GenericTnPFitter.h

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#include "RooGaussian.h"
#include "RooChebychev.h"
#include "RooVoigtian.h"
#include "RooExponential.h"
#include "RooRealVar.h"
#include "RooFormulaVar.h"
#include "RooDataHist.h"
#include "RooAddPdf.h"
#include "RooGlobalFunc.h"
#include "RooCategory.h"
#include "RooSimultaneous.h"
#include "RooChi2Var.h"
#include "TFile.h"
#include "TH1F.h"
#include "TH2F.h"
#include "TH3F.h"
#include "TProfile2D.h"
#include "TCanvas.h"
#include "RooPlot.h"

namespace dqmTnP{

class AbstractFitter{
  protected:
  RooRealVar mass;
  RooRealVar mean;
  double expectedMean;
  RooRealVar sigma;
  double expectedSigma;
  RooRealVar efficiency;
  RooRealVar nSignalAll;
  RooFormulaVar nSignalPass;
  RooFormulaVar nSignalFail;
  RooRealVar nBackgroundFail;
  RooRealVar nBackgroundPass;
  RooCategory category;
  RooSimultaneous simPdf;
  RooDataHist *data;
  double chi2;
  bool verbose;

  public:
  AbstractFitter(bool verbose_ = false):
    mass("mass","mass",0.,100.,"GeV"),
    mean("mean","mean",0.,100.,"GeV"),
    sigma("sigma","sigma",0.,100.,"GeV"),
    efficiency("efficiency","efficiency",0.5,0.0,1.0),
    nSignalAll("nSignalAll","nSignalAll",0.,1e10),
    nSignalPass("nSignalPass","nSignalAll*efficiency",RooArgList(nSignalAll,efficiency)),
    nSignalFail("nSignalFail","nSignalAll*(1-efficiency)",RooArgList(nSignalAll,efficiency)),
    nBackgroundFail("nBackgroundFail","nBackgroundFail",0.,1e10),
    nBackgroundPass("nBackgroundPass","nBackgroundPass",0.,1e10),
    category("category","category"),
    simPdf("simPdf","simPdf",category),
    data(0),
    verbose(verbose_)
  {
    //turn on/off default messaging of roofit
    RooMsgService::instance().setSilentMode( !verbose?kTRUE:kFALSE );
    for(int i=0; i<RooMsgService::instance().numStreams(); i++){
      RooMsgService::instance().setStreamStatus( i, verbose?kTRUE:kFALSE );
    }
    category.defineType("pass");
    category.defineType("fail");
  };
  virtual ~AbstractFitter(){};
  void setup(double expectedMean_, double massLow, double massHigh, double expectedSigma_){
    expectedMean = expectedMean_;
    expectedSigma = expectedSigma_;
    mass.setRange(massLow,massHigh);
    mean.setRange(massLow,massHigh);
  }
  virtual void fit(TH1* num, TH1* den) = 0;
  double getEfficiency(){ return efficiency.getVal(); }
  double getEfficiencyError(){ return efficiency.getError(); }
  double getChi2(){ return chi2; }
  void savePlot(const TString& name){
    using namespace RooFit;
    RooPlot* frame = mass.frame(Name(name), Title("Failing and Passing Probe Distributions"));
    data->plotOn(frame,Cut("category==category::pass"),LineColor(kGreen),MarkerColor(kGreen));
    data->plotOn(frame,Cut("category==category::fail"),LineColor(kRed),MarkerColor(kRed));
    simPdf.plotOn(frame,Slice(category,"pass"),ProjWData(category,*data),LineColor(kGreen));
    simPdf.plotOn(frame,Slice(category,"fail"),ProjWData(category,*data),LineColor(kRed));
    simPdf.paramOn(frame,Layout(0.58,0.99,0.99));
    data->statOn(frame,Layout(0.70,0.99,0.5));
    frame->Write();
    delete frame;
  }

