7 jets_ (cfg.getParameter<edm::InputTag>(
"jets")),
8 match_ (cfg.getParameter<edm::InputTag>(
"match")),
9 useOnlyMatch_ (cfg.getParameter<bool>(
"useOnlyMatch")),
10 bTagAlgo_ (cfg.getParameter<std::string>(
"bTagAlgo")),
11 minBTagValueBJet_ (cfg.getParameter<double>(
"minBTagValueBJet")),
12 maxBTagValueNonBJet_ (cfg.getParameter<double>(
"maxBTagValueNonBJet")),
13 useBTagging_ (cfg.getParameter<bool>(
"useBTagging")),
14 bTags_ (cfg.getParameter<unsigned int>(
"bTags")),
15 jetCorrectionLevel_ (cfg.getParameter<std::string>(
"jetCorrectionLevel")),
16 maxNJets_ (cfg.getParameter<int>(
"maxNJets")),
17 maxNComb_ (cfg.getParameter<int>(
"maxNComb")),
18 maxNrIter_ (cfg.getParameter<unsigned int>(
"maxNrIter")),
19 maxDeltaS_ (cfg.getParameter<double>(
"maxDeltaS")),
20 maxF_ (cfg.getParameter<double>(
"maxF")),
21 jetParam_ (cfg.getParameter<unsigned>(
"jetParametrisation")),
22 constraints_ (cfg.getParameter<std::vector<unsigned> >(
"constraints")),
23 mW_ (cfg.getParameter<double>(
"mW" )),
24 mTop_ (cfg.getParameter<double>(
"mTop")),
25 jetEnergyResolutionScaleFactors_(cfg.getParameter<std::vector<double> >(
"jetEnergyResolutionScaleFactors")),
26 jetEnergyResolutionEtaBinning_ (cfg.getParameter<std::vector<double> >(
"jetEnergyResolutionEtaBinning"))
28 if(cfg.
exists(
"udscResolutions") && cfg.
exists(
"bResolutions")){
32 else if(cfg.
exists(
"udscResolutions") || cfg.
exists(
"bResolutions")){
33 if(cfg.
exists(
"udscResolutions"))
throw cms::Exception(
"Configuration") <<
"Parameter 'bResolutions' is needed if parameter 'udscResolutions' is defined!\n";
34 else throw cms::Exception(
"Configuration") <<
"Parameter 'udscResolutions' is needed if parameter 'bResolutions' is defined!\n";
44 produces< std::vector<pat::Particle> >(
"PartonsB");
45 produces< std::vector<pat::Particle> >(
"PartonsBBar");
46 produces< std::vector<pat::Particle> >(
"PartonsLightQ");
47 produces< std::vector<pat::Particle> >(
"PartonsLightQBar");
48 produces< std::vector<pat::Particle> >(
"PartonsLightP");
49 produces< std::vector<pat::Particle> >(
"PartonsLightPBar");
51 produces< std::vector<std::vector<int> > >();
52 produces< std::vector<double> >(
"Chi2");
53 produces< std::vector<double> >(
"Prob");
54 produces< std::vector<int> >(
"Status");
69 event.getByLabel(
jets_, jets);
72 std::vector<int>
match;
73 bool invalidMatch=
false;
78 event.getByLabel(
match_, matches);
79 match = *(matches->begin());
85 for(
unsigned int idx=0; idx<match.size(); ++idx) {
86 if(match[idx]<0 || match[idx]>=(
int)jets->size()) {
99 std::list<TtFullHadKinFitter::KinFitResult> fitResults =
kinFitter->
fit(*jets);
102 std::auto_ptr< std::vector<pat::Particle> > pPartonsB(
new std::vector<pat::Particle> );
103 std::auto_ptr< std::vector<pat::Particle> > pPartonsBBar(
new std::vector<pat::Particle> );
104 std::auto_ptr< std::vector<pat::Particle> > pPartonsLightQ (
new std::vector<pat::Particle> );
105 std::auto_ptr< std::vector<pat::Particle> > pPartonsLightQBar(
new std::vector<pat::Particle> );
106 std::auto_ptr< std::vector<pat::Particle> > pPartonsLightP (
new std::vector<pat::Particle> );
107 std::auto_ptr< std::vector<pat::Particle> > pPartonsLightPBar(
new std::vector<pat::Particle> );
109 std::auto_ptr< std::vector<std::vector<int> > > pCombi (
new std::vector<std::vector<int> > );
110 std::auto_ptr< std::vector<double> > pChi2 (
new std::vector<double> );
111 std::auto_ptr< std::vector<double> > pProb (
new std::vector<double> );
112 std::auto_ptr< std::vector<int> > pStatus(
new std::vector<int> );
114 unsigned int iComb = 0;
115 for(std::list<TtFullHadKinFitter::KinFitResult>::const_iterator res = fitResults.begin(); res != fitResults.end(); ++res){
121 pPartonsB ->push_back( res->B );
122 pPartonsBBar ->push_back( res->BBar );
123 pPartonsLightQ ->push_back( res->LightQ );
124 pPartonsLightQBar->push_back( res->LightQBar );
125 pPartonsLightP ->push_back( res->LightP );
