Esempio n. 1
0
TH1D * smartGausProfileXSQRTN (TH2F * strip, double width){
 TProfile * stripProfile = strip->ProfileX () ;
 
 // (from FitSlices of TH2.h)
 
 double xmin = stripProfile->GetXaxis ()->GetXmin () ;
 double xmax = stripProfile->GetXaxis ()->GetXmax () ;
 int profileBins = stripProfile->GetNbinsX () ;
 
 std::string name = strip->GetName () ;
 name += "_smartGaus_X" ; 
 TH1D * prof = new TH1D(name.c_str (),strip->GetTitle (),profileBins,xmin,xmax) ;
 
 int cut = 0 ; // minimum number of entries per fitted bin
 int nbins = strip->GetXaxis ()->GetNbins () ;
 int binmin = 1 ;
 int ngroup = 1 ; // bins per step
 int binmax = nbins ;
 
 // loop over the strip bins
 for (int bin=binmin ; bin<=binmax ; bin += ngroup) 
 {
  TH1D *hpy = strip->ProjectionY ("_temp",bin,bin+ngroup-1,"e") ;
  if (hpy == 0) continue ;
  int nentries = Int_t (hpy->GetEntries ()) ;
  if (nentries == 0 || nentries < cut) {delete hpy ; continue ;} 
  
  Int_t biny = bin + ngroup/2 ;
  
  TF1 * gaussian = new TF1 ("gaussian","gaus", hpy->GetMean () - width * hpy->GetRMS (), hpy->GetMean () + width * hpy->GetRMS ()) ; 
  gaussian->SetParameter (1,hpy->GetMean ()) ;
  gaussian->SetParameter (2,hpy->GetRMS ()) ;
  hpy->Fit ("gaussian","RQL") ;           
  
  //       hpy->GetXaxis ()->SetRangeUser ( hpy->GetMean () - width * hpy->GetRMS (), hpy->GetMean () + width * hpy->GetRMS ()) ;         
  prof->Fill (strip->GetXaxis ()->GetBinCenter (biny), gaussian->GetParameter (1)) ;       
  prof->SetBinError (biny,gaussian->GetParameter (2) / sqrt(hpy->GetEntries())) ;
//   prof->SetBinError (biny,gaussian->GetParError (1)) ;
  
  delete gaussian ;
  delete hpy ;
 } // loop over the bins
 
 delete stripProfile ;
 return prof ;
}
Esempio n. 2
0
//------------------------------------------------------------------------------
double meanY( char* hs ) // for profiles only
{
  TObject* obj = gDirectory->Get(hs);
  if( !obj->InheritsFrom( "TProfile" ) ) {
    cout << hs << " is not profile plot" << endl;
    return 0;
  }
  TProfile* p = (TProfile*)obj;
  double sumw = 0;
  double sumy = 0;
  for( int i = 1; i <= p->GetNbinsX(); ++i ) { // bin 0 is underflow
    double w = p->GetBinEntries(i);
    sumw += w;
    sumy += w * p->GetBinContent(i);
  }
  if( sumw > 0.1 )
    return sumy/sumw;
  else
    return 0;
}
Esempio n. 3
0
void plotAnaMult4(char *infname="ana.root")
{    
   TFile *inf = new TFile(infname);
   
   TTree *tData = (TTree*) inf->Get("Data_tree");
   TTree *tMC   = (TTree*) inf->Get("MC_tree");
   TTree *tPP   = (TTree*) inf->Get("PP_tree");

   TCanvas *c1 = new TCanvas("c","",1200,700);
//   c->Divide(4,1);
   TCut recoCut = "leadingJetPt>120&&subleadingJetPt>50&&dphi>5*3.14159265358979/6.&&abs(leadingJetEta)<1.6&&abs(subleadingJetEta)<1.6";
   TCut genCut = "genleadingJetPt>120&&gensubleadingJetPt>50&&genDphi>5*3.14159265358979/6.&&abs(genleadingJetEta)<1.6&&abs(gensubleadingJetEta)<1.6";

   
   const int nPtBin=5;
   Float_t PtBins[nPtBin+1] = {0.001,0.5,1,1.5,2,3.2};
   
   Int_t centBin[5] = {200,100,60,20,0};
   makeMultiPanelCanvas(c1,4,2,0.0,0.0,0.2,0.2,0.02);
   
   for (int i=0;i<4;i++) {
      c1->cd(i+1);
      TH1D * empty=new TH1D("empty","",100,0,3.19);
//      empty->Fill(0.5,1000); 
      empty->SetMaximum(39.99); 
      empty->SetMinimum(0.001); 
      empty->SetNdivisions(105,"X");
      empty->GetXaxis()->SetTitleSize(28);
      empty->GetXaxis()->SetTitleFont(43); 
      empty->GetXaxis()->SetTitleOffset(1.8);
      empty->GetXaxis()->SetLabelSize(22);
      empty->GetXaxis()->SetLabelFont(43);
      empty->GetYaxis()->SetTitleSize(28);
      empty->GetYaxis()->SetTitleFont(43); 
      empty->GetYaxis()->SetTitleOffset(1.8);
      empty->GetYaxis()->SetLabelSize(22);
      empty->GetYaxis()->SetLabelFont(43);
      empty->GetXaxis()->CenterTitle();
      empty->GetYaxis()->CenterTitle();

      empty->SetXTitle("#Delta#eta_{1,2}");
      empty->SetYTitle("Multiplicity Difference");
   
      TProfile *pData = new TProfile(Form("pData%d",i),"",nPtBin,PtBins);
      TProfile *pMC = new TProfile(Form("pMC%d",i),"",nPtBin,PtBins);
      TProfile *pPP = new TProfile(Form("pPP%d",i),"",nPtBin,PtBins);
      TProfile *pGen = new TProfile(Form("pGen%d",i),"",nPtBin,PtBins);
      TCut centCut = Form("hiBin>=%d&&hiBin<%d",centBin[i+1],centBin[i]);
      tData->Draw(Form("-multDiff:abs(leadingJetEta-subleadingJetEta)>>pData%d",i),recoCut&&centCut);
      tPP->Draw(Form("-multDiff:abs(leadingJetEta-subleadingJetEta)>>pPP%d",i),recoCut);
      tMC->Draw(Form("-multDiff:abs(leadingJetEta-subleadingJetEta)>>pMC%d",i),recoCut&&centCut);  
      tMC->Draw(Form("-genMultDiff:abs(genleadingJetEta-gensubleadingJetEta)>>pGen%d",i),genCut&&centCut);  

      pMC->SetLineColor(2);
      pMC->SetMarkerColor(2);
      pPP->SetLineColor(4);
      pPP->SetMarkerColor(4);
      
//      pData->SetAxisRange(0,50,"Y");
//      pData->SetAxisRange(0,0.49,"X");
      empty->Draw();

      double diff=0;
      if (i==0) diff=0.1;
      drawText(Form("%d-%d %%",(int)(0.5*centBin[i+1]),(int)(0.5*centBin[i])),0.22+diff,0.65);
      if (i==0) drawText("PbPb #sqrt{s_{NN}}=2.76 TeV 150/#mub",0.22+diff,0.85);
      if (i==0) drawText("pp      #sqrt{s_{NN}}=2.76 TeV 5.3/pb",0.22+diff,0.75);
      if (i==3) drawText("CMS Preliminary",0.3+diff,0.85);
            
      Float_t sys[4]={1,1,2.5,3};
      

      for (int j=1;j<=pData->GetNbinsX();j++)
      {
         TBox *b = new TBox(pData->GetBinLowEdge(j),pData->GetBinContent(j)-sys[i],pData->GetBinLowEdge(j+1),pData->GetBinContent(j)+sys[i]);
	 //b->SetFillColor(kGray);
	 b->SetFillStyle(0);
	 b->SetLineColor(1);
	 b->Draw();
         TBox *b2 = new TBox(pPP->GetBinLowEdge(j),pPP->GetBinContent(j)-1,pPP->GetBinLowEdge(j+1),pPP->GetBinContent(j)+1);
	 //b2->SetFillColor(65);
	 b2->SetFillStyle(0);
	 b2->SetLineColor(4);
	 b2->Draw();
      }
      pData->Draw("same");
      pMC->Draw("same");
      pPP->Draw("same");
      pGen->SetMarkerColor(4);
      pGen->SetMarkerStyle(24);
      pData->Draw("same");
      
//      pGen->Draw(" same");

      c1->cd(5+i);
      TH1D *empty2 = (TH1D*)empty->Clone("empty2");
      empty2->SetYTitle("PbPb - pp");
      empty2->SetMinimum(-5);
      empty2->SetMaximum(+29.99);
      empty2->Draw();
//      TProfile *pDiff = (TProfile*)pData->Clone("pDiff");
      TH1D *pDiff = new TH1D("pDiff","",nPtBin,PtBins);
      
      for (int j=1;j<=pData->GetNbinsX();j++)
      {
	 pDiff->SetBinContent(j,pData->GetBinContent(j)-pPP->GetBinContent(j));
  	 pDiff->SetBinError(j,sqrt(pData->GetBinError(j)*pData->GetBinError(j)+pPP->GetBinError(j)*pPP->GetBinError(j)));
         TBox *b = new TBox(pDiff->GetBinLowEdge(j),pDiff->GetBinContent(j)-sys[i],pDiff->GetBinLowEdge(j+1),pDiff->GetBinContent(j)+sys[i]);
         TBox *b2 = new TBox(pDiff->GetBinLowEdge(j),pDiff->GetBinContent(j)-sys[i],pDiff->GetBinLowEdge(j+1),pDiff->GetBinContent(j)+sys[i]);
         b->SetFillColor(TColor::GetColor("#FFEE00"));
	 b2->SetLineColor(1);
	 b2->SetFillStyle(0);
	 b->Draw();
	 b2->Draw();
      }
      
      pDiff->Draw("p same");


