// -----------------------------------------------------------------------------
//
void test() {
time_t start = TTimeStamp().GetSec();
set_plot_style();
bool draw = true;
//bool debug = true;
// Define analysis configuration
PSet ps;
defaultPSet(ps);
// Response plots
if (false) {
//xSectDistr(ps);
responseProfile();
return;
}
// Print configuration
std::stringstream ss;
printPSet(ps,ss);
std::cout << ss.str() << std::endl;
// Params to store
DoubleVV ratio, ratio_errh, ratio_errl, pass, pass_err, fail, fail_err;
IntV length;
clear( ratio, ratio_errh, ratio_errl, pass, pass_err, fail, fail_err, length );
init( ps, ratio, ratio_errh, ratio_errl, pass, pass_err, fail, fail_err, length );
// Loop through Meff bins
int loop = 0;
int nloops = ps.nmeff;
for ( int imeff = 0; imeff < ps.nmeff; ++imeff ) {
// Generate numbers in (x1,x2) plane
DoubleVV dalitz;
generateTruth( ps, imeff, dalitz, true );
// Integrate across dalitz plane
integrate( ps, imeff, dalitz, ratio, ratio_errh, ratio_errl,
pass, pass_err, fail, fail_err, length );
// Labeling
std::stringstream ss;
ss << "Meff" << int( ps.meff_bins[imeff] );
// New canvas for plots
TCanvas* c1 = 0;
if (draw) c1 = new TCanvas( TString("Canvas"+ss.str()), "" );
// Pad for cross-section plot
TPad* pad = 0;
if (draw) pad = new TPad(TString("Pad"+ss.str()),"",0.,0.,1.,1.);
if (pad) {
pad->SetGrid();
pad->Draw();
pad->cd();
pad->SetLogz();
}
TH1F* hr = 0;
if (draw) hr = pad->DrawFrame(ps.min,ps.min,ps.max,ps.max);
// Histo title
if (hr) {
std::stringstream sss;
sss << "M_{eff}=" << ps.meff_bins[imeff] << " GeV"
<< ", p_{T1}=" << dr(ps.pt1_bins[imeff],1) << " GeV"
<< ", p_{T2}=" << dr(ps.pt2_bins[imeff],1) << " GeV"
<< ", p_{T3}=" << dr(ps.pt3_bins[imeff],1) << " GeV";
hr->SetTitle( sss.str().c_str() );
hr->GetXaxis()->SetTitle( "x_{2}" );
hr->GetYaxis()->SetTitle( "x_{1}" );
}
// Create 2D cross-section plot
TH2D* his = 0;
if (draw) his = new TH2D(TString("Histo"+ss.str()),"",
ps.nbins,ps.min,ps.max,
ps.nbins,ps.min,ps.max);
//double x3 = ( 2. * ps.pt3_bins[imeff] ) / ( ps.meff_bins[imeff] + ps.pt3_bins[imeff] );
// Fill 2D cross-section plot
for ( int x2_bin = 0; x2_bin < ps.nbins; ++x2_bin ) {
for ( int x1_bin = 0; x1_bin < ps.nbins; ++x1_bin ) {
// std::cout << " Fill:"
// << " x2_bin: " << x2_bin
// << " x2: " << val(x2_bin,nbins)
// << " x1_bin: " << x1_bin
// << " x1: " << val(x1_bin,nbins)
// << " val: " << dalitz[x2_bin][x1_bin]
// << std::endl;
if (his) his->Fill( val(x2_bin,ps)+ps.width/2.,
val(x1_bin,ps)+ps.width/2.,
dalitz[x2_bin][x1_bin] );
}
}
// Draw 2D cross-section plot
gStyle->SetPalette(1);
if (his) {
//his->SetMaximum( his->GetMaximum()*10. );
//his->SetMinimum( his->GetMinimum(1.e-12)*0.1 );
// his->SetMaximum( 1.e9 );
// his->SetMinimum( 1.e0 );
his->Draw("COLZsame");
}
// Pad for AlphaT contours
if (c1) c1->cd();
TPad* overlay = 0;
if (draw) overlay = new TPad(TString("Overlay"+ss.str()),"",0.,0.,1.,1.);
if (overlay) {
overlay->SetFillStyle(4000);
overlay->SetFillColor(0);
overlay->SetFrameFillStyle(4000);
overlay->Draw();
overlay->cd();
}
//TH1F* hframe = 0;
if (draw) overlay->DrawFrame(pad->GetUxmin(),
pad->GetUymin(),
pad->GetUxmax(),
pad->GetUymax());
// Graphs of AlphaT contours
TMultiGraph* mg = 0;
if (draw) {
mg = new TMultiGraph();
for ( Int_t icut = 0; icut < (int)ps.cutValues.size(); icut++ ) {
Double_t alpha_t = ps.cutValues[icut];
const Int_t n = ps.nbins;
DoubleV x1(n,0.);
DoubleV x2(n,0.);
for ( Int_t x2_bin = 0; x2_bin < ps.nbins; x2_bin++ ) {
x2[x2_bin] = x2_bin * ps.width;
x1[x2_bin] = cutAlgoInverse(ps.cutValues[icut],x2[x2_bin],ALGO_TYPE);
}
TGraph* gr = new TGraph(n,&x2.front(),&x1.front());
mg->Add(gr,"l");
}
mg->Draw();
}
if (c1) c1->cd();
if (c1) c1->SaveAs(TString(ss.str()+".png"));
if (c1) c1->SaveAs(TString(ss.str()+".pdf"));
if (c1) c1->SaveAs(TString(ss.str()+".C"));
}
// Canvas for ratio vs Meff
if (false) {
TCanvas* c2 = new TCanvas( "c2", "" );
c2->SetRightMargin(0.2);
c2->SetLogy();
c2->cd();
TMultiGraph* mg2 = new TMultiGraph();
DoubleV err( ps.nmeff, 0. );
for ( Int_t icut = 0; icut < (int)ps.cutValues.size(); icut++ ) {
if ( length[icut] == 0 ) { continue; }
// TGraphAsymmErrors* gr = new TGraphAsymmErrors( length[icut],
