#ifdef ASIMOV
leg->AddEntry(data , "sum(bkg) + H(125)" , "LP");
#else
leg->AddEntry(data , "Observed" , "LP");
#endif
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(EWK , "Z#rightarrow ee" , "F" );
leg->AddEntry(EWK1 , "W+jets" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
$ERROR_LEGEND
leg->Draw();
/*
Ratio Data over MC
*/
TCanvas *canv0 = MakeCanvas("canv0", "histograms", 600, 400);
canv0->SetGridx();
canv0->SetGridy();
canv0->cd();
TH1F* model = (TH1F*)Ztt ->Clone("model");
TH1F* test1 = (TH1F*)data->Clone("test1");
for(int ibin=0; ibin<test1->GetNbinsX(); ++ibin){
//the small value in case of 0 entries in the model is added to prevent the chis2 test from failing
model->SetBinContent(ibin+1, model->GetBinContent(ibin+1)>0 ? model->GetBinContent(ibin+1)*model->GetBinWidth(ibin+1) : 0.01);
model->SetBinError (ibin+1, CONVERVATIVE_CHI2 ? 0. : model->GetBinError (ibin+1)*model->GetBinWidth(ibin+1));
test1->SetBinContent(ibin+1, test1->GetBinContent(ibin+1)*test1->GetBinWidth(ibin+1));
test1->SetBinError (ibin+1, test1->GetBinError (ibin+1)*test1->GetBinWidth(ibin+1));
}
double chi2prob = test1->Chi2Test (model,"PUW"); std::cout << "chi2prob:" << chi2prob << std::endl;
double chi2ndof = test1->Chi2Test (model,"CHI2/NDFUW"); std::cout << "chi2ndf :" << chi2ndof << std::endl;
double ksprob = test1->KolmogorovTest(model); std::cout << "ksprob :" << ksprob << std::endl;
double ksprobpe = test1->KolmogorovTest(model,"DX"); std::cout << "ksprobpe:" << ksprobpe << std::endl;
std::vector<double> edges;
TH1F* zero = (TH1F*)ref->Clone("zero"); zero->Clear();
TH1F* rat1 = (TH1F*)data->Clone("rat1");
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
rat1->SetBinContent(ibin+1, Ztt->GetBinContent(ibin+1)>0 ? data->GetBinContent(ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
rat1->SetBinError (ibin+1, Ztt->GetBinContent(ibin+1)>0 ? data->GetBinError (ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
zero->SetBinContent(ibin+1, 0.);
zero->SetBinError (ibin+1, Ztt->GetBinContent(ibin+1)>0 ? Ztt ->GetBinError (ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
}
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
if(rat1->GetBinContent(ibin+1)>0){
edges.push_back(TMath::Abs(rat1->GetBinContent(ibin+1)-1.)+TMath::Abs(rat1->GetBinError(ibin+1)));
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
}
}
float range = 0.1;
std::sort(edges.begin(), edges.end());
if (edges[edges.size()-2]>0.1) { range = 0.2; }
if (edges[edges.size()-2]>0.2) { range = 0.5; }
if (edges[edges.size()-2]>0.5) { range = 1.0; }
if (edges[edges.size()-2]>1.0) { range = 1.5; }
if (edges[edges.size()-2]>1.5) { range = 2.0; }
rat1->SetLineColor(kBlack);
rat1->SetFillColor(kGray );
rat1->SetMaximum(+range);
rat1->SetMinimum(-range);
rat1->GetYaxis()->CenterTitle();
rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
rat1->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
rat1->Draw();
zero->SetFillStyle( 3013);
zero->SetFillColor(kBlack);
zero->SetLineColor(kBlack);
zero->SetMarkerSize(0.1);
zero->Draw("e2histsame");
canv0->RedrawAxis();
TPaveText* stat1 = new TPaveText(0.20, 0.76+0.061, 0.32, 0.76+0.161, "NDC");
stat1->SetBorderSize( 0 );
stat1->SetFillStyle( 0 );
stat1->SetTextAlign( 12 );
stat1->SetTextSize ( 0.05 );
stat1->SetTextColor( 1 );
stat1->SetTextFont ( 62 );
stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f", chi2ndof, chi2prob));
//stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f, P(KS)=%.3f", chi2ndof, chi2prob, ksprob));
stat1->Draw();
/*
Ratio After fit over Prefit
*/
TCanvas *canv1 = MakeCanvas("canv1", "histograms", 600, 400);
canv1->SetGridx();
canv1->SetGridy();
canv1->cd();
edges.clear();
TH1F* rat2 = (TH1F*) Ztt->Clone("rat2");
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
rat2->SetBinContent(ibin+1, ref->GetBinContent(ibin+1)>0 ? Ztt->GetBinContent(ibin+1)/ref->GetBinContent(ibin+1) : 0);
rat2->SetBinError (ibin+1, ref->GetBinContent(ibin+1)>0 ? Ztt->GetBinError (ibin+1)/ref->GetBinContent(ibin+1) : 0);
}
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
if(rat2->GetBinContent(ibin+1)>0){
edges.push_back(TMath::Abs(rat2->GetBinContent(ibin+1)-1.)+TMath::Abs(rat2->GetBinError(ibin+1)));
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat2 ->SetBinContent(ibin+1, rat2->GetBinContent(ibin+1)-1.);
}
}
range = 0.1;
std::sort(edges.begin(), edges.end());
if (edges[edges.size()-2]>0.1) { range = 0.2; }
if (edges[edges.size()-2]>0.2) { range = 0.5; }
if (edges[edges.size()-2]>0.5) { range = 1.0; }
if (edges[edges.size()-2]>1.0) { range = 1.5; }
if (edges[edges.size()-2]>1.5) { range = 2.0; }
#if defined MSSM
if(!log){ rat2->GetXaxis()->SetRange(0, rat2->FindBin(345)); } else{ rat2->GetXaxis()->SetRange(0, rat2->FindBin(UPPER_EDGE)); };
#else
rat2->GetXaxis()->SetRange(0, rat2->FindBin(345));
#endif
rat2->SetNdivisions(505);
rat2->SetLineColor(kRed+ 3);
rat2->SetMarkerColor(kRed+3);
rat2->SetMarkerSize(1.1);
rat2->SetMaximum(+range);
rat2->SetMinimum(-range);
rat2->GetYaxis()->SetTitle("#bf{Postfit/Prefit-1}");
rat2->GetYaxis()->CenterTitle();
rat2->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
rat2->Draw();
zero->SetFillStyle( 3013);
zero->SetFillColor(kBlack);
zero->SetLineColor(kBlack);
zero->Draw("e2histsame");
canv1->RedrawAxis();
/*
Relative shift per sample
*/
TCanvas *canv2 = MakeCanvas("canv2", "histograms", 600, 400);
canv2->SetGridx();
canv2->SetGridy();
canv2->cd();
InitHist (scales[0], "", "", TColor::GetColor(250,202,255), 1001);
InitHist (scales[1], "", "", TColor::GetColor(222,90,106), 1001);
InitHist (scales[2], "", "", TColor::GetColor(155,152,204), 1001);
InitHist (scales[3], "", "", TColor::GetColor(248,206,104), 1001);
#ifndef DROP_SIGNAL
InitSignal(scales[4]);
InitSignal(scales[5]);
InitSignal(scales[6]);
#endif
scales[0]->Draw();
scales[0]->GetXaxis()->SetBinLabel(1, "#bf{Fakes}");
scales[0]->GetXaxis()->SetBinLabel(2, "#bf{EWK}" );
scales[0]->GetXaxis()->SetBinLabel(3, "#bf{ttbar}");
scales[0]->GetXaxis()->SetBinLabel(4, "#bf{Ztt}" );
#ifdef MSSM
scales[0]->GetXaxis()->SetBinLabel(5, "#bf{ggH}" );
scales[0]->GetXaxis()->SetBinLabel(6, "#bf{bbH}" );
scales[0]->GetXaxis()->SetBinLabel(7, "NONE" );
#else
scales[0]->GetXaxis()->SetBinLabel(5, "#bf{ggH}" );
scales[0]->GetXaxis()->SetBinLabel(6, "#bf{qqH}" );
scales[0]->GetXaxis()->SetBinLabel(7, "#bf{VH}" );
#endif
scales[0]->SetMaximum(+0.5);
scales[0]->SetMinimum(-0.5);
scales[0]->GetYaxis()->CenterTitle();
scales[0]->GetYaxis()->SetTitle("#bf{Postfit/Prefit-1}");
scales[1]->Draw("same");
scales[2]->Draw("same");
scales[3]->Draw("same");
#ifndef DROP_SIGNAL
scales[4]->Draw("same");
scales[5]->Draw("same");
scales[6]->Draw("same");
#endif
TH1F* zero_samples = (TH1F*)scales[0]->Clone("zero_samples"); zero_samples->Clear();
zero_samples->SetBinContent(1,0.);
zero_samples->Draw("same");
canv2->RedrawAxis();
/*
prepare output
*/
bool isSevenTeV = std::string(inputfile).find("7TeV")!=std::string::npos;
canv ->Print(TString::Format("%s_%sfit_%s_%s.png" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv ->Print(TString::Format("%s_%sfit_%s_%s.pdf" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv ->Print(TString::Format("%s_%sfit_%s_%s.eps" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
if(!log || FULLPLOTS)
{
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
}
if((!log && scaled) || FULLPLOTS)
{
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
}
TFile* output = new TFile(TString::Format("%s_%sfit_%s_%s.root", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"), "update");
output->cd();
data ->Write("data_obs");
Fakes->Write("Fakes" );
EWK ->Write("Zee" );
EWK1 ->Write("EWK" );
//EWK ->Write("EWK" );
EWK1 ->Write("EWK1" );
ttbar->Write("ttbar" );
Ztt ->Write("Ztt" );
#ifdef MSSM
ggH ->Write("ggH" );
bbH ->Write("bbH" );
#else
#ifndef DROP_SIGNAL
ggH ->Write("ggH" );
qqH ->Write("qqH" );
VH ->Write("VH" );
#endif
#endif
if(errorBand){
errorBand->Write("errorBand");
}
output->Close();
delete errorBand;
delete model;
delete test1;
delete zero;
delete rat1;
delete rat2;
delete zero_samples;
delete ref;
}
TCanvas* example_plot( int iPeriod, int iPos, bool t, int nt,double miPt, double maPt,string c,string hname, string lbl1, string lbl2,string lbl3 )
{
// if( iPos==0 ) relPosX = 0.12;
int W = 800;
int H = 600;
int H_ref = 600;
int W_ref = 800;
// references for T, B, L, R
float T = 0.08*H_ref;
float B = 0.12*H_ref;
float L = 0.12*W_ref;
float R = 0.04*W_ref;
TString canvName = "FigMass_";
canvName += W;
canvName += "_";
canvName += H;
canvName += "_";
canvName += iPeriod;
if( writeExtraText ) canvName += "_prelim";
if( iPos%10==0 ) canvName += "_out";
else if( iPos%10==1 ) canvName += "_left";
else if( iPos%10==2 ) canvName += "_center";
else if( iPos%10==3 ) canvName += "_right";
TCanvas* canv = new TCanvas(canvName,canvName,50,50,W,H);
canv->SetFillColor(0);
canv->SetBorderMode(0);
canv->SetFrameFillStyle(0);
canv->SetFrameBorderMode(0);
canv->SetLeftMargin( L/W );
canv->SetRightMargin( R/W );
canv->SetTopMargin( T/H );
canv->SetBottomMargin( B/H );
canv->SetTickx(0);
canv->SetTicky(0);
fit(4,t,nt,miPt,maPt,c);
// fit(4,1,32,"Mass>8.6 && Mass<11.0 && TMath::Abs(EtaMuP)<1.2 && TMath::Abs(EtaMuM)<1.2 && Rapidity<1.2 ");
{
TLatex latex;
int n_ = 3;
float x1_l = 0.95;
float y1_l = 0.70;
float dx_l = 0.37;
float dy_l = 0.23;
float x0_l = x1_l-dx_l;
float y0_l = y1_l-dy_l;
TPad* legend = new TPad("legend_0","legend_0",x0_l,y0_l,x1_l, y1_l );
// legend->SetFillColor( kGray );
legend->Draw();
legend->cd();
float gap_ = 1./(n_+1);
float bwx_ = 0.12;
x_l[0] = 1.2*bwx_;
y_l[0] = 1-gap_;
latex.SetTextFont(42);
latex.SetTextAngle(0);
latex.SetTextColor(kBlack);
latex.SetTextSize(0.20);
latex.SetTextAlign(12);
float xx_ = x_l[0];
float yy_ = y_l[0];
//latex.DrawLatex(xx_+1.*bwx_,yy_,"#sigma = 26.5 #pm 2.2 MeV");
//latex.DrawLatex(xx_+1.*bwx_,yy_,"#sigma = 13 MeV");
// latex.DrawLatex(xx_+0.5*bwx_,yy_,"#sqrt{f_{1}#sigma_{1}^{2}+f_{2}#sigma_{2}^{2}} = 110 MeV");
latex.DrawLatex(xx_+0.5*bwx_,yy_,lbl1.c_str());
yy_ -= gap_;
// latex.DrawLatex(xx_+0.5*bwx_,yy_,"p_{T}^{#mu^{+}#mu^{-}} > 13 GeV");
latex.DrawLatex(xx_+0.5*bwx_,yy_,lbl2.c_str());
yy_ -= gap_;
latex.DrawLatex(xx_+0.5*bwx_,yy_,lbl3.c_str());
// latex.DrawLatex(xx_+1.*bwx_,yy_,"|#eta_{#mu}| < 0.5");
canv->cd();
}
// writing the lumi information and the CMS "logo"
CMS_lumi( canv, iPeriod, iPos );
canv->Update();
canv->RedrawAxis();
canv->GetFrame()->Draw();
string hn="Plots/"+hname+".pdf";
string hnpng ="Plots/"+hname+".png";
canv->SaveAs(hn.c_str());
canv->SaveAs(hnpng.c_str());
// canv->Print(hname+".png",".png");
return canv;
}
//______________________________________________________________________________
void DrawEvolution(const char* file, bool normalized=true)
{
TFile* f = TFile::Open(gSystem->ExpandPathName(file));
if (!f) return;
TCanvas* c = new TCanvas("mch-status-evolution","mch-status-evolution");
c->SetGridy();
c->SetTicky();
c->Draw();
TLegend* l = new TLegend(0.1,0.7,0.3,0.95,"ch evolution");
TGraph* g = static_cast<TGraph*>(f->Get("nbad"));
if (!g) return;
int runmin = TMath::Nint(g->GetX()[0]);
int runmax = TMath::Nint(g->GetX()[g->GetN()-1]);
cout << Form("Run range found in file %s = %d - %d",file,runmin,runmax) << endl;
double ymax(0.4);
TH2* h = new TH2F("hframe","hframe;Run number;Fraction of dead channels",100,runmin-200,runmax+200,100,0,ymax);
gStyle->SetOptStat(kFALSE);
h->Draw();
h->GetXaxis()->SetNoExponent();
h->GetXaxis()->SetNdivisions(505);
gStyle->SetOptTitle(kFALSE);
DrawPeriod(runmin,runmax,115881,117222,0,ymax,"10b");
DrawPeriod(runmin,runmax,119159,120824,0,ymax,"10c");
DrawPeriod(runmin,runmax,122374,126424,0,ymax,"10d");
DrawPeriod(runmin,runmax,127724,130850,0,ymax,"10e");
DrawPeriod(runmin,runmax,133005,134929,0,ymax,"10f");
DrawPeriod(runmin,runmax,135658,136376,0,ymax,"10g");
DrawPeriod(runmin,runmax,137133,139513,0,ymax,"10h");
DrawPeriod(runmin,runmax,143856,146860,0,ymax,"11a");
DrawPeriod(runmin,runmax,148370,150702,0,ymax,"11b");
DrawPeriod(runmin,runmax,151566,154583,0,ymax,"11c");
DrawPeriod(runmin,runmax,158084,159606,0,ymax,"11d");
DrawPeriod(runmin,runmax,160677,162717,0,ymax,"11e");
DrawPeriod(runmin,runmax,162933,165744,0,ymax,"11f");
DrawPeriod(runmin,runmax,167703,170593,0,ymax,"11h");
// 2012
DrawPeriod(runmin,runmax,176661,177295,0,ymax,"12a");
DrawPeriod(runmin,runmax,177384,178053,0,ymax,"12b");
DrawPeriod(runmin,runmax,179603,180569,0,ymax,"12c");
DrawPeriod(runmin,runmax,183913,186320,0,ymax,"12d");
DrawPeriod(runmin,runmax,186365,186602,0,ymax,"12e");
DrawPeriod(runmin,runmax,186668,188123,0,ymax,"12f");
DrawPeriod(runmin,runmax,188362,188503,0,ymax,"12g");
DrawPeriod(runmin,runmax,189122,190110,0,ymax,"12h");
// 2013
DrawPeriod(runmin,runmax,195344,195483,0,ymax,"13b");
DrawPeriod(runmin,runmax,195529,195677,0,ymax,"13c");
DrawPeriod(runmin,runmax,195681,195873,0,ymax,"13d");
DrawPeriod(runmin,runmax,195949,196311,0,ymax,"13e");
DrawPeriod(runmin,runmax,196433,197388,0,ymax,"13f");
// 2015
// periods are from the logbook, taking only PHYSICS% partitions
// into account
DrawPeriod(runmin,runmax,213329,215151,0,ymax,"15a");
DrawPeriod(runmin,runmax,215160,215579,0,ymax,"15b");
DrawPeriod(runmin,runmax,215580,219968,0,ymax,"15c");
DrawPeriod(runmin,runmax,220050,223195,0,ymax,"15d");
DrawPeriod(runmin,runmax,223227,224779,0,ymax,"15e");
DrawPeriod(runmin,runmax,224826,226606,0,ymax,"15f");
DrawPeriod(runmin,runmax,228936,231321,0,ymax,"15g");
DrawPeriod(runmin,runmax,232914,234050,0,ymax,"15h");
DrawPeriod(runmin,runmax,235196,236866,0,ymax,"15i");
DrawPeriod(runmin,runmax,236965,238621,0,ymax,"15j");
DrawPeriod(runmin,runmax,238890,239025,0,ymax,"15k");
DrawPeriod(runmin,runmax,239319,241544,0,ymax,"15l");
DrawPeriod(runmin,runmax,244340,244628,0,ymax,"15n");
DrawPeriod(runmin,runmax,244918,246994,0,ymax,"15o");
// 2016
DrawPeriod(runmin,runmax,247189,247193,0,ymax,"16a");
DrawPeriod(runmin,runmax,247723,250585,0,ymax,"16b");
DrawPeriod(runmin,runmax,250647,252091,0,ymax,"16c");
DrawPeriod(runmin,runmax,252191,252518,0,ymax,"16d");
DrawPeriod(runmin,runmax,252598,253609,0,ymax,"16e");
DrawPeriod(runmin,runmax,253613,253979,0,ymax,"16f");
DrawPeriod(runmin,runmax,253991,254332,0,ymax,"16g");
DrawPeriod(runmin,runmax,254373,255469,0,ymax,"16h");
DrawPeriod(runmin,runmax,255515,255650,0,ymax,"16i");
DrawPeriod(runmin,runmax,256083,256420,0,ymax,"16j");
DrawPeriod(runmin,runmax,256504,258574,0,ymax,"16k");
DrawPeriod(runmin,runmax,258883,260187,0,ymax,"16l");
DrawPeriod(runmin,runmax,260216,260647,0,ymax,"16m");
DrawPeriod(runmin,runmax,260649,261812,0,ymax,"16n");
DrawPeriod(runmin,runmax,262394,262858,0,ymax,"16o");
Draw(f,"nbad",l,normalized);
Draw(f,"nbadped",l,normalized);
Draw(f,"nbadocc",l,normalized);
Draw(f,"nbadhv",l,normalized);
Draw(f,"nbadlv",l,normalized);
Draw(f,"nmissing",l,normalized);
Draw(f,"nreco",l,normalized);
h->Draw("same");
c->RedrawAxis("g");
l->Draw();
}
void
HBB_LEP_X(bool scaled=true, bool log=true, float min=0.1, float max=-1., const char* inputfile="root/$HISTFILE", const char* directory="bb_$CATEGORY")
{
// define common canvas, axes pad styles
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
// determine category tag
const char* category_extra = "";
if(std::string(directory) == std::string("bb_had0" )){ category_extra = "all-had_{0}"; }
if(std::string(directory) == std::string("bb_had1" )){ category_extra = "all-had_{1}"; }
if(std::string(directory) == std::string("bb_had2" )){ category_extra = "all-had_{2}"; }
if(std::string(directory) == std::string("bb_had3" )){ category_extra = "all-had_{3}"; }
if(std::string(directory) == std::string("bb_had4" )){ category_extra = "all-had_{4}"; }
if(std::string(directory) == std::string("bb_had5" )){ category_extra = "all-had_{5}"; }
if(std::string(directory) == std::string("bb_lep" )){ category_extra = "semi-lep"; }
const char* dataset;
if(std::string(inputfile).find("7TeV")!=std::string::npos){dataset = "Preliminary, #sqrt{s} = 7 TeV, L = 4.8 fb^{-1}";}
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "Preliminary, #sqrt{s} = 8 TeV, L = 19.4 fb^{-1}";}
TFile* input = new TFile(inputfile);
TH1F* bkgBBB = refill((TH1F*)input->Get(TString::Format("%s/bkgBBB" , directory)), "bkgBBB"); InitHist(bkgBBB, "", "", kMagenta-10, 1001);;
#ifdef MSSM
float bbHScale = 1.; // scenario for MSSM, mhmax, mA=160, tanb=20, A+H for the time being
if(std::string(inputfile).find("7TeV")!=std::string::npos){ bbHScale = (23314.3*0.879 + 21999.3*0.877)/1000.; }
if(std::string(inputfile).find("8TeV")!=std::string::npos){ bbHScale = (31087.9*0.879 + 29317.8*0.877)/1000.; }
// float bbHScale = 1.; // scenario for MSSM, mhmax, mA=160, tanb=10, A+H for the time being
// if(std::string(inputfile).find("7TeV")!=std::string::npos){ bbHScale = (6211.6*0.89 + 5145.0*0.85)/1000.; }
// if(std::string(inputfile).find("8TeV")!=std::string::npos){ bbHScale = (8282.7*0.89 + 6867.8*0.85)/1000.; }
TH1F* bbH = refill((TH1F*)input->Get(TString::Format("%s/bbH160" , directory)), "bbH" ); InitSignal(bbH); bbH->Scale(bbHScale);
#endif
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs", directory)), "data", true);
InitHist(data, "#bf{m_{b#bar{b}} [GeV]}", "#bf{dN/dm_{b#bar{b}} [1/GeV]}"); InitData(data);
TH1F* ref=(TH1F*)bkgBBB->Clone("ref");
double unscaled[7];
unscaled[0] = bkgBBB ->Integral();
#ifdef MSSM
unscaled[1] = bbH ->Integral();
unscaled[2] = 0;
#endif
if(scaled){
rescale(bkgBBB, 1);
#ifdef MSSM
rescale(bbH, 2);
#endif
}
TH1F* scales[7];
scales[0] = new TH1F("scales-bkgBBB", "", 3, 0, 3);
scales[0]->SetBinContent(1, unscaled[0]>0 ? (bkgBBB ->Integral()/unscaled[0]-1.) : 0.);
#ifdef MSSM
scales[1] = new TH1F("scales-bbH" , "", 3, 0, 3);
scales[1]->SetBinContent(2, unscaled[1]>0 ? (bbH ->Integral()/unscaled[1]-1.) : 0.);
scales[2] = new TH1F("scales-NONE" , "", 3, 0, 3);
scales[2]->SetBinContent(3, 0.);
#endif
if(!log){
#ifdef MSSM
bbH ->Add(bkgBBB);
#endif
}
/*
mass plot before and after fit
*/
TCanvas* canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
if(log){ canv->SetLogy(1); }
#if defined MSSM
if(!log){ data->GetXaxis()->SetRange(0, data->FindBin(350)); } else{ data->GetXaxis()->SetRange(0, data->FindBin(1000)); };
#endif
data->SetNdivisions(505);
data->SetMinimum(min);
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(bkgBBB, log)));
data->Draw("e");
TH1F* errorBand = (TH1F*)bkgBBB ->Clone();
errorBand ->SetMarkerSize(0);
errorBand ->SetFillColor(1);
errorBand ->SetFillStyle(3013);
errorBand ->SetLineWidth(1);
if(log){
bkgBBB ->Draw("histsame");
$DRAW_ERROR
#ifndef DROP_SIGNAL
bbH ->Draw("histsame");
#endif
}
else{
#ifndef DROP_SIGNAL
bbH ->Draw("histsame");
#endif
bkgBBB ->Draw("histsame");
$DRAW_ERROR
}
data->Draw("esame");
canv->RedrawAxis();
//CMSPrelim(dataset, "b#bar{b}", 0.17, 0.835);
CMSPrelim(dataset, "", 0.17, 0.835);
TPaveText* chan = new TPaveText(0.20, 0.74+0.061, 0.32, 0.74+0.161, "NDC");
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
chan->AddText("b#bar{b}");
chan->Draw();
TPaveText* cat = new TPaveText(0.20, 0.68+0.061, 0.32, 0.68+0.161, "NDC");
cat->SetBorderSize( 0 );
cat->SetFillStyle( 0 );
cat->SetTextAlign( 12 );
cat->SetTextSize ( 0.05 );
cat->SetTextColor( 1 );
cat->SetTextFont ( 62 );
cat->AddText(category_extra);
cat->Draw();
#ifdef MSSM
TPaveText* massA = new TPaveText(0.75, 0.48+0.061, 0.85, 0.48+0.161, "NDC");
massA->SetBorderSize( 0 );
massA->SetFillStyle( 0 );
massA->SetTextAlign( 12 );
massA->SetTextSize ( 0.03 );
massA->SetTextColor( 1 );
massA->SetTextFont ( 62 );
massA->AddText("m_{A}=160GeV");
massA->Draw();
TPaveText* tanb = new TPaveText(0.75, 0.44+0.061, 0.85, 0.44+0.161, "NDC");
tanb->SetBorderSize( 0 );
tanb->SetFillStyle( 0 );
tanb->SetTextAlign( 12 );
tanb->SetTextSize ( 0.03 );
tanb->SetTextColor( 1 );
tanb->SetTextFont ( 62 );
tanb->AddText("tan#beta=20");
tanb->Draw();
TPaveText* scen = new TPaveText(0.75, 0.40+0.061, 0.85, 0.40+0.161, "NDC");
scen->SetBorderSize( 0 );
scen->SetFillStyle( 0 );
scen->SetTextAlign( 12 );
scen->SetTextSize ( 0.03 );
scen->SetTextColor( 1 );
scen->SetTextFont ( 62 );
scen->AddText("mhmax");
scen->Draw();
#endif
#ifdef MSSM
TLegend* leg = new TLegend(0.55, 0.65, 0.94, 0.90);
SetLegendStyle(leg);
leg->AddEntry(bbH , "#phi#rightarrowb#bar{b}" , "L" );
#endif
leg->AddEntry(data, "observed" , "LP");
leg->AddEntry(bkgBBB, "bkgBBB" , "F" );
$ERROR_LEGEND
leg->Draw();
//#ifdef MSSM
// TPaveText* mssm = new TPaveText(0.69, 0.85, 0.90, 0.90, "NDC");
// mssm->SetBorderSize( 0 );
// mssm->SetFillStyle( 0 );
// mssm->SetTextAlign( 12 );
// mssm->SetTextSize ( 0.03 );
// mssm->SetTextColor( 1 );
// mssm->SetTextFont ( 62 );
// mssm->AddText("(m_{A}=250, tan#beta=5)");
// mssm->Draw();
//#else
// TPaveText* mssm = new TPaveText(0.83, 0.85, 0.95, 0.90, "NDC");
// mssm->SetBorderSize( 0 );
// mssm->SetFillStyle( 0 );
// mssm->SetTextAlign( 12 );
// mssm->SetTextSize ( 0.03 );
// mssm->SetTextColor( 1 );
// mssm->SetTextFont ( 62 );
// mssm->AddText("m_{H}=125");
// mssm->Draw();
//#endif
/*
Ratio Data over MC
*/
TCanvas *canv0 = MakeCanvas("canv0", "histograms", 600, 400);
canv0->SetGridx();
canv0->SetGridy();
canv0->cd();
TH1F* zero = (TH1F*)ref ->Clone("zero"); zero->Clear();
TH1F* rat1 = (TH1F*)data->Clone("rat");
rat1->Divide(bkgBBB);
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
if(rat1->GetBinContent(ibin+1)>0){
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
}
zero->SetBinContent(ibin+1, 0.);
}
rat1->SetLineColor(kBlack);
rat1->SetFillColor(kGray );
rat1->SetMaximum(+1.5);
rat1->SetMinimum(-1.5);
rat1->GetYaxis()->CenterTitle();
rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
rat1->GetXaxis()->SetTitle("#bf{m_{b#bar{b}} [GeV]}");
rat1->Draw();
zero->SetLineColor(kBlack);
zero->Draw("same");
canv0->RedrawAxis();
/*
Ratio After fit over Prefit
*/
TCanvas *canv1 = MakeCanvas("canv1", "histograms", 600, 400);
canv1->SetGridx();
canv1->SetGridy();
canv1->cd();
TH1F* rat2 = (TH1F*) bkgBBB->Clone("rat2");
rat2->Divide(ref);
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
if(rat2->GetBinContent(ibin+1)>0){
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat2 ->SetBinContent(ibin+1, rat2->GetBinContent(ibin+1)-1.);
}
}
rat2->SetLineColor(kRed+ 3);
rat2->SetFillColor(kRed-10);
rat2->SetMaximum(+0.3);
rat2->SetMinimum(-0.3);
rat2->GetYaxis()->SetTitle("#bf{Fit/Prefit-1}");
rat2->GetYaxis()->CenterTitle();
rat2->GetXaxis()->SetTitle("#bf{m_{b#bar{b}} [GeV]}");
rat2->GetXaxis()->SetRange(0, 28);
rat2->Draw();
zero->SetLineColor(kBlack);
zero->Draw("same");
canv1->RedrawAxis();
/*
Relative shift per sample
*/
TCanvas *canv2 = MakeCanvas("canv2", "histograms", 600, 400);
canv2->SetGridx();
canv2->SetGridy();
canv2->cd();
InitHist (scales[0], "", "", kMagenta-10, 1001);
scales[0]->Draw();
scales[0]->GetXaxis()->SetBinLabel(1, "#bf{bkgBBB}");
#ifdef MSSM
scales[0]->GetXaxis()->SetBinLabel(2, "#bf{bbH}" );
scales[0]->GetXaxis()->SetBinLabel(3, "#bf{NONE}" );
#endif
scales[0]->SetMaximum(+1.0);
scales[0]->SetMinimum(-1.0);
scales[0]->GetYaxis()->CenterTitle();
scales[0]->GetYaxis()->SetTitle("#bf{Fit/Prefit-1}");
zero->Draw("same");
canv2->RedrawAxis();
/*
prepare output
*/
bool isSevenTeV = std::string(inputfile).find("7TeV")!=std::string::npos;
canv ->Print(TString::Format("%s_%sscaled_%s_%s.png" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv ->Print(TString::Format("%s_%sscaled_%s_%s.pdf" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv ->Print(TString::Format("%s_%sscaled_%s_%s.eps" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
TFile* output = new TFile(TString::Format("%s_%sscaled_%s_%s.root", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""), "update");
output->cd();
data ->Write("data_obs");
bkgBBB ->Write("bkgBBB" );
#ifdef MSSM
bbH ->Write("bbH" );
#endif
if(errorBand){
errorBand->Write("errorBand");
}
output->Close();
}
/*
* Main Function
*/
void ratio() {
gStyle->SetFrameLineWidth(1);
//Number of Measurements
const int NUM = 2;
//Measurements and uncertainties
// mean, -stat, +stat, -syst, +syst
double m[NUM][5] = {
0.98, 0.10, 0.10, 0.14, 0.14,
//1.33, 0.32, 0.32, 0.22, 0.22
1.26, 0.37, 0.37, 0.46, 0.46
};
//Theory and uncertainties
// mean, -uncert, +uncert
double t[NUM][3] = {
1.0, 0.114, 0.114,
1.0, 0.111, 0.111
};
// label text, sub-label text
// Note: TString does not work, b/c one cannot pass an array of TStrings
// as an argument to a function
char label[NUM][2][100] = {
"Z#gamma#gamma", "",
//"W#gamma#gamma", ""
"W#gamma#gamma (#mu)", ""
};
// format:
// # color, bgColor, fontSytle, linewidth, markerStyle
int aux[NUM][5] = {
1, 10, 42, 2, 20,
1, 10, 42, 2, 20
};
// determning the x size of the plot
double lowX = LOW_X;
double uppX = UPP_X;
TH2F* lft = new TH2F("lft", "", 50, lowX, uppX, 1, 0.0, 1.0);
// height = NUM*unitHeight + 2*spacers + 1*bottomMargin + 0.5*topMargin
const double unitHeight = 50.0; // even number
const double height = (double(NUM)+2.0)*unitHeight+100.0+30.0;
// how much to step each time to cover the vertical range of the histo in
// exactly NUM+2 steps
const double vstep = unitHeight/(height-100.0-30.0);
const double width = 800.0;
printf("Canvas: width=%d, height=%d\n",
TMath::Nint(width), TMath::Nint(height));