      TLegend *leg = new TLegend(0.3,0.6,0.9,0.9);
      leg->SetFillStyle(0);
      leg->SetBorderSize(0);
      leg->AddEntry(pData,"PbPb","pl");
      leg->AddEntry(pPP,"pp","pl");
      leg->AddEntry(pMC,"PYTHIA+HYDJET","pl");
      if (i==0) leg->Draw();

      if (i==1) drawText("p_{T,1} > 120 GeV/c",0.22+diff,0.85);
      if (i==1) drawText("p_{T,2} >  50 GeV/c",0.22+diff,0.75);
      if (i==1) drawText("#Delta#phi_{1,2} > 5#pi/6",0.22+diff,0.65);

   }
/*
   TCanvas *c1 = new TCanvas("c1","",(ncent+1)*300,700);
   makeMultiPanelCanvas(c1,ncent+1,2,0.0,0.0,0.2,0.2,0.02);
   TH1D * empty=new TH1D("empty",Form(";%s;<#slash{p}_{T}^{#parallel}> (GeV)",axistitle[index_var].Data()),nalpha/2+1,frac);
   TH1D * empty2=new TH1D("empty2",Form(";%s;<#slash{p}_{T}^{#parallel}> (GeV)",axistitle[index_var].Data()),nalpha/2+1,frac);
   empty->Fill(0.5,1000); 
   empty2->Fill(0.5,1000);   
   if(doIntegrate){
      if(index_var==0){
         empty->SetMaximum(30); 
         empty->SetMinimum(-70); 
      }else{
         empty->SetMaximum(35); 
         empty->SetMinimum(-45); 
      }
   }else{
      empty->SetMaximum(15); 
      empty->SetMinimum(-10); 
      empty2->SetMaximum(15); 
      empty2->SetMinimum(-10); 
   }
   empty->GetXaxis()->SetTitleSize(28);
   empty->GetXaxis()->SetTitleFont(43); 
   empty->GetXaxis()->SetTitleOffset(2.2);
   empty->GetXaxis()->SetLabelSize(22);
   empty->GetXaxis()->SetLabelFont(43);
   empty->GetYaxis()->SetTitleSize(28);
   empty->GetYaxis()->SetTitleFont(43); 
   empty->GetYaxis()->SetTitleOffset(2.2);
   empty->GetYaxis()->SetLabelSize(22);
   empty->GetYaxis()->SetLabelFont(43);
   empty2->GetXaxis()->SetTitleSize(28);
   empty2->GetXaxis()->SetTitleFont(43); 
   empty2->GetXaxis()->SetTitleOffset(2.2);
   empty2->GetXaxis()->SetLabelSize(22);
   empty2->GetXaxis()->SetLabelFont(43);
   empty2->GetYaxis()->SetTitleSize(28);
   empty2->GetYaxis()->SetTitleFont(43); 
   empty2->GetYaxis()->SetTitleOffset(2.2);
   empty2->GetYaxis()->SetLabelSize(22);
   empty2->GetYaxis()->SetLabelFont(43);
   
   
   c1->cd(ncent+2); 
*/

   c1->SaveAs("results/MultiplicityDifference-DeltaEta.C");
   c1->SaveAs("results/MultiplicityDifference-DeltaEta.gif");
   c1->SaveAs("results/MultiplicityDifference-DeltaEta.eps");
   c1->SaveAs("results/MultiplicityDifference-DeltaEta.pdf");


}
Esempio n. 4
0
void fitBjetJES(int ppPbPb=1, int cbinlo=12, int cbinhi=40){

  if(!ppPbPb){
    cbinlo=0;
    cbinhi=40;
  }

  gStyle->SetOptTitle(0);
  gStyle->SetOptStat(0);

  TFile *fL;
  
  if(!ppPbPb)fL=new TFile("histos/ppMC_hiReco_jetTrig_highPurity_JEC.root");
  else     fL=new TFile("histos/PbPbQCDMC_pt30by3_ipHICalibCentWeight.root");

  // these are dummy files for pp
  TFile *fB=new TFile("histos/PbPbBMC_pt30by3_ipHICalibCentWeight.root");
  TFile *fC=new TFile("histos/PbPbCMC_pt30by3_ipHICalibCentWeight.root");


  TNtuple *tL = (TNtuple*) fL->Get("nt");
  TNtuple *tB = (TNtuple*) fB->Get("nt");
  TNtuple *tC = (TNtuple*) fC->Get("nt");
  
  float jtptL, refptL, jtetaL, weightL, refparton_flavorForBL, binL;

  tL->SetBranchAddress("jtpt",&jtptL);
  tL->SetBranchAddress("jteta",&jtetaL);
  tL->SetBranchAddress("refpt",&refptL);
  tL->SetBranchAddress("weight",&weightL);
  if(ppPbPb)tL->SetBranchAddress("bin",&binL);
  tL->SetBranchAddress("refparton_flavorForB",&refparton_flavorForBL);

  float jtptB, refptB, jtetaB, weightB, refparton_flavorForBB, binB;

  tB->SetBranchAddress("jtpt",&jtptB);
  tB->SetBranchAddress("jteta",&jtetaB);
  tB->SetBranchAddress("refpt",&refptB);
  tB->SetBranchAddress("weight",&weightB);
  if(ppPbPb)tB->SetBranchAddress("bin",&binB);
  tB->SetBranchAddress("refparton_flavorForB",&refparton_flavorForBB);

  float jtptC, refptC, jtetaC, weightC, refparton_flavorForBC, binC;

  tC->SetBranchAddress("jtpt",&jtptC);
  tC->SetBranchAddress("jteta",&jtetaC);
  tC->SetBranchAddress("refpt",&refptC);
  tC->SetBranchAddress("weight",&weightC);
  if(ppPbPb)tC->SetBranchAddress("bin",&binC);
  tC->SetBranchAddress("refparton_flavorForB",&refparton_flavorForBC);

  TProfile  *hL = new TProfile("hL","hL",250,50,300,0,10);
  TProfile  *hB = new TProfile("hB","hB",250,50,300,0,10);
  TProfile  *hC = new TProfile("hC","hC",250,50,300,0,10);
  hL->Sumw2(),hB->Sumw2(),hC->Sumw2();


  for(int i=0;i<tL->GetEntries();i++){
    tL->GetEntry(i);
    if(!ppPbPb) binL=39;

    if(fabs(jtetaL)<2 && binL>=cbinlo && binL<cbinhi)
      hL->Fill(refptL,jtptL/refptL,weightL); 


    if(!ppPbPb){
      if(fabs(jtetaL)<2 && binL>=cbinlo && binL<cbinhi && abs(refparton_flavorForBL)==5)
	hB->Fill(refptL,jtptL/refptL,weightL);
      
      if(fabs(jtetaL)<2 && binL>=cbinlo && binL<cbinhi && abs(refparton_flavorForBL)==4)
	hC->Fill(refptL,jtptL/refptL,weightL);      
    }
  }

  if(ppPbPb){
    for(int i=0;i<tB->GetEntries();i++){
      tB->GetEntry(i);
      if(fabs(jtetaB)<2 && binB>=cbinlo && binB<cbinhi && abs(refparton_flavorForBB)==5)
	hB->Fill(refptB,jtptB/refptB,weightB);
    }
    for(int i=0;i<tC->GetEntries();i++){
      tC->GetEntry(i);
      if(fabs(jtetaC)<2 && binC>=cbinlo && binC<cbinhi && abs(refparton_flavorForBC)==4)
	hC->Fill(refptC,jtptC/refptC,weightC);
    }
  }

  
 
  hL->SetMinimum(0.);
  
  hL->SetLineColor(kBlue);
  hB->SetLineColor(kRed);
  hC->SetLineColor(kGreen);

  hL->SetMarkerColor(kBlue);
  hB->SetMarkerColor(kRed);
  hC->SetMarkerColor(kGreen);
  
  //hL->SetMarkerStyle(4);
  //hB->SetMarkerStyle(4);
  //hC->SetMarkerStyle(4);
  
  hL->SetXTitle("genJet p_{T} (GeV/c)");
  hL->SetYTitle("<reco p_{T} / gen p_{T} >");

  hL->GetXaxis()->SetRangeUser(50.,199.999);
  hL->GetYaxis()->SetRangeUser(0.5,1.05);
  
  TCanvas *c1=new TCanvas("c1","c1",800,600);
  c1->SetGridx(1);
  c1->SetGridy(1);

  hL->Draw("e1");
  hB->Draw("e1,same");
  hC->Draw("e1,same");