// &ps.meff_bins.front(),
// &err.front(),
// &err.front(),
// &ratio[icut].front(),
// &ratio_errl[icut].front(),
// &ratio_errh[icut].front() );
TGraph* gr = new TGraphAsymmErrors( length[icut],
&ps.meff_bins.front(),
&ratio[icut].front() );
std::stringstream ss;
ss << "a_{T}=" << ps.cutValues[icut];
// << " Meff=" << meff_bins[imeff]
// << ", p_{T3}=" << pt3_bins[imeff];
mg2->Add(gr,"lp");
gr->SetTitle(TString(ss.str()));
gr->SetLineColor(2+icut);
gr->SetLineWidth(2);
gr->SetMarkerStyle(20+icut);
gr->SetMarkerColor(2+icut);
gr->SetMarkerSize(1.5);
}
mg2->Draw("a");
mg2->GetYaxis()->SetRangeUser(1.e-6,1.e0);
c2->Update();
c2->BuildLegend(0.81,0.1,0.99,0.9);
// Save canvases
c2->cd();
c2->SaveAs("RatioVsMeff.png");
c2->SaveAs("RatioVsMeff.pdf");
c2->SaveAs("RatioVsMeff.C");
}
time_t stop = TTimeStamp().GetSec();
std::cout << " Time taken: " << stop - start << " seconds" << std::endl;
}
void composeTrackAnalysisbyAssociator(string FileListName, int FileNumber) {
if(debug) cout << FileListName << endl;
string theFileName;
ifstream composeFileList;
composeFileList.open(FileListName.c_str());
string OutputPlotNamepreFix = FileListName + "_";
string OutputPlotNameFix = ".png";
unsigned int EventNumber;
unsigned int trackingParticleMatch;
double recTrackPurity;
double recTrackrefMomentum;
double recTrackrefPhi;
double recTrackrefEta;
double recTrackinnerMomentum;
double recTrackinnerPhi;
double recTrackinnerEta;
unsigned int recTrackinnerValid;
double recTrackouterMomentum;
double recTrackouterPhi;
double recTrackouterEta;
unsigned int recTrackouterValid;
double simTrackinnerMomentum;
double simTrackinnerPhi;
double simTrackinnerEta;
unsigned int simTrackinnerMatch;
double simTrackouterMomentum;
double simTrackouterPhi;
double simTrackouterEta;
unsigned int simTrackouterMatch;
double recTrackinnerMomentumofTSOS;
double recTrackinnerPhiofTSOS;
double recTrackinnerEtaofTSOS;
unsigned int recTrackinnerValidofTSOS;
double recTrackouterMomentumofTSOS;
double recTrackouterPhiofTSOS;
double recTrackouterEtaofTSOS;
unsigned int recTrackouterValidofTSOS;
double recTrackimpactMomentumofTSOS;
double recTrackimpactPhiofTSOS;
double recTrackimpactEtaofTSOS;
unsigned int recTrackimpactValidofTSOS;
int recTrackCharge;
double simTrackMomentumPt;
double simTrackPhi;
double simTrackEta;
int simTrackCharge;
TObjArray* myEfficiencyHist = new TObjArray();
TObjArray* myParticleHist = new TObjArray();
TObjArray* mySTAHist = new TObjArray();
TObjArray* myChargeCheckHist = new TObjArray();
TObjArray* myDeltaPtHist = new TObjArray();
TObjArray* myDeltaPhiHist = new TObjArray();
TObjArray* myDeltaEtaHist = new TObjArray();
vector<string> TypeName;
TypeName.clear();
for(int Index = 0; Index < FileNumber; Index++) {
getline(composeFileList, theFileName);
TypeName.push_back(theFileName);
string fullFileName = "data/"+ theFileName + ".root";
if(debug) cout << theFileName << endl;
TFile* RootFile = TFile::Open(fullFileName.c_str());
TTree* T1 = (TTree*)RootFile->Get("ExTree");
T1->SetBranchAddress("EventNumber", &EventNumber);
T1->SetBranchAddress("trackingParticleMatch", &trackingParticleMatch);
T1->SetBranchAddress("recTrackPurity", &recTrackPurity);
T1->SetBranchAddress("recTrackrefMomentum", &recTrackrefMomentum);
T1->SetBranchAddress("recTrackrefPhi", &recTrackrefPhi);
T1->SetBranchAddress("recTrackrefEta", &recTrackrefEta);
T1->SetBranchAddress("recTrackinnerMomentum", &recTrackinnerMomentum);
T1->SetBranchAddress("recTrackinnerPhi", &recTrackinnerPhi);
T1->SetBranchAddress("recTrackinnerEta", &recTrackinnerEta);
T1->SetBranchAddress("recTrackinnerValid", &recTrackinnerValid);
T1->SetBranchAddress("recTrackouterMomentum", &recTrackouterMomentum);
T1->SetBranchAddress("recTrackouterPhi", &recTrackouterPhi);
T1->SetBranchAddress("recTrackouterEta", &recTrackouterEta);
T1->SetBranchAddress("recTrackouterValid", &recTrackouterValid);
T1->SetBranchAddress("simTrackinnerMomentum", &simTrackinnerMomentum);
T1->SetBranchAddress("simTrackinnerPhi", &simTrackinnerPhi);
T1->SetBranchAddress("simTrackinnerEta", &simTrackinnerEta);
T1->SetBranchAddress("simTrackinnerMatch", &simTrackinnerMatch);
