7 #define BOOK1D(name,title,nbinsx,lowx,highx) \
8 h##name = dbe_ ? dbe_->book1D(#name,title,nbinsx,lowx,highx)->getTH1F() \
9 : new TH1F(#name,title,nbinsx,lowx,highx)
12 #define BOOK2D(name,title,nbinsx,lowx,highx,nbinsy,lowy,highy) \
13 h##name = dbe_ ? dbe_->book2D(#name,title,nbinsx,lowx,highx,nbinsy,lowy,highy)->getTH2F() \
14 : new TH2F(#name,title,nbinsx,lowx,highx,nbinsy,lowy,highy)
17 #define DBOOK1D(name,title,nbinsx,lowx,highx) \
18 BOOK1D(B##name,"Barrel "#title,nbinsx,lowx,highx); BOOK1D(E##name,"Endcap "#title,nbinsx,lowx,highx); BOOK1D(F##name,"Forward "#title,nbinsx,lowx,highx);
19 #define DBOOK2D(name,title,nbinsx,lowx,highx,nbinsy,lowy,highy) \
20 BOOK2D(B##name,"Barrel "#title,nbinsx,lowx,highx,nbinsy,lowy,highy); BOOK2D(E##name,"Endcap "#title,nbinsx,lowx,highx,nbinsy,lowy,highy); BOOK2D(F##name,"Forward "#title,nbinsx,lowx,highx,nbinsy,lowy,highy);
24 #define SETAXES(name,xtitle,ytitle) \
25 h##name->GetXaxis()->SetTitle(xtitle); h##name->GetYaxis()->SetTitle(ytitle)
28 #define DSETAXES(name,xtitle,ytitle) \
29 SETAXES(B##name,xtitle,ytitle);SETAXES(E##name,xtitle,ytitle);SETAXES(F##name,xtitle,ytitle);
34 #define PT (plotAgainstReco_)?"reconstructed P_{T}" :"generated P_{T}"
35 #define P (plotAgainstReco_)?"generated P" :"generated P"
54 cout <<
"Benchmark output written to file " <<
outputFile_.c_str() << endl;
59 cout <<
"No output file specified ("<<
outputFile_<<
"). Results will not be saved!" << endl;
83 cout<<
"PFJetBenchmark Setup parameters =============================================="<<endl;
84 cout <<
"Filename to write histograms " << Filename<<endl;
85 cout <<
"PFJetBenchmark debug " <<
debug_<< endl;
88 cout <<
"deltaRMax " << deltaRMax << endl;
89 cout <<
"benchmarkLabel " << benchmarkLabel_ << endl;
96 string path =
"PFTask/Benchmarks/"+ benchmarkLabel_ +
"/";
97 if (plotAgainstReco) path +=
"Reco";
else path +=
"Gen";
99 dbe_->setCurrentFolder(path.c_str());
105 cout <<
"Info: DQM is not available to provide data storage service. Using TFile to save histograms. "<<endl;
109 sprintf(cutString,
"Jet multiplicity P_{T}>%4.1f GeV",
recPt_cut);
110 BOOK1D(Njets,cutString,50, 0, 50);
112 BOOK1D(jetsPt,
"Jets P_{T} Distribution",100, 0, 500);
114 sprintf(cutString,
"Jets #eta Distribution |#eta|<%4.1f",
maxEta_cut);