  TLegend *leg=new TLegend(0.4,0.15,0.9,0.45);
  leg->SetBorderSize(0);
  leg->SetFillStyle(0);
  if(ppPbPb&&cbinlo==0&&cbinhi==40)leg->SetHeader("Pythia+Hydjet, 0-100%");
  leg->AddEntry(hL,"Inclusive jets","pl");
  leg->AddEntry(hC,"c-jets","pl");
  leg->AddEntry(hB,"b-jets","pl");
  leg->Draw();

  TCanvas *c2=new TCanvas("c2","c2",1);
  /*
  TH1F *hL2 = (TH1F*)hL->Clone("hL2");
  TH1F *hB2 = (TH1F*)hB->Clone("hB2");
  hL2->Add(hB2,-1);
  hL2->Draw();
  */

  TH1F  *hcorr = new TH1F("hcorr","hcorr",250,50,300);
  hcorr->Sumw2();

  for(int i=0;i<hL->GetNbinsX();i++){
    cout<<" b resp "<<hB->GetBinContent(i+1)<<endl;
    cout<<" l resp "<<hL->GetBinContent(i+1)<<endl;
    cout<<" l offset "<<1.-hL->GetBinContent(i+1)<<endl;
    cout<<" corrected b resp "<<hB->GetBinContent(i+1)+1.-hL->GetBinContent(i+1)<<endl;
    float jesOffset = 1.-hL->GetBinContent(i+1);

    hcorr->SetBinContent(i+1,hB->GetBinContent(i+1)+jesOffset);

    hcorr->SetBinError(i+1,sqrt(hB->GetBinError(i+1)*hB->GetBinError(i+1)+hL->GetBinError(i+1)*hL->GetBinError(i+1)));


  }

  hcorr->SetMinimum(0.5);
  hcorr->SetMaximum(1.1);
      
  hcorr->SetLineColor(kRed);
  hcorr->SetMarkerColor(kRed);
  hcorr->SetMarkerStyle(4);
  hcorr->Draw();

  TF1 *fCorr = new TF1("fCorr","[0]+[1]*log(x)+[2]*log(x)*log(x)",50,300);
  fCorr->SetLineWidth(1);
  fCorr->SetLineColor(kBlue);
  hcorr->Fit(fCorr);

  TFile *fout;
  if(ppPbPb) fout =new TFile(Form("bJEShistos/bJetScale_PbPb_Cent_fineBin_%d_%d.root",cbinlo,cbinhi),"recreate");
  else fout =new TFile("bJEShistos/bJetScale_PP_fineBin.root","recreate");
  hcorr->Write();
  fCorr->Write();
  fout->Close();

}
Esempio n. 5
0
void DoEvolutions( const TString &sim, Int_t time, Int_t Nbins=1, const TString &options="") { 
  
#ifdef __CINT__  
  gSystem->Load("libptools.so");
#endif

  PGlobals::Initialize();
    
  // Palettes!
  gROOT->Macro("PPalettes.C");

  TString opt = options;
  // cout << "options = " << opt << endl;

  // Load PData
  PData *pData = PData::Get(sim.Data());
  pData->LoadFileNames(time);
  if(!pData->IsInit()) return;

  Bool_t CYL = kFALSE;
  if(sim.Contains("cyl")) { CYL = kTRUE; opt += "cyl"; } 
    
  Bool_t ThreeD = kFALSE;
  if(sim.Contains("3D")) ThreeD = kTRUE; 
  
  // Some plasma constants
  Double_t n0 = pData->GetPlasmaDensity();
  Double_t kp = pData->GetPlasmaK();
  Double_t skindepth = 1.0;
  if(kp!=0.0) skindepth = 1/kp;
  Double_t E0 = pData->GetPlasmaE0();

  // Some initial beam properties:
  Float_t Ebeam = pData->GetBeamEnergy() * PUnits::MeV;
  Float_t gamma = pData->GetBeamGamma();
  Float_t vbeam = pData->GetBeamVelocity();
  
  Double_t rms0 = pData->GetBeamRmsY() * kp;
  if(CYL)  rms0 = pData->GetBeamRmsR() * kp;
  
  // Time in OU
  Float_t Time = pData->GetRealTime();
  // z start of the plasma in normalized units.
  Float_t zStartPlasma = pData->GetPlasmaStart() * kp;
  // z start of the beam in normalized units.
  Float_t zStartBeam = pData->GetBeamStart() * kp;
  
  if(opt.Contains("center")) {
    Time -= zStartPlasma;
    if(opt.Contains("comov"))      // Centers on the head of the beam.
      Time += zStartBeam;
  }

  // Beam charge 2D and 1D histogram (on-axis)
  // ------------------------------------------------------------------
  TH2F *hDen2D = NULL;
  if(pData->GetChargeFileName(1)) {
    char hName[24];
    sprintf(hName,"hDen2D");
    hDen2D = (TH2F*) gROOT->FindObject(hName);
    if(hDen2D) { delete hDen2D; hDen2D = NULL; }

    if(!ThreeD)
      hDen2D = pData->GetCharge(1,opt);
    else
      hDen2D = pData->GetCharge2DSliceZY(1,-1,1,opt+"avg");

    hDen2D->SetName(hName);
    hDen2D->GetXaxis()->CenterTitle();
    hDen2D->GetYaxis()->CenterTitle();
    hDen2D->GetZaxis()->CenterTitle();
    
    if(opt.Contains("comov"))
      hDen2D->GetXaxis()->SetTitle("k_{p}#zeta");
    else
      hDen2D->GetXaxis()->SetTitle("k_{p}z");
    
    if(CYL) 
      hDen2D->GetYaxis()->SetTitle("k_{p}r");
    else
      hDen2D->GetYaxis()->SetTitle("k_{p}y");

    hDen2D->GetZaxis()->SetTitle("n_{b}/n_{0}");

 
  }
  
  // Define ranges from the charge 2D histogram:
  // Binning for 2D histograms:
  // We get this values from the 2D density histogram.
  Int_t   x1Nbin    = hDen2D->GetNbinsX();
  Float_t x1Range   = (hDen2D->GetXaxis()->GetXmax() - hDen2D->GetXaxis()->GetXmin());
  Float_t x1Mid     = (hDen2D->GetXaxis()->GetXmax() + hDen2D->GetXaxis()->GetXmin())/2.;
  Float_t x1Min     = hDen2D->GetXaxis()->GetXmin();
  Float_t x1Max     = hDen2D->GetXaxis()->GetXmax();
  
  Int_t   x2Nbin    = hDen2D->GetNbinsY();      
  Float_t x2Range   = (hDen2D->GetYaxis()->GetXmax() - hDen2D->GetYaxis()->GetXmin());
  Float_t x2Mid     = (hDen2D->GetYaxis()->GetXmax() + hDen2D->GetYaxis()->GetXmin())/2.;
  Float_t x2Min     = x2Mid - x2Range/2;
  Float_t x2Max     = x2Mid + x2Range/2;
  
  if(Nbins==0) {
    Nbins = TMath::Nint(rms0 / hDen2D->GetYaxis()->GetBinWidth(1)) ;
    // cout << Form(" Rms0 = %6.2f  Dx = %6.2f  Nbins = %4i .", 
    // 	   rms0, hDen2D->GetYaxis()->GetBinWidth(1), Nbins) << endl;
  }
  
  // Slice width limits.
  Int_t FirstyBin = 0;
  Int_t LastyBin  = 0;
  if(!CYL) {
    FirstyBin = hDen2D->GetNbinsY()/2 + 1 - Nbins;
    LastyBin =  hDen2D->GetNbinsY()/2 + Nbins;
  } else {
    FirstyBin = 1; 
    LastyBin  = Nbins;
  }  


  // OUTPUT ROOT FILE WITH THE PLOTS:
  TString filename = Form("./%s/Plots/Evolutions/Evolutions-%s.root",sim.Data(),sim.Data());
  TFile * ifile = (TFile*) gROOT->GetListOfFiles()->FindObject(filename);
  // if doesn't exist the directory should be created
  if (!ifile) {
    TString f = filename;
    TString dir2 = f.Remove( f.Last( '/' ), f.Length() - f.Last( '/' ) );
    TString dir1 = f.Remove( f.Last( '/' ), f.Length() - f.Last( '/' ) );
    gSystem->mkdir( dir1 );
    gSystem->mkdir( dir2 );
    ifile = new TFile(filename,"UPDATE");
  }  