T1->SetBranchAddress("simTrackouterMomentum", &simTrackouterMomentum);
T1->SetBranchAddress("simTrackouterPhi", &simTrackouterPhi);
T1->SetBranchAddress("simTrackouterEta", &simTrackouterEta);
T1->SetBranchAddress("simTrackouterMatch", &simTrackouterMatch);
T1->SetBranchAddress("recTrackinnerMomentumofTSOS", &recTrackinnerMomentumofTSOS);
T1->SetBranchAddress("recTrackinnerPhiofTSOS", &recTrackinnerPhiofTSOS);
T1->SetBranchAddress("recTrackinnerEtaofTSOS", &recTrackinnerEtaofTSOS);
T1->SetBranchAddress("recTrackinnerValidofTSOS", &recTrackinnerValidofTSOS);
T1->SetBranchAddress("recTrackouterMomentumofTSOS", &recTrackouterMomentumofTSOS);
T1->SetBranchAddress("recTrackouterPhiofTSOS", &recTrackouterPhiofTSOS);
T1->SetBranchAddress("recTrackouterEtaofTSOS", &recTrackouterEtaofTSOS);
T1->SetBranchAddress("recTrackouterValidofTSOS", &recTrackouterValidofTSOS);
T1->SetBranchAddress("recTrackimpactMomentumofTSOS", &recTrackimpactMomentumofTSOS);
T1->SetBranchAddress("recTrackimpactPhiofTSOS", &recTrackimpactPhiofTSOS);
T1->SetBranchAddress("recTrackimpactEtaofTSOS", &recTrackimpactEtaofTSOS);
T1->SetBranchAddress("recTrackimpactValidofTSOS", &recTrackimpactValidofTSOS);
T1->SetBranchAddress("recTrackCharge", &recTrackCharge);
T1->SetBranchAddress("simTrackMomentumPt", &simTrackMomentumPt);
T1->SetBranchAddress("simTrackPhi", &simTrackPhi);
T1->SetBranchAddress("simTrackEta", &simTrackEta);
T1->SetBranchAddress("simTrackCharge", &simTrackCharge);
string TempHistName;
TempHistName = theFileName + "_Efficiency2simPt";
TH1D* Efficiency2simPtHist = new TH1D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale);
TempHistName = theFileName + "_Particle2simPt";
TH1D* Particle2simPtHist = new TH1D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale);
TempHistName = theFileName + "_STA2simPt";
TH1D* STA2simPtHist = new TH1D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale);
TempHistName = theFileName + "_InverseChargeRato2simPt";
TH1D* InverseChargeRato2simPtHist = new TH1D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale);
TempHistName = theFileName + "_DeltaPt2simPt";
TH1D* DeltaPt2simPtHist = new TH1D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale);
TempHistName = theFileName + "_DeltaPhi2simPt";
TH1D* DeltaPhi2simPtHist = new TH1D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale);
TempHistName = theFileName + "_DeltaEta2simPt";
TH1D* DeltaEta2simPtHist = new TH1D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale);
TempHistName = theFileName + "_MaxPurity2simPt";
TH2D* MaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 6, 0., 1.2);
TempHistName = theFileName + "_Multiplicity2simPt";
TH2D* Multiplicity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 10, 0., 10.);
TempHistName = theFileName + "_ChargeCheck2simPt";
TH2D* ChargeCheck2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 5, -2.5, 2.5);
TempHistName = theFileName + "_simTrackMomentumPtmaxPurity2simPt";
TH2D* simTrackMomentumPtmaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, (int)5*PtScale, 0, PtScale);
TempHistName = theFileName + "_simTrackPhimaxPurity2simPt";
TH2D* simTrackPhimaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 314, -PI, PI);
TempHistName = theFileName + "_simTrackEtamaxPurity2simPt";
TH2D* simTrackEtamaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 400, -2.0, 2.0);
TempHistName = theFileName + "_recTrackimpactMomentumofTSOSmaxPurity2simPt";
TH2D* recTrackimpactMomentumofTSOSmaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, (int)5*PtScale, 0, PtScale);
TempHistName = theFileName + "_recTrackimpactPhiofTSOSmaxPurity2simPt";
TH2D* recTrackimpactPhiofTSOSmaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 314, -PI, PI);
TempHistName = theFileName + "_recTrackimpactEtaofTSOSmaxPurity2simPt";
TH2D* recTrackimpactEtaofTSOSmaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 600, -3.0, 3.0);
TempHistName = theFileName + "_recTrackimpactValidofTSOSmaxPurity2simPt";
TH2D* recTrackimpactValidofTSOSmaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 2, 0., 2.);
TempHistName = theFileName + "_DeltaPtmaxPurity2simPt";
TH2D* DeltaPtmaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, (int)5*PtScale, -1.*PtScale, PtScale);