printf("Y-step = %6.4f\n", vstep);
// Set canvas and margins
TCanvas* canvas = new TCanvas("canvas", "canvas", 200, 0,
TMath::Nint(width), TMath::Nint(height));
canvas->SetFillColor(10);
canvas->SetRightMargin(20.0/width);
canvas->SetLeftMargin(20.0/width);
canvas->SetBottomMargin(56.0/height);
canvas->SetTopMargin(30.0/height);
canvas->Draw();
canvas->cd();
//printf("TopMargin : %6.4f\n", canvas->GetTopMargin());
//printf("BottomMargin: %6.4f\n", canvas->GetBottomMargin());
TAxis* xaxis = lft->GetXaxis();
TAxis* yaxis = lft->GetYaxis();
xaxis->CenterTitle(kTRUE);
xaxis->SetTitleSize(0.07);
xaxis->SetTitleFont(62);
xaxis->SetTitleOffset(1.1);
xaxis->SetNdivisions(6,5,0);
xaxis->SetLabelOffset(0.01);
xaxis->SetLabelSize(0.05);
xaxis->SetLabelFont(42);
yaxis->SetLabelSize(0.0);
yaxis->SetNdivisions(-1);
lft->SetXTitle("Cross Section Ratio #sigma_{Exp} / #sigma_{Theory}");
lft->SetYTitle("");
lft->SetStats(kFALSE);
lft->SetTitle("");
lft->Draw();
// Draw Theory Bands
for (int i=0; i!=NUM; ++i) {
drawTheory(i, t[i][0], t[i][1], t[i][2], vstep);
}
canvas->RedrawAxis();
gPad->RedrawAxis();
// Draw Measurements
for (int i=0; i!=NUM; ++i) {
drawMeasurement(i, m[i], label[i], aux[i], vstep, lft, canvas);
}
//Set CMS Preliminary marker
int iPeriod=2; // 8 TeV
int iPos = 0; //
CMS_lumi( canvas, iPeriod, iPos );
// Print
//canvas->Print("Ratio_CrossSec_Exp_Theory.pdf");
canvas->Draw();
}
void plot(TString hname, TString legpos, TString pdfname, TString pdfmode="", Int_t rebinFactor=2)
{
TGraphAsymmErrors* gJES = new TGraphAsymmErrors(); gJES->GetXaxis()->SetTitle(histos1[hname+"_calib"]->GetXaxis()->GetTitle()); gJES->GetYaxis()->SetTitle("Normalized"); gJES->SetTitle(histos1[hname+"_calib"]->GetTitle());
TGraphAsymmErrors* gJER = new TGraphAsymmErrors(); gJER->GetXaxis()->SetTitle(histos1[hname+"_calib"]->GetXaxis()->GetTitle()); gJER->GetYaxis()->SetTitle("Normalized"); gJER->SetTitle(histos1[hname+"_calib"]->GetTitle());
TGraphAsymmErrors* gTOT = new TGraphAsymmErrors(); gTOT->GetXaxis()->SetTitle(histos1[hname+"_calib"]->GetXaxis()->GetTitle()); gTOT->GetYaxis()->SetTitle("Normalized"); gTOT->SetTitle(histos1[hname+"_calib"]->GetTitle());
Double_t entries_calib = 0;
for(Int_t i=1 ; i<=histos1[hname+"_calib"]->GetNbinsX() ; i++) entries_calib+=histos1[hname+"_calib"]->GetBinContent(i);
Double_t entries_uncalib = 0;
for(Int_t i=1 ; i<=histos1[hname+"_uncalib"]->GetNbinsX() ; i++) entries_uncalib+=histos1[hname+"_uncalib"]->GetBinContent(i);
histos1[hname+"_uncalib"]->Rebin(rebinFactor);
histos1[hname+"_calib"]->Rebin(rebinFactor);
histos1[hname+"_JESUP"]->Rebin(rebinFactor);
histos1[hname+"_JESDWN"]->Rebin(rebinFactor);
histos1[hname+"_JERUP"]->Rebin(rebinFactor);
histos1[hname+"_JERDWN"]->Rebin(rebinFactor);
for(Int_t i=1 ; i<=histos1[hname+"_calib"]->GetNbinsX() ; i++)
{
float x = histos1[hname+"_calib"]->GetBinCenter(i);
float y = histos1[hname+"_calib"]->GetBinContent(i)/entries_calib;
float dx = histos1[hname+"_calib"]->GetBinWidth(i)/2;
gJES->SetPoint(i-1, x, y);
gJER->SetPoint(i-1, x, y);
gTOT->SetPoint(i-1, x, y);
float dyJES1 = fabs(y-histos1[hname+"_JESUP"]->GetBinContent(i)/entries_calib);
float dyJES2 = fabs(y-histos1[hname+"_JESDWN"]->GetBinContent(i)/entries_calib);
float dyJES = (dyJES1>dyJES2) ? dyJES1 : dyJES2;
float yErrDwnJES = dyJES;
float yErrUpJES = dyJES;
if((y-yErrDwnJES)<0.) yErrDwnJES = 0.;
gJES->SetPointError(i-1, dx,dx, yErrDwnJES,yErrUpJES);
float dyJER1 = fabs(y-histos1[hname+"_JERUP"]->GetBinContent(i)/entries_calib);
float dyJER2 = fabs(y-histos1[hname+"_JERDWN"]->GetBinContent(i)/entries_calib);
float dyJER = (dyJER1>dyJER2) ? dyJER1 : dyJER2;
float yErrDwnJER = dyJER;
float yErrUpJER = dyJER;
if((y-yErrDwnJER)<0.) yErrDwnJER = 0.;
gJER->SetPointError(i-1, dx,dx, yErrDwnJER,yErrUpJER);
float yErrDwnTOT = sqrt(yErrDwnJES*yErrDwnJES + yErrDwnJER*yErrDwnJER);
float yErrUpTOT = sqrt(yErrUpJES*yErrUpJES + yErrUpJER*yErrUpJER);
if((y-yErrDwnTOT)<0.) yErrDwnTOT = 0.;
gTOT->SetPointError(i-1, dx,dx, yErrDwnTOT,yErrUpTOT);
}
gTOT->SetFillColor(kRed); gTOT->SetLineColor(kRed);
gTOT->SetFillColor(kRed); gTOT->SetLineColor(kRed);
gJER->SetFillColor(kYellow); gJER->SetLineColor(kYellow);
gJER->SetFillColor(kYellow); gJER->SetLineColor(kYellow);
gJES->SetFillColor(kGreen); gJES->SetLineColor(kGreen);
gJES->SetFillColor(kGreen); gJES->SetLineColor(kGreen);
TMultiGraph *mgBands = new TMultiGraph();
mgBands->Add(gTOT);
mgBands->Add(gJER);
mgBands->Add(gJES);
TLegend* legLeft = new TLegend(0.12,0.65,0.42,0.85,NULL,"brNDC");
legLeft->SetFillStyle(4000); //will be transparent
legLeft->SetFillColor(0);
legLeft->SetTextFont(42);
legLeft->SetBorderSize(0);
legLeft->AddEntry(histos1[hname+"_calib"], "Calibrated jets","ple");
legLeft->AddEntry(histos1[hname+"_uncalib"], "Non calibrated jets","ple");
legLeft->AddEntry(gJES, "JES uncertainty","f");
legLeft->AddEntry(gJER, "JER uncertainty","f");
legLeft->AddEntry(gTOT, "Total uncertainty","f");
TLegend* legRight = new TLegend(0.5,0.65,0.8,0.85,NULL,"brNDC");
legRight->SetFillStyle(4000); //will be transparent
legRight->SetFillColor(0);
legRight->SetTextFont(42);
legRight->SetBorderSize(0);
legRight->AddEntry(histos1[hname+"_calib"], "Calibrated jets","ple");
legRight->AddEntry(histos1[hname+"_uncalib"], "Non calibrated jets","ple");
legRight->AddEntry(gJES, "JES uncertainty","f");
legRight->AddEntry(gJER, "JER uncertainty","f");
legRight->AddEntry(gTOT, "Total uncertainty","f");
histos1[hname+"_calib"]->Scale(1./entries_calib);
histos1[hname+"_uncalib"]->Scale(1./entries_uncalib);
TCanvas* cnv = new TCanvas("c","c",600,400);
cnv->Draw();
cnv->SetTicks(1,1);
cnv->cd();
histos1[hname+"_calib"]->Draw("p");
mgBands->Draw("a2");
mgBands->GetXaxis()->SetTitle(histos1[hname+"_calib"]->GetXaxis()->GetTitle());
mgBands->GetYaxis()->SetTitle("Normalized");
mgBands->SetTitle(histos1[hname+"_calib"]->GetTitle());
histos1[hname+"_uncalib"]->GetYaxis()->SetTitle("Normalized");
histos1[hname+"_uncalib"]->Draw("p same");
histos1[hname+"_calib"]->GetYaxis()->SetTitle("Normalized");
histos1[hname+"_calib"]->Draw("p same");
if(legpos=="left") legLeft->Draw("same");
if(legpos=="right") legRight->Draw("same");
ptxt->Draw("same");
cnv->RedrawAxis();
cnv->Update();
TString pngname = "figures/syst."+hname+".png"; pngname.ReplaceAll("calib_","");
TString epsname = "figures/syst."+hname+".eps"; epsname.ReplaceAll("calib_","");
cnv->SaveAs(pngname);
cnv->SaveAs(epsname);
cnv->SaveAs(pdfname+pdfmode);
delete gJES;
delete gJER;
delete gTOT;
delete mgBands;
delete legLeft;
delete legRight;
delete cnv;
}
void plot_BSM_MCFM(int SignalOnly=0){
gROOT->ProcessLine(".x tdrstyle.cc");
double mPOLE = 125.6;
TString OUTPUT_NAME;
OUTPUT_NAME = "HtoZZ4l_MCFM_125p6_BSMPlots";
if (SignalOnly==0) OUTPUT_NAME.Append(".root");
else OUTPUT_NAME.Append("_SignalOnly.root");
TString coutput_common = user_TemplateswithTrees_dir + "../BSMReweight_GenLevel/Plots/";
gSystem->Exec("mkdir -p " + coutput_common);
TString coutput = coutput_common + OUTPUT_NAME;
TFile* foutput = new TFile(coutput, "recreate");
foutput->cd();
float ZZMass = 0;
float p0plus_VAJHU;
float p0hplus_VAJHU;
float p0minus_VAJHU;
float p0_g1prime2_VAJHU;
float p0_g1prime4_VAJHU;
float pg1g2_VAJHU;
float pg1g4_VAJHU;
float pg1g1prime2_VAJHU;
float pg1g1prime4_VAJHU;
TChain* tc[2][3][4];
TH1F* hfill[4][9];
int nbinsx = 73;
double xlimits[2]={ 160, 1620 };
if (SignalOnly==1){
xlimits[0]=100;
nbinsx = 76;
}
for (int t=0; t<4; t++){
for (int ac=0; ac<9; ac++){
hfill[t][ac]= new TH1F(Form("hSum_BSI%i_Hypo%i", t, ac), "", nbinsx, xlimits[0], xlimits[1]);
hfill[t][ac]->SetXTitle("m_{4l} (GeV)");
hfill[t][ac]->SetYTitle(Form("Events / %.0f GeV", (xlimits[1]-xlimits[0])/nbinsx));
}
}
double nCounted[2][3][9]={ { { 0 } } };
double nCountedScaled[2][3][9]={ { { 0 } } };
for (int erg_tev=7; erg_tev<9; erg_tev++){
for (int folder=0; folder<3; folder++){
TString comstring;
comstring.Form("%iTeV", erg_tev);
TString erg_dir;
erg_dir.Form("LHC_%iTeV/", erg_tev);
int EnergyIndex = 1;
if (erg_tev == 7) EnergyIndex = 0;
TString cinput_common = user_TemplateswithTrees_dir + "../BSMReweight_GenLevel/";
cinput_common.Append(+erg_dir);
cinput_common += user_folder[folder] + "/";
cout << cinput_common << endl;
for (int t=0; t<4; t++){
TString INPUT_NAME;
INPUT_NAME = "HtoZZ4l_MCFM_125p6_BSMTrees_";
INPUT_NAME += sample_suffix[t] + ".root";
INPUT_NAME.Prepend(cinput_common);
tc[EnergyIndex][folder][t] = new TChain("GenTree");
if (t!=3) tc[EnergyIndex][folder][t]->Add(INPUT_NAME);
tc[EnergyIndex][folder][t]->SetBranchAddress("ZZMass", &ZZMass);
tc[EnergyIndex][folder][t]->SetBranchAddress("p0plus_VAJHU", &p0plus_VAJHU);
tc[EnergyIndex][folder][t]->SetBranchAddress("p0hplus_VAJHU", &p0hplus_VAJHU);
tc[EnergyIndex][folder][t]->SetBranchAddress("p0minus_VAJHU", &p0minus_VAJHU);
tc[EnergyIndex][folder][t]->SetBranchAddress("p0_g1prime2_VAJHU", &p0_g1prime2_VAJHU);
tc[EnergyIndex][folder][t]->SetBranchAddress("p0_g1prime4_VAJHU", &p0_g1prime4_VAJHU);
tc[EnergyIndex][folder][t]->SetBranchAddress("pg1g2_VAJHU", &pg1g2_VAJHU);
tc[EnergyIndex][folder][t]->SetBranchAddress("pg1g4_VAJHU", &pg1g4_VAJHU);
tc[EnergyIndex][folder][t]->SetBranchAddress("pg1g1prime2_VAJHU", &pg1g1prime2_VAJHU);
tc[EnergyIndex][folder][t]->SetBranchAddress("pg1g1prime4_VAJHU", &pg1g1prime4_VAJHU);
}
double nsig_counted[9] ={ 0 };
for (int ev=0; ev<tc[EnergyIndex][folder][0]->GetEntries(); ev++){
tc[EnergyIndex][folder][0]->GetEntry(ev);
if (fabs(ZZMass-mPOLE)<0.1){
nsig_counted[0] += p0plus_VAJHU;
nsig_counted[1] += p0hplus_VAJHU;
nsig_counted[2] += p0minus_VAJHU;
nsig_counted[3] += p0_g1prime2_VAJHU;
nsig_counted[4] += p0_g1prime4_VAJHU;
nsig_counted[5] += (2.*(p0plus_VAJHU+p0hplus_VAJHU)-pg1g2_VAJHU);
nsig_counted[6] += pg1g4_VAJHU;
nsig_counted[7] += pg1g1prime2_VAJHU;
nsig_counted[8] += pg1g1prime4_VAJHU;
}
}
for (int ac=0; ac<9; ac++) nCounted[EnergyIndex][folder][ac] = nsig_counted[ac];
}
}
for (int erg_tev=7; erg_tev<9; erg_tev++){
for (int folder=0; folder<3; folder++){
int EnergyIndex = 1;
if (erg_tev == 7) EnergyIndex = 0;
double nsig_SM = nSM_ScaledPeak[EnergyIndex][folder];
double SMscale = nsig_SM/nCounted[EnergyIndex][folder][0];
double scale=1;
for (int t=0; t<4; t++){
for (int ev=0; ev<tc[EnergyIndex][folder][t]->GetEntries(); ev++){
tc[EnergyIndex][folder][t]->GetEntry(ev);
if (ZZMass<xlimits[0]) continue;
if (ZZMass>=xlimits[1]) ZZMass=xlimits[1]*0.999;
scale = SMscale;
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][0] = nCounted[EnergyIndex][folder][0]*scale;
hfill[t][0]->Fill(ZZMass, p0plus_VAJHU*scale);
scale = SMscale;
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][1] = nCounted[EnergyIndex][folder][1]*scale;
hfill[t][1]->Fill(ZZMass, p0hplus_VAJHU*scale);
scale = SMscale;
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][2] = nCounted[EnergyIndex][folder][2]*scale;
hfill[t][2]->Fill(ZZMass, p0minus_VAJHU*scale);
scale = SMscale;
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][3] = nCounted[EnergyIndex][folder][3]*scale;
hfill[t][3]->Fill(ZZMass, p0_g1prime2_VAJHU*scale);
scale = SMscale;
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][4] = nCounted[EnergyIndex][folder][4]*scale;
hfill[t][4]->Fill(ZZMass, p0_g1prime4_VAJHU*scale);
scale = SMscale;
if (t>0){
hfill[t][5]->Fill(ZZMass, pg1g2_VAJHU*scale);
}
else{
scale *= (nCounted[0][2][0]+nCounted[1][2][0])/(nCounted[0][2][5]+nCounted[1][2][5]);
hfill[t][5]->Fill(ZZMass, (2.*(p0plus_VAJHU+p0hplus_VAJHU)-pg1g2_VAJHU)*scale);
}
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][5] = nCounted[EnergyIndex][folder][5]*scale;
scale = SMscale;
if (t==0) scale *= (nCounted[0][2][0]+nCounted[1][2][0])/(nCounted[0][2][6]+nCounted[1][2][6]);
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][6] = nCounted[EnergyIndex][folder][6]*scale;
hfill[t][6]->Fill(ZZMass, pg1g4_VAJHU*scale);
scale = SMscale;
if (t==0) scale *= (nCounted[0][2][0]+nCounted[1][2][0])/(nCounted[0][2][7]+nCounted[1][2][7]);
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][7] = nCounted[EnergyIndex][folder][7]*scale;
hfill[t][7]->Fill(ZZMass, pg1g1prime2_VAJHU*scale);
scale = SMscale;
// if (t==0) scale *= (nCounted[0][2][0]+nCounted[1][2][0])/(nCounted[0][2][8]+nCounted[1][2][8]);
if (t==0 && ev==0) nCountedScaled[EnergyIndex][folder][8] = nCounted[EnergyIndex][folder][8]*scale;
hfill[t][8]->Fill(ZZMass, pg1g1prime4_VAJHU*scale);
}
delete tc[EnergyIndex][folder][t];
}
}
}
for (int ac=1; ac<9; ac++){
double nTotal[2]={ 0 };
for (int erg_tev=7; erg_tev<9; erg_tev++){
for (int folder=0; folder<3; folder++){
int EnergyIndex = 1;
if (erg_tev == 7) EnergyIndex = 0;
nTotal[0] += nCountedScaled[EnergyIndex][folder][0];
nTotal[1] += nCountedScaled[EnergyIndex][folder][ac];
}
}
if (ac!=8) hfill[0][ac]->Scale(nTotal[0]/nTotal[1]);
else hfill[0][ac]->Scale(0.5);
}
double maxplot=0;
for (int t=0; t<4; t++){
for (int ac=0; ac<9; ac++){
if (SignalOnly==0 && ac<5) maxplot = max(maxplot, hfill[t][ac]->GetMaximum());
else if (SignalOnly==1 && !(ac<5 && ac>0) && t==0) maxplot = max(maxplot, hfill[t][ac]->GetMaximum());
hfill[t][ac]->SetLineWidth(2);
if (t==0 && ac>=5){
hfill[t][ac]->SetLineStyle(7);
// hfill[t][ac]->Add(hfill[1][ac]);
}
if (t==1) hfill[t][ac]->SetLineStyle(3);
if (t==3) hfill[t][ac]->SetLineStyle(9);
hfill[t][ac]->GetXaxis()->SetLabelFont(42);
hfill[t][ac]->GetXaxis()->SetLabelOffset(0.007);
hfill[t][ac]->GetXaxis()->SetLabelSize(0.04);
hfill[t][ac]->GetXaxis()->SetTitleSize(0.06);
hfill[t][ac]->GetXaxis()->SetTitleOffset(0.9);
hfill[t][ac]->GetXaxis()->SetTitleFont(42);
hfill[t][ac]->GetYaxis()->SetNdivisions(505);
hfill[t][ac]->GetYaxis()->SetLabelFont(42);
hfill[t][ac]->GetYaxis()->SetLabelOffset(0.007);
hfill[t][ac]->GetYaxis()->SetLabelSize(0.04);
hfill[t][ac]->GetYaxis()->SetTitleSize(0.06);
hfill[t][ac]->GetYaxis()->SetTitleOffset(1.1);
hfill[t][ac]->GetYaxis()->SetTitleFont(42);
}
}
TPaveText* pt = new TPaveText(0.15, 0.93, 0.85, 1, "brNDC");
pt->SetBorderSize(0);
pt->SetFillStyle(0);
pt->SetTextAlign(12);
pt->SetTextFont(42);
pt->SetTextSize(0.045);
TText* text = pt->AddText(0.025, 0.45, "#font[61]{CMS}");
text->SetTextSize(0.044);
text = pt->AddText(0.165, 0.42, "#font[52]{Simulation}");
text->SetTextSize(0.0315);
TString cErgTev = "#font[42]{19.7 fb^{-1} (8 TeV) + 5.1 fb^{-1} (7 TeV)}";
text = pt->AddText(0.537, 0.45, cErgTev);
text->SetTextSize(0.0315);
float lxmin = 0.22;
float lxwidth = 0.38;
float lymax = 0.9;
float lywidth = 0.3;
float lxmax = lxmin + lxwidth;
float lymin = lymax;
if (SignalOnly==0) lymin -= lywidth*4./5.;
else lymin -= lywidth;
float lxmin2 = 0.22+0.39;
float lymax2 = lymax;
float lxmax2 = lxmin2 + lxwidth;
float lymin2 = lymax2;
if (SignalOnly==0) lymin2 -= lywidth*2./5.;
else lymin2 -= lywidth*4./5.;
if (SignalOnly==1){
float lxmin3 = lxmin2;
float lymax3 = lymax2;
float lxmax3 = lxmax2;
float lymin3 = lymin2;
lxmin2 = lxmin;
lxmax2 = lxmax;
lymin2 = lymin;
lymax2 = lymax;
lxmin = lxmin3;
lxmax = lxmax3;
lymin = lymin3;
lymax = lymax3;
}
float pxmin = 0.756;
float pymin = 0.76;
float pxmax = 0.85;
if (SignalOnly==1){
pymin -= 0.12;
}
float pymax = pymin+0.05;
TPaveText* ptx = new TPaveText(pxmin, pymin, pxmax, pymax, "brNDC");
ptx->SetBorderSize(0);
ptx->SetTextFont(42);
ptx->SetTextSize(0.04);
ptx->SetLineColor(1);
ptx->SetLineStyle(1);
ptx->SetLineWidth(1);
ptx->SetFillColor(0);
ptx->SetFillStyle(0);
text = ptx->AddText(0.01, 0.01, "gg#rightarrow4l");
text->SetTextSize(0.04);
TString canvasname = "cCanvas_MCFMBSM_GenLevel";
if (SignalOnly==1) canvasname.Append("_SignalOnly");
TCanvas* cc = new TCanvas(canvasname, "", 8, 30, 800, 800);
cc->cd();
gStyle->SetOptStat(0);
cc->SetFillColor(0);
cc->SetBorderMode(0);
cc->SetBorderSize(2);
cc->SetTickx(1);
cc->SetTicky(1);
cc->SetLeftMargin(0.17);
cc->SetRightMargin(0.05);
cc->SetTopMargin(0.07);
cc->SetBottomMargin(0.13);
cc->SetFrameFillStyle(0);
cc->SetFrameBorderMode(0);
cc->SetFrameFillStyle(0);
cc->SetFrameBorderMode(0);
cc->SetLogy();
TLegend* ll;
TLegend* ll2;
ll = new TLegend(lxmin2, lymin2, lxmax2, lymax2);
ll2 = new TLegend(lxmin, lymin, lxmax, lymax);
ll->SetBorderSize(0);
ll->SetTextFont(42);
ll->SetTextSize(0.04);
ll->SetLineColor(1);
ll->SetLineStyle(1);
ll->SetLineWidth(1);
ll->SetFillColor(0);
ll->SetFillStyle(0);
ll2->SetBorderSize(0);
ll2->SetTextFont(42);
ll2->SetTextSize(0.04);
ll2->SetLineColor(1);
ll2->SetLineStyle(1);
ll2->SetLineWidth(1);
ll2->SetFillColor(0);
ll2->SetFillStyle(0);
TString strACtitle[9]={ "",
"f_{a2}=1", "f_{a3}=1", "f_{#Lambda1}=1", "f_{#LambdaQ}=1",
"f_{a2}=0.5, #phi_{#lower[-0.2]{a2}}=#pi", "f_{a3}=0.5", "f_{#Lambda1}=0.5", "f_{#LambdaQ}=0.5"
};
int iDraw = 2 - 2*SignalOnly;
if (SignalOnly==0) hfill[iDraw][0]->GetYaxis()->SetRangeUser(7e-3, maxplot*15.);
else{
double histmin = 7e-3;
if (hfill[iDraw][0]->GetMinimum()>0) histmin = hfill[iDraw][0]->GetMinimum();
hfill[iDraw][0]->GetYaxis()->SetRangeUser(histmin, maxplot*2000.);
}
hfill[iDraw][0]->GetXaxis()->SetRangeUser(xlimits[0], 800.);
hfill[iDraw][0]->SetLineColor(kBlack);
if (SignalOnly==0){
hfill[iDraw][0]->SetFillColor(kAzure-2);
hfill[iDraw][0]->SetFillStyle(1001);
}
hfill[iDraw][0]->Draw("hist");
hfill[iDraw][1]->SetLineColor(kBlue);
hfill[iDraw][1]->Draw("histsame");
hfill[iDraw][2]->SetLineColor(kRed);
hfill[iDraw][2]->Draw("histsame");
hfill[iDraw][3]->SetLineColor(kViolet);
hfill[iDraw][3]->Draw("histsame");
hfill[iDraw][4]->SetLineColor(kGreen+2);
hfill[iDraw][4]->Draw("histsame");
if (SignalOnly==1){
hfill[iDraw][5]->SetLineColor(kBlue);
hfill[iDraw][5]->Draw("histsame");
hfill[iDraw][6]->SetLineColor(kRed);
hfill[iDraw][6]->Draw("histsame");
hfill[iDraw][7]->SetLineColor(kViolet);
hfill[iDraw][7]->Draw("histsame");
hfill[iDraw][8]->SetLineColor(kGreen+2);
hfill[iDraw][8]->Draw("histsame");
}
if (SignalOnly==0){
hfill[1][0]->SetLineColor(kBlack);
hfill[1][0]->SetLineStyle(3);
hfill[1][0]->Draw("histsame");
}
hfill[iDraw][0]->Draw("histsame");
TLegendEntry* legendtext;
if (SignalOnly==0){
legendtext = ll->AddEntry(hfill[iDraw][0], "SM total", "f");
legendtext = ll->AddEntry(hfill[1][0], "SM bkg.", "f");
legendtext->SetFillStyle(1001);
legendtext->SetFillColor(hfill[1][0]->GetFillColor());
}
else{
legendtext = ll->AddEntry(hfill[iDraw][0], "SM signal", "f");
legendtext->SetFillStyle(3001);
}
if (SignalOnly==0){
legendtext = ll2->AddEntry(hfill[iDraw][4], Form("#Gamma_{H}=#Gamma^{SM}_{H}, %s", strACtitle[4].Data()), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][4]->GetFillColor());
legendtext = ll2->AddEntry(hfill[iDraw][2], Form("#Gamma_{H}=#Gamma^{SM}_{H}, %s", strACtitle[2].Data()), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][2]->GetFillColor());
legendtext = ll2->AddEntry(hfill[iDraw][1], Form("#Gamma_{H}=#Gamma^{SM}_{H}, %s", strACtitle[1].Data()), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][1]->GetFillColor());
legendtext = ll2->AddEntry(hfill[iDraw][3], Form("#Gamma_{H}=#Gamma^{SM}_{H}, %s", strACtitle[3].Data()), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][3]->GetFillColor());
}
else{
legendtext = ll->AddEntry(hfill[iDraw][4], strACtitle[4].Data(), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][4]->GetFillColor());
legendtext = ll->AddEntry(hfill[iDraw][2], strACtitle[2].Data(), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][2]->GetFillColor());
legendtext = ll->AddEntry(hfill[iDraw][1], strACtitle[1].Data(), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][1]->GetFillColor());
legendtext = ll->AddEntry(hfill[iDraw][3], strACtitle[3].Data(), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][3]->GetFillColor());
}
if (SignalOnly==1){
legendtext = ll2->AddEntry(hfill[iDraw][8], strACtitle[8].Data(), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][8]->GetFillColor());
legendtext = ll2->AddEntry(hfill[iDraw][5], strACtitle[5].Data(), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][5]->GetFillColor());
legendtext = ll2->AddEntry(hfill[iDraw][7], strACtitle[7].Data(), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][7]->GetFillColor());
legendtext = ll2->AddEntry(hfill[iDraw][6], strACtitle[6].Data(), "f");
legendtext->SetFillStyle(3001);
legendtext->SetFillColor(hfill[iDraw][6]->GetFillColor());
}
ll->Draw("same");
ll2->Draw("same");
ptx->Draw();
pt->Draw();
cc->RedrawAxis();
cc->Update();
canvasname.Prepend(coutput_common);
TString canvasname_pdf = canvasname;
TString canvasname_eps = canvasname;
TString canvasname_png = canvasname;
TString canvasname_root = canvasname;
TString canvasname_c = canvasname;
canvasname_pdf.Append(".pdf");
canvasname_eps.Append(".eps");
canvasname_png.Append(".png");
canvasname_root.Append(".root");
canvasname_c.Append(".C");
cc->SaveAs(canvasname_pdf);
cc->SaveAs(canvasname_eps);
cc->SaveAs(canvasname_png);
cc->SaveAs(canvasname_root);
cc->SaveAs(canvasname_c);
foutput->WriteTObject(cc);
delete ll2;
delete ll;
cc->Close();
delete ptx;
delete pt;
for (int t=0; t<4; t++){
for (int ac=0; ac<5; ac++){
foutput->WriteTObject(hfill[t][ac]);
delete hfill[t][ac];
}
}
foutput->Close();
}
void PlotFinal(TGraphAsymmErrors* g_data_final, TGraphAsymmErrors* g_mg_final, TGraphAsymmErrors* g_ph_final, TGraphAsymmErrors* g_ratio_phistar, TGraphAsymmErrors* g_ratio_mg_phistar, TGraphAsymmErrors* g_ratio_ph_phistar, bool isPlot2 = 0, TGraphAsymmErrors* g_re_final = 0, TGraphAsymmErrors* g_ratio_re_phistar = 0) {
vector<TGraphAsymmErrors*> g_data = SplitGraph(g_data_final);
vector<TGraphAsymmErrors*> g_mg = SplitGraph(g_mg_final);
vector<TGraphAsymmErrors*> g_ph = SplitGraph(g_ph_final);
vector<TGraphAsymmErrors*> r_data = SplitGraph(g_ratio_phistar, 1);
vector<TGraphAsymmErrors*> r_mg = SplitGraph(g_ratio_mg_phistar);
vector<TGraphAsymmErrors*> r_ph = SplitGraph(g_ratio_ph_phistar);
vector<TGraphAsymmErrors*> g_re = SplitGraph(g_re_final);
vector<TGraphAsymmErrors*> r_re = SplitGraph(g_ratio_re_phistar);
//New Graphs
TGraphAsymmErrors* g_ANlo_final = ResbosFromRaj(2);
TGraphAsymmErrors* r_ANlo_Ratio_final = CreateRatio(g_data_final, g_ANlo_final, 0);
TGraphAsymmErrors* g_PowPyth8_final = ResbosFromRaj(1);
TGraphAsymmErrors* r_PowPyth8_Ratio_final = CreateRatio(g_data_final, g_PowPyth8_final, 0);
vector<TGraphAsymmErrors*> g_ANlo = SplitGraph(g_ANlo_final);
vector<TGraphAsymmErrors*> r_ANlo = SplitGraph(r_ANlo_Ratio_final);
vector<TGraphAsymmErrors*> g_Pyth8 = SplitGraph(g_PowPyth8_final);
vector<TGraphAsymmErrors*> r_Pyth8 = SplitGraph(r_PowPyth8_Ratio_final);
vector<TGraphAsymmErrors*> g_dummy = CreateDummy(g_data);
OneDYPlot(g_data, g_mg, g_ph, g_re, g_ANlo, g_Pyth8);
for (uint i = 0; i < ny; i++) {
// for (uint i=0; i<5; i++){
std::ostringstream strs;
strs << i;
//TO HERE
std::string Canvasname = "EventEff_Bin" + strs.str();
TCanvas* FinalPhiTot = new TCanvas(Canvasname.c_str(), Canvasname.c_str(), 800, 900);
FinalPhiTot->Divide(1, 2);
FinalPhiTot->cd(1);
gPad->SetPad("p1", "p1", 0, 2.5 / 9.0, 1, 1, kWhite, 0, 0);
gPad->SetBottomMargin(0.01);
gPad->SetTopMargin(0.06);
gPad->SetLeftMargin(0.15);
gPad->SetRightMargin(0.06);
gPad->SetLogx(1);
gPad->SetLogy(1);
g_dummy[i]->GetXaxis()->SetRangeUser(0.001, 10.0);
if (doNorm) g_dummy[i]->GetYaxis()->SetRangeUser(0.00000005, 1000.0);
else g_dummy[i]->GetYaxis()->SetRangeUser(0.00005, 1000000.0);
g_dummy[i]->GetXaxis()->CenterTitle();
g_dummy[i]->GetYaxis()->CenterTitle();
g_dummy[i]->Draw("A2");
g_mg[i]->SetMarkerColor(kBlue - 7);
g_mg[i]->SetLineColor(kBlue - 7);
g_mg[i]->SetMarkerSize(1);
g_mg[i]->SetLineWidth(2);
g_mg[i]->SetMarkerStyle(21);
g_mg[i]->Draw("PEsame");
g_ph[i]->SetMarkerColor(kRed);
g_ph[i]->SetLineColor(kRed);
g_ph[i]->SetMarkerSize(1);
g_ph[i]->SetLineWidth(2);
g_ph[i]->SetMarkerStyle(22);
g_ph[i]->Draw("PEsame");
if (!isPlot2 && elec == 1 && g_re_final) {
g_re[i]->SetMarkerColor(kGreen + 1);
g_re[i]->SetLineColor(kGreen + 1);
g_re[i]->SetMarkerSize(1);
g_re[i]->SetLineWidth(2);
g_re[i]->SetMarkerStyle(23);
g_re[i]->Draw("PEsame");
}
g_data[i]->SetFillColor(kYellow);
g_data[i]->SetMarkerSize(1);
g_data[i]->SetLineWidth(2);
g_data[i]->SetMarkerStyle(20);
g_data[i]->Draw("PEsame");
g_data[i]->SetFillColor(kYellow);
TLegend* leg;
if (isPlot2) leg = new TLegend(0.15, 0.06, 0.80, 0.27);
else leg = new TLegend(0.15, 0.06, 0.80, 0.31); //TLegend(0.45,0.73,0.94,0.93);//.19 0.06
leg->SetFillStyle(0);
leg->SetBorderSize(0);
leg->SetLineWidth(1);
leg->SetNColumns(1);
leg->SetTextFont(42);
if (!isPlot2) {
leg->AddEntry(g_data[i], "2012 data", "PEF");
if (Type == "elec") {
leg->AddEntry(g_mg[i], "#gamma*/Z #rightarrow ee (MadGraph+Pythia6 Z2*)", "P");
leg->AddEntry(g_ph[i], "#gamma*/Z #rightarrow ee (Powheg+Pythia6 Z2*)", "P");
//ToDo AMCAt decisions
//if (elec == 1 && g_re_final) leg->AddEntry(g_re[i], "#gamma*/Z #rightarrow ee (Resbos)", "P");
if (elec == 1 && g_re_final) leg->AddEntry(g_re[i], "#gamma*/Z #rightarrow ee (POWHEG+Pythia8)", "P");
}
if (Type == "muon") {
leg->AddEntry(g_mg[i], "#gamma*/Z #rightarrow #mu#mu (MadGraph+Pythia6 Z2*)", "P");
leg->AddEntry(g_ph[i], "#gamma*/Z #rightarrow #mu#mu (Powheg+Pythia6 Z2*)", "P");
if (elec == 1 && g_re_final) leg->AddEntry(g_re[i], "#gamma*/Z #rightarrow #mu#mu (Resbos)", "P");
//if (elec == 1 && g_re_final) leg->AddEntry(g_re[i], "#gamma*/Z #rightarrow #mu#mu (POWHEG+Pythia8 CUETP8M1)", "P");
}
if (Type == "combined") {