126 pPartonsLightPBar->push_back( res->LightPBar );
128 pCombi ->push_back( res->JetCombi );
129 pChi2 ->push_back( res->Chi2 );
130 pProb ->push_back( res->Prob );
131 pStatus->push_back( res->Status );
136 event.put(pPartonsB ,
"PartonsB" );
137 event.put(pPartonsBBar ,
"PartonsBBar" );
138 event.put(pPartonsLightQ ,
"PartonsLightQ" );
139 event.put(pPartonsLightQBar,
"PartonsLightQBar");
140 event.put(pPartonsLightP ,
"PartonsLightP" );
141 event.put(pPartonsLightPBar,
"PartonsLightPBar");
142 event.put(pChi2 ,
"Chi2" );
143 event.put(pProb ,
"Prob" );
144 event.put(pStatus ,
"Status" );
T getParameter(std::string const &) const
static const unsigned int nPartons
TtFullHadKinFitter::KinFit * kinFitter
kinematic fit interface
#define DEFINE_FWK_MODULE(type)
edm::InputTag match_
input tag for matches (in case the fit should be performed on certain matches)
void setUseOnlyMatch(bool useOnlyMatch)
set useOnlyMatch
bool exists(std::string const ¶meterName) const
checks if a parameter exists
unsigned int jetParam_
numbering of different possible jet parametrizations
double mTop_
top mass value used for constraints
std::vector< unsigned > constraints_
numbering of different possible kinematic constraints
~TtFullHadKinFitProducer()
default destructor
double mW_
W mass value used for constraints.
std::list< TtFullHadKinFitter::KinFitResult > fit(const std::vector< pat::Jet > &jets)
do the fitting and return fit result
std::vector< edm::ParameterSet > udscResolutions_
store the resolutions for the jets
class that does the fitting
bool useBTagging_
switch to tell whether to use b-tagging or not
std::vector< edm::ParameterSet > bResolutions_
virtual void produce(edm::Event &event, const edm::EventSetup &setup)
produce fitted object collections and meta data describing fit quality
int maxNComb_
maximal number of combinations to be written to the event
std::string jetCorrectionLevel_
correction level for jets
How EventSelector::AcceptEvent() decides whether to accept an event for output otherwise it is excluding the probing of A single or multiple positive and the trigger will pass if any such matching triggers are PASS or EXCEPTION[A criterion thatmatches no triggers at all is detected and causes a throw.] A single negative with an expectation of appropriate bit checking in the decision and the trigger will pass if any such matching triggers are FAIL or EXCEPTION A wildcarded negative criterion that matches more than one trigger in the trigger but the state exists so we define the behavior If all triggers are the negative crieriion will lead to accepting the event(this again matches the behavior of"!*"before the partial wildcard feature was incorporated).The per-event"cost"of each negative criterion with multiple relevant triggers is about the same as!*was in the past
double maxF_
maximal deviation for contstraints
double maxDeltaS_
maximal chi2 equivalent
edm::InputTag jets_
input tag for jets
unsigned int maxNrIter_
maximal number of iterations to be performed for the fit
std::string bTagAlgo_
input tag for b-tagging algorithm
std::vector< double > jetEnergyResolutionScaleFactors_
scale factors for jet energy resolution
std::pair< typename Association::data_type::first_type, double > match(Reference key, Association association, bool bestMatchByMaxValue)
Generic matching function.
int maxNJets_
maximal number of jets (-1 possible to indicate 'all')
double maxBTagValueNonBJet_
max value of bTag for a non-b-jet
unsigned int bTags_
minimal number of b-jets
std::vector< double > jetEnergyResolutionEtaBinning_
double minBTagValueBJet_
min value of bTag for a b-jet
void setup(std::vector< TH2F > &depth, std::string name, std::string units="")
void setMatch(std::vector< int > match)
set match to be used
TtFullHadKinFitProducer(const edm::ParameterSet &cfg)
default constructor
void setMatchInvalidity(bool invalidMatch)
set the validity of a match