CMS 3D CMS Logo

 All Classes Namespaces Files Functions Variables Typedefs Enumerations Enumerator Properties Friends Macros Pages
BasicGenParticleValidation.cc
Go to the documentation of this file.
1 /*class BasicGenParticleValidation
2  *
3  * Class to fill dqm monitor elements from existing EDM file
4  *
5  */
6 
8 
9 #include "CLHEP/Units/defs.h"
10 #include "CLHEP/Units/PhysicalConstants.h"
11 
12 using namespace edm;
13 
15  wmanager_(iPSet,consumesCollector()),
16  hepmcCollection_(iPSet.getParameter<edm::InputTag>("hepmcCollection")),
17  genparticleCollection_(iPSet.getParameter<edm::InputTag>("genparticleCollection")),
18  genjetCollection_(iPSet.getParameter<edm::InputTag>("genjetsCollection")),
19  matchPr_(iPSet.getParameter<double>("matchingPrecision")),
20  verbosity_(iPSet.getUntrackedParameter<unsigned int>("verbosity",0))
21 {
22 
23  hepmcCollectionToken_=consumes<HepMCProduct>(hepmcCollection_);
24  genparticleCollectionToken_=consumes<reco::GenParticleCollection>(genparticleCollection_);
25  genjetCollectionToken_=consumes<reco::GenJetCollection>(genjetCollection_);
26 
27 }
28 
30 
31 
32 
35  i.setCurrentFolder("Generator/GenParticles");
36 
38 
39  // Number of analyzed events
40  nEvt = i.book1D("nEvt", "n analyzed Events", 1, 0., 1.);
41 
43  genPMultiplicity = i.book1D("genPMultiplicty", "Log(No. all GenParticles)", 50, -1, 5); //Log
44  //difference in HepMC and reco multiplicity
45  genMatched = i.book1D("genMatched", "Difference reco - matched", 50, -25, 25);
46  //multiple matching
47  multipleMatching = i.book1D("multipleMatching", "multiple reco HepMC matching", 50, 0, 50);
48  //momentum difference of matched particles
49  matchedResolution = i.book1D("matchedResolution", "log10(momentum difference of matched particles)", 70, -10., -3.);
50 
51  // GenJet general distributions
52  genJetMult = i.book1D("genJetMult", "GenJet multiplicity", 50, 0, 50);
53  genJetEnergy = i.book1D("genJetEnergy", "Log10(GenJet energy)", 60, -1, 5);
54  genJetPt = i.book1D("genJetPt", "Log10(GenJet pt)", 60, -1, 5);
55  genJetEta = i.book1D("genJetEta", "GenJet eta", 220, -11, 11);
56  genJetPhi = i.book1D("genJetPhi", "GenJet phi", 360, -180, 180);
57  genJetDeltaEtaMin = i.book1D("genJetDeltaEtaMin", "GenJet minimum rapidity gap", 30, 0, 30);
58 
59  genJetPto1 = i.book1D("genJetPto1", "GenJet multiplicity above 1 GeV", 50, 0, 50);
60  genJetPto10 = i.book1D("genJetPto10", "GenJet multiplicity above 10 GeV", 50, 0, 50);
61  genJetPto100 = i.book1D("genJetPto100", "GenJet multiplicity above 100 GeV", 50, 0, 50);
62  genJetCentral = i.book1D("genJetCentral", "GenJet multiplicity |eta|.lt.2.5", 50, 0, 50);
63 
64  genJetTotPt = i.book1D("genJetTotPt", "Log10(GenJet total pt)", 100, -5, 5);
65 
66  return;
67 }
68 
70 {
71 
72  unsigned int initSize = 1000;
73 
76  iEvent.getByToken(hepmcCollectionToken_, evt);
77 
78  //Get HepMC EVENT
79  HepMC::GenEvent *myGenEvent = new HepMC::GenEvent(*(evt->GetEvent()));
80 
81  double weight = wmanager_.weight(iEvent);
82 
83  nEvt->Fill(0.5, weight);
84 
85  std::vector<const HepMC::GenParticle*> hepmcGPCollection;
86  std::vector<int> barcodeList;
87  hepmcGPCollection.reserve(initSize);
88  barcodeList.reserve(initSize);
89 
90  //Looping through HepMC::GenParticle collection to search for status 1 particles
