#include <TtHadEvtSolutionMaker.h>
Public Member Functions | |
virtual void | produce (edm::Event &iEvent, const edm::EventSetup &iSetup) |
TtHadEvtSolutionMaker (const edm::ParameterSet &iConfig) | |
constructor | |
~TtHadEvtSolutionMaker () | |
destructor | |
Private Attributes | |
bool | addLRJetComb_ |
bool | addLRSignalSel_ |
std::vector< unsigned int > | constraints_ |
bool | doKinFit_ |
int | jetCorrScheme_ |
int | jetParam_ |
edm::InputTag | jetSrc_ |
std::string | lrJetCombFile_ |
std::vector< int > | lrJetCombObs_ |
std::string | lrSignalSelFile_ |
std::vector< int > | lrSignalSelObs_ |
int | matchingAlgo_ |
bool | matchToGenEvt_ |
double | maxDeltaS_ |
double | maxDist_ |
double | maxF_ |
int | maxNrIter_ |
TtFullHadKinFitter * | myKinFitter |
TtHadLRJetCombCalc * | myLRJetCombCalc |
TtHadLRJetCombObservables * | myLRJetCombObservables |
TtHadLRSignalSelCalc * | myLRSignalSelCalc |
TtHadLRSignalSelObservables * | myLRSignalSelObservables |
TtHadSimpleBestJetComb * | mySimpleBestJetComb |
bool | useDeltaR_ |
bool | useMaxDist_ |
Definition at line 27 of file TtHadEvtSolutionMaker.h.
TtHadEvtSolutionMaker::TtHadEvtSolutionMaker | ( | const edm::ParameterSet & | iConfig | ) | [explicit] |
constructor
Definition at line 19 of file TtHadEvtSolutionMaker.cc.
References addLRJetComb_, addLRSignalSel_, constraints_, doKinFit_, edm::ParameterSet::getParameter(), jetCorrScheme_, jetParam_, jetSrc_, lrJetCombFile_, lrJetCombObs_, lrSignalSelFile_, lrSignalSelObs_, matchingAlgo_, matchToGenEvt_, maxDeltaS_, maxDist_, maxF_, maxNrIter_, myKinFitter, myLRJetCombCalc, myLRJetCombObservables, myLRSignalSelCalc, myLRSignalSelObservables, mySimpleBestJetComb, useDeltaR_, and useMaxDist_.
{ // configurables jetSrc_ = iConfig.getParameter<edm::InputTag> ("jetSource"); jetCorrScheme_ = iConfig.getParameter<int> ("jetCorrectionScheme"); doKinFit_ = iConfig.getParameter<bool> ("doKinFit"); addLRSignalSel_ = iConfig.getParameter<bool> ("addLRSignalSel"); lrSignalSelObs_ = iConfig.getParameter<std::vector<int> >("lrSignalSelObs"); lrSignalSelFile_ = iConfig.getParameter<std::string> ("lrSignalSelFile"); addLRJetComb_ = iConfig.getParameter<bool> ("addLRJetComb"); lrJetCombObs_ = iConfig.getParameter<std::vector<int> >("lrJetCombObs"); lrJetCombFile_ = iConfig.getParameter<std::string> ("lrJetCombFile"); maxNrIter_ = iConfig.getParameter<int> ("maxNrIter"); maxDeltaS_ = iConfig.getParameter<double> ("maxDeltaS"); maxF_ = iConfig.getParameter<double> ("maxF"); jetParam_ = iConfig.getParameter<int> ("jetParametrisation"); constraints_ = iConfig.getParameter<std::vector<unsigned int> >("constraints"); matchToGenEvt_ = iConfig.getParameter<bool> ("matchToGenEvt"); matchingAlgo_ = iConfig.getParameter<bool> ("matchingAlgorithm"); useMaxDist_ = iConfig.getParameter<bool> ("useMaximalDistance"); useDeltaR_ = iConfig.getParameter<bool> ("useDeltaR"); maxDist_ = iConfig.getParameter<double> ("maximalDistance"); // define kinfitter if(doKinFit_){ myKinFitter = new TtFullHadKinFitter(jetParam_, maxNrIter_, maxDeltaS_, maxF_, constraints_); } // define jet combinations related calculators mySimpleBestJetComb = new TtHadSimpleBestJetComb(); myLRSignalSelObservables = new TtHadLRSignalSelObservables(); myLRJetCombObservables = new TtHadLRJetCombObservables(); if (addLRJetComb_) myLRJetCombCalc = new TtHadLRJetCombCalc(lrJetCombFile_, lrJetCombObs_); // instantiate signal selection calculator if (addLRSignalSel_) myLRSignalSelCalc = new TtHadLRSignalSelCalc(lrSignalSelFile_, lrSignalSelObs_); // define what will be produced produces<std::vector<TtHadEvtSolution> >(); }
TtHadEvtSolutionMaker::~TtHadEvtSolutionMaker | ( | ) |
destructor
Definition at line 63 of file TtHadEvtSolutionMaker.cc.