115 BOOK1D(jetsEta,cutString,100, -5, 5);
117 BOOK2D(RPtvsEta,
"#DeltaP_{T}/P_{T} vs #eta",200, -5., 5., 200,-1,1);
118 BOOK2D(RNeutvsEta,
"R_{Neutral} vs #eta",200, -5., 5., 200,-1,1);
119 BOOK2D(RNEUTvsEta,
"R_{HCAL+ECAL} vs #eta",200, -5., 5., 200,-1,1);
120 BOOK2D(RNONLvsEta,
"R_{HCAL+ECAL - Hcal Only} vs #eta",200, -5., 5., 200,-1,1);
121 BOOK2D(RHCALvsEta,
"R_{HCAL} vs #eta",200, -5., 5., 200,-1,1);
122 BOOK2D(RHONLvsEta,
"R_{HCAL only} vs #eta",200, -5., 5., 200,-1,1);
123 BOOK2D(RCHEvsEta,
"R_{Charged} vs #eta",200, -5., 5., 200,-1,1);
124 BOOK2D(NCHvsEta,
"N_{Charged} vs #eta",200, -5., 5., 200,0.,200.);
125 BOOK2D(NCH0vsEta,
"N_{Charged} vs #eta, iter 0",200, -5., 5., 200,0.,200.);
126 BOOK2D(NCH1vsEta,
"N_{Charged} vs #eta, iter 1",200, -5., 5., 200,0.,200.);
127 BOOK2D(NCH2vsEta,
"N_{Charged} vs #eta, iter 2",200, -5., 5., 200,0.,200.);
128 BOOK2D(NCH3vsEta,
"N_{Charged} vs #eta, iter 3",200, -5., 5., 200,0.,200.);
129 BOOK2D(NCH4vsEta,
"N_{Charged} vs #eta, iter 4",200, -5., 5., 200,0.,200.);
130 BOOK2D(NCH5vsEta,
"N_{Charged} vs #eta, iter 5",200, -5., 5., 200,0.,200.);
131 BOOK2D(NCH6vsEta,
"N_{Charged} vs #eta, iter 6",200, -5., 5., 200,0.,200.);
132 BOOK2D(NCH7vsEta,
"N_{Charged} vs #eta, iter 7",200, -5., 5., 200,0.,200.);
135 DBOOK1D(RCHE,#DeltaE/E (charged had),80,-2,2);
136 DBOOK1D(RNHE,#DeltaE/E (neutral had),80,-2,2);
137 DBOOK1D(RNEE,#DeltaE/E (neutral em),80,-2,2);
138 DBOOK1D(Rneut,#DeltaE/E (neutral),80,-2,2);
140 DBOOK2D(RPtvsPt,#DeltaP_{
T}/P_{
T} vs P_{
T},250, 0, 500, 200,-1,1);
141 DBOOK2D(RCHEvsPt,#DeltaE/E (charged had) vs P_{
T},250, 0, 500, 120,-1,2);
142 DBOOK2D(RNHEvsPt,#DeltaE/E (neutral had) vs P_{
T},250, 0, 500, 120,-1,2);
143 DBOOK2D(RNEEvsPt,#DeltaE/E (neutral em) vs P_{
T},250, 0, 500, 120,-1,2);
144 DBOOK2D(RneutvsPt,#DeltaE/E (neutral) vs P_{
T},250, 0, 500, 120,-1,2);
145 DBOOK2D(NCHvsPt,N_{charged} vs P_{
T},250,0,500,200,0.,200.);
146 DBOOK2D(NCH0vsPt, N_{charged} vs P_{
T}
iter 0,250,0,500,200,0.,200.);
147 DBOOK2D(NCH1vsPt, N_{charged} vs P_{
T}
iter 1,250,0,500,200,0.,200.);
148 DBOOK2D(NCH2vsPt, N_{charged} vs P_{
T}
iter 2,250,0,500,200,0.,200.);
149 DBOOK2D(NCH3vsPt, N_{charged} vs P_{
T}
iter 3,250,0,500,200,0.,200.);
150 DBOOK2D(NCH4vsPt, N_{charged} vs P_{
T}
iter 4,250,0,500,200,0.,200.);
151 DBOOK2D(NCH5vsPt, N_{charged} vs P_{