TempHistName = theFileName + "_DeltaPhimaxPurity2simPt";
TH2D* DeltaPhimaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 314, -PI, PI);
TempHistName = theFileName + "_DeltaEtamaxPurity2simPt";
TH2D* DeltaEtamaxPurity2simPtHist = new TH2D(TempHistName.c_str(), TempHistName.c_str(), (int)(PtScale/2), 0, PtScale, 400, -2.0, 2.0);
unsigned int trackingParticleMatch_temp;
unsigned int efficiency_temp;
double recTrackPurity_temp;
double recTrackrefMomentum_temp;
double recTrackrefPhi_temp;
double recTrackrefEta_temp;
double recTrackinnerMomentum_temp;
double recTrackinnerPhi_temp;
double recTrackinnerEta_temp;
unsigned int recTrackinnerValid_temp;
double recTrackouterMomentum_temp;
double recTrackouterPhi_temp;
double recTrackouterEta_temp;
unsigned int recTrackouterValid_temp;
double simTrackinnerMomentum_temp;
double simTrackinnerPhi_temp;
double simTrackinnerEta_temp;
unsigned int simTrackinnerMatch_temp;
double simTrackouterMomentum_temp;
double simTrackouterPhi_temp;
double simTrackouterEta_temp;
unsigned int simTrackouterMatch_temp;
double recTrackinnerMomentumofTSOS_temp;
double recTrackinnerPhiofTSOS_temp;
double recTrackinnerEtaofTSOS_temp;
unsigned int recTrackinnerValidofTSOS_temp;
double recTrackouterMomentumofTSOS_temp;
double recTrackouterPhiofTSOS_temp;
double recTrackouterEtaofTSOS_temp;
unsigned int recTrackouterValidofTSOS_temp;
double recTrackimpactMomentumofTSOS_temp;
double recTrackimpactPhiofTSOS_temp;
double recTrackimpactEtaofTSOS_temp;
unsigned int recTrackimpactValidofTSOS_temp;
int recTrackCharge_temp;
double simTrackMomentumPt_temp;
double simTrackPhi_temp;
double simTrackEta_temp;
int simTrackCharge_temp;
int Nentries = T1->GetEntries();
for(int i = 0; i < Nentries; i++) {
T1->GetEntry(i);
if(trackingParticleMatch == 0) {
MaxPurity2simPtHist->Fill(simTrackMomentumPt, 0);
Multiplicity2simPtHist->Fill(simTrackMomentumPt, 0);
int tempParticleBinNumber = Particle2simPtHist->FindBin(simTrackMomentumPt);
double tempParticleBinValue = Particle2simPtHist->GetBinContent(tempParticleBinNumber);
tempParticleBinValue += 1.;
Particle2simPtHist->SetBinContent(tempParticleBinNumber, tempParticleBinValue);
}
else {
efficiency_temp = 1;
trackingParticleMatch_temp = trackingParticleMatch;
recTrackPurity_temp = recTrackPurity;
recTrackrefMomentum_temp = recTrackrefMomentum;
recTrackrefPhi_temp = recTrackrefPhi;
recTrackrefEta_temp = recTrackrefEta;
recTrackinnerMomentum_temp = recTrackinnerMomentum;
recTrackinnerPhi_temp = recTrackinnerPhi;
recTrackinnerEta_temp = recTrackinnerEta;
recTrackinnerValid_temp = recTrackinnerValid;
recTrackouterMomentum_temp = recTrackouterMomentum;
recTrackouterPhi_temp = recTrackouterPhi;
recTrackouterEta_temp = recTrackouterEta;
recTrackouterValid_temp = recTrackouterValid;
simTrackinnerMomentum_temp = simTrackinnerMomentum;
simTrackinnerPhi_temp = simTrackinnerPhi;
simTrackinnerEta_temp = simTrackinnerEta;
simTrackinnerMatch_temp = simTrackinnerMatch;
simTrackouterMomentum_temp = simTrackouterMomentum;
simTrackouterPhi_temp = simTrackouterPhi;
simTrackouterEta_temp = simTrackouterEta;
simTrackouterMatch_temp = simTrackouterMatch;
recTrackinnerMomentumofTSOS_temp = recTrackinnerMomentumofTSOS;
recTrackinnerPhiofTSOS_temp = recTrackinnerPhiofTSOS;
recTrackinnerEtaofTSOS_temp = recTrackinnerEtaofTSOS;
recTrackinnerValidofTSOS_temp = recTrackinnerValidofTSOS;
recTrackouterMomentumofTSOS_temp = recTrackouterMomentumofTSOS;
recTrackouterPhiofTSOS_temp = recTrackouterPhiofTSOS;
recTrackouterEtaofTSOS_temp = recTrackouterEtaofTSOS;
recTrackouterValidofTSOS_temp = recTrackouterValidofTSOS;
recTrackimpactMomentumofTSOS_temp = recTrackimpactMomentumofTSOS;
recTrackimpactPhiofTSOS_temp = recTrackimpactPhiofTSOS;
recTrackimpactEtaofTSOS_temp = recTrackimpactEtaofTSOS;
recTrackimpactValidofTSOS_temp = recTrackimpactValidofTSOS;
recTrackCharge_temp = recTrackCharge;
simTrackMomentumPt_temp = simTrackMomentumPt;
simTrackPhi_temp = simTrackPhi;
simTrackEta_temp = simTrackEta;
simTrackCharge_temp = simTrackCharge;
bool nextStep = true;
while(nextStep) {
i++;
T1->GetEntry(i);
if(trackingParticleMatch <= trackingParticleMatch_temp)
nextStep = false;