  TString calculateEfficiency(TH3 *pass, TH3 *all, int massDimension, TProfile2D* &eff, TProfile2D* &effChi2, TString plotName=""){
    //sort out the TAxis
    TAxis *par1Axis, *par2Axis, *massAxis;
    int par1C, par2C, massC;
    if(massDimension==1){
      massAxis = all->GetXaxis();
      massC = 1;
      par1Axis = all->GetYaxis();
      par1C = all->GetXaxis()->GetNbins()+2;
      par2Axis = all->GetZaxis();
      par2C = (all->GetXaxis()->GetNbins()+2)*(all->GetYaxis()->GetNbins()+2);
    }else if(massDimension==2){
      par1Axis = all->GetXaxis();
      par1C = 1;
      massAxis = all->GetYaxis();
      massC = all->GetXaxis()->GetNbins()+2;
      par2Axis = all->GetZaxis();
      par2C = (all->GetXaxis()->GetNbins()+2)*(all->GetYaxis()->GetNbins()+2);
    }else if(massDimension==3){
      par1Axis = all->GetXaxis();
      par1C = 1;
      par2Axis = all->GetYaxis();
      par2C = all->GetXaxis()->GetNbins()+2;
      massAxis = all->GetZaxis();
      massC = (all->GetXaxis()->GetNbins()+2)*(all->GetYaxis()->GetNbins()+2);
    }else{
      return "massDimension > 3 !, skipping...";
    }

    //create eff and effChi2 TProfiles
    if(!par1Axis || !par2Axis) return "No par1Axis or par2Axis!";
    if( par1Axis->GetXbins()->GetSize()==0 && par2Axis->GetXbins()->GetSize()==0 ){
      eff = new TProfile2D("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXmin(),par1Axis->GetXmax(),par2Axis->GetNbins(),par2Axis->GetXmin(),par2Axis->GetXmax());
    }else if( par1Axis->GetXbins()->GetSize()==0 ){
      eff = new TProfile2D("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXmin(),par1Axis->GetXmax(),par2Axis->GetNbins(),par2Axis->GetXbins()->GetArray());
    }else if( par2Axis->GetXbins()->GetSize()==0 ){
      eff = new TProfile2D("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXbins()->GetArray(),par2Axis->GetNbins(),par2Axis->GetXmin(),par2Axis->GetXmax());
    }else{
      eff = new TProfile2D("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXbins()->GetArray(),par2Axis->GetNbins(),par2Axis->GetXbins()->GetArray());
    }
    eff->SetTitle("");
    eff->SetXTitle( par1Axis->GetTitle() );
    eff->SetYTitle( par2Axis->GetTitle() );
    eff->SetStats(kFALSE);
    effChi2 = (TProfile2D*)eff->Clone("efficiencyChi2");
    eff->SetZTitle("Efficiency");
    eff->SetOption("colztexte");
    eff->GetZaxis()->SetRangeUser(-0.001,1.001);
    effChi2->SetZTitle("Chi^2/NDF");
    effChi2->SetOption("colztext");

    //create the 1D mass distribution container histograms
    TH1D* all1D = (massAxis->GetXbins()->GetSize()==0) ?
      new TH1D("all1D","all1D",massAxis->GetNbins(),massAxis->GetXmin(),massAxis->GetXmax()):
      new TH1D("all1D","all1D",massAxis->GetNbins(),massAxis->GetXbins()->GetArray()); 
    TH1D* pass1D = (TH1D *)all1D->Clone("pass1D");

    //for each parameter bin fit the mass distributions
    for(int par1=1; par1<=par1Axis->GetNbins(); par1++){
      for(int par2=1; par2<=par2Axis->GetNbins(); par2++){
        for(int mass=1; mass<=massAxis->GetNbins(); mass++){
          int index = par1*par1C + par2*par2C + mass*massC;
          all1D->SetBinContent(mass,all->GetBinContent(index));
          pass1D->SetBinContent(mass,pass->GetBinContent(index));
        }
        fit( pass1D, all1D );
        int index = par1 + par2*(par1Axis->GetNbins()+2);
        eff->SetBinContent( index, getEfficiency() );
        eff->SetBinEntries( index, 1 );
        eff->SetBinError( index, sqrt( getEfficiency()*getEfficiency() + getEfficiencyError()*getEfficiencyError() ) );
        effChi2->SetBinContent( index, getChi2() );
        effChi2->SetBinEntries( index, 1 );
        if(plotName!=""){
          savePlot( TString::Format("%s_%d_%d",plotName.Data(),par1,par2) );
        }
      }
    }
    delete all1D;
    delete pass1D;
    return "";//OK
  }

  TString calculateEfficiency(TH2 *pass, TH2 *all, int massDimension, TProfile* &eff, TProfile* &effChi2, TString plotName=""){
    //sort out the TAxis
    TAxis *par1Axis, *massAxis;
    int par1C, massC;
    if(massDimension==1){
      massAxis = all->GetXaxis();
      massC = 1;
      par1Axis = all->GetYaxis();
      par1C = all->GetXaxis()->GetNbins()+2;
    }else if(massDimension==2){
      par1Axis = all->GetXaxis();
      par1C = 1;
      massAxis = all->GetYaxis();
      massC = all->GetXaxis()->GetNbins()+2;
    }else{
      return "massDimension > 2 !, skipping...";
    }