References addLRJetComb_, addLRSignalSel_, doKinFit_, myKinFitter, myLRJetCombCalc, myLRJetCombObservables, myLRSignalSelCalc, myLRSignalSelObservables, and mySimpleBestJetComb.
{ if (doKinFit_) { delete myKinFitter; } delete mySimpleBestJetComb; delete myLRSignalSelObservables; delete myLRJetCombObservables; if(addLRSignalSel_) delete myLRSignalSelCalc; if(addLRJetComb_) delete myLRJetCombCalc; }
void TtHadEvtSolutionMaker::produce | ( | edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [virtual] |
Implements edm::EDProducer.
Definition at line 76 of file TtHadEvtSolutionMaker.cc.
References TtFullHadKinFitter::addKinFitInfo(), addLRJetComb_, addLRSignalSel_, gather_cfg::cout, doKinFit_, TtGenEvtProducer_cfi::genEvt, EgammaValidation_cff::genp, edm::Event::getByLabel(), JetPartonMatching::getDistanceForParton(), JetPartonMatching::getMatchForParton(), JetPartonMatching::getSumDistances(), i, j, jetCorrScheme_, jetParam_, analyzePatCleaning_cfg::jets, jetSrc_, gen::k, matchingAlgo_, matchToGenEvt_, maxDist_, myKinFitter, AlCaHLTBitMon_ParallelJobs::p, edm::Event::put(), lumiQueryAPI::q, asciidump::s, TtHadEvtSolution::setJetParametrisation(), useDeltaR_, and useMaxDist_.
{ // TopObject Selection // Select Jets bool jetsFound = false; edm::Handle<std::vector<pat::Jet> > jets; iEvent.getByLabel(jetSrc_, jets); if (jets->size() >= 6) jetsFound = true; // Build Event solutions according to the ambiguity in the jet combination // Note, hardcoded to only run through the 6 most energetic jets - could be changed .... std::vector<TtHadEvtSolution> * evtsols = new std::vector<TtHadEvtSolution>(); if(jetsFound){ for (unsigned int p=0; p<3; p++) { // loop over light jet p for (unsigned int q=p+1; q<4; q++) { // loop over light jet q for (unsigned int j=q+1; j<5; j++) { // loop over light jet j for (unsigned int k=j+1; k<6; k++) { // loop over light jet k for (unsigned int bh=0; bh!=jets->size(); bh++) { //loop over hadronic b-jet1 if(!(bh==p || bh==q || bh==j || bh==k)) { for (unsigned int bbarh=0; bbarh!=jets->size(); bbarh++) { //loop over hadronic b-jet2 if (!(bbarh==p || bbarh==q || bbarh==j || bbarh==k) && !(bbarh==bh)) { // Make event solutions for all possible combinations of the 4 light // jets and 2 possible b-jets, not including the option of the b's being swapped. // Hadp,Hadq is one pair, Hadj,Hadk the other std::vector<TtHadEvtSolution> asol; asol.resize(3); //[p][q][b] and [j][k][bbar] asol[0].setJetCorrectionScheme(jetCorrScheme_); asol[0].setHadp(jets, p); asol[0].setHadq(jets, q); asol[0].setHadj(jets, j); asol[0].setHadk(jets, k); asol[0].setHadb(jets, bh); asol[0].setHadbbar(jets, bbarh); //[p][j][b] and [q][k][bbar] asol[1].setJetCorrectionScheme(jetCorrScheme_); asol[1].setHadp(jets, p); asol[1].setHadq(jets, j); asol[1].setHadj(jets, q); asol[1].setHadk(jets, k); asol[1].setHadb(jets, bh); asol[1].setHadbbar(jets, bbarh); //[p][k][b] and [j][q][bbar] asol[2].setJetCorrectionScheme(jetCorrScheme_); asol[2].setHadp(jets, p); asol[2].setHadq(jets, k); asol[2].setHadj(jets, j); asol[2].setHadk(jets, q); asol[2].setHadb(jets, bh); asol[2].setHadbbar(jets, bbarh); if(doKinFit_){ for(unsigned int i=0;i!=asol.size();i++){ asol[i] = myKinFitter->addKinFitInfo(&(asol[i])); asol[i].setJetParametrisation(jetParam_); } }else{ std::cout<<"Fitting needed to decide on best solution, enable fitting!"<<std::endl; } // these lines calculate the observables to be used in the TtHadSignalSelection LR for(unsigned int i=0;i!=asol.size();i++){ (*myLRSignalSelObservables)(asol[i]); } // if asked for, calculate with these observable values the LRvalue and // (depending on the configuration) probability this event is signal if(addLRSignalSel_){ for(unsigned int i=0;i!=asol.size();i++){ (*myLRSignalSelCalc)(asol[i]); } } // these lines calculate the observables to be used in the TtHadJetCombination LR for(unsigned int i=0;i!=asol.size();i++){ (*myLRJetCombObservables)(asol[i]); } // if asked for, calculate with these observable values the LRvalue and // (depending on the configuration) probability a jet combination is correct if(addLRJetComb_){ for(unsigned int i=0;i!