T}
iter 5,250,0,500,200,0.,200.);
152 DBOOK2D(NCH6vsPt, N_{charged} vs P_{
T}
iter 6,250,0,500,200,0.,200.);
153 DBOOK2D(NCH7vsPt, N_{charged} vs P_{
T}
iter 7,250,0,500,200,0.,200.);
157 DBOOK2D(RNONLvsP,#DeltaE/E (
ECAL+
HCAL-only) vs P,250, 0, 1000, 150,-1.5,1.5);
158 DBOOK2D(RHCALvsP,#DeltaE/E (
HCAL) vs P,250, 0, 1000, 150,-1.5,1.5);
159 DBOOK2D(RHONLvsP,#DeltaE/E (
HCAL only) vs P,250, 0, 1000, 150,-1.5,1.5);
160 DBOOK1D(RPt20_40,#DeltaP_{
T}/P_{
T},80,-1,1);
161 DBOOK1D(RPt40_60,#DeltaP_{
T}/P_{
T},80,-1,1);
162 DBOOK1D(RPt60_80,#DeltaP_{
T}/P_{
T},80,-1,1);
163 DBOOK1D(RPt80_100,#DeltaP_{
T}/P_{
T},80,-1,1);
164 DBOOK1D(RPt100_150,#DeltaP_{
T}/P_{
T},80,-1,1);
165 DBOOK1D(RPt150_200,#DeltaP_{
T}/P_{
T},80,-1,1);
166 DBOOK1D(RPt200_250,#DeltaP_{
T}/P_{
T},80,-1,1);
167 DBOOK1D(RPt250_300,#DeltaP_{
T}/P_{
T},80,-1,1);
168 DBOOK1D(RPt300_400,#DeltaP_{
T}/P_{
T},160,-1,1);
169 DBOOK1D(RPt400_500,#DeltaP_{
T}/P_{
T},160,-1,1);
170 DBOOK1D(RPt500_750,#DeltaP_{
T}/P_{
T},160,-1,1);
171 DBOOK1D(RPt750_1250,#DeltaP_{
T}/P_{
T},160,-1,1);
172 DBOOK1D(RPt1250_2000,#DeltaP_{
T}/P_{
T},160,-1,1);
173 DBOOK1D(RPt2000_5000,#DeltaP_{
T}/P_{
T},160,-1,1);
175 DBOOK2D(DEtavsPt,#Delta#
eta vs P_{
T},1000,0,2000,500,-0.5,0.5);
176 DBOOK2D(DPhivsPt,#Delta#
phi vs P_{
T},1000,0,2000,500,-0.5,0.5);
177 BOOK2D(DEtavsEta,
"#Delta#eta vs P_{T}",1000,-5.,+5.,500,-0.5,0.5);
178 BOOK2D(DPhivsEta,
"#Delta#phi vs P_{T}",1000,-5.,+5.,500,-0.5,0.5);
183 SETAXES(Njets,
"",
"Multiplicity");
185 SETAXES(jetsEta,
"#eta",
"Number of Events");
186 SETAXES(RNeutvsEta,
"#eta",
"#DeltaE/E (Neutral)");
187 SETAXES(RNEUTvsEta,
"#eta",
"#DeltaE/E (ECAL+HCAL)");
188 SETAXES(RNONLvsEta,
"#eta",
"#DeltaE/E (ECAL+HCAL-only)");
189 SETAXES(RHCALvsEta,
"#eta",
"#DeltaE/E (HCAL)");
190 SETAXES(RHONLvsEta,
"#eta",
"#DeltaE/E (HCAL Only)");
191 SETAXES(RCHEvsEta,
"#eta",
"#DeltaE/E (Charged)");
192 SETAXES(RPtvsEta,
"#eta",
"#DeltaP_{T}/P_{T}");
193 SETAXES(DEtavsEta,
"#eta",
"#Delta#eta");
194 SETAXES(DPhivsEta,
"#eta",
"#Delta#phi");
196 DSETAXES(RPt,
"#DeltaP_{T}/P_{T}",
"Events");
197 DSETAXES(RPt20_40,
"#DeltaP_{T}/P_{T}",
"Events");
198 DSETAXES(RPt40_60,
"#DeltaP_{T}/P_{T}",
"Events");
199 DSETAXES(RPt60_80,
"#DeltaP_{T}/P_{T}",
"Events");
200 DSETAXES(RPt80_100,
"#DeltaP_{T}/P_{T}",