  
  // Charge 1D histogram on axis
  TH1F *hDen1D = NULL;
  if(pData->GetChargeFileName(1)) {
    TString opth1 = opt;
    opth1 += "avg";
    
    char hName[24];
    sprintf(hName,"hDen1D");
    hDen1D = (TH1F*) gROOT->FindObject(hName);
    if(hDen1D) delete hDen1D;
    
    if(ThreeD) {
      hDen1D = pData->GetH1SliceZ3D(pData->GetChargeFileName(1)->c_str(),"charge",-1,Nbins,-1,Nbins,opth1.Data());
    } else if(CYL) { // Cylindrical: The first bin with r>0 is actually the number 1 (not the 0).
      hDen1D = pData->GetH1SliceZ(pData->GetChargeFileName(1)->c_str(),"charge",1,Nbins,opth1.Data());
    } else { // 2D cartesian
      hDen1D = pData->GetH1SliceZ(pData->GetChargeFileName(1)->c_str(),"charge",-1,Nbins,opth1.Data());
    }
    hDen1D->SetName(hName); 
    
    if(opt.Contains("comov"))
      hDen1D->GetXaxis()->SetTitle("k_{p}#zeta");
    else
      hDen1D->GetXaxis()->SetTitle("k_{p}z");
  
    hDen1D->GetYaxis()->SetTitle("n_{b}/n_{0}");
  }

  // On-axis beam density vs \zeta vs time! _________________________________
  TH2F *hDen1DvsTime = NULL; 
  if(hDen1D) {
    char hName[24];
    sprintf(hName,"hDen1DvsTime");
    TH2F *hDen1DvsTimeOld = (TH2F*) ifile->Get(hName);

    Int_t nBins   = 1;
    Float_t edge0 = Time-0.5;
    Float_t edge1 = Time+0.5;
    if(hDen1DvsTimeOld!=NULL) {
      nBins = hDen1DvsTimeOld->GetNbinsX()+1;
      Float_t binwidth =  (Time - hDen1DvsTimeOld->GetXaxis()->GetBinCenter(1))/(nBins-1);
      edge0 = hDen1DvsTimeOld->GetXaxis()->GetBinCenter(1) - binwidth/2.;
      edge1 = Time + binwidth/2.;
    }
    hDen1DvsTime = new TH2F("temp","",nBins,edge0,edge1,
		       	hDen1D->GetNbinsX(),
			hDen1D->GetBinLowEdge(1),
			hDen1D->GetBinLowEdge(hDen1D->GetNbinsX()+1));
    
    for(Int_t ix=1;ix<hDen1DvsTime->GetNbinsX();ix++) {
      for(Int_t iy=1;iy<hDen1DvsTime->GetNbinsY();iy++) {
	hDen1DvsTime->SetBinContent(ix,iy,hDen1DvsTimeOld->GetBinContent(ix,iy));
      }
    }  
    delete hDen1DvsTimeOld;
  
    // Fill last bin with the newest values.
    for(Int_t iy=1;iy<=hDen1D->GetNbinsX();iy++) {
      hDen1DvsTime->SetBinContent(nBins,iy,hDen1D->GetBinContent(iy));
    }   

    hDen1DvsTime->GetZaxis()->SetTitle("n_{b}/n_{0}");
    hDen1DvsTime->GetYaxis()->SetTitle("k_{p}#zeta");
    hDen1DvsTime->GetXaxis()->SetTitle("k_{p}z");
    hDen1DvsTime->GetZaxis()->CenterTitle();
    hDen1DvsTime->GetYaxis()->CenterTitle();
    hDen1DvsTime->GetXaxis()->CenterTitle();
    hDen1DvsTime->SetName(hName);

    // Change the range of z axis 
    Float_t Denmax = hDen1DvsTime->GetMaximum();
    hDen1DvsTime->GetZaxis()->SetRangeUser(0,Denmax); 
    hDen1DvsTime->Write(hName,TObject::kOverwrite);

  }

  // RMS (vs z) of the beam's charge distribution: 
  TProfile *hDen2Dprof = NULL;
  TH1F *hRms = NULL;
  Double_t axisPos = x2Mid;
  if(hDen2D) {
    TString pname = hDen2D->GetName();
    pname += "_pfx";
    
    hDen2Dprof =  (TProfile*) gROOT->FindObject(pname.Data());
    if(hDen2Dprof) { delete hDen2Dprof; hDen2Dprof = NULL; }
    hDen2Dprof = hDen2D->ProfileX("_pfx",1,-1,"s");
    
    hRms = (TH1F*) gROOT->FindObject("hRms");
    if(hRms) delete hRms;
    
    hRms = new TH1F("hRms","",x1Nbin,x1Min,x1Max);
    
    if(CYL) axisPos = 0.0;
    
    for(Int_t j=0;j<hRms->GetNbinsX();j++) {
      Double_t rms = 0;
      Double_t total = 0;
      for(Int_t k=1;k<=x2Nbin;k++) {
	Double_t value  = hDen2D->GetBinContent(j,k);
	Double_t radius = hDen2D->GetYaxis()->GetBinCenter(k) - axisPos;
	if(CYL) {
	  rms += radius*radius*radius*value;
	  total += radius*value;
	} else {
	  rms += radius*radius*value;
	  total += value;
	}
	// cout << Form(" (%i,%i) -> radius = %7.4f ,  density = %7.4f",j,k,radius,value) << endl;
      }
      
      rms /= total;
      rms = sqrt(rms);
      
      hRms->SetBinContent(j,rms); 
      
    }
    
    hRms->GetXaxis()->SetTitle("k_{p}z");
    if(opt.Contains("comov"))
      hRms->GetXaxis()->SetTitle("k_{p}#zeta");
    
    hRms->GetYaxis()->SetTitle("k_{p}#LTr#GT_{rms}");
  }
  
  // Transverse charge RMS vs \zeta vs time! _________________________________
  TH2F *hRmsvsTime = NULL; 
  if(hRms) {
    char hName[24];
    sprintf(hName,"hRmsvsTime");
    TH2F *hRmsvsTimeOld = (TH2F*) ifile->Get(hName);

    Int_t nBins   = 1;
    Float_t edge0 = Time-0.5;
    Float_t edge1 = Time+0.5;
    if(hRmsvsTimeOld!=NULL) {
      nBins = hRmsvsTimeOld->GetNbinsX()+1;
      Float_t binwidth =  (Time - hRmsvsTimeOld->GetXaxis()->GetBinCenter(1))/(nBins-1);
      edge0 = hRmsvsTimeOld->GetXaxis()->GetBinCenter(1) - binwidth/2.;
      edge1 = Time + binwidth/2.;
    }
    hRmsvsTime = new TH2F("temp","",nBins,edge0,edge1,
		       	hRms->GetNbinsX(),
			hRms->GetBinLowEdge(1),
			hRms->GetBinLowEdge(hRms->GetNbinsX()+1));
    
    for(Int_t ix=1;ix<hRmsvsTime->GetNbinsX();ix++) {
      for(Int_t iy=1;iy<hRmsvsTime->GetNbinsY();iy++) {
	hRmsvsTime->SetBinContent(ix,iy,hRmsvsTimeOld->GetBinContent(ix,iy));
      }
    }  
    delete hRmsvsTimeOld;
  
    // Fill last bin with the newest values.
    for(Int_t iy=1;iy<=hRms->GetNbinsX();iy++) {
      hRmsvsTime->SetBinContent(nBins,iy,hRms->GetBinContent(iy));
    }   

    hRmsvsTime->GetZaxis()->SetTitle("#LTr#GT_{rms}");
    hRmsvsTime->GetYaxis()->SetTitle("k_{p}#zeta");
    hRmsvsTime->GetXaxis()->SetTitle("k_{p}z");
    hRmsvsTime->GetZaxis()->CenterTitle();
    hRmsvsTime->GetYaxis()->CenterTitle();
    hRmsvsTime->GetXaxis()->CenterTitle();
    hRmsvsTime->SetName(hName);

    // Change the range of z axis
    Float_t Rmsmax = hRmsvsTime->GetMaximum();
    hRmsvsTime->GetZaxis()->SetRangeUser(0,Rmsmax); 
    hRmsvsTime->Write(hName,TObject::kOverwrite);

  }

  // INTEGRATED Beam's Charge:
  // Total charge vs time :
  TGraph *gQvsTime = NULL;
  if(hDen2D) {
    Double_t Q = 0;
    for(Int_t i=1;i<=x1Nbin;i++) {
      for(Int_t j=1;j<=x2Nbin;j++) {
	Double_t value  = hDen2D->GetBinContent(i,j);
	if(CYL) {
	  Double_t radius = hDen2D->GetYaxis()->GetBinCenter(j);
	  Q += radius * value;
	  // cout << Form(" (%i,%i) -> radius = %7.4f , value = %7.4f",i,j,radius,value) << endl;
	} else {
	  Q += value;
	}
      }    
    }
    Double_t xbinsize = hDen2D->GetXaxis()->GetBinWidth(1);
    Double_t ybinsize = hDen2D->GetYaxis()->GetBinWidth(1); 
    Q *= xbinsize * ybinsize;
    
    if(!CYL && !ThreeD) {
      Q *= TMath::Sqrt(2*TMath::Pi()) * rms0; 
    } else if(CYL) {
      Q *= 2*TMath::Pi();
    }
    
    if(opt.Contains("units")) {
      Double_t dV = skindepth * skindepth * skindepth;
      Q *= n0 * dV;
      Q *= (PConst::ElectronCharge/PUnits::picocoulomb); 
      cout << Form(" Integrated charge     = %8i pC", TMath::Nint(Q)) << endl;
    } else {
      cout << Form(" Integrated charge     = %8.4f n0 * kp^-3",Q) << endl;
    }
    