91  for (HepMC::GenEvent::particle_const_iterator iter = myGenEvent->particles_begin(); iter != myGenEvent->particles_end(); ++iter){
92  if ( (*iter)->status() == 1) {
93  hepmcGPCollection.push_back(*iter);
94  barcodeList.push_back((*iter)->barcode());
95  if ( verbosity_ > 0 ) {
96  std::cout << "HepMC " << std::setw(14) << std::fixed << (*iter)->pdg_id() << std::setw(14) << std::fixed << (*iter)->momentum().px() << std::setw(14) << std::fixed
97  << (*iter)->momentum().py() << std::setw(14) << std::fixed << (*iter)->momentum().pz() << std::endl;
98  }
99  }
100  }
101 
102 
103  // Gather information on the reco::GenParticle collection
105  iEvent.getByToken(genparticleCollectionToken_, genParticles );
106 
107  std::vector<const reco::GenParticle*> particles;
108  particles.reserve(initSize);
109  for (reco::GenParticleCollection::const_iterator iter=genParticles->begin();iter!=genParticles->end();++iter){
110  if ( (*iter).status() == 1) {
111  particles.push_back(&*iter);
112  if ( verbosity_ > 0 ) {
113  std::cout << "reco " << std::setw(14) << std::fixed << (*iter).pdgId() << std::setw(14) << std::fixed << (*iter).px()
114  << std::setw(14) << std::fixed << (*iter).py() << std::setw(14) << std::fixed << (*iter).pz() << std::endl;
115  }
116  }
117  }
118 
119  unsigned int nReco = particles.size();
120  unsigned int nHepMC = hepmcGPCollection.size();
121 
122  genPMultiplicity->Fill(std::log10(nReco), weight);
123 
124  // Define vector containing index of hepmc corresponding to the reco::GenParticle
125  std::vector<int> hepmcMatchIndex;
126  hepmcMatchIndex.reserve(initSize);
127 
128  // Matching procedure
129 
130  // Check array size consistency
131 
132  if ( nReco != nHepMC ) {
133  edm::LogWarning("CollectionSizeInconsistency") << "Collection size inconsistency: HepMC::GenParticle = " << nHepMC << " reco::GenParticle = " << nReco;
134  }
135 
136  // Match each HepMC with a reco
137 
138  for ( unsigned int i = 0; i < nReco; ++i ){
139  for ( unsigned int j = 0; j < nHepMC; ++j ){
140  if ( matchParticles( hepmcGPCollection[j], particles[i] ) ) {
141  hepmcMatchIndex.push_back((int)j);
142  if ( hepmcGPCollection[j]->momentum().rho() != 0. ) {
143  double reso = 1.-particles[i]->p()/hepmcGPCollection[j]->momentum().rho();
144  if ( verbosity_ > 0 ) {
145  std::cout << "Matching momentum: reco = " << particles[i]->p() << " HepMC = "
146  << hepmcGPCollection[j]->momentum().rho() << " resoultion = " << reso << std::endl;
147  }
148  matchedResolution->Fill(std::log10(std::fabs(reso)),weight); }
149  continue;
150  }
151  }
152  }
153 
154  // Check unicity of matching
155 
156  unsigned int nMatched = hepmcMatchIndex.size();
157 
158  if ( nMatched != nReco ) {
159  edm::LogWarning("IncorrectMatching") << "Incorrect number of matched indexes: GenParticle = " << nReco << " matched indexes = " << nMatched;
160  }
161  genMatched->Fill(int(nReco-nMatched),weight);
162 
163  unsigned int nWrMatch = 0;
164 
165  for ( unsigned int i = 0; i < nMatched; ++i ){
166  for (unsigned int j = i+1; j < nMatched; ++j ){
167  if ( hepmcMatchIndex[i] == hepmcMatchIndex[j] ) {
168  int theIndex = hepmcMatchIndex[i];
169  edm::LogWarning("DuplicatedMatching") << "Multiple matching occurencies for GenParticle barcode = " << barcodeList[theIndex];
170  nWrMatch++;
171  }
172  }
173  }