"Events");
201 DSETAXES(RPt100_150,
"#DeltaP_{T}/P_{T}",
"Events");
202 DSETAXES(RPt150_200,
"#DeltaP_{T}/P_{T}",
"Events");
203 DSETAXES(RPt200_250,
"#DeltaP_{T}/P_{T}",
"Events");
204 DSETAXES(RPt250_300,
"#DeltaP_{T}/P_{T}",
"Events");
205 DSETAXES(RPt300_400,
"#DeltaP_{T}/P_{T}",
"Events");
206 DSETAXES(RPt400_500,
"#DeltaP_{T}/P_{T}",
"Events");
207 DSETAXES(RPt500_750,
"#DeltaP_{T}/P_{T}",
"Events");
208 DSETAXES(RPt750_1250,
"#DeltaP_{T}/P_{T}",
"Events");
209 DSETAXES(RPt1250_2000,
"#DeltaP_{T}/P_{T}",
"Events");
210 DSETAXES(RPt2000_5000,
"#DeltaP_{T}/P_{T}",
"Events");
211 DSETAXES(RCHE,
"#DeltaE/E(charged had)",
"Events");
212 DSETAXES(RNHE,
"#DeltaE/E(neutral had)",
"Events");
213 DSETAXES(RNEE,
"#DeltaE/E(neutral em)",
"Events");
214 DSETAXES(Rneut,
"#DeltaE/E(neutral)",
"Events");
216 DSETAXES(RCHEvsPt,
PT,
"#DeltaE/E(charged had)");
217 DSETAXES(RNHEvsPt,
PT,
"#DeltaE/E(neutral had)");
218 DSETAXES(RNEEvsPt,
PT,
"#DeltaE/E(neutral em)");
219 DSETAXES(RneutvsPt,
PT,
"#DeltaE/E(neutral)");
220 DSETAXES(RHCALvsP, P,
"#DeltaE/E(HCAL)");
221 DSETAXES(RHONLvsP, P,
"#DeltaE/E(HCAL-only)");
222 DSETAXES(RNEUTvsP, P,
"#DeltaE/E(ECAL+HCAL)");
223 DSETAXES(RNONLvsP, P,
"#DeltaE/E(ECAL+HCAL-only)");
238 for(
unsigned i=0;
i<pfJets.size();
i++) {
241 unsigned highJets = 0;
242 for(
unsigned j=0;
j<pfJets.size();
j++) {
243 if (
j !=
i && pfJets[
j].
pt() > pfJets[
i].pt() ) highJets++;
249 double rec_pt = pfj.
pt();
250 double rec_eta = pfj.
eta();
251 double rec_phi = pfj.
phi();
268 bool Forward =
false;
269 if (
std::abs(rec_eta) < 1.4 ) Barrel =
true;
287 double true_E = truth->
p();
288 double true_pt = truth->
pt();
289 double true_eta = truth->
eta();
290 double true_phi = truth->
phi();
293 else {pt_denom = true_pt;}
295 double true_ChargedHadEnergy;
296 double true_NeutralHadEnergy;
297 double true_NeutralEmEnergy;
298 gettrue (truth, true_ChargedHadEnergy, true_NeutralHadEnergy, true_NeutralEmEnergy);
299 double true_NeutralEnergy = true_NeutralHadEnergy + true_NeutralEmEnergy;
303 double rec_NeutralEnergy = rec_NeutralHadEnergy + rec_NeutralEmEnergy;
306 std::vector <unsigned int> chMult(9, static_cast<unsigned int>(0));
307 for (
unsigned ic = 0; ic < constituents.size (); ++ic) {
308 if ( constituents[ic]->particleId() > 3 )
continue;
310 if ( trackRef.