else
trackingParticleMatch_temp = trackingParticleMatch;
if(nextStep == true && recTrackPurity_temp < recTrackPurity) {
if(debug) cout << "step another match, trackingParticleMatch_temp: " << trackingParticleMatch_temp << endl;
//trackingParticleMatch_temp = trackingParticleMatch;
recTrackPurity_temp = recTrackPurity;
recTrackrefMomentum_temp = recTrackrefMomentum;
recTrackrefPhi_temp = recTrackrefPhi;
recTrackrefEta_temp = recTrackrefEta;
recTrackinnerMomentum_temp = recTrackinnerMomentum;
recTrackinnerPhi_temp = recTrackinnerPhi;
recTrackinnerEta_temp = recTrackinnerEta;
recTrackinnerValid_temp = recTrackinnerValid;
recTrackouterMomentum_temp = recTrackouterMomentum;
recTrackouterPhi_temp = recTrackouterPhi;
recTrackouterEta_temp = recTrackouterEta;
recTrackouterValid_temp = recTrackouterValid;
simTrackinnerMomentum_temp = simTrackinnerMomentum;
simTrackinnerPhi_temp = simTrackinnerPhi;
simTrackinnerEta_temp = simTrackinnerEta;
simTrackinnerMatch_temp = simTrackinnerMatch;
simTrackouterMomentum_temp = simTrackouterMomentum;
simTrackouterPhi_temp = simTrackouterPhi;
simTrackouterEta_temp = simTrackouterEta;
simTrackouterMatch_temp = simTrackouterMatch;
recTrackinnerMomentumofTSOS_temp = recTrackinnerMomentumofTSOS;
recTrackinnerPhiofTSOS_temp = recTrackinnerPhiofTSOS;
recTrackinnerEtaofTSOS_temp = recTrackinnerEtaofTSOS;
recTrackinnerValidofTSOS_temp = recTrackinnerValidofTSOS;
recTrackouterMomentumofTSOS_temp = recTrackouterMomentumofTSOS;
recTrackouterPhiofTSOS_temp = recTrackouterPhiofTSOS;
recTrackouterEtaofTSOS_temp = recTrackouterEtaofTSOS;
recTrackouterValidofTSOS_temp = recTrackouterValidofTSOS;
recTrackimpactMomentumofTSOS_temp = recTrackimpactMomentumofTSOS;
recTrackimpactPhiofTSOS_temp = recTrackimpactPhiofTSOS;
recTrackimpactEtaofTSOS_temp = recTrackimpactEtaofTSOS;
recTrackimpactValidofTSOS_temp = recTrackimpactValidofTSOS;
recTrackCharge_temp = recTrackCharge;
simTrackMomentumPt_temp = simTrackMomentumPt;
simTrackPhi_temp = simTrackPhi;
simTrackEta_temp = simTrackEta;
simTrackCharge_temp = simTrackCharge;
}
}
i--;
//if(debug) cout << "Filling Multiplicity " << trackingParticleMatch_temp << endl;
MaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, recTrackPurity_temp);
Multiplicity2simPtHist->Fill(simTrackMomentumPt_temp, trackingParticleMatch_temp);
ChargeCheck2simPtHist->Fill(simTrackMomentumPt_temp, simTrackCharge_temp*recTrackCharge_temp);
simTrackMomentumPtmaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, simTrackMomentumPt_temp);
simTrackPhimaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, simTrackPhi_temp);
simTrackEtamaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, simTrackEta_temp);
recTrackimpactMomentumofTSOSmaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, recTrackimpactMomentumofTSOS_temp);
recTrackimpactPhiofTSOSmaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, recTrackimpactPhiofTSOS_temp);
recTrackimpactEtaofTSOSmaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, recTrackimpactEtaofTSOS_temp);
recTrackimpactValidofTSOSmaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, recTrackimpactValidofTSOS_temp);
DeltaPtmaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, (recTrackimpactMomentumofTSOS_temp-simTrackMomentumPt_temp)/simTrackMomentumPt_temp);
DeltaPhimaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, recTrackimpactPhiofTSOS_temp-simTrackPhi_temp);
DeltaEtamaxPurity2simPtHist->Fill(simTrackMomentumPt_temp, recTrackimpactEtaofTSOS_temp-simTrackEta_temp);
int tempParticleBinNumber = STA2simPtHist->FindBin(simTrackMomentumPt_temp);
double tempParticleBinValue = Particle2simPtHist->GetBinContent(tempParticleBinNumber);
tempParticleBinValue += 1.;
Particle2simPtHist->SetBinContent(tempParticleBinNumber, tempParticleBinValue);
double tempSTABinValue = STA2simPtHist->GetBinContent(tempParticleBinNumber);
tempSTABinValue += 1.;
STA2simPtHist->SetBinContent(tempParticleBinNumber, tempSTABinValue);
}
}
for(int PtIndex = 1; PtIndex <= (int)(PtScale/2); PtIndex++) {
double ParticleBinValue = Particle2simPtHist->GetBinContent(PtIndex);
double STABinValue = STA2simPtHist->GetBinContent(PtIndex);
if(ParticleBinValue == 0.)