    //create eff and effChi2 TProfiles
    if(!par1Axis) return "No par1Axis!";
    eff = (par1Axis->GetXbins()->GetSize()==0)?
      new TProfile("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXmin(),par1Axis->GetXmax()):
      new TProfile("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXbins()->GetArray());
    eff->SetTitle("");
    eff->SetXTitle( par1Axis->GetTitle() );
    eff->SetLineColor(2);
    eff->SetLineWidth(2);
    eff->SetMarkerStyle(20);
    eff->SetMarkerSize(0.8);
    eff->SetStats(kFALSE);
    effChi2 = (TProfile*)eff->Clone("efficiencyChi2");
    eff->SetYTitle("Efficiency");
    eff->SetOption("PE");
    eff->GetYaxis()->SetRangeUser(-0.001,1.001);
    effChi2->SetYTitle("Chi^2/NDF");
    effChi2->SetOption("HIST");

    //create the 1D mass distribution container histograms
    TH1D * all1D = (massAxis->GetXbins()->GetSize()==0) ?
      new TH1D("all1D","all1D",massAxis->GetNbins(),massAxis->GetXmin(),massAxis->GetXmax()):
      new TH1D("all1D","all1D",massAxis->GetNbins(),massAxis->GetXbins()->GetArray()); 
    TH1D * pass1D = (TH1D *)all1D->Clone("pass1D");

    //for each parameter bin fit the mass distributions
    for(int par1=1; par1<=par1Axis->GetNbins(); par1++){
      for(int mass=1; mass<=massAxis->GetNbins(); mass++){
        int index = par1*par1C + mass*massC;
        all1D->SetBinContent(mass,all->GetBinContent(index));
        pass1D->SetBinContent(mass,pass->GetBinContent(index));
      }
      fit( pass1D, all1D );
      int index = par1;
      eff->SetBinContent( index, getEfficiency() );
      eff->SetBinEntries( index, 1 );
      eff->SetBinError( index, sqrt( getEfficiency()*getEfficiency() + getEfficiencyError()*getEfficiencyError() ) );
      effChi2->SetBinContent( index, getChi2() );
      effChi2->SetBinEntries( index, 1 );
      if(plotName!=""){
        savePlot( TString::Format("%s_%d",plotName.Data(),par1) );
      }
    }
    delete all1D;
    delete pass1D;
    return "";//OK
  }
};

//concrete fitter: Gaussian signal plus linear background
class GaussianPlusLinearFitter: public AbstractFitter{
  protected:
  RooGaussian gaussian;
  RooRealVar slopeFail;
  RooChebychev linearFail;
  RooRealVar slopePass;
  RooChebychev linearPass;
  RooAddPdf pdfFail;
  RooAddPdf pdfPass;
  public:
  GaussianPlusLinearFitter(bool verbose = false):
    AbstractFitter(verbose),
    gaussian("gaussian","gaussian",mass,mean,sigma),
    slopeFail("slopeFail","slopeFail",0.,-1.,1.),
    linearFail("linearFail","linearFail",mass,slopeFail),
    slopePass("slopePass","slopePass",0.,-1.,1.),
    linearPass("linearPass","linearPass",mass,slopePass),
    pdfFail("pdfFail","pdfFail", RooArgList(gaussian,linearFail), RooArgList(nSignalFail,nBackgroundFail)),
    pdfPass("pdfPass","pdfPass", RooArgList(gaussian,linearPass), RooArgList(nSignalPass,nBackgroundPass))
  {
    simPdf.addPdf(pdfFail,"fail");
    simPdf.addPdf(pdfPass,"pass");
  };
  ~GaussianPlusLinearFitter(){};
  void fit(TH1* pass, TH1* all){
    using namespace RooFit;
    all->Add(pass,-1);
    TH1* &fail = all;
    if(!data) delete data;
    data = new RooDataHist("data", "data", mass, Index(category), Import("fail",*fail), Import("pass",*pass) );
    if(pass->Integral()+fail->Integral() < 5){
      efficiency.setVal(0.5);
      efficiency.setError(0.5);
      chi2 = 0;
      return;
    }
    mean.setVal(expectedMean);
    sigma.setVal(expectedSigma);
    efficiency.setVal(pass->Integral()/(pass->Integral()+fail->Integral()));
    nSignalAll.setVal(0.5*(fail->Integral()+pass->Integral()));
    nBackgroundFail.setVal(0.5*fail->Integral());
    nBackgroundPass.setVal(0.5*pass->Integral());
    slopeFail.setVal(0.);
    slopePass.setVal(0.);
    if(verbose){
      simPdf.fitTo( *data );
    }else{
      simPdf.fitTo( *data, Verbose(kFALSE), PrintLevel(-1), Warnings(kFALSE), PrintEvalErrors(-1) );
    }
    RooDataHist dataFail("fail", "fail", mass, fail );
    RooDataHist dataPass("pass", "pass", mass, pass );
    chi2 = ( RooChi2Var("chi2Fail","chi2Fail",pdfFail,dataFail,DataError(RooAbsData::Poisson)).getVal()
      +RooChi2Var("chi2Pass","chi2Pass",pdfPass,dataPass,DataError(RooAbsData::Poisson)).getVal() )/(2*pass->GetNbinsX()-8);
    if(chi2>3){
      efficiency.setVal(0.5);
      efficiency.setError(0.5);
    }
  }
};

