Beispiel #1
0
// Modes: linear or log
plotHistogram(const char* canvas, const char* mode, const char* title,
	      double xlo, double xhi, int nbin,
	      double* sig, double* sigerr, double* bgr, double* bgrerr)
{
  TCanvas *c 
    = new TCanvas(canvas,"SPR Classifier Output",200,10,600,400);
  gStyle->SetPalette(1);
  TLegend *leg = new TLegend(0.1,0.85,0.5,1.,"Classifier Output","NDC");
  double dx = (xhi-xlo) / nbin;
  TH1D* hs = new TH1D("signal",    title,nbin,xlo,xhi);
  TH1D* hb = new TH1D("background",title,nbin,xlo,xhi);
  leg->AddEntry(hs,"Signal","L");
  leg->AddEntry(hb,"Background","L");
  for( int i=0;i<nbin;i++ ) {
    hs->SetBinContent(i+1,sig[i]);
    hs->SetBinError(i+1,sigerr[i]);
    hb->SetBinContent(i+1,bgr[i]);
    hb->SetBinError(i+1,bgrerr[i]);
  }
  TPad* pad = new TPad("pad","pad",0,0,1,1);
  if( strcmp(mode,"log") == 0 ) pad->SetLogy(1);
  pad->Draw();
  pad->cd();
  hs->SetLineColor(2);
  hs->SetLineWidth(3);
  hb->SetLineColor(4);
  hb->SetLineWidth(3);
  hb->Draw();
  hs->Draw("same");
  leg->Draw();
}
Beispiel #2
0
void LHCHiggsExample() 
{ 

#ifdef __CINT__
  gROOT->LoadMacro("LHCHiggsUtils.C");
#endif

  SetLHCHiggsStyle();

  TCanvas* c1 = new TCanvas("c1","Higgs Cross Section",50,50,600,600);
  TPad* thePad = (TPad*)c1->cd();
  thePad->SetLogy();

  Double_t ymin=1.e-2;  Double_t ymax=1.e2;
  Double_t xmin=90.00;  Double_t xmax=600.;
  TH1F *h1 = thePad->DrawFrame(xmin,ymin,xmax,ymax);
  h1->SetYTitle("#sigma_{pp #rightarrow H} [pb]");
  h1->SetXTitle("M_{H}  [GeV]");
  h1->GetYaxis()->SetTitleOffset(1.4);
  h1->GetXaxis()->SetTitleOffset(1.4);
  //h1->GetXaxis()->SetNdivisions(5);
  h1->Draw();

  myText(0.2,0.88,1,"#sqrt{s}= 13 TeV");
  myBoxText(0.55,0.67,0.05,5,"NNLO QCD");

  LHCHIGGS_LABEL(0.98,0.725);
  myText(0.2,0.2,1,"Preliminary");

  c1->Print("LHCHiggsExample.eps");
  c1->Print("LHCHiggsExample.png");
  c1->Print("LHCHiggsExample.pdf");

}
Beispiel #3
0
/** 
 * Draw the Poisson estimate of the occupancy in a given ring.
 * 
 * @param p            List 
 * @param d            Detector
 * @param r            Ring
 * 
 * @return The occupancy (in percent)
 *
 * @deprecated Use QATrender instead
 * @ingroup pwglf_forward_scripts_qa
 */
Double_t
DrawRingOccupancy(TList* p, UShort_t d, Char_t r)
{
  if (!p) return 0;

  TList* ring = static_cast<TList*>(p->FindObject(Form("FMD%d%c",d,r)));
  if (!ring) { 
    Error("DrawOccupancy", "List FMD%d%c not found in %s",d,r,p->GetName());
    return 0;
  }
  
  TH1* corr = static_cast<TH1*>(ring->FindObject("occupancy"));
  if (!corr) { 
    Error("DrawRingOccupancy", "Histogram occupancy not found in FMD%d%c",
	  d, r);
    return 0;
  }
  corr->Rebin(4);

  TPad* pad = static_cast<TPad*>(gPad);
  pad->SetGridy();
  pad->SetGridx();
  pad->SetLogy();
  pad->SetFillColor(0);
    pad->SetRightMargin(0.01);
#if 0
  if (d == 3) { 
    pad->SetPad(pad->GetXlowNDC(), pad->GetYlowNDC(), .99, 
		 pad->GetYlowNDC()+pad->GetHNDC());
    pad->SetRightMargin(0.15);
  }
#endif

  corr->Draw("hist");

  TLatex* ltx = new TLatex(.95, .95, Form("FMD%d%c", d, r));
  ltx->SetNDC();
  ltx->SetTextAlign(33);
  ltx->SetTextSize(.08);
  ltx->Draw();

  return corr->GetMean();
}
void EMCDistribution(TString gain = "CALIB", bool log_scale = false)
{
  TText *t;
  TCanvas *c1 = new TCanvas(
      "EMCDistribution_" + gain + TString(log_scale ? "_Log" : "") + cuts,
      "EMCDistribution_" + gain + TString(log_scale ? "_Log" : "") + cuts, 1800,
      1000);
  c1->Divide(8, 8, 0., 0.01);
  int idx = 1;
  TPad *p;

  for (int iphi = 8 - 1; iphi >= 0; iphi--)
  {
    for (int ieta = 0; ieta < 8; ieta++)
    {
      p = (TPad *) c1->cd(idx++);
      c1->Update();

      p->SetLogy();
      p->SetGridx(0);
      p->SetGridy(0);

      TString hname = Form("hEnergy_ieta%d_iphi%d", ieta, iphi) + TString(log_scale ? "_Log" : "");

      TH1 *h = NULL;

      if (log_scale)
        h = new TH1F(hname,
                     Form(";Calibrated Tower Energy Sum (GeV);Count / bin"), 300,
                     5e-3, 3096);
      else
        //            h = new TH1F(hname,
        //                Form(";Calibrated Tower Energy Sum (GeV);Count / bin"), 196,
        //                1900, 2096);
        h = new TH1F(hname,
                     Form(";Calibrated Tower Energy Sum (GeV);Count / bin"), 596,
                     -96, 500);

      h->SetLineWidth(0);
      h->SetLineColor(kBlue + 3);
      h->SetFillColor(kBlue + 3);
      h->GetXaxis()->SetTitleSize(.09);
      h->GetXaxis()->SetLabelSize(.08);
      h->GetYaxis()->SetLabelSize(.08);

      if (log_scale)
        QAHistManagerDef::useLogBins(h->GetXaxis());

      T->Draw(
          "TOWER_" + gain + "_CEMC[].get_energy_power_law_exp()>>" + hname,
          Form(
              "TOWER_%s_CEMC[].get_bineta()==%d && TOWER_%s_CEMC[].get_binphi()==%d",
              gain.Data(), ieta, gain.Data(), iphi),
          "");

      TText *t = new TText(.9, .9, Form("Col%d Row%d", ieta, iphi));
      t->SetTextAlign(33);
      t->SetTextSize(.15);
      t->SetNDC();
      t->Draw();

      //          return;
    }
  }

  SaveCanvas(c1,
             TString(_file0->GetName()) + TString("_DrawPrototype3EMCalTower_") + TString(c1->GetName()), false);
}
void EMCDistribution_PeakSample_Fast(bool full_gain = false)
{
  const TString gain = "RAW";

  TString hname = "EMCDistribution_" + gain + TString(full_gain ? "_FullGain" : "") + cuts;

  TH2 *h2 = NULL;
  {
    if (full_gain)
    {
      h2 = new TH2F(hname,
                    Form(";Calibrated Tower Energy Sum (ADC);Count / bin"), 100,
                    .05 * 100, 25 * 100, 64, -.5, 63.5);
      QAHistManagerDef::useLogBins(h2->GetXaxis());
    }
    else
    {
      h2 = new TH2F(hname,
                    Form(";Calibrated Tower Energy Sum (ADC);Count / bin"), 260,
                    -.2 * 100, 5 * 100, 64, -.5, 63.5);
    }
    T->Draw(
        "TOWER_" + gain + "_CEMC[].get_bineta() + 8* TOWER_" + gain + "_CEMC[].get_binphi():(TOWER_RAW_CEMC[].signal_samples[10] - TOWER_RAW_CEMC[].signal_samples[0])*(-1)>>" + hname, "", "goff");
  }

  TText *t;
  TCanvas *c1 = new TCanvas(
      "EMCDistribution_PeakSample_Fast_" + TString(full_gain ? "_FullGain" : "") + cuts,
      "EMCDistribution_PeakSample_Fast_" + TString(full_gain ? "_FullGain" : "") + cuts, 1800, 950);
  c1->Divide(8, 8, 0., 0.01);
  int idx = 1;
  TPad *p;

  for (int iphi = 8 - 1; iphi >= 0; iphi--)
  {
    for (int ieta = 0; ieta < 8; ieta++)
    {
      p = (TPad *) c1->cd(idx++);
      c1->Update();

      p->SetLogy();
      if (full_gain)
      {
        p->SetLogx();
      }
      p->SetGridx(0);
      p->SetGridy(0);

      TString hname = Form("hEnergy_ieta%d_iphi%d", ieta, iphi) + TString(full_gain ? "_FullGain" : "");

      TH1 *h = h2->ProjectionX(hname, ieta + 8 * iphi + 1,
                               ieta + 8 * iphi + 1);  // axis bin number is encoded as ieta+8*iphi+1

      h->SetLineWidth(0);
      h->SetLineColor(kBlue + 3);
      h->SetFillColor(kBlue + 3);

      h->GetXaxis()->SetTitleSize(.09);
      h->GetXaxis()->SetLabelSize(.08);
      h->GetYaxis()->SetLabelSize(.08);

      h->Draw();

      if (full_gain)
        h->Fit("x*gaus", "M");
      else
        h->Fit("landau", "M");

      double peak = -1;

      TF1 *fit = ((TF1 *) (h->GetListOfFunctions()->At(0)));
      if (fit)
      {
        fit->SetLineColor(kRed);
        peak = fit->GetParameter(1);
      }

      cout << Form("Finished <Col%d Row%d> = %.1f", ieta, iphi, peak)
           << endl;

      TText *t = new TText(.9, .9,
                           Form("<Col%d Row%d> = %.1f", ieta, iphi, peak));
      t->SetTextAlign(33);
      t->SetTextSize(.15);
      t->SetNDC();
      t->Draw();
    }
  }

  SaveCanvas(c1,
             TString(_file0->GetName()) + TString("_DrawPrototype3EMCalTower_") + TString(c1->GetName()), false);
}
Beispiel #6
0
void vs_PlotQCDcomp() {

  Bool_t saveC  = false;
  Bool_t diJets = true;
  Bool_t isMC   = false;

  TString vsSave;
  vsSave = "_T07w";

  TString jSave;
  if(diJets) jSave = "2j";
  else       jSave = "3j";

  TString sample;
  if(diJets) sample = "select_1ph_2jets";
  else       sample = "select_1ph_3jets";

  TString FOtag;
  if(isMC) FOtag = "_FO_CorrMC";
  //  else     FOtag = "_FO_Corr";
  else     FOtag = "_FO";

  TString sysu = "SYSTUP_";
  TString sysd = "SYSTDOWN_";

  TString outDir;
  outDir = "Plots_PhotonSusyAnalysis/QCDweights/";


  //  string inputFile1 = "/data/user/vsola/CMSSW_Releases/CMSSW_5_3_9/src/Plots_PhotonSusyAnalysis/Merged_QCD_PhotonJet_T07w_PAT/mergedHistos.root";
  //  string inputFile1 = "/data/user/vsola/CMSSW_Releases/CMSSW_5_3_9/src/Plots_PhotonSusyAnalysis/Merged_Data_V05w_PAT/mergedHistos.root";
  string inputFile1 = "/data/user/vsola/CMSSW_Releases/CMSSW_5_3_9/src/Plots_PhotonSusyAnalysis/PhotonHadReReco_22Jan2013_V05_PAT/mergedHistos.root";
  
  
  setMyTDRStyle();
  gROOT->SetStyle("mytdrStyle");
  
  //  gStyle->SetHistMinimumZero();
  //  gStyle->SetPaintTextFormat("4.2f");

  gStyle->SetHistLineWidth(2);
  gStyle->UseCurrentStyle();

  //  gStyle->SetPadTopMargin(1.0);
  //  gStyle->SetPadLeftMargin(3.2);
  //  gStyle->SetPadRightMargin(4.5);
  //  gStyle->SetPadBottomMargin(3.2);

  gROOT->ForceStyle(1);


  static const Int_t nHt  =  7;
  static const Int_t nPt  = 13;
  static const Int_t nMet = 16;
  static const Int_t nJet = 15;

  Double_t binPt[nPt+1]   = {0.,75.,90.,120.,160.,210.,260.,320.,400.,500.,650.,800.,1000.,1500.};
  Double_t binHt[nHt+1]   = {0.,400.,450.,550.,700.,900.,1200.,1500.};
  Double_t binMet[nMet+1] = {0.,10.,20.,30.,40.,50.,60.,70.,80.,90.,100.,120.,160.,200.,270.,350.,500.};
  Double_t binJet[nJet+1] = {0.,1.,2.,3.,4.,5.,6.,7.,8.,9.,10.,11.,12.,13.,14.,15};


  TLatex *as = new TLatex();
  as->SetNDC(true);
  as->SetTextColor(12);
  as->SetTextFont(43);
  as->SetTextSize(19);

  TLegend *legend = new TLegend(0.60, 0.70, 0.75, 0.85, "");
  legend->SetFillColor(10);
  legend->SetFillStyle(1001);
  legend->SetTextSize(0.04);
  legend->SetBorderSize(0);
  legend->SetShadowColor(0);

  std::string outLumi  = "CMS Work in Progress - QCD MC #sqrt{s} = 8 TeV - #geq 1 #gamma, #geq 2 j";

  TFile* f1 = TFile::Open( inputFile1.c_str() );

  //photon Pt
  TCanvas * cPt = new TCanvas("cPt","cPt");

  TH1F* hpt   = (TH1F*) f1->Get( sample+"/PreselCut_photonPt" );
  TH1F* hptFO = (TH1F*) f1->Get( sample+FOtag+"/PreselCut_photonPt" );

  TH1F *hptR = (TH1F*) hpt->Rebin(nPt,hpt->GetTitle(),binPt);
  if (hptR->GetSumw2N() == 0)
    hptR->Sumw2();

  TH1F *hptFOR = (TH1F*) hptFO->Rebin(nPt,hptFO->GetTitle(),binPt);
  if (hptFOR->GetSumw2N() == 0)
    hptFOR->Sumw2();

  TH1F* hptSU = (TH1F*) f1->Get( sample+FOtag+"/PreselCut_"+sysu+"photonPt" );
  TH1F* hptSD = (TH1F*) f1->Get( sample+FOtag+"/PreselCut_"+sysd+"photonPt" );

  TH1F *hptSUR = (TH1F*) hptSU->Rebin(nPt,hptSU->GetTitle(),binPt);
  if (hptSUR->GetSumw2N() == 0)
    hptSUR->Sumw2();

  TH1F *hptSDR = (TH1F*) hptSD->Rebin(nPt,hptSD->GetTitle(),binPt);
  if (hptSDR->GetSumw2N() == 0)
    hptSDR->Sumw2();

  if ( hptFOR != 0 ) {
    for (int b = 0; b < hptFOR->GetNbinsX(); b++) {

      Double_t mainHistoContent   = hptFOR->GetBinContent(b);
      Double_t systUpHistoContent = hptSUR->GetBinContent(b);
      Double_t systDnHistoContent = hptSDR->GetBinContent(b);
      Double_t systDiffUp = fabs( (double) systUpHistoContent - mainHistoContent );
      Double_t systDiffDn = fabs( (double) mainHistoContent - systDnHistoContent );

      // use average error for histogram
      Double_t systDiff = ( systDiffUp + systDiffDn ) / 2.;
      
      Double_t statErr   = hptFOR->GetBinError(b);
      Double_t combError = sqrt( systDiff * systDiff + statErr * statErr );
      hptFOR->SetBinError(b, combError);
    } //for
  }//if
    
  cPt->SetLogy(1);
  gPad->Update();
  cPt->Update();

  //  hptR->Scale(1,"width");
  //  hptR->SetMinimum(0.02);
  //  hptR->SetMaximum(1000); 
  hptR->GetXaxis()->SetTitle("1^{st} photon p_{T} [GeV]");
  hptR->GetYaxis()->SetTitle("Number of Events / GeV");

  if(isMC) hptR->SetMarkerSize(0);
  if(isMC) hptR->Draw("histE");
  else     hptR->Draw("E X0");


  hptFOR->SetMarkerSize(0);
  hptFOR->SetLineColor(2);
  hptFOR->SetFillColor(2);
  hptFOR->SetFillStyle(3004);
  hptFOR->Draw("same hist ][ E2");

  legend->Clear();
  if(isMC) legend->SetHeader("#gamma/QCD (Sim)");
  else     legend->SetHeader("#gamma/QCD (Data)");
  if(isMC) legend->AddEntry(hptR, "#gamma", "l");
  else     legend->AddEntry(hptR, "#gamma", "p");
  legend->AddEntry(hptFOR, "Pred (from #gamma_{jet})", "f");
  legend->Draw();

  as->DrawLatex(0.17, 0.93, outLumi.c_str() );
  cPt->Update();
  cPt->SetBottomMargin(0.2 + 0.8 * cPt->GetBottomMargin() - 0.2 * cPt->GetTopMargin());

  TPad *ratioPt = new TPad("BottomPad", "", 0, 0, 1, 1);
  ratioPt->SetTopMargin(0.8 - 0.8 * ratioPt->GetBottomMargin() + 0.2 * ratioPt->GetTopMargin());
  ratioPt->SetFillStyle(0);
  ratioPt->SetFrameFillColor(10);
  ratioPt->SetFrameBorderMode(0);
  ratioPt->Draw();

  ratioPt->cd();
  ratioPt->SetLogy(0);

  TH1F *hptRat = (TH1F*) divideHistosForRatio(hptR,hptFOR);
  hptRat->SetMinimum(0.);
  hptRat->SetMaximum(10.);
  hptRat->GetXaxis()->SetNdivisions(505);
  if(isMC) hptRat->GetYaxis()->SetTitle("Sim/Pred");
  else     hptRat->GetYaxis()->SetTitle("Data/Pred");
  hptRat->GetYaxis()->SetTitleSize(0.04);
  hptRat->GetYaxis()->SetLabelSize(0.03);
  hptRat->GetYaxis()->SetTitleOffset(1.3);
  hptRat->GetYaxis()->SetNdivisions(505);
  hptRat->SetMarkerStyle(20);
  hptRat->SetMarkerSize(1);
  hptRat->SetMarkerColor(1);
  hptRat->SetLineColor(1);
  hptRat->Draw("E X0");

  TH1F *hptFRat = (TH1F*) getSystErrForRatio(hptFOR);
  hptFRat->SetLineColor(2);
  hptFRat->SetFillColor(2);
  hptFRat->SetFillStyle(3004);
  hptFRat->Draw("same hist ][ E2");


  TLine * line = new TLine( hptRat->GetXaxis()->GetXmin(), 1., hptRat->GetXaxis()->GetXmax(), 1. );
  line->SetLineColor(1);
  line->SetLineWidth(0.5);
  line->SetLineStyle(1);
  line->Draw("same");

  hptR->GetXaxis()->SetLabelSize(0);
  hptR->GetXaxis()->SetTitle("");
  cPt->RedrawAxis();
  gPad->Update();
  cPt->Update();


  return;
}
void QA_Draw_CEMC_G4Hit(
    const char *qa_file_name_new =
        "/phenix/u/jinhuang/links/ePHENIX_work/sPHENIX_work/production_analysis_updates/spacal1d/fieldmap/G4Hits_sPHENIX_pi-_eta0.30_32GeV-0000.root_qa.root",
    const char *qa_file_name_ref =
        "/phenix/u/jinhuang/links/ePHENIX_work/sPHENIX_work/production_analysis_updates/spacal1d/fieldmap/G4Hits_sPHENIX_pi+_eta0.30_32GeV-0000.root_qa.root")

{
  SetsPhenixStyle();
  TVirtualFitter::SetDefaultFitter("Minuit2");

  TFile *qa_file_new = new TFile(qa_file_name_new);
  assert(qa_file_new->IsOpen());

  TFile *qa_file_ref = NULL;
  if (qa_file_name_ref)
  {
    qa_file_ref = new TFile(qa_file_name_ref);
    assert(qa_file_ref->IsOpen());
  }

  TCanvas *c1 = new TCanvas("QA_Draw_CEMC_G4Hit", "QA_Draw_CEMC_G4Hit", 1800, 900);
  c1->Divide(4, 2);
  int idx = 1;
  TPad *p;

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogz();

  TH2F *h_QAG4Sim_CEMC_G4Hit_XY = (TH2F *) qa_file_new->GetObjectChecked(
      "h_QAG4Sim_CEMC_G4Hit_XY", "TH2F");
  assert(h_QAG4Sim_CEMC_G4Hit_XY);
  h_QAG4Sim_CEMC_G4Hit_XY->GetYaxis()->SetTitleOffset(1.5);
  h_QAG4Sim_CEMC_G4Hit_XY->Draw("COLZ");

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogz();

  TH2F *h_QAG4Sim_CEMC_G4Hit_RZ = (TH2F *) qa_file_new->GetObjectChecked(
      "h_QAG4Sim_CEMC_G4Hit_RZ", "TH2F");
  assert(h_QAG4Sim_CEMC_G4Hit_RZ);
  h_QAG4Sim_CEMC_G4Hit_RZ->GetYaxis()->SetTitleOffset(1.5);
  h_QAG4Sim_CEMC_G4Hit_RZ->Draw("COLZ");

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogz();

  {
    TH2F *h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection =
        (TH2F *) qa_file_new->GetObjectChecked(
            "h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection", "TH2F");
    assert(h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection);

    TH1D *proj_new =
        h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection->ProjectionX(
            "qa_file_new_h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection_px");

    proj_new->Scale(1. / proj_new->GetSum());

    TH1D *proj_ref = NULL;
    if (qa_file_ref)
    {
      TH2F *h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection =
          (TH2F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection", "TH2F");
      assert(h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection);

      proj_ref = h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection->ProjectionX(
          "qa_file_ref_h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection_px");
      proj_ref->Scale(1. / proj_ref->GetSum());
    }

    proj_new->GetYaxis()->SetTitle("Normalized energy distribution");
    proj_new->GetXaxis()->SetRangeUser(-10, 10);

    DrawReference(proj_new, proj_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogz();

  {
    TH2F *h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection =
        (TH2F *) qa_file_new->GetObjectChecked(
            "h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection", "TH2F");
    assert(h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection);

    TH1D *proj_new =
        h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection->ProjectionY(
            "qa_file_new_h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection_py");

    proj_new->Scale(1. / proj_new->GetSum());

    TH1D *proj_ref = NULL;
    if (qa_file_ref)
    {
      TH2F *h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection =
          (TH2F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection", "TH2F");
      assert(h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection);

      proj_ref = h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection->ProjectionY(
          "qa_file_ref_h_QAG4Sim_CEMC_G4Hit_LateralTruthProjection_py");
      proj_ref->Scale(1. / proj_ref->GetSum());
    }

    proj_new->GetYaxis()->SetTitle("Normalized energy distribution");
    proj_new->GetXaxis()->SetRangeUser(-10, 10);

    DrawReference(proj_new, proj_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogx();
  p->SetLogy();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        "h_QAG4Sim_CEMC_G4Hit_HitTime", "TH1F");
    assert(h_new);

    h_new->Rebin(5);
    h_new->Scale(1. / h_new->GetSum());

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          "h_QAG4Sim_CEMC_G4Hit_HitTime", "TH1F");
      assert(h_ref);

      h_ref->Rebin(5);
      h_ref->Scale(1. / h_ref->GetSum());
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Normalized energy per bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //    p->SetLogx();
  p->SetLogy();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        "h_QAG4Sim_CEMC_G4Hit_FractionTruthEnergy", "TH1F");
    assert(h_new);

    h_new->Rebin(20);
    h_new->Sumw2();
    h_new->Scale(1. / h_new->GetSum());

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          "h_QAG4Sim_CEMC_G4Hit_FractionTruthEnergy", "TH1F");
      assert(h_ref);

      h_ref->Rebin(20);
      h_ref->Scale(1. / h_ref->GetSum());
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Probability per bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogz();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        "h_QAG4Sim_CEMC_G4Hit_VSF", "TH1F");
    assert(h_new);

    h_new->Rebin(2);
    h_new->Sumw2();
    h_new->Scale(1. / h_new->GetSum());

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          "h_QAG4Sim_CEMC_G4Hit_VSF", "TH1F");
      assert(h_ref);

      h_ref->Rebin(2);
      h_ref->Sumw2();
      h_ref->Scale(1. / h_ref->GetSum());
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Probability per bin");
    h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogz();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        "h_QAG4Sim_CEMC_G4Hit_FractionEMVisibleEnergy", "TH1F");
    assert(h_new);

    h_new->Rebin(4);
    h_new->Sumw2();
    h_new->Scale(1. / h_new->GetSum());

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          "h_QAG4Sim_CEMC_G4Hit_FractionEMVisibleEnergy", "TH1F");
      assert(h_ref);

      h_ref->Rebin(4);
      h_ref->Scale(1. / h_ref->GetSum());
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Probability per bin");
    //          h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

//  PutInputFileName(c1, .04, qa_file_name_new, qa_file_name_ref);
  SaveCanvas(c1, TString(qa_file_name_new) + TString(c1->GetName()), true);
}
void
QA_Draw_Calorimeter_Sum_TrackProjEP(
    const char * qa_file_name_new =
        "/phenix/u/jinhuang/links/ePHENIX_work/sPHENIX_work/production_analysis_updates/spacal1d/fieldmap/G4Hits_sPHENIX_pi-_eta0.30_32GeV-0000.root_qa.root",
    const char * qa_file_name_ref =
        "/phenix/u/jinhuang/links/ePHENIX_work/sPHENIX_work/production_analysis_updates/spacal1d/fieldmap/G4Hits_sPHENIX_pi+_eta0.30_32GeV-0000.root_qa.root")
//QA_Draw_Calorimeter_Sum_TrackProjEP(const char * qa_file_name_new =
//    "data/G4sPHENIXCells_100e24GeV.root_qa.root",
//    const char * qa_file_name_ref =
//        "data/G4Hits_sPHENIX_e-_eta0_24GeV-0000.root_qa.root")
{

  SetOKStyle();
  gStyle->SetOptStat(0);
  gStyle->SetOptFit(1111);
  TVirtualFitter::SetDefaultFitter("Minuit2");

  TFile * qa_file_new = new TFile(qa_file_name_new);
  assert(qa_file_new->IsOpen());

  TFile * qa_file_ref = NULL;
  if (qa_file_name_ref)
    {
      qa_file_ref = new TFile(qa_file_name_ref);
      assert(qa_file_ref->IsOpen());
    }

  // obtain normalization
  double Nevent_new = 1;
  double Nevent_ref = 1;

  // obtain normalization
  double Ntrack_new = 0;
  double Ntrack_ref = 0;

  if (qa_file_new)
    {
      TH1D * h_norm = (TH1D *) qa_file_new->GetObjectChecked(
          TString("h_QAG4Sim_CalorimeterSum_Normalization"), "TH1D");
      assert(h_norm);

      Nevent_new = h_norm->GetBinContent(h_norm->GetXaxis()->FindBin("Event"));
      Ntrack_new = h_norm->GetBinContent(h_norm->GetXaxis()->FindBin("Track"));
    }
  if (qa_file_ref)
    {
      TH1D * h_norm = (TH1D *) qa_file_ref->GetObjectChecked(
          TString("h_QAG4Sim_CalorimeterSum_Normalization"), "TH1D");
      assert(h_norm);

      Nevent_ref = h_norm->GetBinContent(h_norm->GetXaxis()->FindBin("Event"));
      Ntrack_ref = h_norm->GetBinContent(h_norm->GetXaxis()->FindBin("Track"));
    }

  TCanvas *c1 = new TCanvas("QA_Draw_Calorimeter_Sum_TrackProjEP",
      "QA_Draw_Calorimeter_Sum_TrackProjEP", 1800, 600);
  c1->Divide(3, 1);
  int idx = 1;
  TPad * p;

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  if (Ntrack_new>0)
    {
      TH1F * h_new = (TH1F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_CalorimeterSum_TrackProj_3x3Tower_EP", "TH1F");
      assert(h_new);

      h_new->Sumw2();
      h_new->Scale(1. / Ntrack_new);

      TH1F * h_ref = NULL;
      if (qa_file_ref)
        {
          TH1F * h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_CalorimeterSum_TrackProj_3x3Tower_EP", "TH1F");
          assert(h_ref);

          h_ref->Scale(1. / Ntrack_ref);
        }

      h_new->GetYaxis()->SetTitleOffset(1.5);
      h_new->GetYaxis()->SetTitle("Count / track / bin");
      //      h_new->GetXaxis()->SetRangeUser(-0, .1);

      DrawReference(h_new, h_ref);
    }


  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  if (Ntrack_new>0)
    {
      TH1F * h_new = (TH1F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_CalorimeterSum_TrackProj_5x5Tower_EP", "TH1F");
      assert(h_new);

      h_new->Sumw2();
      h_new->Scale(1. / Ntrack_new);

      TH1F * h_ref = NULL;
      if (qa_file_ref)
        {
          TH1F * h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_CalorimeterSum_TrackProj_5x5Tower_EP", "TH1F");
          assert(h_ref);

          h_ref->Scale(1. / Ntrack_ref);
        }

      h_new->GetYaxis()->SetTitleOffset(1.5);
      h_new->GetYaxis()->SetTitle("Count / track / bin");
      //      h_new->GetXaxis()->SetRangeUser(-0, .1);

      DrawReference(h_new, h_ref);
    }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  if (Nevent_new>0)
    {
      TH1F * h_new = (TH1F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_CalorimeterSum_Cluster_EP", "TH1F");
      if (h_new)
        {

          h_new->Sumw2();
          h_new->Scale(1. / Nevent_new);

          TH1F * h_ref = NULL;
          if (qa_file_ref)
            {
              TH1F * h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
                  "h_QAG4Sim_CalorimeterSum_Cluster_EP", "TH1F");
              assert(h_ref);

              h_ref->Scale(1. / Nevent_ref);
            }

          h_new->GetYaxis()->SetTitleOffset(1.5);
          h_new->GetYaxis()->SetTitle("Count / event / bin");
          //      h_new->GetXaxis()->SetRangeUser(-0, .1);

          DrawReference(h_new, h_ref);
        }
    }


  PutInputFileName(c1,0.07, qa_file_name_new, qa_file_name_ref);
  SaveCanvas(c1, TString(qa_file_name_new) + TString(c1->GetName()), true);
}
void determineWorkingPoint(TString algo="csv",TString baseURL="~/scratch0/top-nosyst/plotter.root")
{
  float workPoint(0.244);
  float sfb(1.020),    sfberr(0.04);      //from BTV-11-003
  float sflight(1.08), sflighterr(0.13);  //from BTV-11-002
  //  float sfb(0.99),        sfberr(0.099);      //from BTV-11-001
  //  float sflight(1.07882), sflighterr(0.244);  //from BTV-11-001
  if(algo=="tche")
    {
      workPoint=1.7;
      sfb=0.95; sfberr=0.095;
      sflight=1.08018; sflighterr=0.1125;
    }