ParticleBinValue += 1.;
double EfficiencyBinValue = STABinValue / ParticleBinValue * 100.;
double EfficiencyBinError = sqrt(EfficiencyBinValue * (100. - EfficiencyBinValue) / ParticleBinValue);
cout << ParticleBinValue << ", " << STABinValue << ", " << EfficiencyBinValue << endl;
Efficiency2simPtHist->SetBinContent(PtIndex, EfficiencyBinValue);
Efficiency2simPtHist->SetBinError(PtIndex, EfficiencyBinError);
TH1D* ChargeCheckHist = ChargeCheck2simPtHist->ProjectionY("ChargeCheck", PtIndex, PtIndex, "o");
double ReverseChargeBinValue = ChargeCheckHist->GetBinContent(2);
double CoverseChargeBinValue = ChargeCheckHist->GetBinContent(4);
double TotalChargeBinValue = ReverseChargeBinValue + CoverseChargeBinValue;
if(TotalChargeBinValue == 0.);
TotalChargeBinValue += 1.;
double ReverseChargeRato = ReverseChargeBinValue / TotalChargeBinValue;
InverseChargeRato2simPtHist->SetBinContent(PtIndex, ReverseChargeRato);
TH1D* DeltaPtHist = DeltaPtmaxPurity2simPtHist->ProjectionY("DeltaPt", PtIndex, PtIndex, "o");
double DeltaPtMean = DeltaPtHist->GetMean();
double DeltaPtRMS = DeltaPtHist->GetRMS();
DeltaPt2simPtHist->SetBinContent(PtIndex, DeltaPtMean);
DeltaPt2simPtHist->SetBinError(PtIndex, DeltaPtRMS);
TH1D* DeltaPhiHist = DeltaPhimaxPurity2simPtHist->ProjectionY("DeltaPhi", PtIndex, PtIndex, "o");
double DeltaPhiMean = DeltaPhiHist->GetMean();
double DeltaPhiRMS = DeltaPhiHist->GetRMS();
DeltaPhi2simPtHist->SetBinContent(PtIndex, DeltaPhiMean);
DeltaPhi2simPtHist->SetBinError(PtIndex, DeltaPhiRMS);
TH1D* DeltaEtaHist = DeltaEtamaxPurity2simPtHist->ProjectionY("DeltaEta", PtIndex, PtIndex, "o");
double DeltaEtaMean = DeltaEtaHist->GetMean();
double DeltaEtaRMS = DeltaEtaHist->GetRMS();
DeltaEta2simPtHist->SetBinContent(PtIndex, DeltaEtaMean);
DeltaEta2simPtHist->SetBinError(PtIndex, DeltaEtaRMS);
}
myEfficiencyHist->AddLast(Efficiency2simPtHist);
myParticleHist->AddLast(Particle2simPtHist);
mySTAHist->AddLast(STA2simPtHist);
myChargeCheckHist->AddLast(InverseChargeRato2simPtHist);
myDeltaPtHist->AddLast(DeltaPt2simPtHist);
}
double minX = 0;
double minY = 0;
double maxX = 110;
double maxY = 40;
TCanvas* myCanvas = new TCanvas("Canvas", "Canvas", 800, 600);
myCanvas->cd();
TPad* myPad = new TPad("Pad", "Pad", 0, 0, 1, 1);
myPad->Draw();
myPad->cd();
((TH1D*)(myParticleHist->At(0)))->SetStats(0);
((TH1D*)(myParticleHist->At(0)))->GetXaxis()->SetTitle("simPt/Gev");
((TH1D*)(myParticleHist->At(0)))->GetXaxis()->CenterTitle(1);
((TH1D*)(myParticleHist->At(0)))->Draw();
for(int Index = 0; Index < FileNumber; Index++) {
((TH1D*)(mySTAHist->At(Index)))->SetStats(0);
((TH1D*)(mySTAHist->At(Index)))->SetLineColor(kRed+Index);
((TH1D*)(mySTAHist->At(Index)))->Draw("same");
}
TLegend *STALeg = new TLegend(0.6,0.1,0.9,0.3);
STALeg->SetBorderSize(1);
TString LegKey = "ParticleTrack";
STALeg->AddEntry(myParticleHist->At(0), LegKey, "lpf");
for(int Index = 0; Index < FileNumber; Index++) {
LegKey = TypeName[Index];
STALeg->AddEntry(mySTAHist->At(Index), LegKey, "lpf");
}
STALeg->Draw();
string SaveName = OutputPlotNamepreFix + "_STA2simPt" + OutputPlotNameFix;
myCanvas->SaveAs(SaveName.c_str());
myPad->Clear();
myPad->Update();
double YScale = myPad->GetUymax() / 110.;
((TH1D*)(myEfficiencyHist->At(0)))->GetXaxis()->SetTitle("simPt/Gev");
((TH1D*)(myEfficiencyHist->At(0)))->GetXaxis()->CenterTitle(1);
((TH1D*)(myEfficiencyHist->At(0)))->SetStats(0);
((TH1D*)(myEfficiencyHist->At(0)))->Scale(YScale);
((TH1D*)(myEfficiencyHist->At(0)))->SetLineColor(kRed);
((TH1D*)(myEfficiencyHist->At(0)))->Draw("same,ah");
for(int Index = 1; Index < FileNumber; Index++) {
((TH1D*)(myEfficiencyHist->At(Index)))->SetStats(0);
((TH1D*)(myEfficiencyHist->At(Index)))->Scale(YScale);
((TH1D*)(myEfficiencyHist->At(Index)))->SetLineColor(kRed+Index);
((TH1D*)(myEfficiencyHist->At(Index)))->Draw("same,ah");
}
myPad->Update();
if(debug) cout << "Y: " << myPad->GetUymax() << endl;