isNull() ) {
316 unsigned int iter = 0;
317 switch (trackRef->algo()) {
322 case TrackBase::lowPtTripletStep:
325 case TrackBase::pixelPairStep:
337 case TrackBase::tobTecStep:
340 case TrackBase::conversionStep:
347 std::cout <<
"Warning in entry " <<
entry_ <<
" : iter = " << trackRef->algo() << std::endl;
348 std::cout << ic <<
" " << *(constituents[ic]) << std::endl;
361 double cut1 = 0.0001;
362 double cut2 = 0.0001;
363 double cut3 = 0.0001;
364 double cut4 = 0.0001;
365 double cut5 = 0.0001;
366 double cut6 = 0.0001;
367 double cut7 = 0.0001;
369 double resChargedHadEnergy= 0.;
370 double resNeutralHadEnergy= 0.;
371 double resNeutralEmEnergy= 0.;
372 double resNeutralEnergy= 0.;
374 double resHCALEnergy = 0.;
375 double resNEUTEnergy = 0.;
376 if ( rec_NeutralHadEnergy > cut6 && rec_ChargedHadEnergy < cut1 ) {
377 double true_NEUTEnergy = true_NeutralHadEnergy + true_NeutralEmEnergy;
378 double true_HCALEnergy = true_NEUTEnergy - rec_NeutralEmEnergy;
379 double rec_NEUTEnergy = rec_NeutralHadEnergy+rec_NeutralEmEnergy;
380 double rec_HCALEnergy = rec_NeutralHadEnergy;
381 resHCALEnergy = (rec_HCALEnergy-true_HCALEnergy)/rec_HCALEnergy;
382 resNEUTEnergy = (rec_NEUTEnergy-true_NEUTEnergy)/rec_NEUTEnergy;
383 if ( rec_NeutralEmEnergy > cut7 ) {
391 if (true_pt > 0.0001){
392 resPt = (rec_pt -true_pt)/true_pt ;
394 if (true_ChargedHadEnergy > cut1){
395 resChargedHadEnergy = (rec_ChargedHadEnergy- true_ChargedHadEnergy)/true_ChargedHadEnergy;
397 if (true_NeutralHadEnergy > cut2){
398 resNeutralHadEnergy = (rec_NeutralHadEnergy- true_NeutralHadEnergy)/true_NeutralHadEnergy;
401 if (rec_NeutralHadEnergy > cut3){
402 resNeutralHadEnergy = (rec_NeutralHadEnergy- true_NeutralHadEnergy)/rec_NeutralHadEnergy;
404 if (true_NeutralEmEnergy > cut4){
405 resNeutralEmEnergy = (rec_NeutralEmEnergy- true_NeutralEmEnergy)/true_NeutralEmEnergy;
407 if (true_NeutralEnergy > cut5){
408 resNeutralEnergy = (rec_NeutralEnergy- true_NeutralEnergy)/true_NeutralEnergy;
415 if ( ( resPt > 0.2 && true_pt > 100. ) ||
416 ( resPt < -0.5 && true_pt > 100. ) ) {
421 <<
" resPt = " << resPt
422 <<
" resCharged " << resChargedHadEnergy
423 <<
" resNeutralHad " << resNeutralHadEnergy
424 <<
" resNeutralEm " << resNeutralEmEnergy
425 <<
" pT (T/R) " << true_pt <<
"/" << rec_pt
426 <<
" Eta (T/R) " << truth->
eta() <<
"/" << rec_eta
427 <<
" Phi (T/R) " << truth->
phi() <<
"/" << rec_phi
433 for(
unsigned j=0;
j<pfJets.size();
j++) {
445 for(
unsigned j=0;
j<genJets.size();
j++) {
447 if ( gjo != truth &&
algo_->
deltaR(truth,gjo) < dRgo && gjo->
pt() > 0.25*truth->
pt() ) {
454 std::cout <<
"Excess probably due to overlapping jets (DR = " <<
algo_->
deltaR(genoj,pfoj) <<
"),"
455 <<
" at DeltaR(T/R) = " << dRgo <<
"/" << dRo
456 <<
" with pT(T/R) " << genoj->
pt() <<
"/" << pfoj->
pt()
457 <<
" and Eta (T/R) " << genoj->
eta() <<
"/" << pfoj->
eta()
458 <<
" and Phi (T/R) " << genoj->
phi() <<
"/" << pfoj->
phi()
467 cout <<
i <<
" =========PFJet Pt "<< rec_pt
468 <<
" eta " << rec_eta
469 <<
" phi " << rec_phi
470 <<
" Charged Had Energy " << rec_ChargedHadEnergy
471 <<
" Neutral Had Energy " << rec_NeutralHadEnergy