  TObjArray bjets=getDistributionFromPlotter(algo+"b",baseURL);
  TObjArray lightjets=getDistributionFromPlotter(algo+"light",baseURL);
  
  TH1F *bDisc=(TH1F *) bjets.At(1);
  TH1F *lightDisc=(TH1F *) lightjets.At(1);
  
  setStyle();
  gStyle->SetOptFit(0);

  TCanvas *cnv = getNewCanvas("c","c",false);
  cnv->Clear();
  cnv->SetCanvasSize(1200,1200);
  cnv->SetWindowSize(1200,1200);
  cnv->Divide(2,2);

  //draw the discriminator
  TPad *p = (TPad *)cnv->cd(1); 
  bDisc->SetTitle("b");
  bDisc->SetLineColor(1);
  bDisc->SetMarkerColor(1);
  bDisc->SetMarkerStyle(20);
  bDisc->SetFillStyle(0);
  bDisc->DrawNormalized("histe1");
  lightDisc->SetLineColor(1);
  lightDisc->SetMarkerColor(1);
  lightDisc->SetMarkerStyle(24);
  lightDisc->SetFillStyle(0);
  lightDisc->SetTitle("udcsg");
  lightDisc->DrawNormalized("histe1same");
  TLegend *leg=p->BuildLegend();
  formatForCmsPublic(p,leg,"CMS simulation",2);

  //draw the b/light efficiencies
  p=(TPad *)cnv->cd(2);
  p->SetLogy();
  TGraphAsymmErrors *bEff     = getEfficiencyFrom(bDisc);
  TGraphAsymmErrors *lightEff = getEfficiencyFrom(lightDisc);
  bEff->SetMarkerStyle(20);
  bEff->SetFillStyle(0);
  bEff->Draw("ap");
  bEff->GetXaxis()->SetTitle(bDisc->GetXaxis()->GetTitle());
  bEff->GetYaxis()->SetTitle("Efficiency");
  lightEff->SetMarkerStyle(24);
  lightEff->SetFillStyle(0);
  lightEff->Draw("p");

  //draw relatively to a given working point
  p=(TPad *)cnv->cd(3);
  Double_t baseBEff=bEff->Eval(workPoint);
  TGraphAsymmErrors *relBEff=new TGraphAsymmErrors;
  relBEff->SetMarkerStyle(20);
  relBEff->SetFillStyle(0);
  Double_t baseLightEff=lightEff->Eval(workPoint);
  TGraphAsymmErrors *relLightEff=new TGraphAsymmErrors;
  relLightEff->SetMarkerStyle(24);
  relLightEff->SetFillStyle(0);
  for(int ip=0; ip<bEff->GetN(); ip++)
    {
      Double_t cut, y,ey; 
      bEff->GetPoint(ip,cut,y);     ey = bEff->GetErrorY(ip);
      Double_t relEff(y/baseBEff);
      if(relEff<sfb+2*sfberr && relEff>sfb-2*sfberr)
	{
	  int ipt=relBEff->GetN();
	  relBEff->SetPoint(ipt,cut,relEff);
	  relBEff->SetPointError(ipt,0,0,ey/baseBEff,ey/baseBEff);
	}

      lightEff->GetPoint(ip,cut,y);     ey = lightEff->GetErrorY(ip);
      relEff=y/baseLightEff;
      //      if(relEff<sflight+7*sflighterr && relEff>sflight-7*sflighterr)
      if(relEff<sflight+3*sflighterr && relEff>sflight-3*sflighterr)
	{
	  int ipt=relLightEff->GetN();
	  relLightEff->SetPoint(ipt,cut,relEff);
	  relLightEff->SetPointError(ipt,0,0,ey/baseLightEff,ey/baseLightEff);
	}
    }

  relLightEff->Draw("ap");
  relLightEff->GetXaxis()->SetTitle( bDisc->GetXaxis()->GetTitle() );
  relLightEff->GetYaxis()->SetTitle( "#varepsilon/#varepsilon_{0}" );
  relLightEff->Fit("expo","Q+");
  TF1 *ffunc=relLightEff->GetFunction("expo");
  float newLightCut=(TMath::Log(sflight)-ffunc->GetParameter(0))/ffunc->GetParameter(1);
  float newLightCutErrPlus=(TMath::Log(sflight+sflighterr)-ffunc->GetParameter(0))/ffunc->GetParameter(1)-newLightCut;
  float newLightCutErrMinus=(TMath::Log(sflight-sflighterr)-ffunc->GetParameter(0))/ffunc->GetParameter(1)-newLightCut;
  TArrow *lightArrow = new TArrow(newLightCut, sflight-3*sflighterr, newLightCut, sflight-3*sflighterr*0.8, 0.02, "<|");
  lightArrow->SetLineColor(kGray+2);
  lightArrow->SetFillColor(kGray+2);
  lightArrow->Draw("SAME <|");

  relBEff->Draw("p");
  relBEff->Fit("expo","Q+");
  ffunc=relBEff->GetFunction("expo");
  float newBCut=(TMath::Log(sfb)-ffunc->GetParameter(0))/ffunc->GetParameter(1);
  float newBCutErrPlus=(TMath::Log(sfb+sfberr)-ffunc->GetParameter(0))/ffunc->GetParameter(1)-newBCut;
  float newBCutErrMinus=(TMath::Log(sfb-sfberr)-ffunc->GetParameter(0))/ffunc->GetParameter(1)-newBCut;
  cout <<  sfb << " " << sfb+sfberr << " " << sfb-sfberr << endl;
  TArrow *bArrow    = new TArrow(newBCut, sflight-3*sflighterr, newBCut, sflight-3*sflighterr*0.8, 0.02, "<|");
  bArrow->Draw("SAME <|");

  //draw epsilon_b vs epsilon_q
  p=(TPad *)cnv->cd(4);
  p->SetLogy();

  TGraphAsymmErrors *perf=new TGraphAsymmErrors;
  perf->SetName("algoperformance");
  perf->SetMarkerStyle(20);
  perf->SetFillStyle(0);
  for(int ip=0; ip<bEff->GetN(); ip++)
    {
      Double_t cut;
      Double_t x,ex; bEff->GetPoint(ip,cut,x);     ex = bEff->GetErrorY(ip);
      Double_t y,ey; lightEff->GetPoint(ip,cut,y); ey = lightEff->GetErrorY(ip);
      perf->SetPoint(ip,x,y);
      perf->SetPointError(ip,ex,ex,ey,ey);
    }
  perf->Draw("ap");
  perf->GetXaxis()->SetTitle( bEff->GetTitle() );
  perf->GetYaxis()->SetTitle( lightEff->GetTitle() );

  //new performance expected after applying the new cuts
  TGraphAsymmErrors *newperf=new TGraphAsymmErrors;
  newperf->SetName("newalgoperformance");
  newperf->SetMarkerStyle(24);
  newperf->SetFillStyle(0);
  newperf->SetLineWidth(2);
  newperf->SetLineColor(kRed);
  newperf->SetLineColor(kRed);
  newperf->SetPoint(0,baseBEff*sfb,baseLightEff*sflight);
  newperf->SetPointError(0,baseBEff*sfberr,baseBEff*sfberr,baseLightEff*sflighterr,baseLightEff*sflighterr);
  newperf->Draw("p");

  cnv->Modified();
  cnv->Update();
  cnv->SaveAs("discFlavor.C");  
  cnv->SaveAs("discFlavor.png");  


  cout << "[determineWorkingPoint]" << endl
       << "To emulate the measured scale-factors you can use the following new cuts per jet flavor" << endl
       << "SF-b : "     << newBCut << " +" << newBCutErrPlus << " " << newBCutErrMinus << endl
       << "SF-light : " << newLightCut << " +" << newLightCutErrPlus << " " << newLightCutErrMinus << endl;
}
Beispiel #10
0
void limit()
{
//=========Macro generated from canvas: limit/limit
//=========  (Thu Apr 27 14:38:33 2017) by ROOT version6.02/05
   TCanvas *limit = new TCanvas("limit", "limit",0,0,600,600);
   gStyle->SetOptFit(1);
   gStyle->SetOptStat(0);
   gStyle->SetOptTitle(0);
   limit->SetHighLightColor(2);
   limit->Range(0,0,1,1);
   limit->SetFillColor(0);
   limit->SetBorderMode(0);
   limit->SetBorderSize(2);
   limit->SetLeftMargin(0.16);
   limit->SetRightMargin(0.04);
   limit->SetTopMargin(0.06);
   limit->SetBottomMargin(0.12);
   limit->SetFrameFillStyle(0);
   limit->SetFrameBorderMode(0);
  
// ------------>Primitives in pad: pad
   TPad *pad = new TPad("pad", "pad",0,0,1,1);
   pad->Draw();
   pad->cd();
   pad->Range(-59.99999,-2.046818,1565,15.01);
   pad->SetFillColor(0);
   pad->SetBorderMode(0);
    pad->SetLogy();
   pad->SetBorderSize(2);
   pad->SetTickx(1);
   pad->SetTicky(1);
   pad->SetLeftMargin(0.16);
   pad->SetRightMargin(0.04);
   pad->SetTopMargin(0.06);
   pad->SetBottomMargin(0.12);
   pad->SetFrameFillStyle(0);
   pad->SetFrameBorderMode(0);
   pad->SetFrameFillStyle(0);
   pad->SetFrameBorderMode(0);
   
   TH1F *tmp01 = new TH1F("tmp01","Graph",100,200,1500);
   tmp01->SetMinimum(0.);
   tmp01->SetMaximum(13.98659);
   tmp01->SetStats(0);
   tmp01->SetLineStyle(0);
   tmp01->SetMarkerStyle(20);
   tmp01->GetXaxis()->SetTitle("m_{H} (GeV)");
   tmp01->GetXaxis()->SetLabelFont(42);
   tmp01->GetXaxis()->SetLabelOffset(0.01);
   tmp01->GetXaxis()->SetTitleSize(0.05);
   tmp01->GetXaxis()->SetTickLength(0.02);
   tmp01->GetXaxis()->SetTitleOffset(1.08);
   tmp01->GetXaxis()->SetTitleFont(42);
   tmp01->GetYaxis()->SetTitle("95% CL limit on #sigma/#sigma_{SM}");
   tmp01->GetYaxis()->SetLabelFont(42);
   tmp01->GetYaxis()->SetLabelOffset(0.007);
   tmp01->GetYaxis()->SetTitleSize(0.05);
   tmp01->GetYaxis()->SetTickLength(0.02);
   tmp01->GetYaxis()->SetTitleOffset(1.56);
   tmp01->GetYaxis()->SetTitleFont(42);
   tmp01->GetZaxis()->SetLabelFont(42);
   tmp01->GetZaxis()->SetLabelOffset(0.007);
   tmp01->GetZaxis()->SetTitleSize(0.05);
   tmp01->GetZaxis()->SetTickLength(0.02);
   tmp01->GetZaxis()->SetTitleFont(42);
   tmp01->Draw("AXIS");
   
   TH1F *tmp02 = new TH1F("tmp02","Graph",100,200,1500);
   tmp02->SetMinimum(0);
   tmp02->SetMaximum(13.98659);
   tmp02->SetStats(0);
   tmp02->SetLineStyle(0);
   tmp02->SetMarkerStyle(20);
   tmp02->GetXaxis()->SetTitle("m_{H} (GeV)");
   tmp02->GetXaxis()->SetLabelFont(42);
   tmp02->GetXaxis()->SetLabelOffset(0.01);
   tmp02->GetXaxis()->SetTitleSize(0.05);
   tmp02->GetXaxis()->SetTickLength(0.02);
   tmp02->GetXaxis()->SetTitleOffset(1.08);
   tmp02->GetXaxis()->SetTitleFont(42);
   tmp02->GetYaxis()->SetTitle("95% CL limit on #sigma/#sigma_{SM}");
   tmp02->GetYaxis()->SetLabelFont(42);
   tmp02->GetYaxis()->SetLabelOffset(0.007);
   tmp02->GetYaxis()->SetTitleSize(0.05);
   tmp02->GetYaxis()->SetTickLength(0.02);
   tmp02->GetYaxis()->SetTitleOffset(1.56);
   tmp02->GetYaxis()->SetTitleFont(42);
   tmp02->GetZaxis()->SetLabelFont(42);
   tmp02->GetZaxis()->SetLabelOffset(0.007);
   tmp02->GetZaxis()->SetTitleSize(0.05);
   tmp02->GetZaxis()->SetTickLength(0.02);
   tmp02->GetZaxis()->SetTitleFont(42);
   tmp02->Draw("AXIGSAME");
   
   Double_t Graph0_fx3001[27] = {
   200,
   250,
   300,
   350,
   400,
   450,
   500,
   550,
   600,
   650,
   700,
   750,
   800,
   850,
   900,
   950,
   1000,
   1050,
   1100,
   1150,
   1200,
   1250,
   1300,
   1350,
   1400,
   1450,
   1500};
   Double_t Graph0_fy3001[27] = {
   4.796875,
   2.148438,
   0.8398438,
   0.3857422,
   0.2001953,
   0.1088867,
   0.06591797,
   0.04736328,
   0.03564453,
   0.02783203,
   0.02294922,
   0.01806641,
   0.01513672,
   0.01220703,
   0.01123047,
   0.009277344,
   0.008300781,
   0.007324219,
   0.007324219,
   0.006347656,
   0.006347656,
   0.005371094,
   0.005371094,
   0.004394531,
   0.004394531,
   0.004394531,
   0.004394531};
   Double_t Graph0_felx3001[27] = {
   4.032346e-316,
   0,
   0,
   0,
   6.906313e-310,
   4.032343e-316,
   2.121996e-314,
   4.032582e-316,
   0,
   4.032588e-316,
   4.032343e-316,
   0,
   4.032584e-316,
   1.508018e-316,
   1.508219e-316,
   4.032589e-316,
   2.124327e-314,
   4.032593e-316,
   5.582942e-322,
   6.906313e-310,
   0,
   4.032344e-316,
   4.032583e-316,
   4.032588e-316,
   1.58101e-322,
   4.032293e-316,
   5.582942e-322};
   Double_t Graph0_fely3001[27] = {
   2.370331,
   1.057434,
   0.405159,
   0.1845837,
   0.09618759,
   0.05231667,
   0.03192902,
   0.02331161,
   0.01754379,
   0.01435089,
   0.01183319,
   0.009315491,
   0.008041382,
   0.006484985,
   0.005966187,
   0.004928589,
   0.00440979,
   0.004119873,
   0.004119873,
   0.003570557,
   0.003570557,
   0.00302124,
   0.00302124,
   0.002471924,
   0.002471924,
   0.002471924,
   0.002471924};
   Double_t Graph0_fehx3001[27] = {
   4.031643e-316,
   0,
   0,
   0,
   6.906313e-310,
   4.032106e-316,
   2.121996e-314,
   4.032349e-316,
   0,
   4.032354e-316,
   4.032106e-316,
   0,
   4.032351e-316,
   1.508018e-316,
   1.508219e-316,
   4.032356e-316,
   2.124327e-314,
   4.03236e-316,
   5.582942e-322,
   6.906313e-310,
   0,
   4.032107e-316,
   4.03235e-316,
   4.032354e-316,
   1.58101e-322,
   4.032222e-316,
   5.582942e-322};
   Double_t Graph0_fehy3001[27] = {
   5.693069,
   2.47175,
   0.8989364,
   0.4081147,
   0.2108151,
   0.1170805,
   0.07362081,
   0.05438244,
   0.04146756,
   0.03243252,
   0.02825768,
   0.02361592,
   0.01990321,
   0.01752287,
   0.01712826,
   0.0153559,
   0.01456667,
   0.01341494,
   0.01192601,
   0.0124739,
   0.01149977,
   0.01055484,
   0.01051202,
   0.008670811,
   0.008670811,
   0.008635777,
   0.008635777};
   TGraphAsymmErrors *grae = new TGraphAsymmErrors(27,Graph0_fx3001,Graph0_fy3001,Graph0_felx3001,Graph0_fehx3001,Graph0_fely3001,Graph0_fehy3001);
   grae->SetName("Graph0");
   grae->SetTitle("Graph");

   Int_t ci;      // for color index setting
   TColor *color; // for color definition with alpha
   ci = TColor::GetColor("#ffff00");
   grae->SetFillColor(ci);
   grae->SetMarkerStyle(20);
   
   TH1F *Graph_Graph3001 = new TH1F("Graph_Graph3001","Graph",100,70,1630);
   Graph_Graph3001->SetMinimum(0);
   Graph_Graph3001->SetMaximum(11.53875);
   Graph_Graph3001->SetDirectory(0);
   Graph_Graph3001->SetStats(0);
   Graph_Graph3001->SetLineStyle(0);
   Graph_Graph3001->SetMarkerStyle(20);
   Graph_Graph3001->GetXaxis()->SetLabelFont(42);
   Graph_Graph3001->GetXaxis()->SetTitleSize(0.05);
   Graph_Graph3001->GetXaxis()->SetTickLength(0.02);
   Graph_Graph3001->GetXaxis()->SetTitleOffset(1.08);
   Graph_Graph3001->GetXaxis()->SetTitleFont(42);
   Graph_Graph3001->GetYaxis()->SetLabelFont(42);
   Graph_Graph3001->GetYaxis()->SetLabelOffset(0.007);
   Graph_Graph3001->GetYaxis()->SetTitleSize(0.05);
   Graph_Graph3001->GetYaxis()->SetTickLength(0.02);
   Graph_Graph3001->GetYaxis()->SetTitleOffset(1.56);
   Graph_Graph3001->GetYaxis()->SetTitleFont(42);
   Graph_Graph3001->GetZaxis()->SetLabelFont(42);
   Graph_Graph3001->GetZaxis()->SetLabelOffset(0.007);
   Graph_Graph3001->GetZaxis()->SetTitleSize(0.05);
   Graph_Graph3001->GetZaxis()->SetTickLength(0.02);
   Graph_Graph3001->GetZaxis()->SetTitleFont(42);
   grae->SetHistogram(Graph_Graph3001);
   
   grae->Draw("3");
   
   Double_t Graph1_fx3002[27] = {
   200,
   250,
   300,
   350,
   400,
   450,
   500,
   550,
   600,
   650,
   700,
   750,
   800,
   850,
   900,
   950,
   1000,
   1050,
   1100,
   1150,
   1200,
   1250,
   1300,
   1350,
   1400,
   1450,
   1500};
   Double_t Graph1_fy3002[27] = {
   4.796875,
   2.148438,
   0.8398438,
   0.3857422,
   0.2001953,
   0.1088867,
   0.06591797,
   0.04736328,
   0.03564453,
   0.02783203,
   0.02294922,
   0.01806641,
   0.01513672,
   0.01220703,
   0.01123047,
   0.009277344,
   0.008300781,
   0.007324219,
   0.007324219,
   0.006347656,
   0.006347656,
   0.005371094,
   0.005371094,
   0.004394531,
   0.004394531,
   0.004394531,
   0.004394531};
   Double_t Graph1_felx3002[27] = {
   4.028644e-316,
   2.608667e-321,
   4.022558e-316,
   0,
   2.420922e-322,
   4.028601e-316,
   0,
   2.11372e-314,
   0,
   4.940656e-323,
   8.744962e-322,
   0,
   0,
   4.940656e-323,
   0,
   6.906314e-310,
   5.33769e+160,
   0,
   4.021573e-316,
   6.906314e-310,
   0,
   1.188318e-312,
   4.027998e-316,
   0,
   1.58101e-322,
   4.027629e-316,
   1.630417e-322};
   Double_t Graph1_fely3002[27] = {
   1.490716,
   0.6650269,
   0.2516418,
   0.1146438,
   0.05974151,
   0.03228919,
   0.01945674,
   0.01420552,
   0.01069075,
   0.009417772,
   0.007765532,
   0.006113291,
   0.005277157,
   0.003647804,
   0.00335598,
   0.002772331,
   0.002480507,
   0.002317429,
   0.002832413,
   0.002231598,
   0.002231598,
   0.001888275,
   0.001888275,
   0.001544952,
   0.001544952,
   0.001544952,
   0.002162933};
   Double_t Graph1_fehx3002[27] = {
   1.179415e-312,
   2.608667e-321,
   4.022558e-316,
   0,
   2.420922e-322,
   4.028634e-316,
   0,
   2.113722e-314,
   0,
   4.940656e-323,
   8.744962e-322,
   0,
   0,
   4.940656e-323,
   0,
   6.906314e-310,
   2.139459e+161,
   0,
   4.021573e-316,
   6.906314e-310,
   0,
   1.188318e-312,
   4.027998e-316,
   0,
   1.58101e-322,
   4.027675e-316,
   1.630417e-322};
   Double_t Graph1_fehy3002[27] = {
   2.351828,
   1.053343,
   0.3849801,
   0.1768222,
   0.09017253,
   0.05078118,
   0.03126747,
   0.02303264,
   0.01790216,
   0.012869,
   0.0113431,
   0.009505779,
   0.008205643,
   0.007395977,
   0.0068043,
   0.006212621,
   0.006088058,
   0.005138258,
   0.004204029,
   0.005262822,
   0.003643492,
   0.004453157,
   0.003768056,
   0.004204029,
   0.004204029,
   0.003643492,
   0.003643492};
   grae = new TGraphAsymmErrors(27,Graph1_fx3002,Graph1_fy3002,Graph1_felx3002,Graph1_fehx3002,Graph1_fely3002,Graph1_fehy3002);
   grae->SetName("Graph1");
   grae->SetTitle("Graph");

   ci = TColor::GetColor("#00ff00");
   grae->SetFillColor(ci);
   grae->SetMarkerStyle(20);
   
   TH1F *Graph_Graph3002 = new TH1F("Graph_Graph3002","Graph",100,-8.010917e+160,2.406781e+161);
   Graph_Graph3002->SetMinimum(0);
   Graph_Graph3002->SetMaximum(7.86335);
   Graph_Graph3002->SetDirectory(0);
   Graph_Graph3002->SetStats(0);
   Graph_Graph3002->SetLineStyle(0);
   Graph_Graph3002->SetMarkerStyle(20);
   Graph_Graph3002->GetXaxis()->SetLabelFont(42);
   Graph_Graph3002->GetXaxis()->SetTitleSize(0.05);
   Graph_Graph3002->GetXaxis()->SetTickLength(0.02);
   Graph_Graph3002->GetXaxis()->SetTitleOffset(1.08);
   Graph_Graph3002->GetXaxis()->SetTitleFont(42);
   Graph_Graph3002->GetYaxis()->SetLabelFont(42);
   Graph_Graph3002->GetYaxis()->SetLabelOffset(0.007);
   Graph_Graph3002->GetYaxis()->SetTitleSize(0.05);
   Graph_Graph3002->GetYaxis()->SetTickLength(0.02);
   Graph_Graph3002->GetYaxis()->SetTitleOffset(1.56);
   Graph_Graph3002->GetYaxis()->SetTitleFont(42);
   Graph_Graph3002->GetZaxis()->SetLabelFont(42);
   Graph_Graph3002->GetZaxis()->SetLabelOffset(0.007);
   Graph_Graph3002->GetZaxis()->SetTitleSize(0.05);
   Graph_Graph3002->GetZaxis()->SetTickLength(0.02);
   Graph_Graph3002->GetZaxis()->SetTitleFont(42);
   grae->SetHistogram(Graph_Graph3002);
   
   grae->Draw("3");
   
   Double_t Graph2_fx1[27] = {
   200,
   250,
   300,
   350,
   400,
   450,
   500,
   550,
   600,
   650,
   700,
   750,
   800,
   850,
   900,
   950,
   1000,
   1050,
   1100,
   1150,
   1200,
   1250,
   1300,
   1350,
   1400,
   1450,
   1500};
   Double_t Graph2_fy1[27] = {
   4.796875,
   2.148438,
   0.8398438,
   0.3857422,
   0.2001953,
   0.1088867,
   0.06591797,
   0.04736328,
   0.03564453,
   0.02783203,
   0.02294922,
   0.01806641,
   0.01513672,
   0.01220703,
   0.01123047,
   0.009277344,
   0.008300781,
   0.007324219,
   0.007324219,
   0.006347656,
   0.006347656,
   0.005371094,
   0.005371094,
   0.004394531,
   0.004394531,
   0.004394531,
   0.004394531};
   TGraph *graph = new TGraph(27,Graph2_fx1,Graph2_fy1);
   graph->SetName("Graph2");
   graph->SetTitle("Graph");
   graph->SetFillColor(1);

   ci = TColor::GetColor("#ff0000");
   graph->SetLineColor(ci);
   graph->SetLineWidth(2);
   graph->SetMarkerStyle(20);
   
   TH1F *Graph_Graph1 = new TH1F("Graph_Graph1","Graph",100,70,1630);
   Graph_Graph1->SetMinimum(0);
   Graph_Graph1->SetMaximum(5.276123);
   Graph_Graph1->SetDirectory(0);
   Graph_Graph1->SetStats(0);
   Graph_Graph1->SetLineStyle(0);
   Graph_Graph1->SetMarkerStyle(20);
   Graph_Graph1->GetXaxis()->SetLabelFont(42);
   Graph_Graph1->GetXaxis()->SetTitleSize(0.05);
   Graph_Graph1->GetXaxis()->SetTickLength(0.02);
   Graph_Graph1->GetXaxis()->SetTitleOffset(1.08);
   Graph_Graph1->GetXaxis()->SetTitleFont(42);
   Graph_Graph1->GetYaxis()->SetLabelFont(42);
   Graph_Graph1->GetYaxis()->SetLabelOffset(0.007);
   Graph_Graph1->GetYaxis()->SetTitleSize(0.05);
   Graph_Graph1->GetYaxis()->SetTickLength(0.02);
   Graph_Graph1->GetYaxis()->SetTitleOffset(1.56);
   Graph_Graph1->GetYaxis()->SetTitleFont(42);
   Graph_Graph1->GetZaxis()->SetLabelFont(42);
   Graph_Graph1->GetZaxis()->SetLabelOffset(0.007);
   Graph_Graph1->GetZaxis()->SetTitleSize(0.05);
   Graph_Graph1->GetZaxis()->SetTickLength(0.02);
   Graph_Graph1->GetZaxis()->SetTitleFont(42);
   graph->SetHistogram(Graph_Graph1);
   
   graph->Draw("l");
   
   Double_t Graph3_fx2[27] = {
   200,
   250,
   300,
   350,
   400,
   450,
   500,
   550,
   600,
   650,
   700,
   750,
   800,
   850,
   900,
   950,
   1000,
   1050,
   1100,
   1150,
   1200,
   1250,
   1300,
   1350,
   1400,
   1450,
   1500};
   Double_t Graph3_fy2[27] = {
   4.79203,
   2.152691,
   0.8377939,
   0.3861777,
   0.1995838,
   0.1090425,
   0.0660598,
   0.04759021,
   0.03596779,
   0.02751563,
   0.02238263,
   0.01815241,
   0.01512282,
   0.01228406,
   0.01162986,
   0.009836298,
   0.008643669,
   0.007866618,
   0.007089044,
   0.006702567,
   0.005960677,
   0.005744891,
   0.005145786,
   0.004956617,
   0.004917011,
   0.004476165,
   0.004343825};
   graph = new TGraph(27,Graph3_fx2,Graph3_fy2);
   graph->SetName("Graph3");
   graph->SetTitle("Graph");
   graph->SetFillColor(1);
   graph->SetLineWidth(2);
   graph->SetMarkerStyle(20);
   
   TH1F *Graph_Graph2 = new TH1F("Graph_Graph2","Graph",100,70,1630);
   Graph_Graph2->SetMinimum(0);
   Graph_Graph2->SetMaximum(5.270799);
   Graph_Graph2->SetDirectory(0);
   Graph_Graph2->SetStats(0);
   Graph_Graph2->SetLineStyle(0);
   Graph_Graph2->SetMarkerStyle(20);
   Graph_Graph2->GetXaxis()->SetLabelFont(42);
   Graph_Graph2->GetXaxis()->SetTitleSize(0.05);
   Graph_Graph2->GetXaxis()->SetTickLength(0.02);
   Graph_Graph2->GetXaxis()->SetTitleOffset(1.08);
   Graph_Graph2->GetXaxis()->SetTitleFont(42);
   Graph_Graph2->GetYaxis()->SetLabelFont(42);
   Graph_Graph2->GetYaxis()->SetLabelOffset(0.007);
   Graph_Graph2->GetYaxis()->SetTitleSize(0.05);
   Graph_Graph2->GetYaxis()->SetTickLength(0.02);
   Graph_Graph2->GetYaxis()->SetTitleOffset(1.56);
   Graph_Graph2->GetYaxis()->SetTitleFont(42);
   Graph_Graph2->GetZaxis()->SetLabelFont(42);
   Graph_Graph2->GetZaxis()->SetLabelOffset(0.007);
   Graph_Graph2->GetZaxis()->SetTitleSize(0.05);
   Graph_Graph2->GetZaxis()->SetTickLength(0.02);
   Graph_Graph2->GetZaxis()->SetTitleFont(42);
   graph->SetHistogram(Graph_Graph2);
   
   graph->Draw("pl");
   
   TH1F *tmp0_copy3 = new TH1F("tmp0_copy3","Graph",100,200,1500);
   tmp0_copy3->SetMinimum(0);
   tmp0_copy3->SetMaximum(11.53875);
   tmp0_copy3->SetDirectory(0);
   tmp0_copy3->SetStats(0);
   tmp0_copy3->SetLineStyle(0);
   tmp0_copy3->SetMarkerStyle(20);
   tmp0_copy3->GetXaxis()->SetLabelFont(42);
   tmp0_copy3->GetXaxis()->SetTitleSize(0.05);
   tmp0_copy3->GetXaxis()->SetTickLength(0.02);
   tmp0_copy3->GetXaxis()->SetTitleOffset(1.08);
   tmp0_copy3->GetXaxis()->SetTitleFont(42);
   tmp0_copy3->GetYaxis()->SetLabelFont(42);
   tmp0_copy3->GetYaxis()->SetLabelOffset(0.007);
   tmp0_copy3->GetYaxis()->SetTitleSize(0.05);
   tmp0_copy3->GetYaxis()->SetTickLength(0.02);
   tmp0_copy3->GetYaxis()->SetTitleOffset(1.56);
   tmp0_copy3->GetYaxis()->SetTitleFont(42);
   tmp0_copy3->GetZaxis()->SetLabelFont(42);
   tmp0_copy3->GetZaxis()->SetLabelOffset(0.007);
   tmp0_copy3->GetZaxis()->SetTitleSize(0.05);
   tmp0_copy3->GetZaxis()->SetTickLength(0.02);
   tmp0_copy3->GetZaxis()->SetTitleFont(42);
   tmp0_copy3->Draw("sameaxis");
   