double YAxisMinValue=((TH1D*)(myEfficiencyHist->At(0)))->GetYaxis()->GetXmin();
double YAxisMaxValue=((TH1D*)(myEfficiencyHist->At(0)))->GetYaxis()->GetXmax();
int YAxisNBins=((TH1D*)(myEfficiencyHist->At(0)))->GetYaxis()->GetNbins();
TGaxis* YAxis = new TGaxis(myPad->GetUxmin(), myPad->GetUymin(), myPad->GetUxmin(), myPad->GetUymax(), 0, 110, 510, "-R");
YAxis->SetLineColor(kGreen);
YAxis->SetLabelColor(kGreen);
YAxis->SetTitle("Efficiency of STA for simPts");
YAxis->CenterTitle(1);
YAxis->Draw();
double XAxisMinValue=((TH1D*)(myEfficiencyHist->At(0)))->GetXaxis()->GetXmin();
double XAxisMaxValue=((TH1D*)(myEfficiencyHist->At(0)))->GetXaxis()->GetXmax();
int XAxisNBins=((TH1D*)(myEfficiencyHist->At(0)))->GetXaxis()->GetNbins();
TGaxis* XAxis = new TGaxis(myPad->GetUxmin(), myPad->GetUymin(), myPad->GetUxmax(), myPad->GetUymin(), XAxisMinValue, XAxisMaxValue, 510, "+L");
XAxis->SetTitle("simPt/Gev");
XAxis->CenterTitle(1);
XAxis->Draw();
TLegend *EffLeg = new TLegend(0.1,0.9,0.4,1.0);
EffLeg->SetBorderSize(1);
for(int Index = 0; Index < FileNumber; Index++) {
TString LegKey = TypeName[Index];
EffLeg->AddEntry(myEfficiencyHist->At(Index), LegKey, "lpf");
}
EffLeg->Draw();
string SaveName = OutputPlotNamepreFix + "_Eff2simPt" + OutputPlotNameFix;
myCanvas->SaveAs(SaveName.c_str());
((TH1D*)(myDeltaPtHist->At(0)))->SetStats(0);
((TH1D*)(myDeltaPtHist->At(0)))->GetXaxis()->SetTitle("simPt/Gev");
((TH1D*)(myDeltaPtHist->At(0)))->GetXaxis()->CenterTitle(1);
((TH1D*)(myDeltaPtHist->At(0)))->GetYaxis()->SetTitle("deltPt/simPt");
((TH1D*)(myDeltaPtHist->At(0)))->GetYaxis()->CenterTitle(1);
((TH1D*)(myDeltaPtHist->At(0)))->SetLineColor(kRed);
((TH1D*)(myDeltaPtHist->At(0)))->Draw("");
for(int Index = 1; Index < FileNumber; Index++) {
((TH1D*)(myDeltaPtHist->At(Index)))->SetStats(0);
//((TH1D*)(myDeltaPtHist->At(Index)))->GetXaxis()->SetTitle("simPt/Gev");
//((TH1D*)(myDeltaPtHist->At(Index)))->GetXaxis()->CenterTitle(1);
//((TH1D*)(myDeltaPtHist->At(Index)))->GetYaxis()->SetTitle("deltPt/simPt");
//((TH1D*)(myDeltaPtHist->At(Index)))->GetYaxis()->CenterTitle(1);
((TH1D*)(myDeltaPtHist->At(Index)))->SetLineColor(kRed+Index);
((TH1D*)(myDeltaPtHist->At(Index)))->Draw("same");
//SaveName = OutputPlotNamepreFix + TypeName[Index] + "DeltaPt" + OutputPlotNameFix;
//myCanvas->SaveAs(SaveName.c_str());
}
TLegend *PtLeg = new TLegend(0.6,0.8,0.9,0.9);
PtLeg->SetBorderSize(1);
for(int Index = 0; Index < FileNumber; Index++) {
TString LegKey = TypeName[Index];
PtLeg->AddEntry(myDeltaPtHist->At(Index), LegKey, "lpf");
}
PtLeg->Draw();
SaveName = OutputPlotNamepreFix + "_DeltaPt" + OutputPlotNameFix;
myCanvas->SaveAs(SaveName.c_str());
}
// -----------------------------------------------------------------------------
//
void talk() {
time_t start = TTimeStamp().GetSec();
bool draw = true;
bool debug = true;
// Binning
int xbins = 100;
int ybins = 100;
double xmin = 0.0;
double xmax = 1.0;
double ymin = 0.0;
double ymax = 1.0;
double xbin_centre = ( ( xmax - xmin ) / xbins ) / 2.;
double ybin_centre = ( ( ymax - ymin ) / ybins ) / 2.;
// AlphaT values
const int nat = 1;
double at[nat];
for ( int ii = 0; ii < nat; ++ii ) { at[ii] = 0.55 + ii * 0.001; }
// HT regions
const int nht = 3;
double ht_min[nht] = { 250., 300., 350. };
// Jet pT thresholds
double pt1_min[nht] = { 71.4, 85.7, 100. };
double pt2_min[nht] = { 71.4, 85.7, 100. };
double pt3_min[nht] = { 35.7, 42.9., 50. };
// x fractions
double x1_min[nht];
double x2_min[nht];
double x3_max[nht];
for ( int ii = 0; ii < nht; ++ii ) { x1_min[ii] = ( 2. * pt1_min[ii]) / ( ht_min[ii] + pt3_min[ii] ); }
for ( int ii = 0; ii < nht; ++ii ) { x2_min[ii] = ( 2. * pt2_min[ii]) / ( ht_min[ii] + pt3_min[ii] ); }
for ( int ii = 0; ii < nht; ++ii ) { x3_max[ii] = ( 2. * pt3_min[ii]) / ( ht_min[ii] + pt3_min[ii] ); }
// Loop through bins
int loop = 0;
int nloops = nht;
for ( int iht = 0; iht < nht; ++iht ) {
std::cout << "Completed "
<< 100.*float(loop)/float(nloops)
<< "%..."
