Namespaces | |
namespace | Private |
Classes | |
struct | AbsPileupCalculator |
class | CompositeFunctor |
class | ConstDouble |
struct | EnergyEtaP4Builder |
class | EtaAndPtDependentPeakSelector |
class | EtaAndPtLookupPeakSelector |
class | EtaDependentPileup |
class | FFTJetInterface |
struct | JetAbsEta |
class | JetConvergenceDistance |
class | JetEtaDependent |
class | JetToPeakDistance |
class | LinInterpolatedTable1D |
class | LookupTable2d |
class | MagnitudeDependent |
class | MultiplyByConst |
struct | PeakAbsEta |
class | PeakEtaDependent |
class | PeakEtaMagSsqDependent |
class | PileupGrid2d |
class | Polynomial |
class | ProductFunctor |
class | ProportionalToScale |
struct | PtEtaP4Builder |
Typedefs | |
typedef fftjet::Functor2 < double, double, BgData > | AbsBgFunctor |
typedef double | BgData |
typedef fftw_complex | Complex |
typedef fftjet::FFTWDoubleEngine | MyFFTEngine |
typedef double | Real |
typedef PtEtaP4Builder | VBuilder |
typedef math::XYZTLorentzVector | VectorLike |
Functions | |
template<typename F1 , typename F2 > | |
void | add_Grid2d_data (fftjet::Grid2d< F2 > *to, const fftjet::Grid2d< F1 > &from) |
template<typename Numeric > | |
fftjet::Grid2d< double > * | convert_Grid2d_to_double (const fftjet::Grid2d< Numeric > &grid) |
template<typename Numeric > | |
fftjet::Grid2d< float > * | convert_Grid2d_to_float (const fftjet::Grid2d< Numeric > &grid) |
template<typename F1 , typename F2 > | |
void | copy_Grid2d_data (fftjet::Grid2d< F2 > *to, const fftjet::Grid2d< F1 > &from) |
template<class Real > | |
void | densePeakTreeFromStorable (const reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > &in, const std::vector< double > *scaleSetIfNotAdaptive, double completeEventScale, fftjet::AbsClusteringTree< fftjet::Peak, long > *out) |
template<class Real > | |
void | densePeakTreeToStorable (const fftjet::AbsClusteringTree< fftjet::Peak, long > &in, bool writeOutScaleInfo, reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > *out) |
std::auto_ptr< AbsBgFunctor > | fftjet_BgFunctor_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::ClusteringTreeSparsifier < fftjet::Peak, long > > | fftjet_ClusteringTreeSparsifier_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::AbsDistanceCalculator < fftjet::Peak > > | fftjet_DistanceCalculator_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::Functor1< double, double > > | fftjet_Function_parser (const edm::ParameterSet &ps) |
std::auto_ptr< fftjet::Grid2d < Real > > | fftjet_Grid2d_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::Functor2< double, fftjet::RecombinedJet < VectorLike > , fftjet::RecombinedJet < VectorLike > > > | fftjet_JetDistance_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::Functor1< double, fftjet::RecombinedJet < VectorLike > > > | fftjet_JetFunctor_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::JetMagnitudeMapper2d < fftjet::RecombinedJet < VectorLike > > > | fftjet_JetMagnitudeMapper2d_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::LinearInterpolator1d > | fftjet_LinearInterpolator1d_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::LinearInterpolator2d > | fftjet_LinearInterpolator2d_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjetcms::LinInterpolatedTable1D > | fftjet_LinInterpolatedTable1D_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::ScaleSpaceKernel > | fftjet_MembershipFunction_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::Functor1< double, fftjet::Peak > > | fftjet_PeakFunctor_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::JetMagnitudeMapper2d < fftjet::Peak > > | fftjet_PeakMagnitudeMapper2d_parser (const edm::ParameterSet &ps) |