   TH1F *tmp0_copy4 = new TH1F("tmp0_copy4","Graph",100,200,1500);
   tmp0_copy4->SetMinimum(0);
   tmp0_copy4->SetMaximum(11.53875);
   tmp0_copy4->SetDirectory(0);
   tmp0_copy4->SetStats(0);
   tmp0_copy4->SetLineStyle(0);
   tmp0_copy4->SetMarkerStyle(20);
   tmp0_copy4->GetXaxis()->SetLabelFont(42);
   tmp0_copy4->GetXaxis()->SetTitleSize(0.05);
   tmp0_copy4->GetXaxis()->SetTickLength(0.02);
   tmp0_copy4->GetXaxis()->SetTitleOffset(1.08);
   tmp0_copy4->GetXaxis()->SetTitleFont(42);
   tmp0_copy4->GetYaxis()->SetLabelFont(42);
   tmp0_copy4->GetYaxis()->SetLabelOffset(0.007);
   tmp0_copy4->GetYaxis()->SetTitleSize(0.05);
   tmp0_copy4->GetYaxis()->SetTickLength(0.02);
   tmp0_copy4->GetYaxis()->SetTitleOffset(1.56);
   tmp0_copy4->GetYaxis()->SetTitleFont(42);
   tmp0_copy4->GetZaxis()->SetLabelFont(42);
   tmp0_copy4->GetZaxis()->SetLabelOffset(0.007);
   tmp0_copy4->GetZaxis()->SetTitleSize(0.05);
   tmp0_copy4->GetZaxis()->SetTickLength(0.02);
   tmp0_copy4->GetZaxis()->SetTitleFont(42);
   tmp0_copy4->Draw("sameaxig");
   
   TLegend *leg = new TLegend(0.495,0.825,0.945,0.925,NULL,"NBNDC");
   leg->SetBorderSize(0);
   leg->SetLineColor(1);
   leg->SetLineStyle(1);
   leg->SetLineWidth(1);
   leg->SetFillColor(0);
   leg->SetFillStyle(1001);
   TLegendEntry *entry=leg->AddEntry("Graph3","Observed","LP");
   entry->SetLineColor(1);
   entry->SetLineStyle(1);
   entry->SetLineWidth(2);
   entry->SetMarkerColor(1);
   entry->SetMarkerStyle(20);
   entry->SetMarkerSize(1);
   entry->SetTextFont(42);
   entry=leg->AddEntry("Graph2","Expected","L");

   ci = TColor::GetColor("#ff0000");
   entry->SetLineColor(ci);
   entry->SetLineStyle(1);
   entry->SetLineWidth(2);
   entry->SetMarkerColor(1);
   entry->SetMarkerStyle(21);
   entry->SetMarkerSize(1);
   entry->SetTextFont(42);
   entry=leg->AddEntry("Graph1","#pm1#sigma Expected","F");

   ci = TColor::GetColor("#00ff00");
   entry->SetFillColor(ci);
   entry->SetFillStyle(1001);
   entry->SetLineColor(1);
   entry->SetLineStyle(1);
   entry->SetLineWidth(1);
   entry->SetMarkerColor(1);
   entry->SetMarkerStyle(21);
   entry->SetMarkerSize(1);
   entry->SetTextFont(42);
   entry=leg->AddEntry("Graph0","#pm2#sigma Expected","F");

   ci = TColor::GetColor("#ffff00");
   entry->SetFillColor(ci);
   entry->SetFillStyle(1001);
   entry->SetLineColor(1);
   entry->SetLineStyle(1);
   entry->SetLineWidth(1);
   entry->SetMarkerColor(1);
   entry->SetMarkerStyle(21);
   entry->SetMarkerSize(1);
   entry->SetTextFont(42);
   leg->Draw();
   TPave *pave = new TPave(0.16,0.81,0.96,0.94,1,"brNDC");
   pave->SetFillColor(0);
   pave->Draw();
   
   leg = new TLegend(0.495,0.825,0.945,0.925,NULL,"NBNDC");
   leg->SetBorderSize(0);
   leg->SetLineColor(1);
   leg->SetLineStyle(1);
   leg->SetLineWidth(1);
   leg->SetFillColor(0);
   leg->SetFillStyle(1001);
   entry=leg->AddEntry("Graph3","Observed","LP");
   entry->SetLineColor(1);
   entry->SetLineStyle(1);
   entry->SetLineWidth(2);
   entry->SetMarkerColor(1);
   entry->SetMarkerStyle(20);
   entry->SetMarkerSize(1);
   entry->SetTextFont(42);
   entry=leg->AddEntry("Graph2","Expected","L");

   ci = TColor::GetColor("#ff0000");
   entry->SetLineColor(ci);
   entry->SetLineStyle(1);
   entry->SetLineWidth(2);
   entry->SetMarkerColor(1);
   entry->SetMarkerStyle(21);
   entry->SetMarkerSize(1);
   entry->SetTextFont(42);
   entry=leg->AddEntry("Graph1","#pm1#sigma Expected","F");

   ci = TColor::GetColor("#00ff00");
   entry->SetFillColor(ci);
   entry->SetFillStyle(1001);
   entry->SetLineColor(1);
   entry->SetLineStyle(1);
   entry->SetLineWidth(1);
   entry->SetMarkerColor(1);
   entry->SetMarkerStyle(21);
   entry->SetMarkerSize(1);
   entry->SetTextFont(42);
   entry=leg->AddEntry("Graph0","#pm2#sigma Expected","F");

   ci = TColor::GetColor("#ffff00");
   entry->SetFillColor(ci);
   entry->SetFillStyle(1001);
   entry->SetLineColor(1);
   entry->SetLineStyle(1);
   entry->SetLineWidth(1);
   entry->SetMarkerColor(1);
   entry->SetMarkerStyle(21);
   entry->SetMarkerSize(1);
   entry->SetTextFont(42);
   leg->Draw();
   TLatex *   tex = new TLatex(0.196,0.9113,"CMS");
tex->SetNDC();
   tex->SetTextAlign(13);
   tex->SetTextSize(0.048);
   tex->SetLineWidth(2);
   tex->Draw();
      tex = new TLatex(0.196,0.8537,"Internal");
tex->SetNDC();
   tex->SetTextAlign(13);
   tex->SetTextFont(52);
   tex->SetTextSize(0.03648);
   tex->SetLineWidth(2);
   tex->Draw();
      tex = new TLatex(0.96,0.952,"");
tex->SetNDC();
   tex->SetTextAlign(31);
   tex->SetTextFont(42);
   tex->SetTextSize(0.036);
   tex->SetLineWidth(2);
   tex->Draw();
      tex = new TLatex(0.16,0.952,"");
tex->SetNDC();
   tex->SetTextFont(42);
   tex->SetTextSize(0.036);
   tex->SetLineWidth(2);
   tex->Draw();
   pad->Modified();
   limit->cd();
   limit->Modified();
   limit->cd();
   limit->SetSelected(limit);
}
Beispiel #11
0
void readroot(char* input="/gpfs/mnt/gpfs02/phenix/mpcex/liankun/Run16/Ana/offline/analysis/mpcexcode/Liankun/macro/offline_monitor/453692/Run16Ana_MinBias_NoCMN_Sub-453692-0.root"){
  char input_file[5000];
  strcpy(input_file,input);
  strtok(input_file, "-");
  int runnumber = atoi(strtok(0, "-"));
  int segment = atoi(strtok(strtok(0, "-"), "."));

  cout<<"Run Number: "<<runnumber<<" segment: "<<segment<<endl;

  gSystem->Load("libMyMpcEx.so");
  TFile* ifile = new TFile(input,"READONLY");
  if(!ifile){
    cout<<"Open "<<input<<" failed !"<<endl;
    return;
  }
  TH2D* hkey_adc_high;
  TH2D* hkey_adc_low;
  TH2D* hkey_rawadc_high;
  TH2D* hkey_rawadc_low;

  TH2D* hHL_sensor[2][8][24];
  TH2D* hHL_sensor_raw[2][8][24];
  Exogram* hgrammy_high[2];
  Exogram* hgrammy_low[2];
  Exogram* hgrammy_combine[2];
  TH2D* hadc_mpc_e[2];
  TH2D* hlayer_adc_high[2];
  TH2D* hlayer_adc_low[2];
  TH2D* htower_e;

  TH2D* hbbc_adc[2];
  TH2D* hbbc_adc_low[2];
  TH2D* hbbc_nhits[2];

  char hname[500];
  vector<TH2D*> h2d_list;
  hkey_adc_high = (TH2D*)ifile->Get("hkey_adc_high");
  h2d_list.push_back(hkey_adc_high);

  hkey_adc_low = (TH2D*)ifile->Get("hkey_adc_low");
  h2d_list.push_back(hkey_adc_low);
  
  hkey_rawadc_high = (TH2D*)ifile->Get("hkey_rawadc_high");
  h2d_list.push_back(hkey_rawadc_high);

  hkey_rawadc_low = (TH2D*)ifile->Get("hkey_rawadc_low");
  h2d_list.push_back(hkey_rawadc_low);

  hbbc_nhits[0] = (TH2D*)ifile->Get("hbbc_nhits_arm0");
  hbbc_nhits[1] = (TH2D*)ifile->Get("hbbc_nhits_arm1");
  h2d_list.push_back(hbbc_nhits[0]);
  h2d_list.push_back(hbbc_nhits[1]);
  
  hbbc_adc[0] = (TH2D*)ifile->Get("hbbc_adc_arm0");
  hbbc_adc[1] = (TH2D*)ifile->Get("hbbc_adc_arm1");
  h2d_list.push_back(hbbc_adc[0]);
  h2d_list.push_back(hbbc_adc[1]);
  
  hbbc_adc_low[0] = (TH2D*)ifile->Get("hbbc_adc_low_arm0");
  hbbc_adc_low[1] = (TH2D*)ifile->Get("hbbc_adc_low_arm1");
  h2d_list.push_back(hbbc_adc_low[0]);
  h2d_list.push_back(hbbc_adc_low[1]);
  
  hlayer_adc_high[0] = (TH2D*)ifile->Get("hlayer_adc_high_arm0");
  hlayer_adc_high[1] = (TH2D*)ifile->Get("hlayer_adc_high_arm1");
  h2d_list.push_back(hlayer_adc_high[0]);
  h2d_list.push_back(hlayer_adc_high[1]);

  hlayer_adc_low[0] = (TH2D*)ifile->Get("hlayer_adc_low_arm0");
  hlayer_adc_low[1] = (TH2D*)ifile->Get("hlayer_adc_low_arm1");
  h2d_list.push_back(hlayer_adc_low[0]);
  h2d_list.push_back(hlayer_adc_low[1]);

  htower_e = (TH2D*)ifile->Get("htower_e");
  h2d_list.push_back(htower_e);

  hadc_mpc_e[0] = (TH2D*)ifile->Get("hadc_mpc_e_arm0");
  hadc_mpc_e[1] = (TH2D*)ifile->Get("hadc_mpc_e_arm1");
  h2d_list.push_back(hadc_mpc_e[0]);
  h2d_list.push_back(hadc_mpc_e[1]);

  for(unsigned int i = 0;i < h2d_list.size();i++){
    string s = h2d_list[i]->GetName();
    stringstream ss("");
    ss<<s<<"_"<<runnumber<<"_"<<segment;
    s=ss.str();
//    cout << s <<endl;
    TCanvas* c = new TCanvas(s.c_str(),s.c_str(),1200,800);
    c->SetLogz();
    h2d_list[i]->Draw("colz");
    ss.str("");
    ss << runnumber <<"/"<<s<<".gif";
    s=ss.str();
    c->Print(s.c_str(),"gif");
    delete c;
  }

  vector<Exogram*> hexo_list;
  hgrammy_high[0] = (Exogram*)ifile->Get("hgrammy_high0");
  hgrammy_high[1] = (Exogram*)ifile->Get("hgrammy_high1");
  hexo_list.push_back(hgrammy_high[0]);
  hexo_list.push_back(hgrammy_high[1]);

  hgrammy_low[0] = (Exogram*)ifile->Get("hgrammy_low0");
  hgrammy_low[1] = (Exogram*)ifile->Get("hgrammy_low1");
  hexo_list.push_back(hgrammy_low[0]);
  hexo_list.push_back(hgrammy_low[1]);

  hgrammy_combine[0] = (Exogram*)ifile->Get("hgrammy_combine0");
  hgrammy_combine[1] = (Exogram*)ifile->Get("hgrammy_combine1");
  hexo_list.push_back(hgrammy_combine[0]);
  hexo_list.push_back(hgrammy_combine[1]);
  
  for(unsigned int i = 0;i < hexo_list.size();i++){
    string s = hexo_list[i]->GetName();
    stringstream ss("");
    ss<<s<<"_"<<runnumber<<"_"<<segment;
    s=ss.str();
    TCanvas* c = new TCanvas(s.c_str(),s.c_str(),1400,800);
    c->Divide(4,2);
    double max = hexo_list[i]->GetBinContent(hexo_list[i]->GetMaximumBin());
    for(unsigned int j = 0;j < 8;j++){
      c->cd(j+1);
      TPad *pd =(TPad*)c->cd(j+1);
      pd->SetLogz();
      hexo_list[i]->SetAxisRange(j,j,"z");
      TH2D* htemp = hexo_list[i]->Project3D("yx");
      string tmp_s = htemp->GetName();
      stringstream tmp_ss("");
      tmp_ss<<tmp_s<<"_"<<"layer"<<j;
      tmp_s = tmp_ss.str();
      htemp->SetName(tmp_s.c_str());
      htemp->SetMaximum(max);
      htemp->Draw("colz");
    }
    ss.str("");
    ss << runnumber <<"/"<<s<<".gif";
    s=ss.str();
    c->Print(s.c_str(),"gif");
    delete c;
  }

  for(int iarm = 0;iarm < 2;iarm++){
    for(int ilayer = 0;ilayer < 8;ilayer++){
      for(int isen = 0;isen< 24;isen++){
        char hname[500];
	sprintf(hname,"hHL_sensor_arm%d_layer%d_sensor%d",iarm,ilayer,isen);
	hHL_sensor[iarm][ilayer][isen] = (TH2D*)ifile->Get(hname);
	sprintf(hname,"hHL_sensor_raw_arm%d_layer%d_sensor%d",iarm,ilayer,isen);
	hHL_sensor_raw[iarm][ilayer][isen] = (TH2D*)ifile->Get(hname);
      }
    }
  }

  //sensor adc for each layer
  double max_sensor_x[2][8][24] = {{{0.}}};
  double max_sensor_y[2][8][24] = {{{0.}}};
  double min_sensor_x[2][8][24] = {{{0.}}};
  double min_sensor_y[2][8][24] = {{{0.}}};
  
  TH1D* hsensor_high[2][8][24];
  TH1D* hsensor_low[2][8][24];
 
  for(int iarm = 0;iarm < 2;iarm++){
    for(int ilayer = 0;ilayer < 8;ilayer++){
      for(int isen = 0;isen < 24;isen++){
        char name[100];
        sprintf(name,"hsensor_arm%d_layer%d_index%d_high",iarm,ilayer,isen);
        hsensor_high[iarm][ilayer][isen] = new TH1D(name,name,300,-40.5,259.5);
        sprintf(name,"hsensor_arm%d_layer%d_index%d_low",iarm,ilayer,isen);
        hsensor_low[iarm][ilayer][isen] = new TH1D(name,name,300,-40.5,259.5);
        max_sensor_x[iarm][ilayer][isen] = -9999;
        max_sensor_y[iarm][ilayer][isen] = -9999;
        min_sensor_x[iarm][ilayer][isen] = 9999;
        min_sensor_y[iarm][ilayer][isen] = 9999;
      }
    }
  }
  
  ifstream sensor_pos("sensor_position.txt");
  string s;
  while(getline(sensor_pos,s)){
    stringstream ss(s);
    int arm = 0;
    int layer = 0;
    int sensor = 0;
    double x0=0;
    double x1=0;
    double y0=0;
    double y1=0;
    ss>>arm>>layer>>sensor>>x0>>x1>>y0>>y1;
//    cout <<arm <<" "<<layer<<" "<<sensor<<" "<<x0<<" "<<x1<<" "<<y0<<" "<<y1<<endl;
    max_sensor_x[arm][layer][sensor] = x1;
    min_sensor_x[arm][layer][sensor] = x0;
    max_sensor_y[arm][layer][sensor] = y1;
    min_sensor_y[arm][layer][sensor] = y0;
  }
 
  MpcExMapper* mapper = MpcExMapper::instance(); 
  for(unsigned int i = 0;i < 50000;i++){
    hkey_adc_high->SetAxisRange(i,i,"X");
    hkey_adc_low->SetAxisRange(i,i,"X");
    TH1D* htemp0 = hkey_adc_high->ProjectionY();
    TH1D* htemp1 = hkey_adc_low->ProjectionY();
    if(htemp0->GetEntries() < 10) continue;
    int arm = mapper->get_arm(i);
    int quadrant = mapper->get_quadrant(i);
    int sensor = mapper->get_sensor_in_quadrant(i);
    int index = 6*quadrant+sensor;
    int layer = mapper->get_layer(i);
    hsensor_high[arm][layer][index]->Add(htemp0);
    hsensor_low[arm][layer][index]->Add(htemp1);
  }
  
  for(int iarm = 0;iarm < 2;iarm++){
    for(int ilayer = 0;ilayer < 8;ilayer++){
      char cname[100];
      sprintf(cname,"csensor_arm%d_layer%d_%d_%d",iarm,ilayer,runnumber,segment);
      TCanvas* c = new TCanvas(cname,cname,1400,800);
      for(int index = 0;index < 24;index++){
        char pname[100];
        sprintf(pname,"sensor_arm%d_layer%d_index%d",iarm,ilayer,index);
        double x0 = min_sensor_x[iarm][ilayer][index];
        double x1 = max_sensor_x[iarm][ilayer][index];
        double y0 = min_sensor_y[iarm][ilayer][index];
        double y1 = max_sensor_y[iarm][ilayer][index];
        if(ilayer%2 == 0){
          y0 = y0 - 0.85;
          y1 = y1 + 0.85;
        }
        if(ilayer%2 == 1){
          x0 = x0 - 0.85;
          x1 = x1 + 0.85;
        }
        TPad* pad = new TPad(pname,pname,0.5+x0/40.,0.5+y0/40.,0.5+x1/40.,0.5+y1/40.);
        pad->cd();
        pad->SetLogy();
	hsensor_high[iarm][ilayer][index]->Draw("");
	hsensor_low[iarm][ilayer][index]->SetLineColor(kRed);
        hsensor_low[iarm][ilayer][index]->Draw("");
        c->cd();
        pad->DrawClone("same");
        delete pad;
      }
      sprintf(cname,"%d/csensor_arm%d_layer%d_%d_%d.gif",runnumber,iarm,ilayer,runnumber,segment);
      c->Print(cname,"gif"); 
      delete c;
    }
  }
}
Beispiel #12
0
void FastVsSlowSimPtRes() {

  Int_t plusTPC =0;

  gROOT->LoadMacro("~/fig_template.C"); // figure style
  myOptions(0);
  gROOT->ForceStyle();

  TCanvas *myCan = new TCanvas("myCan");
  myCan->Draw();
  myCan->cd();
  
  TPad *myPad = new TPad("myPad", "The pad",0,0,1,1);
  myPadSetUp(myPad,0.15,0.04,0.04,0.15);
  myPad->Draw();   myPad->cd();
  myPad->SetGridx();   myPad->SetGridy();  myPad->SetLogx(); myPad->SetLogy();


  TLegend *leg = new TLegend(0.44,0.13,0.1.7,0.9,"","brCDN"); 
  leg->SetFillColor(0);

  TGraph *c[6];
  
  // Current ITS +++++++++++++++++++++++++++++++++++++++++
  Int_t color=1; Int_t linewidth=2;

  Int_t pi =0;
 
  DetectorK its("ALICE","ITS");
  its.MakeAliceCurrent(0,plusTPC);
  its.SetMaxRadiusOfSlowDetectors(0.1);
  its.SolveViaBilloir(0);
  Int_t color=1; Int_t linewidth=2;

  c[pi] = its.GetGraphMomentumResolution(color,linewidth);
  c[pi]->Draw("AC");

  leg->AddEntry(c[pi],"FastTool: Current ITS","l");


  // Current ITS +++++++++++++++++++++++++++++++++++++++++

  Int_t color=3; Int_t linewidth=2;
  Int_t pi =2;

  DetectorK its("ALICE","ITS");
  its.MakeAliceCurrent(0,plusTPC);
  
  its.SetRadius("bpipe",2.0);
  its.AddLayer("spd0", 2.2,1,1,1);  

  its.SetRadius("spd0",2.2); its.SetRadiationLength("spd0",X0); its.SetResolution("spd0",resRPhi,resZ);
  its.SetRadius("spd1",4.8);   its.SetRadiationLength("spd1",X0); its.SetResolution("spd1",resRPhi,resZ);
  its.SetRadius("spd2",9.1);   its.SetRadiationLength("spd2",X0); its.SetResolution("spd2",resRPhi,resZ);

  its.SetMaxRadiusOfSlowDetectors(0.1);
  its.SolveViaBilloir(0);

  c[pi] = its.GetGraphMomentumResolution(color,linewidth);
  c[pi]->Draw("C");

  leg->AddEntry(c[pi],"FastTool: \"New SPDs\"","l");


  // ALL NEW +++++++++++++++++++++++++++++++++++++++++++

  color=2; Int_t linewidth=2;
  Int_t pi =1; 


  // for a 0.8,0.2 weight configuration
  
  DetectorK *itsU = new DetectorK((char*)"ALICE",(char*)"ITS");
  
  itsU->AddLayer((char*)"bpipe", 2.0,0.0022); // beam pipe
  itsU->AddLayer((char*)"vertex",  0,     0); // dummy vertex for matrix calculation
  
  itsU->AddLayer("ddd1",  2.2 ,  X0, resRPhi, resZ); 
  itsU->AddLayer("ddd2",  3.8 ,  X0, resRPhi, resZ); 
  itsU->AddLayer("ddd3",  6.8 ,  X0, resRPhi, resZ); 
  itsU->AddLayer("ddd4", 12.4 ,  X0, resRPhi, resZ); 
  itsU->AddLayer("ddd5", 23.5 ,  X0, resRPhi, resZ); 
  itsU->AddLayer("ddd6", 39.6 ,  X0, resRPhi, resZ); 
  itsU->AddLayer("ddd7", 43.0 ,  X0, resRPhi, resZ); 
 
  if(plusTPC) itsU->AddTPC(0.1,0.1);
  itsU->SetMaxRadiusOfSlowDetectors(0.1);
  itsU->SolveViaBilloir(0);
  itsU->PrintLayout();

  
  c[pi] = itsU->GetGraphMomentumResolution(color,linewidth);
  c[pi]->Draw("C");

  leg->AddEntry(c[pi],"FastTool: \"All New\" ","l");

  // ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++



  TFile f1("root/FastVsSlow_CurrentITS-PbPb-fran.root");
  TFile f2("root/FastVsSlow_NewSPDs-PbPb-fran.root");
  TFile f3("root/FastVsSlow_AllNew-PbPb-fran.root");

  TGraphErrors *gpt1 = (TGraphErrors*)f1.Get("dPt");
  TGraphErrors *gpt2 = (TGraphErrors*)f2.Get("dPt");
  TGraphErrors *gpt3 = (TGraphErrors*)f3.Get("dPt");
  
  gpt1->SetMarkerStyle(21); gpt1->SetMarkerColor(1);
  gpt2->SetMarkerStyle(21); gpt2->SetMarkerColor(3);
  gpt3->SetMarkerStyle(21); gpt3->SetMarkerColor(2);

  leg->AddEntry(gpt1,"FullMC: Current ITS","PE");
  leg->AddEntry(gpt2,"FullMC: \"New SPDs\"","PE");
  leg->AddEntry(gpt3,"FullMC: \"All New\" ","PE");

  gpt1->Draw("APE"); gpt1->SetMinimum(0.1); gpt1->SetMaximum(20);
  gpt2->Draw("PE");
  gpt3->Draw("PE");
  c[0]->Draw("C");
  c[1]->Draw("C");
  c[2]->Draw("C");

  leg->Draw();
 
  myCan->SaveAs(Form("FastVsSlowSim-PtRes-%d.pdf",plusTPC));
  myCan->SaveAs(Form("FastVsSlowSim-PtRes-%d.eps",plusTPC));



}
Beispiel #13
0
void AtlasExample() 
{ 

#ifdef __CINT__
  gROOT->LoadMacro("AtlasUtils.C");
#endif

  SetAtlasStyle();

  Int_t icol1=5;
  Int_t icol2=5;

  TCanvas* c1 = new TCanvas("c1","single inclusive jets",50,50,600,600);
  // TCanvas* c1 = new TCanvas("c1","single inclusive jets");
  TPad* thePad = (TPad*)c1->cd();
  thePad->SetLogy();

  Double_t ymin=1.e-3;  Double_t ymax=2e7;
  Double_t xmin=60.00;  Double_t xmax=3500.;
  TH1F *h1 = thePad->DrawFrame(xmin,ymin,xmax,ymax);
  h1->SetYTitle("d#sigma_{jet}/dE_{T,jet} [fb/GeV]");
  h1->SetXTitle("E_{T,jet}  [GeV]");
  h1->GetYaxis()->SetTitleOffset(1.4);
  h1->GetXaxis()->SetTitleOffset(1.4);
  //h1->GetXaxis()->SetNdivisions(5);
  h1->Draw();

  const Int_t ncut=1;
  TGraphErrors *data[ncut];

  for (Int_t icut=0; icut<ncut; icut++) { // loop over cuts

    TGraphErrors *g1[nren][ncut];
    for (Int_t ir=0; ir<nren; ir++) { // loop over ren scale
      g1[ir][icut]= GetGraph(ir,ir,icut,0);
      if (g1[ir][icut]) 
	cout << g1[ir][icut]->GetTitle() << " found "  << g1[ir][icut]->GetName()  << endl;
      else { 
	cout << " g1 not  found " << endl; 
	return; 
      } 
      g1[ir][icut]->SetLineColor(1);
      g1[ir][icut]->SetMarkerStyle(0);
      //g1[ir][icut]->Draw("C");
    }

    char daname[100];
    sprintf(daname,"data_%d",icut); 
    data[icut]=(TGraphErrors*)g1[0][icut]->Clone(daname); 
    data[icut]->SetMarkerStyle(20);
    data[icut]->SetMarkerColor(1);

    // just invent some data
    for (Int_t i=0; i< data[icut]->GetN(); i++) {
      Double_t x1,y1,e,dx1=0.;
      data[icut]->GetPoint(i,x1,y1);
      Double_t r1 = 0.4*(gRandom->Rndm(1)+2);
      Double_t r2 = 0.4*(gRandom->Rndm(1)+2);
      //cout << " i= " << i << " x1= " << x1 << " y1= " << y1 << " r= " << r << endl;
      Double_t y;
      if (icut==0) y=r1*y1+r1*r2*r2*x1/50000.;
      else         y=r1*y1;
      e=sqrt(y*1000)/200;
      data[icut]->SetPoint(i, x1,y);
      data[icut]->SetPointError(i,dx1,e);
    }
    //data[icut]->Print();
  
    TGraphAsymmErrors* scale[ncut];
    TGraphAsymmErrors* scalepdf[ncut];

    scale[icut]=  myMakeBand(g1[0][icut],g1[1][icut],g1[2][icut]);
    //printf(" band1: \n");
    //scale->Print();

    scalepdf[icut]=(TGraphAsymmErrors* ) scale[icut]->Clone("scalepdf");

    TGraphErrors *gpdf[NUMPDF][ncut];
    for (Int_t ipdf=0; ipdf<NUMPDF; ipdf++) {
      gpdf[ipdf][icut]= GetGraph(0,0,icut,ipdf);
      if (gpdf[ipdf][icut]) 
	cout << gpdf[ipdf][icut]->GetTitle() << " found "  << gpdf[ipdf][icut]->GetName() << endl;
      else { 
	cout << " gpdf not  found " << endl; 
	return; 
      } 
      gpdf[ipdf][icut]->SetLineColor(2);
      gpdf[ipdf][icut]->SetLineStyle(1);
      gpdf[ipdf][icut]->SetMarkerStyle(0);
      myAddtoBand(gpdf[ipdf][icut],scalepdf[icut]); 
    }

    scalepdf[icut]->SetFillColor(icol2);
    scalepdf[icut]->Draw("zE2"); 
    scale[icut]->SetFillColor(icol1);
    scale[icut]->Draw("zE2");
    g1[0][icut]->SetLineWidth(3);
    g1[0][icut]->Draw("z");
    data[icut]->Draw("P");
    
  }

  myText(       0.3,  0.85, 1, "#sqrt{s}= 14 TeV");
  myText(       0.57, 0.85, 1, "|#eta_{jet}|<0.5");
  myMarkerText( 0.55, 0.75, 1, 20, "Data 2009",1.3);
  myBoxText(    0.55, 0.67, 0.05, icol1, "NLO QCD");

  //ATLAS_LABEL(0.2,0.2); myText( 0.37,0.2,1,"Preliminary");

  // new method for ATLAS labels. Use this!
  //ATLASLabel(0.2,0.2);
  ATLASLabel(0.2,0.2,"Preliminary");
  //ATLASLabel(0.2,0.2,"Work in progress");

  c1->Print("AtlasExample.eps");
  c1->Print("AtlasExample.png");
  c1->Print("AtlasExample.pdf");

}
Beispiel #14
0
// *************************************** //
// this is a function that takes a set of  //
// histograms and draws them on a canvas   //
// in a stack, returning the canvas.       //
// It also plots the signal as a dashed    //
// line and the data with a ratio at the   //
// the bottom of data/allBackgrounds       //
//                                         //
// This one is supposed to make plots for  //
// the paper draft                         //
// *************************************** //
TCanvas* drawPlots::plotAll_VLQ_paperStyle(std::vector<TH1D*> histos, std::vector<std::string> names, std::string axisName, std::vector<TH1D*> signal, TH1D* data, TGraphAsymmErrors* err, bool doLogAxis, std::string extraTag){

   const unsigned int CANVAS_WIDTH  = 720;
   const unsigned int CANVAS_HEIGHT = 750;
   const double RATIOPLOT_YAXIS_TITLE_OFFSET = 0.75;
   const double RATIOPLOT_YAXIS_TITLE_SIZE   = 0.11;
   const double RATIOPLOT_YAXIS_LABEL_SIZE   = 0.09;  
   const double RATIOPLOT_XAXIS_TITLE_OFFSET = 1.6;
   const double RATIOPLOT_XAXIS_TITLE_SIZE   = 0.11;
   const double RATIOPLOT_XAXIS_LABEL_SIZE   = 0.09;
   
   TCanvas* canvas = new TCanvas("canvas","canvas",0,0,CANVAS_WIDTH,CANVAS_HEIGHT);
   
   canvas->SetMargin(0.,0.,0.,0.);
   canvas->Clear();
   //canvas->cd();
   
   SetAtlasStyle();
   gStyle->SetHistLineWidth(1.);
   gStyle->SetErrorX(0);

   err->SetLineColor(kWhite);
   err->SetLineWidth(0);