472 <<
" Neutral elm Energy " << rec_NeutralEmEnergy << endl;
473 cout <<
" matching Gen Jet Pt " << true_pt
474 <<
" eta " << truth->
eta()
475 <<
" phi " << truth->
phi()
476 <<
" Charged Had Energy " << true_ChargedHadEnergy
477 <<
" Neutral Had Energy " << true_NeutralHadEnergy
478 <<
" Neutral elm Energy " << true_NeutralEmEnergy << endl;
484 cout <<
"==============deltaR " << deltaR <<
" resPt " << resPt
485 <<
" resChargedHadEnergy " << resChargedHadEnergy
486 <<
" resNeutralHadEnergy " << resNeutralHadEnergy
487 <<
" resNeutralEmEnergy " << resNeutralEmEnergy
500 hNCHvsEta->Fill(true_eta, rec_ChargedMultiplicity);
510 if(plot2)
hRCHEvsEta->Fill(true_eta, resChargedHadEnergy);
511 if(plot5)
hRNeutvsEta->Fill(true_eta, resNeutralEnergy);
526 if ( pt_denom > 20. && pt_denom < 40. )
hBRPt20_40->Fill (resPt);
527 if ( pt_denom > 40. && pt_denom < 60. )
hBRPt40_60->Fill (resPt);
528 if ( pt_denom > 60. && pt_denom < 80. )
hBRPt60_80->Fill (resPt);
529 if ( pt_denom > 80. && pt_denom < 100. )
hBRPt80_100->Fill (resPt);
530 if ( pt_denom > 100. && pt_denom < 150. )
hBRPt100_150->Fill (resPt);
531 if ( pt_denom > 150. && pt_denom < 200. )
hBRPt150_200->Fill (resPt);
532 if ( pt_denom > 200. && pt_denom < 250. )
hBRPt200_250->Fill (resPt);
533 if ( pt_denom > 250. && pt_denom < 300. )
hBRPt250_300->Fill (resPt);
534 if ( pt_denom > 300. && pt_denom < 400. )
hBRPt300_400->Fill (resPt);
535 if ( pt_denom > 400. && pt_denom < 500. )
hBRPt400_500->Fill (resPt);
536 if ( pt_denom > 500. && pt_denom < 750. )
hBRPt500_750->Fill (resPt);
537 if ( pt_denom > 750. && pt_denom < 1250. )
hBRPt750_1250->Fill (resPt);
538 if ( pt_denom > 1250. && pt_denom < 2000. )
hBRPt1250_2000->Fill (resPt);
539 if ( pt_denom > 2000. && pt_denom < 5000. )
hBRPt2000_5000->Fill (resPt);
540 hBNCH->Fill(rec_ChargedMultiplicity);
549 hBNCHvsPt->Fill(pt_denom,rec_ChargedMultiplicity);
556 if(plot2)
hBRCHE->Fill(resChargedHadEnergy);
557 if(plot3)
hBRNHE->Fill(resNeutralHadEnergy);
558 if(plot4)
hBRNEE->Fill(resNeutralEmEnergy);
559 if(plot5)
hBRneut->Fill(resNeutralEnergy);
560 if(plot1)
hBRPtvsPt->Fill(pt_denom, resPt);
561 if(plot2)
hBRCHEvsPt->Fill(pt_denom, resChargedHadEnergy);
562 if(plot3)
hBRNHEvsPt->Fill(pt_denom, resNeutralHadEnergy);
563 if(plot4)
hBRNEEvsPt->Fill(pt_denom, resNeutralEmEnergy);
564 if(plot5)
hBRneutvsPt->Fill(pt_denom, resNeutralEnergy);
579 if ( pt_denom > 20. && pt_denom < 40. )
hERPt20_40->Fill (resPt);
580 if ( pt_denom > 40. && pt_denom < 60. )
hERPt40_60->Fill (resPt);
581 if ( pt_denom > 60. && pt_denom < 80. )
hERPt60_80->Fill (resPt);
582 if ( pt_denom > 80. && pt_denom < 100. )
hERPt80_100->Fill (resPt);
583 if ( pt_denom > 100. && pt_denom < 150. )
hERPt100_150->Fill (resPt);
584 if ( pt_denom > 150. && pt_denom < 200. )
hERPt150_200->Fill (resPt);
585 if ( pt_denom > 200. && pt_denom < 250. )
hERPt200_250->Fill (resPt);
586 if ( pt_denom > 250. && pt_denom < 300. )
hERPt250_300->Fill (resPt);
587 if ( pt_denom > 300. && pt_denom < 400. )
hERPt300_400->Fill (resPt);
588 if ( pt_denom > 400. && pt_denom < 500. )
hERPt400_500->Fill (resPt);
589 if ( pt_denom > 500. && pt_denom < 750. )