std::auto_ptr < fftjet::Functor1< bool, fftjet::Peak > > | fftjet_PeakSelector_parser (const edm::ParameterSet &ps) |
std::auto_ptr < AbsPileupCalculator > | fftjet_PileupCalculator_parser (const edm::ParameterSet &ps) |
std::auto_ptr< std::vector < double > > | fftjet_ScaleSet_parser (const edm::ParameterSet &ps) |
template<class Real > | |
fftjet::RecombinedJet< VectorLike > | jetFromStorable (const reco::FFTJet< Real > &jet) |
template<class Real > | |
reco::FFTJet< Real > | jetToStorable (const fftjet::RecombinedJet< VectorLike > &jet) |
template<class T1 , class T2 , class DistanceCalculator > | |
unsigned | matchOneToOne (const std::vector< T1 > &v1, const std::vector< T2 > &v2, const DistanceCalculator &calc, std::vector< int > *matchFrom1To2, const double maxMatchingDistance=1.0e300) |
template<class Real > | |
void | sparsePeakTreeFromStorable (const reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > &in, const std::vector< double > *scaleSetIfNotAdaptive, double completeEventScale, fftjet::SparseClusteringTree< fftjet::Peak, long > *out) |
template<class Real > | |
void | sparsePeakTreeToStorable (const fftjet::SparseClusteringTree< fftjet::Peak, long > &in, bool writeOutScaleInfo, reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > *out) |
typedef fftjet::Functor2<double,double,BgData> fftjetcms::AbsBgFunctor |
Definition at line 38 of file fftjetTypedefs.h.
typedef double fftjetcms::BgData |
Definition at line 34 of file fftjetTypedefs.h.
typedef fftw_complex fftjetcms::Complex |
Definition at line 22 of file fftjetTypedefs.h.
typedef fftjet::FFTWDoubleEngine fftjetcms::MyFFTEngine |
Definition at line 23 of file fftjetTypedefs.h.
typedef double fftjetcms::Real |
Definition at line 21 of file fftjetTypedefs.h.
typedef PtEtaP4Builder fftjetcms::VBuilder |
Definition at line 30 of file fftjetTypedefs.h.
Definition at line 26 of file fftjetTypedefs.h.
void fftjetcms::add_Grid2d_data | ( | fftjet::Grid2d< F2 > * | to, |
const fftjet::Grid2d< F1 > & | from | ||
) |
Definition at line 57 of file gridConverters.h.
References i.
Referenced by FFTJetPileupProcessor::mixExtraGrid().
fftjet::Grid2d< double > * fftjetcms::convert_Grid2d_to_double | ( | const fftjet::Grid2d< Numeric > & | grid | ) |
Definition at line 82 of file gridConverters.h.
References copy_Grid2d_data().
{ fftjet::Grid2d<double>* to = new fftjet::Grid2d<double>( grid.nEta(), grid.etaMin(), grid.etaMax(), grid.nPhi(), grid.phiBin0Edge(), grid.title()); copy_Grid2d_data(to, grid); return to; }
fftjet::Grid2d< float > * fftjetcms::convert_Grid2d_to_float | ( | const fftjet::Grid2d< Numeric > & | grid | ) |
Definition at line 71 of file gridConverters.h.
References copy_Grid2d_data().
Referenced by FFTJetPatRecoProducer::produce().
{ fftjet::Grid2d<float>* to = new fftjet::Grid2d<float>( grid.nEta(), grid.etaMin(), grid.etaMax(), grid.nPhi(), grid.phiBin0Edge(), grid.title()); copy_Grid2d_data(to, grid); return to; }
void fftjetcms::copy_Grid2d_data | ( | fftjet::Grid2d< F2 > * | to, |
const fftjet::Grid2d< F1 > & | from | ||
) |
Definition at line 43 of file gridConverters.h.
References i.
Referenced by convert_Grid2d_to_double(), convert_Grid2d_to_float(), and FFTJetPatRecoProducer::produce().
void fftjetcms::densePeakTreeFromStorable | ( | const reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > & | in, |
const std::vector< double > * | scaleSetIfNotAdaptive, | ||
double | completeEventScale, | ||
fftjet::AbsClusteringTree< fftjet::Peak, long > * | out | ||
) |
Definition at line 297 of file clusteringTreeConverters.h.