   // create histogram to store all backgrounds
   TH1D* allBackgrounds;
   bool gotSomething=false;
   for(int c=0; c<signal.size(); c++){
     if(signal[c]){
       allBackgrounds = (TH1D*)signal[c]->Clone("all_backgrounds");
       gotSomething=true;
     }
   }

   if(!gotSomething && data){
     allBackgrounds = (TH1D*)data->Clone("all_backgrounds");
     gotSomething=true;
   }
   if(!gotSomething){
     for(int b=0; b<histos.size(); b++){
       if(histos[b] && !gotSomething){
	 allBackgrounds = (TH1D*)histos[b]->Clone("all_backgrounds");
	 gotSomething=true;
       }
     }
   }

   if(!gotSomething){
     std::cout << "Error: could not find any background, data, or signal for this plot" << std::endl;
     return canvas;
   }
   
   // set all bins to zero
   for(int i=0; i<=allBackgrounds->GetNbinsX()+1; i++)
     allBackgrounds->SetBinContent(i,0);

   // go through histos and combine the histograms that need to be combined
   // WZ stays separate, ttV stays separate, all others become "Other bkg"
   TH1D* otherBkgs=0; TH1D* ttbarX=0; TH1D* WZ_Sherpa=0;
   for(int cc=0; cc<histos.size(); cc++){
     if(histos[cc]){
       for(int j=0; j<=allBackgrounds->GetNbinsX()+1; j++){
	 double binContent=allBackgrounds->GetBinContent(j)+histos[cc]->GetBinContent(j);
	 allBackgrounds->SetBinContent(j,binContent);
       }
       
       if(names[cc]=="ttbarX")
	 ttbarX=(TH1D*)histos[cc]->Clone("ttbarX_new");
       else if(names[cc]=="WZ_Sherpa")
	 WZ_Sherpa=(TH1D*)histos[cc]->Clone("WZ_new");
       else{

	 if(!otherBkgs)
	   otherBkgs=(TH1D*)histos[cc]->Clone("other_bkg_new");
	 else
	   otherBkgs->Add(histos[cc]);
       }
     }
   }

   // make stack of backgrounds, fill backgrounds histogram
   THStack* Stack = new THStack();
   if(ttbarX){
     ttbarX->SetLineColor(kGray);
     ttbarX->SetFillColor(kGray);
     Stack->Add(ttbarX);
   }
   if(WZ_Sherpa){
     WZ_Sherpa->SetLineColor(kBlue-9);
     WZ_Sherpa->SetFillColor(kBlue-9);
     Stack->Add(WZ_Sherpa);
   }
   if(otherBkgs){
     otherBkgs->SetLineColor(kOrange-2);
     otherBkgs->SetFillColor(kOrange-2);
     Stack->Add(otherBkgs);
   }

   TH1D* backgroundsForRatio = (TH1D*)allBackgrounds->Clone("bkgds_for_ratio");

   // create main pad
   const double mainPad_ylow  = 0.3;
   const double mainPad_yhigh = 0.95;
   const double mainPad_xlow = 0.;
   const double mainPad_xhigh = 0.95;
   const double pad_margin_left = 0.2;
   const double pad_margin_right  = 0.02;
   double main_y_max = -99;
   double main_y_min = -99;

   TPad* mainPad = new TPad("main","main",mainPad_xlow,mainPad_ylow,mainPad_xhigh,mainPad_yhigh);
   mainPad->SetMargin(pad_margin_left,pad_margin_right,0.,.05); // left, right, bottom, top
   mainPad->Draw();
   mainPad->cd();

   // find max y
   if(allBackgrounds){
     int maxBinBkg = allBackgrounds->GetMaximumBin();
     double bkgYmax = allBackgrounds->GetBinContent(maxBinBkg);
     main_y_max = bkgYmax;
   }
   if(data){
     int maxBinData = data->GetMaximumBin();
     double dataYmax = data->GetBinContent(maxBinData);
     if(dataYmax > main_y_max) main_y_max = dataYmax;
   }
   if(main_y_max < .002) main_y_max = .1;

   if(doLogAxis){
     mainPad->SetLogy();
     main_y_min = 0.07;
     main_y_max*=60;
   }else{
     main_y_min = 0.001;
     main_y_max*=1.6;
   }

   // draw axis
   allBackgrounds->SetMaximum(main_y_max);
   allBackgrounds->SetMinimum(main_y_min);
   std::string title = std::string(";") + axisName + ";Events";
   std::stringstream binw; 
   
   binw<<allBackgrounds->GetBinWidth(1);
   std::string width = binw.str();
   if (axisName.find("GeV") != std::string::npos){
     width += " GeV";
     title += " / "+width;
   }
   allBackgrounds->SetTitle(title.c_str());   
   allBackgrounds->GetYaxis()->SetTitleOffset(1.4);
   allBackgrounds->GetYaxis()->SetTitleSize(0.06);
   allBackgrounds->GetXaxis()->SetTitleOffset(1.2);
   allBackgrounds->GetYaxis()->SetLabelSize(0.04);
   allBackgrounds->GetXaxis()->SetLabelSize(0.04);
   allBackgrounds->Draw("hist");

   // draw stack with error
   Stack->Draw("hist same");
   if(err){
     err->Draw("E2 same");
   }

   // make error histograms for the ratio plot
   TGraphAsymmErrors* ratioErr = tools::getRatio(err, backgroundsForRatio);

   // draw data
   if(data)
      data->Draw("e same");

   // draw signal
   if(signal[0]){
     signal[0]->SetLineStyle(2);
     signal[0]->SetLineColor(kRed+2);//kGreen+3 before
     signal[0]->SetLineWidth(5);
     signal[0]->Draw("hist same");
   }
   if(signal.size() > 1){
     if(signal[1]){
       //signal[1]->SetLineStyle(2);
       signal[1]->SetLineColor(kRed+2);
       signal[1]->SetLineWidth(4);
       signal[1]->Draw("hist same");
     }
     if(signal.size() > 2){
       if(signal[2]){
	 //signal[2]->SetLineStyle(2);
	 signal[2]->SetLineColor(kBlue+2);
	 signal[2]->SetLineWidth(4);
	 signal[2]->Draw("hist same");
       }
     }
   }
   allBackgrounds->Draw("axis same");

   // draw legend
   float leg_height = 0.3;
   float leg_width = 0.2;
   float leg_xoffset = 0.74;
   float leg_yoffset = 0.77;
   
   TLegend* leg = new TLegend(leg_xoffset,leg_yoffset-leg_height/2,leg_xoffset+leg_width,leg_yoffset+leg_height/2);
   leg->SetFillColor(0);
   leg->SetFillStyle(0);
   leg->SetBorderSize(0);
   leg->SetTextFont(52);
   leg->SetTextSize(0.033);
   
   // currently assuming first signal is Tbq (single T production), second is TTS, third is BBS
   leg->AddEntry(data, "data 2012");
   leg->AddEntry(otherBkgs, "Other bkg.", "f");
   leg->AddEntry(WZ_Sherpa, "WZ", "f");
   leg->AddEntry(ttbarX, "t#bar{t}+X", "f");
   if(signal.size()>1){
     if(signal[2])
       leg->AddEntry(signal[2], "B#bar{B} (650 GeV)", "l");
     if(signal[1])
       leg->AddEntry(signal[1], "T#bar{T} (650 GeV)", "l");
   }   
   if(signal[0])
     leg->AddEntry(signal[0], "T#bar{b}q (650 GeV)", "l");
   
   
   leg->AddEntry( err, "Uncertainty", "f");


   leg->Draw("lpe");
   
   ATLAS_LABEL(0.24,0.86,1);
   myText(0.36, 0.86, 1, .05, "Internal");
   char text[]="#sqrt{s}=8 TeV";
   myText(0.55,0.77,1,.04, text);
   char text_L[]="#int L dt = 20.3 fb^{-1}";
   myText(0.5, 0.84,1, .04, text_L);
   if(extraTag!=""){
     char tag_txt[extraTag.size()];
     strcpy(tag_txt, extraTag.c_str());
     if(extraTag.size()>15)
       myText(0.7, 0.56, 1, .04, tag_txt);
     else
       myText(0.75, 0.56, 1, .04, tag_txt);
   }
   char text_tri[]="Trilepton";
   myText(0.55, 0.70, 1, .04, text_tri);

   /*
   double back_int = allBackgrounds->Integral(0,allBackgrounds->GetNbinsX()+1);
   int t;
   char inText[100];
   if(back_int > 10000.)
     t=sprintf(inText, "N_{B} = %.3e", back_int);
   else
     t=sprintf(inText, "N_{B} = %.1f", back_int);
   myText(0.24, 0.6, 1, .04, inText);
   if(data)
     t=sprintf(inText, "N_{D} = %.0f", data->Integral(0,data->GetNbinsX()+1));
   else
     t=sprintf(inText, "N_{D} = %.0f", 0.);
   myText(0.24, 0.7, 1, .04, inText);
   */
   canvas->cd();
   
   // Draw Ratio plot
   // 1.6 and .4 are the normal ones
   double ratio_max = 3.2;
   double ratio_min = -.9;
  
   double pad_xlow = 0.;
   double pad_xhigh = 0.95;
   double pad_ylow = 0.0;
   double pad_yhigh = 0.3;
   
   const char* pad_name = "pad";
   TPad* pad4ratio = new TPad(pad_name,pad_name,pad_xlow,pad_ylow,pad_xhigh,pad_yhigh);

   pad4ratio->SetMargin(pad_margin_left,pad_margin_right,0.46,0.);
   pad4ratio->Draw();
   pad4ratio->cd();

   TH1D* ratioPlot;
   if(data)
     ratioPlot = (TH1D*)data->Clone("ratio");
   else if (signal[0]) 
     ratioPlot = (TH1D*)signal[0]->Clone("ratio"); // just for getting the axis
   else if (signal[1])
     ratioPlot = (TH1D*)signal[1]->Clone("ratio");
   else
     return canvas;

   ratioPlot->SetTitle("");
   ratioPlot->Divide(allBackgrounds);
   ratioPlot->GetYaxis()->SetTitle("Data / bkg");
   ratioPlot->GetXaxis()->SetTitle(axisName.c_str());

   if (data){
     
     // here change ratio_min and ratio_max if the ratio plot is quite flat
     double maxDeviation=0;
     double minDeviation=10.;
     double tempDev=0;
     for(int ibin=1; ibin<=allBackgrounds->GetNbinsX(); ibin++){
       double binContent = ratioPlot->GetBinContent(ibin);
       tempDev=0;
       if(binContent>0 && binContent < 10) tempDev = std::abs(binContent-1.);
       if(tempDev > maxDeviation) maxDeviation = tempDev;
       if(tempDev < minDeviation) minDeviation = tempDev;
     }
     if(maxDeviation < 0.6){
       ratio_max = 1.6;
       ratio_min = 0.4;
     }
     else if(maxDeviation < 0.1){
       ratio_max = 1.12;
       ratio_min = 0.88;
     }
     else if(maxDeviation < 0.2){
       ratio_max = 1.25;
       ratio_min = .75;
     }
     if(minDeviation > 1.5){
       if(minDeviation > 2.)
	 ratio_max = 2.7;
       else
	 ratio_max = 2.2;
     }
     ratioPlot->SetMinimum(ratio_min);
     ratioPlot->SetMaximum(ratio_max);
   }     

   if(ratioPlot->GetXaxis()->GetNdivisions() > ratioPlot->GetNbinsX())
     ratioPlot->GetXaxis()->SetNdivisions(ratioPlot->GetNbinsX());
   if(ratioPlot->GetXaxis()->GetNdivisions() > 11)
     ratioPlot->GetXaxis()->SetNdivisions(11);
   ratioPlot->GetXaxis()->SetLabelSize(RATIOPLOT_XAXIS_LABEL_SIZE);
   ratioPlot->GetYaxis()->SetLabelSize(RATIOPLOT_YAXIS_LABEL_SIZE);
   ratioPlot->GetYaxis()->SetNdivisions(3);
   ratioPlot->GetYaxis()->SetTitleSize(RATIOPLOT_YAXIS_TITLE_SIZE);
   ratioPlot->GetYaxis()->SetTitleOffset(RATIOPLOT_YAXIS_TITLE_OFFSET);
   ratioPlot->GetXaxis()->SetTitleSize(RATIOPLOT_XAXIS_TITLE_SIZE);
   ratioPlot->GetXaxis()->SetTitleOffset(RATIOPLOT_XAXIS_TITLE_OFFSET);
   
   if(data){
     ratioPlot->Draw();
     // plot horizontal line at y=1
     TF1* horizontal = new TF1("horizontal","pol1",-10000,10000);
     horizontal->SetParameter(0,1.);
     horizontal->SetParameter(1,0.);
     horizontal->SetLineColor(kBlack);
     horizontal->SetLineStyle(2);
     horizontal->SetLineWidth(1);
     horizontal->Draw("same");
     ratioErr->Draw("E2 same");
   }else{ // there is no data
     ratioPlot->Draw("axis");
     char text[]="NO DATA";
     myText(0.4,0.6,1,.15,text);
   }
   
   return canvas;
}
Beispiel #15
0
// *************************************** //
// this is a function that takes a set of  //
// histograms and draws them on a canvas   //
// in a stack, returning the canvas.       //
// It also plots the signal as a dashed    //
// line and the data with a ratio at the   //
// the bottom of data/allBackgrounds       //
//                                         //
// This one is supposed to match the plots //
// make by JP                              //
// *************************************** //
TCanvas* drawPlots::plotAll_VLQ(std::vector<TH1D*> histos, std::vector<std::string> names, std::string axisName, std::vector<TH1D*> signal, TH1D* data, TGraphAsymmErrors* err, bool isSignalRegion, bool doLogAxis, std::string channel){

   const unsigned int CANVAS_WIDTH  = 720;
   const unsigned int CANVAS_HEIGHT = 750;
   const double RATIOPLOT_YAXIS_TITLE_OFFSET = 0.75;
   const double RATIOPLOT_YAXIS_TITLE_SIZE   = 0.11;
   const double RATIOPLOT_YAXIS_LABEL_SIZE   = 0.09;  
   const double RATIOPLOT_XAXIS_TITLE_OFFSET = 1.6;
   const double RATIOPLOT_XAXIS_TITLE_SIZE   = 0.11;
   const double RATIOPLOT_XAXIS_LABEL_SIZE   = 0.09;
   
   TCanvas* canvas = new TCanvas("canvas","canvas",0,0,CANVAS_WIDTH,CANVAS_HEIGHT);
   
   canvas->SetMargin(0.,0.,0.,0.);
   canvas->Clear();
   canvas->cd();
   
   SetAtlasStyle();
   gStyle->SetHistLineWidth(1.);
   
   // create histogram to store all backgrounds
   TH1D* allBackgrounds;
   bool gotSomething=false;
   for(int c=0; c<signal.size(); c++){
     if(signal[c]){
       allBackgrounds = (TH1D*)signal[c]->Clone("all_backgrounds");
       gotSomething=true;
     }
   }
   if(!gotSomething && data)
     allBackgrounds = (TH1D*)data->Clone("all_backgrounds");
   if(!gotSomething){
     for(int b=0; b<histos.size(); b++){
       if(histos[b] && !gotSomething){
	 allBackgrounds = (TH1D*)histos[b]->Clone("all_backgrounds");
	 gotSomething=true;
       }
     }
   }

   if(!gotSomething){
     std::cout << "Error: could not find any background, data, or signal for this plot" << std::endl;
     return canvas;
   }
   
   // set all bins to zero
   for(int i=0; i<=allBackgrounds->GetNbinsX()+1; i++)
     allBackgrounds->SetBinContent(i,0);
   
   // make stack of backgrounds, fill backgrounds histogram
   THStack* Stack = new THStack();
   for(int b=0; b<histos.size(); b++){
     if(histos[b]){
       if(histos[b]->GetEntries() > 0.){
	 histos[b]->SetLineColor(1);
	 histos[b]->SetFillColor(tools::setColor(names[b]));
	 Stack->Add(histos[b]);
	 for(int j=0; j<=allBackgrounds->GetNbinsX()+1; j++){
	   double binContent=allBackgrounds->GetBinContent(j)+histos[b]->GetBinContent(j);
	   allBackgrounds->SetBinContent(j,binContent);
	 }
       }
     }
   } 
   TH1D* backgroundsForRatio = (TH1D*)allBackgrounds->Clone("bkgds_for_ratio");

   // create main pad
   const double mainPad_ylow  = 0.3;
   const double mainPad_yhigh = 0.95;
   const double mainPad_xlow = 0.;
   const double mainPad_xhigh = 0.95;
   const double pad_margin_left = 0.2;
   const double pad_margin_right  = 0.02;
   double main_y_max = -99;
   double main_y_min = -99;

   TPad* mainPad = new TPad("main","main",mainPad_xlow,mainPad_ylow,mainPad_xhigh,mainPad_yhigh);
   mainPad->SetMargin(pad_margin_left,pad_margin_right,0.,.05); // left, right, bottom, top
   mainPad->Draw();
   mainPad->cd();

   // find max y
   if(allBackgrounds){
     int maxBinBkg = allBackgrounds->GetMaximumBin();
     double bkgYmax = allBackgrounds->GetBinContent(maxBinBkg);
     main_y_max = bkgYmax;
   }
   if(data){
     int maxBinData = data->GetMaximumBin();
     double dataYmax = data->GetBinContent(maxBinData);
     if(dataYmax > main_y_max) main_y_max = dataYmax;
   }
   if(main_y_max < .002) main_y_max = .1;

   if(doLogAxis){
     mainPad->SetLogy();
     main_y_min = 0.007;
     main_y_max*=600;
   }else{
     main_y_min = 0.001;
     main_y_max*=1.6;
   }

   // draw axis
   allBackgrounds->SetMaximum(main_y_max);
   allBackgrounds->SetMinimum(main_y_min);
   std::string title = std::string(";") + axisName + ";events/bin";
   allBackgrounds->SetTitle(title.c_str());   
   allBackgrounds->GetYaxis()->SetTitleOffset(1.4);
   allBackgrounds->GetYaxis()->SetTitleSize(0.06);
   allBackgrounds->GetXaxis()->SetTitleOffset(1.2);
   allBackgrounds->GetYaxis()->SetLabelSize(0.04);
   allBackgrounds->GetXaxis()->SetLabelSize(0.04);
   allBackgrounds->Draw("hist");

   // draw stack with error
   Stack->Draw("hist same");
   if(err){
     err->Draw("E2 same");
   }

   // make error histograms for the ratio plot
   TGraphAsymmErrors* ratioErr = tools::getRatio(err, backgroundsForRatio);

   // draw data
   if(!isSignalRegion && data)
      data->Draw("e same");

   // draw signal
   if(signal[0]){
     signal[0]->SetLineStyle(2);
     signal[0]->SetLineColor(kRed);
     signal[0]->SetLineWidth(5);
     signal[0]->Draw("hist same");
   }
   if(signal.size() > 1){
     if(signal[1]){
       signal[1]->SetLineStyle(2);
       signal[1]->SetLineColor(kOrange+7);
       signal[1]->SetLineWidth(4);
       signal[1]->Draw("hist same");
     }
     if(signal.size() > 2){
       if(signal[2]){
	 signal[2]->SetLineStyle(2);
	 signal[2]->SetLineColor(kPink-6);
	 signal[2]->SetLineWidth(4);
	 signal[2]->Draw("hist same");
       }
     }
   }
   allBackgrounds->Draw("axis same");

   // draw legend
   float leg_height = 0.45;
   float leg_width = 0.2;
   float leg_xoffset = 0.74;
   float leg_yoffset = 0.7;
   
   TLegend* leg = new TLegend(leg_xoffset,leg_yoffset-leg_height/2,leg_xoffset+leg_width,leg_yoffset+leg_height/2);
   leg->SetFillColor(0);
   leg->SetFillStyle(0);
   leg->SetBorderSize(0);
   leg->SetTextFont(52);
   leg->SetTextSize(0.033);
   
   // currently assuming first signal is Tbq (single T production), second is TTS, third is BBS
   if(signal[0])
     leg->AddEntry(signal[0], "Tbq (650 GeV)", "l");
   if(signal.size()>1){
     if(signal[1])
       leg->AddEntry(signal[1], "TT_{S} (650 GeV)", "l");
     if(signal[2])
       leg->AddEntry(signal[2], "BB_{S} (650 GeV)", "l");
   }
   if(!isSignalRegion)
     leg->AddEntry(data, "data 2012");
   for(int q=0; q<histos.size(); q++){
     if(histos[q]){
       if(histos[q]->GetEntries() > 0.)
	 leg->AddEntry(histos[q], plotLists::GetLegendName(names[q]).c_str(), "f");
     }
   }
   leg->Draw("lpe");
   
   ATLAS_LABEL(0.24,0.86,1);
   myText(0.36, 0.86, 1, .05, "Internal");
   char text[]="#sqrt{s}=8 TeV";
   myText(0.55,0.77,1,.04, text);
   char text_L[]="#int L dt = 20.3 fb^{-1}";
   myText(0.5, 0.84,1, .04, text_L);
   if(channel!=""){
     char chan_txt[channel.size()-1];
     strcpy(chan_txt, (channel.substr(1)).c_str());
     myText(0.5, 0.7, 1, .06, chan_txt);
   }
   char inText[100];
   int t;
   if(signal[0])
     t=sprintf(inText, "N_{Tbq} = %.1f", signal[0]->Integral(0,signal[0]->GetNbinsX()+1));
   else
     t=sprintf(inText, "N_{Tbq} = %.1f", 0.);
   myText(0.24, 0.7, 1, .04, inText);
   if(signal.size()>1){
     if(signal[1])
       t=sprintf(inText, "N_{TTS} = %.1f", signal[1]->Integral(0,signal[1]->GetNbinsX()+1));
     else
       t=sprintf(inText, "N_{TTS} = %.1f", 0.);
     myText(0.24, 0.65, 1, .04, inText);
     if(signal.size()>2){
       if(signal[2])
	 t=sprintf(inText, "N_{BBS} = %.1f", signal[2]->Integral(0,signal[2]->GetNbinsX()+1));
       else
	 t=sprintf(inText, "N_{BBS} = %.1f", 0.);
       myText(0.24, 0.6, 1, .04, inText);
     }
   }

   double back_int = allBackgrounds->Integral(0,allBackgrounds->GetNbinsX()+1);
   if(back_int > 10000.)
     t=sprintf(inText, "N_{B} = %.3e", back_int);
   else
     t=sprintf(inText, "N_{B} = %.1f", back_int);
   myText(0.24, 0.75, 1, .04, inText);
   if(!isSignalRegion){
     if(data)
       t=sprintf(inText, "N_{D} = %.0f", data->Integral(0,data->GetNbinsX()+1));
     else
       t=sprintf(inText, "N_{D} = %.0f", 0.);
     myText(0.24, 0.8, 1, .04, inText);
   }
   
   canvas->cd();
   
   // Draw Ratio plot
   double ratio_max = 1.6;
   double ratio_min = 0.4;
  
   double pad_xlow = 0.;
   double pad_xhigh = 0.95;
   double pad_ylow = 0.0;
   double pad_yhigh = 0.3;
   
   const char* pad_name = "pad";
   TPad* pad4ratio = new TPad(pad_name,pad_name,pad_xlow,pad_ylow,pad_xhigh,pad_yhigh);

   pad4ratio->SetMargin(pad_margin_left,pad_margin_right,0.46,0.);
   pad4ratio->Draw();
   pad4ratio->cd();

   TH1D* ratioPlot;
   if(data)
     ratioPlot = (TH1D*)data->Clone("ratio");
   else if (signal[0]) 
     ratioPlot = (TH1D*)signal[0]->Clone("ratio"); // just for getting the axis

   ratioPlot->SetTitle("");
   ratioPlot->Divide(allBackgrounds);
   ratioPlot->GetYaxis()->SetTitle("Data/MC");
   ratioPlot->GetXaxis()->SetTitle(axisName.c_str());

   if (data){
     // here change ratio_min and ratio_max if the ratio plot is quite flat
     double maxDeviation=0;
     double tempDev=0;
     for(int ibin=1; ibin<=allBackgrounds->GetNbinsX(); ibin++){
       tempDev = std::abs(ratioPlot->GetBinContent(ibin)-1.);
       if(tempDev > maxDeviation) maxDeviation = tempDev;
     }
     if(maxDeviation < 0.1){
       ratio_max = 1.12;
       ratio_min = 0.88;
     }
     else if(maxDeviation < 0.2){
       ratio_max = 1.25;
       ratio_min = .75;
     }
     ratioPlot->SetMinimum(ratio_min);
     ratioPlot->SetMaximum(ratio_max);
   }     

   if(ratioPlot->GetXaxis()->GetNdivisions() > ratioPlot->GetNbinsX())
     ratioPlot->GetXaxis()->SetNdivisions(ratioPlot->GetNbinsX());
   if(ratioPlot->GetXaxis()->GetNdivisions() > 11)
     ratioPlot->GetXaxis()->SetNdivisions(11);
   ratioPlot->GetXaxis()->SetLabelSize(RATIOPLOT_XAXIS_LABEL_SIZE);
   ratioPlot->GetYaxis()->SetLabelSize(RATIOPLOT_YAXIS_LABEL_SIZE);
   ratioPlot->GetYaxis()->SetNdivisions(3);
   ratioPlot->GetYaxis()->SetTitleSize(RATIOPLOT_YAXIS_TITLE_SIZE);
   ratioPlot->GetYaxis()->SetTitleOffset(RATIOPLOT_YAXIS_TITLE_OFFSET);
   ratioPlot->GetXaxis()->SetTitleSize(RATIOPLOT_XAXIS_TITLE_SIZE);
   ratioPlot->GetXaxis()->SetTitleOffset(RATIOPLOT_XAXIS_TITLE_OFFSET);
   
   if(!isSignalRegion && data){
     ratioPlot->Draw();
     // plot horizontal line at y=1
     TF1* horizontal = new TF1("horizontal","pol1",-10000,10000);
     horizontal->SetParameter(0,1.);
     horizontal->SetParameter(1,0.);
     horizontal->SetLineColor(kBlack);
     horizontal->SetLineStyle(2);
     horizontal->SetLineWidth(1);
     horizontal->Draw("same");
     ratioErr->Draw("E2 same");
   }else if(isSignalRegion){
     ratioPlot->Draw("axis");
     char text[]="DATA IS BLIND HERE";
     myText(0.4,0.6,1,.15,text);
   }else{ // in this case it is not the signal region but there is no data
     ratioPlot->Draw("axis");
     char text[]="NO DATA";
     myText(0.4,0.6,1,.15,text);
   }
   
   return canvas;
}
Beispiel #16
0
// *************************************** //
// this is a function that takes a set of  //
// histograms and draws them on a canvas   //
// in a stack, returning the canvas.       //
// It also plots the signal as a dashed    //
// line and the data with a ratio at the   //
// the bottom of data/allBackgrounds       //
// *************************************** //
TCanvas* drawPlots::plotAll(std::vector<TH1D*> histos, std::vector<std::string> names, std::string axisName, TH1D* signal, TH1D* data, TH1D* errDown, TH1D* errUp, bool isSignalRegion, bool doLogAxis){
         
   const unsigned int MAINPLOT_WIDTH  = 800;
   const unsigned int MAINPLOT_HEIGHT = 500;
   const unsigned int RATIOPLOT_HEIGHT = 125;
   const unsigned int OFFSET = 10;
   
  //LUKE: Title offset and title size are proportional in 
  //root, so you have to change them together, 
  //this makes me a sad panda 
   const double RATIOPLOT_YAXIS_TITLE_OFFSET = 0.4;
   const double RATIOPLOT_YAXIS_TITLE_SIZE   = 0.14;
   const double RATIOPLOT_YAXIS_TICK_LENGTH  = 0.01;
   const double RATIOPLOT_YAXIS_LABEL_SIZE   = 0.15;
  
   const double RATIOPLOT_XAXIS_TITLE_OFFSET = 0.9;
   const double RATIOPLOT_XAXIS_TITLE_SIZE   = 0.2;
   const double RATIOPLOT_XAXIS_TICK_LENGTH  = 0.05;
   const double RATIOPLOT_XAXIS_LABEL_SIZE   = 0.2;
   
   const double CANVAS_HEIGHT = MAINPLOT_HEIGHT+RATIOPLOT_HEIGHT+OFFSET;
   
   TCanvas* canvas = new TCanvas("canvas","canvas",0,0,MAINPLOT_WIDTH,CANVAS_HEIGHT);
   
   canvas->SetMargin(0.,0.,0.,0.);
   canvas->Clear();
   canvas->cd();
   
   // create main pad
   const double mainPad_ylow  = (CANVAS_HEIGHT - MAINPLOT_HEIGHT)/CANVAS_HEIGHT;
   const double mainPad_yhigh = 1.;
  
   const double pad_margin_left = 0.15;
   const double pad_margin_right  = 0.05;
   
   double main_y_max = -99;
   double main_y_min = -99;
   double main_x_max = -99;
   double main_x_min = -99;
   for(int a=0; a<histos.size(); a++){
     if(histos[a]){
       if(histos[a]->GetEntries()> 0.){
	 GetAxisLimits(histos[a], main_x_min, main_x_max, main_y_min, main_y_max);
       }
     }
   }
   
   if(data){
     int maxBinData = data->GetMaximumBin();
     double dataYmax = data->GetBinContent(maxBinData);
     if(dataYmax > main_y_max) main_y_max = dataYmax;
   }

   // create main pad
   TPad* mainPad = new TPad("main","main",0.,mainPad_ylow,1.,mainPad_yhigh);
   mainPad->SetMargin(pad_margin_left,pad_margin_right,0.,.05); // left, right, bottom, top
   mainPad->Draw();
   mainPad->cd();

   SetAtlasStyle();

   if(doLogAxis)mainPad->SetLogy();

   // clone signal or data because one should exist for each plot
   TH1D* allBackgrounds;
   bool gotSomething=false;
   if(signal)
     allBackgrounds = (TH1D*)signal->Clone("all_backgrounds");
   else if(data)
     allBackgrounds = (TH1D*)data->Clone("all_backgrounds");
   else{
     for(int b=0; b<histos.size(); b++){
       if(histos[b] && !gotSomething){
	 allBackgrounds = (TH1D*)histos[b]->Clone("all_backgrounds");
	 gotSomething=true;
       }
     }  
   }

   // set all bins to zero so that you can add all histograms to it
   for(int i=0; i<=allBackgrounds->GetNbinsX()+1; i++)
      allBackgrounds->SetBinContent(i,0);
   
   THStack* Stack = new THStack();
   std::string title = std::string(";") + axisName + ";Events";
   Stack->SetTitle(title.c_str());
   
   for(int b=0; b<histos.size(); b++){
     if(histos[b]){
       if(histos[b]->GetEntries() > 0.){
	 histos[b]->SetLineColor(1);
	 histos[b]->SetFillColor(tools::setColor(names[b]));
	 Stack->Add(histos[b]);
	 for(int j=0; j<=allBackgrounds->GetNbinsX()+1; j++){
	   double binContent=allBackgrounds->GetBinContent(j)+histos[b]->GetBinContent(j);
	   allBackgrounds->SetBinContent(j,binContent);
	 }
       }
     }
   }

   TH1D* backgroundsForRatio = (TH1D*)allBackgrounds->Clone("bkgds_for_ratio");
   
   if(doLogAxis){ 
     main_y_max = main_y_max*10;
     if(Stack->GetMinimum()>.1) Stack->SetMinimum(.1);
   }
   else main_y_max = main_y_max*1.4;
   Stack->SetMaximum(main_y_max);
   Stack->Draw("hist");
   errDown->Draw("E2same");
   errUp->Draw("E2Same");
   