leg->AddEntry(g_mg[i], "#gamma*/Z #rightarrow ll (MadGraph+Pythia6 Z2*)", "P");
leg->AddEntry(g_ph[i], "#gamma*/Z #rightarrow ll (Powheg+Pythia6 Z2*)", "P");
if (elec == 1 && g_re_final) leg->AddEntry(g_re[i], "#gamma*/Z #rightarrow ll (Resbos)", "P");
//if (elec == 1 && g_re_final) leg->AddEntry(g_re[i], "#gamma*/Z #rightarrow ll (POWHEG+Pythia8 CUETP8M1)", "P");
}
} else {
if (Type == "combined") {
leg->AddEntry(g_mg[i], "#gamma*/Z #rightarrow ee (2012 data)", "P");
leg->AddEntry(g_ph[i], "#gamma*/Z #rightarrow #mu#mu (2012 data)", "P");
if (doMG)leg->AddEntry(g_data[i], "#gamma*/Z #rightarrow ll (MadGraph+Pythia6 Z2*)", "PEF");
else leg->AddEntry(g_data[i], "#gamma*/Z #rightarrow ll (Powheg+Pythia6 Z2*)", "PEF");
}
if (Type == "elec") {
leg->AddEntry(g_mg[i], "data (unfolded with Powheg)", "P");
leg->AddEntry(g_ph[i], "data (unfolded with MadGraph)", "P");
if (doMG)leg->AddEntry(g_data[i], "#gamma*/Z #rightarrow ll (MadGraph+Pythia6 Z2*)", "PEF");
else leg->AddEntry(g_data[i], "#gamma*/Z #rightarrow ll (Powheg+Pythia6 Z2*)", "PEF");
}
}
leg->Draw();
TLatex mark3;
mark3.SetTextSize(0.043);
mark3.SetTextFont(42);
mark3.SetNDC(true);
mark3.DrawLatex(0.71, 0.955, "19.7 fb^{-1} (8 TeV)");
TLatex mark;
mark.SetTextSize(0.043);
mark.SetTextFont(42);
mark.SetNDC(true);
if (Type == "elec" && !isPlot2) {
mark.DrawLatex(0.53, 0.88, "|#eta^{e_{0}}| < 2.1, |#eta^{e_{1}}| < 2.4");
mark.DrawLatex(0.53, 0.81, "p_{T}^{e_{0}} > 30 GeV, p_{T}^{e_{1}} > 20 GeV");
mark.DrawLatex(0.53, 0.74, "60 GeV < M_{ee} < 120 GeV");
}
if (Type == "combined" || isPlot2) {
mark.DrawLatex(0.53, 0.88, "|#eta^{l_{0}}| < 2.1, |#eta^{l_{1}}| < 2.4");
mark.DrawLatex(0.53, 0.81, "p_{T}^{l_{0}} > 30 GeV, p_{T}^{l_{1}} > 20 GeV");
mark.DrawLatex(0.53, 0.74, "60 GeV < M_{ll} < 120 GeV");
}
if (i == 0) mark.DrawLatex(0.2, 0.88, "0.0 < |y_{ee}| < 0.4");
if (i == 1) mark.DrawLatex(0.2, 0.88, "0.4 < |y_{ee}| < 0.8");
if (i == 2) mark.DrawLatex(0.2, 0.88, "0.8 < |y_{ee}| < 1.2");
if (i == 3) mark.DrawLatex(0.2, 0.88, "1.2 < |y_{ee}| < 1.6");
if (i == 4) mark.DrawLatex(0.2, 0.88, "1.6 < |y_{ee}| < 2.0");
if (i == 5) mark.DrawLatex(0.2, 0.88, "2.0 < |y_{ee}| < 2.4");
FinalPhiTot->cd(2);
gPad->SetPad("p2", "p2", 0, 0, 1, 2.5 / 9.0, kWhite, 0, 0);
gPad->SetBottomMargin(0.37);
gPad->SetTopMargin(0.01);
gPad->SetLeftMargin(0.15);
gPad->SetRightMargin(0.06);
gPad->SetLogx(1);
r_data[i]->SetLineWidth(2);
r_data[i]->GetXaxis()->SetRangeUser(0.001, 10);
r_data[i]->GetXaxis()->SetTitle("#phi*");
r_data[i]->GetXaxis()->SetTitleOffset(1.05);
r_data[i]->GetXaxis()->SetTitleSize(0.12);
r_data[i]->GetXaxis()->SetLabelSize(0.12);
r_data[i]->GetYaxis()->SetTitle("MC/Data ");
// r_data[i]->GetYaxis()->SetRangeUser(0.8,1.2);
r_data[i]->GetYaxis()->SetTitleOffset(0.32);
r_data[i]->GetYaxis()->SetTitleSize(0.12);
r_data[i]->GetYaxis()->SetLabelSize(0.12);
r_data[i]->SetTitle(0);
if (isPlot2) r_data[i]->GetYaxis()->SetTitle("Data/MC ");
else r_data[i]->GetYaxis()->SetTitle("MC/Data ");
r_data[i]->GetYaxis()->SetRangeUser(0.5, 1.5);
r_data[i]->GetYaxis()->SetNdivisions(2, 5, 0);
if (isPlot2) r_data[i]->GetYaxis()->SetRangeUser(0.3, 1.35);
if (isPlot2 && (!doNorm)) r_data[i]->GetYaxis()->SetRangeUser(0.7, 1.3);
r_data[i]->GetYaxis()->SetNdivisions(2, 5, 0);
r_data[i]->GetYaxis()->SetTitleOffset(0.45);
r_data[i]->SetFillColor(kYellow);
r_data[i]->GetXaxis()->SetTitleSize(0.15);
r_data[i]->GetXaxis()->CenterTitle();
r_data[i]->GetYaxis()->CenterTitle();
r_data[i]->Draw("APE2");
r_mg[i]->SetMarkerSize(1);
r_mg[i]->SetLineWidth(2);
r_mg[i]->SetMarkerStyle(21);
r_mg[i]->SetMarkerColor(kBlue - 7);
r_mg[i]->SetLineColor(kBlue - 7);
r_mg[i]->Draw("PEsame");
r_ph[i]->SetMarkerSize(1);
r_ph[i]->SetLineWidth(2);
r_ph[i]->SetMarkerStyle(22);
r_ph[i]->SetMarkerColor(kRed);
r_ph[i]->SetLineColor(kRed);
r_ph[i]->Draw("PEsame");
r_re[i]->SetMarkerSize(1);
r_re[i]->SetLineWidth(2);
r_re[i]->SetMarkerStyle(23);
r_re[i]->SetMarkerColor(kGreen + 1);
r_re[i]->SetLineColor(kGreen + 1);
r_re[i]->Draw("PEsame");
std::string plotname = "Plots/ZShape_2D_";
plotname += "Bin" + strs.str() + "_";
plotname += Tag;
if (isPlot2 && Type == "combined")plotname += "MuEl";
else if (isPlot2 && Type == "elec")plotname += "PHMG";
else plotname += Type;
plotname += "_";
if ((Type == "elec" || isPlot2) && !doMG) plotname += "PH_";
if ((Type == "elec" || isPlot2) && doMG) plotname += "MG_";
if (doNorm) plotname += "Norm_";
else plotname += "Abs_";
if (elec == 0)plotname += "Dressed.";
if (elec == 1)plotname += "Born.";
if (elec == 2)plotname += "Naked.";
//FinalPhiTot->SaveAs((plotname + OutType).c_str());
delete FinalPhiTot;
//TO HERE ZACH
TCanvas* FinalPhiRatio = new TCanvas("FinalPhiRatio", "FinalPhiRatio", 800, 900);
FinalPhiRatio->cd();
FinalPhiRatio->SetLogx();
r_data[i]->GetYaxis()->SetTitle("MC/Data");
r_data[i]->SetFillColor(kYellow);
r_data[i]->GetYaxis()->SetRangeUser(0.5, 1.5);
r_data[i]->GetYaxis()->SetTitleOffset(1.2);
r_data[i]->GetYaxis()->SetTitleSize(0.04);
r_data[i]->GetYaxis()->SetLabelSize(0.04);
r_data[i]->GetXaxis()->SetTitleSize(0.04);
r_data[i]->GetXaxis()->SetLabelSize(0.04);
r_data[i]->GetXaxis()->SetLabelOffset(-0.01);
r_data[i]->Draw("AE2");
r_mg[i]->SetMarkerStyle(kFullTriangleUp);
r_mg[i]->SetMarkerColor(kBlue - 7);
r_mg[i]->SetLineColor(kBlue - 7);
r_ph[i]->SetMarkerSize(1);
r_ph[i]->SetLineWidth(2);
r_ph[i]->SetMarkerStyle(kFullSquare);
r_ph[i]->SetMarkerColor(kRed);
r_ph[i]->SetLineColor(kRed);
r_ph[i]->Draw("PEsame");
r_mg[i]->Draw("PEsame");
r_re[i]->SetMarkerColor(kGreen + 1);
r_re[i]->SetLineColor(kGreen + 1);
r_re[i]->SetMarkerSize(1);
r_re[i]->SetLineWidth(2);
r_re[i]->SetMarkerStyle(kStar);
r_re[i]->Draw("PEsame");
r_ANlo[i]->SetMarkerSize(1);
r_ANlo[i]->SetLineWidth(2);
r_ANlo[i]->SetMarkerStyle(kOpenCircle);
r_ANlo[i]->SetMarkerColor(kCyan + 2);
r_ANlo[i]->SetLineColor(kCyan + 2);
r_ANlo[i]->Draw("PEsame");
r_Pyth8[i]->SetMarkerSize(1);
r_Pyth8[i]->SetLineWidth(2);
r_Pyth8[i]->SetMarkerStyle(kOpenSquare);
r_Pyth8[i]->SetMarkerColor(kRed);
r_Pyth8[i]->SetLineColor(kRed);
r_Pyth8[i]->Draw("PEsame");
//r_data[i]->Draw("PEsame");
mark.SetTextSize(0.03);
mark.DrawLatex(0.7, 0.907, "19.7 fb^{-1} (8 TeV)");
mark.DrawLatex(0.19, 0.907, "CMS Preliminary");
if (i == 0) mark.DrawLatex(0.15, 0.3, "0.0 < |y_{ll}| < 0.4");
if (i == 1) mark.DrawLatex(0.15, 0.3, "0.4 < |y_{ll}| < 0.8");
if (i == 2) mark.DrawLatex(0.15, 0.3, "0.8 < |y_{ll}| < 1.2");
if (i == 3) mark.DrawLatex(0.15, 0.3, "1.2 < |y_{ll}| < 1.6");
if (i == 4) mark.DrawLatex(0.15, 0.3, "1.6 < |y_{ll}| < 2.0");
if (i == 5) mark.DrawLatex(0.15, 0.35, "2.0 < |y_{ll}| < 2.4");
if (Type == "elec" && !isPlot2) {
mark.DrawLatex(0.15, 0.25, "|#eta^{l_{0}}| < 2.1, |#eta^{l_{1}}| < 2.4");
mark.DrawLatex(0.15, 0.20, "p_{T}^{l_{0}} > 30 GeV, p_{T}^{l_{1}} > 20 GeV");
if (i != 5)mark.DrawLatex(0.15, 0.15, "60 GeV < M_{ll} < 120 GeV");
else mark.DrawLatex(0.15, 0.30, "60 GeV < M_{ll} < 120 GeV");
}
if (Type == "muon" && !isPlot2) {
mark.DrawLatex(0.15, 0.25, "|#eta^{#mu_{0}}| < 2.1, |#eta^{#mu_{1}}| < 2.4");
mark.DrawLatex(0.15, 0.20, "p_{T}^{#mu_{0}} > 30 GeV, p_{T}^{#mu_{1}} > 20 GeV");
mark.DrawLatex(0.15, 0.15, "60 GeV < M_{#mu#mu} < 120 GeV");
}
if (Type == "combined" || isPlot2) {
mark.DrawLatex(0.15, 0.25, "|#eta^{l_{0}}| < 2.1, |#eta^{l_{1}}| < 2.4");
mark.DrawLatex(0.15, 0.20, "p_{T}^{l_{0}} > 30 GeV, p_{T}^{l_{1}} > 20 GeV");
mark.DrawLatex(0.15, 0.15, "60 GeV < M_{ll} < 120 GeV");
}
TLegend* leg2 = new TLegend(0.13, 0.72, 0.7, 0.9);
leg2->SetFillStyle(0);
leg2->SetBorderSize(0);
leg2->SetLineWidth(1);
leg2->SetNColumns(1);
leg2->SetTextFont(22);
leg2->AddEntry(r_data[i], "2012 data", "F");
if (Type == "elec") {
leg2->AddEntry(r_mg[i], " MadGraph+Pythia6 (Z2*)", "P");
leg2->AddEntry(r_ph[i], "POWHEG+Pythia6 (Z2*)", "P");
leg2->AddEntry(r_re[i], "Resbos", "P");
leg2->AddEntry(r_ANlo[i], "AMC@nlo+Pythia8(CUETP8M1)", "P");
leg2->AddEntry(r_Pyth8[i], "POWHEG+Pythia8 (CT10)", "P");
}
if (Type == "muon") {
leg2->AddEntry(r_mg[i], "Z #rightarrow #mu#mu MadGraph", "P");
leg2->AddEntry(r_ph[i], "Z #rightarrow #mu#mu Powheg", "P");
}
if (Type == "combined") {
leg2->AddEntry(r_mg[i], "Z #rightarrow ll MadGraph", "P");
leg2->AddEntry(r_ph[i], "Z #rightarrow ll Powheg", "P");
}
leg2->Draw();
plotname = "ZShape_Ratio";
plotname += Tag;
if (isPlot2)plotname += "MuEl";
else plotname += Type;
plotname = "Plots/Ratio_ZShape_2D_";
plotname += "Bin" + strs.str() + "_";
plotname += Tag;
//if (isPlot2 && Type == "combined")plotname += "MuEl";
//else if (isPlot2 && Type == "elec")plotname += "PHMG";
plotname += Type;
plotname += "_";
if ((Type == "elec" || isPlot2) && !doMG) plotname += "PH_";
if ((Type == "elec" || isPlot2) && doMG) plotname += "MG_";
if (doNorm) plotname += "Norm_";
else plotname += "Abs_";
if (elec == 0)plotname += "Dressed.";
if (elec == 1)plotname += "Born.";
if (elec == 2)plotname += "Naked.";
FinalPhiRatio->RedrawAxis();
FinalPhiRatio->SaveAs((plotname + "pdf").c_str());
FinalPhiRatio->SaveAs((plotname + "png").c_str());
FinalPhiRatio->SaveAs((plotname + "C").c_str());
}
//TOTAL PLOT FROM HERE
TCanvas* FinalPhiRatio = new TCanvas("FinalPhiRatio", "FinalPhiRatio", 800, 900);
FinalPhiRatio->SetBottomMargin(0.1);
TPad* Info = new TPad("p1", "p1", 0, .03, 1, .9);
Info->Draw();
Info->cd();
Info->Divide(1, 6, 0, 0);
for (uint i = 0; i < ny; i++) {
Info->cd(i + 1);
std::ostringstream strs;
strs << i;
std::string gPadName = "p" + strs.str();
//gPad->SetPad(gPadName.c_str(), gPadName.c_str(), 0, i / 6, 1, (1 + i) / 6, kWhite, 0, 0);
//gPad->SetLeftMargin(0.15);
//gPad->SetRightMargin(0.06);
if (i == 5)gPad->SetBottomMargin(0.2);
gPad->SetLogx(1);
if (i == 0)r_data[i]->SetTitle("");
else r_data[i]->SetTitle("");
if (i == 0)r_data[i]->GetYaxis()->SetTitle("");
else if (i == 1)r_data[i]->GetYaxis()->SetTitle("");
else if (i == 2)r_data[i]->GetYaxis()->SetTitle("MC/Data");
else if (i == 3)r_data[i]->GetYaxis()->SetTitle("");
else if (i == 4)r_data[i]->GetYaxis()->SetTitle("");
else if (i == 5)r_data[i]->GetYaxis()->SetTitle("");
r_data[i]->GetYaxis()->CenterTitle();
r_data[i]->SetFillColor(kYellow);
r_data[i]->GetYaxis()->SetNdivisions(503);
r_data[i]->GetYaxis()->SetRangeUser(0.865, 1.135);
if (i == 4)r_data[i]->GetYaxis()->SetRangeUser(0.77, 1.23);
if (i == 5)r_data[i]->GetYaxis()->SetRangeUser(0.4, 1.6);
r_data[i]->GetYaxis()->SetTitleOffset(0.2); //OFFSET
r_data[i]->GetYaxis()->SetTitleSize(0.2); //Y TITLE SIZE
r_data[i]->GetYaxis()->SetLabelSize(0.15);
r_data[i]->GetXaxis()->SetTitleSize(0);
r_data[i]->GetXaxis()->SetLabelSize(0);
r_data[i]->GetXaxis()->SetTitle("");
r_data[i]->GetXaxis()->CenterTitle();
if (i == ny - 1) {
r_data[i]->GetXaxis()->SetTitleOffset(0.42); //OFFSET
r_data[i]->GetXaxis()->SetTitleSize(0.2); //X TITLE SIZE
r_data[i]->GetXaxis()->SetLabelSize(0.15);
r_data[i]->GetXaxis()->SetLabelOffset(-0.01);
r_data[i]->GetXaxis()->SetTitle("#phi*");
r_data[i]->GetXaxis()->CenterTitle();
}
r_data[i]->GetXaxis()->SetRangeUser(.015, 1.95);
r_data[i]->Draw("AE2");
r_mg[i]->SetMarkerStyle(kFullTriangleUp);
r_mg[i]->SetMarkerColor(kBlue - 7);
r_mg[i]->SetLineColor(kBlue - 7);
r_ph[i]->SetMarkerSize(1);
r_ph[i]->SetLineWidth(2);
r_ph[i]->SetMarkerStyle(kFullSquare);
r_ph[i]->SetMarkerColor(kRed);
r_ph[i]->SetLineColor(kRed);
r_ph[i]->Draw("PEsame");
r_mg[i]->Draw("PEsame");
r_re[i]->SetMarkerColor(kGreen + 1);
r_re[i]->SetLineColor(kGreen + 1);
r_re[i]->SetMarkerSize(1);
r_re[i]->SetLineWidth(2);
r_re[i]->SetMarkerStyle(kStar);
r_re[i]->Draw("PEsame");
r_ANlo[i]->SetMarkerSize(1);
r_ANlo[i]->SetLineWidth(2);
r_ANlo[i]->SetMarkerStyle(kOpenCircle);
r_ANlo[i]->SetMarkerColor(kCyan + 2);
r_ANlo[i]->SetLineColor(kCyan + 2);
r_ANlo[i]->Draw("PEsame");
r_Pyth8[i]->SetMarkerSize(1);
r_Pyth8[i]->SetLineWidth(2);
r_Pyth8[i]->SetMarkerStyle(kOpenSquare);
r_Pyth8[i]->SetMarkerColor(kRed);
r_Pyth8[i]->SetLineColor(kRed);
r_Pyth8[i]->Draw("PEsame");
}
//r_data_WO->Draw("PEsame");
FinalPhiRatio->cd(0);
TLatex mark;
mark.SetTextSize(0.02);
mark.SetNDC(kTRUE);
mark.DrawLatex(.75, .95, "19.7 fb^{-1} (8 TeV)");
mark.DrawLatex(0.1, .95, "CMS Preliminary");
TLatex mark2;
mark2.SetTextSize(0.02);
mark2.SetNDC(kTRUE);
mark2.DrawLatex(.12, .84, "0.0 < |y_{ll}| < 0.4");
mark2.DrawLatex(.12, .7, "0.4 < |y_{ll}| < 0.8");
mark2.DrawLatex(.12, .55, "0.8 < |y_{ll}| < 1.2");
mark2.DrawLatex(.12, .42, "1.2 < |y_{ll}| < 1.6");
mark2.DrawLatex(.12, .28, "1.6 < |y_{ll}| < 2.0");
mark2.DrawLatex(.12, .15, "2.0 < |y_{ll}| < 2.4");
//mark.DrawLatex(-0.15, 0.25, "|#eta^{l_{0}}| < 2.1, |#eta^{l_{1}}| < 2.4");
//mark.DrawLatex(0.15, 0.20, "p_{T}^{l_{0}} > 30 GeV, p_{T}^{l_{1}} > 20 GeV");
//if (i != 5)mark.DrawLatex(0.15, 0.15, "60 GeV < M_{ll} < 120 GeV");
//else mark.DrawLatex(0.15, 0.30, "60 GeV < M_{ll} < 120 GeV");
FinalPhiRatio->cd(1);
TLegend* leg2 = new TLegend(0.09, 0.888, 0.9, 0.94);
leg2->SetNColumns(3);
leg2->SetFillStyle(0);
//leg2->SetBorderSize(1);
leg2->SetLineWidth(1);
leg2->SetTextFont(22);
leg2->AddEntry(r_data[1], "2012 data", "F");
leg2->AddEntry(r_mg[1], " MadGraph+Pythia6 (Z2*)", "P");
leg2->AddEntry(r_ph[1], "POWHEG+Pythia6 (Z2*)", "P");
leg2->AddEntry(r_re[1], "Resbos", "P");
leg2->AddEntry(r_ANlo[1], "AMC@nlo+Pythia8(CUETP8M1)", "P");
leg2->AddEntry(r_Pyth8[1], "POWHEG+Pythia8 (CT10)", "P");
leg2->Draw();
std::string plotname = "Plots/Ratio_ZShape_2D_ALL";
plotname += Tag;
//if (isPlot2 && Type == "combined")plotname += "MuEl";
//else if (isPlot2 && Type == "elec")plotname += "PHMG";
plotname += Type;
plotname += "_";
if ((Type == "elec" || isPlot2) && !doMG) plotname += "PH_";
if (doNorm) plotname += "Norm_";
else plotname += "Abs_";
if (elec == 0)plotname += "Dressed.";
if (elec == 1)plotname += "Born.";
if (elec == 2)plotname += "Naked.";
FinalPhiRatio->RedrawAxis();
FinalPhiRatio->SaveAs((plotname + "pdf").c_str());
FinalPhiRatio->SaveAs((plotname + "png").c_str());
FinalPhiRatio->SaveAs((plotname + "C").c_str());
//TO HEREs
}
void OneDYPlot(vector<TGraphAsymmErrors*> g_data, vector<TGraphAsymmErrors*> g_mg, vector<TGraphAsymmErrors*> g_ph, vector<TGraphAsymmErrors*> g_re, vector<TGraphAsymmErrors*> g_ANlo, vector<TGraphAsymmErrors*> g_Pyth8) {
TGraphAsymmErrors* g_data_Y = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_mg_Y = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_ph_Y = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_re_Y = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_ANlo_Y = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_Pyh8_Y = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_Data_Y_ratio = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_mg_Y_ratio = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_ph_Y_ratio = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_re_Y_ratio = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_ANlo_Y_ratio = new TGraphAsymmErrors(ny);
TGraphAsymmErrors* g_Pyh8_Y_ratio = new TGraphAsymmErrors(ny);
for (size_t i = 0; i < ny; i++) {
cout << "our error for the first bin is " << g_data[i]->GetErrorYhigh(0) << endl;
}
double YError = 0;
size_t YBin = 5;
for (size_t i = 0; i < nphistar; i++) {
double BinSizeSquared = (phistarBins[i + 1] - phistarBins[i])*(phistarBins[i + 1] - phistarBins[i]);
double x, y;
g_data[YBin]->GetPoint(i, x, y);
cout << "Error For Phistar bin " << i << " is: " << sqrt(g_data[YBin]->GetErrorYhigh(i) * g_data[YBin]->GetErrorYhigh(i)) << endl;
YError = sqrt(YError * YError + g_data[YBin]->GetErrorYhigh(i) * g_data[YBin]->GetErrorYhigh(i) * BinSizeSquared);
}
cout << "OOOKAy our int value is " << IntValue(g_data[YBin]) << endl;
cout << "And our error is " << YError << endl;
for (int i = 0; i < (int) ny; i++) {
g_data_Y->SetPoint(i, .2 + .4 * i, IntValue(g_data[i]));
g_mg_Y->SetPoint(i, .2 + .4 * i, IntValue(g_mg[i]));
g_ph_Y->SetPoint(i, .2 + .4 * i, IntValue(g_ph[i]));
g_re_Y->SetPoint(i, .2 + .4 * i, IntValue(g_re[i]));
g_ANlo_Y->SetPoint(i, .2 + .4 * i, IntValue(g_ANlo[i]));
g_Pyh8_Y->SetPoint(i, .2 + .4 * i, IntValue(g_Pyth8[i]));
g_data_Y->SetPointError(i, 0, 0, YErrorValue(g_data[i]), YErrorValue(g_data[i]));
g_mg_Y->SetPointError(i, 0, 0, YErrorValue(g_mg[i]), YErrorValue(g_mg[i]));
g_ph_Y->SetPointError(i, 0, 0, YErrorValue(g_ph[i]), YErrorValue(g_ph[i]));
g_re_Y->SetPointError(i, 0, 0, YErrorValue(g_re[i]), YErrorValue(g_re[i]));
g_ANlo_Y->SetPointError(i, 0, 0, YErrorValue(g_ANlo[i]), YErrorValue(g_ANlo[i]));
g_Pyh8_Y->SetPointError(i, 0, 0, YErrorValue(g_Pyth8[i]), YErrorValue(g_Pyth8[i]));
}
RatioValue(g_Data_Y_ratio, g_data_Y, g_data_Y);
RatioValue(g_mg_Y_ratio, g_data_Y, g_mg_Y);
RatioValue(g_ph_Y_ratio, g_data_Y, g_ph_Y);
RatioValue(g_re_Y_ratio, g_data_Y, g_re_Y);
RatioValue(g_ANlo_Y_ratio, g_data_Y, g_ANlo_Y);
RatioValue(g_Pyh8_Y_ratio, g_data_Y, g_Pyh8_Y);
TCanvas* FinalPhiTot = new TCanvas("FinalPhiTot", "FinalPhiTot", 800, 900);
FinalPhiTot->Divide(1, 2);
FinalPhiTot->cd(1);
gPad->SetPad("p1", "p1", 0, 2.5 / 9.0, 1, 1, kWhite, 0, 0);
gPad->SetBottomMargin(0.01);
gPad->SetTopMargin(0.06);
gPad->SetLeftMargin(0.15);
gPad->SetRightMargin(0.06);
//gPad->SetLogy(1);
g_data_Y->SetTitle("");
g_data_Y->GetYaxis()->SetTitle("1/#sigma^{fid} #bullet d#sigma^{fid}/dy");
g_data_Y->GetYaxis()->SetTitleSize(.065);
g_data_Y->GetYaxis()->SetTitleOffset(1.);
g_data_Y->GetYaxis()->CenterTitle();
g_data_Y->GetYaxis()->SetLabelSize(0.05);
g_data_Y->GetXaxis()->SetRangeUser(0.0, 2.4);
g_data_Y->GetXaxis()->SetLabelSize(.0);
g_data_Y->SetFillColor(kGray);
if (doNorm) g_data_Y->GetYaxis()->SetRangeUser(.01, .8);
else g_data_Y->GetYaxis()->SetRangeUser(1000, 400000.0);
g_data_Y->Draw("A2");
int Color1 = kBlue;
int Color2 = kRed;
g_mg_Y->SetMarkerColor(Color1);
g_mg_Y->SetLineColor(Color1);
g_mg_Y->SetMarkerSize(1);
g_mg_Y->SetLineWidth(2);
g_mg_Y->SetMarkerStyle(4);
g_mg_Y->Draw("PEsame");
g_ph_Y->SetMarkerColor(Color2);
g_ph_Y->SetLineColor(Color2);
g_ph_Y->SetMarkerSize(1);
g_ph_Y->SetLineWidth(2);
g_ph_Y->SetMarkerStyle(20);
g_ph_Y->Draw("PEsame");
int ColorError = kYellow;
g_data_Y->SetFillColor(ColorError);
g_data_Y->SetMarkerSize(1);
g_data_Y->SetLineWidth(2);
g_data_Y->SetMarkerStyle(20);
g_data_Y->Draw("PEsame");
g_data_Y->SetFillColor(ColorError);
TLegend* leg = new TLegend(0.23, 0.76, 0.95, 0.94);
leg->SetFillStyle(0);
leg->SetBorderSize(0);
leg->SetLineWidth(1);
leg->SetNColumns(1);
leg->SetTextFont(42);
leg->AddEntry(g_data_Y, "2012 data", "PEF");
leg->AddEntry(g_mg_Y, "Z #rightarrow ee MadGraph+Pythia6 (Z2star)", "P");
leg->AddEntry(g_ph_Y, "Z #rightarrow ee POWHEG+Pythia6 (Z2star)", "P");
leg->Draw();
TLatex mark;
// mark.SetTextSize(0.05);
mark.SetTextSize(0.035);
mark.SetNDC(true);
mark.DrawLatex(0.745, 0.95, "19.7 fb^{-1} (8 TeV)");
mark.DrawLatex(0.19, 0.955, "CMS Preliminary");
//if (Type == "elec") {
mark.DrawLatex(0.19, 0.20, "|#eta^{l_{0}}| < 2.1, |#eta^{l_{1}}| < 2.4");
mark.DrawLatex(0.19, 0.13, "p_{T}^{l_{0}} > 30 GeV, p_{T}^{l_{1}} > 20 GeV");
mark.DrawLatex(0.19, 0.06, "60 GeV < M_{ll} < 120 GeV");
//}
FinalPhiTot->cd(2);
gPad->SetPad("p2", "p2", 0, 0, 1, 2.5 / 9.0, kWhite, 0, 0);
gPad->SetBottomMargin(0.37);
gPad->SetTopMargin(0.01);
gPad->SetLeftMargin(0.15);
gPad->SetRightMargin(0.06);
g_Data_Y_ratio->SetTitle("");
g_Data_Y_ratio->GetYaxis()->SetTitle("MC/Data ");
g_Data_Y_ratio->GetYaxis()->SetTitleOffset(0.4);
g_Data_Y_ratio->GetYaxis()->SetTitleSize(.15);
g_Data_Y_ratio->SetFillColor(kYellow);
g_Data_Y_ratio->GetYaxis()->SetRangeUser(0.9, 1.1);
g_Data_Y_ratio->GetYaxis()->SetLabelSize(0.04);
g_Data_Y_ratio->GetXaxis()->SetLabelSize(0.13);
g_Data_Y_ratio->GetXaxis()->SetLabelOffset(0.02);
g_Data_Y_ratio->GetXaxis()->SetRangeUser(0, 2.4);
g_Data_Y_ratio->GetXaxis()->SetNdivisions(510);
g_Data_Y_ratio->GetXaxis()->SetTitle("y_{ll}");
g_Data_Y_ratio->GetXaxis()->SetTitleSize(0.15);
g_Data_Y_ratio->GetXaxis()->SetTitleOffset(1);
g_Data_Y_ratio->GetXaxis()->CenterTitle();
g_Data_Y_ratio->GetYaxis()->SetNdivisions(505);
g_Data_Y_ratio->GetYaxis()->SetLabelSize(0.13);
g_Data_Y_ratio->Draw("AE2");
g_mg_Y_ratio->SetMarkerSize(1);
g_mg_Y_ratio->SetLineWidth(2);
g_mg_Y_ratio->SetMarkerStyle(4);
g_mg_Y_ratio->SetMarkerColor(Color1);
g_mg_Y_ratio->SetLineColor(Color1);
g_mg_Y_ratio->Draw("PEsame");
g_ph_Y_ratio->SetMarkerSize(1);
g_ph_Y_ratio->SetLineWidth(2);
g_ph_Y_ratio->SetMarkerStyle(20);
g_ph_Y_ratio->SetMarkerColor(Color2);
g_ph_Y_ratio->SetLineColor(Color2);
g_ph_Y_ratio->Draw("PEsame");
std::string plotname = "Plots/YFull";
if (!doMG) plotname += "PH_";
if (doNorm) plotname += "Norm_";
else plotname += "Abs_";
if (elec == 0)plotname += "Dressed.";
if (elec == 1)plotname += "Born.";
if (elec == 2)plotname += "Naked.";
FinalPhiTot->SaveAs((plotname + "pdf").c_str());
FinalPhiTot->SaveAs((plotname + "png").c_str());
FinalPhiTot->SaveAs((plotname + "C").c_str());
//RatioPlotStart
TCanvas* FinalPhiRatio = new TCanvas("FinalPhiRatio", "FinalPhiRatio", 800, 900);
FinalPhiRatio->cd();
g_Data_Y_ratio->SetTitle("");
g_Data_Y_ratio->GetYaxis()->SetTitle("MC/Data");
g_Data_Y_ratio->GetYaxis()->CenterTitle();
g_Data_Y_ratio->SetFillColor(kYellow);
g_Data_Y_ratio->GetYaxis()->SetRangeUser(0.5, 1.25);
g_Data_Y_ratio->GetYaxis()->SetTitleOffset(1.2);
g_Data_Y_ratio->GetYaxis()->SetTitleSize(0.04);
g_Data_Y_ratio->GetYaxis()->SetLabelSize(0.04);
g_Data_Y_ratio->GetXaxis()->SetRangeUser(0.0, 2.4);
g_Data_Y_ratio->GetXaxis()->SetTitleSize(0.043);
g_Data_Y_ratio->GetXaxis()->SetLabelSize(0.04);
g_Data_Y_ratio->GetXaxis()->SetLabelOffset(0.012);
g_Data_Y_ratio->Draw("AE2");
g_mg_Y_ratio->SetMarkerStyle(kFullTriangleUp);
g_mg_Y_ratio->SetMarkerColor(kBlue - 7);
g_mg_Y_ratio->SetLineColor(kBlue - 7);
g_ph_Y_ratio->SetMarkerSize(1);
g_ph_Y_ratio->SetLineWidth(2);
g_ph_Y_ratio->SetMarkerStyle(kFullSquare);
g_ph_Y_ratio->SetMarkerColor(kRed);
g_ph_Y_ratio->SetLineColor(kRed);
g_ph_Y_ratio->Draw("PEsame");
g_mg_Y_ratio->Draw("PEsame");
g_re_Y_ratio->SetMarkerColor(kGreen + 1);
g_re_Y_ratio->SetLineColor(kGreen + 1);
g_re_Y_ratio->SetMarkerSize(1);
g_re_Y_ratio->SetLineWidth(2);
g_re_Y_ratio->SetMarkerStyle(kStar);
g_re_Y_ratio->Draw("PEsame");
g_ANlo_Y_ratio->SetMarkerSize(1);
g_ANlo_Y_ratio->SetLineWidth(2);
g_ANlo_Y_ratio->SetMarkerStyle(kOpenCircle);
g_ANlo_Y_ratio->SetMarkerColor(kCyan + 2);
g_ANlo_Y_ratio->SetLineColor(kCyan + 2);
g_ANlo_Y_ratio->Draw("PEsame");
g_Pyh8_Y_ratio->SetMarkerSize(1);
g_Pyh8_Y_ratio->SetLineWidth(2);
g_Pyh8_Y_ratio->SetMarkerStyle(kOpenSquare);
g_Pyh8_Y_ratio->SetMarkerColor(kRed);
g_Pyh8_Y_ratio->SetLineColor(kRed);
g_Pyh8_Y_ratio->Draw("PEsame");
//r_data_WO->Draw("PEsame");
mark.SetTextSize(0.03);
mark.DrawLatex(0.7, 0.907, "19.7 fb^{-1} (8 TeV)");
mark.DrawLatex(0.19, 0.907, "CMS Preliminary");
if (Type == "elec") {
mark.DrawLatex(0.15, 0.25, "|#eta^{l_{0}}| < 2.1, |#eta^{l_{1}}| < 2.4");
mark.DrawLatex(0.15, 0.20, "p_{T}^{l_{0}} > 30 GeV, p_{T}^{l_{1}} > 20 GeV");
mark.DrawLatex(0.15, 0.15, "60 GeV < M_{ll} < 120 GeV");
}
TLegend* leg2 = new TLegend(0.13, 0.72, 0.7, 0.9);
leg2->SetFillStyle(0);
leg2->SetBorderSize(0);
leg2->SetLineWidth(1);
leg2->SetNColumns(1);
leg2->SetTextFont(22);
leg2->AddEntry(g_Data_Y_ratio, "2012 data", "F");
if (Type == "elec") {
leg2->AddEntry(g_mg_Y_ratio, " MadGraph+Pythia6 (Z2*)", "P");
leg2->AddEntry(g_ph_Y_ratio, "POWHEG+Pythia6 (Z2*)", "P");
leg2->AddEntry(g_re_Y_ratio, "Resbos", "P");
leg2->AddEntry(g_ANlo_Y_ratio, "AMC@nlo+Pythia8(CUETP8M1)", "P");
leg2->AddEntry(g_Pyh8_Y_ratio, "POWHEG+Pythia8 (CT10)", "P");
}
leg2->Draw();
plotname = "Plots/Ratio_YRatio";
plotname += Tag;
//if (isPlot2 && Type == "combined")plotname += "MuEl";
//else if (isPlot2 && Type == "elec")plotname += "PHMG";
plotname += Type;
plotname += "_";
if ((Type == "elec") && !doMG) plotname += "PH_";
if ((Type == "elec") && doMG) plotname += "MG_";
if (doNorm) plotname += "Norm_";
else plotname += "Abs_";
if (elec == 0)plotname += "Dressed.";
if (elec == 1)plotname += "Born.";
if (elec == 2)plotname += "Naked.";
FinalPhiRatio->RedrawAxis();
FinalPhiRatio->SaveAs((plotname + "pdf").c_str());
FinalPhiRatio->SaveAs((plotname + "png").c_str());
FinalPhiRatio->SaveAs((plotname + "C").c_str());
}
void buildPlotAxial_DD(){
TH2F *dummyHist = new TH2F("dum","",1,1,900,1,6E-43,1E-37);
dummyHist->GetYaxis()->SetTitle("#sigma_{SD} (cm^{2})");
dummyHist->GetXaxis()->SetTitle("m_{DM} (GeV)");
dummyHist->GetYaxis()->SetTitleOffset(1.5);
dummyHist->GetYaxis()->SetTitleSize(0.046);
dummyHist->GetXaxis()->SetTitleSize(0.046);
dummyHist->GetYaxis()->SetTitleOffset(1.5);
dummyHist->GetXaxis()->SetTitleOffset(1.25);
dummyHist->GetYaxis()->SetTitleSize(0.045);
dummyHist->GetXaxis()->SetTitleSize(0.045);
dummyHist->GetYaxis()->SetLabelSize(0.04);
dummyHist->GetXaxis()->SetLabelSize(0.04);
gROOT->ProcessLine(".x paperStyle.C");
gStyle->SetOptStat(0);
gStyle->SetPalette(51);
TFile *fiDD = TFile::Open("MassLimit_1_801_0_Both_updatePICO.root");
TGraph *DDF = (TGraph*)fiDD->Get("DD");
TFile *fi = TFile::Open("MassLimit_1_801_0_Both.root");
TCanvas *can = new TCanvas();
dummyHist->Draw("AXIS");
TGraph *combinedD = makeOBV(combined_obs); combinedD->SetLineColor(1); combinedD->SetName("EXP");
TGraph *combined_obsD = makeOBV(combined); combined_obsD->SetLineColor(1);combined_obsD->SetName("OBS");
TGraph *monojetD = makeOBV(monojet); monojetD->SetLineColor(kBlue); monojetD->SetName("mjet");