hERPt500_750->Fill (resPt);
590 if ( pt_denom > 750. && pt_denom < 1250. )
hERPt750_1250->Fill (resPt);
591 if ( pt_denom > 1250. && pt_denom < 2000. )
hERPt1250_2000->Fill (resPt);
592 if ( pt_denom > 2000. && pt_denom < 5000. )
hERPt2000_5000->Fill (resPt);
593 hENCH->Fill(rec_ChargedMultiplicity);
594 hENCHvsPt->Fill(pt_denom,rec_ChargedMultiplicity);
609 if(plot2)
hERCHE->Fill(resChargedHadEnergy);
610 if(plot3)
hERNHE->Fill(resNeutralHadEnergy);
611 if(plot4)
hERNEE->Fill(resNeutralEmEnergy);
612 if(plot5)
hERneut->Fill(resNeutralEnergy);
613 if(plot1)
hERPtvsPt->Fill(pt_denom, resPt);
614 if(plot2)
hERCHEvsPt->Fill(pt_denom, resChargedHadEnergy);
615 if(plot3)
hERNHEvsPt->Fill(pt_denom, resNeutralHadEnergy);
616 if(plot4)
hERNEEvsPt->Fill(pt_denom, resNeutralEmEnergy);
617 if(plot5)
hERneutvsPt->Fill(pt_denom, resNeutralEnergy);
631 if ( pt_denom > 20. && pt_denom < 40. )
hFRPt20_40->Fill (resPt);
632 if ( pt_denom > 40. && pt_denom < 60. )
hFRPt40_60->Fill (resPt);
633 if ( pt_denom > 60. && pt_denom < 80. )
hFRPt60_80->Fill (resPt);
634 if ( pt_denom > 80. && pt_denom < 100. )
hFRPt80_100->Fill (resPt);
635 if ( pt_denom > 100. && pt_denom < 150. )
hFRPt100_150->Fill (resPt);
636 if ( pt_denom > 150. && pt_denom < 200. )
hFRPt150_200->Fill (resPt);
637 if ( pt_denom > 200. && pt_denom < 250. )
hFRPt200_250->Fill (resPt);
638 if ( pt_denom > 250. && pt_denom < 300. )
hFRPt250_300->Fill (resPt);
639 if ( pt_denom > 300. && pt_denom < 400. )
hFRPt300_400->Fill (resPt);
640 if ( pt_denom > 400. && pt_denom < 500. )
hFRPt400_500->Fill (resPt);
641 if ( pt_denom > 500. && pt_denom < 750. )
hFRPt500_750->Fill (resPt);
642 if ( pt_denom > 750. && pt_denom < 1250. )
hFRPt750_1250->Fill (resPt);
643 if ( pt_denom > 1250. && pt_denom < 2000. )
hFRPt1250_2000->Fill (resPt);
644 if ( pt_denom > 2000. && pt_denom < 5000. )
hFRPt2000_5000->Fill (resPt);
651 if(plot2)
hFRCHE->Fill(resChargedHadEnergy);
652 if(plot3)
hFRNHE->Fill(resNeutralHadEnergy);
653 if(plot4)
hFRNEE->Fill(resNeutralEmEnergy);
654 if(plot5)
hFRneut->Fill(resNeutralEnergy);
655 if(plot1)
hFRPtvsPt->Fill(pt_denom, resPt);
656 if(plot2)
hFRCHEvsPt->Fill(pt_denom, resChargedHadEnergy);
657 if(plot3)
hFRNHEvsPt->Fill(pt_denom, resNeutralHadEnergy);
658 if(plot4)
hFRNEEvsPt->Fill(pt_denom, resNeutralEmEnergy);
659 if(plot5)
hFRneutvsPt->Fill(pt_denom, resNeutralEnergy);
678 double& true_NeutralHadEnergy,
double& true_NeutralEmEnergy){
680 true_NeutralEmEnergy = 0.;
681 true_ChargedHadEnergy = 0.;
682 true_NeutralHadEnergy = 0.;
684 for (
unsigned i = 0;
i < mcparts.size ();
i++) {
690 true_NeutralEmEnergy +=
e;
696 true_ChargedHadEnergy +=
e;
702 true_NeutralHadEnergy +=
e;
710 cout<<setiosflags(ios::right);
711 cout<<setiosflags(ios::fixed);
712 cout<<setprecision(3);
714 cout <<
"PFJet p/px/py/pz/pt: " << pfj->
p() <<
"/" << pfj->
px ()
715 <<
"/" << pfj->
py() <<
"/" << pfj->
pz() <<
"/" << pfj->
pt() << endl
716 <<
" eta/phi: " << pfj->
eta () <<
"/" << pfj->
phi () << endl
717 <<
" PFJet specific:" << std::endl
726 cout<<resetiosflags(ios::right|ios::fixed);
732 cout <<
"GenJet p/px/py/pz/pt: " << truth->