   // make error histograms for the ratio plot
   TH1D* ratioErrDown = (TH1D*) errDown->Clone("ratio_error_down");
   TH1D* ratioErrUp = (TH1D*) errUp->Clone("ratio_error_up");

   ratioErrDown->Divide(backgroundsForRatio);
   ratioErrUp->Divide(backgroundsForRatio);

   if(!isSignalRegion && data)
      data->Draw("e same");

   if(signal){
     signal->SetLineStyle(2);
     signal->SetLineColor(kRed);
     signal->SetLineWidth(5);
     signal->Draw("hist same");
   }

   TLegend* leg = new TLegend(0.8,0.65,0.95,0.9);
   leg->SetFillStyle(0);
   leg->SetBorderSize(0);
   
   if(signal)
     leg->AddEntry(signal, "Signal", "l");
   if(!isSignalRegion)
     leg->AddEntry(data, "Data");
   for(int q=0; q<histos.size(); q++){
     if(histos[q]){
       if(histos[q]->GetEntries() > 0.)
	 leg->AddEntry(histos[q], names[q].c_str(), "f");
     }
   }
   leg->Draw("lpe");
   
   ATLAS_LABEL(0.2,0.85,1);
   char text[]="#sqrt{s}=8 TeV";
   myText(0.6,0.75,1,.04, text);
   char text_L[]="#int L dt = 20.3 fb^{-1}";
   myText(0.6, 0.85,1, .04, text_L);
   char inText[100];
   int t;
   if(signal)
     t=sprintf(inText, "N_{Signal} = %.1f", signal->Integral(0,signal->GetNbinsX()+1));
   else
     t=sprintf(inText, "N_{Signal} = %.1f", 0.);
   myText(0.2, 0.75, 1, .04, inText);
   double back_int = allBackgrounds->Integral(0,allBackgrounds->GetNbinsX()+1);
   if(back_int > 10000.)
     t=sprintf(inText, "N_{Bkgd} = %.3e", back_int);
   else
     t=sprintf(inText, "N_{Bkgd} = %.1f", back_int);
   myText(0.2, 0.7, 1, .04, inText);
   if(!isSignalRegion){
     if(data)
       t=sprintf(inText, "N_{Data} = %.0f", data->Integral(0,data->GetNbinsX()+1));
     else
       t=sprintf(inText, "N_{Data} = %.0f", 0.);
     myText(0.2, 0.65, 1, .04, inText);
   }
   
   canvas->cd();
   
   // Draw Ratio plot
   double ratio_max = 1.6;
   double ratio_min = 0.4;
  
   const double x_axis_size = 0.4;
   const double ratio_pad_height = RATIOPLOT_HEIGHT/CANVAS_HEIGHT;
   
   double pad_xlow = 0.,pad_xhigh = 1.;
   double pad_ylow = OFFSET/CANVAS_HEIGHT,pad_yhigh = ratio_pad_height;
   
   const char* pad_name = "pad";
   TPad* pad4ratio = new TPad(pad_name,pad_name,pad_xlow,pad_ylow,pad_xhigh,pad_yhigh);
   
   pad4ratio->SetMargin(pad_margin_left,pad_margin_right,x_axis_size,0.);
   pad4ratio->Draw();
   pad4ratio->cd();

   TH1D* ratioPlot;
   if(data) ratioPlot = (TH1D*)data->Clone("ratio");
   else if(signal) ratioPlot = (TH1D*)signal->Clone("ratio"); // if there is no data then use signal for axis 
   ratioPlot->SetTitle("");
   ratioPlot->GetYaxis()->SetTitle("Data/MC");
   ratioPlot->GetXaxis()->SetTitle(axisName.c_str());
   if(data){
     ratioPlot->Divide(allBackgrounds);
     // here change ratio_min and ratio_max if the ratio plot is quite flat
     double maxDeviation=0;
     double tempDev=0;
     for(int ibin=1; ibin<=allBackgrounds->GetNbinsX(); ibin++){
       tempDev = std::abs(ratioPlot->GetBinContent(ibin)-1.);
       if(tempDev > maxDeviation) maxDeviation = tempDev;
     }
     if(maxDeviation < 0.1){
       ratio_max = 1.12;
       ratio_min = 0.88;
     }
     else if(maxDeviation < 0.2){
       ratio_max = 1.25;
       ratio_min = .75;
     }
     ratioPlot->SetMinimum(ratio_min);
     ratioPlot->SetMaximum(ratio_max);
   }
   ratioPlot->GetXaxis()->SetLabelSize(RATIOPLOT_XAXIS_LABEL_SIZE);
   ratioPlot->GetXaxis()->SetTickLength(RATIOPLOT_XAXIS_TICK_LENGTH);
   ratioPlot->GetYaxis()->SetLabelSize(RATIOPLOT_YAXIS_LABEL_SIZE);
   ratioPlot->GetYaxis()->SetTickLength(RATIOPLOT_YAXIS_TICK_LENGTH);
   ratioPlot->GetYaxis()->SetNdivisions(3);
   ratioPlot->GetYaxis()->SetTitleSize(RATIOPLOT_YAXIS_TITLE_SIZE);
   ratioPlot->GetYaxis()->SetTitleOffset(RATIOPLOT_YAXIS_TITLE_OFFSET);
   ratioPlot->GetXaxis()->SetTitleSize(RATIOPLOT_XAXIS_TITLE_SIZE);
   ratioPlot->GetXaxis()->SetTitleOffset(RATIOPLOT_XAXIS_TITLE_OFFSET);
   
   if(!isSignalRegion && data){
     ratioPlot->Draw();
     // plot horizontal line at y=1
     TF1* horizontal = new TF1("horizontal","pol1",-10000,10000);
     horizontal->SetParameter(0,1.);
     horizontal->SetParameter(1,0.);
     horizontal->SetLineColor(kBlack);
     horizontal->SetLineStyle(2);
     horizontal->SetLineWidth(1);
     horizontal->Draw("same");
     ratioErrDown->Draw("E2same");
     ratioErrUp->Draw("E2same");
   }else if(isSignalRegion){
     ratioPlot->Draw("axis");
     char text[]="DATA IS BLINDED HERE";
     myText(0.4,0.6,1,.2,text);
   }else{ // in this case it is not the signal region but there is no data
     ratioPlot->Draw("axis");
     char text[]="NO DATA";
     myText(0.4,0.6,1,.2,text);
     }
   
   return canvas;
}
Beispiel #17
0
// *************************************** //
// this is a function that draws all       //
// backrounds as a grey area, and compares //
// the shape of the backgrounds to that of //
// the signal                              //
// This one is supposed to match the plots //
// make by JP (Fig 3 of CONF note)         //
// *************************************** //
TCanvas* drawPlots::plotShape_VLQ(TH1D* bkgd, std::string axisName, std::vector<TH1D*> signal, bool doLogAxis, std::string channel){

  // only drawing shapes so normalize histograms
  std::cout << "background integral: " << bkgd->Integral() << std::endl;
  bkgd->Scale(1./bkgd->Integral());
  for(int ahist=0; ahist<signal.size(); ahist++){
    if(signal[ahist]){
      std::cout << "scaling signal: " << ahist << " with integral: " << signal[ahist]->Integral() << std::endl;
      signal[ahist]->Scale(1./signal[ahist]->Integral());
    }
  }

   const unsigned int CANVAS_WIDTH  = 720;
   const unsigned int CANVAS_HEIGHT = 750;
   TCanvas* canvas = new TCanvas("canvas","canvas",0,0,CANVAS_WIDTH,CANVAS_HEIGHT);
   
   canvas->SetMargin(0.,0.,0.,0.);
   canvas->Clear();
   canvas->cd();

   SetAtlasStyle();
   gStyle->SetHistLineWidth(1.);

   
   // create main pad
   const double mainPad_ylow  = 0.;
   const double mainPad_yhigh = 1.;
   const double mainPad_xlow = 0.;
   const double mainPad_xhigh = 1.;
   const double pad_margin_left = 0.16;
   const double pad_margin_right  = 0.035;
   
   double main_y_max = -99;
   double main_y_min = -99;

   TPad* mainPad = new TPad("main","main",mainPad_xlow,mainPad_ylow,mainPad_xhigh,mainPad_yhigh);
   mainPad->SetMargin(pad_margin_left,pad_margin_right,0.16,.05); // left, right, bottom, top
   mainPad->Draw();
   mainPad->cd();

   // find max y
   int maxBinBkg = bkgd->GetMaximumBin();
   double bkgYmax = bkgd->GetBinContent(maxBinBkg);
   main_y_max = bkgYmax;
   //   std::cout << "background maximum: " << bkgYmax << std::endl;
   if(main_y_max < .002) main_y_max = .1;
   
   if(doLogAxis){
     mainPad->SetLogy();
     main_y_min = 0.0001;
     main_y_max*=500;
   }else{
     main_y_min = 0.00001;
     main_y_max*=1.6;
   }

   // draw axis
   bkgd->SetMaximum(main_y_max);
   bkgd->SetMinimum(main_y_min);
   std::string title = std::string(";") + axisName + ";Fraction of events";
   std::stringstream binw; 
   binw<<bkgd->GetBinWidth(1);
   std::string width = binw.str();
   if (axisName.find("GeV") != std::string::npos) width += " GeV";
   if(bkgd->GetBinWidth(1) != 1) title += " / "+width;
   bkgd->SetTitle(title.c_str());   
   bkgd->GetYaxis()->SetTitleOffset(1.6);
   bkgd->GetXaxis()->SetTitleOffset(1.2);
   bkgd->GetYaxis()->SetLabelSize(0.03);
   bkgd->GetYaxis()->SetTitleSize(0.045);
   bkgd->GetXaxis()->SetTitleSize(0.045);
   bkgd->GetXaxis()->SetLabelSize(0.03);
   bkgd->SetFillStyle(3354);
   bkgd->SetFillColor(kGray+2);
   bkgd->SetLineColor(kGray+2);
   bkgd->Draw("histf");

   // draw signal
   if(signal[0]){
     std::cout << "printing Tbq" << std::endl;
     signal[0]->SetLineStyle(2);
     signal[0]->SetLineColor(kRed+2); // kGreen+3 was being used before
     signal[0]->SetLineWidth(5);
     signal[0]->Draw("hist same");
   }
   if(signal.size() > 1){
     if(signal[1]){
       std::cout << "printing TTS" << std::endl;
       //   signal[1]->SetLineStyle(2);
       signal[1]->SetLineColor(kRed+2);
       signal[1]->SetLineWidth(4);
       signal[1]->Draw("hist same");
     }
     if(signal.size() > 2){
       if(signal[2]){
	 std::cout << "printing BBS" << std::endl;
	 //	 signal[2]->SetLineStyle(2);
	 signal[2]->SetLineColor(kBlue+2);
	 signal[2]->SetLineWidth(4);
	 signal[2]->Draw("hist same");
       }
     }
   }
   bkgd->Draw("axis same");

   // draw legend
   float leg_height = 0.2;
   float leg_width = 0.4;
   float leg_xoffset = 0.65;
   float leg_yoffset = 0.8;
   
   TLegend* leg = new TLegend(leg_xoffset,leg_yoffset-leg_height/2,leg_xoffset+leg_width,leg_yoffset+leg_height/2);
   leg->SetFillColor(0);
   leg->SetFillStyle(0);
   leg->SetBorderSize(0);
   leg->SetTextFont(72);
   leg->SetTextSize(0.026);
   
   // currently assuming first signal is single T, second is TTS
   leg->AddEntry(bkgd,"Background", "f");
   if(signal.size()>1){
     if(signal.size()>2){
       if(signal[2])
	 leg->AddEntry(signal[2], "B#bar{B} (650 GeV)", "l");
     }
     if(signal[1])
       leg->AddEntry(signal[1], "T#bar{T} (650 GeV)", "l");
   }  
   if(signal[0])
     leg->AddEntry(signal[0], "T#bar{b}q (650 GeV)", "l");
   
   leg->Draw("lpe");
   
   ATLAS_LABEL(0.24,0.86,1);
   myText(0.26, 0.81, 1, .04, "Internal");
   char text[]="#sqrt{s}=8 TeV";
   myText(0.48,0.82,1,.03, text);
   char text_L[]="Simulation";
   myText(0.47, 0.87,1, .03, text_L);
   char text_tri[]="Trilepton";
   myText(0.485, 0.77, 1, .03, text_tri);
   if(channel!=""){
     char chan_txt[channel.size()-1];
     strcpy(chan_txt, (channel.substr(1)).c_str());
     if(channel.size()>10)
       myText(0.55, 0.56, 1, .03, chan_txt);
     else
       myText(0.65, 0.56, 1, .03, chan_txt);
   }
   canvas->cd();
   
   return canvas;
}
void
QA_Draw_HCALIN_TowerCluster(
    const char * qa_file_name_new =
        "/phenix/u/jinhuang/links/ePHENIX_work/sPHENIX_work/production_analysis_updates/spacal1d/fieldmap/G4Hits_sPHENIX_pi-_eta0.30_32GeV-0000.root_qa.root",
    const char * qa_file_name_ref =
        "/phenix/u/jinhuang/links/ePHENIX_work/sPHENIX_work/production_analysis_updates/spacal1d/fieldmap/G4Hits_sPHENIX_pi+_eta0.30_32GeV-0000.root_qa.root")
{

  SetOKStyle();
  gStyle->SetOptStat(0);
  gStyle->SetOptFit(1111);
  TVirtualFitter::SetDefaultFitter("Minuit2");

  TFile * qa_file_new = new TFile(qa_file_name_new);
  assert(qa_file_new->IsOpen());

  TFile * qa_file_ref = NULL;
  if (qa_file_name_ref)
    {
      qa_file_ref = new TFile(qa_file_name_ref);
      assert(qa_file_ref->IsOpen());
    }

  TCanvas *c1 = new TCanvas("QA_Draw_HCALIN_TowerCluster",
      "QA_Draw_HCALIN_TowerCluster", 1800, 900);
  c1->Divide(4, 2);
  int idx = 1;
  TPad * p;

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogx();
  p->SetLogy();

    {
      TH1F * h_new = (TH1F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_HCALIN_Tower_1x1", "TH1F");
      assert(h_new);

      h_new->Scale(1. / h_new->GetSum());

      TH1F * h_ref = NULL;
      if (qa_file_ref)
        {
          TH1F * h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_HCALIN_Tower_1x1", "TH1F");
          assert(h_ref);

          h_ref->Scale(1. / h_ref->GetSum());
        }

      h_new->GetYaxis()->SetTitleOffset(1.5);
      h_new->GetYaxis()->SetTitle("Normalized tower count per bin");
//      h_new->GetXaxis()->SetRangeUser(-0, .1);

      DrawReference(h_new, h_ref);
    }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogx();
  p->SetLogy();

    {
      TH1F * h_new = (TH1F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_HCALIN_Tower_3x3", "TH1F");
      assert(h_new);

      h_new->Scale(1. / h_new->GetSum());

      TH1F * h_ref = NULL;
      if (qa_file_ref)
        {
          TH1F * h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_HCALIN_Tower_3x3", "TH1F");
          assert(h_ref);

          h_ref->Scale(1. / h_ref->GetSum());
        }

      h_new->GetYaxis()->SetTitleOffset(1.5);
      h_new->GetYaxis()->SetTitle("Normalized tower count per bin");
      //      h_new->GetXaxis()->SetRangeUser(-0, .1);

      DrawReference(h_new, h_ref);
    }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //    p->SetLogx();
  p->SetLogy();

    {

      TH1F * h_new = (TH1F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_HCALIN_Tower_1x1_max", "TH1F");
      assert(h_new);

      h_new->Rebin(40);
      h_new->Sumw2();
      h_new->Scale(1. / h_new->GetSum());

      TH1F * h_ref = NULL;
      if (qa_file_ref)
        {
          TH1F * h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_HCALIN_Tower_1x1_max", "TH1F");
          assert(h_ref);

          h_ref->Rebin(40);
          h_ref->Scale(1. / h_ref->GetSum());
        }

      h_new->GetYaxis()->SetTitleOffset(1.5);
      h_new->GetYaxis()->SetTitle("Probability per bin");
      //      h_new->GetXaxis()->SetRangeUser(-0, .1);

      DrawReference(h_new, h_ref);
    }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //    p->SetLogx();
  p->SetLogy();

    {

      TH1F * h_new = (TH1F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_HCALIN_Tower_4x4_max", "TH1F");
      assert(h_new);

      h_new->Rebin(40);
      h_new->Sumw2();
      h_new->Scale(1. / h_new->GetSum());

      TH1F * h_ref = NULL;
      if (qa_file_ref)
        {
          TH1F * h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_HCALIN_Tower_4x4_max", "TH1F");
          assert(h_ref);

          h_ref->Rebin(40);
          h_ref->Scale(1. / h_ref->GetSum());
        }

      h_new->GetYaxis()->SetTitleOffset(1.5);
      h_new->GetYaxis()->SetTitle("Probability per bin");
      //      h_new->GetXaxis()->SetRangeUser(-0, .1);

      DrawReference(h_new, h_ref);
    }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogz();

  TH2F * h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection =
      (TH2F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection", "TH2F");
  assert(h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection);
  h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection->GetYaxis()->SetTitleOffset(
      1.5);
//  h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection->GetXaxis()->SetRangeUser(-5,
//      5);
//  h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection->GetYaxis()->SetRangeUser(-5,
//      5);
  h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection->Draw("COLZ");

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogz();

    {

      TH2F * h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection =
          (TH2F *) qa_file_new->GetObjectChecked(
              "h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection", "TH2F");
      assert(h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection);

      TH1D * proj_new =
          h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection->ProjectionX(
              "qa_file_new_h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection_px");
      proj_new->Rebin(4);

      proj_new->Scale(1. / proj_new->GetSum());

      TH1D * proj_ref = NULL;
      if (qa_file_ref)
        {
          TH2F * h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection =
              (TH2F *) qa_file_ref->GetObjectChecked(
                  "h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection", "TH2F");
          assert(h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection);

          proj_ref =
              h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection->ProjectionX(
                  "qa_file_ref_h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection_px");
          proj_ref->Rebin(4);
          proj_ref->Scale(1. / proj_ref->GetSum());

        }

      proj_new->GetYaxis()->SetTitleOffset(1.);
      proj_new->GetXaxis()->SetTitleOffset(1.);
      proj_new->GetYaxis()->SetTitle("Normalized energy distribution");
//      proj_new->GetXaxis()->SetRangeUser(-10, 10);

      DrawReference(proj_new, proj_ref);
    }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogz();

    {

      TH2F * h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection =
          (TH2F *) qa_file_new->GetObjectChecked(
              "h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection", "TH2F");
      assert(h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection);

      TH1D * proj_new =
          h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection->ProjectionY(
              "qa_file_new_h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection_py");

      proj_new->Rebin(4);
      proj_new->Scale(1. / proj_new->GetSum());

      TH1D * proj_ref = NULL;
      if (qa_file_ref)
        {
          TH2F * h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection =
              (TH2F *) qa_file_ref->GetObjectChecked(
                  "h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection", "TH2F");
          assert(h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection);

          proj_ref =
              h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection->ProjectionY(
                  "qa_file_ref_h_QAG4Sim_HCALIN_Cluster_LateralTruthProjection_py");
          proj_ref->Rebin(4);
          proj_ref->Scale(1. / proj_ref->GetSum());

        }

      proj_new->GetYaxis()->SetTitleOffset(1.);
      proj_new->GetXaxis()->SetTitleOffset(1.);
      proj_new->GetYaxis()->SetTitle("Normalized energy distribution");
//      proj_new->GetXaxis()->SetRangeUser(-10, 10);

      DrawReference(proj_new, proj_ref);
    }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

    {

      TH1F * h_new = (TH1F *) qa_file_new->GetObjectChecked(
          "h_QAG4Sim_HCALIN_Cluster_BestMatchERatio", "TH1F");
      assert(h_new);

      h_new->Rebin(2);
      h_new->Sumw2();
      h_new->Scale(1. / h_new->GetSum());

      TH1F * h_ref = NULL;
      if (qa_file_ref)
        {
          TH1F * h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
              "h_QAG4Sim_HCALIN_Cluster_BestMatchERatio", "TH1F");
          assert(h_ref);

          h_ref->Rebin(2);
          h_ref->Scale(1. / h_ref->GetSum());
        }

      h_new->GetYaxis()->SetTitleOffset(1.5);
      h_new->GetYaxis()->SetTitle("Probability per bin");
      //          h_new->GetXaxis()->SetRangeUser(-0, .1);

      DrawReference(h_new, h_ref);
    }

  PutInputFileName(c1, .04, qa_file_name_new, qa_file_name_ref);
  SaveCanvas(c1, TString(qa_file_name_new) + TString(c1->GetName()), true);
}
Beispiel #19
0
void goftest() {

   // ------------------------------------------------------------------------
   // C a s e  1 :  C r e a t e   l o g N o r m a l  r a n d o m  s a m p l e
   // ------------------------------------------------------------------------
   
   UInt_t nEvents1 = 1000;

   //ROOT::Math::Random<ROOT::Math::GSLRngMT> r;
   TF1 * f1 = new TF1("logNormal","ROOT::Math::lognormal_pdf(x,[0],[1])",0,500);
   // set the lognormal parameters (m and s) 
   f1->SetParameters(4.0,1.0);
   f1->SetNpx(1000);
      

   Double_t* sample1 = new Double_t[nEvents1];

   TH1D* h1smp = new TH1D("h1smp", "LogNormal distribution histogram", 100, 0, 500);
   h1smp->SetStats(kFALSE);
   
   for (UInt_t i = 0; i < nEvents1; ++i) { 
      //Double_t data = f1->GetRandom();
      Double_t data = gRandom->Gaus(4,1);
      data = TMath::Exp(data);
      sample1[i] = data;
      h1smp->Fill(data);
   }
   // normalize correctly the histogram using the entries inside
   h1smp->Scale( ROOT::Math::lognormal_cdf(500.,4.,1) / nEvents1, "width");

   TCanvas* c = new TCanvas("c","1-Sample and 2-Samples GoF Tests");
   c->Divide(1, 2);
   TPad * pad = (TPad *)c->cd(1);
   h1smp->Draw();
   h1smp->SetLineColor(kBlue);
   pad->SetLogy();
   f1->SetNpx(100); // use same points as histo for drawing
   f1->SetLineColor(kRed);
   f1->Draw("SAME");
      
   // -----------------------------------------
   // C r e a t e   G o F T e s t  o b j e c t 
   // -----------------------------------------
   
   ROOT::Math::GoFTest* goftest_1 = new ROOT::Math::GoFTest(nEvents1, sample1, ROOT::Math::GoFTest::kLogNormal);
      
   /* Possible calls for the Anderson - DarlingTest test */
   /*----------------------------------------------------*/
   
   /* a) Returning the Anderson-Darling standardized test statistic */
   Double_t A2_1 = goftest_1-> AndersonDarlingTest("t"); 
   Double_t A2_2 = (*goftest_1)(ROOT::Math::GoFTest::kAD, "t");
   assert(A2_1 == A2_2);
  
   /* b) Returning the p-value for the Anderson-Darling test statistic */
   Double_t pvalueAD_1 = goftest_1-> AndersonDarlingTest(); // p-value is the default choice
   Double_t pvalueAD_2 = (*goftest_1)(); // p-value and Anderson - Darling Test are the default choices
   assert(pvalueAD_1 == pvalueAD_2);
   
   /* Rebuild the test using the default 1-sample construtor */
   delete goftest_1;
   goftest_1 = new ROOT::Math::GoFTest(nEvents1, sample1 ); // User must then input a distribution type option
   goftest_1->SetDistribution(ROOT::Math::GoFTest::kLogNormal);
   
   
   /* Possible calls for the Kolmogorov - Smirnov test */
   /*--------------------------------------------------*/              
       
   /* a) Returning the Kolmogorov-Smirnov standardized test statistic */
   Double_t Dn_1 = goftest_1-> KolmogorovSmirnovTest("t");
   Double_t Dn_2 = (*goftest_1)(ROOT::Math::GoFTest::kKS, "t");
   assert(Dn_1 == Dn_2);
   
   /* b) Returning the p-value for the Kolmogorov-Smirnov test statistic */
   Double_t pvalueKS_1 = goftest_1-> KolmogorovSmirnovTest();
   Double_t pvalueKS_2 = (*goftest_1)(ROOT::Math::GoFTest::kKS);
   assert(pvalueKS_1 == pvalueKS_2);
   
   /* Valid but incorrect calls for the 2-samples methods of the 1-samples constucted goftest_1 */
#ifdef TEST_ERROR_MESSAGE
    Double_t A2 = (*goftest_1)(ROOT::Math::GoFTest::kAD2s, "t");     // Issues error message
    Double_t pvalueKS = (*goftest_1)(ROOT::Math::GoFTest::kKS2s);    // Issues error message
    assert(A2 == pvalueKS);
#endif
  
   TPaveText* pt1 = new TPaveText(0.58, 0.6, 0.88, 0.80, "brNDC");
   Char_t str1[50];
   sprintf(str1, "p-value for A-D 1-smp test: %f", pvalueAD_1);
   pt1->AddText(str1);
   pt1->SetFillColor(18);
   pt1->SetTextFont(20);
   pt1->SetTextColor(4);
   Char_t str2[50];
   sprintf(str2, "p-value for K-S 1-smp test: %f", pvalueKS_1);
   pt1->AddText(str2);
   pt1->Draw();
   
   // ------------------------------------------------------------------------
   // C a s e  2 :  C r e a t e   G a u s s i a n  r a n d o m  s a m p l e s
   // ------------------------------------------------------------------------

   UInt_t nEvents2 = 2000;

   Double_t* sample2 = new Double_t[nEvents2];

   TH1D* h2smps_1 = new TH1D("h2smps_1", "Gaussian distribution histograms", 100, 0, 500);
   h2smps_1->SetStats(kFALSE);   
   
   TH1D* h2smps_2 = new TH1D("h2smps_2", "Gaussian distribution histograms", 100, 0, 500);
   h2smps_2->SetStats(kFALSE);
   
   TRandom3 r;
   for (UInt_t i = 0; i < nEvents1; ++i) { 
      Double_t data = r.Gaus(300, 50);
      sample1[i] = data;
      h2smps_1->Fill(data);
   }
   h2smps_1->Scale(1. / nEvents1, "width");
   c->cd(2);
   h2smps_1->Draw();
   h2smps_1->SetLineColor(kBlue);
   
   for (UInt_t i = 0; i < nEvents2; ++i) { 
      Double_t data = r.Gaus(300, 50);
      sample2[i] = data;
      h2smps_2->Fill(data);
   }
   h2smps_2->Scale(1. / nEvents2, "width");
   h2smps_2->Draw("SAME");
   h2smps_2->SetLineColor(kRed);

   // -----------------------------------------
   // C r e a t e   G o F T e s t  o b j e c t 
   // -----------------------------------------
   
   ROOT::Math::GoFTest* goftest_2 = new ROOT::Math::GoFTest(nEvents1, sample1, nEvents2, sample2);
   
   /* Possible calls for the Anderson - DarlingTest test */
   /*----------------------------------------------------*/
   
   /* a) Returning the Anderson-Darling standardized test statistic */
   A2_1 = goftest_2->AndersonDarling2SamplesTest("t"); 
   A2_2 = (*goftest_2)(ROOT::Math::GoFTest::kAD2s, "t");
   assert(A2_1 == A2_2);
  
   /* b) Returning the p-value for the Anderson-Darling test statistic */
   pvalueAD_1 = goftest_2-> AndersonDarling2SamplesTest(); // p-value is the default choice
   pvalueAD_2 = (*goftest_2)(ROOT::Math::GoFTest::kAD2s);  // p-value is the default choices
   assert(pvalueAD_1 == pvalueAD_2);
   
   /* Possible calls for the Kolmogorov - Smirnov test */
   /*--------------------------------------------------*/              
       
   /* a) Returning the Kolmogorov-Smirnov standardized test statistic */
   Dn_1 = goftest_2-> KolmogorovSmirnov2SamplesTest("t");
   Dn_2 = (*goftest_2)(ROOT::Math::GoFTest::kKS2s, "t");
   assert(Dn_1 == Dn_2);
   
   /* b) Returning the p-value for the Kolmogorov-Smirnov test statistic */
   pvalueKS_1 = goftest_2-> KolmogorovSmirnov2SamplesTest();
   pvalueKS_2 = (*goftest_2)(ROOT::Math::GoFTest::kKS2s);
   assert(pvalueKS_1 == pvalueKS_2);

#ifdef TEST_ERROR_MESSAGE   
   /* Valid but incorrect calls for the 1-sample methods of the 2-samples constucted goftest_2 */
   A2 = (*goftest_2)(ROOT::Math::GoFTest::kAD, "t");     // Issues error message
   pvalueKS = (*goftest_2)(ROOT::Math::GoFTest::kKS);    // Issues error message
   assert(A2 == pvalueKS);
#endif
   
   TPaveText* pt2 = new TPaveText(0.13, 0.6, 0.43, 0.8, "brNDC");
   sprintf(str1, "p-value for A-D 2-smps test: %f", pvalueAD_1);
   pt2->AddText(str1);
   pt2->SetFillColor(18);
   pt2->SetTextFont(20);
   pt2->SetTextColor(4);
   sprintf(str2, "p-value for K-S 2-smps test: %f", pvalueKS_1);
   pt2-> AddText(str2);
   pt2-> Draw();
   
      
   // ------------------------------------------------------------------------
   // C a s e  3 :  C r e a t e   L a n d a u  r a n d o m  s a m p l e
   // ------------------------------------------------------------------------
   
   UInt_t nEvents3 = 1000;

   Double_t* sample3 = new Double_t[nEvents3];
   for (UInt_t i = 0; i < nEvents3; ++i) { 
      Double_t data = r.Landau();
      sample3[i] = data;
   }

   // ------------------------------------------
   // C r e a t e   G o F T e s t  o b j e c t s 
   // ------------------------------------------
   
   /* Possible constructors for the user input distribution */
   /*-------------------------------------------------------*/
   
   /* a) User input PDF */
   ROOT::Math::Functor1D f(&TMath::Landau);
   double min = 3*TMath::MinElement(nEvents3, sample3);
   double max = 3*TMath::MaxElement(nEvents3, sample3);
   ROOT::Math::GoFTest* goftest_3a = new ROOT::Math::GoFTest(nEvents3, sample3, f,  ROOT::Math::GoFTest::kPDF, min,max);  // need to specify am interval
   /* b) User input CDF */
   ROOT::Math::Functor1D fI(&TMath::LandauI);
   ROOT::Math::GoFTest* goftest_3b = new ROOT::Math::GoFTest(nEvents3, sample3, fI, ROOT::Math::GoFTest::kCDF,min,max);

   
   /* Returning the p-value for the Anderson-Darling test statistic */
   pvalueAD_1 = goftest_3a-> AndersonDarlingTest(); // p-value is the default choice
   
   pvalueAD_2 = (*goftest_3b)(); // p-value and Anderson - Darling Test are the default choices
   