    Int_t nPoints = 0;
    char gName[32];
    sprintf(gName,"gQvsTime");     
    gQvsTime = (TGraph*) ifile->Get(gName);
    if(gQvsTime==NULL) {
      gQvsTime = new TGraph();
      gQvsTime->SetName(gName);
      nPoints = 0;
      // Some cosmetics at creation time:
      gQvsTime->SetLineWidth(3);
      gQvsTime->SetLineColor(PGlobals::fieldLine);
      gQvsTime->SetMarkerStyle(20);
      gQvsTime->SetMarkerSize(0.4);
      gQvsTime->SetMarkerColor(PGlobals::fieldLine);	
      gQvsTime->GetYaxis()->SetTitle("charge [n_{0}/k_{p}^{3}]");
      gQvsTime->GetXaxis()->SetTitle("k_{p}z");
    } else {
      nPoints = gQvsTime->GetN(); 
    }  
    
    gQvsTime->Set(nPoints+1);
    gQvsTime->SetPoint(nPoints,Time,Q);
    gQvsTime->Write(gName,TObject::kOverwrite);
  }
  
  // ------------------------------------------------------------------------------------
  

  // Longitudinal phasespace 
  Int_t  gNbin = 100;
  // Float_t gMin = 80;
  // Float_t gMax = 120;
  Float_t gMin = 43.07 - 1.2;
  Float_t gMax = 43.07 + 1.2;
  TH2F *hGvsZ = NULL;
  if(pData->GetRawFileName(1)) {
    char hName[24];
    sprintf(hName,"hGvsZ");
    hGvsZ = (TH2F*) gROOT->FindObject(hName);
    if(hGvsZ) { delete hGvsZ; hGvsZ = NULL; }
    hGvsZ = new TH2F(hName,"",x1Nbin,x1Min,x1Max,gNbin,gMin,gMax);
    pData->GetH2Raw(pData->GetRawFileName(1)->c_str(),"x1","gamma",hGvsZ,opt);
    
    hGvsZ->GetXaxis()->CenterTitle();
    hGvsZ->GetYaxis()->CenterTitle();
    hGvsZ->GetZaxis()->CenterTitle();
    hGvsZ->GetYaxis()->SetTitle("#gamma");
    if(opt.Contains("comov")) {
      hGvsZ->GetXaxis()->SetTitle("k_{p}#zeta");
      hGvsZ->GetZaxis()->SetTitle("dN/d#zetad#gamma [a.u.]");
    }  else {
      hGvsZ->GetXaxis()->SetTitle("k_{p}z");
      hGvsZ->GetZaxis()->SetTitle("dN/dzd#gamma [a.u.]");
    }    
  } else {
    cout << Form("--> No RAW data file is present for species 1") << endl;
  }

  TH2F *hGvsTime = NULL; 
  TProfile *hGvsZprof = NULL;
  TGraphErrors *gGvsZ = NULL;
  if(hGvsZ) {
    TString pname = hGvsZ->GetName();
    pname += "_pfx";
    hGvsZprof =  (TProfile*) gROOT->FindObject(pname.Data());
    if(hGvsZprof) delete hGvsZprof;

    hGvsZprof = hGvsZ->ProfileX("_pfx",1,-1,"s");

    gGvsZ = (TGraphErrors*) gROOT->FindObject("gGvsZ");
    if(gGvsZ) delete gGvsZ;

    Int_t Npoints = hGvsZprof->GetNbinsX();
    Double_t *x = new Double_t[Npoints];
    Double_t *y = new Double_t[Npoints];
    Double_t *ex = new Double_t[Npoints];
    Double_t *ey = new Double_t[Npoints];
    
    for(Int_t j=0;j<Npoints;j++) {
      x[j] = hGvsZprof->GetBinCenter(j);
      y[j] = hGvsZprof->GetBinContent(j);
      ex[j] = 0;
      ey[j] = hGvsZprof->GetBinError(j);   
    }
    
    gGvsZ = new TGraphErrors(Npoints,x,y,ex,ey);
    gGvsZ->SetName("gGvsZ");
        
    // PGlobals::SetH1Style((TH1*)gGvsZ,1);
    PGlobals::SetGraphStyle(gGvsZ,1);

   
    if(opt.Contains("comov")) 
      gGvsZ->GetXaxis()->SetTitle("k_{p}#zeta");
    else
      gGvsZ->GetXaxis()->SetTitle("k_{p}z");
    
    gGvsZ->GetYaxis()->SetTitle("#LT#gamma#GT [MeV]");

    char hName[24];
    sprintf(hName,"hGvsTime");
    TH2F *hGvsTimeOld = (TH2F*) ifile->Get(hName);

    Int_t nBins   = 1;
    Float_t edge0 = Time-0.5;
    Float_t edge1 = Time+0.5;
    if(hGvsTimeOld!=NULL) {
      nBins = hGvsTimeOld->GetNbinsX()+1;
      Float_t binwidth =  (Time - hGvsTimeOld->GetXaxis()->GetBinCenter(1))/(nBins-1);
      edge0 = hGvsTimeOld->GetXaxis()->GetBinCenter(1) - binwidth/2.;
      edge1 = Time + binwidth/2.;
    }
    hGvsTime = new TH2F("temp","",nBins,edge0,edge1,
		       	hGvsZprof->GetNbinsX(),
			hGvsZprof->GetBinLowEdge(1),
			hGvsZprof->GetBinLowEdge(hGvsZprof->GetNbinsX()+1));
    
    for(Int_t ix=1;ix<hGvsTime->GetNbinsX();ix++) {
      for(Int_t iy=1;iy<hGvsTime->GetNbinsY();iy++) {
	hGvsTime->SetBinContent(ix,iy,hGvsTimeOld->GetBinContent(ix,iy));
      }
    }  
    delete hGvsTimeOld;
  
    // Fill last bin with the newest values.
    for(Int_t iy=1;iy<=hGvsZprof->GetNbinsX();iy++) {
      hGvsTime->SetBinContent(nBins,iy,hGvsZprof->GetBinContent(iy));
    }   

    hGvsTime->GetZaxis()->SetTitle("#LT#gamma#GT");
    hGvsTime->GetYaxis()->SetTitle("k_{p}#zeta");
    hGvsTime->GetXaxis()->SetTitle("k_{p}z");
    hGvsTime->GetZaxis()->CenterTitle();
    hGvsTime->GetYaxis()->CenterTitle();
    hGvsTime->GetXaxis()->CenterTitle();
    hGvsTime->SetName(hName);

    // Change the range of z axis
    Float_t Gmax = hGvsTime->GetMaximum();
    Float_t Gmin = hGvsTime->GetMinimum();    
    hGvsTime->GetZaxis()->SetRangeUser(Gmin,Gmax); 
    hGvsTime->Write(hName,TObject::kOverwrite);
    
  }

  // ---------------------------------------------------------------------------------


  // EM fields on - axis :

  TString opth1 = opt;
  opth1 += "avg";
  // Get electric fields
  const Int_t Nfields = 2;
  TH1F **hE1D = new TH1F*[Nfields];
  for(Int_t i=0;i<Nfields;i++) {
    hE1D[i] = NULL;
    if(!pData->GetEfieldFileName(i))
      continue;
    
    char nam[3]; sprintf(nam,"e%i",i+1);
    if(ThreeD) {
      if(i==0) 
	hE1D[i] = pData->GetH1SliceZ3D(pData->GetEfieldFileName(i)->c_str(),nam,-1,Nbins,-1,Nbins,opth1.Data());
      else  
	hE1D[i] = pData->GetH1SliceZ3D(pData->GetEfieldFileName(i)->c_str(),nam,-Nbins,Nbins,-Nbins,Nbins,opth1.Data());
    } else if(CYL) { // Cylindrical: The first bin with r>0 is actually the number 1 (not the 0).
      if(i==0) 
	hE1D[i] = pData->GetH1SliceZ(pData->GetEfieldFileName(i)->c_str(),nam,1,Nbins,opth1.Data());
      else
	hE1D[i] = pData->GetH1SliceZ(pData->GetEfieldFileName(i)->c_str(),nam,1,Nbins,opth1.Data());
    } else { // 2D cartesian
      if(i==0) 
	hE1D[i] = pData->GetH1SliceZ(pData->GetEfieldFileName(i)->c_str(),nam,-1,Nbins,opth1.Data());
      else 
	hE1D[i] = pData->GetH1SliceZ(pData->GetEfieldFileName(i)->c_str(),nam,-Nbins,Nbins,opth1.Data());
    }
    
    char hName[24];
    sprintf(hName,"hE_%i_%i",i,time);
    hE1D[i]->SetName(hName);
    if(opt.Contains("comov"))
      hE1D[i]->GetXaxis()->SetTitle("k_{p}#zeta");
    else
      hE1D[i]->GetXaxis()->SetTitle("k_{p}z");
   
    if(i==0)
      hE1D[i]->GetYaxis()->SetTitle("E_{z}/E_{0}");
    else if(i==1)
      hE1D[i]->GetYaxis()->SetTitle("E_{y}/E_{0}");
    else if(i==2)
      hE1D[i]->GetYaxis()->SetTitle("E_{x}/E_{0}");
    
    hE1D[i]->GetYaxis()->CenterTitle();
    hE1D[i]->GetXaxis()->CenterTitle();
    
  }  
  
  // Calculate wave positions:
  // ----------------------------------------------------------------
    