// Phil swapped boosted and resolved
TGraph *boostedD = makeOBV(resolved); boostedD->SetLineColor(kMagenta); boostedD->SetName("bjet");
TGraph *resolvedD = makeOBV(boosted); resolvedD->SetLineColor(kGreen); resolvedD->SetName("rjet");
TGraph *monovD = makeOBV(monov); monovD->SetLineColor(kRed); monovD->SetName("MV");
/* other lines */
combinedD->Draw("lsame");
combined_obsD->Draw("lsame");
monojetD->Draw("lsame");
boostedD->Draw("lsame");
resolvedD->Draw("lsame");
monovD->Draw("lsame");
DDF->Draw("lsame");
TLegend *leg = new TLegend(0.19,0.40,0.51,0.63,NULL,"brNDC");
leg->SetFillStyle(0);
leg->AddEntry(combinedD,"Median Expected","L");
leg->AddEntry(combined_obsD,"Observed","L");
leg->AddEntry(monojetD,"Monojet","L");
leg->AddEntry(boostedD,"Boosted","L");
leg->AddEntry(resolvedD,"Resolved","L");
leg->AddEntry(monovD,"V-tagged","L");
leg->AddEntry(DDF,"PICO-2L","L");
leg->Draw();
TLatex * texCMS = new TLatex(0.20,0.84,"#bf{CMS}");
//TLegend *WHITEBOX = new TLegend(0.18,0.83,0.3,0.89);
//TLatex * texCMS = new TLatex(0.20,0.84,"#bf{CMS}#it{Preliminary}");
TLegend *WHITEBOX = new TLegend(0.18,0.83,0.42,0.89);
WHITEBOX->SetFillColor(kWhite);
//WHITEBOX->Draw();
texCMS->SetNDC();
texCMS->SetTextFont(42);
texCMS->SetLineWidth(2);
texCMS->SetTextSize(0.042); texCMS->Draw();
//tex->SetFillColor(kWhite);
TLatex * tex = new TLatex();
tex->SetNDC();
tex->SetTextFont(42);
tex->SetLineWidth(2);
tex->SetTextSize(0.035);
tex->Draw();
tex->DrawLatex(0.69,0.94,"19.7 fb^{-1} (8 TeV)");
tex->DrawLatex(0.20,0.8,"g_{DM}=g_{SM}=1");
tex->DrawLatex(0.20,0.7,"Axial");
can->SetRightMargin(0.11);
can->SetLogx();
can->SetLogy();
can->RedrawAxis();
can->SaveAs("MassLimit_1_801_0_Both_DD.pdf");
TFile *rout = new TFile("axialDD_out.root","RECREATE");
rout->WriteTObject(combined_obsD,"combined");
rout->WriteTObject(combinedD,"combined_expected");
rout->WriteTObject(DDF,"DD_mass");
rout->Close();
/*
KEY: TCanvas A;1 A
KEY: TGraph DD_mass;1 DD_mass
KEY: TGraph DD;1 DD
KEY: TGraph monojet;1 monojet
KEY: TGraph resolved;1 resolved
KEY: TGraph boosted;1 boosted
KEY: TGraph monov;1 monov
KEY: TGraph combined;1 combined
KEY: TGraph combinedUp;1 combinedUp
KEY: TGraph combinedDown;1 combinedDown
KEY: TGraph monojet_obs;1 monojet_obs
KEY: TGraph resolved_obs;1 resolved_obs
KEY: TGraph boosted_obs;1 boosted_obs
KEY: TGraph monov_obs;1 monov_obs
KEY: TGraph combined_obs;1 combined_obs
KEY: TGraph2D 2D;1 2D
*/
}
void gluinoMass(double lumi=-1., double maxInstLumi=-1.) {
if (lumi<0)
lumi=877.;
if (maxInstLumi<0)
maxInstLumi=1300.;
LimitPlots plots(lumi);
plots.calculateCrossSections(7,4,39,9);
// expected limit (1 and 2 sigma bands)
TGraph* g_exp = plots.getExpMassLimitGluino();
TGraphAsymmErrors* g_exp1 = plots.getExpMassLimitGluino1Sig();
TGraphAsymmErrors* g_exp2 = plots.getExpMassLimitGluino2Sig();
// three points on counting expt curve
TGraph* g_gluino = plots.getMassLimitGluino();
TGraph* g_stop = plots.getMassLimitStop();
// one point from lifetime fit
TGraph* g_tp = plots.getMassLimitGluinoTP();
// theory prediction
TGraph* g_thGluino = plots.getGluinoTheory();
TGraph* g_thStop = plots.getStopTheory();
TCanvas* canvas = new TCanvas("canvas");
//canvas->SetGrid();
canvas->SetLogy();
TH1 * h;
h = canvas->DrawFrame(300., .02, 1000., 1e2);
//h->SetTitle("Beamgap Expt;m_{#tilde{g}} [GeV/c^{2}]; Stopped HSCP Cross Section #times BR [pb]");
h->SetTitle("Beamgap Expt;m_{#tilde{g}} [GeV/c^{2}]; #sigma(pp #rightarrow #tilde{g}#tilde{g}) #times BR(#tilde{g} #rightarrow g#tilde{#chi}^{0}) [pb]");
// not covered region
TBox* nc = new TBox(100., .1, 150., 5e2);
nc->SetFillStyle(3354);
nc->SetFillColor(kRed-4);
//nc->Draw();
// details
TPaveText* blurb = new TPaveText(300., 2, 550., 1e2);
blurb->AddText("CMS Preliminary 2012");
std::stringstream label;
label<<"#int L dt = "<<lumi<<" fb^{-1}";
blurb->AddText(label.str().c_str());
label.str("");
double peakInstLumi=maxInstLumi;
int exponent=30;
while (peakInstLumi>10) {
peakInstLumi/=10.;
++exponent;
}
label<<"L^{max}_{inst} = "<<peakInstLumi<<" x 10^{"<<exponent<<"} cm^{-2}s^{-1}";
blurb->AddText(label.str().c_str());
label.str("");
label << "#sqrt{s} = " << ENERGY << " TeV";
blurb->AddText(label.str().c_str());
blurb->AddText("m_{#tilde{g}} - m_{#tilde{#chi}^{0}} = 100 GeV/c^{2}");
//blurb->AddText("m_{#tilde{t}} - m_{#tilde{#chi}^{0}} = 200 GeV/c^{2}");
blurb->SetTextFont(42);
blurb->SetBorderSize(0);
blurb->SetFillColor(0);
blurb->SetShadowColor(0);
blurb->SetTextAlign(12);
blurb->SetTextSize(0.032);
// legend
TBox *legbg = new TBox(600., 2., 900., 1e2);
legbg->Draw();
TLegend *leg = new TLegend(600., 2., 900., 1e2,"95% C.L. Limits","");
leg->SetTextSize(0.028);
leg->SetBorderSize(0);
leg->SetTextFont(42);
leg->SetFillColor(0);
leg->AddEntry(g_exp, "Expected: 10 #mus - 1000 s Counting Exp. ", "l");
leg->AddEntry(g_exp1, "Expected #pm1#sigma: 10 #mus - 1000 s Counting Exp. ", "f");
leg->AddEntry(g_exp2, "Expected #pm2#sigma: 10 #mus - 1000 s Counting Exp. ", "f");
// leg->AddEntry(graph3, "Obs.: 10^{6} s Counting Exp.", "l");
leg->AddEntry(g_gluino, "Obs.: 10 #mus - 1000 s Counting Exp. ", "l");
leg->AddEntry(g_tp, "Obs.: 10 #mus Timing Profile ", "l");
//leg->AddEntry(g_stop, "Obs.: 10 #mus - 1000 s Counting Exp. (#tilde{t})", "l");
//leg->AddEntry(graph_em, "Obs.: 10 #mus - 1000 s Counting Exp. (EM only)", "l");
// leg->AddEntry(graph1, "Obs.: 570 ns Counting Exp.", "l");
leg->Draw();
// 2 sigma expected band
g_exp2->SetLineColor(0);
g_exp2->SetLineStyle(0);
g_exp2->SetLineWidth(0);
g_exp2->SetFillColor(5);
g_exp2->SetFillStyle(1001);
g_exp2->Draw("3");
// 1 sigma expected band
g_exp1->SetLineColor(0);
g_exp1->SetLineStyle(0);
g_exp1->SetLineWidth(0);
g_exp1->SetFillColor(3);
g_exp1->SetFillStyle(1001);
g_exp1->Draw("3");
// expected line
g_exp->SetLineStyle(2);
g_exp->SetLineWidth(1);
g_exp->Draw("l");
// plateau limit - 1 ms
g_gluino->SetLineColor(1);
g_gluino->SetLineStyle(1);
g_gluino->SetLineWidth(2);
g_gluino->Draw("l");
// stop curve
g_stop->SetLineColor(1);
g_stop->SetLineStyle(5);
g_stop->SetLineWidth(2);
//g_stop->Draw("l");
// 1 mus lifetime fit limit
g_tp->SetLineColor(kRed);
g_tp->SetLineStyle(1);
g_tp->SetLineWidth(2);
g_tp->Draw("l");
// theory line
g_thGluino->SetLineColor(kBlue);
g_thGluino->SetLineStyle(1);
g_thGluino->SetLineWidth(2);
g_thGluino->SetFillStyle(3001);
g_thGluino->SetFillColor(kBlue-4);
g_thGluino->Draw("l3");
g_thStop->SetLineColor(kRed);
g_thStop->SetLineStyle(1);
g_thStop->SetLineWidth(2);
g_thStop->SetFillStyle(3001);
g_thStop->SetFillColor(kRed-4);
//g_thStop->Draw("l3");
// theory line label
TLatex* th = new TLatex(600., .3, "NLO+NLL #tilde{g}");
th->SetTextColor(kBlue);
th->SetTextFont(42);
th->SetTextSize(0.035);
th->Draw();
TLatex* ths = new TLatex(330., 2., "NLO+NLL #tilde{t}");
ths->SetTextColor(kRed);
ths->SetTextFont(42);
ths->SetTextSize(0.035);
//ths->Draw();
// not explored label
TText* ne = new TText(125., .2, "Not Sensitive");
ne->SetTextColor(kRed+1);
ne->SetTextFont(42);
ne->SetTextAngle(90);
ne->SetTextSize(0.035);
//ne->Draw();
blurb->Draw();
canvas->RedrawAxis();
canvas->Print("gluinoMassLimit.pdf");
canvas->Print("gluinoMassLimit.C");
plots.calculateIntercepts();
}
void
draw2DLimitBFstyle(map<string,TList *>& m_contours,
const TString& par1,
const TString& par2,
const TString& plotprefix,
TLegend *legend)
{
//from here we build the two-dimensional aTGC limit
TCanvas *finalPlot = new TCanvas("final","limits",500,500);
finalPlot->cd();
cout << "Drawing +2s" << endl;
TList *contLevel = m_contours["+2s"];
TGraph *curv;
assert(contLevel);
curv = (TGraph*)(contLevel->First());
//curv->GetYaxis()->SetRangeUser(-1.25*curv->GetYaxis()->GetXmax(),
//+2.0*curv->GetYaxis()->GetXmax());
//curv->GetYaxis()->SetRangeUser(-0.1,0.15);
curv->GetYaxis()->SetRangeUser(parmin(par2),parmax(par2));
curv->SetTitle();
curv->GetXaxis()->SetTitle(par2latex(par1));
curv->GetXaxis()->SetTitleFont(42);
curv->GetYaxis()->SetTitle(par2latex(par2));
curv->GetYaxis()->SetTitleFont(42);
curv->GetYaxis()->SetTitleOffset(1.20);
for (int i=0; i<contLevel->GetSize(); i++) {
assert(curv);
curv->SetLineColor(kYellow);
curv->SetFillColor(kYellow);
curv->GetXaxis()->SetLimits(parmin(par1),parmax(par1));
if (!i) {
curv->Draw("ACF");
legend->AddEntry(curv,"#pm 2#sigma","F");
} else
curv->Draw("SAME CF");
curv=(TGraph *)(contLevel->After(curv));
}
cout << "Drawing +1s" << endl;
contLevel = m_contours["+1s"];
curv = (TGraph*)(contLevel->First());
for (int i=0; i<contLevel->GetSize(); i++) {
curv->SetLineColor(kGreen);
curv->SetFillColor(kGreen);
curv->Draw("SAME CF");
if (!i) legend->AddEntry(curv,"#pm 1#sigma","F");
curv=(TGraph *)(contLevel->After(curv));
}
cout << "Drawing -1s" << endl;
contLevel = m_contours["-1s"];
curv = (TGraph*)(contLevel->First());
for (int i=0; i<contLevel->GetSize(); i++) {
curv->SetLineColor(kYellow);
curv->SetFillColor(kYellow);
curv->Draw("SAME CF");
curv=(TGraph *)(contLevel->After(curv));
}
cout << "Drawing -2s" << endl;
contLevel = m_contours["-2s"];
if (!contLevel)
// this can happen more often for this contour if there is insufficient
// sensitivity close to the SM
cerr << "No contour level for +2s, have to fill in the central region" << endl;
else {
curv = (TGraph*)(contLevel->First());
for (int i=0; i<contLevel->GetSize(); i++) {
curv->SetFillColor(kWhite);
curv->SetLineColor(kYellow);
curv->Draw("SAME CF");
curv=(TGraph *)(contLevel->After(curv));
}
}
cout << "Drawing median" << endl;
curv = (TGraph*)(m_contours["median"]->First());
curv->SetLineColor(kBlack);
curv->SetLineWidth(2);
curv->SetLineStyle(2);
curv->Draw("SAME C");
legend->AddEntry(curv,"Expected","L");
cout << "Drawing obs" << endl;
contLevel = m_contours["obs"];
curv = (TGraph*)(contLevel->First());
for (int i=0; i<contLevel->GetSize(); i++) {
curv->SetLineColor(kBlack);
curv->SetLineWidth(2);
curv->Draw("SAME C");
if (!i) legend->AddEntry(curv,"Observed","L");
curv=(TGraph *)(contLevel->After(curv));
}
TGraph *SMpoint = new TGraph(1);
SMpoint->SetPoint(1,0,0);
SMpoint->Draw("SAME Po");
// smLabel = TPaveText(0,
// m_contours["-2s"]->GetYaxis()->GetXmax()/8,
// m_contours["-2s"]->GetXaxis()->GetXmax()/3->5,
// -m_contours["-2s"]->GetYaxis()->GetXmax()/8);
// smLabel->SetFillStyle(0);
// smLabel->SetBorderSize(0);
// smLabel->AddText(" SM");
// smLabel->Draw();
legend->Draw();
TPaveText *text = new TPaveText(0.566,0.87,0.965,1.101,"NDC");
text->SetFillStyle(0);
text->SetBorderSize(0);
text->AddText(Form("95%% CL Limit on %s and %s",par2latex(par1).Data(),par2latex(par2).Data()));
text->AddText(0,0.35,Form("#intL dt= %.1f fb^{-1}, #sqrt{s} = %d TeV",intlumifbinv,beamcometev));
text->Draw();
// text2 = TPaveText(0.155,0.199,0.974,0.244,"NDC");
// text2->SetFillStyle(0);
// text2->SetBorderSize(0);
// text2->AddText("Values outside contour excluded");
// text2->Draw();
//text3 = TPaveText(0.506,0.699,0.905,0.758,"NDC");
//text3->SetFillStyle(0);
//text3->SetBorderSize(0);
//text3->AddText(options.flavorText);
//text3->Draw();
finalPlot->RedrawAxis();
finalPlot->ResetAttPad();
finalPlot->Update();
finalPlot->Draw();
finalPlot->Update();
finalPlot->Modified();
finalPlot->Update();
finalPlot->Print(Form("%s.pdf",plotprefix.Data()));
finalPlot->Print(Form("%s.eps",plotprefix.Data()));
finalPlot->Print(Form("%s.png",plotprefix.Data()));
} // draw2DlimitBFstyle
void
HTT_EE_X(bool scaled=true, bool log=true, float min=0.1, float max=-1., string inputfile="root/$HISTFILE", const char* directory="ee_$CATEGORY")
{
// define common canvas, axes pad styles
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
// determine category tag
const char* category = ""; const char* category_extra = ""; const char* category_extra2 = "";
if(std::string(directory) == std::string("ee_0jet_low" )){ category = "ee, 0 jet"; }
if(std::string(directory) == std::string("ee_0jet_low" )){ category_extra = "p_{T}(lep1) low"; }
if(std::string(directory) == std::string("ee_0jet_high" )){ category = "ee, 0 jet"; }
if(std::string(directory) == std::string("ee_0jet_high" )){ category_extra = "p_{T}(lep1) high"; }
if(std::string(directory) == std::string("ee_1jet_low" )){ category = "ee, 1 jet"; }
if(std::string(directory) == std::string("ee_1jet_low" )){ category_extra = "p_{T}(lep1) low"; }
if(std::string(directory) == std::string("ee_1jet_high" )){ category = "ee, 1 jet"; }
if(std::string(directory) == std::string("ee_1jet_high" )){ category_extra = "p_{T}(lep1) high"; }
if(std::string(directory) == std::string("ee_vbf" )){ category = "ee, 2 jet"; }
if(std::string(directory) == std::string("ee_vbf" )){ category_extra = "VBF"; }
if(std::string(directory) == std::string("ee_nobtag" )){ category = "ee"; }
if(std::string(directory) == std::string("ee_nobtag" )){ category_extra = "No B-Tag"; }
if(std::string(directory) == std::string("ee_btag" )){ category = "ee"; }
if(std::string(directory) == std::string("ee_btag" )){ category_extra = "B-Tag"; }
const char* dataset;
if(std::string(inputfile).find("7TeV")!=std::string::npos){dataset = "CMS Preliminary, H#rightarrow#tau#tau, 4.9 fb^{-1} at 7 TeV";}
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "CMS Preliminary, H#rightarrow#tau#tau, 19.8 fb^{-1} at 8 TeV";}
TFile* input = new TFile(inputfile.c_str());
#ifdef MSSM
TFile* input2 = new TFile((inputfile+"_$MA_$TANB").c_str());
#endif
TH1F* ZTT = refill((TH1F*)input ->Get(TString::Format("%s/ZTT" , directory)), "ZTT" ); InitHist(ZTT , "", "", kOrange - 4, 1001);
TH1F* ZEE = refill((TH1F*)input ->Get(TString::Format("%s/ZEE" , directory)), "ZEE" ); InitHist(ZEE , "", "", kAzure + 2, 1001);
TH1F* TTJ = refill((TH1F*)input ->Get(TString::Format("%s/TTJ" , directory)), "TTJ" ); InitHist(TTJ , "", "", kBlue - 8, 1001);
TH1F* QCD = refill((TH1F*)input ->Get(TString::Format("%s/QCD" , directory)), "QCD" ); InitHist(QCD , "", "", kMagenta - 10, 1001);
TH1F* Dibosons= refill((TH1F*)input ->Get(TString::Format("%s/Dibosons", directory)), "Dibosons"); InitHist(Dibosons, "", "", kGreen - 4, 1001);
TH1F* WJets = refill((TH1F*)input ->Get(TString::Format("%s/WJets" , directory)), "WJets" ); InitHist(WJets , "", "", kRed + 2, 1001);
#ifdef MSSM
TH1F* ggH = refill((TH1F*)input2->Get(TString::Format("%s/ggH$MA" , directory)), "ggH" ); InitSignal(ggH); ggH->Scale($TANB);
TH1F* bbH = refill((TH1F*)input2->Get(TString::Format("%s/bbH$MA" , directory)), "bbH" ); InitSignal(bbH); bbH->Scale($TANB);
#else
#ifndef DROP_SIGNAL
TH1F* ggH = refill((TH1F*)input ->Get(TString::Format("%s/ggH125" , directory)), "ggH" ); InitSignal(ggH); ggH->Scale(SIGNAL_SCALE);
TH1F* qqH = refill((TH1F*)input ->Get(TString::Format("%s/qqH125" , directory)), "qqH" ); InitSignal(qqH); qqH->Scale(SIGNAL_SCALE);
TH1F* VH = refill((TH1F*)input ->Get(TString::Format("%s/VH125" , directory)), "VH" ); InitSignal(VH ); VH ->Scale(SIGNAL_SCALE);
#endif
#endif
#ifdef ASIMOV
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs_asimov", directory)), "data", true);
#else
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs", directory)), "data", true);
#endif
#ifdef MSSM
InitHist(data, "#bf{m_{#tau#tau} [GeV]}" , "#bf{dN/dm_{#tau#tau} [1/GeV]}"); InitData(data);
#else
InitHist(data, "#bf{D}", "#bf{dN/dD}" ); InitData(data);
#endif
TH1F* ref=(TH1F*)ZTT->Clone("ref");
ref->Add(ZEE);
ref->Add(TTJ);
ref->Add(QCD);
ref->Add(Dibosons);
ref->Add(WJets);
double unscaled[9];
unscaled[0] = ZTT->Integral();
unscaled[1] = ZEE->Integral();
unscaled[2] = TTJ->Integral();
unscaled[3] = QCD->Integral();
unscaled[4] = Dibosons->Integral();
unscaled[5] = WJets->Integral();
#ifdef MSSM
unscaled[6] = ggH->Integral();
unscaled[7] = bbH->Integral();
unscaled[8] = 0;
#else
#ifndef DROP_SIGNAL
unscaled[6] = ggH->Integral();
unscaled[7] = qqH->Integral();
unscaled[8] = VH ->Integral();
#endif
#endif
if(scaled){
rescale(ZTT, 1);
rescale(ZEE, 2);
rescale(TTJ, 3);
rescale(QCD, 4);
rescale(Dibosons, 5);
rescale(WJets, 6);
#ifdef MSSM
rescale(ggH, 7);
rescale(bbH, 8);
#else
#ifndef DROP_SIGNAL
rescale(ggH, 7);
rescale(qqH, 8);
rescale(VH, 9);
#endif
#endif
}
TH1F* scales[9];
scales[0] = new TH1F("scales-ZTT", "", 9, 0, 9);
scales[0]->SetBinContent(1, unscaled[0]>0 ? (ZTT->Integral()/unscaled[0]-1.) : 0.);
scales[1] = new TH1F("scales-ZEE" , "", 9, 0, 9);
scales[1]->SetBinContent(2, unscaled[1]>0 ? (ZEE->Integral()/unscaled[1]-1.) : 0.);
scales[2] = new TH1F("scales-TTJ", "", 9, 0, 9);
scales[2]->SetBinContent(3, unscaled[2]>0 ? (TTJ->Integral()/unscaled[2]-1.) : 0.);
scales[3] = new TH1F("scales-QCD" , "", 9, 0, 9);
scales[3]->SetBinContent(4, unscaled[3]>0 ? (QCD->Integral()/unscaled[3]-1.) : 0.);
scales[4] = new TH1F("scales-Dibosons", "", 9, 0, 9);
scales[4]->SetBinContent(5, unscaled[4]>0 ? (Dibosons->Integral()/unscaled[4]-1.) : 0.);
scales[5] = new TH1F("scales-WJets" , "", 9, 0, 9);
scales[5]->SetBinContent(6, unscaled[5]>0 ? (WJets->Integral()/unscaled[5]-1.) : 0.);
#ifdef MSSM
scales[6] = new TH1F("scales-ggH" , "", 9, 0, 9);
scales[6]->SetBinContent(7, unscaled[6]>0 ? (ggH->Integral()/unscaled[6]-1.) : 0.);
scales[7] = new TH1F("scales-bbH" , "", 9, 0, 9);
scales[7]->SetBinContent(8, unscaled[7]>0 ? (bbH->Integral()/unscaled[7]-1.) : 0.);
scales[8] = new TH1F("scales-NONE" , "", 9, 0, 9);
scales[8]->SetBinContent(9, 0.);
#else
#ifndef DROP_SIGNAL
scales[6] = new TH1F("scales-ggH" , "", 9, 0, 9);
scales[6]->SetBinContent(7, unscaled[6]>0 ? (ggH->Integral()/unscaled[4]-1.) : 0.);
scales[7] = new TH1F("scales-qqH" , "", 9, 0, 9);
scales[7]->SetBinContent(8, unscaled[7]>0 ? (qqH->Integral()/unscaled[5]-1.) : 0.);
scales[8] = new TH1F("scales-VH" , "", 9, 0, 9);
scales[8]->SetBinContent(9, unscaled[8]>0 ? (VH ->Integral()/unscaled[6]-1.) : 0.);
#endif
#endif
WJets->Add(Dibosons);
QCD->Add(WJets);
TTJ->Add(QCD);
ZTT->Add(TTJ);
ZEE->Add(ZTT);
if(log){
#ifdef MSSM
ggH ->Add(bbH);
#else
#ifndef DROP_SIGNAL
qqH ->Add(VH );
ggH ->Add(qqH);
#endif
#endif
}
else{
#ifdef MSSM
bbH ->Add(WJets);
ggH ->Add(bbH);
#else
#ifndef DROP_SIGNAL
VH ->Add(WJets);
qqH ->Add(VH );
ggH ->Add(qqH);
#endif
#endif
}
/*
mass plot before and after fit
*/
TCanvas* canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
if(log){ canv->SetLogy(1); }
#if defined MSSM
if(!log){ data->GetXaxis()->SetRange(0, data->FindBin(345)); } else{ data->GetXaxis()->SetRange(0, data->FindBin(UPPER_EDGE)); };
#else
data->GetXaxis()->SetRange(0, data->FindBin(345));
#endif
data->SetNdivisions(505);
data->SetMinimum(min);
#ifndef DROP_SIGNAL
data->SetMaximum(max>0 ? max : std::max(std::max(maximum(data, log), maximum(ZTT, log)), maximum(ggH, log)));
#else
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(ZTT, log)));
#endif
data->Draw("e");
TH1F* errorBand = (TH1F*)ZEE ->Clone("errorBand");
errorBand ->SetMarkerSize(0);
errorBand ->SetFillColor(1);
errorBand ->SetFillStyle(3013);
errorBand ->SetLineWidth(1);
for(int idx=0; idx<errorBand->GetNbinsX(); ++idx){
if(errorBand->GetBinContent(idx)>0){
std::cout << "Uncertainties on summed background samples: " << errorBand->GetBinError(idx)/errorBand->GetBinContent(idx) << std::endl;
break;
}
}
if(log){
ZEE->Draw("histsame");
ZTT->Draw("histsame");
TTJ->Draw("histsame");
QCD->Draw("histsame");
WJets->Draw("histsame");
//Dibosons->Draw("histsame");
$DRAW_ERROR
#ifndef DROP_SIGNAL
ggH->Draw("histsame");
#endif
}
else{
#ifndef DROP_SIGNAL
ggH ->Draw("histsame");
#endif
ZEE->Draw("histsame");
ZTT->Draw("histsame");
TTJ->Draw("histsame");
QCD->Draw("histsame");
WJets->Draw("histsame");
//Dibosons->Draw("histsame");
$DRAW_ERROR
}
data->Draw("esame");
canv->RedrawAxis();
//CMSPrelim(dataset, "#tau_{e}#tau_{e}", 0.17, 0.835);
CMSPrelim(dataset, "", 0.16, 0.835);
TPaveText* chan = new TPaveText(0.20, (category_extra2 && category_extra2[0]=='\0') ? 0.65+0.061 : 0.65+0.061, 0.32, 0.75+0.161, "tlbrNDC");
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
chan->AddText(category);
chan->AddText(category_extra);
chan->AddText(category_extra2);
chan->Draw();
/* TPaveText* cat = new TPaveText(0.20, 0.71+0.061, 0.32, 0.71+0.161, "NDC");
cat->SetBorderSize( 0 );
cat->SetFillStyle( 0 );
cat->SetTextAlign( 12 );
cat->SetTextSize ( 0.05 );
cat->SetTextColor( 1 );
cat->SetTextFont ( 62 );
cat->AddText(category_extra);
cat->Draw();
*/
#ifdef MSSM
TPaveText* massA = new TPaveText(0.55, 0.50+0.061, 0.95, 0.50+0.161, "NDC");
massA->SetBorderSize( 0 );
massA->SetFillStyle( 0 );
massA->SetTextAlign( 12 );
massA->SetTextSize ( 0.03 );
massA->SetTextColor( 1 );
massA->SetTextFont ( 62 );
massA->AddText("m^{h}_{max} (m_{A}=$MA GeV, tan#beta=$TANB)");
massA->Draw();
#endif
#ifdef MSSM
TLegend* leg = new TLegend(0.55, 0.65, 0.95, 0.90);
SetLegendStyle(leg);
leg->AddEntry(ggH , "#phi#rightarrow#tau#tau" , "L" );
#else
TLegend* leg = new TLegend(0.50, 0.65, 0.95, 0.90);
SetLegendStyle(leg);
#ifndef DROP_SIGNAL
if(SIGNAL_SCALE!=1){
leg->AddEntry(ggH , TString::Format("%.0f#timesH(125 GeV)#rightarrow#tau#tau", SIGNAL_SCALE) , "L" );
}
else{
leg->AddEntry(ggH , "H(125 GeV)#rightarrow#tau#tau" , "L" );
}
#endif
#endif
#ifdef ASIMOV
leg->AddEntry(data , "sum(bkg) + H(125)" , "LP");
#else
leg->AddEntry(data , "observed" , "LP");
#endif
leg->AddEntry(ZEE , "Z#rightarrowee" , "F" );
leg->AddEntry(ZTT , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(TTJ , "t#bar{t}" , "F" );
leg->AddEntry(QCD , "QCD" , "F" );
leg->AddEntry(WJets, "electroweak" , "F" );
//leg->AddEntry(Dibosons , "Dibosons" , "F" );
$ERROR_LEGEND
leg->Draw();
/*
Ratio Data over MC
*/
TCanvas *canv0 = MakeCanvas("canv0", "histograms", 600, 400);
canv0->SetGridx();
canv0->SetGridy();
canv0->cd();
TH1F* model = (TH1F*)ZEE ->Clone("model");
TH1F* test1 = (TH1F*)data->Clone("test1");
for(int ibin=0; ibin<test1->GetNbinsX(); ++ibin){
//the small value in case of 0 entries in the model is added to prevent the chis2 test from failing
model->SetBinContent(ibin+1, model->GetBinContent(ibin+1)>0 ? model->GetBinContent(ibin+1)*model->GetBinWidth(ibin+1) : 0.01);
model->SetBinError (ibin+1, CONVERVATIVE_CHI2 ? 0. : model->GetBinError (ibin+1)*model->GetBinWidth(ibin+1));
test1->SetBinContent(ibin+1, test1->GetBinContent(ibin+1)*test1->GetBinWidth(ibin+1));
test1->SetBinError (ibin+1, test1->GetBinError (ibin+1)*test1->GetBinWidth(ibin+1));
}
double chi2prob = test1->Chi2Test (model,"PUW"); std::cout << "chi2prob:" << chi2prob << std::endl;
double chi2ndof = test1->Chi2Test (model,"CHI2/NDFUW"); std::cout << "chi2ndf :" << chi2ndof << std::endl;
double ksprob = test1->KolmogorovTest(model); std::cout << "ksprob :" << ksprob << std::endl;
double ksprobpe = test1->KolmogorovTest(model,"DX"); std::cout << "ksprobpe:" << ksprobpe << std::endl;
std::vector<double> edges;
TH1F* zero = (TH1F*)ref ->Clone("zero"); zero->Clear();
TH1F* rat1 = (TH1F*)data->Clone("rat1");
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
rat1->SetBinContent(ibin+1, ZEE->GetBinContent(ibin+1)>0 ? data->GetBinContent(ibin+1)/ZEE->GetBinContent(ibin+1) : 0);
rat1->SetBinError (ibin+1, ZEE->GetBinContent(ibin+1)>0 ? data->GetBinError (ibin+1)/ZEE->GetBinContent(ibin+1) : 0);
zero->SetBinContent(ibin+1, 0.);
zero->SetBinError (ibin+1, ZEE->GetBinContent(ibin+1)>0 ? ZEE ->GetBinError (ibin+1)/ZEE->GetBinContent(ibin+1) : 0);
}
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
if(rat1->GetBinContent(ibin+1)>0){
edges.push_back(TMath::Abs(rat1->GetBinContent(ibin+1)-1.)+TMath::Abs(rat1->GetBinError(ibin+1)));
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
}
}
float range = 0.1;
std::sort(edges.begin(), edges.end());
if (edges[edges.size()-2]>0.1) { range = 0.2; }
if (edges[edges.size()-2]>0.2) { range = 0.5; }
if (edges[edges.size()-2]>0.5) { range = 1.0; }
if (edges[edges.size()-2]>1.0) { range = 1.5; }
if (edges[edges.size()-2]>1.5) { range = 2.0; }
rat1->SetLineColor(kBlack);
rat1->SetFillColor(kGray );
rat1->SetMaximum(+range);
rat1->SetMinimum(-range);
rat1->GetYaxis()->CenterTitle();
rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
#ifdef MSSM
rat1->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
#else
rat1->GetXaxis()->SetTitle("#bf{D}");
#endif
rat1->Draw();
zero->SetFillStyle( 3013);
zero->SetFillColor(kBlack);
zero->SetLineColor(kBlack);
zero->SetMarkerSize(0.1);
zero->Draw("e2histsame");
canv0->RedrawAxis();
TPaveText* stat1 = new TPaveText(0.20, 0.76+0.061, 0.32, 0.76+0.161, "NDC");
stat1->SetBorderSize( 0 );
stat1->SetFillStyle( 0 );
stat1->SetTextAlign( 12 );
stat1->SetTextSize ( 0.05 );
stat1->SetTextColor( 1 );
stat1->SetTextFont ( 62 );
stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f", chi2ndof, chi2prob));
//stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f, P(KS)=%.3f", chi2ndof, chi2prob, ksprob));
stat1->Draw();
/*
Ratio After fit over Prefit
*/
TCanvas *canv1 = MakeCanvas("canv1", "histograms", 600, 400);
canv1->SetGridx();
canv1->SetGridy();
canv1->cd();
edges.clear();
TH1F* rat2 = (TH1F*) ZEE->Clone("rat2");
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
rat2->SetBinContent(ibin+1, ref->GetBinContent(ibin+1)>0 ? ZEE->GetBinContent(ibin+1)/ref->GetBinContent(ibin+1) : 0);
rat2->SetBinError (ibin+1, ref->GetBinContent(ibin+1)>0 ? ZEE->GetBinError (ibin+1)/ref->GetBinContent(ibin+1) : 0);
}
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
if(rat2->GetBinContent(ibin+1)>0){