   /* Checking consistency between both tests */ 
   std::cout << " \n\nTEST with LANDAU distribution:\t";
   if (TMath::Abs(pvalueAD_1 - pvalueAD_2) > 1.E-1 * pvalueAD_2) { 
      std::cout << "FAILED " << std::endl;
      Error("goftest","Error in comparing testing using Landau and Landau CDF");
      std::cerr << " pvalues are " << pvalueAD_1 << "  " << pvalueAD_2 << std::endl;
   }
   else 
      std::cout << "OK ( pvalues = " << pvalueAD_2 << "  )" << std::endl;
}
Beispiel #20
0
void plotFinal() {

  double yPos, xPos, theta, energy = 0.;  // NOTE: theta comes in degrees
  int numHit, pID = 0;

  TFile* file = new TFile("complete.root");

  TTree* Hits_Info = (TTree *)file->Get("Signal");

  Hits_Info->SetBranchAddress("numHits", &numHit);
  Hits_Info->SetBranchAddress("energyTot", &energy);
  Hits_Info->SetBranchAddress("XPosition", &xPos);
  Hits_Info->SetBranchAddress("YPosition", &yPos);
  Hits_Info->SetBranchAddress("Particle_ID", &pID);
  Hits_Info->SetBranchAddress("Theta", &theta);


  // Initialize histograms
  double nEnergyMin = 10; // MeV
  double nEnergyMax = 510; // MeV
  int nEnergyBins = 50;
  double dEnergyBinSize = (double)(nEnergyMax - nEnergyMin) / (double)nEnergyBins;

  double nThetaMin = 52; // mrad
  double nThetaMax = 70; // mrad
  int nThetaBins = 50;
  double dThetaBinSize = (nThetaMax - nThetaMin) / nThetaBins;

  double nM2Min = -1000; // MeV
  double nM2Max = 1000; // MeV
  int nM2Bins = 100;
  double dM2BinSize = (nM2Max - nM2Min)/nM2Bins;

  TH1D* hgammaEnergy = new TH1D("Energy" ,                    // plot label
                                "Gamma Energy Distribution",  // title
                                nEnergyBins,                  // x number of bins
                                nEnergyMin,                   // x lower bound
                                nEnergyMax);                  // x upper bound

  TH1D* hgammaTheta = new TH1D("#theta" ,                      // plot label
                               "Gamma #theta Distribution",    // title
                               nThetaBins,                    // x number of bins
                               nThetaMin,                     // x lower bound
                               nThetaMax);                    // x upper bound

  TH1D* hm2 = new TH1D("M_{A'}^{2}" ,             // plot label
                       "Missing Mass Squared",    // title
                       nM2Bins,                   // x number of bins
                       nM2Min,                    // x lower bound
                       nM2Max);                   // x upper bound

  TH2F* henergytheta = new TH2F("scatter",            // plot label
                                "#theta vs Energy",   // title
                                nThetaBins,           // x num of bins
                                nThetaMin,            // x min
                                nThetaMax,            // x max
                                nEnergyBins,          // y num of bins
                                nEnergyMin,           // y min
                                nEnergyMax);          // y max





  // go through all entries and fill the histograms
  int nentries = Hits_Info->GetEntries();
  for (int i=0; i<nentries; i++) {
    Hits_Info->GetEntry(i);

    if (pID == 22) { // gammas only
      theta*= TMath::Pi()/180; //radians
      hgammaEnergy->Fill(energy,BINNING_WEIGHT / dEnergyBinSize);
      hgammaTheta->Fill(theta*1000, BINNING_WEIGHT / dThetaBinSize);
      henergytheta->Fill(theta*1000, energy);
      hm2->Fill(mSquared(energy, theta), BINNING_WEIGHT / dM2BinSize);
    }
  }




  // create canvas and draw histogram
  TCanvas* canvas = new TCanvas("canvas", "canvas", 700, 700);
  canvas->Divide(3,2);
  TPad* p;

  p = (TPad*)canvas->cd(2);
  p->SetLogy();
  p->SetGrid();
  hgammaEnergy->SetFillColor(kBlue);
  hgammaEnergy->SetFillStyle(3001);
  hgammaEnergy->Draw();
  hgammaEnergy->GetXaxis()->SetTitle("Energy (MeV)");
  hgammaEnergy->GetYaxis()->SetTitle("Photons per MeV per Second (MeV^{-1} s^{-1})");
  hgammaEnergy->GetXaxis()->CenterTitle();
  hgammaEnergy->GetYaxis()->CenterTitle();

  p = (TPad*)canvas->cd(5);
  p->SetLogy();
  p->SetGrid();
  hgammaTheta->SetFillColor(kBlue);
  hgammaTheta->SetFillStyle(3001);
  hgammaTheta->Draw();
  hgammaTheta->GetXaxis()->SetTitle("#theta (mrad)");
  hgammaTheta->GetXaxis()->CenterTitle();
  hgammaTheta->GetYaxis()->SetTitle("Photons per mrad per Second (mrad^{-1} s^{-1})");
  hgammaTheta->GetYaxis()->CenterTitle();

  p = (TPad*)canvas->cd(1);
  p->SetGrid();
  hm2->SetFillColor(kBlue);
  hm2->SetFillStyle(3001);
  hm2->GetXaxis()->SetTitle("M_{A'}^{2} (MeV^{2})");
  hm2->GetYaxis()->SetTitle("Photons per MeV^{2} per Second (MeV^{-2} s^{-1})");
  hm2->GetXaxis()->CenterTitle();
  hm2->GetYaxis()->CenterTitle();
  hm2->Draw();

  p = (TPad*)canvas->cd(4);
  p->SetLogy();
  p->SetGrid();
  hm2->Draw();

  p = (TPad*)canvas->cd(3);
  henergytheta->Draw();
  henergytheta->GetYaxis()->SetTitle("Energy (MeV)");
  henergytheta->GetXaxis()->SetTitle("#theta (mrad)");
  henergytheta->GetXaxis()->CenterTitle();
  henergytheta->GetYaxis()->CenterTitle();

}
Beispiel #21
0
void plot1d(int hid) {
  gStyle->SetOptStat(0);
  char c[50];
  c1->Clear();  
  if(m1dHist[hid]==0){ 
    c1->Divide(2,2); 
    for(int quad=0; quad<kFgtNumQuads; quad++){
      TVirtualPad* pad1 = c1->cd(quad+1); 
      pad1->SetLogy(l1dHist[hid]);
      double xmin, xmax, ymin=0.0, ymax=0.0;
      if(l1dHist[hid]==1) ymin=0.1;
      for(int disc=0; disc<kFgtNumDiscs; disc++){
	sprintf(c,"%1d%1s-%s",disc+1,cquad[quad],c1dHist[hid]);
	//printf("Getting %s\n",c);
	TH1F *h = hist1[disc][quad][hid] = (TH1F*)file->Get(c);
	xmin=h->GetXaxis()->GetXmin();
	xmax=h->GetXaxis()->GetXmax();
	double m=h->GetMaximum();
	if(ymax<m) ymax=m;
	printf("disc=%d max=%6.1f ymax=%6.1f xmin=%6.1f xmax=%6.1f\n",disc+1,m,ymax,xmin,xmax);
      }
      sprintf(c,"Quad%1s-%s",cquad[quad],c1dHist[hid]);
      TH2F *frame = new TH2F(c,c,1,xmin,xmax,1,ymin,ymax*1.2); frame->SetStats(0); frame->Draw();
      for(int disc=0; disc<kFgtNumDiscs; disc++){
	TH1F *h=hist1[disc][quad][hid];
	h->SetLineColor(color[disc]); h->SetLineWidth(3); h->Draw("SAME");  
	if(f1dHist[hid]==0){
	  float mean=h->GetMean();
	  sprintf(c,"%1d%s mean=%6.2f",disc+1,cquad[quad],mean);
	}else if(f1dHist[hid]==1){	  
	  int res = h->Fit("gaus","0Q");
	  TF1 *f = h->GetFunction("gaus");
	  float sig = f->GetParameter(2);	
	  if(res==0 && sig>0.0001 && h->GetEntries()>5){
	    f->SetLineColor(color[disc]); f->SetLineWidth(2); f->Draw("SAME");
	    sprintf(c,"%1d%s sig=%6.3f",disc+1,cquad[quad],sig);
	  }else{
	    sprintf(c,"%1d%s",disc+1,cquad[quad]);
	  }
	}else if(f1dHist[hid]==2){	  
	  int res = h->Fit("landau","0Q");
	  TF1 *f = h->GetFunction("landau");
	  float peak = f->GetParameter(1);	
	  if(res==0 && peak>0 && h->GetEntries()>5){
	    f->SetLineColor(color[disc]); f->SetLineWidth(2); f->Draw("SAME");
	    sprintf(c,"%1d%s mpv=%6.0f",disc+1,cquad[quad],peak);
	  }else{
	    sprintf(c,"%1d%s",disc+1,cquad[quad]);
	  }
	}
	TText *t1;
	float x1= 0.2, x2= 0.55;
	float y1=0.8 - 0.07*disc;
	float y2=0.8 - 0.07*(disc-3);
        if(disc<3) { t1 = new TText(x1,y1,c); }
        else       { t1 = new TText(x2,y2,c); }
	t1->SetNDC();
	t1->SetTextSize(0.04); 
	t1->SetTextColor(color[disc]); 
	t1->Draw();
      }
    }
  }else{
    c1->Divide(4,6);
    gStyle->SetOptStat(0);
    gStyle->SetOptTitle(0);
    gStyle->SetOptFit(0);
    for(int disc=0; disc<kFgtNumDiscs; disc++){
      for(int quad=0; quad<kFgtNumQuads; quad++){
	TPad* pad = c1->cd(disc*4+quad+1);
	pad->SetRightMargin(0.01); pad->SetLeftMargin(0.1);
	pad->SetTopMargin(0.01);   pad->SetBottomMargin(0.1);
	pad->SetLogy(l1dHist[hid]);
	sprintf(c,"%1d%1s-%s",disc+1,cquad[quad],c1dHist[hid]);
	TH1F *h = hist1[disc][quad][hid] = (TH1F*)file->Get(c);
	h->SetFillColor(color[disc]);
	h->GetXaxis()->SetLabelSize(0.1);
	h->GetYaxis()->SetLabelSize(0.1);
	h->GetXaxis()->SetNdivisions(205);
	h->Draw();

	if(f1dHist[hid]==0){
	  float mean=h->GetMean();
	  sprintf(c,"%1d%s mean=%6.2f",disc+1,cquad[quad],mean);
	}else if(f1dHist[hid]==1){	  
	  int res = h->Fit("gaus","0Q");
	  TF1 *f = h->GetFunction("gaus");
	  float sig = f->GetParameter(2);	
	  if(res==0 && sig>0.0001 && h->GetEntries()>5){
	    f->SetLineColor(color[disc]); f->SetLineWidth(2); f->Draw("SAME");
	    sprintf(c,"%1d%s sig=%6.3f",disc+1,cquad[quad],sig);
	  }else{
	    sprintf(c,"%1d%s",disc+1,cquad[quad]);
	  }
	}else if(f1dHist[hid]==2){	  
	  int res = h->Fit("landau","0Q");
	  TF1 *f = h->GetFunction("landau");
	  float peak = f->GetParameter(1);	
	  if(res==0 && peak>0 && h->GetEntries()>5){
	    f->SetLineColor(1); f->SetLineWidth(2); f->Draw("SAME");
	    sprintf(c,"%1d%s mpv=%6.0f",disc+1,cquad[quad],peak);
	  }else{
	    sprintf(c,"%1d%s",disc+1,cquad[quad]);
	  }
	  if(hid==8) {mPeakC[disc][quad]=peak;}
	  if(hid==9) {
	    mPeakA[disc][quad]=peak;	    
	    int n=h->GetEntries();
	    if(n>0){
	      float cut=2800;
	      int bin=h->FindBin(cut);
	      int nbin=h->GetNbinsX();
	      float sat=h->Integral(bin,nbin+1);
	      //printf("bin=%d nbin=%d sat=%f\n",bin,nbin,sat);
	      mFracA[disc][quad]=sat/float(n);
	    }
	  }
	  if(hid==11) {mPeakL[disc][quad]=peak;} // printf("LandauPeak=%f\n",peak);}
	}
	TText *t1 = new TText(0.3,0.85,c);
	t1->SetNDC();
	t1->SetTextSize(0.15); 
	t1->SetTextColor(color[disc]); 
	t1->Draw();
      }
    }
  }
  c1->Update();
  save(c1dHist[hid]);
}
bool createPlot(TString hname, TString dirname, TFile *V1file, TString relstring1, TFile *V2file, TString relstring2, TCanvas *canvas, int scale) {
  setTDRStyle();

  // don't look at non-zero bin
  Int_t range_upper = histV1->GetXaxis()->GetLast();
  histV1->GetXaxis()->SetRangeUser(1,range_upper);
  histV2->GetXaxis()->SetRangeUser(1,range_upper);

  int SetScale = scale;

  //IF =0 --> No scale applied ('direct' comparison)
  //IF =1 --> Scale INDIVIDUALLY (scale histograms individually) 
  //IF =2 --> Scale all GLOBALLY (scale all histograms to #tracks=1)
  //IF =3 --> Scale all GLOBALLY nEVENTS (scale all histos to nEntries in nTracks per Event)

  bool DrawRatio = true;
  canvas->cd();
  TPad* mainpad = new TPad("mainpad","mainpad",0.0,0.0,1.0,0.8);
  mainpad->Draw();
  mainpad->cd();

  // ************ Get name of histos and get histos ************* //
  
  TString basename1 = "DQMData/Run ";
  basename1.Append("1");

  TString hnameV1 = basename1;
  hnameV1.Append(dirname+"/");
  hnameV1.Append(hname);

  if (hname != "vtxNbr"){
    hnameV1.Append("_GenTk");
  }

  TH1F * histV1 = (TH1F*)V1file->Get(hnameV1);
  if ( histV1 == (TH1F*) NULL ) {
    cout << "histV1 failed on " << hnameV1  << endl << " for file " << V1file->GetName() << endl;
    exit(1);
  }

  TString basename2 = "DQMData/Run ";
  basename2.Append("1");

  TString hnameV2 = basename2;
  hnameV2.Append(dirname+"/");
  hnameV2.Append(hname);
  
  if (hname != "vtxNbr"){
    hnameV2.Append("_GenTk");
  }

  TH1F * histV2 = (TH1F*)V2file->Get(hnameV2);
  if ( histV2 == (TH1F*) NULL ) {
    cout << "histV2 failed on " << hnameV2  << endl << " for file " << V2file->GetName() << endl;
    exit(1);
  }

  //******************* Get histo integrals ***********************//
  double V1_integral = 1.0;
  double V2_integral = 1.0;

  TH1F * hTempV1 = 0;
  TH1F * hTempV2 = 0;

  if (SetScale==1){    
    V1_integral = histV1->Integral();
    V2_integral = histV2->Integral();
  }
  else if ( (SetScale==2) || (SetScale==3) ){
    if (hname != "NumberOfTracks"){
      TString hTempNameV1 = basename1;
      hTempNameV1.Append("/Tracking/Run summary/TrackParameters/generalTracks/GeneralProperties/NumberOfTracks_GenTk");
      hTempV1 = (TH1F*)V1file->Get(hTempNameV1);
      
      TString hTempNameV2 = basename2;
      hTempNameV2.Append("/Tracking/Run summary/TrackParameters/generalTracks/GeneralProperties/NumberOfTracks_GenTk");
      hTempV2 = (TH1F*)V2file->Get(hTempNameV2);
    }
    else{
      hTempV1 = (TH1F*)histV1->Clone("hTempV1");
      hTempV2 = (TH1F*)histV2->Clone("hTempV2");
    }

    if (SetScale==2){
      V1_integral = hTempV1->GetBinContent(2);
      V2_integral = hTempV2->GetBinContent(2);

      std::cout << "The number of single tracks for V1 is " << V1_integral << std::endl;
      std::cout << "The number of single tracks for V2 is " << V2_integral << std::endl;
    }
    else if (SetScale==3){
      V1_integral = hTempV1->GetEntries();
      V2_integral = hTempV2->GetEntries();

      std::cout << "The number of events for V1 is " << V1_integral << std::endl;
      std::cout << "The number of events for V2 is " << V2_integral << std::endl;
    }
  }

  //*****NORMALIZING V1-V2****************************************

  if(V1_integral>V2_integral) {
    histV1->Scale(V2_integral / V1_integral);
    histV2->Scale(1);
  } 
  else if(V2_integral>V1_integral){
    histV1->Scale(1);
    histV2->Scale(V1_integral / V2_integral);
  }

  //*****NORMALIZING V1-V2*end***************************************

  //***Name the files under comparison***
  TString V1_V1run = "Run 1 ("+relstring1+")";
  TString V2_V2run = "Run 1 ("+relstring2+")";

  histV1->SetName(V1_V1run);
  histV2->SetName(V2_V2run);

  TString x_title = "";
  if( hname.Contains("vtxNbr"))                               x_title="Number of Primary Vertices per Event";

  histV1->SetLineWidth(5);
  histV1->SetLineStyle(1);
  histV1->SetLineColor(kRed);
  histV1->GetYaxis()->SetLabelSize(0.038);

  histV2->SetLineWidth(3);
  histV2->SetLineStyle(1);
  histV2->SetLineColor(kBlue);

  if ( hname.Contains("NumberOfTracks",TString::kExact)
      || hname.Contains("NumberOfGoodTracks",TString::kExact)
      || hname.Contains("TrackPt",TString::kExact)
      || hname.Contains("Chi2Prob",TString::kExact)
       ){
    mainpad->SetLogy(1);
  }
  else {
    mainpad->SetLogy(0);
  }

  if (hname.Contains("NumberOfGoodTracks",TString::kExact)) {
    histV1->GetXaxis()->SetRangeUser(0,200);
    histV2->GetXaxis()->SetRangeUser(0,200);
  }

  if (hname.Contains("Chi2oNDF",TString::kExact)) {
    histV1->GetXaxis()->SetRangeUser(0,10);
    histV2->GetXaxis()->SetRangeUser(0,10);
  }

  if (hname.Contains("vtxNbr")){
    histV1->GetXaxis()->SetTitle(x_title);
    histV1->GetYaxis()->SetTitle("Number of Events");
  }

  if ( hname.Contains("NumberOfTracks",TString::kExact)){
    histV1->GetXaxis()->SetRangeUser(125,range_upper);
    histV2->GetXaxis()->SetRangeUser(125,range_upper);
  }

  double max = 0;
  double V1max = histV1->GetBinContent(histV1->GetMaximumBin());
  double V2max = histV2->GetBinContent(histV2->GetMaximumBin());

  max = (V1max>V2max) ? V1max : V2max;
  histV1->SetMaximum(max*(1.1));

  histV1->Draw();
  histV2->Draw("sames");

  mainpad->Update();

  TPaveStats *st1 = (TPaveStats*)(histV1->GetListOfFunctions()->FindObject("stats"));

  st1->SetX1NDC(0.77);
  st1->SetY1NDC(0.80);

  st1->SetX2NDC(0.98);
  st1->SetY2NDC(0.97);
  Double_t defaulth = st1->GetY2NDC() - st1->GetY1NDC();
  Double_t gaph = 0.02;
  TPaveStats *st2 = (TPaveStats*)(histV2->GetListOfFunctions()->FindObject("stats"));
  st2->SetX1NDC(0.77);  
  st2->SetY1NDC(st1->GetY1NDC() - 1.0*defaulth - gaph);
  st2->SetX2NDC(0.98);    
  st2->SetY2NDC(st1->GetY1NDC() - gaph);

  TLegend *leg = new TLegend(0.32,0.86,0.76,0.97);
  leg->SetTextSize(0.042);
  leg->SetTextFont(42);
  leg->SetFillColor(10); 
  leg->SetBorderSize(1); // no frame, no shadow
  leg->AddEntry(histV1, V1_V1run, "L" );
  leg->AddEntry(histV2, V2_V2run, "L" );
  leg->Draw("SAME");

  // Draw ratio histogram
  if (DrawRatio){
    canvas->cd();
    TPad* respad = new TPad("respad","respad",0.0,0.78,1.0,0.95);
    respad->SetTopMargin(1.05);
    respad->Draw();
    respad->cd();
    TH1F* hratio = (TH1F*) histV2->Clone("hratio");
    hratio->Divide(histV1);
    hratio->SetMaximum(hratio->GetMaximum()*1.01);
    //if (hratio->GetMinimum()==0.0) hratio->SetMinimum(1.0/hratio->GetMaximum());
    hratio->SetMinimum(1.0/hratio->GetMaximum());
    hratio->GetYaxis()->SetLabelSize(0.1);
    hratio->GetYaxis()->SetRangeUser(0,2);
    hratio->GetXaxis()->SetLabelSize(0);
    hratio->GetXaxis()->SetTitleSize(0);
    hratio->GetYaxis()->SetTitleSize(0.22);
    hratio->GetYaxis()->SetTitleOffset(0.26);
    hratio->GetYaxis()->SetLabelSize(0.2);
    hratio->GetYaxis()->SetNdivisions(5);
    hratio->GetYaxis()->SetTitle("PM/SM");
 
    hratio->Draw();
  }

  // Compare parameters of histograms
  double Entries1 = histV1->GetEntries();
  double Entries2 = histV2->GetEntries();
  if (Entries1 != Entries2) {
    std::cout<<" Difference in # of ENTRIES for " <<hname<< std::endl;
    std::cout<<"\t Entries1 = " << Entries1 << "\t Entries2 = " << Entries2 << std::endl;
  }

  double Mean1 = histV1->GetMean();
  double Mean2 = histV2->GetMean();
  if (Mean1 != Mean2) {
    std::cout<<" Difference in MEANS for " <<hname<< std::endl;
    std::cout<<"\t Mean1 = " << Mean1 << "\t Mean2 = " << Mean2 << std::endl;
  }

  double RMS1 = histV1->GetRMS();
  double RMS2 = histV2->GetRMS();
  if (RMS1 != RMS2) {
    std::cout<<" Difference in RMS for " <<hname<< std::endl;
    std::cout<<"\t RMS1 = " << RMS1 << "\t RMS2 = " << RMS2 << std::endl;
  }

  TString filename = hname;

  if (hname.Contains("vtxNbr")){
    filename = "NumberOfPrimaryVertices";
  }

  if (dirname.Contains("highPurityTracks/pt_1/GeneralProperties",TString::kExact))
    filename.Prepend("RunComparison/GoodTracks_");
  else filename.Prepend("RunComparison/");

  filename.Append(".png");

  canvas->Print(filename);

  if ( histV1 ) {histV1->Delete();}
  if ( histV2 ) {histV2->Delete();}

  if ( hTempV1 ) {hTempV1->Delete();}
  if ( hTempV2 ) {hTempV2->Delete();}

  return true;
}
Beispiel #23
0
void compareInDir(TFile* f1, TFile* f2, std::string dirName,unsigned int logmod=0, unsigned int dOpt=1){
  TCanvas* cv = 0;
  TPad* pH = 0;
  TPad* pD = 0;

  TPaveText* pt = 0;

  //  std::cout<<"Start with "<<dirName.c_str()<<std::endl;
  //  cv->Print("diff.ps[");
  
  TDirectory* d1 = f1->GetDirectory(dirName.c_str());
  TDirectory* d2 = f2->GetDirectory(dirName.c_str());

  if (d1==0 || d2 == 0){
    std::cout<<"ERROR: "<<dirName.c_str()<<" not found"<<std::endl;
    return;
  }
  //  std::cout<<"\t\t "<<d1->GetName()<<std::endl;

  TList* list1 = d1->GetListOfKeys();
  
  TIterator* keyIt1 = list1->MakeIterator();

  TObject* obj;  
  while ((obj = keyIt1->Next())){
    TObject* obj1 = d1->Get(obj->GetName());    
    if(obj1 == 0){
      //      std::cout<<"ERROR: failed to read in "<<d1->GetName()<<" / "<<obj->GetName()<<std::endl;
      continue;
    }
    //    std::cout<<d1->GetName()<<"/"<<obj->GetName()<<std::endl;
    if (! obj1->InheritsFrom(TH1::Class())) continue;
    
    TObject* obj2 = d2->Get(obj1->GetName());
    if (obj2 == 0){
      //      std::cout<<"WARNING: failed to get"<<d1->GetName()<<"/"<<obj1->GetName()<<std::endl;
      continue;
    }

    TH1* h1 = (TH1*)obj1;
    TH1* h2 = (TH1*)obj2;
    //    std::cout<<"Will check "<<dirName.c_str()<<"/"<<h1->GetName()<<" dOpt "<<dOpt<<std::endl;
    if(h1->Integral() == 0 && h2->Integral() == 0){
      //      std::cout<<"Integral is 0: "<<d1->GetName()<<"/"<<obj1->GetName()<<std::endl;
      continue;
    }
    //    if (TString(h1->GetTitle()).Index("ffic")<0) continue;
    bool isProf = obj1->InheritsFrom(TProfile::Class());
    bool isH2   = obj1->InheritsFrom(TH2::Class());
    double bDiff = 0;
    if(!isH2){
      unsigned int nX1 = h1->GetNbinsX();
      //      std::cout<<"\t is 1D with nBins "<<nX1<<std::endl;
      for(unsigned int iB=0; iB<=nX1+1; ++iB){
	if(h1->GetBinError(iB)==0 && h1->GetBinContent(iB)!=0) h1->SetBinError(iB,1e-3*fabs(h1->GetBinContent(iB)));
	if(h2->GetBinError(iB)==0 && h2->GetBinContent(iB)!=0) h2->SetBinError(iB,1e-3*fabs(h2->GetBinContent(iB)));
	bDiff +=fabs(h1->GetBinContent(iB) - h2->GetBinContent(iB));
      }
    } else {
      unsigned int nX1 = h1->GetNbinsX();
      unsigned int nY1 = h1->GetNbinsY();
      //      std::cout<<"\t is 2D with nBins "<<nX1<<" : "<<nY1<<std::endl;
      for(unsigned int iB=0; iB<=nX1+1; ++iB){
	for(unsigned int jB=0; jB<=nY1+1; ++jB){
	  if(h1->GetBinError(iB,jB)==0 && h1->GetBinContent(iB,jB)!=0) h1->SetBinError(iB,jB,1e-3*fabs(h1->GetBinContent(iB,jB)));
	  if(h2->GetBinError(iB,jB)==0 && h2->GetBinContent(iB,jB)!=0) h2->SetBinError(iB,jB,1e-3*fabs(h2->GetBinContent(iB,jB)));
	  bDiff +=fabs(h1->GetBinContent(iB,jB) - h2->GetBinContent(iB,jB));
	}
      }
    }

    double ksProb = 0;
    if (bDiff == 0) ksProb = 1;
    else ksProb = h1->KolmogorovTest(h2);
    if (dOpt%10 == 0 && bDiff ==0 ) continue;
    if (dOpt%10 == 1 && (bDiff ==0 || 1.-ksProb <1e-12) ) continue;
    if (dOpt%10 == 2 && (bDiff ==0 || ksProb >0.1 )) continue;
    if (dOpt%10 == 3 && (bDiff ==0 || 1.-ksProb < 0.001 )) continue;
    if (dOpt%10 == 4 && (bDiff ==0 || ksProb >0.9 )) continue;
    if (dOpt%10 == 5 && (bDiff ==0 || ksProb >0.5 )) continue;

    if (cv == 0){
      cv = new TCanvas(dirName.c_str(),dirName.c_str());
      cv->cd();
      pH = new TPad("head","head", 0, 0.93, 1, 1);
      pH->Draw();
      pH->cd();
      pt = new TPaveText(0,0,1,1); pt->SetFillColor(0);
      pt->AddText(dirName.c_str());
      pt->Draw();
      cv->cd();
      pD = new TPad("dis","dis", 0, 0.0, 1, 0.93);
      pD->Draw();
      pD->cd();
    }
    
    pD->Clear();
    pD->cd();
    std::cout<<"Save : "<<dirName.c_str()<<"/"<<h1->GetName()<<std::endl;

    if (! isH2){
      h1->SetLineWidth(2);
      h1->SetLineColor(1);
      h1->SetMarkerColor(1);
      h2->SetLineColor(2);
      h2->SetMarkerColor(2);
      //      if (h1->GetNbinsX() > 25) h1 = h1->Rebin();
 //     if (h2->GetNbinsX() > 25) h2 = h2->Rebin();
      //      if (h1->GetNbinsX() > 50) h1 = h1->Rebin(5);
      //      if (h2->GetNbinsX() > 50) h2 = h2->Rebin(5);
      double max1 = h1->GetMaximum();
      double max2 = h2->GetMaximum();
      double min1 = h1->GetMinimum();
      double min2 = h2->GetMinimum();
      if (max2> max1) h1->SetMaximum(max2+0.15*fabs(max2));
      if (min2 < min1) h1->SetMinimum(min2-0.15*fabs(min2));
      //      pD->SetLogy();
      if ((logmod&1)) pD->SetLogx();
      if ((logmod&2)) pD->SetLogy();
      h1->Draw();
      h2->Draw("sames");   

      if (std::string(h1->GetName())==std::string("reconstruction_step_module_total")
	  || std::string(h1->GetName())==std::string("validation_step_module_total")){
	TPaveText ksPt(0,0, 0.35, 0.04, "NDC"); ksPt.SetBorderSize(0); ksPt.SetFillColor(0);
	ksPt.AddText(Form("P(KS)=%g, diffBins=%g, eblk %g ered %g",ksProb, bDiff, h1->GetEntries(), h2->GetEntries()));
	//	ksPt.AddText(h1->GetName());
	ksPt.Draw();
	cv->Print("diff.ps");

	int nX = h1->GetNbinsX();
	TAxis* h1Ax = h1->GetXaxis();
	int nRanges = nX/20 + 1;
	double h1Int = h1->Integral();
	float curBMargin = pD->GetBottomMargin(); 
	pD->SetBottomMargin(0.3);
	for (int iR = 0; iR < nRanges; iR++){
	  h1Ax->SetRange(iR*20+1, iR*20+20);
	  double bDiffL = 0;
	  double max1L = -1;
	  double max2L = -1;
	  double min1L = h1->GetMaximum();
	  double min2L = h2->GetMaximum();
	  for (int iBL = iR*20+1; iBL<= iR*20+20; ++iBL){
	    double h1L = h1->GetBinContent(iBL);
	    double h2L = h2->GetBinContent(iBL);
	    bDiffL += std::abs(h1L-h2L);
	    if (max1L < h1L) max1L = h1L;
	    if (max2L < h2L) max2L = h2L;
	    if (min1L > h1L) min1L = h1L;
	    if (min2L > h2L) min2L = h2L;
	  }
	  if (max2L> max1L)  h1->SetMaximum(max2L+0.15*std::abs(max2L));
	  else h1->SetMaximum(max1L+0.15*std::abs(max1L));
	  if (min2L < min1L) h1->SetMinimum(min2L-0.15*std::abs(min2L));
	  else h1->SetMinimum(min1L-0.15*std::abs(min1L));
	  h1->Draw();
	  h2->Draw("sames");
	  TPaveText ksPtL(0,0, 0.35, 0.04, "NDC"); ksPtL.SetBorderSize(0); ksPtL.SetFillColor(0);
	  ksPtL.AddText(Form("P(KS)=%g, diffBinsL=%g(%g), eblk %g ered %g",ksProb, bDiffL, bDiffL/h1Int, h1->GetEntries(), h2->GetEntries()));
	  ksPtL.Draw();
	  cv->Print("diff.ps");
	}
	pD->SetBottomMargin(curBMargin);