=asol.size();i++){ (*myLRJetCombCalc)(asol[i]); } } //std::cout<<"SignalSelLRval = "<<asol.getLRSignalEvtLRval()<<" JetCombProb = "<<asol.getLRSignalEvtProb()<<std::endl; //std::cout<<"JetCombLRval = "<<asol.getLRJetCombLRval()<<" JetCombProb = "<<asol.getLRJetCombProb()<<std::endl; // fill solution to vector with all possible solutions for(unsigned int i=0;i!=asol.size();i++){ evtsols->push_back(asol[i]); } } } } } } } } } // add TtHadSimpleBestJetComb to solutions int simpleBestJetComb = (*mySimpleBestJetComb)(*evtsols); for(size_t s=0; s<evtsols->size(); s++){ (*evtsols)[s].setSimpleBestJetComb(simpleBestJetComb); // if asked for, match the event solutions to the gen Event if(matchToGenEvt_){ int bestSolution = -999; int bestSolutionChangeW1Q = -999; int bestSolutionChangeW2Q = -999; edm::Handle<TtGenEvent> genEvt; iEvent.getByLabel ("genEvt",genEvt); std::vector<const reco::Candidate*> quarks; const reco::Candidate & genp = *(genEvt->daughterQuarkOfWPlus()); const reco::Candidate & genq = *(genEvt->daughterQuarkBarOfWPlus()); const reco::Candidate & genb = *(genEvt->b()); const reco::Candidate & genj = *(genEvt->daughterQuarkOfWMinus()); const reco::Candidate & genk = *(genEvt->daughterQuarkBarOfWMinus()); const reco::Candidate & genbbar = *(genEvt->bBar()); quarks.push_back( &genp ); quarks.push_back( &genq ); quarks.push_back( &genb ); quarks.push_back( &genj ); quarks.push_back( &genk ); quarks.push_back( &genbbar ); std::vector<const reco::Candidate*> jets; for(size_t s=0; s<evtsols->size(); s++) { jets.clear(); const reco::Candidate & jetp = (*evtsols)[s].getRecHadp(); const reco::Candidate & jetq = (*evtsols)[s].getRecHadq(); const reco::Candidate & jetbh = (*evtsols)[s].getRecHadb(); const reco::Candidate & jetj = (*evtsols)[s].getRecHadj(); const reco::Candidate & jetk = (*evtsols)[s].getRecHadk(); const reco::Candidate & jetbbar = (*evtsols)[s].getRecHadbbar(); jets.push_back( &jetp ); jets.push_back( &jetq ); jets.push_back( &jetbh ); jets.push_back( &jetj ); jets.push_back( &jetk ); jets.push_back( &jetbbar ); JetPartonMatching aMatch(quarks, jets, matchingAlgo_, useMaxDist_, useDeltaR_, maxDist_); (*evtsols)[s].setGenEvt(genEvt); (*evtsols)[s].setMCBestSumAngles(aMatch.getSumDistances()); (*evtsols)[s].setMCBestAngleHadp(aMatch.getDistanceForParton(0)); (*evtsols)[s].setMCBestAngleHadq(aMatch.getDistanceForParton(1)); (*evtsols)[s].setMCBestAngleHadb(aMatch.getDistanceForParton(2)); (*evtsols)[s].setMCBestAngleHadb(aMatch.getDistanceForParton(2)); (*evtsols)[s].setMCBestAngleHadj(aMatch.getDistanceForParton(3)); (*evtsols)[s].setMCBestAngleHadk(aMatch.getDistanceForParton(4)); (*evtsols)[s].setMCBestAngleHadbbar(aMatch.getDistanceForParton(5)); // Check match - checking if two light quarks are swapped wrt matched gen particle if((aMatch.getMatchForParton(2) == 2 && aMatch.getMatchForParton(5) == 5) || (aMatch.getMatchForParton(2) == 5 && aMatch.getMatchForParton(5) == 2)){ // check b-jets if(aMatch.getMatchForParton(3) == 3 && aMatch.getMatchForParton(4) == 4){ //check light jets bestSolutionChangeW2Q = 0; if(aMatch.getMatchForParton(0) == 0 && aMatch.getMatchForParton(1) == 1) { bestSolution = s; bestSolutionChangeW1Q = 0; }else{ if(aMatch.getMatchForParton(0) == 1 && aMatch.getMatchForParton(1) == 0){ bestSolution = s; bestSolutionChangeW1Q = 1; } } }else{ if(aMatch.getMatchForParton(2) == 3 && aMatch.getMatchForParton(3) == 2){ // or check if swapped bestSolutionChangeW2Q = 1; if(aMatch.getMatchForParton(0) == 1 && aMatch.getMatchForParton(1) == 0){ bestSolution = s; bestSolutionChangeW1Q = 1; }else{ if(aMatch.getMatchForParton(0) == 0 && aMatch.getMatchForParton(1) == 1) { bestSolution = s; bestSolutionChangeW1Q = 0; } } } if(aMatch.getMatchForParton(2) == 2 && aMatch.getMatchForParton(3) == 3){ bestSolutionChangeW2Q = 0; if(aMatch.getMatchForParton(0) == 0 && aMatch.getMatchForParton(1) == 1) { bestSolution = s; bestSolutionChangeW1Q = 0; } else if(aMatch.getMatchForParton(0) == 1 && aMatch.getMatchForParton(1) == 0) { bestSolution = s; bestSolutionChangeW1Q = 1; } } } } for(size_t s=0; s<evtsols->size(); s++) { (*evtsols)[s].setMCBestJetComb(bestSolution); (*evtsols)[s].setMCChangeW1Q(bestSolutionChangeW1Q); (*evtsols)[s].setMCChangeW2Q(bestSolutionChangeW2Q); } } } // end matchEvt } //store the vector of solutions to the event std::auto_ptr<std::vector<TtHadEvtSolution> > pOut(evtsols); iEvent.put(pOut); }else { //end loop jet/MET found std::cout<<"No calibrated solutions built, because only "<<jets->size()<<" were present"; std::auto_ptr<std::vector<TtHadEvtSolution> > pOut(evtsols); iEvent.put(pOut); } }
bool TtHadEvtSolutionMaker::addLRJetComb_ [private] |
Definition at line 42 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
bool TtHadEvtSolutionMaker::addLRSignalSel_ [private] |
Definition at line 42 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
std::vector<unsigned int> TtHadEvtSolutionMaker::constraints_ [private] |
Definition at line 50 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker().
bool TtHadEvtSolutionMaker::doKinFit_ [private] |
Definition at line 42 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
int TtHadEvtSolutionMaker::jetCorrScheme_ [private] |
Definition at line 40 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), and TtHadEvtSolutionMaker().
int TtHadEvtSolutionMaker::jetParam_ [private] |
Definition at line 48 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), and TtHadEvtSolutionMaker().
edm::InputTag TtHadEvtSolutionMaker::jetSrc_ [private] |
Definition at line 39 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), and TtHadEvtSolutionMaker().
std::string TtHadEvtSolutionMaker::lrJetCombFile_ [private] |
Definition at line 41 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker().
std::vector<int> TtHadEvtSolutionMaker::lrJetCombObs_ [private] |
Definition at line 49 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker().
std::string TtHadEvtSolutionMaker::lrSignalSelFile_ [private] |
Definition at line 41 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker().
std::vector<int> TtHadEvtSolutionMaker::lrSignalSelObs_ [private] |
Definition at line 49 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker().
int TtHadEvtSolutionMaker::matchingAlgo_ [private] |
Definition at line 43 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), and TtHadEvtSolutionMaker().
bool TtHadEvtSolutionMaker::matchToGenEvt_ [private] |
Definition at line 42 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), and TtHadEvtSolutionMaker().
double TtHadEvtSolutionMaker::maxDeltaS_ [private] |
Definition at line 47 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker().
double TtHadEvtSolutionMaker::maxDist_ [private] |
Definition at line 45 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), and TtHadEvtSolutionMaker().
double TtHadEvtSolutionMaker::maxF_ [private] |
Definition at line 47 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker().
int TtHadEvtSolutionMaker::maxNrIter_ [private] |
Definition at line 46 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker().
Definition at line 52 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
Definition at line 55 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
Definition at line 54 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
Definition at line 57 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
Definition at line 56 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
Definition at line 53 of file TtHadEvtSolutionMaker.h.
Referenced by TtHadEvtSolutionMaker(), and ~TtHadEvtSolutionMaker().
bool TtHadEvtSolutionMaker::useDeltaR_ [private] |
Definition at line 44 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), and TtHadEvtSolutionMaker().
bool TtHadEvtSolutionMaker::useMaxDist_ [private] |
Definition at line 44 of file TtHadEvtSolutionMaker.h.
Referenced by produce(), and TtHadEvtSolutionMaker().