edges.push_back(TMath::Abs(rat2->GetBinContent(ibin+1)-1.)+TMath::Abs(rat2->GetBinError(ibin+1)));
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat2 ->SetBinContent(ibin+1, rat2->GetBinContent(ibin+1)-1.);
}
}
range = 0.1;
std::sort(edges.begin(), edges.end());
if (edges[edges.size()-2]>0.1) { range = 0.2; }
if (edges[edges.size()-2]>0.2) { range = 0.5; }
if (edges[edges.size()-2]>0.5) { range = 1.0; }
if (edges[edges.size()-2]>1.0) { range = 1.5; }
if (edges[edges.size()-2]>1.5) { range = 2.0; }
#if defined MSSM
if(!log){ rat2->GetXaxis()->SetRange(0, rat2->FindBin(345)); } else{ rat2->GetXaxis()->SetRange(0, rat2->FindBin(UPPER_EDGE)); };
#else
rat2->GetXaxis()->SetRange(0, rat2->FindBin(345));
#endif
rat2->SetNdivisions(505);
rat2->SetLineColor(kRed+ 3);
rat2->SetMarkerColor(kRed+3);
rat2->SetMarkerSize(1.1);
rat2->SetMaximum(+range);
rat2->SetMinimum(-range);
rat2->GetYaxis()->SetTitle("#bf{Postfit/Prefit-1}");
rat2->GetYaxis()->CenterTitle();
#if defined MSSM
rat2->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
#else
rat2->GetXaxis()->SetTitle("#bf{D}");
#endif
rat2->Draw();
zero->SetFillStyle( 3013);
zero->SetFillColor(kBlack);
zero->SetLineColor(kBlack);
zero->Draw("e2histsame");
canv1->RedrawAxis();
/*
Relative shift per sample
*/
TCanvas *canv2 = MakeCanvas("canv2", "histograms", 600, 400);
canv2->SetGridx();
canv2->SetGridy();
canv2->cd();
InitHist (scales[0], "", "", kOrange - 4, 1001);
InitHist (scales[1], "", "", kAzure + 2, 1001);
InitHist (scales[2], "", "", kBlue - 8, 1001);
InitHist (scales[3], "", "", kMagenta - 10, 1001);
InitHist (scales[4], "", "", kGreen - 4, 1001);
InitHist (scales[5], "", "", kRed + 2, 1001);
#ifndef DROP_SIGNAL
InitSignal(scales[6]);
InitSignal(scales[7]);
InitSignal(scales[8]);
#endif
scales[0]->Draw();
scales[0]->GetXaxis()->SetBinLabel(1, "#bf{ZTT}");
scales[0]->GetXaxis()->SetBinLabel(2, "#bf{ZEE}" );
scales[0]->GetXaxis()->SetBinLabel(3, "#bf{TTJ}");
scales[0]->GetXaxis()->SetBinLabel(4, "#bf{QCD}" );
scales[0]->GetXaxis()->SetBinLabel(5, "#bf{Dibosons}");
scales[0]->GetXaxis()->SetBinLabel(6, "#bf{WJets}" );
#ifdef MSSM
scales[0]->GetXaxis()->SetBinLabel(7, "#bf{ggH}" );
scales[0]->GetXaxis()->SetBinLabel(8, "#bf{bbH}" );
scales[0]->GetXaxis()->SetBinLabel(9, "#bf{NONE}" );
#else
scales[0]->GetXaxis()->SetBinLabel(7, "#bf{ggH}" );
scales[0]->GetXaxis()->SetBinLabel(8, "#bf{qqH}" );
scales[0]->GetXaxis()->SetBinLabel(9, "#bf{VH}" );
#endif
scales[0]->SetMaximum(+0.5);
scales[0]->SetMinimum(-0.5);
scales[0]->GetYaxis()->CenterTitle();
scales[0]->GetYaxis()->SetTitle("#bf{Postfit/Prefit-1}");
scales[1]->Draw("same");
scales[2]->Draw("same");
scales[3]->Draw("same");
scales[4]->Draw("same");
scales[5]->Draw("same");
#ifndef DROP_SIGNAL
scales[6]->Draw("same");
scales[7]->Draw("same");
scales[8]->Draw("same");
#endif
TH1F* zero_samples = (TH1F*)scales[0]->Clone("zero_samples"); zero_samples->Clear();
zero_samples->SetBinContent(1,0.);
zero_samples->Draw("same");
canv2->RedrawAxis();
/*
prepare output
*/
bool isSevenTeV = std::string(inputfile).find("7TeV")!=std::string::npos;
canv ->Print(TString::Format("%s_%sfit_%s_%s.png" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv ->Print(TString::Format("%s_%sfit_%s_%s.pdf" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv ->Print(TString::Format("%s_%sfit_%s_%s.eps" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
if(log || FULLPLOTS)
{
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
}
if((log && scaled) || FULLPLOTS)
{
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"));
}
TFile* output = new TFile(TString::Format("%s_%sfit_%s_%s.root", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : "LIN"), "update");
output->cd();
data ->Write("data_obs");
ZTT->Write("Ztt" );
ZEE->Write("Zee" );
TTJ->Write("ttbar");
QCD->Write("Fakes");
Dibosons->Write("Dibosons");
WJets->Write("EWK");
#ifdef MSSM
ggH ->Write("ggH");
bbH ->Write("bbH");
#else
#ifndef DROP_SIGNAL
ggH ->Write("ggH");
qqH ->Write("qqH");
VH ->Write("VH" );
#endif
#endif
if(errorBand){
errorBand->Write("errorBand");
}
output->Close();
delete errorBand;
delete model;
delete test1;
delete zero;
delete rat1;
delete rat2;
delete zero_samples;
delete ref;
}
void
draw2DLimitContours(map<string,TList *>& m_contours,
const TString& par1,
const TString& par2,
const TString& plotprefix,
TLegend *legend)
{
//from here we build the two-dimensional aTGC limit
TCanvas *finalPlot = new TCanvas("final","limits",500,500);
finalPlot->cd();
cout << "Drawing expected 68%" << endl;
TList *contLevel = m_contours["exp68"];
TGraph *curv;
std::cout << "m_contours.size() = " << m_contours.size() << std::endl;
for (map<string,TList *>::const_iterator iter = m_contours.begin(); iter != m_contours.end(); iter++ ){
std::cout << "iter->first = " << iter->first << std::endl;
std::cout << "iter->second = " << iter->second << std::endl;
}
std::cout << "contLevel = " << contLevel << std::endl;
assert(contLevel);
curv = (TGraph*)(contLevel->First());
curv->GetXaxis()->SetLimits(parmin(par1),parmax(par1));
curv->GetYaxis()->SetRangeUser(parmin(par2),parmax(par2));
curv->SetTitle();
curv->GetXaxis()->SetTitle(par2latex(par1));
curv->GetXaxis()->SetTitleFont(42);
curv->GetYaxis()->SetTitle(par2latex(par2));
curv->GetYaxis()->SetTitleFont(42);
curv->GetYaxis()->SetTitleOffset(1.20);
for (int i=0; i<contLevel->GetSize(); i++) {
assert(curv);
curv->SetLineColor(kBlue);
curv->SetLineWidth(2);
curv->SetLineStyle(9);
if (!i) {
curv->Draw("AC");
legend->AddEntry(curv,"Expected 68% C.L.","L");
} else
curv->Draw("SAME C");
curv=(TGraph *)(contLevel->After(curv));
}
cout << "Drawing expected 95%" << endl;
contLevel = m_contours["exp95"];
curv = (TGraph*)(contLevel->First());
for (int i=0; i<contLevel->GetSize(); i++) {
curv->SetLineColor(kGreen);
curv->SetLineWidth(2);
curv->SetLineStyle(9);
curv->Draw("SAME C");
if (!i) legend->AddEntry(curv,"Expected 95% C.L.","L");
curv=(TGraph *)(contLevel->After(curv));
}
cout << "Drawing expected 99%" << endl;
contLevel = m_contours["exp99"];
curv = (TGraph*)(contLevel->First());
for (int i=0; i<contLevel->GetSize(); i++) {
curv->SetLineColor(kRed);
curv->SetLineWidth(2);
curv->SetLineStyle(9);
curv->Draw("SAME C");
if (!i) legend->AddEntry(curv,"Expected 99% C.L.","L");
curv=(TGraph *)(contLevel->After(curv));
}
contLevel = m_contours["obs95"];
if (contLevel) {
cout << "Drawing obs95" << endl;
curv = (TGraph*)(contLevel->First());
for (int i=0; i<contLevel->GetSize(); i++) {
curv->Draw("SAME C");
curv->SetLineWidth(2);
if (!i) legend->AddEntry(curv,"Observed 95% C.L.","L");
curv=(TGraph *)(contLevel->After(curv));
}
}
TGraph *SMpoint = new TGraph(1);
SMpoint->SetPoint(1,0,0);
//SMpoint->Draw("SAME Po");
//smLabel = TPaveText(0,
// m_contours["-2s"]->GetYaxis()->GetXmax()/8,
// m_contours["-2s"]->GetXaxis()->GetXmax()/3->5,
// -m_contours["-2s"]->GetYaxis()->GetXmax()/8);
//smLabel->SetFillStyle(0);
//smLabel->SetBorderSize(0);
//smLabel->AddText(" SM");
//smLabel->Draw();
legend->Draw();
TPaveText *text = new TPaveText(0.566,0.87,0.965,1.101,"NDC");
text->SetFillStyle(0);
text->SetBorderSize(0);
//text->AddText(Form("95%% CL Limit on %s and %s",par2latex(par1).Data(),par2latex(par2).Data()));
text->AddText(0,0.35,Form("#intL dt= %.1f fb^{-1}, #sqrt{s} = %d TeV",intlumifbinv,beamcometev));
text->Draw();
// text2 = TPaveText(0.155,0.199,0.974,0.244,"NDC");
// text2->SetFillStyle(0);
// text2->SetBorderSize(0);
// text2->AddText("Values outside contour excluded");
// text2->Draw();
//text3 = TPaveText(0.506,0.699,0.905,0.758,"NDC");
//text3->SetFillStyle(0);
//text3->SetBorderSize(0);
//text3->AddText(options.flavorText);
//text3->Draw();
gPad->SetGrid(1,1);
finalPlot->RedrawAxis();
finalPlot->ResetAttPad();
finalPlot->Update();
finalPlot->Draw();
finalPlot->Update();
finalPlot->Modified();
finalPlot->Update();
finalPlot->Print(Form("%s.pdf",plotprefix.Data()));
finalPlot->Print(Form("%s.eps",plotprefix.Data()));
//finalPlot->Print(Form("%s.png",plotprefix.Data()));
} // draw2DlimitContours
void
HBB_HAD_X(bool scaled=true, bool log=true, float min=0.1, float max=-1., string inputfile="root/$HISTFILE", const char* directory="bb_$CATEGORY")
{
// define common canvas, axes pad styles
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
const char* category_extra = "";
if(std::string(directory) == std::string("bb_had0" )){ category_extra = "all-had_{0}"; }
if(std::string(directory) == std::string("bb_had1" )){ category_extra = "all-had_{1}"; }
if(std::string(directory) == std::string("bb_had2" )){ category_extra = "all-had_{2}"; }
if(std::string(directory) == std::string("bb_had3" )){ category_extra = "all-had_{3}"; }
if(std::string(directory) == std::string("bb_had4" )){ category_extra = "all-had_{4}"; }
if(std::string(directory) == std::string("bb_had5" )){ category_extra = "all-had_{5}"; }
if(std::string(directory) == std::string("bb_lep" )){ category_extra = "semi-lep"; }
const char* dataset;
if(std::string(inputfile).find("7TeV")!=std::string::npos){dataset = "Preliminary, #sqrt{s} = 7 TeV, L = 2.7 fb^{-1}";}
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "Preliminary, #sqrt{s} = 8 TeV, L = 19.4 fb^{-1}";}
TFile* input = new TFile(inputfile.c_str());
#ifdef MSSM
TFile* input2 = new TFile((inputfile+"_$MA_$TANB").c_str());
#endif
TH1F* Bbb = refill((TH1F*)input->Get(TString::Format("%s/Bbb" , directory)), "Bbb"); InitHist(Bbb, "", "", kMagenta-10, 1001);
TH1F* Cbb = refill((TH1F*)input->Get(TString::Format("%s/Cbb" , directory)), "Cbb"); InitHist(Cbb, "", "", kRed + 2, 1001);
TH1F* Qbb = refill((TH1F*)input->Get(TString::Format("%s/Qbb" , directory)), "Qbb"); InitHist(Qbb, "", "", kBlue - 8, 1001);
TH1F* bbB = refill((TH1F*)input->Get(TString::Format("%s/bbB" , directory)), "bbB"); InitHist(bbB, "", "", kOrange - 4, 1001);
TH1F* bbX = refill((TH1F*)input->Get(TString::Format("%s/bbX" , directory)), "bbX"); InitHist(bbX, "", "", kViolet - 0, 1001);
#ifdef MSSM
//float bbHScale = 1.;
//ggHScale = ($MSSM_SIGNAL_ggH_xseff_A + $MSSM_SIGNAL_ggH_xseff_hH);
//bbHScale = ($MSSM_SIGNAL_bbH_xseff_A + $MSSM_SIGNAL_bbH_xseff_hH);
TH1F* bbH = refill((TH1F*)input2->Get(TString::Format("%s/bbH$MA" , directory)), "bbH" ); InitSignal(bbH); bbH->Scale($TANB); //bbH->Scale(bbHScale);
#endif
#ifdef ASIMOV
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs_asimov", directory)), "data", true);
#else
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs", directory)), "data", true);
#endif
InitHist(data, "#bf{m_{b#bar{b}} [GeV]}", "#bf{dN/dm_{b#bar{b}} [1/GeV]}"); InitData(data);
TH1F* ref=(TH1F*)Qbb->Clone("ref");
ref->Add(bbX);
ref->Add(Cbb);
ref->Add(bbB);
ref->Add(Bbb);
double unscaled[7];
unscaled[0] = Qbb ->Integral();
unscaled[1] = bbX ->Integral();
unscaled[2] = Cbb ->Integral();
unscaled[3] = bbB ->Integral();
unscaled[4] = Bbb ->Integral();
#ifdef MSSM
unscaled[5] = bbH ->Integral();
unscaled[6] = 0;
#endif
if(scaled){
rescale(Bbb, 1);
rescale(bbB, 4);
rescale(Cbb, 2);
rescale(bbX, 5);
rescale(Qbb, 3);
#ifdef MSSM
rescale(bbH, 6);
#endif
}
TH1F* scales[7];
scales[0] = new TH1F("scales-Qbb", "", 7, 0, 7);
scales[0]->SetBinContent(1, unscaled[0]>0 ? (Qbb ->Integral()/unscaled[0]-1.) : 0.);
scales[1] = new TH1F("scales-bbX" , "", 7, 0, 7);
scales[1]->SetBinContent(2, unscaled[1]>0 ? (bbX ->Integral()/unscaled[1]-1.) : 0.);
scales[2] = new TH1F("scales-Cbb", "", 7, 0, 7);
scales[2]->SetBinContent(3, unscaled[2]>0 ? (Cbb ->Integral()/unscaled[2]-1.) : 0.);
scales[3] = new TH1F("scales-bbB" , "", 7, 0, 7);
scales[3]->SetBinContent(4, unscaled[3]>0 ? (bbB ->Integral()/unscaled[3]-1.) : 0.);
scales[4] = new TH1F("scales-Bbb" , "", 7, 0, 7);
scales[4]->SetBinContent(5, unscaled[4]>0 ? (Bbb ->Integral()/unscaled[4]-1.) : 0.);
#ifdef MSSM
scales[5] = new TH1F("scales-bbH" , "", 7, 0, 7);
scales[5]->SetBinContent(6, unscaled[5]>0 ? (bbH ->Integral()/unscaled[5]-1.) : 0.);
scales[6] = new TH1F("scales-NONE" , "", 7, 0, 7);
scales[6]->SetBinContent(7, 0.);
#endif
bbX ->Add(Qbb);
Cbb ->Add(bbX);
bbB ->Add(Cbb);
Bbb ->Add(bbB);
if(!log){
#ifdef MSSM
bbH ->Add(Bbb);
#endif
}
/*
mass plot before and after fit
*/
TCanvas* canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
if(log){ canv->SetLogy(1); }
#if defined MSSM
if(!log){ data->GetXaxis()->SetRange(0, data->FindBin(350)); } else{ data->GetXaxis()->SetRange(0, data->FindBin(1000)); };
#endif
data->SetNdivisions(505);
data->SetMinimum(min);
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(Bbb, log)));
data->Draw("e");
TH1F* errorBand = (TH1F*)Bbb ->Clone();
errorBand ->SetMarkerSize(0);
errorBand ->SetFillColor(1);
errorBand ->SetFillStyle(3013);
errorBand ->SetLineWidth(1);
if(log){
Bbb ->Draw("histsame");
bbB ->Draw("histsame");
Cbb ->Draw("histsame");
bbX ->Draw("histsame");
Qbb ->Draw("histsame");
$DRAW_ERROR
#ifndef DROP_SIGNAL
bbH ->Draw("histsame");
#endif
}
else{
#ifndef DROP_SIGNAL
bbH ->Draw("histsame");
#endif
Bbb ->Draw("histsame");
bbB ->Draw("histsame");
Cbb ->Draw("histsame");
bbX ->Draw("histsame");
Qbb ->Draw("histsame");
$DRAW_ERROR
}
data->Draw("esame");
canv->RedrawAxis();
//CMSPrelim(dataset, "b#bar{b}", 0.17, 0.835);
CMSPrelim(dataset, "", 0.17, 0.835);
TPaveText* chan = new TPaveText(0.20, 0.74+0.061, 0.32, 0.74+0.161, "NDC");
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
chan->AddText("b#bar{b}");
chan->Draw();
TPaveText* cat = new TPaveText(0.20, 0.68+0.061, 0.32, 0.68+0.161, "NDC");
cat->SetBorderSize( 0 );
cat->SetFillStyle( 0 );
cat->SetTextAlign( 12 );
cat->SetTextSize ( 0.05 );
cat->SetTextColor( 1 );
cat->SetTextFont ( 62 );
cat->AddText(category_extra);
cat->Draw();
#ifdef MSSM
TPaveText* massA = new TPaveText(0.75, 0.48+0.061, 0.85, 0.48+0.161, "NDC");
massA->SetBorderSize( 0 );
massA->SetFillStyle( 0 );
massA->SetTextAlign( 12 );
massA->SetTextSize ( 0.03 );
massA->SetTextColor( 1 );
massA->SetTextFont ( 62 );
massA->AddText("m_{A}=$MA GeV");
massA->Draw();
TPaveText* tanb = new TPaveText(0.75, 0.44+0.061, 0.85, 0.44+0.161, "NDC");
tanb->SetBorderSize( 0 );
tanb->SetFillStyle( 0 );
tanb->SetTextAlign( 12 );
tanb->SetTextSize ( 0.03 );
tanb->SetTextColor( 1 );
tanb->SetTextFont ( 62 );
tanb->AddText("tan#beta=$TANB");
tanb->Draw();
TPaveText* scen = new TPaveText(0.75, 0.40+0.061, 0.85, 0.40+0.161, "NDC");
scen->SetBorderSize( 0 );
scen->SetFillStyle( 0 );
scen->SetTextAlign( 12 );
scen->SetTextSize ( 0.03 );
scen->SetTextColor( 1 );
scen->SetTextFont ( 62 );
scen->AddText("m^{h}_{max}");
scen->Draw();
#endif
#ifdef MSSM
TLegend* leg = new TLegend(0.55, 0.65, 0.95, 0.90);
SetLegendStyle(leg);
leg->AddEntry(bbH , "#phi#rightarrowb#bar{b}" , "L" );
#endif
#ifdef ASIMOV
leg->AddEntry(data , "sum(bkg) + SM125 GeV signal" , "LP");
#else
leg->AddEntry(data , "observed" , "LP");
#endif
leg->AddEntry(Bbb, "Bbb" , "F" );
leg->AddEntry(bbB, "bbB" , "F" );
leg->AddEntry(Cbb, "Cbb" , "F" );
leg->AddEntry(bbX, "bbX" , "F" );
leg->AddEntry(Qbb, "Qbb" , "F" );
$ERROR_LEGEND
leg->Draw();
//#ifdef MSSM
// TPaveText* mssm = new TPaveText(0.69, 0.85, 0.90, 0.90, "NDC");
// mssm->SetBorderSize( 0 );
// mssm->SetFillStyle( 0 );
// mssm->SetTextAlign( 12 );
// mssm->SetTextSize ( 0.03 );
// mssm->SetTextColor( 1 );
// mssm->SetTextFont ( 62 );
// mssm->AddText("(m_{A}=250, tan#beta=5)");
// mssm->Draw();
//#else
// TPaveText* mssm = new TPaveText(0.83, 0.85, 0.95, 0.90, "NDC");
// mssm->SetBorderSize( 0 );
// mssm->SetFillStyle( 0 );
// mssm->SetTextAlign( 12 );
// mssm->SetTextSize ( 0.03 );
// mssm->SetTextColor( 1 );
// mssm->SetTextFont ( 62 );
// mssm->AddText("m_{H}=125");
// mssm->Draw();
//#endif
/*
Ratio Data over MC
*/
TCanvas *canv0 = MakeCanvas("canv0", "histograms", 600, 400);
canv0->SetGridx();
canv0->SetGridy();
canv0->cd();
TH1F* zero = (TH1F*)ref ->Clone("zero"); zero->Clear();
TH1F* rat1 = (TH1F*)data->Clone("rat");
rat1->Divide(Bbb);
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
if(rat1->GetBinContent(ibin+1)>0){
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
}
zero->SetBinContent(ibin+1, 0.);
}
rat1->SetLineColor(kBlack);
rat1->SetFillColor(kGray );
rat1->SetMaximum(+1.5);
rat1->SetMinimum(-1.5);
rat1->GetYaxis()->CenterTitle();
rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
rat1->GetXaxis()->SetTitle("#bf{m_{b#bar{b}} [GeV]}");
rat1->Draw();
zero->SetLineColor(kBlack);
zero->Draw("same");
canv0->RedrawAxis();
/*
Ratio After fit over Prefit
*/
TCanvas *canv1 = MakeCanvas("canv1", "histograms", 600, 400);
canv1->SetGridx();
canv1->SetGridy();
canv1->cd();
TH1F* rat2 = (TH1F*) Bbb->Clone("rat2");
rat2->Divide(ref);
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
if(rat2->GetBinContent(ibin+1)>0){
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat2 ->SetBinContent(ibin+1, rat2->GetBinContent(ibin+1)-1.);
}
}
rat2->SetLineColor(kRed+ 3);
rat2->SetFillColor(kRed-10);
rat2->SetMaximum(+0.3);
rat2->SetMinimum(-0.3);
rat2->GetYaxis()->SetTitle("#bf{Fit/Prefit-1}");
rat2->GetYaxis()->CenterTitle();
rat2->GetXaxis()->SetTitle("#bf{m_{b#bar{b}} [GeV]}");
rat2->GetXaxis()->SetRange(0, 28);
rat2->Draw();
zero->SetLineColor(kBlack);
zero->Draw("same");
canv1->RedrawAxis();
/*
Relative shift per sample
*/
TCanvas *canv2 = MakeCanvas("canv2", "histograms", 600, 400);
canv2->SetGridx();
canv2->SetGridy();
canv2->cd();
InitHist (scales[4], "", "", kMagenta-10, 1001);
InitHist (scales[2], "", "", kRed + 2, 1001);
InitHist (scales[0], "", "", kBlue - 8, 1001);
InitHist (scales[3], "", "", kOrange - 4, 1001);
InitHist (scales[1], "", "", kViolet - 0, 1001);
scales[0]->Draw();
scales[0]->GetXaxis()->SetBinLabel(1, "#bf{Qbb}");
scales[0]->GetXaxis()->SetBinLabel(2, "#bf{bbX}");
scales[0]->GetXaxis()->SetBinLabel(3, "#bf{Cbb}");
scales[0]->GetXaxis()->SetBinLabel(4, "#bf{bbB}");
scales[0]->GetXaxis()->SetBinLabel(5, "#bf{Bbb}");
#ifdef MSSM
scales[0]->GetXaxis()->SetBinLabel(6, "#bf{bbH}" );
scales[0]->GetXaxis()->SetBinLabel(7, "#bf{NONE}" );
#endif
scales[0]->SetMaximum(+1.0);
scales[0]->SetMinimum(-1.0);
scales[0]->GetYaxis()->CenterTitle();
scales[0]->GetYaxis()->SetTitle("#bf{Fit/Prefit-1}");
scales[1]->Draw("same");
scales[2]->Draw("same");
scales[3]->Draw("same");
scales[4]->Draw("same");
zero->Draw("same");
canv2->RedrawAxis();
/*
prepare output
*/
bool isSevenTeV = std::string(inputfile).find("7TeV")!=std::string::npos;
canv ->Print(TString::Format("%s_%sfit_%s_%s.png" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv ->Print(TString::Format("%s_%sfit_%s_%s.pdf" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv ->Print(TString::Format("%s_%sfit_%s_%s.eps" , directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
if(!log || FULLPLOTS)
{
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv0->Print(TString::Format("%s_datamc_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
}
if((!log && scaled) || FULLPLOTS)
{
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv1->Print(TString::Format("%s_prefit_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.png", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.pdf", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sfit_%s_%s.eps", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
}
TFile* output = new TFile(TString::Format("%s_%sfit_%s_%s.root", directory, scaled ? "post" : "pre", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""), "update");
output->cd();
data ->Write("data_obs");
Qbb ->Write("Qbb" );
bbX ->Write("bbX" );
Cbb ->Write("Cbb" );
bbB ->Write("bbB" );
Bbb ->Write("Bbb" );
#ifdef MSSM
bbH ->Write("bbH" );
#endif
if(errorBand){
errorBand->Write("errorBand");
}
output->Close();
}
// examples macro
void
etauAfterFit_novbf(bool scaled = true, bool log = true)
{
// defining the common canvas, axes pad styles
SetStyle();
// open example histogram file
TFile* exampleFile = new TFile("eleTau_sm.root");
//load example histograms
TH1F* data = (TH1F*)exampleFile->Get("eleTau_SM0/data_obs");
if(data) {InitHist(data, "#bf{m_{vis} [GeV]}", "#bf{Events}"); InitData(data);} else{std::cout << "can't find hitogram " << "eleTau_SM0/data_obs" << std::endl;}
TH1F* Fakes = refill((TH1F*)exampleFile->Get("eleTau_SM0/QCD")) ; InitHist(Fakes, "", "", kMagenta-10, 1001);
TH1F* EWK1 = refill((TH1F*)exampleFile->Get("eleTau_SM0/W" )) ; InitHist(EWK1 , "", "", kRed + 2, 1001);
TH1F* EWK2 = refill((TH1F*)exampleFile->Get("eleTau_SM0/ZJ" )) ; InitHist(EWK2 , "", "", kRed + 2, 1001);
TH1F* EWK3 = refill((TH1F*)exampleFile->Get("eleTau_SM0/ZL" )) ; InitHist(EWK3 , "", "", kRed + 2, 1001);
TH1F* EWK = refill((TH1F*)exampleFile->Get("eleTau_SM0/VV" )) ; InitHist(EWK , "", "", kRed + 2, 1001);
TH1F* ttbar = refill((TH1F*)exampleFile->Get("eleTau_SM0/TT" )) ; InitHist(ttbar, "", "", kBlue - 8, 1001);
TH1F* Ztt = refill((TH1F*)exampleFile->Get("eleTau_SM0/ZTT")) ; InitHist(Ztt , "", "", kOrange - 4, 1001);
TH1F* ggH = refill((TH1F*)exampleFile->Get("eleTau_SM0/SM120" )) ; InitSignal(ggH); ggH ->Scale(10*16.63*0.071*16.083/ggH ->Integral());
TH1F* qqH = refill((TH1F*)exampleFile->Get("eleTau_SM0/VBF120")) ; InitSignal(qqH); qqH ->Scale(10*1.269*0.071* 1.105/qqH ->Integral());
if(scaled){
rescale(Fakes, 2);
rescale(EWK1 , 3);
rescale(EWK2 , 4);
rescale(EWK3 , 5);
rescale(EWK , 7);
rescale(ttbar, 6);
rescale(Ztt , 1);
rescale(ggH , 8);
rescale(qqH , 9);
}
if(log){
qqH ->Add(ggH );
Fakes->Add(qqH );
EWK1 ->Add(Fakes);
EWK2 ->Add(EWK1 );
EWK3 ->Add(EWK2 );
EWK ->Add(EWK3 );
ttbar->Add(EWK );
Ztt ->Add(ttbar);
}
else{
EWK1 ->Add(Fakes);
EWK2 ->Add(EWK1 );
EWK3 ->Add(EWK2 );
EWK ->Add(EWK3 );
ttbar->Add(EWK );
Ztt ->Add(ttbar);
ggH ->Add(Ztt );
qqH ->Add(ggH );
}
// define canvas
TCanvas *canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
if(log){
canv->SetLogy(1);
data->SetMinimum(5.0);
data->SetMaximum(500000.);
}
else{
data->SetMaximum(4000.);
}
data->SetNdivisions(505);
data->Draw("e");
if(log){
Ztt->Draw("same");
ttbar->Draw("same");
EWK->Draw("same");
Fakes->Draw("same");
qqH->Draw("same");
}
else{
qqH->Draw("same");
Ztt->Draw("same");
ttbar->Draw("same");
EWK->Draw("same");
Fakes->Draw("same");
}
data->Draw("esame");
canv->RedrawAxis();
CMSPrelim("#tau_{e}#tau_{h}", 0.45, 0.75);
TLegend* leg = new TLegend(0.45, 0.45, 0.9, 0.75);
SetLegendStyle(leg);
leg->AddEntry(qqH , "(10x) H#rightarrow#tau#tau" , "L" );
leg->AddEntry(data , "Observed" , "LP");
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
leg->AddEntry(EWK , "Electroweak" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
leg->Draw();
TPaveText* mssm = new TPaveText(0.78, 0.70, 0.90, 0.74, "NDC");
mssm->SetBorderSize( 0 );
mssm->SetFillStyle( 0 );
mssm->SetTextAlign( 12 );
mssm->SetTextSize ( 0.04 );
mssm->SetTextColor( 1 );
mssm->SetTextFont ( 62 );
mssm->AddText("m_{H}=120");
mssm->Draw();
if(log){
if(scaled) canv->Print("etau_rescaled_novbf_LOG.pdf"); else canv->Print("etau_unscaled_novbf_LOG.pdf");
if(scaled) canv->Print("etau_rescaled_novbf_LOG.png"); else canv->Print("etau_unscaled_novbf_LOG.png");
}
else{
if(scaled) canv->Print("etau_rescaled_novbf.pdf"); else canv->Print("etau_unscaled_novbf.pdf");
if(scaled) canv->Print("etau_rescaled_novbf.png"); else canv->Print("etau_unscaled_novbf.png");
}
}
TCanvas* tdrCanvas(const char* canvName, TH1D *h,
int iPeriod = 2, int iPos = 11,
bool square = kRectangular) {
setTDRStyle();
//writeExtraText = true; // if extra text
//extraText = "Preliminary"; // default extra text is "Preliminary"
//lumi_8TeV = "19.5 fb^{-1}"; // default is "19.7 fb^{-1}"
//lumi_7TeV = "5.0 fb^{-1}"; // default is "5.1 fb^{-1}"
//int iPeriod = 3; // 1=7TeV, 2=8TeV, 3=7+8TeV, 7=7+8+13TeV
// second parameter in example_plot is iPos, which drives the position of the CMS logo in the plot
// iPos=11 : top-left, left-aligned
// iPos=33 : top-right, right-aligned
// iPos=22 : center, centered
// iPos=0 : out of frame (in exceptional cases)
// mode generally :
// iPos = 10*(alignement 1/2/3) + position (1/2/3 = left/center/right)
// if( iPos==0 ) relPosX = 0.12;
int W = (square ? 600 : 800);
int H = (square ? 600 : 600);
//
// Simple example of macro: plot with CMS name and lumi text
// (this script does not pretend to work in all configurations)
// iPeriod = 1*(0/1 7 TeV) + 2*(0/1 8 TeV) + 4*(0/1 13 TeV)
// For instance:
// iPeriod = 3 means: 7 TeV + 8 TeV
// iPeriod = 7 means: 7 TeV + 8 TeV + 13 TeV
// Initiated by: Gautier Hamel de Monchenault (Saclay)
//
int W_ref = (square ? 600 : 800);
int H_ref = (square ? 600 : 600);
// references for T, B, L, R
//float T = (square ? 0.07*H_ref : 0.08*H_ref);
float T = (square ? 0.07*H_ref : 0.08*H_ref);
//float B = (square ? 0.13*H_ref : 0.12*H_ref);
float B = (square ? 0.1*H_ref : 0.12*H_ref);
//float L = (square ? 0.15*W_ref : 0.12*W_ref);
float L = (square ? 0.12*W_ref : 0.12*W_ref);
//float R = (square ? 0.05*W_ref : 0.04*W_ref);
float R = (square ? 0.17*W_ref : 0.04*W_ref);
TCanvas *canv = new TCanvas(canvName,canvName,50,50,W,H);
canv->SetFillColor(0);
canv->SetBorderMode(0);
canv->SetFrameFillStyle(0);
canv->SetFrameBorderMode(0);
canv->SetLeftMargin( L/W );
canv->SetRightMargin( R/W );
canv->SetTopMargin( T/H );
canv->SetBottomMargin( B/H );
// FOR JEC plots, prefer to keep ticks on both sides
//canv->SetTickx(0);
//canv->SetTicky(0);
assert(h);
h->GetYaxis()->SetTitleOffset(square ? 1.25 : 1);
h->GetXaxis()->SetTitleOffset(square ? 1.0 : 0.9);