      }
    }
    if (isH2){
      pD->Divide(2);
      pD->cd(1);
      h1->Draw("colz");
      pD->cd(2);
      h2->Draw("colz");
    }
    TPaveText ksPt(0,0, 0.55, 0.06, "NDC"); ksPt.SetBorderSize(0); ksPt.SetFillColor(0);
    ksPt.AddText(Form("P(KS)=%g, diffBins=%g, eblk %g ered %g",ksProb, bDiff, h1->GetEntries(), h2->GetEntries()));
    ksPt.AddText(h1->GetName());
    ksPt.Draw();
    cv->Print("diff.ps");
    cv->Print("diff.pdf");


  }

  //  std::cout<<"Done in "<<dirName.c_str()<<std::endl;
  //  delete pH; delete pD;
  if (cv) delete cv;
  //  cv->Print("diff.ps]");
}
bool createPlot(TString hname, TString dirname, TFile *V1file, TString runstring1, TString relstring1, TFile *V2file, TString runstring2, TString relstring2, TCanvas *canvas, int scale) {
  setTDRStyle();

  int SetScale = scale;

  //IF =0 --> No scale applied ('direct' comparison)
  //IF =1 --> Scale INDIVIDUALLY (scale histograms individually) 
  //IF =2 --> Scale all GLOBALLY (scale all histograms to #tracks=1)
  //IF =3 --> Scale all GLOBALLY nEVENTS (scale all histos to nEntries in nTracks per Event)

  bool DrawRatio = true;
  canvas->cd();
  TPad* mainpad = new TPad("mainpad","mainpad",0.0,0.0,1.0,0.8);
  mainpad->Draw();
  mainpad->cd();

  // ************ Get name of histos and get histos ************* //

  if (dirname.Contains("GeneralProperties/GoodTracks",TString::kExact)){
    if ((hname != "FractionOfGoodTracks") && (hname != "NumberOfGoodTracks")){
      hname.Prepend("GoodTrack");
    }
  }
  
  TString basename1 = "DQMData/Run ";
  basename1.Append(runstring1);

  TString hnameV1 = basename1;
  hnameV1.Append(dirname+"/");
  hnameV1.Append(hname);

  if (hname != "vtxNbr"){
    hnameV1.Append("_GenTk");
  }

  TH1F * hBinTempV1 = (TH1F*)V1file->Get(hnameV1);
  if ( hBinTempV1 == (TH1F*) NULL ) {
    cout << "histV1 failed on " << hnameV1  << endl << " for file " << V1file->GetName() << endl;
    exit(1);
  }

  TString basename2 = "DQMData/Run ";
  basename2.Append(runstring2);

  TString hnameV2 = basename2;
  hnameV2.Append(dirname+"/");
  hnameV2.Append(hname);
  
  if (hname != "vtxNbr"){
    hnameV2.Append("_GenTk");
  }

  TH1F * hBinTempV2 = (TH1F*)V2file->Get(hnameV2);
  if ( hBinTempV2 == (TH1F*) NULL ) {
    cout << "histV2 failed on " << hnameV2  << endl << " for file " << V2file->GetName() << endl;
    exit(1);
  }

  // Check that bins match for ratio plot

  TH1F * histV1 = 0;
  TH1F * histV2 = 0;

  Double_t h1_xlow = hBinTempV1->GetXaxis()->GetBinLowEdge(hBinTempV1->GetXaxis()->GetFirst());
  Double_t h2_xlow = hBinTempV2->GetXaxis()->GetBinLowEdge(hBinTempV2->GetXaxis()->GetFirst());

  Double_t h1_xup = hBinTempV1->GetXaxis()->GetBinUpEdge(hBinTempV1->GetXaxis()->GetLast());
  Double_t h2_xup = hBinTempV2->GetXaxis()->GetBinUpEdge(hBinTempV2->GetXaxis()->GetLast());

  Int_t h1_nbins = hBinTempV1->GetNbinsX();
  Int_t h2_nbins = hBinTempV2->GetNbinsX();

  Double_t h1_binWidth = (h1_xup - h1_xlow) / (Double_t)h1_nbins;
  Double_t h2_binWidth = (h2_xup - h2_xlow) / (Double_t)h2_nbins;

  if ((h1_xlow == h2_xlow) && (h1_xup == h2_xup) && (h1_binWidth == h2_binWidth)){
    histV1 = (TH1F*)V1file->Get(hnameV1);
    histV2 = (TH1F*)V2file->Get(hnameV2);
  }
  else if((h1_xlow == h2_xlow) && (h1_xup < h2_xup) && (h1_binWidth == h2_binWidth)){ // Fill h1 from h1xlow to h1high with h1 info, and up to h2high, fill zero 
    histV2 = (TH1F*)V2file->Get(hnameV2); // copy histV2 

    histV1 = new TH1F(hBinTempV1->GetName(),hBinTempV1->GetTitle(),h2_nbins,h2_xlow,h2_xup);
    histV1->SetXTitle(hBinTempV1->GetXaxis()->GetTitle());
    histV1->SetYTitle(hBinTempV1->GetYaxis()->GetTitle());
    for (Int_t ibin = 1; ibin <= h2_nbins; ibin++){
      if (ibin <= h1_nbins){
	histV1->SetBinContent(ibin,hBinTempV1->GetBinContent(ibin));
      }
      else if (ibin > h1_nbins){
	histV1->SetBinContent(ibin,0.0); 
      }
    }
  }
  else if((h1_xlow == h2_xlow) && (h1_xup > h2_xup) && (h1_binWidth == h2_binWidth)){ // Fill h1 from h1xlow to h1high with h1 info, and up to h2high, fill zero 
    histV1 = (TH1F*)V1file->Get(hnameV1); // copy histV1 

    histV2 = new TH1F(hBinTempV2->GetName(),hBinTempV2->GetTitle(),h1_nbins,h1_xlow,h1_xup);
    histV2->SetXTitle(hBinTempV2->GetXaxis()->GetTitle());
    histV2->SetYTitle(hBinTempV2->GetYaxis()->GetTitle());
    for (Int_t ibin = 1; ibin <= h1_nbins; ibin++){
      if (ibin <= h2_nbins){
	histV2->SetBinContent(ibin,hBinTempV2->GetBinContent(ibin));
      }
      else if (ibin > h2_nbins){
	histV2->SetBinContent(ibin,0.0); 
      }
    }
  }
  else{
    cout << "Bin Check Failed... here's what happened: " << endl;
    cout << "histV1 failed on " << hnameV1  << endl << " for file " << V1file->GetName() << endl;
    cout << "       bin info: " << h1_xlow << " " << h1_xup << " " << h1_nbins << endl;
    cout << "histV2 failed on " << hnameV2  << endl << " for file " << V2file->GetName() << endl;
    cout << "       bin info: " << h2_xlow << " " << h2_xup << " " << h2_nbins << endl;
    exit(1);
  }

  // Don't look at zero bin -- > Also could use this for truncation and bin setting -->Range is binlower to upper
  //  Int_t range_upper = histV1->GetXaxis()->GetLast();
  //  histV1->GetXaxis()->SetRangeUser(1,range_upper);
  //  histV2->GetXaxis()->SetRangeUser(1,range_upper);

  //******************* Get histo integrals ***********************//
  double V1_integral = 1.0;
  double V2_integral = 1.0;

  TH1F * hNormTempV1 = 0;
  TH1F * hNormTempV2 = 0;

  if (SetScale==1){    
    V1_integral = histV1->Integral();
    V2_integral = histV2->Integral();
  }
  else if ( (SetScale==2) || (SetScale==3) ){
    if (hname != "NumberOfTracks"){
      TString hTempNameV1 = basename1;
      hTempNameV1.Append("/Tracking/Run summary/TrackParameters/GeneralProperties/NumberOfTracks_GenTk");
      hNormTempV1 = (TH1F*)V1file->Get(hTempNameV1);
      
      TString hTempNameV2 = basename2;
      hTempNameV2.Append("/Tracking/Run summary/TrackParameters/GeneralProperties/NumberOfTracks_GenTk");
      hNormTempV2 = (TH1F*)V2file->Get(hTempNameV2);
    }
    else{
      hNormTempV1 = (TH1F*)histV1->Clone("hNormTempV1");
      hNormTempV2 = (TH1F*)histV2->Clone("hNormTempV2");
    }

    if (SetScale==2){
      V1_integral = hNormTempV1->GetBinContent(2);
      V2_integral = hNormTempV2->GetBinContent(2);

      std::cout << "The number of single tracks for V1 is " << V1_integral << std::endl;
      std::cout << "The number of single tracks for V2 is " << V2_integral << std::endl;
    }
    else if (SetScale==3){
      V1_integral = hNormTempV1->GetEntries();
      V2_integral = hNormTempV2->GetEntries();

      std::cout << "The number of events for V1 is " << V1_integral << std::endl;
      std::cout << "The number of events for V2 is " << V2_integral << std::endl;
    }
  }

  //*****NORMALIZING V1-V2****************************************

  if(V1_integral>V2_integral) {
    histV1->Scale(V2_integral / V1_integral);
    histV2->Scale(1);
  } 
  else if(V2_integral>V1_integral){
    histV1->Scale(1);
    histV2->Scale(V1_integral / V2_integral);
  }

  //*****NORMALIZING V1-V2*end***************************************

  //***Name the files under comparison***
  TString V1_V1run = "Run "+runstring1+" ("+relstring1+")";
  TString V2_V2run = "Run "+runstring2+" ("+relstring2+")";

  histV1->SetName(V1_V1run);
  histV2->SetName(V2_V2run);

  double max = 0;
  double V1max = histV1->GetBinContent(histV1->GetMaximumBin());
  double V2max = histV2->GetBinContent(histV2->GetMaximumBin());

  max = (V1max>V2max) ? V1max : V2max;
  histV1->Draw();
  histV1->SetLineStyle(1);
  histV1->GetYaxis()->SetLabelSize(0.038);
  histV1->SetLineWidth(5);
  histV1->SetLineColor(kRed);
  histV1->SetMaximum(max*(1.1));
  histV2->Draw();
  histV2->SetLineWidth(3);
  histV2->SetLineStyle(1);
  histV2->SetLineColor(kBlue);



  if( hname.Contains("NumberOfTracks",TString::kExact)
      || hname.Contains("NumberOfGoodTracks",TString::kExact)
      || hname.Contains("TrackPt",TString::kExact)
      || hname.Contains("Chi2Prob",TString::kExact)
      ){
    mainpad->SetLogy(1);
  }
  else{
    mainpad->SetLogy(0);
  }

  if (hname.Contains("NumberOfTracks",TString::kExact)){
    histV1->GetXaxis()->SetRangeUser(0,500);
    histV2->GetXaxis()->SetRangeUser(0,500);
  }
  
  if (hname.Contains("NumberOfGoodTracks",TString::kExact)) {
    histV1->GetXaxis()->SetRangeUser(0,200);
    histV2->GetXaxis()->SetRangeUser(0,200);
  }

  if (hname.Contains("Chi2oNDF",TString::kExact)) {
    histV1->GetXaxis()->SetRangeUser(0,10);
    histV2->GetXaxis()->SetRangeUser(0,10);
  }

  if (hname.Contains("vtxNbr")){
    histV1->GetXaxis()->SetTitle("Number of Primary Vertices per Event");
    histV1->GetYaxis()->SetTitle("Number of Events");
  }

  histV1->Draw(); // Draw old histo first, ratio is new/old
  histV2->Draw("sames");

  mainpad->Update();

  TPaveStats *st1 = (TPaveStats*)(histV1->GetListOfFunctions()->FindObject("stats"));

  st1->SetX1NDC(0.77);
  st1->SetY1NDC(0.80);

  st1->SetX2NDC(0.98);
  st1->SetY2NDC(0.97);
  Double_t defaulth = st1->GetY2NDC() - st1->GetY1NDC();
  Double_t gaph = 0.02;
  TPaveStats *st2 = (TPaveStats*)(histV2->GetListOfFunctions()->FindObject("stats"));
  st2->SetX1NDC(0.77);  
  st2->SetY1NDC(st1->GetY1NDC() - 1.0*defaulth - gaph);
  st2->SetX2NDC(0.98);    
  st2->SetY2NDC(st1->GetY1NDC() - gaph);

  TLegend *leg = new TLegend(0.32,0.86,0.76,0.97);
  leg->SetTextSize(0.042);
  leg->SetTextFont(42);
  leg->SetFillColor(10); 
  leg->SetBorderSize(1); // no frame, no shadow
  leg->AddEntry(histV1, V1_V1run, "L" );
  leg->AddEntry(histV2, V2_V2run, "L" );
  leg->Draw("SAME");

  // Draw ratio histogram
  if (DrawRatio){
    canvas->cd();
    TPad* respad = new TPad("respad","respad",0.0,0.78,1.0,0.95);
    respad->SetTopMargin(1.05);
    respad->Draw();
    respad->cd();
    TH1F* hratio = (TH1F*) histV2->Clone("hratio");
    hratio->Divide(histV1);
    hratio->SetMaximum(hratio->GetMaximum()*1.1);
    hratio->SetMinimum(hratio->GetMinimum()/1.1);
    //if (hratio->GetMinimum()==0.0) hratio->SetMinimum(1.0/hratio->GetMaximum());
    //    hratio->SetMinimum(1.0/hratio->GetMaximum());
    hratio->GetYaxis()->SetLabelSize(0.1);
    //    hratio->GetYaxis()->SetRangeUser(0,2);
    hratio->GetXaxis()->SetLabelSize(0);
    hratio->GetXaxis()->SetTitleSize(0);
    hratio->GetYaxis()->SetTitleSize(0.22);
    hratio->GetYaxis()->SetTitleOffset(0.26);
    hratio->GetYaxis()->SetLabelSize(0.2);
    hratio->GetYaxis()->SetNdivisions(5);
    hratio->GetYaxis()->SetTitle("NEW/REF");
    hratio->Draw();
  }

  // Compare parameters of histograms
  double Entries1 = histV1->GetEntries();
  double Entries2 = histV2->GetEntries();
  if (Entries1 != Entries2) {
    std::cout<<" Difference in # of ENTRIES for " <<hname<< std::endl;
    std::cout<<"\t Entries1 = " << Entries1 << "\t Entries2 = " << Entries2 << std::endl;
  }

  double Mean1 = histV1->GetMean();
  double Mean2 = histV2->GetMean();
  if (Mean1 != Mean2) {
    std::cout<<" Difference in MEANS for " <<hname<< std::endl;
    std::cout<<"\t Mean1 = " << Mean1 << "\t Mean2 = " << Mean2 << std::endl;
  }

  double RMS1 = histV1->GetRMS();
  double RMS2 = histV2->GetRMS();
  if (RMS1 != RMS2) {
    std::cout<<" Difference in RMS for " <<hname<< std::endl;
    std::cout<<"\t RMS1 = " << RMS1 << "\t RMS2 = " << RMS2 << std::endl;
  }

  TString filename = hname;

  if (hname.Contains("vtxNbr")){
    filename = "NumberOfPrimaryVertices";
  }

  if (dirname.Contains("GeneralProperties/GoodTracks",TString::kExact))
    filename.Prepend("RunComparison/GoodTracks_");
  else filename.Prepend("RunComparison/");

  filename.Append(".png");

  canvas->Print(filename);

  if ( histV1 ) {histV1->Delete();}
  if ( histV2 ) {histV2->Delete();}

  if ( hNormTempV1 ) {hNormTempV1->Delete();}
  if ( hNormTempV2 ) {hNormTempV2->Delete();}

  //  if ( hBinTempV1 ) {hBinTempV1->Delete();} // why cant this work?! 
  //  if ( hBinTempV2 ) {hBinTempV2->Delete();}

  return true;
}
Beispiel #25
0
void plotDistribution( TChain* data , TChain *mc , TCut sel , TCut vtxweight , char* var , int nbins , float xmin , float xmax , char* xtitle , char* plottitle = "" , bool printplot = false , bool residual = false , bool log = false ){

  //--------------------------------------
  // define histograms and TGraphs
  //--------------------------------------

  TH1F* hdata      = new TH1F(Form("hdata_%i"     , iplot),Form("hdata_%i"    , iplot),nbins,xmin,xmax);
  TH1F* hmc        = new TH1F(Form("hmc_%i"       , iplot),Form("hmc_%i"      , iplot),nbins,xmin,xmax);
  TH1F* hmc_novtx  = new TH1F(Form("hmc_novtx_%i" , iplot),Form("hmc_novtx%i" , iplot),nbins,xmin,xmax);

  hdata->Sumw2();
  hmc->Sumw2();

  TGraphAsymmErrors* grdata = new TGraphAsymmErrors();
  TGraphAsymmErrors* grmc   = new TGraphAsymmErrors();

  TH1F* hdata_denom = new TH1F(Form("hdata_denom_%i",iplot),"",nbins,xmin,xmax);
  TH1F* hmc_denom   = new TH1F(Form("hmc_denom_%i"  ,iplot),"",nbins,xmin,xmax);

  //--------------------------------------
  // set up canvas and pads
  //--------------------------------------

  TCanvas *can = new TCanvas(Form("can_%i",iplot),Form("can_%i",iplot),600,600);
  can->cd();
  if( log ) gPad->SetLogy();

  TPad *mainpad = new TPad("mainpad","mainpad",0.0,0.0,1.0,0.8);

  if( residual ){
    mainpad->Draw();
    mainpad->cd();
    if( log ) mainpad->SetLogy();
  }

  //--------------------------------------
  // fill histos and TGraphs
  //--------------------------------------

  data->Draw(Form("min(%s,%f)>>hdata_%i"     , var,xmax-0.0001,iplot),sel);
  mc  ->Draw(Form("min(%s,%f)>>hmc_%i"       , var,xmax-0.0001,iplot),sel*vtxweight);
  mc  ->Draw(Form("min(%s,%f)>>hmc_novtx_%i" , var,xmax-0.0001,iplot),sel);

  for( int ibin = 1 ; ibin <= nbins ; ibin++ ){
    hdata_denom->SetBinContent(ibin,hdata->Integral());
    hmc_denom->SetBinContent(ibin,hmc->Integral());
  }

  grdata->BayesDivide(hdata,hdata_denom);
  grmc->BayesDivide(hmc_novtx,hmc_denom);

  //--------------------------------------
  // get efficiencies and errors
  //--------------------------------------

  /*
  float ndata1     = (float) hdata->GetBinContent(1);
  float ndata      = (float) hdata->Integral();
  float effdata    = 1-ndata1 / ndata;

  // TGraphAsymmErrors* grdata_temp = new TGraphAsymmErrors();
  // TH1F* hdata_num_temp = new TH1F(Form("hdata_num_temp_%i",iplot),"",1,0,1);
  // TH1F* hdata_den_temp = new TH1F(Form("hdata_den_temp_%i",iplot),"",1,0,1);
  // hdata_num_temp->SetBinContent(1,ndata-ndata1);
  // hdata_den_temp->SetBinContent(1,ndata);
  // grdata_temp->BayesDivide(hdata_num_temp,hdata_den_temp);

  //float effdataerr = sqrt(ndata1) / ndata;
  float effdataerr = 0.5 * ( grdata->GetErrorYlow(0) + grdata->GetErrorYhigh(0) );
  //float effdataerr = 0.5 * ( grdata_temp->GetErrorYlow(0) + grdata_temp->GetErrorYhigh(0) );

  float nmc1       = (float) hmc->GetBinContent(1);
  float nmc        = (float) hmc->Integral();
  float effmc      = 1-nmc1 / nmc;
  //float effmcerr   = hmc->GetBinError(1) / nmc;
  float effmcerr   = 0.5 * ( grmc->GetErrorYlow(0) + grmc->GetErrorYhigh(0) );


  float datatot = hdata->Integral();
  float mctot   = hmc->Integral();
  
  cout << endl;
  cout << plottitle << endl;

  cout << "Data eff  " << Form("%.2f +/- %.3f",effdata,effdataerr) << endl;
  cout << "MC   eff  " << Form("%.2f +/- %.3f",effmc  ,effmcerr)   << endl;
  cout << "Data/MC   " << Form("%.2f +/- %.2f",ratio  ,ratioerr)   << endl;
  */

  float ndata    = hdata->Integral();
  float ndata1   = hdata->Integral(2,20);
  float ndata2   = hdata->Integral(3,20);
  float ndata3   = hdata->Integral(4,20);
  float ndata4   = hdata->Integral(5,20);
  float ndata5   = hdata->Integral(6,20);

  float nmc      = hmc->Integral();
  float nmc1     = hmc->Integral(2,20);
  float nmc2     = hmc->Integral(3,20);
  float nmc3     = hmc->Integral(4,20);
  float nmc4     = hmc->Integral(5,20);
  float nmc5     = hmc->Integral(6,20);

  float effdata1 = ndata1/ndata;
  float effdata2 = ndata2/ndata;
  float effdata3 = ndata3/ndata;
  float effdata4 = ndata4/ndata;
  float effdata5 = ndata5/ndata;

  float effmc1   = nmc1/nmc;
  float effmc2   = nmc2/nmc;
  float effmc3   = nmc3/nmc;
  float effmc4   = nmc4/nmc;
  float effmc5   = nmc5/nmc;

  float effdata1err = getBinomialError(ndata1,ndata);
  float effdata2err = getBinomialError(ndata2,ndata);
  float effdata3err = getBinomialError(ndata3,ndata);
  float effdata4err = getBinomialError(ndata4,ndata);
  float effdata5err = getBinomialError(ndata5,ndata);

  float effmc1err   = getBinomialError(nmc1,nmc);
  float effmc2err   = getBinomialError(nmc2,nmc);
  float effmc3err   = getBinomialError(nmc3,nmc);
  float effmc4err   = getBinomialError(nmc4,nmc);
  float effmc5err   = getBinomialError(nmc5,nmc);

  float ratio1      = effdata1/effmc1;
  float ratio2      = effdata2/effmc2;
  float ratio3      = effdata3/effmc3;
  float ratio4      = effdata4/effmc4;
  float ratio5      = effdata5/effmc5;

  float ratio1err   = ratio1 * sqrt(pow(effdata1err/effdata1,2)+pow(effmc1err/effmc1,2));
  float ratio2err   = ratio2 * sqrt(pow(effdata2err/effdata2,2)+pow(effmc2err/effmc2,2));
  float ratio3err   = ratio3 * sqrt(pow(effdata3err/effdata3,2)+pow(effmc3err/effmc3,2));
  float ratio4err   = ratio4 * sqrt(pow(effdata4err/effdata4,2)+pow(effmc4err/effmc4,2));
  float ratio5err   = ratio5 * sqrt(pow(effdata5err/effdata5,2)+pow(effmc5err/effmc5,2));

  cout << endl << endl << plottitle << endl;

  int left = 20;


  // char* delimstart = "|";
  // char* delim      = "|";
  // char* delimend   = "|";
  // char* pm         = "+/-";

  char* delimstart = "";
  char* delim      = "&";
  char* delimend   = "\\\\";
  char* pm         = "$\\pm$";

  cout << delimstart << setw(10) << "" << setw(4)
       << delim << setw(left) << "$>$ 1 GeV" << setw(4)
       << delim << setw(left) << "$>$ 2 GeV" << setw(4)
       << delim << setw(left) << "$>$ 3 GeV" << setw(4) 
       << delim << setw(left) << "$>$ 4 GeV" << setw(4)
       << delim << setw(left) << "$>$ 5 GeV" << setw(4) 
       << delimend << endl;

  cout << delimstart << setw(10) << "data" << setw(4)
       << delim << setw(left) << Form("%.3f %s %.4f",effdata1,pm,effdata1err) << setw(4)
       << delim << setw(left) << Form("%.3f %s %.4f",effdata2,pm,effdata2err) << setw(4)
       << delim << setw(left) << Form("%.3f %s %.4f",effdata3,pm,effdata3err) << setw(4) 
       << delim << setw(left) << Form("%.3f %s %.4f",effdata4,pm,effdata4err) << setw(4)
       << delim << setw(left) << Form("%.3f %s %.4f",effdata5,pm,effdata5err) << setw(4) 
       << delimend << endl;

  cout << delimstart << setw(10) << "mc" << setw(4)
       << delim << setw(left) << Form("%.3f %s %.4f",effmc1,pm,effmc1err) << setw(4)
       << delim << setw(left) << Form("%.3f %s %.4f",effmc2,pm,effmc2err) << setw(4)
       << delim << setw(left) << Form("%.3f %s %.4f",effmc3,pm,effmc3err) << setw(4) 
       << delim << setw(left) << Form("%.3f %s %.4f",effmc4,pm,effmc4err) << setw(4)
       << delim << setw(left) << Form("%.3f %s %.4f",effmc5,pm,effmc5err) << setw(4) 
       << delimend << endl;

  cout << delimstart << setw(10) << "data/mc" << setw(4)
       << delim << setw(left) << Form("%.2f %s %.2f",ratio1,pm,ratio1err) << setw(4)
       << delim << setw(left) << Form("%.2f %s %.2f",ratio2,pm,ratio2err) << setw(4)
       << delim << setw(left) << Form("%.2f %s %.2f",ratio3,pm,ratio3err) << setw(4) 
       << delim << setw(left) << Form("%.2f %s %.2f",ratio4,pm,ratio4err) << setw(4)
       << delim << setw(left) << Form("%.2f %s %.2f",ratio5,pm,ratio5err) << setw(4) 
       << delimend << endl;

  //--------------------------------------
  // draw stuff
  //--------------------------------------

  hdata->Scale(1.0/hdata->Integral());
  hmc->Scale(1.0/hmc->Integral());

  if( log ) hmc->GetYaxis()->SetRangeUser(0.0001,5);  
  else      hmc->GetYaxis()->SetRangeUser(0.0,1);  

  hmc->GetXaxis()->SetTitle(xtitle);
  hmc->SetLineColor(2);
  hmc->SetMarkerColor(2);
  hmc->DrawNormalized("hist");
  hmc->DrawNormalized("sameE1");
  hdata->SetLineColor(4);
  hdata->SetMarkerColor(4);
  hdata->Draw("sameE1");

  grdata->SetLineColor(6);
  grmc->SetLineColor(7);
  //grdata->Draw("sameP");
  //grmc->Draw("sameP");

  TLegend *leg = new TLegend(0.6,0.7,0.8,0.9);
  leg->AddEntry(hdata , "data" , "lp");
  leg->AddEntry(hmc   , "MC"   , "lp");
  leg->SetBorderSize(0);
  leg->SetFillColor(0);			       
  leg->Draw();

  TLatex *t = new TLatex();
  t->SetNDC();

  if( TString(plottitle).Contains("el") ) t->DrawLatex(0.6,0.6,"electrons");
  if( TString(plottitle).Contains("mu") ) t->DrawLatex(0.6,0.6,"muons");

  if( TString(plottitle).Contains("0j") ) t->DrawLatex(0.6,0.5,"n_{jets} #geq 0");
  if( TString(plottitle).Contains("1j") ) t->DrawLatex(0.6,0.5,"n_{jets} #geq 1");
  if( TString(plottitle).Contains("2j") ) t->DrawLatex(0.6,0.5,"n_{jets} #geq 2");
  if( TString(plottitle).Contains("3j") ) t->DrawLatex(0.6,0.5,"n_{jets} #geq 3");
  if( TString(plottitle).Contains("4j") ) t->DrawLatex(0.6,0.5,"n_{jets} #geq 4");

  //--------------------------------------
  // draw residual plots
  //--------------------------------------

  if( residual ){
    can->cd();
  
    TPad *respad = new TPad("respad","respad",0.0,0.8,1.0,1.0);
    respad->Draw();
    respad->cd();
    respad->SetGridy();

    TH1F* hratio = (TH1F*) hdata->Clone(Form("hratio_%i",iplot));
    hratio->Divide(hmc);

    hratio->SetMarkerColor(1);
    hratio->SetLineColor(1);
    hratio->Draw();
    hratio->GetYaxis()->SetRangeUser(0.5,1.5);
    hratio->GetYaxis()->SetNdivisions(5);
    hratio->GetYaxis()->SetLabelSize(0.2);
    hratio->GetXaxis()->SetLabelSize(0.0);
  
    TLine line;
    line.DrawLine(xmin,1.0,xmax,1.0);
  }
  
  //data->Scan("run:lumi:event:probe->pt():probe->eta():tkisonew:met:mt:njets:nbl:nbm",sel+"tkisonew>20");
  //data->Scan("run:lumi:event:probe->pt():probe->eta():tkisonew:met:mt:njets:nbl:nbm",sel);

  if( printplot ) can->Print(Form("plots/%s.pdf",plottitle));

  iplot++;

  // TCanvas *c2 = new TCanvas();
  // c2->cd();
  // grdata->Draw("AP");

}
void QA_Draw_Jet_Spectrum(
    //
    //    const char * jet = "h_QAG4SimJet_AntiKt_Tower_r07",
    const char *jet = "h_QAG4SimJet_AntiKt_Truth_r07",
    const char *qa_file_name_new =
        "data/G4sPHENIXCells_250jets25GeV.root_qa.root",
    const char *qa_file_name_ref =
        "data/G4sPHENIXCells_2000jets25GeV.root_qa.root")
{
  SetsPhenixStyle();
  TVirtualFitter::SetDefaultFitter("Minuit2");

  TFile *qa_file_new = new TFile(qa_file_name_new);
  assert(qa_file_new->IsOpen());

  TFile *qa_file_ref = NULL;
  if (qa_file_name_ref)
  {
    qa_file_ref = new TFile(qa_file_name_ref);
    assert(qa_file_ref->IsOpen());
  }

  // obtain normalization
  double Nevent_new = 1;
  double Nevent_ref = 1;

  if (qa_file_new)
  {
    TH1D *h_norm = (TH1D *) qa_file_new->GetObjectChecked(
        TString(jet) + TString("_Normalization"), "TH1D");
    assert(h_norm);

    Nevent_new = h_norm->GetBinContent(h_norm->GetXaxis()->FindBin("Event"));
  }
  if (qa_file_ref)
  {
    TH1D *h_norm = (TH1D *) qa_file_ref->GetObjectChecked(
        TString(jet) + TString("_Normalization"), "TH1D");
    assert(h_norm);

    Nevent_ref = h_norm->GetBinContent(h_norm->GetXaxis()->FindBin("Event"));
  }

  TCanvas *c1 = new TCanvas(TString("QA_Draw_Jet_Spectrum_") + TString(jet),
                            TString("QA_Draw_Jet_Spectrum_") + TString(jet), 1800, 1000);
  c1->Divide(4, 2);
  int idx = 1;
  TPad *p;

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        TString(jet) + TString("_Leading_eta"), "TH1F");
    assert(h_new);

    h_new->Rebin(2);
    h_new->Sumw2();
    h_new->Scale(1. / Nevent_new);