  // Calculate the crossings and the extremes of the Electric fields
  Float_t Ecross[Nfields][100] = {{0.0}};
  Float_t Eextr[Nfields][100] = {{0.0}};
  Int_t Ncross[Nfields] = {0};

  for(Int_t i=0;i<Nfields;i++) {
    Ncross[i] = 0;
    
    if(!hE1D[i]) continue;
    
    // Only smooths the focusing if flag activated..
    if(i>0 && opt.Contains("smooth")) {
      // cout << " Smoothing fields on axis..." << endl;
      hE1D[i]->Smooth(10);
    } 

    Float_t maxZeta = zStartBeam;
    if(opt.Contains("center")) 
      maxZeta -= zStartBeam;
          
    for(Int_t ip=hE1D[i]->GetNbinsX();ip>1;ip--) {

      Float_t Z2 = hE1D[i]->GetBinCenter(ip-1);
      if(Z2 > maxZeta) continue;
      Float_t E1 = hE1D[i]->GetBinContent(ip);
      Float_t E2 = hE1D[i]->GetBinContent(ip-1);
      Float_t Z1 = hE1D[i]->GetBinCenter(ip);
      
      // cout << Form("Z1 = %6.4f  Z2 = %6.4f   E1 = %6.4f   E2 = %6.4f", Z1, Z2, E1, E2) << endl; 

      if(E1*E2 >= 0) { // No change of sign means we are in a side of the zero axis.
	if(fabs(E2)>fabs(Eextr[i][Ncross[i]])) {
	  Eextr[i][Ncross[i]] = E2;
	} 
      }
      
      if(E1*E2 < 0) { // change of sign means a crossing!
	
	// The next crossing has to be far enough from the previous one:
	Float_t zcross =  -E1 * ( (Z2-Z1)/(E2-E1) ) + Z1;
        if(Ncross[i]>0 && fabs(Ecross[i][Ncross[i]-1]-zcross)<TMath::PiOver2() ) continue;	
	// cout << " CROSS! " << endl;

	// add the point
	Ecross[i][Ncross[i]] = zcross;
	Ncross[i]++;
      }
    }
    
    cout << "  -> Number of crossings for field " << i << " : " << Ncross[i] << endl;
    for(Int_t ic=0;ic<Ncross[i];ic++) {
      //  cout << Form(" %2i:  zeta = %6.4f  E = %6.4f", ic, Ecross[i][ic], Eextr[i][ic]) << endl; 
    }  
    
    
    hE1D[i]->SetLineColor(kRed);
    hE1D[i]->Write(hE1D[i]->GetName(),TObject::kOverwrite);

  }
  
  // Get the Graphs and histos from file
  Int_t nPoints = 0;
  TGraph ***gEcross = new TGraph**[Nfields]; 
  TGraph ***gEextr  = new TGraph**[Nfields]; 
  TH2F **hEvsTime = new TH2F*[Nfields]; 
  for(Int_t i=0;i<Nfields;i++) {
    char hName[24];
    sprintf(hName,"hEvsTime_%i",i);
    TH2F *hEvsTimeOld = (TH2F*) ifile->Get(hName);
    Int_t nBins   = 1;
    Float_t edge0 = Time-0.5;
    Float_t edge1 = Time+0.5;
    if(hEvsTimeOld!=NULL) {
      nBins = hEvsTimeOld->GetNbinsX()+1;
      Float_t binwidth =  (Time - hEvsTimeOld->GetXaxis()->GetBinCenter(1))/(nBins-1);
      edge0 = hEvsTimeOld->GetXaxis()->GetBinCenter(1) - binwidth/2.;
      edge1 = Time + binwidth/2.;
    }
    hEvsTime[i] = new TH2F("temp","",nBins,edge0,edge1,
			hE1D[i]->GetNbinsX(),
			hE1D[i]->GetBinLowEdge(1),
			hE1D[i]->GetBinLowEdge(hE1D[i]->GetNbinsX()+1));
    
    for(Int_t ix=1;ix<hEvsTime[i]->GetNbinsX();ix++) {
      for(Int_t iy=1;iy<hEvsTime[i]->GetNbinsY();iy++) {
	hEvsTime[i]->SetBinContent(ix,iy,hEvsTimeOld->GetBinContent(ix,iy));
      }
    }  
    delete hEvsTimeOld;
  
    // Fill last bin with the newest values.
    for(Int_t iy=1;iy<=hE1D[i]->GetNbinsX();iy++) {
      hEvsTime[i]->SetBinContent(nBins,iy,hE1D[i]->GetBinContent(iy));
    }   

    if(i==0) 
      hEvsTime[i]->GetZaxis()->SetTitle("E_{z}/E_{0}");
    else if(i==1)
      hEvsTime[i]->GetZaxis()->SetTitle("E_{y}/E_{0}");
    else if(i==2)
      hEvsTime[i]->GetZaxis()->SetTitle("E_{x}/E_{0}");
  
    hEvsTime[i]->GetYaxis()->SetTitle("k_{p}#zeta");
    hEvsTime[i]->GetXaxis()->SetTitle("k_{p}z");
    hEvsTime[i]->GetZaxis()->CenterTitle();
    hEvsTime[i]->GetYaxis()->CenterTitle();
    hEvsTime[i]->GetXaxis()->CenterTitle();
    hEvsTime[i]->SetName(hName);

    // Change the range of z axis for the fields to be symmetric.
    Float_t Emax = hEvsTime[i]->GetMaximum();
    Float_t Emin = hEvsTime[i]->GetMinimum();
    if(Emax > TMath::Abs(Emin))
      Emin = -Emax;
    else
      Emax = -Emin;
    hEvsTime[i]->GetZaxis()->SetRangeUser(Emin,Emax); 
    
    hEvsTime[i]->Write(hName,TObject::kOverwrite);

    // ---

    gEcross[i] = new TGraph*[Ncross[i]];
    gEextr[i] = new TGraph*[Ncross[i]];
    char gName[24];
    Int_t ifail = 0;
    for(Int_t ic=0;ic<Ncross[i];ic++) {
      sprintf(gName,"gEcross_%i_%i",i,ic);     
      gEcross[i][ic] = (TGraph*) ifile->Get(gName);
      if(gEcross[i][ic]==NULL) {
	gEcross[i][ic] = new TGraph();
	gEcross[i][ic]->SetName(gName);
	nPoints = 0;
	// Some cosmetics at creation time:
	if(i==1) gEcross[i][ic]->SetLineStyle(2);
	else gEcross[i][ic]->SetLineStyle(1);
	gEcross[i][ic]->SetLineWidth(1);
	gEcross[i][ic]->SetLineColor(kGray+1);
	gEcross[i][ic]->SetMarkerStyle(20);
	gEcross[i][ic]->SetMarkerSize(0.4);
	gEcross[i][ic]->SetMarkerColor(kGray+1);	
	gEcross[i][ic]->GetYaxis()->SetTitle("k_{p}#zeta]");
	gEcross[i][ic]->GetXaxis()->SetTitle("k_{p}z");
      } else {
	nPoints = gEcross[i][ic]->GetN(); 
      }  
      
      // Check the new crossings respect the previous ones:
      // Double_t t,zeta;
      // if(nPoints>0) {
      // 	gEcross[i][ic]->GetPoint(nPoints-1,t,zeta);
      // 	if(fabs(zeta-Ecross[i][ic+ifail])>TMath::Pi()) {
      // 	  ic--;
      // 	  ifail++;
      // 	  continue;
      // 	}
      // }
      
      gEcross[i][ic]->Set(nPoints+1);
      gEcross[i][ic]->SetPoint(nPoints,Time,Ecross[i][ic+ifail]);
      gEcross[i][ic]->Write(gName,TObject::kOverwrite);
      
      // if(ic==Ncross[i]-1) continue;
      
      sprintf(gName,"gEextr_%i_%i",i,ic);     
      gEextr[i][ic] = (TGraph*) ifile->Get(gName);
      if(gEextr[i][ic]==NULL) {
	gEextr[i][ic] = new TGraph();
	gEextr[i][ic]->SetName(gName);
	nPoints = 0;
	// Some cosmetics at creation time:
	if(i==0) {
	  gEextr[i][ic]->SetLineWidth(3);
	  gEextr[i][ic]->SetLineColor(PGlobals::fieldLine);
	  gEextr[i][ic]->SetMarkerStyle(20);
	  gEextr[i][ic]->SetMarkerSize(0.4);
	  gEextr[i][ic]->SetMarkerColor(PGlobals::fieldLine);	
	  gEextr[i][ic]->GetYaxis()->SetTitle("E_{z}/E_{0}");
	  gEextr[i][ic]->GetXaxis()->SetTitle("k_{p}z");
	} else if(i==1) {
	  gEextr[i][ic]->SetLineWidth(1);
	  gEextr[i][ic]->SetLineColor(kGray+2);
	  gEextr[i][ic]->SetMarkerStyle(20);
	  gEextr[i][ic]->SetMarkerSize(0.4);
	  gEextr[i][ic]->SetMarkerColor(kGray+2);	
	  gEextr[i][ic]->GetYaxis()->SetTitle("E_{y}/E_{0}");
	  gEextr[i][ic]->GetXaxis()->SetTitle("k_{p}z");	  
	}
      } else {
	nPoints = gEextr[i][ic]->GetN(); 
      }  
      
      gEextr[i][ic]->Set(nPoints+1);
      gEextr[i][ic]->SetPoint(nPoints,Time,Eextr[i][ic]);
      gEextr[i][ic]->Write(gName,TObject::kOverwrite);
    }
  }

  
  ifile->Close();
  