h->Draw("AXIS");
// writing the lumi information and the CMS "logo"
CMS_lumi( canv, iPeriod, iPos );
canv->Update();
canv->RedrawAxis();
canv->GetFrame()->Draw();
return canv;
}
void bbtt_upg_em(std::string var,int nbins, double xmin, double xmax,std::string xtitle, std::string ytitle, double sigscale=1)
{
TFile *outDC = new TFile("hh_em_inputs.root","RECREATE");
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
TH1::SetDefaultSumw2(1);
//std::string dir = "/data/blue/Bacon/029a/Upgrade/merged_talk_jun30/";
std::string dir = "/afs/cern.ch/work/j/jlawhorn/public/ntuples/";
std::stringstream scale; scale << sigscale;
//Cut definitions
double luminosity = 3000;
std::stringstream lumi; lumi << luminosity;
std::string objcut = "(tauCat1==3 && tauCat2==2 && ptTau1>20 && ptTau2>20 && tauIso2<0.4 && tauIso1<0.4 && (bTag1==2||bTag1==3||bTag1==6||bTag1==7) && (bTag2==1||bTag2==3||bTag2==6||bTag2==7) && ptB1>20 && ptB2>20 && sqrt( (etaTau1-etaTau2)**2 + (phiTau1-phiTau2)**2 )>0.4)";
std::string jetcut = objcut+"*(mTT>20 && mTT<90)*(mBB1>70 && mBB1<140)*(mt2pileup>100)*(bdtVal>-0.05)";
//signal region
std::string mccut = jetcut+"*eventWeight*"+lumi.str();
std::string sigcut = jetcut+"*eventWeight*"+lumi.str();
std::string zjetcut = jetcut+"*eventWeight*(eventType==4)*"+lumi.str();
std::string wjetcut = jetcut+"*eventWeight*(eventType==3)*"+lumi.str();
std::string ewkcut = jetcut+"*eventWeight*(eventType!=1)*"+lumi.str();
//--------------------------------------------------------------------------
//Get the trees
TTree *hhtree = load(dir+"HHToTTBB_14TeV.root");
TTree *tttree = load(dir+"tt.root");
//TTree *vbfhtree = load(dir+"VBFToTT_14TeV_phase2.root");
//TTree *gfhtree = load(dir+"H.root");
//TTree *vjettree = load(dir+"Vjets.root");
//TTree *ewktree = load(dir+"diboson.root");
//-------------------------------------------------------------------------
//Get histograms
TCanvas *canv0 = MakeCanvas("canv", "histograms", 600, 600);
canv0->cd();
std::string vardraw;
/* TH1F *Ztt = new TH1F("DY","",nbins,xmin,xmax);
vardraw = var+">>"+"DY";
vjettree->Draw(vardraw.c_str(),zjetcut.c_str());
InitHist(Ztt , xtitle.c_str(), ytitle.c_str(), TColor::GetColor(248,206,104), 1001);*/
TH1F *ttbar = new TH1F("TTbar","",nbins,xmin,xmax);
vardraw = var+">>"+"TTbar";
tttree->Draw(vardraw.c_str(),mccut.c_str());
InitHist(ttbar, xtitle.c_str(), ytitle.c_str(), TColor::GetColor(155,152,204), 1001);
/* TH1F *wjets = new TH1F("Wjets","",nbins,xmin,xmax);
vardraw = var+">>"+"Wjets";
vjettree->Draw(vardraw.c_str(),wjetcut.c_str());
InitHist(wjets, xtitle.c_str(), ytitle.c_str(), TColor::GetColor(222,90,106), 1001);
TH1F *ewk = new TH1F("Ewk","",nbins,xmin,xmax);
vardraw = var+">>"+"Ewk";
ewktree->Draw(vardraw.c_str(),ewkcut.c_str());
InitHist(ewk, xtitle.c_str(), ytitle.c_str(), TColor::GetColor(222,90,106), 1001);
TH1F *vbfh = new TH1F("VBFH","",nbins,xmin,xmax);
vardraw = var+">>"+"VBFH";
vbfhtree->Draw(vardraw.c_str(),mccut.c_str());
InitHist(vbfh, xtitle.c_str(), ytitle.c_str(), TColor::GetColor(250,202,255), 1001);
TH1F *ggh = new TH1F("GGH","",nbins,xmin,xmax);
vardraw = var+">>"+"GGH";
gfhtree->Draw(vardraw.c_str(),mccut.c_str());
InitHist(ggh, xtitle.c_str(), ytitle.c_str(), TColor::GetColor(250,202,255), 1001);*/
TH1F *smhh = new TH1F("SMhh","",nbins,xmin,xmax);
vardraw = var+">>"+"SMhh";
hhtree->Draw(vardraw.c_str(),sigcut.c_str());
InitSignal(smhh);
smhh->SetLineColor(kBlack);
delete canv0;
//---------------------------------------------------------------------------
//Print out the yields
Double_t error=999;
//ofstream outfile;
//outfile.open("yields.txt");
//outfile << "Yields for the signal region." << std::endl;
cout << "SM hh " << smhh->IntegralAndError(0,smhh->GetNbinsX(),error) << "+/-";
cout << error << endl; error=999;
/* outfile << "SM h " << smhh->IntegralAndError(0,smhh->GetNbinsX(),error) << "+/-" << error << endl;
outfile << "Ztt " << Ztt->IntegralAndError(0,Ztt->GetNbinsX(),error) << "+/-" << error << endl;*/
cout << "ttbar " << ttbar->IntegralAndError(0,ttbar->GetNbinsX(),error) << "+/-";
cout << error << endl; error=999;
/* outfile << "ewk " << ewk->IntegralAndError(0,ewk->GetNbinsX(),error) << "+/-" << error << endl;
outfile << "wjets " << wjets->IntegralAndError(0,wjets->GetNbinsX(),error) << "+/-" << error << endl;*/
//--------------------------------------------------------------------------
//outfile.close();
outDC->cd();
TDirectory* lTD = outDC->mkdir("emu");
outDC->cd(lTD->GetPath());
ttbar->SetName("data_obs");
ttbar->SetTitle("data_obs");
ttbar->Write();
/*Ztt->SetName("ZTT");
Ztt->SetTitle("ZTT");
Ztt->Write();*/
ttbar->SetName("TT");
ttbar->SetTitle("TT");
ttbar->Write();
/*wjets->SetName("W");
wjets->SetTitle("W");
wjets->Write();
ewk->SetName("VV");
ewk->SetTitle("VV");
ewk->Write();
vbfh->SetName("qqH");
vbfh->SetTitle("qqH");
vbfh->Write();
ggh->SetName("ggH");
ggh->SetTitle("ggH");
ggh->Write();*/
smhh->SetName("ggHH");
smhh->SetTitle("ggHH");
smhh->Write();
outDC->Close();
//stack some histtograms together
//vbfh->Add(ggh);
//wjets->Add(ewk);
//-----------------------------------------------------------------------
smhh->Scale(sigscale);
//Draw the histograms
TCanvas *canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
//wjets->Add(ttbar); //Ztt->Add(wjets);
//vbfh->Add(Ztt);
//Error band stat
//TH1F* errorBand = (TH1F*)vbfh ->Clone("errorBand");
TH1F* errorBand = (TH1F*)ttbar ->Clone("errorBand");
errorBand ->SetMarkerSize(0);
errorBand ->SetFillColor(13);
errorBand ->SetFillStyle(3013);
errorBand ->SetLineWidth(1);
// for(int idx=0; idx<errorBand->GetNbinsX(); ++idx){
// if(errorBand->GetBinContent(idx)>0){
// std::cout << "Uncertainties on summed background samples: " << errorBand->GetBinError(idx)/errorBand->GetBinContent(idx) << std::endl;
// break;
// }
//}
ttbar->SetMaximum(1.1*std::max(maximum(ttbar, 0), maximum(smhh, 0)));
//blind(data,75,150);
//data->Draw("e");
//vbfh->Draw("hist");
//Ztt->Draw("histsame");
//wjets->Draw("histsame");
//ttbar->Draw("histsame");
ttbar->SetTitle("");
ttbar->Draw("hist");
//data->Draw("esame");
errorBand->Draw("e2same");
smhh->Draw("histsame");
canv->RedrawAxis();
//canv->SetLogy(1);
//---------------------------------------------------------------------------
//Adding a legend
TLegend* leg = new TLegend(0.53, 0.65, 0.95, 0.90);
SetLegendStyle(leg);
leg->AddEntry(smhh , TString::Format("%.0f#timeshh#rightarrow#tau#tau bb", sigscale) , "L" );
//leg->AddEntry(smhh , TString::Format("%.0f#timeshh#rightarrow#tau#tau bb", sigscale1) , "L" );
//leg->AddEntry(data , "Observed" , "LP");
//leg->AddEntry(vbfh , "SM H#rightarrow#tau#tau" , "F" );
//leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
//leg->AddEntry(wjets , "Electroweak" , "F" );
leg->AddEntry(errorBand,"bkg. uncertainty","F");
leg->Draw();
//---------------------------------------------------------------------------
//CMS preliminary
const char* dataset = "CMS Simulation, 3000 fb^{-1} at 14 TeV";
const char* category = "";
CMSPrelim(dataset, "#tau_{e}#tau_{#mu}", 0.17, 0.835);
//CMSPrelim(dataset, "", 0.16, 0.835);
TPaveText* chan = new TPaveText(0.52, 0.35, 0.91, 0.55, "tlbrNDC");
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
chan->AddText(category);
chan->Draw();
//-------------------------------------------------------------------------
//Save histograms
canv->Print((var+"_em.png").c_str());
/*
Ratio Data over MC
*/
/*
TCanvas *canv1 = MakeCanvas("canv0", "histograms", 600, 400);
canv1->SetGridx();
canv1->SetGridy();
canv1->cd();
TH1F* model = (TH1F*)Ztt ->Clone("model");
TH1F* test1 = (TH1F*)vbfh->Clone("test1");
for(int ibin=0; ibin<test1->GetNbinsX(); ++ibin){
//the small value in case of 0 entries in the model is added to prevent the chis2 test from failing
model->SetBinContent(ibin+1, model->GetBinContent(ibin+1)>0 ? model->GetBinContent(ibin+1)*model->GetBinWidth(ibin+1) : 0.01);
//model->SetBinError (ibin+1, CONVERVATIVE_CHI2 ? 0. : model->GetBinError (ibin+1)*model->GetBinWidth(ibin+1));
model->SetBinError (ibin+1, 0);
test1->SetBinContent(ibin+1, test1->GetBinContent(ibin+1)*test1->GetBinWidth(ibin+1));
test1->SetBinError (ibin+1, test1->GetBinError (ibin+1)*test1->GetBinWidth(ibin+1));
}
double chi2prob = test1->Chi2Test (model,"PUW"); std::cout << "chi2prob:" << chi2prob << std::endl;
double chi2ndof = test1->Chi2Test (model,"CHI2/NDFUW"); std::cout << "chi2ndf :" << chi2ndof << std::endl;
double ksprob = test1->KolmogorovTest(model); std::cout << "ksprob :" << ksprob << std::endl;
double ksprobpe = test1->KolmogorovTest(model,"DX"); std::cout << "ksprobpe:" << ksprobpe << std::endl;
std::vector<double> edges;
TH1F* zero = (TH1F*)ttbar->Clone("zero"); zero->Clear();
TH1F* rat1 = (TH1F*)vbfh->Clone("rat1");
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
rat1->SetBinContent(ibin+1, Ztt->GetBinContent(ibin+1)>0 ? vbfh->GetBinContent(ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
rat1->SetBinError (ibin+1, Ztt->GetBinContent(ibin+1)>0 ? vbfh->GetBinError (ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
zero->SetBinContent(ibin+1, 0.);
zero->SetBinError (ibin+1, Ztt->GetBinContent(ibin+1)>0 ? Ztt ->GetBinError (ibin+1)/Ztt->GetBinContent(ibin+1) : 0);
}
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
if(rat1->GetBinContent(ibin+1)>0){
edges.push_back(TMath::Abs(rat1->GetBinContent(ibin+1)-1.)+TMath::Abs(rat1->GetBinError(ibin+1)));
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
}
}
float range = 0.1;
std::sort(edges.begin(), edges.end());
if (edges[edges.size()-2]>0.1) { range = 0.2; }
if (edges[edges.size()-2]>0.2) { range = 0.5; }
if (edges[edges.size()-2]>0.5) { range = 1.0; }
if (edges[edges.size()-2]>1.0) { range = 1.5; }
if (edges[edges.size()-2]>1.5) { range = 2.0; }
rat1->SetLineColor(kBlack);
rat1->SetFillColor(kGray );
rat1->SetMaximum(+range);
rat1->SetMinimum(-range);
rat1->GetYaxis()->CenterTitle();
rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
rat1->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
rat1->Draw();
zero->SetFillStyle( 3013);
zero->SetFillColor(kBlack);
zero->SetLineColor(kBlack);
zero->SetMarkerSize(0.1);
zero->Draw("e2histsame");
canv1->RedrawAxis();
TPaveText* stat1 = new TPaveText(0.20, 0.76+0.061, 0.32, 0.76+0.161, "NDC");
stat1->SetBorderSize( 0 );
stat1->SetFillStyle( 0 );
stat1->SetTextAlign( 12 );
stat1->SetTextSize ( 0.05 );
stat1->SetTextColor( 1 );
stat1->SetTextFont ( 62 );
stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f", chi2ndof, chi2prob));
//stat1->AddText(TString::Format("#chi^{2}/ndf=%.3f, P(#chi^{2})=%.3f, P(KS)=%.3f", chi2ndof, chi2prob, ksprob));
//stat1->Draw();
canv1->Print((var+"_ratio.png").c_str());
*/
}
TCanvas* example_plot( int iPeriod, int iPos )
{
// if( iPos==0 ) relPosX = 0.12;
int W = 800;
int H = 600;
//
// Simple example of macro: plot with CMS name and lumi text
// (this script does not pretend to work in all configurations)
// iPeriod = 1*(0/1 7 TeV) + 2*(0/1 8 TeV) + 4*(0/1 13 TeV)
// For instance:
// iPeriod = 3 means: 7 TeV + 8 TeV
// iPeriod = 7 means: 7 TeV + 8 TeV + 13 TeV
// Initiated by: Gautier Hamel de Monchenault (Saclay)
// Updated by: Dinko Ferencek (Rutgers)
//
int H_ref = 600;
int W_ref = 800;
// references for T, B, L, R
float T = 0.08*H_ref;
float B = 0.12*H_ref;
float L = 0.12*W_ref;
float R = 0.04*W_ref;
TString canvName = "FigExample_";
canvName += W;
canvName += "-";
canvName += H;
canvName += "_";
canvName += iPeriod;
if( writeExtraText ) canvName += "-prelim";
if( iPos%10==0 ) canvName += "-out";
else if( iPos%10==1 ) canvName += "-left";
else if( iPos%10==2 ) canvName += "-center";
else if( iPos%10==3 ) canvName += "-right";
TCanvas* canv = new TCanvas(canvName,canvName,50,50,W,H);
canv->SetFillColor(0);
canv->SetBorderMode(0);
canv->SetFrameFillStyle(0);
canv->SetFrameBorderMode(0);
canv->SetLeftMargin( L/W );
canv->SetRightMargin( R/W );
canv->SetTopMargin( T/H );
canv->SetBottomMargin( B/H );
canv->SetTickx(0);
canv->SetTicky(0);
TH1* h = new TH1F("h","h",40,70,110);
h->GetXaxis()->SetNdivisions(6,5,0);
h->GetXaxis()->SetTitle("m_{e^{+}e^{-}} (GeV)");
h->GetYaxis()->SetNdivisions(6,5,0);
h->GetYaxis()->SetTitleOffset(1);
h->GetYaxis()->SetTitle("Events / 0.5 GeV");
h->SetMaximum( 260 );
if( iPos==1 ) h->SetMaximum( 300 );
h->Draw();
int histLineColor = kOrange+7;
int histFillColor = kOrange-2;
float markerSize = 1.0;
{
TLatex latex;
int n_ = 2;
float x1_l = 0.92;
float y1_l = 0.60;
float dx_l = 0.30;
float dy_l = 0.18;
float x0_l = x1_l-dx_l;
float y0_l = y1_l-dy_l;
TPad* legend = new TPad("legend_0","legend_0",x0_l,y0_l,x1_l, y1_l );
// legend->SetFillColor( kGray );
legend->Draw();
legend->cd();
float ar_l = dy_l/dx_l;
float x_l[1];
float ex_l[1];
float y_l[1];
float ey_l[1];
// float gap_ = 0.09/ar_l;
float gap_ = 1./(n_+1);
float bwx_ = 0.12;
float bwy_ = gap_/1.5;
x_l[0] = 1.2*bwx_;
// y_l[0] = 1-(1-0.10)/ar_l;
y_l[0] = 1-gap_;
ex_l[0] = 0;
ey_l[0] = 0.04/ar_l;
TGraph* gr_l = new TGraphErrors(1, x_l, y_l, ex_l, ey_l );
gStyle->SetEndErrorSize(0);
gr_l->SetMarkerSize(0.9);
gr_l->Draw("0P");
latex.SetTextFont(42);
latex.SetTextAngle(0);
latex.SetTextColor(kBlack);
latex.SetTextSize(0.25);
latex.SetTextAlign(12);
TLine line_;
TBox box_;
float xx_ = x_l[0];
float yy_ = y_l[0];
latex.DrawLatex(xx_+1.*bwx_,yy_,"Data");
yy_ -= gap_;
box_.SetLineStyle( kSolid );
box_.SetLineWidth( 1 );
// box_.SetLineColor( kBlack );
box_.SetLineColor( histLineColor );
box_.SetFillColor( histFillColor );
box_.DrawBox( xx_-bwx_/2, yy_-bwy_/2, xx_+bwx_/2, yy_+bwy_/2 );
box_.SetFillStyle(0);
box_.DrawBox( xx_-bwx_/2, yy_-bwy_/2, xx_+bwx_/2, yy_+bwy_/2 );
latex.DrawLatex(xx_+1.*bwx_,yy_,"Z #rightarrow e^{+}e^{-} (MC)");
canv->cd();
}
{
// Observed data
TFile file_("histo.root","READ");
TH1F *data = static_cast<TH1F*>(file_.Get("data")->Clone());
data->SetDirectory(0);
data->SetMarkerStyle(20);
data->SetMarkerSize(markerSize);
TH1F *MC = static_cast<TH1F*>(file_.Get("MC")->Clone());
MC->SetDirectory(0);
MC->SetLineColor(histLineColor);
MC->SetFillColor(histFillColor);
MC->Draw("histsame");
data->Draw("esamex0");
file_.Close();
}
// writing the lumi information and the CMS "logo"
CMS_lumi( canv, iPeriod, iPos );
canv->Update();
canv->RedrawAxis();
canv->GetFrame()->Draw();
canv->Print(canvName+".pdf",".pdf");
canv->Print(canvName+".png",".png");
return canv;
}
void xsecSummary()
{
//--------------------------------------------------------------------------------------------------------------
// input parameter
const Double_t xsec_wp = 11356; const Double_t xsec_wp_stat = 9; const Double_t xsec_wp_sys = 197; const Double_t xsec_wp_lumi = 307;
const Double_t xsec_wm = 8284; const Double_t xsec_wm_stat = 8; const Double_t xsec_wm_sys = 124; const Double_t xsec_wm_lumi = 224;
const Double_t xsec_w = 19708; const Double_t xsec_w_stat = 11; const Double_t xsec_w_sys = 265; const Double_t xsec_w_lumi = 532;
const Double_t xsec_z = 1904; const Double_t xsec_z_stat = 1; const Double_t xsec_z_sys = 30; const Double_t xsec_z_lumi = 51;
const Double_t xsec_wr = 1.372; const Double_t xsec_wr_stat = 0.002; const Double_t xsec_wr_sys = 0.022;
const Double_t xsec_wpr= 5.966; const Double_t xsec_wpr_stat= 0.006; const Double_t xsec_wpr_sys= 0.100;
const Double_t xsec_wmr= 4.351; const Double_t xsec_wmr_stat= 0.005; const Double_t xsec_wmr_sys= 0.069;
const Double_t xsec_wz = 10.330; const Double_t xsec_wz_stat = 0.009; const Double_t xsec_wz_sys = 0.147;
const Double_t theo_wp = 11328.8; const Double_t theo_wp_unc = (268.75+323.94)/2.;
const Double_t theo_wm = 8369.09; const Double_t theo_wm_unc = (213.11+244.29)/2.;
const Double_t theo_w = 19697.6; const Double_t theo_w_unc = (473.95+563.48)/2.;
const Double_t theo_z = 1867.66; const Double_t theo_z_unc = (43.49+47.36)/2.;
const Double_t theo_wr = 1.35367; const Double_t theo_wr_unc = (0.0123+0.01054)/2.;
const Double_t theo_wpr= 6.06494; const Double_t theo_wpr_unc= (0.04716+0.04361)/2.;
const Double_t theo_wmr= 4.48044; const Double_t theo_wmr_unc= (0.01779+0.02685)/2.;
const Double_t theo_wz = 10.54538; const Double_t theo_wz_unc = (0.06495+0.07046)/2.;
const Double_t ratio_wp = xsec_wp/theo_wp; const Double_t ratio_wp_the = theo_wp_unc*xsec_wp/(theo_wp*theo_wp);
const Double_t ratio_wp_exp = sqrt(xsec_wp_stat*xsec_wp_stat+xsec_wp_sys*xsec_wp_sys)/(theo_wp);
const Double_t ratio_wm = xsec_wm/theo_wm; const Double_t ratio_wm_the = theo_wm_unc*xsec_wm/(theo_wm*theo_wm);
const Double_t ratio_wm_exp = sqrt(xsec_wm_stat*xsec_wm_stat+xsec_wm_sys*xsec_wm_sys)/(theo_wm);
const Double_t ratio_w = xsec_w/theo_w; const Double_t ratio_w_the = theo_w_unc*xsec_w/(theo_w*theo_w);
const Double_t ratio_w_exp = sqrt(xsec_w_stat*xsec_w_stat+xsec_w_sys*xsec_w_sys)/(theo_w);
const Double_t ratio_z = xsec_z/theo_z; const Double_t ratio_z_the = theo_z_unc*xsec_z/(theo_z*theo_z);
const Double_t ratio_z_exp = sqrt(xsec_z_stat*xsec_z_stat+xsec_z_sys*xsec_z_sys)/(theo_z);
const Double_t ratio_wr = xsec_wr/theo_wr; const Double_t ratio_wr_the = theo_wr_unc*xsec_wr/(theo_wr*theo_wr);
const Double_t ratio_wr_exp = sqrt(xsec_wr_stat*xsec_wr_stat+xsec_wr_sys*xsec_wr_sys)/(theo_wr);
const Double_t ratio_wpr = xsec_wpr/theo_wpr; const Double_t ratio_wpr_the= theo_wpr_unc*xsec_wpr/(theo_wpr*theo_wpr);
const Double_t ratio_wpr_exp= sqrt(xsec_wpr_stat*xsec_wpr_stat+xsec_wpr_sys*xsec_wpr_sys)/(theo_wpr);
const Double_t ratio_wmr = xsec_wmr/theo_wmr; const Double_t ratio_wmr_the = theo_wmr_unc*xsec_wmr/(theo_wmr*theo_wmr);
const Double_t ratio_wmr_exp= sqrt(xsec_wmr_stat*xsec_wmr_stat+xsec_wmr_sys*xsec_wmr_sys)/(theo_wmr);
const Double_t ratio_wz = xsec_wz/theo_wz; const Double_t ratio_wz_the = theo_wz_unc*xsec_wz/(theo_wz*theo_wz);
const Double_t ratio_wz_exp = sqrt(xsec_wz_stat*xsec_wz_stat+xsec_wz_sys*xsec_wz_sys)/(theo_wz);
Double_t test = sqrt(xsec_wp_stat*xsec_wp_stat+xsec_wp_sys*xsec_wp_sys)/(xsec_wp);
//==============================================================================================================
//--------------------------------------------------------------------------------------------------------------
// plotting parameter
Double_t yshift, ydrift; // used for point and error bar
yshift = 3.75;
ydrift = -0.245;
Double_t td, tp, tw; // used for text
td = 0.025;
tp = 0.708;
tw = 0.035;
Double_t range_max, range_min;
//range_min = 0.82;
//range_max = 1.27;
range_min = 0.82;
range_max = 1.25;
Int_t expColor, theColor; // colors used
Int_t prodColor, decayColor, cmbColor; // colors used
expColor = kBlue;
theColor = kGreen+2;
prodColor = kBlue+2;
decayColor= kRed+2;
cmbColor = kBlack;
//==============================================================================================================
//--------------------------------------------------------------------------------------------------------------
// make plots
TCanvas *c = MakeCanvas("c","c",800,600);
c->SetTickx(1);
c->SetTicky(0);
c->SetFrameFillStyle(0);
c->SetFrameLineWidth(2);
c->SetFrameBorderMode(0);
c->SetLeftMargin(0.07);
gStyle->SetEndErrorSize(8);
Double_t xval, errl, errh, yval;
xval = ratio_wp;
yval = yshift+0*ydrift;
errl = ratio_wp_exp;
errh = sqrt(ratio_wp_exp*ratio_wp_exp+ratio_wp_the*ratio_wp_the);
TGraphAsymmErrors grWP(1,&xval,&yval,&errl,&errl,0,0);
grWP.SetTitle("");
grWP.GetXaxis()->SetTitle("");
grWP.GetXaxis()->SetTitleSize(0.05);
grWP.GetYaxis()->SetTitle("");
grWP.GetYaxis()->SetRangeUser(0,5);
grWP.GetXaxis()->SetLimits(range_min,range_max);
grWP.GetXaxis()->SetNdivisions(506);
grWP.GetYaxis()->SetNdivisions(0);
grWP.SetMarkerStyle(kFullCircle);
grWP.SetMarkerSize(1);
grWP.SetLineWidth(2);
grWP.SetMarkerColor(kBlack);
grWP.SetLineColor(expColor);
grWP.Draw("AP");
// lumi uncertainty band
TBox lumi_box(0.973,yshift+7.*ydrift,1.027,3.98);
//TBox lumi_box(0.974,yshift+7.*ydrift,1.026,3.98);
lumi_box.SetLineColor(796);
lumi_box.SetFillColor(796);
lumi_box.Draw();
c->RedrawAxis();
TLine theory_line(1,0.02,1,3.98);
theory_line.SetLineColor(kRed);
theory_line.SetLineStyle(1);
theory_line.SetLineWidth(3);
theory_line.Draw();
TGraphAsymmErrors grWP2(1,&xval,&yval,&errh,&errh,0,0);
grWP2.SetMarkerStyle(kFullCircle);
grWP2.SetMarkerSize(1);
grWP2.SetLineWidth(2);
grWP2.SetMarkerColor(kBlack);
grWP2.SetLineColor(theColor);
grWP2.Draw("EPSAME");
grWP.Draw("EPSAME");
xval = ratio_wm;
yval = yshift+2*ydrift;
errl = ratio_wm_exp;
errh = sqrt(ratio_wm_exp*ratio_wm_exp+ratio_wm_the*ratio_wm_the);
TGraphAsymmErrors grWM(1,&xval,&yval,&errl,&errl,0,0);
grWM.SetMarkerStyle(kFullCircle);
grWM.SetMarkerSize(1);
grWM.SetLineWidth(2);
grWM.SetMarkerColor(kBlack);
grWM.SetLineColor(expColor);
TGraphAsymmErrors grWM2(1,&xval,&yval,&errh,&errh,0,0);
grWM2.SetMarkerStyle(kFullCircle);
grWM2.SetMarkerSize(1);
grWM2.SetLineWidth(2);
grWM2.SetMarkerColor(kBlack);
grWM2.SetLineColor(theColor);
grWM2.Draw("EPSAME");
grWM.Draw("EPSAME");
xval = ratio_w;
yval = yshift+4*ydrift;
errl = ratio_w_exp;
errh = sqrt(ratio_w_exp*ratio_w_exp+ratio_w_the*ratio_w_the);
TGraphAsymmErrors grW(1,&xval,&yval,&errl,&errl,0,0);
grW.SetMarkerStyle(kFullCircle);
grW.SetMarkerSize(1);
grW.SetLineWidth(2);
grW.SetMarkerColor(kBlack);
grW.SetLineColor(expColor);
TGraphAsymmErrors grW2(1,&xval,&yval,&errh,&errh,0,0);
grW2.SetMarkerStyle(kFullCircle);
grW2.SetMarkerSize(1);
grW2.SetLineWidth(2);
grW2.SetMarkerColor(kBlack);
grW2.SetLineColor(theColor);
grW2.Draw("EPSAME");
grW.Draw("EPSAME");
xval = ratio_z;
yval = yshift+6*ydrift;
errl = ratio_z_exp;
errh = sqrt(ratio_z_exp*ratio_z_exp+ratio_z_the*ratio_z_the);
TGraphAsymmErrors grZ(1,&xval,&yval,&errl,&errl,0,0);
grZ.SetMarkerSize(1);
grZ.SetLineWidth(2);
grZ.SetMarkerColor(kBlack);
grZ.SetLineColor(expColor);
TGraphAsymmErrors grZ2(1,&xval,&yval,&errh,&errh,0,0);
grZ2.SetMarkerStyle(kFullCircle);
grZ2.SetMarkerSize(1);
grZ2.SetLineWidth(2);
grZ2.SetMarkerColor(kBlack);
grZ2.SetLineColor(theColor);
grZ2.Draw("EPSAME");
grZ.Draw("EPSAME");
xval = ratio_wr;
yval = yshift+8*ydrift;
errl = ratio_wr_exp;
errh = sqrt(ratio_wr_exp*ratio_wr_exp+ratio_wr_the*ratio_wr_the);
TGraphAsymmErrors grWR(1,&xval,&yval,&errl,&errl,0,0);
grWR.SetMarkerStyle(kFullCircle);
grWR.SetMarkerSize(1);
grWR.SetLineWidth(2);
grWR.SetMarkerColor(kBlack);
grWR.SetLineColor(expColor);
TGraphAsymmErrors grWR2(1,&xval,&yval,&errh,&errh,0,0);
grWR2.SetMarkerStyle(kFullCircle);
grWR2.SetMarkerSize(1);
grWR2.SetLineWidth(2);
grWR2.SetMarkerColor(kBlack);
grWR2.SetLineColor(theColor);
grWR2.Draw("EPSAME");
grWR.Draw("EPSAME");
xval = ratio_wpr;
yval = yshift+10*ydrift;
errl = ratio_wpr_exp;
errh = sqrt(ratio_wpr_exp*ratio_wpr_exp+ratio_wpr_the*ratio_wpr_the);
TGraphAsymmErrors grWPR(1,&xval,&yval,&errl,&errl,0,0);
grWPR.SetMarkerStyle(kFullCircle);
grWPR.SetMarkerSize(1);
grWPR.SetLineWidth(2);
grWPR.SetMarkerColor(kBlack);
grWPR.SetLineColor(expColor);
TGraphAsymmErrors grWPR2(1,&xval,&yval,&errh,&errh,0,0);
grWPR2.SetMarkerStyle(kFullCircle);
grWPR2.SetMarkerSize(1);
grWPR2.SetLineWidth(2);
grWPR2.SetMarkerColor(kBlack);
grWPR2.SetLineColor(theColor);
grWPR2.Draw("EPSAME");
grWPR.Draw("EPSAME");
xval = ratio_wmr;
yval = yshift+12*ydrift;
errl = ratio_wmr_exp;
errh = sqrt(ratio_wmr_exp*ratio_wmr_exp+ratio_wmr_the*ratio_wmr_the);
TGraphAsymmErrors grWMR(1,&xval,&yval,&errl,&errl,0,0);
grWMR.SetMarkerStyle(kFullCircle);
grWMR.SetMarkerSize(1);
grWMR.SetLineWidth(2);
grWMR.SetMarkerColor(kBlack);
grWMR.SetLineColor(expColor);
TGraphAsymmErrors grWMR2(1,&xval,&yval,&errh,&errh,0,0);
grWMR2.SetMarkerStyle(kFullCircle);
grWMR2.SetMarkerSize(1);
grWMR2.SetLineWidth(2);
grWMR2.SetMarkerColor(kBlack);
grWMR2.SetLineColor(theColor);
grWMR2.Draw("EPSAME");
grWMR.Draw("EPSAME");
xval = ratio_wz;
yval = yshift+14*ydrift;
errl = ratio_wz_exp;
errh = sqrt(ratio_wz_exp*ratio_wz_exp+ratio_wz_the*ratio_wz_the);
TGraphAsymmErrors grWZ(1,&xval,&yval,&errl,&errl,0,0);
grWZ.SetMarkerStyle(kFullCircle);
grWZ.SetMarkerSize(1);
grWZ.SetLineWidth(2);
grWZ.SetMarkerColor(kBlack);
grWZ.SetLineColor(expColor);
TGraphAsymmErrors grWZ2(1,&xval,&yval,&errh,&errh,0,0);
grWZ2.SetMarkerStyle(kFullCircle);
grWZ2.SetMarkerSize(1);
grWZ2.SetLineWidth(2);
grWZ2.SetMarkerColor(kBlack);
grWZ2.SetLineColor(theColor);
grWZ2.Draw("EPSAME");
grWZ.Draw("EPSAME");
// legend
xval = range_min+(0.06*(range_max-range_min));
yval = 4.6;
errl = 0.015*(range_max-range_min);
errh = 0.03*(range_max-range_min);
TGraphAsymmErrors grLeg(1,&xval,&yval,&errl,&errl,0,0);
grLeg.SetMarkerStyle(kFullCircle);
grLeg.SetMarkerSize(1);
grLeg.SetLineWidth(2);
grLeg.SetMarkerColor(kBlack);
grLeg.SetLineColor(expColor);
TGraphAsymmErrors grLeg2(1,&xval,&yval,&errh,&errh,0,0);
grLeg2.SetMarkerStyle(kFullCircle);
grLeg2.SetMarkerSize(1);
grLeg2.SetLineWidth(2);
grLeg2.SetMarkerColor(kBlack);
grLeg2.SetLineColor(theColor);
grLeg2.Draw("EPSAME");
grLeg.Draw("EPSAME");
TPaveText tb4(0.14,0.84,0.6,0.875,"NDC");
tb4.SetFillStyle(0);
tb4.SetBorderSize(0);
tb4.SetTextAlign(12);
tb4.AddText("Observation, uncertainty (exp., exp. #oplus theory)");
tb4.Draw();
TPaveText tb6(0.14,0.795,0.6,0.83,"NDC");
tb6.SetFillStyle(0);
tb6.SetBorderSize(0);
tb6.SetTextAlign(12);
tb6.AddText("Uncertainty (lumi)");
tb6.Draw();
TBox exp_box_leg2(range_min+(0.04*(range_max-range_min)),4.18,range_min+(0.08*(range_max-range_min)),4.38);