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          TString(jet) + TString("_Leading_eta"), "TH1F");
      assert(h_ref);

      h_ref->Rebin(2);
      h_ref->Scale(1. / Nevent_ref);
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Count / event / bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        TString(jet) + TString("_Leading_phi"), "TH1F");
    assert(h_new);

    h_new->Rebin(2);
    h_new->Sumw2();
    h_new->Scale(1. / Nevent_new);

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          TString(jet) + TString("_Leading_phi"), "TH1F");
      assert(h_ref);

      h_ref->Rebin(2);
      h_ref->Scale(1. / Nevent_ref);
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Count / event / bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        TString(jet) + TString("_Leading_Et"), "TH1F");
    assert(h_new);

    h_new->Sumw2();
    h_new->Scale(1. / Nevent_new);

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          TString(jet) + TString("_Leading_Et"), "TH1F");
      assert(h_ref);

      h_ref->Scale(1. / Nevent_ref);
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Count / event / bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        TString(jet) + TString("_Leading_Mass"), "TH1F");
    assert(h_new);

    h_new->Rebin(2);
    h_new->Sumw2();
    h_new->Scale(1. / Nevent_new);

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          TString(jet) + TString("_Leading_Mass"), "TH1F");
      assert(h_ref);

      h_ref->Rebin(2);
      h_ref->Scale(1. / Nevent_ref);
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Count / event / bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogx();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        TString(jet) + TString("_Leading_CompSize"), "TH1F");
    assert(h_new);

    h_new->Rebin(2);
    h_new->Sumw2();
    h_new->Scale(1. / Nevent_new);

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          TString(jet) + TString("_Leading_CompSize"), "TH1F");
      assert(h_ref);

      h_ref->Rebin(2);
      h_ref->Scale(1. / Nevent_ref);
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Count / event / bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        TString(jet) + TString("_Leading_CEMC_Ratio"), "TH1F");
    assert(h_new);

    h_new->Rebin(2);
    h_new->Sumw2();
    h_new->Scale(1. / Nevent_new);

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          TString(jet) + TString("_Leading_CEMC_Ratio"), "TH1F");
      assert(h_ref);

      h_ref->Rebin(2);
      h_ref->Scale(1. / Nevent_ref);
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Count / event / bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();

  {
    TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
        TString(jet) + TString("_Leading_CEMC_HCalIN_Ratio"), "TH1F");
    assert(h_new);

    h_new->Rebin(2);
    h_new->Sumw2();
    h_new->Scale(1. / Nevent_new);

    TH1F *h_ref = NULL;
    if (qa_file_ref)
    {
      h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
          TString(jet) + TString("_Leading_CEMC_HCalIN_Ratio"), "TH1F");
      assert(h_ref);

      h_ref->Rebin(2);
      h_ref->Scale(1. / Nevent_ref);
    }

    h_new->GetYaxis()->SetTitleOffset(1.5);
    h_new->GetYaxis()->SetTitle("Count / event / bin");
    //      h_new->GetXaxis()->SetRangeUser(-0, .1);

    DrawReference(h_new, h_ref);
  }

  if (TString(jet).Contains("Truth"))
  {
    // truth jets

    p = (TPad *) c1->cd(idx++);
    c1->Update();
    p->SetLogy();

    {
      TH1F *h_new = (TH1F *) qa_file_new->GetObjectChecked(
          TString(jet) + TString("_Leading_Leakage_Ratio"), "TH1F");
      assert(h_new);

      h_new->Rebin(2);
      h_new->Sumw2();
      h_new->Scale(1. / Nevent_new);

      TH1F *h_ref = NULL;
      if (qa_file_ref)
      {
        h_ref = (TH1F *) qa_file_ref->GetObjectChecked(
            TString(jet) + TString("_Leading_Leakage_Ratio"), "TH1F");
        assert(h_ref);

        h_ref->Rebin(2);
        h_ref->Scale(1. / Nevent_ref);
      }

      h_new->GetYaxis()->SetTitleOffset(1.5);
      h_new->GetYaxis()->SetTitle("Count / event / bin");
      //      h_new->GetXaxis()->SetRangeUser(-0, .1);

      DrawReference(h_new, h_ref);
    }
  }

//  PutInputFileName(c1, .04, qa_file_name_new, qa_file_name_ref);
  SaveCanvas(c1, TString(qa_file_name_new) + TString(c1->GetName()), true);
}
Beispiel #27
0
void showHistograms(double canvasSizeX, double canvasSizeY,
		    TH1* histogram_ref, const std::string& legendEntry_ref, double integral_ref,
		    TH1* histogram2, const std::string& legendEntry2, double integral2,
		    TH1* histogram3, const std::string& legendEntry3, double integral3,
		    TH1* histogram4, const std::string& legendEntry4, double integral4,
		    TH1* histogram5, const std::string& legendEntry5, double integral5,
		    TH1* histogram6, const std::string& legendEntry6, double integral6,
		    const std::string& xAxisTitle, double xAxisOffset,
		    bool useLogScale, double yMin, double yMax, const std::string& yAxisTitle, double yAxisOffset,
		    double legendX0, double legendY0, 
		    const std::string& outputFileName)
{
  if ( !(histogram_ref && histogram2) ) return;

  TCanvas* canvas = new TCanvas("canvas", "canvas", canvasSizeX, canvasSizeY);
  canvas->SetFillColor(10);
  canvas->SetBorderSize(2);
  canvas->SetLeftMargin(0.12);
  canvas->SetBottomMargin(0.12);

  TPad* topPad = new TPad("topPad", "topPad", 0.00, 0.35, 1.00, 1.00);
  topPad->SetFillColor(10);
  topPad->SetTopMargin(0.04);
  topPad->SetLeftMargin(0.15);
  topPad->SetBottomMargin(0.03);
  topPad->SetRightMargin(0.05);
  topPad->SetLogy(useLogScale);

  TPad* bottomPad = new TPad("bottomPad", "bottomPad", 0.00, 0.00, 1.00, 0.35);
  bottomPad->SetFillColor(10);
  bottomPad->SetTopMargin(0.02);
  bottomPad->SetLeftMargin(0.15);
  bottomPad->SetBottomMargin(0.24);
  bottomPad->SetRightMargin(0.05);
  bottomPad->SetLogy(false);

  canvas->cd();
  topPad->Draw();
  topPad->cd();

  //int colors[6] = { kBlack, kGreen - 6, kBlue - 7,  kMagenta - 7, kCyan - 6, kRed - 6 };
  int colors[6] = { kBlack, kRed, kBlue - 7,  kMagenta - 7, kCyan - 6, kRed - 6 };
  int markerStyles[6] = { 24, 25, 20, 21, 22, 23 };
  int markerSizes[6] = { 1, 1, 1, 1, 1, 1 };

  TLegend* legend = new TLegend(legendX0, legendY0, legendX0 + 0.61, legendY0 + 0.21, "", "brNDC"); 
  legend->SetBorderSize(0);
  legend->SetFillColor(0);

  histogram_ref->SetTitle("");
  histogram_ref->SetStats(false);
  histogram_ref->SetMinimum(yMin);
  histogram_ref->SetMaximum(yMax);
  histogram_ref->SetLineColor(colors[0]);
  histogram_ref->SetLineWidth(2);
  histogram_ref->SetMarkerColor(colors[0]);
  histogram_ref->SetMarkerStyle(markerStyles[0]);
  histogram_ref->SetMarkerSize(markerSizes[0]);
  histogram_ref->Draw("e1p");
  //if ( integral_ref >= 0. ) legend->AddEntry(histogram_ref, Form("%s: %1.2f", legendEntry_ref.data(), integral_ref), "p");
  //else legend->AddEntry(histogram_ref, legendEntry_ref.data(), "p");
  legend->AddEntry(histogram_ref, Form("%s: %1.2f", legendEntry_ref.data(), integral_ref), "p");

  TAxis* xAxis_top = histogram_ref->GetXaxis();
  xAxis_top->SetTitle(xAxisTitle.data());
  xAxis_top->SetTitleOffset(xAxisOffset);
  xAxis_top->SetLabelColor(10);
  xAxis_top->SetTitleColor(10);

  TAxis* yAxis_top = histogram_ref->GetYaxis();
  yAxis_top->SetTitle(yAxisTitle.data());
  yAxis_top->SetTitleOffset(yAxisOffset);

  if ( histogram2 ) {
    histogram2->SetLineColor(colors[1]);
    histogram2->SetLineWidth(2);
    histogram2->SetMarkerColor(colors[1]);
    histogram2->SetMarkerStyle(markerStyles[1]);
    histogram2->SetMarkerSize(markerSizes[1]);
    histogram2->Draw("e1psame");
    //if ( integral2 >= 0. ) legend->AddEntry(histogram2, Form("%s: %1.2f", legendEntry2.data(), integral2), "p");
    //else legend->AddEntry(histogram2, legendEntry2.data(), "p");
    legend->AddEntry(histogram2, Form("%s: %1.2f", legendEntry2.data(), integral2), "p");
  }

  if ( histogram3 ) {
    histogram3->SetLineColor(colors[2]);
    histogram3->SetLineWidth(2);
    histogram3->SetMarkerColor(colors[2]);
    histogram3->SetMarkerStyle(markerStyles[2]);
    histogram3->SetMarkerSize(markerSizes[2]);
    histogram3->Draw("e1psame");
    //if ( integral3 >= 0. ) legend->AddEntry(histogram3, Form("%s: %1.2f", legendEntry3.data(), integral3), "p");
    //else legend->AddEntry(histogram3, legendEntry3.data(), "p");
    legend->AddEntry(histogram3, Form("%s: %1.2f", legendEntry3.data(), integral3), "p");
  }

  if ( histogram4 ) {
    histogram4->SetLineColor(colors[3]);
    histogram4->SetLineWidth(2);
    histogram4->SetMarkerColor(colors[3]);
    histogram4->SetMarkerStyle(markerStyles[3]);
    histogram4->SetMarkerSize(markerSizes[3]);
    histogram4->Draw("e1psame");
    if ( integral4 >= 0. ) legend->AddEntry(histogram4, Form("%s: %1.2f", legendEntry4.data(), integral4), "p");
    else legend->AddEntry(histogram4, legendEntry4.data(), "p");
  }

  if ( histogram5 ) {
    histogram5->SetLineColor(colors[4]);
    histogram5->SetLineWidth(2);
    histogram5->SetMarkerColor(colors[4]);
    histogram5->SetMarkerStyle(markerStyles[4]);
    histogram5->SetMarkerSize(markerSizes[4]);
    histogram5->Draw("e1psame");
    if ( integral5 >= 0. ) legend->AddEntry(histogram5, Form("%s: %1.2f", legendEntry5.data(), integral5), "p");
    else legend->AddEntry(histogram5, legendEntry5.data(), "p");
  }

  if ( histogram6 ) {
    histogram6->SetLineColor(colors[5]);
    histogram6->SetLineWidth(2);
    histogram6->SetMarkerColor(colors[5]);
    histogram6->SetMarkerStyle(markerStyles[5]);
    histogram6->SetMarkerSize(markerSizes[5]);
    histogram6->Draw("e1psame");
    if ( integral6 >= 0. ) legend->AddEntry(histogram6, Form("%s: %1.2f", legendEntry6.data(), integral6), "p");
    else legend->AddEntry(histogram6, legendEntry6.data(), "p");
  }

  legend->Draw();

  canvas->cd();
  bottomPad->Draw();
  bottomPad->cd();

  TH1* histogram2_div_ref = 0;
  if ( histogram2 ) {
    std::string histogramName2_div_ref = std::string(histogram2->GetName()).append("_div_").append(histogram_ref->GetName());
    histogram2_div_ref = compRatioHistogram(histogramName2_div_ref, histogram2, histogram_ref);
    if ( histogram2_div_ref ) {
      histogram2_div_ref->SetTitle("");
      histogram2_div_ref->SetStats(false);
      histogram2_div_ref->SetMinimum(-0.50);
      histogram2_div_ref->SetMaximum(+0.50);
      
      TAxis* xAxis_bottom = histogram2_div_ref->GetXaxis();
      xAxis_bottom->SetTitle(xAxis_top->GetTitle());
      xAxis_bottom->SetLabelColor(1);
      xAxis_bottom->SetTitleColor(1);
      xAxis_bottom->SetTitleOffset(1.20);
      xAxis_bottom->SetTitleSize(0.08);
      xAxis_bottom->SetLabelOffset(0.02);
      xAxis_bottom->SetLabelSize(0.08);
      xAxis_bottom->SetTickLength(0.055);
      
      TAxis* yAxis_bottom = histogram2_div_ref->GetYaxis();
      yAxis_bottom->SetTitle(Form("#frac{%s - %s}{%s}", legendEntry2.data(), legendEntry_ref.data(), legendEntry_ref.data()));
      yAxis_bottom->SetTitleOffset(0.85);
      yAxis_bottom->SetNdivisions(505);
      yAxis_bottom->CenterTitle();
      yAxis_bottom->SetTitleSize(0.08);
      yAxis_bottom->SetLabelSize(0.08);
      yAxis_bottom->SetTickLength(0.04);  
      
      histogram2_div_ref->Draw("e1p");
    }
  }

  TH1* histogram3_div_ref = 0;
  if ( histogram3 ) {
    std::string histogramName3_div_ref = std::string(histogram3->GetName()).append("_div_").append(histogram_ref->GetName());
    histogram3_div_ref = compRatioHistogram(histogramName3_div_ref, histogram3, histogram_ref);
    if ( histogram3_div_ref ) {
      histogram3_div_ref->SetTitle("");
      histogram3_div_ref->SetStats(false);
      histogram3_div_ref->SetMinimum(-0.50);
      histogram3_div_ref->SetMaximum(+0.50);
      
      TAxis* xAxis_bottom = histogram3_div_ref->GetXaxis();
      xAxis_bottom->SetTitle(xAxis_top->GetTitle());
      xAxis_bottom->SetLabelColor(1);
      xAxis_bottom->SetTitleColor(1);
      xAxis_bottom->SetTitleOffset(1.20);
      xAxis_bottom->SetTitleSize(0.08);
      xAxis_bottom->SetLabelOffset(0.02);
      xAxis_bottom->SetLabelSize(0.08);
      xAxis_bottom->SetTickLength(0.055);
      
      TAxis* yAxis_bottom = histogram3_div_ref->GetYaxis();
      yAxis_bottom->SetTitle(Form("#frac{%s - %s}{%s}", legendEntry3.data(), legendEntry_ref.data(), legendEntry_ref.data()));
      yAxis_bottom->SetTitleOffset(0.85);
      yAxis_bottom->SetNdivisions(505);
      yAxis_bottom->CenterTitle();
      yAxis_bottom->SetTitleSize(0.08);
      yAxis_bottom->SetLabelSize(0.08);
      yAxis_bottom->SetTickLength(0.04);  
      
      if ( histogram2 ) histogram3_div_ref->Draw("e1psame");
      else histogram3_div_ref->Draw("e1p");
    }
  }

  TGraph* graph_line = new TGraph(2);
  graph_line->SetPoint(0, xAxis_top->GetXmin(), 0.);
  graph_line->SetPoint(1, xAxis_top->GetXmax(), 0.);
  graph_line->SetLineColor(8);
  graph_line->SetLineWidth(1);
  graph_line->Draw("L");

  if ( histogram2_div_ref ) histogram2_div_ref->Draw("e1psame");
  if ( histogram3_div_ref ) histogram3_div_ref->Draw("e1psame");

  TH1* histogram4_div_ref = 0;
  if ( histogram4 ) {
    std::string histogramName4_div_ref = std::string(histogram4->GetName()).append("_div_").append(histogram_ref->GetName());
    histogram4_div_ref = compRatioHistogram(histogramName4_div_ref, histogram4, histogram_ref);
    if ( histogram4_div_ref ) {
      histogram4_div_ref->Draw("e1psame");
    }
  }

  TH1* histogram5_div_ref = 0;
  if ( histogram5 ) {
    std::string histogramName5_div_ref = std::string(histogram5->GetName()).append("_div_").append(histogram_ref->GetName());
    histogram5_div_ref = compRatioHistogram(histogramName5_div_ref, histogram5, histogram_ref);
    if ( histogram5_div_ref ) {
      histogram5_div_ref->Draw("e1psame");
    }
  }

  TH1* histogram6_div_ref = 0;
  if ( histogram6 ) {
    std::string histogramName6_div_ref = std::string(histogram6->GetName()).append("_div_").append(histogram_ref->GetName());
    histogram6_div_ref = compRatioHistogram(histogramName6_div_ref, histogram6, histogram_ref);
    if ( histogram6_div_ref ) {
      histogram6_div_ref->Draw("e1psame");
    }
  }
  
  canvas->Update();
  size_t idx = outputFileName.find_last_of('.');
  std::string outputFileName_plot = std::string(outputFileName, 0, idx);
  if ( useLogScale ) outputFileName_plot.append("_log");
  else outputFileName_plot.append("_linear");
  if ( idx != std::string::npos ) canvas->Print(std::string(outputFileName_plot).append(std::string(outputFileName, idx)).data());
  canvas->Print(std::string(outputFileName_plot).append(".png").data());
  //canvas->Print(std::string(outputFileName_plot).append(".pdf").data());
  //canvas->Print(std::string(outputFileName_plot).append(".root").data());
  
  delete legend;
  delete histogram2_div_ref;
  delete histogram3_div_ref;
  delete histogram4_div_ref;
  delete histogram5_div_ref;
  delete histogram6_div_ref;
  delete topPad;
  delete bottomPad;
  delete canvas;  
}
void EMCDistribution_ShowShape(TString CherenkovSignal = "C2_Inner",
                               const double che_cut = 10)
{
  TString cut_pass = CherenkovSignal + Form(">%.1f", che_cut);
  TString cut_rej = CherenkovSignal + Form("<%.1f", che_cut);

  const double event_pass = T->GetEntries(cut_pass);
  const double event_rej = T->GetEntries(cut_rej);

  TH2 *EnergyDist_pass = new TH2F("EnergyDist_pass",
                                  cut_pass + ";Column;Row;<Energy> / Event / Tower", 8, -.5, 7.5, 8, -.5,
                                  7.5);
  TH2 *EnergyDist_rej = new TH2F("EnergyDist_rej",
                                 cut_rej + ";Column;Row;<Energy> / Event / Tower", 8, -.5, 7.5, 8, -.5,
                                 7.5);
  TH2 *Hodoscope_dist = new TH2F("Hodoscope_dist",
                                 cut_rej + ";7 - Horizontal Hodoscope (5 mm);7 - Vertical Hodoscope (5 mm); Event / finger^2", 8, -.5, 7.5, 8, -.5,
                                 7.5);

  TH1 *Che_full = new TH1F("Che_full",
                           ";" + CherenkovSignal + " Signal (ADC);Count / bin", 200, 0, 2000);
  TH1 *Che_pass = new TH1F("Che_pass",
                           ";" + CherenkovSignal + " Signal (ADC);Count / bin", 200, 0, 2000);
  TH1 *Che_rej = new TH1F("Che_rej",
                          ";" + CherenkovSignal + " Signal (ADC);Count / bin", 200, 0, 2000);

  Che_full->SetLineColor(kBlue + 3);
  Che_full->SetLineWidth(2);
  Che_pass->SetLineColor(kGreen + 3);
  Che_pass->SetLineWidth(2);
  Che_pass->SetFillColor(kGreen + 3);
  Che_pass->SetFillStyle(1);
  Che_rej->SetLineColor(kBlue + 3);
  Che_rej->SetLineWidth(2);
  Che_rej->SetFillColor(kBlue + 3);
  Che_rej->SetFillStyle(1);

  T->Draw(
      "TOWER_CALIB_CEMC[].get_binphi():TOWER_CALIB_CEMC[].get_bineta()>>EnergyDist_pass",
      Form("(%s) * (TOWER_CALIB_CEMC[].get_energy())", cut_pass.Data()),
      "goff");
  T->Draw(
      "TOWER_CALIB_CEMC[].get_binphi():TOWER_CALIB_CEMC[].get_bineta()>>EnergyDist_rej",
      Form("(%s) * (TOWER_CALIB_CEMC[].get_energy())", cut_rej.Data()), "goff");
  T->Draw(
      "7 - Average_HODO_VERTICAL:7 - Average_HODO_HORIZONTAL>>Hodoscope_dist", "1", "goff");

  T->Draw(CherenkovSignal + ">>Che_full", NULL, "goff");
  T->Draw(CherenkovSignal + ">>Che_pass", cut_pass, "goff");
  T->Draw(CherenkovSignal + ">>Che_rej", cut_rej, "goff");

  EnergyDist_pass->Scale(1. / event_pass);
  EnergyDist_rej->Scale(1. / event_rej);

  TText *t;
  TCanvas *c1 = new TCanvas("EMCDistribution_ShowShape" + cuts,
                            "EMCDistribution_ShowShape" + cuts, 1100, 950);
  c1->Divide(2, 2);
  int idx = 1;
  TPad *p;

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();
  p->SetGridx(0);
  p->SetGridy(0);

  Che_full->DrawClone();
  Che_pass->DrawClone("same");
  Che_rej->DrawClone("same");

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogy();

  EnergyDist_pass->DrawClone("colz");

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogy();
  //  p->SetGridx(0);
  //  p->SetGridy(0);

  EnergyDist_rej->DrawClone("colz");

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogy();
  //  p->SetGridx(0);
  //  p->SetGridy(0);

  Hodoscope_dist->DrawClone("colz");

  SaveCanvas(c1,
             TString(_file0->GetName()) + TString("_DrawPrototype3EMCalTower_") + TString(c1->GetName()), false);
}
Beispiel #29
0
void plotComparison( TH1F* h_dt , TH1F* h_mc , TH1F *h_extra, char* label, bool dolog, bool drawbkg) {

  TPad* fullpad = new TPad();
  TPad* plotpad = new TPad();
  TPad* respad  = new TPad();
  fullpad = new TPad("fullpad","fullpad",0,0,1,1);
  fullpad->Draw();
  fullpad->cd();
  plotpad = new TPad("plotpad","plotpad",0,0,1,0.8);
  plotpad->Draw();
  plotpad->cd();
  if (dolog) plotpad->SetLogy();

  h_dt->GetYaxis()->SetTitle("Entries");
  h_dt->GetXaxis()->SetTitle(Form("%s", label));
  h_dt->GetYaxis()->SetTitleSize(0.05);
  h_dt->GetXaxis()->SetTitleSize(0.05);
  h_dt->GetYaxis()->SetTitleOffset(1.5);
  h_dt->GetXaxis()->SetTitleOffset(1.3);
  if (!dolog) h_dt->GetYaxis()->SetRangeUser(0., 1.4*h_dt->GetMaximum());
  h_dt->SetLineColor(kBlack);
  h_dt->SetMarkerColor(kBlack);
  h_mc->SetLineColor(kBlue);
  h_mc->SetMarkerColor(kBlue);
  h_extra->SetLineColor(kRed);
  h_extra->SetLineWidth(2);
  h_mc->SetLineWidth(2);
  h_dt->Draw();
  h_mc->Draw("HISTSAME");
  if (drawbkg) h_extra->Draw("HISTSAME");
  h_dt->Draw("ESAME");

  TLegend *legComp = new TLegend( 0.653, 0.663, 0.944, 0.870);
  legComp->AddEntry(h_dt, "Data", "lp");
  legComp->AddEntry(h_mc, "MC", "l");
  if (drawbkg) legComp->AddEntry(h_extra, "MC Bkg", "l");
  legComp->SetFillColor(0);
  legComp->SetBorderSize(0);
  legComp->Draw();
  
  TLatex *text = new TLatex();
  text->SetNDC();
  text->SetTextSize(0.04);
  //  float xtex = 0.65;
  //  text->DrawLatex(xtex,0.88,"1 lepton + jets Sample");
  
  fullpad->cd();
  
  respad = new TPad("respad","respad",0,0.8,1,1);
  respad->Draw();
  respad->cd();
  
  //gPad->SetGridy();
  
  TH1F* ratio = (TH1F*) h_dt->Clone("ratio");
  ratio->Divide(h_mc);

  ratio->GetYaxis()->SetTitleOffset(0.3);
  ratio->GetYaxis()->SetTitleSize(0.2);
  ratio->GetYaxis()->SetNdivisions(5);
  ratio->GetYaxis()->SetLabelSize(0.2);
  if (dolog) ratio->GetYaxis()->SetRangeUser(0.5,1.5);
  else ratio->GetYaxis()->SetRangeUser(0.7,1.3);
  ratio->GetYaxis()->SetTitle("Ratio    ");
  ratio->GetXaxis()->SetLabelSize(0);
  ratio->GetXaxis()->SetTitleSize(0);
  ratio->SetMarkerSize(1);
  ratio->SetLineWidth(2);
  ratio->SetLineColor(kBlue);
  ratio->SetMarkerColor(kBlue);
  ratio->SetFillColor(kBlue);
  ratio->SetFillStyle(3002);
  ratio->Draw("E2");
  
  TLine line;
  line.SetLineWidth(2);
  line.DrawLine(h_dt->GetXaxis()->GetXmin(),1,h_dt->GetXaxis()->GetXmax(),1);

}
void EMCDistribution_SUM_RawADC(TString sTOWER = "Energy_Sum_col1_row2_5x5",
                                TString CherenkovSignal = "C2_Inner")
{
  TH1 *EnergySum_LG_full = new TH1F("EnergySum_LG_full",
                                    ";Tower Energy Sum (ADC);Count / bin", 260, -100, 2500);
  TH1 *EnergySum_LG = new TH1F("EnergySum_LG",
                               ";Tower Energy Sum (ADC);Count / bin", 260, -100, 2500);
  //  TH1 * EnergySum_HG = new TH1F("EnergySum_HG",
  //      ";Low range Tower Energy Sum (ADC);Count / bin", 50, 0, 500);

  TH1 *C2_Inner_full = new TH1F("C2_Inner_full",
                                CherenkovSignal + ";Cherenkov Signal (ADC);Count / bin", 1000, 0, 2000);
  TH1 *C2_Inner = new TH1F("C2_Inner",
                           CherenkovSignal + ";Cherenkov Inner Signal (ADC);Count / bin", 1000, 0, 2000);

  EnergySum_LG_full->SetLineColor(kBlue + 3);
  EnergySum_LG_full->SetLineWidth(2);

  EnergySum_LG->SetLineColor(kGreen + 3);
  EnergySum_LG->SetLineWidth(3);
  EnergySum_LG->SetMarkerColor(kGreen + 3);

  C2_Inner_full->SetLineColor(kBlue + 3);
  C2_Inner_full->SetLineWidth(2);

  C2_Inner->SetLineColor(kGreen + 3);
  C2_Inner->SetLineWidth(3);
  C2_Inner->SetMarkerColor(kGreen + 3);

  TCut c2 = CherenkovSignal + ">240";

  T->Draw(sTOWER + ">>EnergySum_LG_full", "", "goff");
  T->Draw(sTOWER + ">>EnergySum_LG", c2, "goff");
  T->Draw(CherenkovSignal + ">>C2_Inner_full", "", "goff");
  T->Draw(CherenkovSignal + ">>C2_Inner", c2, "goff");

  TText *t;
  TCanvas *c1 = new TCanvas(
      "EMCDistribution_SUM_RawADC_" + sTOWER + "_" + CherenkovSignal + cuts,
      "EMCDistribution_SUM_RawADC_" + sTOWER + "_" + CherenkovSignal + cuts, 1800,
      600);
  c1->Divide(3, 1);
  int idx = 1;
  TPad *p;

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();
  p->SetGridx(0);
  p->SetGridy(0);

  C2_Inner_full->DrawClone();
  C2_Inner->DrawClone("same");

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  p->SetLogy();
  p->SetGridx(0);
  p->SetGridy(0);

  TH1 *h = (TH1 *) EnergySum_LG_full->DrawClone();
  //  h->GetXaxis()->SetRangeUser(0, h->GetMean() + 5 * h->GetRMS());
  (TH1 *) EnergySum_LG->DrawClone("same");

  p = (TPad *) c1->cd(idx++);
  c1->Update();
  //  p->SetLogy();
  p->SetGridx(0);
  p->SetGridy(0);

  TH1 *h_full = (TH1 *) EnergySum_LG_full->DrawClone();
  TH1 *h = (TH1 *) EnergySum_LG->DrawClone("same");

  TF1 *fgaus_g = new TF1("fgaus_LG_g", "gaus", h->GetMean() - 1 * h->GetRMS(),
                         h->GetMean() + 4 * h->GetRMS());
  fgaus_g->SetParameters(1, h->GetMean() - 2 * h->GetRMS(),
                         h->GetMean() + 2 * h->GetRMS());
  h->Fit(fgaus_g, "MR0N");

  TF1 *fgaus = new TF1("fgaus_LG", "gaus",
                       fgaus_g->GetParameter(1) - 1 * fgaus_g->GetParameter(2),
                       fgaus_g->GetParameter(1) + 4 * fgaus_g->GetParameter(2));
  fgaus->SetParameters(fgaus_g->GetParameter(0), fgaus_g->GetParameter(1),
                       fgaus_g->GetParameter(2));
  h->Fit(fgaus, "MR");

  h->Sumw2();
  h_full->Sumw2();
  h_full->GetXaxis()->SetRangeUser(h->GetMean() - 4 * h->GetRMS(),
                                   h->GetMean() + 4 * h->GetRMS());

  h->SetLineWidth(2);
  h->SetMarkerStyle(kFullCircle);

  h_full->SetTitle(
      Form("#DeltaE/<E> = %.1f%%",
           100 * fgaus->GetParameter(2) / fgaus->GetParameter(1)));

  //  p = (TPad *) c1->cd(idx++);
  //  c1->Update();
  //  p->SetLogy();
  //  p->SetGridx(0);
  //  p->SetGridy(0);
  //
  //  TH1 * h = (TH1 *) EnergySum_LG->DrawClone();
  //  h->GetXaxis()->SetRangeUser(0,500);
  //  h->SetLineWidth(2);
  //  h->SetLineColor(kBlue + 3);
  ////  h->Sumw2();
  //  h->GetXaxis()->SetRangeUser(0, h->GetMean() + 5 * h->GetRMS());
  //
  //  p = (TPad *) c1->cd(idx++);
  //  c1->Update();
  ////  p->SetLogy();
  //  p->SetGridx(0);
  //  p->SetGridy(0);
  //
  //  TH1 * h = (TH1 *) EnergySum_LG->DrawClone();
  //  h->GetXaxis()->SetRangeUser(0,500);
  //
  //  TF1 * fgaus = new TF1("fgaus_HG", "gaus", 0, 100);
  //  fgaus->SetParameters(1, h->GetMean() - 2 * h->GetRMS(),
  //      h->GetMean() + 2 * h->GetRMS());
  //  h->Fit(fgaus, "M");
  //
  //  h->Sumw2();
  //  h->GetXaxis()->SetRangeUser(h->GetMean() - 4 * h->GetRMS(),
  //      h->GetMean() + 4 * h->GetRMS());
  //
  //  h->SetLineWidth(2);
  //  h->SetMarkerStyle(kFullCircle);
  //
  //  h->SetTitle(
  //      Form("#DeltaE/<E> = %.1f%%",
  //          100 * fgaus->GetParameter(2) / fgaus->GetParameter(1)));

  SaveCanvas(c1,
             TString(_file0->GetName()) + TString("_DrawPrototype3EMCalTower_") + TString(c1->GetName()), false);
}