}
Esempio n. 6
0
void recurseFile(TDirectory *indir, TDirectory *outdir,
                 double etawid, double etamid) {

  TDirectory *curdir = gDirectory;

  // Automatically go through the list of keys (directories)
  TList *keys = indir->GetListOfKeys();
  TListIter itkey(keys);
  TObject *key, *obj;
  TDirectory *dir;

  while ( (key = itkey.Next()) ) {

    if (_debug) cout << key->GetName() << endl << flush;
    obj = ((TKey*)key)->ReadObj(); assert(obj);
    dir = indir;

    // Found a subdirectory: copy it to output and go deeper
    if (obj->InheritsFrom("TDirectory")) {

      //assert(outdir->mkdir(obj->GetName()));
      outdir->mkdir(obj->GetName());
      assert(outdir->cd(obj->GetName()));
      TDirectory *outdir2 = outdir->GetDirectory(obj->GetName()); assert(outdir2);
      outdir2->cd();

      assert(indir->cd(obj->GetName()));
      TDirectory *indir2 = indir->GetDirectory(obj->GetName());
      indir2->cd();

      // Check if directory name contains information on eta bin width
      float etamin, etamax;
      if ( (sscanf(indir->GetName(),"Eta_%f-%f",&etamin,&etamax)==2)
           && (etamax>etamin) ) {
        etawid = 2.*(etamax-etamin);
        etamid = 0.5*(etamax+etamin);
        //cout << "Eta bin width: " << etawid << flush << endl;
      }

      recurseFile(indir2, outdir2, etawid, etamid);
      //outdir2->Write(); // does this speedup or slow down?
    } // inherits from TDirectory

    // Found a plot: normalize if hpt, then copy to output
    if (obj->InheritsFrom("TH1")) {

      outdir->cd();
      TObject *obj2 = obj->Clone(obj->GetName());

      // Normalize hpt and hselpt histograms
      // Same for hbpt
      if (string(obj2->GetName())=="hpt" ||
          string(obj2->GetName())=="hpt_evt" ||
          string(obj2->GetName())=="hpt_jet" ||
          string(obj2->GetName())=="hpt_pre" ||
          string(obj2->GetName())=="hpt0" ||
          string(obj2->GetName())=="hpt1" ||
          string(obj2->GetName())=="hpt2" ||
          string(obj2->GetName())=="hpt3" ||
          string(obj2->GetName())=="hpt_jk1" ||
          string(obj2->GetName())=="hpt_jk2" ||
          string(obj2->GetName())=="hpt_jk3" ||
          string(obj2->GetName())=="hpt_jk4" ||
          string(obj2->GetName())=="hpt_jk5" ||
          string(obj2->GetName())=="hpt_jk6" ||
          string(obj2->GetName())=="hpt_jk7" ||
          string(obj2->GetName())=="hpt_jk8" ||
          string(obj2->GetName())=="hpt_jk9" ||
          string(obj2->GetName())=="hpt_jk10" ||
          string(obj2->GetName())=="hpt_l1off" ||
          string(obj2->GetName())=="hpt_l1fast" ||
          string(obj2->GetName())=="hpt_plus" ||
          string(obj2->GetName())=="hpt_minus" ||
          string(obj2->GetName())=="hpt0_plus" ||
          string(obj2->GetName())=="hpt0_minus" ||
          string(obj2->GetName())=="hpt_noid" ||
          string(obj2->GetName())=="hpt_noevtid" ||
          string(obj2->GetName())=="hpt_nojetid" ||
          string(obj2->GetName())=="hpt_ak5calo" ||
          string(obj2->GetName())=="hpt_ak5pf" ||
          string(obj2->GetName())=="hpt_evt_ak5pf" ||
          string(obj2->GetName())=="hpt_jet_ak5pf" ||
          string(obj2->GetName())=="hselpt" ||
          string(obj2->GetName())=="hpt_r" ||
          string(obj2->GetName())=="hpt_g" ||
          string(obj2->GetName())=="hpt_gg" ||
          string(obj2->GetName())=="hpt_g0" ||
          string(obj2->GetName())=="hpt_g0tw" ||
          string(obj2->GetName())=="hdjmass" ||
          string(obj2->GetName())=="hdjmass0" ||
          string(obj2->GetName())=="hdjmass0_hgg") {

          cout << "." << flush;

        TH1D *hpt = (TH1D*)obj2;
        bool isgen = TString(obj2->GetName()).Contains("pt_g");
        bool isoth = (TString(obj2->GetName()).Contains("pt_no") ||
                      TString(obj2->GetName()).Contains("djmass") ||
                      TString(obj2->GetName()).Contains("hpt0") ||
                      TString(obj2->GetName()).Contains("l1off") ||
                      TString(obj2->GetName()).Contains("l1fast"));
        bool iscalo = (TString(obj2->GetName()).Contains("_ak5calo"));
        bool ispf5 = (TString(obj2->GetName()).Contains("_ak5pf"));
        bool ispre = (TString(obj2->GetName()).Contains("_pre"));
        bool isjk = (TString(obj2->GetName()).Contains("hpt_jk"));
        bool isjet = (TString(obj2->GetName()).Contains("hpt_jet"));

        TProfile *peff = (TProfile*)dir->Get("peff"); assert(peff);

        TH1D *hlumi = (TH1D*)dir->Get("hlumi"); assert(hlumi);
        TH1D *hlumi0 = (TH1D*)dir->Get("../jt450/hlumi"); assert(hlumi0);
        if (_jp_usetriglumi) {

          TH1D *hlumi_orig = (TH1D*)outdir->FindObject("hlumi_orig");
          if (!hlumi_orig) hlumi_orig = (TH1D*)hlumi->Clone("hlumi_orig");

          // regular prescaled luminosity
          TH1D *hlumi_new = (TH1D*)outdir->FindObject("hlumi");
          if (hlumi_new) hlumi = hlumi_new;
          string strg = dir->GetName();
          double lumi = triglumi[strg];
          for (int i = 1; i != hlumi->GetNbinsX()+1; ++i) {
            hlumi->SetBinContent(i, lumi);
          }

          // unprescaled luminosity
          double lumi0 = triglumi["jt450"];
          for (int i = 1; i != hlumi0->GetNbinsX()+1; ++i) {
            hlumi0->SetBinContent(i, lumi0);
          }
        } // _jp_usetriglumi

        // Test MC-based normalization for trigger efficiency
        bool dotrigeff = ((string(obj2->GetName())=="hpt") || isjk || isjet);
        TH1D *htrigeff = (TH1D*)outdir->FindObject("htrigeff");
        TH1D *htrigeffmc = (TH1D*)outdir->FindObject("htrigeffmc");
        TH1D *htrigeffsf = (TH1D*)outdir->FindObject("htrigeffsf");
        TH1D *hpt_notrigeff = 0;

        if (!htrigeff && _jp_dotrigeff) {

          TFile *fmc = new TFile("output-MC-1.root","READ");
          assert(fmc && !fmc->IsZombie());
          assert(fmc->cd("Standard"));
          fmc->cd("Standard");
          TDirectory *dmc0 = fmc->GetDirectory("Standard");
          //assert(gDirectory->cd(Form("Eta_%1.1f-%1.1f",
          //                 etamid-0.25*etawid,etamid+0.25*etawid)));
          //TDirectory *dmc = gDirectory;
          TDirectory *dmc = dmc0->GetDirectory(Form("Eta_%1.1f-%1.1f",
                                                    etamid-0.25*etawid,etamid+0.25*etawid));
          assert(dmc);
          dmc->cd();

          // Add MC truth based trigger efficiency
          if(!htrigeffmc && dmc->cd(dir->GetName())) {

            TDirectory *dir1 = dmc->GetDirectory(dir->GetName()); assert(dir1);
            TH1D *hpty = (TH1D*)dir1->Get("hpt"); assert(hpty);
            assert(dmc->cd("mc"));
            dmc->cd("mc");
            TDirectory *dir2 = dmc->GetDirectory("mc"); assert(dir2);
            TH1D *hptx = (TH1D*)dir2->Get(Form("hpt_%s",dir->GetName()));

            outdir->cd();
            if (hpty && hptx) htrigeffmc = (TH1D*)hpty->Clone("htrigeffmc");
            if (hpty && hptx) htrigeffmc->Divide(hpty,hptx,1,1,"B");
          }

          // Add data/MC scale factor for trigger efficiency
          if (_nh_dt && !htrigeffsf) {

            assert(dmc->cd(dir->GetName()));
            dmc->cd(dir->GetName());
            TDirectory *dirmc = dmc->GetDirectory(dir->GetName()); assert(dirmc);
            TProfile *pm = (TProfile*)dirmc->Get("ptrigefftp");
            TProfile *pd = (TProfile*)dir->Get("ptrigefftp");

            outdir->cd();
            if (pm && pd) htrigeffsf = pm->ProjectionX("htrigeffsf");
            if (pm && pd) htrigeffsf->Divide(pd,pm,1);
          }