exp_box_leg2.SetLineColor(796);
exp_box_leg2.SetFillColor(796);
exp_box_leg2.Draw();
// split lines
TLine split_line0(range_min,yshift+1*ydrift,range_max,yshift+1*ydrift);
split_line0.SetLineColor(kBlack);
split_line0.SetLineStyle(2);
split_line0.SetLineWidth(1);
split_line0.Draw();
TLine split_line1(range_min,yshift+3*ydrift,range_max,yshift+3*ydrift);
split_line1.SetLineColor(kBlack);
split_line1.SetLineStyle(2);
split_line1.SetLineWidth(1);
split_line1.Draw();
TLine split_line2(range_min,yshift+5*ydrift,range_max,yshift+5*ydrift);
split_line2.SetLineColor(kBlack);
split_line2.SetLineStyle(2);
split_line2.SetLineWidth(1);
split_line2.Draw();
TLine split_line3(range_min,yshift+7*ydrift,range_max,yshift+7*ydrift);
split_line3.SetLineColor(kBlack);
split_line3.SetLineStyle(2);
split_line3.SetLineWidth(1);
split_line3.Draw();
TLine split_line4(range_min,yshift+9*ydrift,range_max,yshift+9*ydrift);
split_line4.SetLineColor(kBlack);
split_line4.SetLineStyle(2);
split_line4.SetLineWidth(1);
split_line4.Draw();
TLine split_line5(range_min,yshift+11*ydrift,range_max,yshift+11*ydrift);
split_line5.SetLineColor(kBlack);
split_line5.SetLineStyle(2);
split_line5.SetLineWidth(1);
split_line5.Draw();
TLine split_line6(range_min,yshift+13*ydrift,range_max,yshift+13*ydrift);
split_line6.SetLineColor(kBlack);
split_line6.SetLineStyle(2);
split_line6.SetLineWidth(1);
split_line6.Draw();
TLine split_line7(range_min,yshift+(-1)*ydrift,range_max,yshift+(-1)*ydrift);
split_line7.SetLineColor(kBlack);
split_line7.SetLineStyle(2);
split_line7.SetLineWidth(1);
split_line7.Draw();
TPaveText tb1(0.08,0.93,0.34,0.99,"NDC");
tb1.SetFillStyle(0);
tb1.SetBorderSize(0);
tb1.SetTextAlign(12);
tb1.AddText("#bf{CMS}");
tb1.Draw();
TPaveText tb2(0.75,0.93,0.95,0.99,"NDC");
tb2.SetFillStyle(0);
tb2.SetBorderSize(0);
tb2.SetTextAlign(12);
tb2.AddText("2.3 fb^{-1} (13 TeV)");
tb2.Draw();
TPaveText tb3(0.6,0.83,0.95,0.88,"NDC");
tb3.SetFillStyle(0);
tb3.SetBorderSize(0);
tb3.SetTextAlign(12);
tb3.AddText("Theory: FEWZ (NNLO), NNPDF3.0");
tb3.Draw();
TPaveText tb7(0.6,0.795,0.95,0.83,"NDC");
tb7.SetFillStyle(0);
tb7.SetBorderSize(0);
tb7.SetTextAlign(12);
tb7.AddText("Observation: NNPDF3.0");
tb7.Draw();
TPaveText textwp(0.10,tp-(0*td),0.50,tp+tw-(0*td),"NDC");
textwp.SetFillStyle(0);
textwp.SetBorderSize(0);
textwp.SetTextAlign(12);
textwp.AddText("#bf{W^{+}#rightarrowl^{+}#nu}");
textwp.Draw();
char buffer[200];
Double_t tmp[4];
Double_t tmp2[4];
roundXsec(xsec_wp, xsec_wp_stat, xsec_wp_sys, xsec_wp_lumi, tmp);
sprintf(buffer,"%.0f #pm %.0f_{stat} #pm %.0f_{syst}", tmp[0], tmp[1], tmp[2]);
sprintf(buffer,"%s #pm %.0f_{lum} pb",buffer,tmp[3]);
TPaveText resultwp(0.60,tp-(-0.5*td),1.00,tp+tw-(-0.5*td),"NDC");
resultwp.SetFillStyle(0);
resultwp.SetBorderSize(0);
resultwp.SetTextAlign(12);
resultwp.AddText(buffer);
resultwp.Draw();
roundXsec(theo_wp, theo_wp_unc, tmp2);
sprintf(buffer,"%.0f #pm %.0f pb", tmp2[0], tmp2[1]);
TPaveText theorywp(0.60,tp-(0.6*td),1.00,tp+tw-(0.6*td),"NDC");
theorywp.SetFillStyle(0);
theorywp.SetBorderSize(0);
theorywp.SetTextAlign(12);
theorywp.AddText(buffer);
theorywp.Draw();
TPaveText textwm(0.10,tp-(3*td),0.50,tp+tw-(3*td),"NDC");
textwm.SetFillStyle(0);
textwm.SetBorderSize(0);
textwm.SetTextAlign(12);
textwm.AddText("#bf{W^{-}#rightarrowl^{-}#nu}");
textwm.Draw();
roundXsec(xsec_wm, xsec_wm_stat, xsec_wm_sys,xsec_wm_lumi, tmp);
sprintf(buffer,"%.0f #pm %.0f_{stat} #pm %.0f_{syst}", tmp[0], tmp[1], tmp[2]);
sprintf(buffer,"%s #pm %.0f_{lum} pb",buffer,tmp[3]);
TPaveText resultwm(0.60,tp-(2.5*td),1.00,tp+tw-(2.5*td),"NDC");
resultwm.SetFillStyle(0);
resultwm.SetBorderSize(0);
resultwm.SetTextAlign(12);
resultwm.AddText(buffer);
resultwm.Draw();
roundXsec(theo_wm, theo_wm_unc, tmp2);
sprintf(buffer,"%.0f #pm %.0f pb", tmp2[0], tmp2[1]);
TPaveText theorywm(0.60,tp-(3.6*td),1.00,tp+tw-(3.6*td),"NDC");
theorywm.SetFillStyle(0);
theorywm.SetBorderSize(0);
theorywm.SetTextAlign(12);
theorywm.AddText(buffer);
theorywm.Draw();
TPaveText textw(0.10,tp-(6*td),0.50,tp+tw-(6*td),"NDC");
textw.SetFillStyle(0);
textw.SetBorderSize(0);
textw.SetTextAlign(12);
textw.AddText("#bf{W#rightarrowl#nu}");
textw.Draw();
roundXsec(xsec_w, xsec_w_stat, xsec_w_sys, xsec_w_lumi, tmp);
sprintf(buffer,"%.0f #pm %.0f_{stat} #pm %.0f_{syst}", tmp[0], tmp[1], tmp[2]);
sprintf(buffer,"%s #pm %.0f_{lum} pb",buffer,tmp[3]);
TPaveText resultw(0.60,tp-(5.5*td),1.00,tp+tw-(5.5*td),"NDC");
resultw.SetFillStyle(0);
resultw.SetBorderSize(0);
resultw.SetTextAlign(12);
resultw.AddText(buffer);
resultw.Draw();
roundXsec(theo_w, theo_w_unc, tmp2);
sprintf(buffer,"%.0f #pm %.0f pb", tmp2[0], tmp2[1]);
TPaveText theoryw(0.60,tp-(6.6*td),1.00,tp+tw-(6.6*td),"NDC");
theoryw.SetFillStyle(0);
theoryw.SetBorderSize(0);
theoryw.SetTextAlign(12);
theoryw.AddText(buffer);
theoryw.Draw();
TPaveText textz(0.10,tp-(9*td),0.50,tp+tw-(9*td),"NDC");
textz.SetFillStyle(0);
textz.SetBorderSize(0);
textz.SetTextAlign(12);
textz.AddText("#bf{Z#rightarrowl^{+}l^{-}}");
textz.Draw();
roundXsec(xsec_z, xsec_z_stat, xsec_z_sys,xsec_z_lumi, tmp);
sprintf(buffer,"%.0f #pm %.0f_{stat} #pm %.0f_{syst}", tmp[0], tmp[1], tmp[2]);
sprintf(buffer,"%s #pm %.0f_{lum} pb",buffer,tmp[3]);
TPaveText resultz(0.60,tp-(8.5*td),1.00,tp+tw-(8.5*td),"NDC");
resultz.SetFillStyle(0);
resultz.SetBorderSize(0);
resultz.SetTextAlign(12);
resultz.AddText(buffer);
resultz.Draw();
roundXsec(theo_z, theo_z_unc, tmp2);
sprintf(buffer,"%.0f #pm %.0f pb", tmp2[0], tmp2[1]);
TPaveText theoryz(0.60,tp-(9.6*td),1.00,tp+tw-(9.6*td),"NDC");
theoryz.SetFillStyle(0);
theoryz.SetBorderSize(0);
theoryz.SetTextAlign(12);
theoryz.AddText(buffer);
theoryz.Draw();
TPaveText textwr(0.10,tp-(12*td),0.50,tp+tw-(12*td),"NDC");
textwr.SetFillStyle(0);
textwr.SetBorderSize(0);
textwr.SetTextAlign(12);
textwr.AddText("#bf{W^{+}#rightarrowl^{+}#nu / W^{-}#rightarrowl^{-}#nu}");
textwr.Draw();
sprintf(buffer,"%.3f #pm %.3f_{stat} #pm %.3f_{syst}", xsec_wr, xsec_wr_stat, xsec_wr_sys);
TPaveText resultwr(0.60,tp-(11.5*td),1.00,tp+tw-(11.5*td),"NDC");
resultwr.SetFillStyle(0);
resultwr.SetBorderSize(0);
resultwr.SetTextAlign(12);
resultwr.AddText(buffer);
resultwr.Draw();
sprintf(buffer,"%.3f #pm %.3f", theo_wr, theo_wr_unc);
TPaveText theorywr(0.60,tp-(12.6*td),1.00,tp+tw-(12.6*td),"NDC");
theorywr.SetFillStyle(0);
theorywr.SetBorderSize(0);
theorywr.SetTextAlign(12);
theorywr.AddText(buffer);
theorywr.Draw();
TPaveText textwpr(0.10,tp-(15*td),0.50,tp+tw-(15*td),"NDC");
textwpr.SetFillStyle(0);
textwpr.SetBorderSize(0);
textwpr.SetTextAlign(12);
textwpr.AddText("#bf{W^{+}#rightarrowl^{+}#nu / Z#rightarrowl^{+}l^{-}}");
textwpr.Draw();
sprintf(buffer,"%.2f #pm %.2f_{stat} #pm %.2f_{syst}", xsec_wpr, xsec_wpr_stat, xsec_wpr_sys);
TPaveText resultwpr(0.60,tp-(14.5*td),1.00,tp+tw-(14.5*td),"NDC");
resultwpr.SetFillStyle(0);
resultwpr.SetBorderSize(0);
resultwpr.SetTextAlign(12);
resultwpr.AddText(buffer);
resultwpr.Draw();
sprintf(buffer,"%.2f #pm %.2f", theo_wpr, theo_wpr_unc);
TPaveText theorywpr(0.60,tp-(15.6*td),1.00,tp+tw-(15.6*td),"NDC");
theorywpr.SetFillStyle(0);
theorywpr.SetBorderSize(0);
theorywpr.SetTextAlign(12);
theorywpr.AddText(buffer);
theorywpr.Draw();
TPaveText textwmr(0.10,tp-(18*td),0.50,tp+tw-(18*td),"NDC");
textwmr.SetFillStyle(0);
textwmr.SetBorderSize(0);
textwmr.SetTextAlign(12);
textwmr.AddText("#bf{W^{-}#rightarrowl^{-}#nu / Z#rightarrowl^{+}l^{-}}");
textwmr.Draw();
sprintf(buffer,"%.2f #pm %.2f_{stat} #pm %.2f_{syst}", xsec_wmr, xsec_wmr_stat, xsec_wmr_sys);
TPaveText resultwmr(0.60,tp-(17.5*td),1.00,tp+tw-(17.5*td),"NDC");
resultwmr.SetFillStyle(0);
resultwmr.SetBorderSize(0);
resultwmr.SetTextAlign(12);
resultwmr.AddText(buffer);
resultwmr.Draw();
sprintf(buffer,"%.2f #pm %.2f", theo_wmr, theo_wmr_unc);
TPaveText theorywmr(0.60,tp-(18.6*td),1.00,tp+tw-(18.6*td),"NDC");
theorywmr.SetFillStyle(0);
theorywmr.SetBorderSize(0);
theorywmr.SetTextAlign(12);
theorywmr.AddText(buffer);
theorywmr.Draw();
TPaveText textwz(0.10,tp-(21*td),0.50,tp+tw-(21*td),"NDC");
textwz.SetFillStyle(0);
textwz.SetBorderSize(0);
textwz.SetTextAlign(12);
textwz.AddText("#bf{W#rightarrowl#nu / Z#rightarrowl^{+}l^{-}}");
textwz.Draw();
sprintf(buffer,"%.2f #pm %.2f_{stat} #pm %.2f_{syst}", xsec_wz, xsec_wz_stat, xsec_wz_sys);
TPaveText resultwz(0.60,tp-(20.5*td),1.00,tp+tw-(20.5*td),"NDC");
resultwz.SetFillStyle(0);
resultwz.SetBorderSize(0);
resultwz.SetTextAlign(12);
resultwz.AddText(buffer);
resultwz.Draw();
sprintf(buffer,"%.2f #pm %.2f", theo_wz, theo_wz_unc);
TPaveText theorywz(0.60,tp-(21.6*td),1.00,tp+tw-(21.6*td),"NDC");
theorywz.SetFillStyle(0);
theorywz.SetBorderSize(0);
theorywz.SetTextAlign(12);
theorywz.AddText(buffer);
theorywz.Draw();
TPaveText tb5(0.28,0.02,0.98,0.12,"NDC");
tb5.SetFillStyle(0);
tb5.SetBorderSize(0);
tb5.SetTextAlign(12);
tb5.AddText("ratio (exp./th.) of total cross sections and ratios");
tb5.Draw();
c->SaveAs("xsecSummary13TeV.png");
c->SaveAs("xsecSummary13TeV.pdf");
}
void
HTT_TT_X(bool scaled=true, bool log=false, float min=0., float max=-1., const char* inputfile="root/$HISTFILE", const char* directory="$CATEGORY")
{
// define common canvas, axes pad styles
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
// determine category tag
const char* category_extra = "";
if(std::string(directory) == std::string("emu_0jet_low" )){ category_extra = "0 jet, low p_{T}"; }
if(std::string(directory) == std::string("emu_0jet_high" )){ category_extra = "0 jet, high p_{T}"; }
if(std::string(directory) == std::string("emu_boost_low" )){ category_extra = "1 jet, low p_{T}"; }
if(std::string(directory) == std::string("emu_boost_high")){ category_extra = "1 jet, high p_{T}"; }
if(std::string(directory) == std::string("emu_vbf" )){ category_extra = "2 jet (VBF)"; }
if(std::string(directory) == std::string("emu_nobtag" )){ category_extra = "No B-Tag"; }
if(std::string(directory) == std::string("emu_btag" )){ category_extra = "B-Tag"; }
const char* dataset;
if(std::string(inputfile).find("7TeV")!=std::string::npos){dataset = "CMS Preliminary, ZH#rightarrow#lltau#tau, 4.9 fb^{-1} at 7 TeV";}
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "CMS Preliminary, ZH#rightarrowll#tau#tau, 19.4 fb^{-1} at 8 TeV";}
#ifdef MSSM
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "CMS Preliminary, H#rightarrow#tau#tau, 19.4 fb^{-1} at 8 TeV";}
#endif
TFile* input = new TFile(inputfile);
TH1F* ZZ = refill((TH1F*)input->Get(TString::Format("%s/ZZ" , directory)), "ZZ"); InitHist(ZZ, "", "", kMagenta-10, 1001);
TH1F* GGToZZ2L2L = refill((TH1F*)input->Get(TString::Format("%s/GGToZZ2L2L" , directory)), "GGToZZ2L2L"); InitHist(GGToZZ2L2L, "", "", kMagenta-10, 1001);
TH1F* Zjets = refill((TH1F*)input->Get(TString::Format("%s/Zjets" , directory)), "Zjets" ); InitHist(Zjets , "", "", kRed + 2, 1001);
#ifndef DROP_SIGNAL
TH1F* ZH_htt = refill((TH1F*)input->Get(TString::Format("%s/ZH_htt" , directory)+"125"), "ZH_htt" ); InitSignal(ZH_htt); ZH_htt->Scale(SIGNAL_SCALE);
TH1F* ZH_hww = refill((TH1F*)input->Get(TString::Format("%s/ZH_hww" , directory)+"125"), "ZH_hww" ); InitSignal(ZH_hww); ZH_hww->Scale(SIGNAL_SCALE);
#endif
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs", directory)), "data", true);
InitHist(data, "#bf{m_{#tau#tau} [GeV]}", "#bf{dN/dm_{#tau#tau} [1/GeV]}"); InitData(data);
TH1F* ref=(TH1F*)ZZ->Clone("ref");
ref->Add(GGToZZ2L2L);
ref->Add(Zjets );
double unscaled[5];
unscaled[0] = ZZ->Integral();
unscaled[1] = GGToZZ2L2L->Integral();
unscaled[2] = Zjets ->Integral();
#ifndef DROP_SIGNAL
unscaled[3] = ZH_htt ->Integral();
unscaled[4] = ZH_hww ->Integral();
#endif
if(scaled){
rescale(ZZ, 1);
rescale(GGToZZ2L2L, 2);
rescale(Zjets, 3);
#ifndef DROP_SIGNAL
rescale(ZH_htt, 4);
rescale(ZH_hww, 5);
#endif
}
TH1F* scales[5];
scales[0] = new TH1F("scales-ZZ", "", 5, 0, 5);
scales[0]->SetBinContent(1, unscaled[0]>0 ? (ZZ->Integral()/unscaled[0]-1.) : 0.);
scales[1] = new TH1F("scales-GGToZZ2L2L", "", 5, 0, 5);
scales[1]->SetBinContent(2, unscaled[1]>0 ? (GGToZZ2L2L->Integral()/unscaled[1]-1.) : 0.);
scales[2] = new TH1F("scales-Zjets" , "", 5, 0, 5);
scales[2]->SetBinContent(3, unscaled[2]>0 ? (Zjets ->Integral()/unscaled[2]-1.) : 0.);
#ifndef DROP_SIGNAL
scales[3] = new TH1F("scales-ZH_htt" , "", 5, 0, 5);
scales[3]->SetBinContent(4, unscaled[3]>0 ? (ZH_htt ->Integral()/unscaled[3]-1.) : 0.);
scales[4] = new TH1F("scales-ZH_hww" , "", 5, 0, 5);
scales[4]->SetBinContent(5, unscaled[4]>0 ? (ZH_hww ->Integral()/unscaled[4]-1.) : 0.);
#endif
GGToZZ2L2L->Add(Zjets);
ZZ ->Add(GGToZZ2L2L);
if(log){
#ifndef DROP_SIGNAL
ZH_htt ->Add(ZH_hww );
#endif
}
else{
#ifndef DROP_SIGNAL
ZH_htt ->Add(ZH_hww);
#endif
}
/*
mass plot before and after fit
*/
TCanvas* canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
if(log){ canv->SetLogy(1); }
#if defined MSSM
if(!log){ data->GetXaxis()->SetRange(0, data->FindBin(350)); } else{ data->GetXaxis()->SetRange(0, data->FindBin(1000)); };
#else
data->GetXaxis()->SetRange(0, data->FindBin(350));
#endif
data->SetNdivisions(505);
data->SetMinimum(min);
float maxZZ=ZZ->GetBinContent(ZZ->GetMaximumBin()); float maxdata=data->GetBinContent(data->GetMaximumBin());
if (maxdata>maxZZ)
data->SetMaximum(1.8*maxdata);
else
data->SetMaximum(1.8*maxZZ);
data->Draw("e");
// TH1F* errorBand = (TH1F*)ZZ ->Clone();
TH1F* errorBand = (TH1F*)Zjets ->Clone();
errorBand ->SetMarkerSize(0);
errorBand ->SetFillColor(1);
errorBand ->SetFillStyle(3013);
errorBand ->SetLineWidth(1);
errorBand ->Scale(0.15);
for(int idx=0; idx<errorBand->GetNbinsX(); ++idx){
if(errorBand->GetBinContent(idx)>0){
std::cout << "Uncertainties on summed background samples: " << errorBand->GetBinError(idx)/errorBand->GetBinContent(idx) << std::endl;
break;
}
}
//if(log){
ZZ ->Draw("histsame");
Zjets->Draw("histsame");
$DRAW_ERROR
#ifndef DROP_SIGNAL
ZH_htt ->Draw("histsame");
#endif
//}
//else{
//#ifndef DROP_SIGNAL
// ggH ->Draw("histsame");
//#endif
// Ztt ->Draw("histsame");
// ttbar->Draw("histsame");
// EWK ->Draw("histsame");
// Fakes->Draw("histsame");
// $DRAW_ERROR
// }
data->Draw("esame");
canv->RedrawAxis();
// //CMSPrelim(dataset, "#tau_{e}#tau_{#mu}", 0.17, 0.835);
CMSPrelim(dataset, "", 0.16, 0.835);
TPaveText* chan = new TPaveText(0.20, 0.74+0.061, 0.32, 0.74+0.161, "NDC");
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
if (directory=="eett_zh")
chan->AddText("#tau#tau");
else
chan->AddText("#mu#mu#tau#tau");
chan->Draw();
//
// TPaveText* cat = new TPaveText(0.20, 0.68+0.061, 0.32, 0.68+0.161, "NDC");
// cat->SetBorderSize( 0 );
// cat->SetFillStyle( 0 );
// cat->SetTextAlign( 12 );
// cat->SetTextSize ( 0.05 );
// cat->SetTextColor( 1 );
// cat->SetTextFont ( 62 );
// cat->AddText(category_extra);
// cat->Draw();
//
//#ifdef MSSM
// TPaveText* massA = new TPaveText(0.75, 0.48+0.061, 0.85, 0.48+0.161, "NDC");
// massA->SetBorderSize( 0 );
// massA->SetFillStyle( 0 );
// massA->SetTextAlign( 12 );
// massA->SetTextSize ( 0.03 );
// massA->SetTextColor( 1 );
// massA->SetTextFont ( 62 );
// massA->AddText("m_{A}=$MAGeV");
// massA->Draw();
//
// TPaveText* tanb = new TPaveText(0.75, 0.44+0.061, 0.85, 0.44+0.161, "NDC");
// tanb->SetBorderSize( 0 );
// tanb->SetFillStyle( 0 );
// tanb->SetTextAlign( 12 );
// tanb->SetTextSize ( 0.03 );
// tanb->SetTextColor( 1 );
// tanb->SetTextFont ( 62 );
// tanb->AddText("tan#beta=$TANB");
// tanb->Draw();
//
// TPaveText* scen = new TPaveText(0.75, 0.40+0.061, 0.85, 0.40+0.161, "NDC");
// scen->SetBorderSize( 0 );
// scen->SetFillStyle( 0 );
// scen->SetTextAlign( 12 );
// scen->SetTextSize ( 0.03 );
// scen->SetTextColor( 1 );
// scen->SetTextFont ( 62 );
// scen->AddText("mhmax");
// scen->Draw();
//#endif
//
//#ifdef MSSM
// TLegend* leg = new TLegend(0.45, 0.65, 0.95, 0.90);
// SetLegendStyle(leg);
// leg->AddEntry(ggH , "#phi#rightarrow#tau#tau" , "L" );
//#else
TLegend* leg = new TLegend(0.50, 0.65, 0.95, 0.90);
SetLegendStyle(leg);
//#ifndef DROP_SIGNAL
// if(SIGNAL_SCALE!=1){
leg->AddEntry(ZH_htt , TString::Format("%.0f#timesZH(125 GeV)#rightarrowll#tau#tau", SIGNAL_SCALE) , "L" );
// }
// else{
// leg->AddEntry(ggH , "H(125 GeV)#rightarrow#tau#tau" , "L" );
// }
//#endif
//#endif
leg->AddEntry(data , "observed" , "LP");
leg->AddEntry(ZZ , "ZZ" , "F" );
leg->AddEntry(Zjets, "Reducible" , "F" );
// leg->AddEntry(EWK , "electroweak" , "F" );
// leg->AddEntry(Fakes, "QCD" , "F" );
$ERROR_LEGEND
leg->Draw();
//
////#ifdef MSSM
//// TPaveText* mssm = new TPaveText(0.69, 0.85, 0.90, 0.90, "NDC");
//// mssm->SetBorderSize( 0 );
//// mssm->SetFillStyle( 0 );
//// mssm->SetTextAlign( 12 );
//// mssm->SetTextSize ( 0.03 );
//// mssm->SetTextColor( 1 );
//// mssm->SetTextFont ( 62 );
//// mssm->AddText("(m_{A}=250, tan#beta=5)");
//// mssm->Draw();
////#else
//// TPaveText* mssm = new TPaveText(0.83, 0.85, 0.95, 0.90, "NDC");
//// mssm->SetBorderSize( 0 );
//// mssm->SetFillStyle( 0 );
//// mssm->SetTextAlign( 12 );
//// mssm->SetTextSize ( 0.03 );
//// mssm->SetTextColor( 1 );
//// mssm->SetTextFont ( 62 );
//// mssm->AddText("m_{H}=125");
//// mssm->Draw();
////#endif
//
// /*
// Ratio Data over MC
// */
// TCanvas *canv0 = MakeCanvas("canv0", "histograms", 600, 400);
// canv0->SetGridx();
// canv0->SetGridy();
// canv0->cd();
//
// TH1F* zero = (TH1F*)ref ->Clone("zero"); zero->Clear();
// TH1F* rat1 = (TH1F*)data->Clone("rat");
// rat1->Divide(Ztt);
// for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
// if(rat1->GetBinContent(ibin+1)>0){
// // catch cases of 0 bins, which would lead to 0-alpha*0-1
// rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
// }
// zero->SetBinContent(ibin+1, 0.);
// }
// rat1->SetLineColor(kBlack);
// rat1->SetFillColor(kGray );
// rat1->SetMaximum(+0.5);
// rat1->SetMinimum(-0.5);
// rat1->GetYaxis()->CenterTitle();
// rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
// rat1->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
// rat1->Draw();
// zero->SetLineColor(kBlack);
// zero->Draw("same");
// canv0->RedrawAxis();
//
// /*
// Ratio After fit over Prefit
// */
// TCanvas *canv1 = MakeCanvas("canv1", "histograms", 600, 400);
// canv1->SetGridx();
// canv1->SetGridy();
// canv1->cd();
//
// TH1F* rat2 = (TH1F*) Ztt->Clone("rat2");
// rat2->Divide(ref);
// for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
// if(rat2->GetBinContent(ibin+1)>0){
// // catch cases of 0 bins, which would lead to 0-alpha*0-1
// rat2 ->SetBinContent(ibin+1, rat2->GetBinContent(ibin+1)-1.);
// }
// }
// rat2->SetLineColor(kRed+ 3);
// rat2->SetFillColor(kRed-10);
// rat2->SetMaximum(+0.3);
// rat2->SetMinimum(-0.3);
// rat2->GetYaxis()->SetTitle("#bf{Fit/Prefit-1}");
// rat2->GetYaxis()->CenterTitle();
// rat2->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
// rat2->GetXaxis()->SetRange(0, 28);
// rat2->Draw();
// zero->SetLineColor(kBlack);
// zero->Draw("same");
// canv1->RedrawAxis();
//
// /*
// Relative shift per sample
// */
// TCanvas *canv2 = MakeCanvas("canv2", "histograms", 600, 400);
// canv2->SetGridx();
// canv2->SetGridy();
// canv2->cd();
//
// InitHist (scales[0], "", "", kMagenta-10, 1001);
// InitHist (scales[1], "", "", kRed + 2, 1001);
// InitHist (scales[2], "", "", kBlue - 8, 1001);
// InitHist (scales[3], "", "", kOrange - 4, 1001);
//#ifndef DROP_SIGNAL
// InitSignal(scales[4]);
// InitSignal(scales[5]);
// InitSignal(scales[6]);
//#endif
// scales[0]->Draw();
// scales[0]->GetXaxis()->SetBinLabel(1, "#bf{Fakes}");
// scales[0]->GetXaxis()->SetBinLabel(2, "#bf{EWK}" );
// scales[0]->GetXaxis()->SetBinLabel(3, "#bf{ttbar}");
// scales[0]->GetXaxis()->SetBinLabel(4, "#bf{Ztt}" );
//#ifdef MSSM
// scales[0]->GetXaxis()->SetBinLabel(5, "#bf{ggH}" );
// scales[0]->GetXaxis()->SetBinLabel(6, "#bf{bbH}" );
// scales[0]->GetXaxis()->SetBinLabel(7, "#bf{NONE}" );
//#else
// scales[0]->GetXaxis()->SetBinLabel(5, "#bf{ggH}" );
// scales[0]->GetXaxis()->SetBinLabel(6, "#bf{qqH}" );
// scales[0]->GetXaxis()->SetBinLabel(7, "#bf{VH}" );
//#endif
// scales[0]->SetMaximum(+1.0);
// scales[0]->SetMinimum(-1.0);
// scales[0]->GetYaxis()->CenterTitle();
// scales[0]->GetYaxis()->SetTitle("#bf{Fit/Prefit-1}");
// scales[1]->Draw("same");
// scales[2]->Draw("same");
// scales[3]->Draw("same");
//#ifndef DROP_SIGNAL
// scales[4]->Draw("same");
// scales[5]->Draw("same");
// scales[6]->Draw("same");
//#endif
// zero->Draw("same");
// canv2->RedrawAxis();
//
// /*
// prepare output
// */
bool isSevenTeV = std::string(inputfile).find("7TeV")!=std::string::npos;
canv ->Print(TString::Format("%s_%sscaled_%s_%s.png" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv ->Print(TString::Format("%s_%sscaled_%s_%s.pdf" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv ->Print(TString::Format("%s_%sscaled_%s_%s.eps" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
// canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
TFile* output = new TFile(TString::Format("%s_%sscaled_%s_%s.root", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""), "update");
output->cd();
data ->Write("data_obs");
ZZ->Write("ZZ" );
Zjets ->Write("Zjets" );
ZH_htt->Write("ZH_htt" );
ZH_hww ->Write("ZH_hww" );
//#ifdef MSSM
// ggH ->Write("ggH" );
// bbH ->Write("bbH" );
//#else
//#ifndef DROP_SIGNAL
// ggH ->Write("ggH" );
// qqH ->Write("qqH" );
// VH ->Write("VH" );
//#endif
//#endif
if(errorBand){
errorBand->Write("errorBand");
}
output->Close();
}
void LEPStyle::draw()
{
if( _canv==0 )
{
setCanvas();
setHist();
_canv->Draw();
if( _ymin==0 ) _ymin = 0.2;
// _ymax = _n*1.5;
if( _ymax==0 ) _ymax = _n+_upDy;
_hist->SetMinimum( _ymin );
_hist->SetMaximum( _ymax );
_hist->Draw();
if( _cmsPrelim ) cmsPrelim( _intLumi );
}
// size_t n_ = _entry.size();
_n = _entry.size();
if( _extraBand )
{
drawExtraBand();
}
if( _band )
{
Double_t xx_[5] = { _bxmin, _bxmax, _bxmax, _bxmin, _bxmin };
float eps1_ = _eps1*(_ymax-_ymin);
float eps2_ = _eps2*(_ymax-_ymin);
Double_t yy_[5] = { _ymin+eps1_, _ymin+eps1_, _ymax-eps2_, _ymax-eps2_, _ymin+eps1_ };
TPolyLine* pl_ = new TPolyLine( 5, xx_, yy_ );
pl_->SetFillStyle(_bandFillStyle);
pl_->SetFillColor(_bandFillColor);
pl_->SetLineWidth(3);
pl_->SetLineColor( kOrange );
pl_->DrawClone("FSame");
TLine* l_ = new TLine( _bx0, _ymin+eps1_, _bx0, _ymax-eps2_ );
l_->SetLineWidth(4);
l_->SetLineColor( kOrange );
l_->DrawClone();
if( _hasLegend )
{
cout << "HELLO!!!!" << endl;
// _y0 = 4.0;
if( _y0==0 ) _y0 = _n+2*_upDy/3.;
if( _dy==0 ) _dy = 0.06;
_x0 = _xmax - 0.05*(_xmax-_xmin);
TLatex leg1_;
leg1_.SetTextSize(_scale*0.05);
leg1_.SetTextAlign(31);
leg1_.DrawLatex( _x0, _y0+_dy, _legend );
TLatex leg2_;
leg2_.SetTextSize(_scale*0.05);
leg2_.SetTextAlign(23);
leg2_.DrawLatex( _bx0, _y0-_dy, _theory );
}
// TLegend* legend=new TLegend(_x0,_y0, _x0+_dx, _y0+_dy );
// legend->SetLineColor(0);
// legend->SetFillColor(0);
// // legend->AddEntry(pl_,_legend,"lf");
// legend->AddEntry(pl_,_legend,"");
// legend->Draw("same");
}
for( size_t ii=0; ii<_entry.size(); ii++ )
{
if( _entry[ii]==("SPACE") ) continue;
Float_t xval_[1];
Float_t yval_[1];
Float_t ey_[1];
Float_t estatup_[1];
Float_t ecombup_[1];
Float_t etotup_[1];
Float_t estatlo_[1];
Float_t ecomblo_[1];
Float_t etotlo_[1];
float yy_ = _n-(Float_t)ii;
xval_[0] = _val[ii];
yval_[0] = yy_;
ey_[0] = 0;
estatup_[0] = _statup[ii];
ecombup_[0] = sqrt( pow( _statup[ii],2 ) + pow( _systup[ii],2 ) );
etotup_[0] = ecombup_[0] + _lumi[ii];
estatlo_[0] = _statlo[ii];
ecomblo_[0] = sqrt( pow( _statlo[ii],2 ) + pow( _systlo[ii],2 ) );
etotlo_[0] = ecomblo_[0] + _lumi[ii];
TGraphAsymmErrors* gtot_ = new TGraphAsymmErrors( 1, xval_, yval_, etotlo_, etotup_, ey_, ey_ );
gtot_->SetLineColor( kGreen );
TGraphAsymmErrors* gcomb_ = new TGraphAsymmErrors( 1, xval_, yval_, ecomblo_, ecombup_, ey_, ey_ );
gcomb_->SetLineColor( kRed );
TGraphAsymmErrors* gstat_ = new TGraphAsymmErrors( 1, xval_, yval_, estatlo_, estatup_, ey_, ey_ );
gstat_->SetLineColor( kBlack );
gstat_->SetLineWidth( 2 );
gstat_->SetMarkerStyle( _marker[ii] );
gstat_->SetMarkerSize( _size[ii] );
gstat_->SetMarkerColor( _color[ii] );
gcomb_->SetLineWidth( 2 );
gtot_->SetLineWidth( 2 );
if( _lumi[ii]>0 )
gtot_->Draw();
gcomb_->DrawClone();
gstat_->DrawClone("P");
if( !_writeText ) continue;
// align = 10*HorizontalAlign + VerticalAlign
// For Horizontal alignment the following convention applies:
// 1=left adjusted, 2=centered, 3=right adjusted
// For Vertical alignment the following convention applies:
// 1=bottom adjusted, 2=centered, 3=top adjusted
float xtxt_ = _xmin + 0.05*(_xmax-_xmin);
TLatex ltx1_;
ltx1_.SetTextSize(_scale*_size1);
ltx1_.SetTextAlign(_align1);
if( _specifyPlacement )
ltx1_.DrawLatex( _xx1, yy_+_e1, _entry[ii] );
else
ltx1_.DrawLatex( xtxt_, yy_+E_+e_, _entry[ii] );
TLatex ltx2_;
char line_[512];
TString str_;
TString pmstr_(" #pm ");
TString format_("%-4.");
format_ += _ndigit[ii];
format_ += "f";
TString valstr_;
TString statstr_;
TString syststr_;
TString lumistr_;
sprintf( line_, format_.Data(), _val[ii] );
// sprintf( line_, "%-4.3f", _val[ii] );
valstr_ = line_;
if( fabs( _statup[ii]-_statlo[ii] )<0.01 )
{
sprintf( line_, format_.Data(), _statlo[ii] );
}
else
{
sprintf( line_, "#scale[0.7]{#splitline{+%-4.3f}{-%-4.3f}}_{ stat.}", _statup[ii], _statlo[ii] );
}
statstr_ = line_;