174  multipleMatching->Fill(int(nWrMatch),weight);
175 
176  // Gather information in the GenJet collection
178  iEvent.getByToken(genjetCollectionToken_, genJets );
179 
180  int nJets = 0;
181  int nJetso1 = 0;
182  int nJetso10 = 0;
183  int nJetso100 = 0;
184  int nJetsCentral = 0;
185  double totPt = 0.;
186 
187  std::vector<double> jetEta;
188  jetEta.reserve(initSize);
189 
190  for (reco::GenJetCollection::const_iterator iter=genJets->begin();iter!=genJets->end();++iter){
191  nJets++;
192  double pt = (*iter).pt();
193  totPt += pt;
194  if (pt > 1.) nJetso1++;
195  if (pt > 10.) nJetso10++;
196  if (pt > 100.) nJetso100++;
197  double eta = (*iter).eta();
198  if ( std::fabs(eta) < 2.5 ) nJetsCentral++;
199  jetEta.push_back(eta);
200 
201  genJetEnergy->Fill(std::log10((*iter).energy()),weight);
202  genJetPt->Fill(std::log10(pt),weight);
203  genJetEta->Fill(eta,weight);
204  genJetPhi->Fill((*iter).phi()/CLHEP::degree,weight);
205  }
206 
207  genJetMult->Fill(nJets,weight);
208  genJetPto1->Fill(nJetso1,weight);
209  genJetPto10->Fill(nJetso10,weight);
210  genJetPto100->Fill(nJetso100,weight);
211  genJetCentral->Fill(nJetsCentral,weight);
212 
213  genJetTotPt->Fill(std::log10(totPt),weight);
214 
215  double deltaEta = 999.;
216  if ( jetEta.size() > 1 ) {
217  for (unsigned int i = 0; i < jetEta.size(); i++){
218  for (unsigned int j = i+1; j < jetEta.size(); j++){
219  deltaEta = std::min(deltaEta,std::fabs(jetEta[i]-jetEta[j]));
220  }
221  }
222  }
223 
224  genJetDeltaEtaMin->Fill(deltaEta,weight);
225 
226  delete myGenEvent;
227 }//analyze
228 
230 
231  bool state = false;
232 
233  if ( hepmcP->pdg_id() != recoP->pdgId() ) return state;
234  if ( std::fabs(hepmcP->momentum().px()-recoP->px()) < std::fabs(matchPr_*hepmcP->momentum().px()) &&
235  std::fabs(hepmcP->momentum().py()-recoP->py()) < std::fabs(matchPr_*hepmcP->momentum().py()) &&
236  std::fabs(hepmcP->momentum().pz()-recoP->pz()) < std::fabs(matchPr_*hepmcP->momentum().pz())) {
237  state = true; }
238 
239  return state;
240 
241 }
int i
Definition: DBlmapReader.cc:9
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:434
virtual int pdgId() const GCC11_FINAL
PDG identifier.
Definition: DDAxes.h:10
theIndex(0)
bool matchParticles(const HepMC::GenParticle *&, const reco::GenParticle *&)
T eta() const
virtual double pz() const GCC11_FINAL
z coordinate of momentum vector
virtual double py() const GCC11_FINAL
y coordinate of momentum vector
void Fill(long long x)
int iEvent
Definition: GenABIO.cc:230
edm::EDGetTokenT< reco::GenJetCollection > genjetCollectionToken_
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:113
virtual double px() const GCC11_FINAL
x coordinate of momentum vector
int j
Definition: DBlmapReader.cc:9
edm::EDGetTokenT< edm::HepMCProduct > hepmcCollectionToken_
void setCurrentFolder(const std::string &fullpath)
Definition: DQMStore.cc:274
virtual void analyze(const edm::Event &, const edm::EventSetup &) override
virtual void bookHistograms(DQMStore::IBooker &i, edm::Run const &, edm::EventSetup const &) override
tuple cout
Definition: gather_cfg.py:121
BasicGenParticleValidation(const edm::ParameterSet &)
int weight
Definition: histoStyle.py:50
double weight(const edm::Event &)
edm::EDGetTokenT< reco::GenParticleCollection > genparticleCollectionToken_
Definition: Run.h:41