          // Combine MC trigger efficiency and scalefactor
          if (htrigeffmc) { // not available for 'mc' directory
            outdir->cd();
            htrigeff = (TH1D*)htrigeffmc->Clone("htrigeff");
            assert(!_nh_dt || htrigeffsf);
            if (_nh_dt) htrigeff->Multiply(htrigeffsf);

            TH1D *h = (TH1D*)dir->Get("hpt");
            assert(outdir->FindObject("hpt_notrigeff")==0);
            outdir->cd();
            hpt_notrigeff = (TH1D*)h->Clone("hpt_notrigeff");
          }

          fmc->Close();
        } // dotrigeff


        // Scale data to account for time dependence
        bool dotimedep = ((string(obj2->GetName())=="hpt") || isjk || isjet);
        TH1D *htimedep = (TH1D*)outdir->FindObject("htimedep");
        TH1D *htimefit = (TH1D*)outdir->FindObject("htimefit");
        TH1D *hpt_notimedep = 0, *hpt_withtimedep = 0;
        double ktime = 1.;

        if (!htimedep) {

          TH1D *h = (TH1D*)dir->Get("hpt");
          TH1D *hsel = (TH1D*)dir->Get("hselpt");
          TH1D *hpre = (TH1D*)dir->Get("hpt_pre");
          //TH1D *hlumi0 = (TH1D*)dir->Get("../jt450/hlumi");

          // Fix luminosity for unprescaled trigger
          //string strg = dir->GetName();
          //double lum0 = triglumi["jt450"];
          //for (int i = 1; i != hlumi0->GetNbinsX()+1; ++i) {
          //hlumi0->SetBinContent(i, lum0);
          //}

          outdir->cd();
          if (h) hpt_notimedep = (TH1D*)h->Clone("hpt_notimedep");
          if (hpre && h) htimedep = (TH1D*)hpre->Clone("htimedep");
          if (hpre && h) htimedep->Divide(hpre,h);//,1,1,"B");

          // Figure out trigger luminosities
          double lumi = 0;
          if (hlumi) lumi = hlumi->GetBinContent(1);
          double lumi0 = 0;
          if (hlumi0) lumi0 = hlumi0->GetBinContent(1);
          if (htimedep && lumi && lumi0) {
            htimedep->Scale(lumi / lumi0);
          }

          // Find proper pT range and fit
          double minpt = 0.;
          double maxpt = 6500.;
          if (hsel) {
            for (int i = 1; i != hsel->GetNbinsX()+1; ++i) {
              if (hsel->GetBinContent(i)!=0 &&
                  hsel->GetBinLowEdge(i)>=_jp_xmin57) {
                if (minpt<20) minpt = hsel->GetBinLowEdge(i);
                maxpt = hsel->GetBinLowEdge(i+1);
              }
            }
          }
          TF1 *ftmp = new TF1("ftmp","[0]",minpt,maxpt);
          ftmp->SetParameter(0,1);
          if (htimedep && htimedep->Integral()>0) htimedep->Fit(ftmp,"QRN");

          if (htimedep && ftmp->GetParameter(0)>0)
            ktime = 1./ftmp->GetParameter(0);

          if (htimedep) {
            outdir->cd();
            htimefit = (TH1D*)hsel->Clone("htimefit");
            hpt_withtimedep = (TH1D*)h->Clone("hpt_withtimedep");

            for (int i = 1; i != htimefit->GetNbinsX()+1; ++i) {

              if (hsel->GetBinContent(i)!=0) {
                htimefit->SetBinContent(i, ftmp->GetParameter(0));
                htimefit->SetBinError(i, ftmp->GetParError(0));
              }

              // Calculate with time dependence here to add ktime fit error
              hpt_withtimedep->SetBinContent(i, hpt_notimedep->GetBinContent(i)
                                             * htimefit->GetBinContent(i));
              double err1 = hpt_notimedep->GetBinError(i)
                / hpt_notimedep->GetBinContent(i);
              double err2 = htimefit->GetBinError(i)
                / htimefit->GetBinContent(i);
              hpt_withtimedep->SetBinError(i, hpt_notimedep->GetBinContent(i)
                                           * sqrt(pow(err1,2) + pow(err2,2)));
            }
          }
        } // dotimedep


        if (!(hpt->GetNbinsX()==peff->GetNbinsX() || isoth || isgen) ||
            !(hpt->GetNbinsX()==hlumi->GetNbinsX() || isoth || isgen)) {
          cerr << "Hist " << hpt->GetName() << " " << dir->GetName()
               << " Nbins=" << hpt->GetNbinsX() << endl << flush;
          assert(hpt->GetNbinsX()==peff->GetNbinsX() || isoth);
          assert(hpt->GetNbinsX()==hlumi->GetNbinsX() || isoth);
        }

        for (int i = 1; i != hpt->GetNbinsX()+1; ++i) {

          // Normalization for bin width in y, pT
          double norm = hpt->GetBinWidth(i) * etawid;
          double trigeff = 1.;
          double pt = hpt->GetBinCenter(i);
          // Normalization for all the common efficiencies
          if (peff->GetBinContent(i)!=0 && !isgen)
            norm *= peff->GetBinContent(i);
          // Test MC-based normalization for trigger efficiency
          if (dotrigeff && htrigeff && _jp_dotrigeff) {
            if (htrigeff->GetBinContent(i)!=0) {
              trigeff = min(1.,max(0.,htrigeff->GetBinContent(i)));
              if (_jp_dotrigefflowptonly && pt>=114) trigeff = 1;
              norm *= trigeff;
            }
          }

          // Normalization for luminosity
          if (hlumi->GetBinContent(i)!=0 && !isoth && !isgen && !ispre)
            norm *= hlumi->GetBinContent(i);
          if (hlumi->GetBinContent(1)!=0 && isoth && !isgen && !ispre)
            norm *= hlumi->GetBinContent(1);
          if (hlumi0->GetBinContent(1)!=0 && !isoth && !isgen && ispre)
            norm *= hlumi0->GetBinContent(1);

          // Fix luminosity from .csv VTX to lumiCalc vdM
          if (!_nh_mc) norm *= _lumiscale;
          // Scale normalization for jackknife
          if (isjk) norm *= 0.9;

          if (_nh_mc && _jp_pthatbins) norm *= 1.;
          if (_nh_mc && !_jp_pthatbins) {
            norm /= 2500.; //(xsecw / (sumw * adhocw) ); // equals 2551.;
          }

          // Correct data for time-dependence
          double norm_notime = norm;
          if (dotimedep && htimedep && _jp_dotimedep) {
            norm *= ktime;
          }

          if (!(peff->GetBinContent(i)!=0||hpt->GetBinContent(i)==0 || isgen ||
                iscalo || ispf5 || isoth || hpt->GetBinCenter(i)<_jp_recopt
                || hpt->GetBinCenter(i)*cosh(etamid)>3500.)) {
            cerr << "Hist " << hpt->GetName() << " " << dir->GetName()
                 << " pt=" << hpt->GetBinCenter(i)
                 << " etamid = " << etamid << endl << flush;
            assert(peff->GetBinContent(i)!=0||hpt->GetBinContent(i)==0||isgen||
                   hpt->GetBinCenter(i)<_jp_recopt);
          }
          /*
          if (!(hlumi->GetBinContent(i)!=0 || hpt->GetBinContent(i)==0
                || isoth || isgen || hpt->GetBinCenter(i)<_jp_recopt)) {
            cerr << "Hist " << hpt->GetName() << " " << dir->GetName()
                 << " pt=" << hpt->GetBinCenter(i) << endl << flush;
            assert(hlumi->GetBinContent(i)!=0 || hpt->GetBinContent(i)==0
                   || isoth || hpt->GetBinCenter(i)<_jp_recopt);
          }
          */

          assert(norm!=0);
          hpt->SetBinContent(i, hpt->GetBinContent(i) / norm);
          hpt->SetBinError(i, hpt->GetBinError(i) / norm);
          if (hpt_notrigeff) {
            hpt_notrigeff->SetBinContent(i, hpt_notrigeff->GetBinContent(i)
                                         / norm * trigeff);
            hpt_notrigeff->SetBinError(i, hpt_notrigeff->GetBinError(i)
                                       / norm * trigeff);
          }
          if (hpt_notimedep) {
            hpt_notimedep->SetBinContent(i, hpt_notimedep->GetBinContent(i)
                                         / norm_notime);
            hpt_notimedep->SetBinError(i, hpt_notimedep->GetBinError(i)
                                       / norm_notime);
          }
          if (hpt_withtimedep) { // ktime already applied => use norm_notime
            hpt_withtimedep->SetBinContent(i, hpt_withtimedep->GetBinContent(i)
                                           / norm_notime);
            hpt_withtimedep->SetBinError(i, hpt_withtimedep->GetBinError(i)
                                         / norm_notime);
          }
        } // for i

      } // hpt

      dir->cd();
    } // inherits from TH1

  } // while key

  curdir->cd();
} // recurseFile