str_ = valstr_ + pmstr_ + statstr_;
str_ += "_{ ";
str_ += _firstError;
str_ += "}";
if( _systup[ii]>0 )
{
if( fabs( _systup[ii]-_systlo[ii] )<0.01 )
{
sprintf( line_, format_.Data(), _systlo[ii] );
}
else
{
sprintf( line_, "#scale[0.7]{#splitline{+%-4.3f}{- %-4.3f}}_", _systup[ii], _systlo[ii] );
}
syststr_ = line_;
str_ += pmstr_;
str_ += syststr_;
str_ += "_{ ";
str_ += _secondError;
str_ += "}";
}
if( _lumi[ii]>0 )
{
sprintf( line_, format_.Data(), _lumi[ii] );
lumistr_ = line_;
lumistr_ += "_{lumi.}";
str_ += pmstr_ + lumistr_;
}
// TString str_(line_);
str_ += _unit;
cout << str_ << endl;
ltx2_.SetTextSize(_scale*_size2);
ltx2_.SetTextAlign(_align2);
if( _specifyPlacement )
ltx2_.DrawLatex( _xx2, yy_+_e2, str_ );
else
ltx2_.DrawLatex( xtxt_+0.02*(_xmax-_xmin), yy_+E_-e_, str_ );
}
_hist->Draw("Same");
_canv->RedrawAxis();
}
void
HTT_MT_X(bool scaled=true, bool log=true, float min=0.1, float max=-1., const char* inputfile="root/$HISTFILE", const char* directory="muTau_$CATEGORY")
{
// defining the common canvas, axes pad styles
SetStyle(); gStyle->SetLineStyleString(11,"20 10");
// determine category tag
const char* category_extra = "";
if(std::string(directory) == std::string("muTau_0jet_low" )){ category_extra = "0 jet, low p_{T}"; }
if(std::string(directory) == std::string("muTau_0jet_high" )){ category_extra = "0 jet, high p_{T}"; }
if(std::string(directory) == std::string("muTau_boost_low" )){ category_extra = "1 jet, low p_{T}"; }
if(std::string(directory) == std::string("muTau_boost_high")){ category_extra = "1 jet, high p_{T}"; }
if(std::string(directory) == std::string("muTau_vbf" )){ category_extra = "2 jet (VBF)"; }
if(std::string(directory) == std::string("muTau_nobtag" )){ category_extra = "No B-Tag"; }
if(std::string(directory) == std::string("muTau_btag" )){ category_extra = "B-Tag"; }
const char* dataset;
if(std::string(inputfile).find("7TeV")!=std::string::npos){dataset = "CMS Preliminary, H#rightarrow#tau#tau, 4.9 fb^{-1} at 7 TeV";}
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "CMS Preliminary, H#rightarrow#tau#tau, 19.4 fb^{-1} at 8 TeV";}
#ifdef MSSM
if(std::string(inputfile).find("8TeV")!=std::string::npos){dataset = "CMS Preliminary, H#rightarrow#tau#tau, 12.1 fb^{-1} at 8 TeV";}
#endif
// open example histogram file
TFile* input = new TFile(inputfile);
TH1F* Fakes = refill((TH1F*)input->Get(TString::Format("%s/QCD" , directory)), "QCD"); InitHist(Fakes, "", "", kMagenta-10, 1001);
TH1F* EWK1 = refill((TH1F*)input->Get(TString::Format("%s/W" , directory)), "W" ); InitHist(EWK1 , "", "", kRed + 2, 1001);
#ifdef EXTRA_SAMPLES
TH1F* EWK2 = refill((TH1F*)input->Get(TString::Format("%s/ZJ" , directory)), "ZJ" ); InitHist(EWK2 , "", "", kRed + 2, 1001);
TH1F* EWK3 = refill((TH1F*)input->Get(TString::Format("%s/ZL" , directory)), "ZL" ); InitHist(EWK3 , "", "", kRed + 2, 1001);
#else
TH1F* EWK2 = refill((TH1F*)input->Get(TString::Format("%s/ZLL" , directory)), "ZLL"); InitHist(EWK2 , "", "", kRed + 2, 1001);
#endif
TH1F* EWK = refill((TH1F*)input->Get(TString::Format("%s/VV" , directory)), "VV" ); InitHist(EWK , "", "", kRed + 2, 1001);
TH1F* ttbar = refill((TH1F*)input->Get(TString::Format("%s/TT" , directory)), "TT" ); InitHist(ttbar, "", "", kBlue - 8, 1001);
TH1F* Ztt = refill((TH1F*)input->Get(TString::Format("%s/ZTT" , directory)), "ZTT"); InitHist(Ztt , "", "", kOrange - 4, 1001);
#ifdef MSSM
float ggHScale = 1., bbHScale = 1.; // scenario for MSSM, mhmax, mA=160, tanb=20, A + H for the time being
if(std::string(inputfile).find("7TeV")!=std::string::npos){ ggHScale = ( 9157.9*0.119 + 10180.7*0.120)/1000.;
bbHScale = (23314.3*0.119 + 21999.3*0.120)/1000.; }
if(std::string(inputfile).find("8TeV")!=std::string::npos){ ggHScale = (11815.3*0.119 + 13124.9*0.120)/1000.;
bbHScale = (31087.9*0.119 + 29317.8*0.120)/1000.; }
// float ggHScale = 1., bbHScale = 1.; // scenario for MSSM, mhmax, mA=160, tanb=10, A + H for the time being
// if(std::string(inputfile).find("7TeV")!=std::string::npos){ ggHScale = (2111.4*0.11 + 4022.9*0.11)/1000.;
// bbHScale = (6211.6*0.11 + 5147.0*0.11)/1000.; }
// if(std::string(inputfile).find("8TeV")!=std::string::npos){ ggHScale = (2729.9*0.11 + 5193.2*0.11)/1000.;
// bbHScale = (8282.7*0.11 + 6867.8*0.11)/1000.; }
TH1F* ggH = refill((TH1F*)input->Get(TString::Format("%s/ggH160", directory)), "ggH"); InitSignal(ggH); ggH ->Scale(ggHScale);
TH1F* bbH = refill((TH1F*)input->Get(TString::Format("%s/bbH160", directory)), "bbH"); InitSignal(bbH); bbH ->Scale(bbHScale);
#else
#ifndef DROP_SIGNAL
TH1F* ggH = refill((TH1F*)input->Get(TString::Format("%s/ggH125", directory)), "ggH"); InitSignal(ggH); ggH ->Scale(SIGNAL_SCALE);
TH1F* qqH = refill((TH1F*)input->Get(TString::Format("%s/qqH125", directory)), "qqH"); InitSignal(qqH); qqH ->Scale(SIGNAL_SCALE);
TH1F* VH = refill((TH1F*)input->Get(TString::Format("%s/VH125" , directory)), "VH" ); InitSignal(VH ); VH ->Scale(SIGNAL_SCALE);
#endif
#endif
TH1F* data = refill((TH1F*)input->Get(TString::Format("%s/data_obs", directory)), "data", true);
InitHist(data, "#bf{m_{#tau#tau} [GeV]}", "#bf{dN/dm_{#tau#tau} [1/GeV]}"); InitData(data);
TH1F* ref=(TH1F*)Fakes->Clone("ref");
ref->Add(EWK1 );
ref->Add(EWK2 );
#ifdef EXTRA_SAMPLES
ref->Add(EWK3 );
#endif
ref->Add(EWK );
ref->Add(ttbar);
ref->Add(Ztt );
double unscaled[7];
unscaled[0] = Fakes->Integral();
unscaled[1] = EWK ->Integral();
unscaled[1]+= EWK1 ->Integral();
unscaled[1]+= EWK2 ->Integral();
#ifdef EXTRA_SAMPLES
unscaled[1]+= EWK3 ->Integral();
#endif
unscaled[2] = ttbar->Integral();
unscaled[3] = Ztt ->Integral();
#ifdef MSSM
unscaled[4] = ggH ->Integral();
unscaled[5] = bbH ->Integral();
unscaled[6] = 0;
#else
#ifndef DROP_SIGNAL
unscaled[4] = ggH ->Integral();
unscaled[5] = qqH ->Integral();
unscaled[6] = VH ->Integral();
#endif
#endif
if(scaled){
rescale(Fakes, 7);
rescale(EWK1 , 3);
rescale(EWK2 , 4);
#ifdef EXTRA_SAMPLES
rescale(EWK3 , 5);
#endif
rescale(EWK , 6);
rescale(ttbar, 2);
rescale(Ztt , 1);
#ifdef MSSM
rescale(ggH , 8);
rescale(bbH , 9);
#else
#ifndef DROP_SIGNAL
rescale(ggH , 8);
rescale(qqH , 9);
rescale(VH ,10);
#endif
#endif
}
TH1F* scales[7];
scales[0] = new TH1F("scales-Fakes", "", 7, 0, 7);
scales[0]->SetBinContent(1, unscaled[0]>0 ? (Fakes->Integral()/unscaled[0]-1.) : 0.);
scales[1] = new TH1F("scales-EWK" , "", 7, 0, 7);
scales[1]->SetBinContent(2, unscaled[1]>0 ? ((EWK ->Integral()
+EWK1 ->Integral()
+EWK2 ->Integral()
#ifdef EXTRA_SAMPLES
+EWK3 ->Integral()
#endif
)/unscaled[1]-1.) : 0.);
scales[2] = new TH1F("scales-ttbar", "", 7, 0, 7);
scales[2]->SetBinContent(3, unscaled[2]>0 ? (ttbar->Integral()/unscaled[2]-1.) : 0.);
scales[3] = new TH1F("scales-Ztt" , "", 7, 0, 7);
scales[3]->SetBinContent(4, unscaled[3]>0 ? (Ztt ->Integral()/unscaled[3]-1.) : 0.);
#ifdef MSSM
scales[4] = new TH1F("scales-ggH" , "", 7, 0, 7);
scales[4]->SetBinContent(5, unscaled[4]>0 ? (ggH ->Integral()/unscaled[4]-1.) : 0.);
scales[5] = new TH1F("scales-bbH" , "", 7, 0, 7);
scales[5]->SetBinContent(6, unscaled[5]>0 ? (bbH ->Integral()/unscaled[5]-1.) : 0.);
scales[6] = new TH1F("scales-NONE" , "", 7, 0, 7);
scales[6]->SetBinContent(7, 0.);
#else
#ifndef DROP_SIGNAL
scales[4] = new TH1F("scales-ggH" , "", 7, 0, 7);
scales[4]->SetBinContent(5, unscaled[4]>0 ? (ggH ->Integral()/unscaled[4]-1.) : 0.);
scales[5] = new TH1F("scales-qqH" , "", 7, 0, 7);
scales[5]->SetBinContent(6, unscaled[5]>0 ? (qqH ->Integral()/unscaled[5]-1.) : 0.);
scales[6] = new TH1F("scales-VH" , "", 7, 0, 7);
scales[6]->SetBinContent(7, unscaled[6]>0 ? (VH ->Integral()/unscaled[6]-1.) : 0.);
#endif
#endif
EWK1 ->Add(Fakes);
EWK2 ->Add(EWK1 );
#ifdef EXTRA_SAMPLES
EWK3 ->Add(EWK2 );
EWK ->Add(EWK3 );
#else
EWK ->Add(EWK2 );
#endif
ttbar->Add(EWK );
Ztt ->Add(ttbar);
if(log){
#ifdef MSSM
ggH ->Add(bbH);
#else
#ifndef DROP_SIGNAL
qqH ->Add(VH );
ggH ->Add(qqH);
#endif
#endif
}
else{
#ifdef MSSM
bbH ->Add(Ztt);
ggH ->Add(bbH);
#else
#ifndef DROP_SIGNAL
VH ->Add(Ztt);
qqH ->Add(VH );
ggH ->Add(qqH);
#endif
#endif
}
/*
Mass plot before and after fit
*/
TCanvas *canv = MakeCanvas("canv", "histograms", 600, 600);
canv->cd();
if(log){ canv->SetLogy(1); }
#if defined MSSM
if(!log){ data->GetXaxis()->SetRange(0, data->FindBin(350)); } else{ data->GetXaxis()->SetRange(0, data->FindBin(1000)); };
#else
data->GetXaxis()->SetRange(0, data->FindBin(350));
#endif
data->SetNdivisions(505);
data->SetMinimum(min);
data->SetMaximum(max>0 ? max : std::max(maximum(data, log), maximum(Ztt, log)));
data->Draw("e");
TH1F* errorBand = (TH1F*)Ztt ->Clone();
errorBand ->SetMarkerSize(0);
errorBand ->SetFillColor(1);
errorBand ->SetFillStyle(3013);
errorBand ->SetLineWidth(1);
for(int idx=0; idx<errorBand->GetNbinsX(); ++idx){
if(errorBand->GetBinContent(idx)>0){
std::cout << "Uncertainties on summed background samples: " << errorBand->GetBinError(idx)/errorBand->GetBinContent(idx) << std::endl;
break;
}
}
if(log){
Ztt ->Draw("histsame");
ttbar->Draw("histsame");
EWK ->Draw("histsame");
Fakes->Draw("histsame");
$DRAW_ERROR
#ifndef DROP_SIGNAL
ggH ->Draw("histsame");
#endif
}
else{
#ifndef DROP_SIGNAL
ggH ->Draw("histsame");
#endif
Ztt ->Draw("histsame");
ttbar->Draw("histsame");
EWK ->Draw("histsame");
Fakes->Draw("histsame");
$DRAW_ERROR
}
data->Draw("esame");
canv->RedrawAxis();
//CMSPrelim(dataset, "#tau_{#mu}#tau_{h}", 0.17, 0.835);
CMSPrelim(dataset, "", 0.16, 0.835);
TPaveText* chan = new TPaveText(0.20, 0.74+0.061, 0.32, 0.74+0.161, "NDC");
chan->SetBorderSize( 0 );
chan->SetFillStyle( 0 );
chan->SetTextAlign( 12 );
chan->SetTextSize ( 0.05 );
chan->SetTextColor( 1 );
chan->SetTextFont ( 62 );
chan->AddText("#mu#tau_{h}");
chan->Draw();
TPaveText* cat = new TPaveText(0.20, 0.68+0.061, 0.32, 0.68+0.161, "NDC");
cat->SetBorderSize( 0 );
cat->SetFillStyle( 0 );
cat->SetTextAlign( 12 );
cat->SetTextSize ( 0.05 );
cat->SetTextColor( 1 );
cat->SetTextFont ( 62 );
cat->AddText(category_extra);
cat->Draw();
#ifdef MSSM
TPaveText* massA = new TPaveText(0.75, 0.48+0.061, 0.85, 0.48+0.161, "NDC");
massA->SetBorderSize( 0 );
massA->SetFillStyle( 0 );
massA->SetTextAlign( 12 );
massA->SetTextSize ( 0.03 );
massA->SetTextColor( 1 );
massA->SetTextFont ( 62 );
massA->AddText("m_{A}=160GeV");
massA->Draw();
TPaveText* tanb = new TPaveText(0.75, 0.44+0.061, 0.85, 0.44+0.161, "NDC");
tanb->SetBorderSize( 0 );
tanb->SetFillStyle( 0 );
tanb->SetTextAlign( 12 );
tanb->SetTextSize ( 0.03 );
tanb->SetTextColor( 1 );
tanb->SetTextFont ( 62 );
tanb->AddText("tan#beta=20");
tanb->Draw();
TPaveText* scen = new TPaveText(0.75, 0.40+0.061, 0.85, 0.40+0.161, "NDC");
scen->SetBorderSize( 0 );
scen->SetFillStyle( 0 );
scen->SetTextAlign( 12 );
scen->SetTextSize ( 0.03 );
scen->SetTextColor( 1 );
scen->SetTextFont ( 62 );
scen->AddText("mhmax");
scen->Draw();
#endif
#ifdef MSSM
TLegend* leg = new TLegend(0.45, 0.65, 0.95, 0.90);
SetLegendStyle(leg);
leg->AddEntry(ggH , "#phi#rightarrow#tau#tau" , "L" );
#else
TLegend* leg = new TLegend(0.50, 0.65, 0.95, 0.90);
SetLegendStyle(leg);
#ifndef DROP_SIGNAL
if(SIGNAL_SCALE!=1){
leg->AddEntry(ggH , TString::Format("%.0f#timesH(125 GeV)#rightarrow#tau#tau", SIGNAL_SCALE) , "L" );
}
else{
leg->AddEntry(ggH , "H(125 GeV)#rightarrow#tau#tau" , "L" );
}
#endif
#endif
leg->AddEntry(data , "observed" , "LP");
leg->AddEntry(Ztt , "Z#rightarrow#tau#tau" , "F" );
leg->AddEntry(ttbar, "t#bar{t}" , "F" );
leg->AddEntry(EWK , "electroweak" , "F" );
leg->AddEntry(Fakes, "QCD" , "F" );
$ERROR_LEGEND
leg->Draw();
//#ifdef MSSM
// TPaveText* mssm = new TPaveText(0.69, 0.85, 0.90, 0.90, "NDC");
// mssm->SetBorderSize( 0 );
// mssm->SetFillStyle( 0 );
// mssm->SetTextAlign( 12 );
// mssm->SetTextSize ( 0.03 );
// mssm->SetTextColor( 1 );
// mssm->SetTextFont ( 62 );
// mssm->AddText("(m_{A}=120, tan#beta=10)");
// mssm->Draw();
//#else
// TPaveText* mssm = new TPaveText(0.83, 0.85, 0.95, 0.90, "NDC");
// mssm->SetBorderSize( 0 );
// mssm->SetFillStyle( 0 );
// mssm->SetTextAlign( 12 );
// mssm->SetTextSize ( 0.03 );
// mssm->SetTextColor( 1 );
// mssm->SetTextFont ( 62 );
// mssm->AddText("m_{H}=125");
// mssm->Draw();
//#endif
/*
Ratio Data over MC
*/
TCanvas *canv0 = MakeCanvas("canv0", "histograms", 600, 400);
canv0->SetGridx();
canv0->SetGridy();
canv0->cd();
TH1F* zero = (TH1F*)ref->Clone("zero"); zero->Clear();
TH1F* rat1 = (TH1F*)data->Clone("rat");
rat1->Divide(Ztt);
for(int ibin=0; ibin<rat1->GetNbinsX(); ++ibin){
if(rat1->GetBinContent(ibin+1)>0){
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat1->SetBinContent(ibin+1, rat1->GetBinContent(ibin+1)-1.);
}
zero->SetBinContent(ibin+1, 0.);
}
rat1->SetLineColor(kBlack);
rat1->SetFillColor(kGray );
rat1->SetMaximum(+0.5);
rat1->SetMinimum(-0.5);
rat1->GetYaxis()->CenterTitle();
rat1->GetYaxis()->SetTitle("#bf{Data/MC-1}");
rat1->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
rat1->Draw();
zero->SetLineColor(kBlack);
zero->Draw("same");
canv0->RedrawAxis();
/*
Ratio After fit over Prefit
*/
TCanvas *canv1 = MakeCanvas("canv1", "histograms", 600, 400);
canv1->SetGridx();
canv1->SetGridy();
canv1->cd();
TH1F* rat2 = (TH1F*) Ztt->Clone("rat2");
rat2->Divide(ref);
for(int ibin=0; ibin<rat2->GetNbinsX(); ++ibin){
if(rat2->GetBinContent(ibin+1)>0){
// catch cases of 0 bins, which would lead to 0-alpha*0-1
rat2 ->SetBinContent(ibin+1, rat2->GetBinContent(ibin+1)-1.);
}
}
rat2->SetLineColor(kRed+ 3);
rat2->SetFillColor(kRed-10);
rat2->SetMaximum(+0.3);
rat2->SetMinimum(-0.3);
rat2->GetYaxis()->SetTitle("#bf{Fit/Prefit-1}");
rat2->GetYaxis()->CenterTitle();
rat2->GetXaxis()->SetTitle("#bf{m_{#tau#tau} [GeV]}");
rat2->Draw();
zero->SetLineColor(kBlack);
zero->Draw("same");
canv1->RedrawAxis();
/*
Relative shift per sample
*/
TCanvas *canv2 = MakeCanvas("canv2", "histograms", 600, 400);
canv2->SetGridx();
canv2->SetGridy();
canv2->cd();
InitHist (scales[0], "", "", kMagenta-10, 1001);
InitHist (scales[1], "", "", kRed + 2, 1001);
InitHist (scales[2], "", "", kBlue - 8, 1001);
InitHist (scales[3], "", "", kOrange - 4, 1001);
#ifndef DROP_SIGNAL
InitSignal(scales[4]);
InitSignal(scales[5]);
InitSignal(scales[6]);
#endif
scales[0]->Draw();
scales[0]->GetXaxis()->SetBinLabel(1, "#bf{Fakes}");
scales[0]->GetXaxis()->SetBinLabel(2, "#bf{EWK}" );
scales[0]->GetXaxis()->SetBinLabel(3, "#bf{ttbar}");
scales[0]->GetXaxis()->SetBinLabel(4, "#bf{Ztt}" );
#ifdef MSSM
scales[0]->GetXaxis()->SetBinLabel(5, "#bf{ggH}" );
scales[0]->GetXaxis()->SetBinLabel(6, "#bf{bbH}" );
scales[0]->GetXaxis()->SetBinLabel(7, "NONE" );
#else
scales[0]->GetXaxis()->SetBinLabel(5, "#bf{ggH}" );
scales[0]->GetXaxis()->SetBinLabel(6, "#bf{qqH}" );
scales[0]->GetXaxis()->SetBinLabel(7, "#bf{VH}" );
#endif
scales[0]->SetMaximum(+1.0);
scales[0]->SetMinimum(-1.0);
scales[0]->GetYaxis()->CenterTitle();
scales[0]->GetYaxis()->SetTitle("#bf{Fit/Prefit-1}");
scales[1]->Draw("same");
scales[2]->Draw("same");
scales[3]->Draw("same");
#ifndef DROP_SIGNAL
scales[4]->Draw("same");
scales[5]->Draw("same");
scales[6]->Draw("same");
#endif
zero->Draw("same");
canv2->RedrawAxis();
/*
prepare output
*/
bool isSevenTeV = std::string(inputfile).find("7TeV")!=std::string::npos;
canv ->Print(TString::Format("%s_%sscaled_%s_%s.png" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv ->Print(TString::Format("%s_%sscaled_%s_%s.pdf" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv ->Print(TString::Format("%s_%sscaled_%s_%s.eps" , directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv0->Print(TString::Format("%s_datamc_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv1->Print(TString::Format("%s_prefit_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.png", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.pdf", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
canv2->Print(TString::Format("%s_sample_%sscaled_%s_%s.eps", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""));
TFile* output = new TFile(TString::Format("%s_%sscaled_%s_%s.root", directory, scaled ? "re" : "un", isSevenTeV ? "7TeV" : "8TeV", log ? "LOG" : ""), "update");
output->cd();
data ->Write("data_obs");
Fakes->Write("Fakes" );
EWK ->Write("EWK" );
ttbar->Write("ttbar" );
Ztt ->Write("Ztt" );
#ifdef MSSM
ggH ->Write("ggH" );
bbH ->Write("bbH" );
#else
#ifndef DROP_SIGNAL
ggH ->Write("ggH" );
qqH ->Write("qqH" );
VH ->Write("VH" );
#endif
#endif
if(errorBand){
errorBand->Write("errorBand");
}
output->Close();
}
void plotLimit(string outputDir="./", TString inputs="", TString inputs_blinded="", TString inputXSec="", bool strengthLimit=true, bool blind=false, double energy=7, double luminosity=5.035, TString legendName="ee and #mu#mu channels")
{
setTDRStyle();
gStyle->SetPadTopMargin (0.05);
gStyle->SetPadBottomMargin(0.12);
gStyle->SetPadRightMargin (0.16);
gStyle->SetPadLeftMargin (0.14);
gStyle->SetTitleSize(0.04, "XYZ");
gStyle->SetTitleXOffset(1.1);
gStyle->SetTitleYOffset(1.45);
gStyle->SetPalette(1);
gStyle->SetNdivisions(505);
//get the limits from the tree
TFile* file = TFile::Open(inputs);
printf("Looping on %s\n",inputs.Data());
if(!file) return;
if(file->IsZombie()) return;
TFile* file_blinded = TFile::Open(inputs_blinded);
printf("Looping on %s\n",inputs_blinded.Data());
if(!file_blinded) return;
if(file_blinded->IsZombie()) return;
TTree* tree_blinded = (TTree*)file_blinded->Get("limit");
tree_blinded->GetBranch("mh" )->SetAddress(&Tmh );
tree_blinded->GetBranch("limit" )->SetAddress(&Tlimit );
tree_blinded->GetBranch("limitErr" )->SetAddress(&TlimitErr);
tree_blinded->GetBranch("quantileExpected")->SetAddress(&TquantExp);
TGraph* ExpLimitm2 = getLimitGraph(tree_blinded,0.025);
TGraph* ExpLimitm1 = getLimitGraph(tree_blinded,0.160);
TGraph* ExpLimit = getLimitGraph(tree_blinded,0.500);
TGraph* ExpLimitp1 = getLimitGraph(tree_blinded,0.840);
TGraph* ExpLimitp2 = getLimitGraph(tree_blinded,0.975);
file_blinded->Close();
TTree* tree = (TTree*)file->Get("limit");
tree->GetBranch("mh" )->SetAddress(&Tmh );
tree->GetBranch("limit" )->SetAddress(&Tlimit );
tree->GetBranch("limitErr" )->SetAddress(&TlimitErr);
tree->GetBranch("quantileExpected")->SetAddress(&TquantExp);
TGraph* ObsLimit = getLimitGraph(tree,-1 );
file->Close();
FILE* pFileSStrenght = fopen((outputDir+"SignalStrenght").c_str(),"w");
std::cout << "Printing Signal Strenght" << std::endl;
for(int i=0;i<ExpLimit->GetN();i++){
double M = ExpLimit->GetX()[i];
std::cout << "Mass: " << M << "; ExpLimit: " << ExpLimit->Eval(M) << std::endl;
printf("$%8.6E$ & $%8.6E$ & $[%8.6E,%8.6E]$ & $[%8.6E,%8.6E]$ \\\\\\hline\n",M, ExpLimit->Eval(M), ExpLimitm1->Eval(M), ExpLimitp1->Eval(M), ExpLimitm2->Eval(M), ExpLimitp2->Eval(M));
fprintf(pFileSStrenght, "$%8.6E$ & $%8.6E$ & $[%8.6E,%8.6E]$ & $[%8.6E,%8.6E]$ & $%8.6E$ \\\\\\hline\n",M, ExpLimit->Eval(M), ExpLimitm1->Eval(M), ExpLimitp1->Eval(M), ExpLimitm2->Eval(M), ExpLimitp2->Eval(M), ObsLimit->Eval(M));
if(int(ExpLimit->GetX()[i])%50!=0)continue; //printf("%f ",ObsLimit->Eval(M));
}printf("\n");
fclose(pFileSStrenght);
//get the pValue
inputs = inputs.ReplaceAll("/LimitTree", "/PValueTree");
file = TFile::Open(inputs);
printf("Looping on %s\n",inputs.Data());
if(!file) return;
if(file->IsZombie()) return;
tree = (TTree*)file->Get("limit");
tree->GetBranch("limit" )->SetAddress(&Tlimit );
TGraph* pValue = getLimitGraph(tree,-1);
file->Close();
//make TH Cross-sections
string suffix = outputDir;
TGraph* THXSec = Hxswg::utils::getXSec(outputDir);
scaleGraph(THXSec, 1000); //convert cross-section to fb
double cprime=1.0; double brnew=0.0;
double XSecScaleFactor = 1.0;
if(suffix.find("_cp")!=string::npos){
sscanf(suffix.c_str()+suffix.find("_cp"), "_cp%lf_brn%lf", &cprime, &brnew);
XSecScaleFactor = pow(cprime,2) * (1-brnew);
}
//XSecScaleFactor = 0.001; //pb to fb
scaleGraph(THXSec, XSecScaleFactor);
string prod = "pp_SM";
if(outputDir.find("ggH")!=std::string::npos)prod="gg";
if(outputDir.find("qqH")!=std::string::npos)prod="qq";
if(outputDir.find("ppH")!=std::string::npos)prod="pp";
strengthLimit = false;
if(prod=="pp_SM")strengthLimit=true;
//TGraph *XSecMELA = Hxswg::utils::getXSecMELA(cprime);
//Hxswg::utils::multiplyGraph( ObsLimit, XSecMELA);
//Hxswg::utils::multiplyGraph( ExpLimitm2, XSecMELA);
//Hxswg::utils::multiplyGraph( ExpLimitm1, XSecMELA);
//Hxswg::utils::multiplyGraph( ExpLimit, XSecMELA);
//Hxswg::utils::multiplyGraph( ExpLimitp1, XSecMELA);
//Hxswg::utils::multiplyGraph( ExpLimitp2, XSecMELA);
//Scale exclusion XSec in fb
scaleGraph(ObsLimit , 0.001); //pb to fb
scaleGraph(ExpLimitm2, 0.001); //pb to fb
scaleGraph(ExpLimitm1, 0.001); //pb to fb
scaleGraph(ExpLimit , 0.001); //pb to fb
scaleGraph(ExpLimitp1, 0.001); //pb to fb
scaleGraph(ExpLimitp2, 0.001); //pb to fb
//scal eTH cross-section and limits according to scale factor
//this only apply to NarrowResonnance case
if(strengthLimit){
Hxswg::utils::divideGraph(ObsLimit , THXSec);
Hxswg::utils::divideGraph(ExpLimitm2 , THXSec);
Hxswg::utils::divideGraph(ExpLimitm1 , THXSec);
Hxswg::utils::divideGraph(ExpLimit , THXSec);
Hxswg::utils::divideGraph(ExpLimitp1 , THXSec);
Hxswg::utils::divideGraph(ExpLimitp2 , THXSec);
Hxswg::utils::divideGraph(THXSec , THXSec);
}
//limits in terms of signal strength
TCanvas* c = new TCanvas("c", "c",800,800);
c->SetGridx();
c->SetGridy();
TH1F* framework = new TH1F("Graph","Graph",1,strengthLimit?199:199,2500); //3000);
framework->SetStats(false);
framework->SetTitle("");
framework->GetXaxis()->SetTitle("M_{H} [GeV]");
framework->GetYaxis()->SetTitleOffset(1.70);
if(strengthLimit){
framework->GetYaxis()->SetTitle("#mu = #sigma_{95%} / #sigma_{th}");
framework->GetYaxis()->SetRangeUser(1E-4,1E3);
c->SetLogy(true);
}else{
framework->GetYaxis()->SetTitle((string("#sigma_{95%} (") + prod +" #rightarrow H #rightarrow ZZ) (pb)").c_str());
framework->GetYaxis()->SetRangeUser(1E-3,1E3);
c->SetLogy(true);
}
framework->GetXaxis()->SetLabelOffset(0.007);
framework->GetXaxis()->SetLabelSize(0.03);
framework->GetXaxis()->SetTitleOffset(1.0);
framework->GetXaxis()->SetTitleFont(42);
framework->GetXaxis()->SetTitleSize(0.035);
framework->GetYaxis()->SetLabelFont(42);
framework->GetYaxis()->SetLabelOffset(0.007);
framework->GetYaxis()->SetLabelSize(0.03);
framework->GetYaxis()->SetTitleOffset(1.3);
framework->GetYaxis()->SetTitleFont(42);
framework->GetYaxis()->SetTitleSize(0.035);
framework->Draw();
TGraph* TGObsLimit = ObsLimit; TGObsLimit->SetLineWidth(2);
TGraph* TGExpLimit = ExpLimit; TGExpLimit->SetLineWidth(2); TGExpLimit->SetLineStyle(2);
TCutG* TGExpLimit1S = GetErrorBand("1S", ExpLimitm1, ExpLimitp1);
TCutG* TGExpLimit2S = GetErrorBand("2S", ExpLimitm2, ExpLimitp2); TGExpLimit2S->SetFillColor(5);
THXSec->SetLineWidth(2); THXSec->SetLineStyle(1); THXSec->SetLineColor(4);
TGExpLimit->SetLineColor(1); TGExpLimit->SetLineStyle(2);
TGObsLimit->SetLineWidth(2); TGObsLimit->SetMarkerStyle(20);
TGExpLimit2S->Draw("fc same");
TGExpLimit1S->Draw("fc same");
if(!blind) TGObsLimit->Draw("same P");
TGExpLimit->Draw("same c");
/*if(strengthLimit){
TLine* SMLine = new TLine(framework->GetXaxis()->GetXmin(),1.0,framework->GetXaxis()->GetXmax(),1.0);
SMLine->SetLineWidth(2); SMLine->SetLineStyle(1); SMLine->SetLineColor(4);
SMLine->Draw("same C");
}else{
THXSec->Draw("same C");
}*/
utils::root::DrawPreliminary(luminosity, energy, c);
TLegend* LEG = new TLegend(0.55,0.75,0.85,0.95);
LEG->SetHeader("");
LEG->SetFillColor(0);
LEG->SetFillStyle(0);
LEG->SetTextFont(42);
LEG->SetBorderSize(0);
//LEG->AddEntry(THXSec , "Th prediction" ,"L");
LEG->AddEntry(TGExpLimit , "median expected" ,"L");
LEG->AddEntry(TGExpLimit1S , "expected #pm 1#sigma" ,"F");
LEG->AddEntry(TGExpLimit2S , "expected #pm 2#sigma" ,"F");
if(!blind) LEG->AddEntry(TGObsLimit , "observed" ,"LP");
LEG->Draw();
c->RedrawAxis();
c->SaveAs((outputDir+"Limit.png").c_str());
c->SaveAs((outputDir+"Limit.C").c_str());
c->SaveAs((outputDir+"Limit.pdf").c_str());
//save a summary of the limits
FILE* pFileSum = fopen((outputDir+"LimitSummary").c_str(),"w");
for(int i=0;i<TGExpLimit->GetN();i++){
double M = ExpLimit->GetX()[i];
fprintf(pFileSum, "$%8.6E$ & $%8.6E$ & $[%8.6E,%8.6E]$ & $[%8.6E,%8.6E]$ & $%8.6E$ & Th=$%8.6E$ & pValue=$%8.6E$\\\\\\hline\n",M, ExpLimit->Eval(M), ExpLimitm1->Eval(M), ExpLimitp1->Eval(M), ExpLimitm2->Eval(M), ExpLimitp2->Eval(M), ObsLimit->Eval(M), (THXSec!=NULL)?THXSec->Eval(M):-1, pValue->Eval(M));
if(int(ExpLimit->GetX()[i])%50!=0)continue; printf("%f ",ObsLimit->Eval(M));
}printf("\n");
fclose(pFileSum);
pFileSum = fopen((outputDir+"LimitRange").c_str(),"w");
fprintf(pFileSum, "EXPECTED LIMIT --> "); printLimits(pFileSum,TGExpLimit, TGExpLimit->GetX()[0], TGExpLimit->GetX()[TGExpLimit->GetN()-1]);
if(!blind) fprintf(pFileSum, "OBSERVED LIMIT --> "); printLimits(pFileSum,TGObsLimit, TGObsLimit->GetX()[0], TGObsLimit->GetX()[TGObsLimit->GetN()-1]);
fprintf(pFileSum, "Exp Limits for Model are: "); for(int i=0;i<TGExpLimit->GetN();i++){if(int(TGExpLimit->GetX()[i])%50==0) fprintf(pFileSum, "%f+-%f ",TGExpLimit->GetY()[i], (ExpLimitp1->GetY()[i]-ExpLimitm1->GetY()[i])/2.0);}fprintf(pFileSum,"\n");
if(!blind) { fprintf(pFileSum, "Obs Limits for Model are: "); for(int i=0;i<TGObsLimit->GetN();i++){if(int(TGObsLimit->GetX()[i])%50==0) fprintf(pFileSum, "%f ",TGObsLimit->GetY()[i]);}fprintf(pFileSum,"\n"); }
fclose(pFileSum);
}