p() <<
'/' << truth->
px ()
733 <<
'/' << truth->
py() <<
'/' << truth->
pz() <<
'/' << truth->
pt() << endl
734 <<
" eta/phi: " << truth->
eta () <<
'/' << truth->
phi () << endl
735 <<
" # of constituents: " << mcparts.size() << endl;
736 cout <<
" constituents:" << endl;
737 for (
unsigned i = 0;
i < mcparts.size ();
i++) {
739 cout <<
" #" <<
i <<
" PDG code:" << mcpart->
pdgId()
740 <<
", p/pt/eta/phi: " << mcpart->
p() <<
'/' << mcpart->
pt()
741 <<
'/' << mcpart->
eta() <<
'/' << mcpart->
phi() << endl;
virtual int pdgId() const
PDG identifier.
virtual double p() const
magnitude of momentum vector
#define BOOK1D(name, title, nbinsx, lowx, highx)
float chargedEmEnergy() const
chargedEmEnergy
std::vector< GenJet > GenJetCollection
collection of GenJet objects
#define SETAXES(name, xtitle, ytitle)
int chargedMultiplicity() const
chargedMultiplicity
Jets made from PFObjects.
virtual double eta() const
momentum pseudorapidity
virtual double pt() const
transverse momentum
float neutralEmEnergy() const
neutralEmEnergy
virtual ~PFJetBenchmark()
void gettrue(const reco::GenJet *truth, double &true_ChargedHadEnergy, double &true_NeutralHadEnergy, double &true_NeutralEmEnergy)
XYZTLorentzVectorD XYZTLorentzVector
Lorentz vector with cylindrical internal representation using pseudorapidity.
virtual double energy() const
energy
void setup(std::string Filename, bool debug, bool plotAgainstReco=0, bool onlyTwoJets=1, double deltaRMax=0.1, std::string benchmarkLabel_="ParticleFlow", double recPt=-1, double maxEta=-1, DQMStore *dbe_store=NULL)
#define BOOK2D(name, title, nbinsx, lowx, highx, nbinsy, lowy, highy)
tuple path
else: Piece not in the list, fine.
virtual std::string print() const
Print object in details.
static double deltaR(const T *, const U *)
#define DBOOK2D(name, title, nbinsx, lowx, highx, nbinsy, lowy, highy)
Abs< T >::type abs(const T &t)
Jets made from MC generator particles.
virtual std::vector< const GenParticle * > getGenConstituents() const
get all constituents
bool isNull() const
Checks for null.
int neutralMultiplicity() const
neutralMultiplicity
void process(const reco::PFJetCollection &, const reco::GenJetCollection &)
double deltaR(double eta1, double eta2, double phi1, double phi2)
tuple detachedTripletStep
double resChargedHadEnergyMax_
static const Collection::value_type * matchByDeltaR(const T *, const Collection *)
virtual double px() const
x coordinate of momentum vector
virtual double pz() const
z coordinate of momentum vector
std::vector< PFJet > PFJetCollection
collection of PFJet objects
double resNeutralHadEnergyMax_
void printPFJet(const reco::PFJet *)
virtual std::vector< reco::PFCandidatePtr > getPFConstituents() const
get all constituents
float neutralHadronEnergy() const
neutralHadronEnergy
float chargedMuEnergy() const
chargedMuEnergy
double resNeutralEmEnergyMax_
#define DSETAXES(name, xtitle, ytitle)
virtual double phi() const
momentum azimuthal angle
void printGenJet(const reco::GenJet *)
#define DBOOK1D(name, title, nbinsx, lowx, highx)
float chargedHadronEnergy() const
chargedHadronEnergy
virtual double py() const
y coordinate of momentum vector