<< std::endl;
loop++;
// Labeling
std::stringstream ss;
ss << "HT" << int(ht_min[iht]);
// New canvas for plots
TCanvas* c1 = 0;
if (draw) c1 = new TCanvas( TString("Canvas"+ss.str()), "" );
// Pad for cross-section plot
TPad* pad = 0;
if (draw) pad = new TPad(TString("Pad"+ss.str()),"",0.,0.,1.,1.);
if (pad) {
pad->SetGrid();
pad->Draw();
pad->cd();
pad->SetLogz();
}
TH1F* hr = 0;
if (draw) hr = pad->DrawFrame(0.,0.,1.,1.);
// Histo title
if (hr) {
std::stringstream sss;
sss << "H_{T}=" << ht_min[iht]
<< "(p_{T1},p_{T2},p_{T3})="
<< pt1_min[iht] << ","
<< pt2_min[iht] << ","
<< pt3_min[iht] << ")"
<< ", (x_{1},x_{2},x_{3})="
<< x1_min[iht] << ","
<< x2_min[iht] << ","
<< x3_max[iht] << ")";
hr->SetTitle( sss.str().c_str() );
hr->GetXaxis()->SetTitle( "x_{2}" );
hr->GetYaxis()->SetTitle( "x_{1}" );
}
// Create 2D cross-section plot
TH2D* his = 0;
if (draw) his = new TH2D(TString("Histo"+ss.str()),"",
xbins,xmin,xmax,
ybins,ymin,ymax);
// Fill 2D cross-section plot
for ( int xbin = 0; xbin < xbins; ++xbin ) {
for ( int ybin = 0; ybin < ybins; ++ybin ) {
double x2 = ( ( xmax - xmin ) / xbins ) * xbin + xmin;
double x1 = ( ( ymax - ymin ) / ybins ) * ybin + ymin;
double val = ( x1*x1 + x2*x2 ) / ( ( 1 - x1 ) * ( 1 - x2 ) );
if ( !constrain( x1, x2, x3 ) ) { continue; }
if ( x1 < x1_cut[ix1] ) { continue; }
double alpha_t = x2 / ( 2 * sqrt(x1+x2-1) );
if (his) his->Fill( x2+xbin_centre, x1+ybin_centre, val );
}
}
// Draw 2D cross-section plot
gStyle->SetPalette(1);
if (his) {
his->SetMaximum( his->GetMaximum() );
his->SetMinimum( his->GetMinimum(1.e-12) );
his->Draw("COLZsame");
}
// Pad for AlphaT contours
if (c1) c1->cd();
TPad* overlay = 0;
if (draw) overlay = new TPad(TString("Overlay"+ss.str()),"",0.,0.,1.,1.);
if (overlay) {
overlay->SetFillStyle(4000);
overlay->SetFillColor(0);
overlay->SetFrameFillStyle(4000);
overlay->Draw();
overlay->cd();
}
TH1F* hframe = 0;
if (draw) overlay->DrawFrame(pad->GetUxmin(),
pad->GetUymin(),
pad->GetUxmax(),
pad->GetUymax());
// Graphs of AlphaT contours
TMultiGraph* mg = 0;
if (draw) {
mg = new TMultiGraph();
for ( Int_t iat = 0; iat < nat; iat++ ) {
Double_t alpha_t = at[iat];
const Int_t n_ = 100;
Double_t x1_[n_];
Double_t x2_[n_];
for ( Int_t j = 0; j < 100; j++ ) {
x2_[j] = j*0.01;
Double_t temp = ( x2_[j] - 2. * alpha_t * alpha_t ) / ( 2. * alpha_t );
x1_[j] = temp * temp + 1 - alpha_t * alpha_t;
}
TGraph* gr = new TGraph(n_,x2_,x1_);
mg->Add(gr,"l");
}
mg->Draw();
}
if (c1) c1->cd();
if (c1) c1->SaveAs(TString(ss.str()+".png"));
}
}