//concrete fitter: voigtian signal plus exponential background
class VoigtianPlusExponentialFitter: public AbstractFitter{
  protected:
  RooRealVar width;
  RooVoigtian voigtian;
  RooRealVar slopeFail;
  RooExponential exponentialFail;
  RooRealVar slopePass;
  RooExponential exponentialPass;
  RooAddPdf pdfFail;
  RooAddPdf pdfPass;
  public:
  VoigtianPlusExponentialFitter(bool verbose = false):
    AbstractFitter(verbose),
    width("width","width",2.5,"GeV"),
    voigtian("voigtian","voigtian",mass,mean,width,sigma),
    slopeFail("slopeFail","slopeFail",0.,-1.,0.),
    exponentialFail("linearFail","linearFail",mass,slopeFail),
    slopePass("slopePass","slopePass",0.,-1.,0.),
    exponentialPass("linearPass","linearPass",mass,slopePass),
    pdfFail("pdfFail","pdfFail", RooArgList(voigtian,exponentialFail), RooArgList(nSignalFail,nBackgroundFail)),
    pdfPass("pdfPass","pdfPass", RooArgList(voigtian,exponentialPass), RooArgList(nSignalPass,nBackgroundPass))
  {
    width.setConstant(kTRUE);
    simPdf.addPdf(pdfFail,"fail");
    simPdf.addPdf(pdfPass,"pass");
  };
  ~VoigtianPlusExponentialFitter(){};
  void setup(double expectedMean_, double massLow, double massHigh, double expectedSigma_, double width_){
    expectedMean = expectedMean_;
    expectedSigma = expectedSigma_;
    mass.setRange(massLow,massHigh);
    mean.setRange(massLow,massHigh);
    width.setVal(width_);
  }
  void fit(TH1* pass, TH1* all){
    using namespace RooFit;
    all->Add(pass,-1);
    TH1* &fail = all;
    if(!data) delete data;
    data = new RooDataHist("data", "data", mass, Index(category), Import("fail",*fail), Import("pass",*pass) );
    if(pass->Integral()+fail->Integral() < 5){
      efficiency.setVal(0.5);
      efficiency.setError(0.5);
      chi2 = 0;
      return;
    }
    mean.setVal(expectedMean);
    sigma.setVal(expectedSigma);
    efficiency.setVal(pass->Integral()/(pass->Integral()+fail->Integral()));
    nSignalAll.setVal(0.5*(fail->Integral()+pass->Integral()));
    nBackgroundFail.setVal(0.5*fail->Integral());
    nBackgroundPass.setVal(0.5*pass->Integral());
    slopeFail.setVal(0.);
    slopePass.setVal(0.);
    if(verbose){
      simPdf.fitTo( *data );
    }else{
      simPdf.fitTo( *data, Verbose(kFALSE), PrintLevel(-1), Warnings(kFALSE), PrintEvalErrors(-1) );
    }
    RooDataHist dataFail("fail", "fail", mass, fail );
    RooDataHist dataPass("pass", "pass", mass, pass );
    chi2 = ( RooChi2Var("chi2Fail","chi2Fail",pdfFail,dataFail,DataError(RooAbsData::Poisson)).getVal()
      +RooChi2Var("chi2Pass","chi2Pass",pdfPass,dataPass,DataError(RooAbsData::Poisson)).getVal() )/(2*all->GetNbinsX()-8);
    if(chi2>3){
      efficiency.setVal(0.5);
      efficiency.setError(0.5);
    }
  }
};

}//namespace dqmTnP