References Exception, i, recoMuon::in, dttmaxenums::L, n, AlCaHLTBitMon_ParallelJobs::p, and pileupReCalc_HLTpaths::scale.
Referenced by FFTJetPatRecoProducer::buildDenseProduct(), and FFTJetTreeDump::processTreeData().
{ typedef fftjet::AbsClusteringTree<fftjet::Peak,long> DenseTree; typedef reco::PattRecoPeak<Real> StoredPeak; typedef reco::PattRecoNode<StoredPeak> StoredNode; typedef reco::PattRecoTree<Real,StoredPeak> StoredTree; if (in.isSparse()) throw cms::Exception("FFTJetBadConfig") << "can't restore dense clustering tree" << " from sparsely stored record" << std::endl; assert(out); out->clear(); const std::vector<StoredNode>& nodes(in.getNodes()); const unsigned n = nodes.size(); double hessian[3] = {0., 0., 0.}; const std::vector<Real>& scales (in.getScales()); unsigned int scnum = 0; std::vector<fftjet::Peak> clusters; const unsigned scsize1 = scales.size(); unsigned scsize2 = scaleSetIfNotAdaptive ? scaleSetIfNotAdaptive->size() : 0; if (scsize2 && completeEventScale) ++scsize2; const unsigned scsize = (scsize1==0?scsize2:scsize1); if (scsize == 0) throw cms::Exception("FFTJetBadConfig") << " No scales passed to the function densePeakTreeFromStorable()" << std::endl; // to check whether the largest level equals the size of scale vector const double* sc_not_ad = scsize2 ? &(*scaleSetIfNotAdaptive)[0] : 0; unsigned templevel = n ? nodes[0].originalLevel() : 1; for (unsigned i=0; i<n; ++i) { const StoredNode& snode(nodes[i]); const StoredPeak& p(snode.getCluster()); p.hessian(hessian); const unsigned levelNumber = snode.originalLevel(); if (templevel != levelNumber) { if (scnum >= scsize) throw cms::Exception("FFTJetBadConfig") << "bad scales, please check the scales" << std::endl; const double scale = ( (scsize1==0) ? sc_not_ad[scnum] : scales[scnum] ); out->insert(scale, clusters, 0L); clusters.clear(); templevel = levelNumber; ++scnum; } fftjet::Peak apeak(p.eta(), p.phi(), p.magnitude(), hessian, p.driftSpeed(), p.magSpeed(), p.lifetime(), p.scale(), p.nearestNeighborDistance(), 1.0, 0.0, 0.0, p.clusterRadius(), p.clusterSeparation()); clusters.push_back(apeak); if (i==(n-1) && levelNumber!=scsize) throw cms::Exception("FFTJetBadConfig") << "bad scales, please check the scales" << std::endl; } const double scale = scsize1 ? scales[scnum] : completeEventScale ? completeEventScale : sc_not_ad[scnum]; out->insert(scale, clusters, 0L); }
void fftjetcms::densePeakTreeToStorable | ( | const fftjet::AbsClusteringTree< fftjet::Peak, long > & | in, |
bool | writeOutScaleInfo, | ||
reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > * | out | ||
) |
Definition at line 219 of file clusteringTreeConverters.h.
References i, and dbtoconf::out.
Referenced by FFTJetPatRecoProducer::buildDenseProduct().
{ typedef fftjet::AbsClusteringTree<fftjet::Peak,long> DenseTree; typedef reco::PattRecoPeak<Real> StoredPeak; typedef reco::PattRecoNode<StoredPeak> StoredNode; typedef reco::PattRecoTree<Real,StoredPeak> StoredTree; assert(out); out->clear(); out->setSparse(false); const unsigned nLevels = in.nLevels(); double hessian[3] = {0., 0., 0.}; // Do not write out the meaningless top node out->reserveNodes(in.nClusters() - 1); for (unsigned i=1; i<nLevels; ++i) { const unsigned int nclus = in.nClusters(i); DenseTree::NodeId id(i,0); for (;id.second<nclus; ++id.second) { const fftjet::Peak& peak(in.getCluster(id)); peak.hessian(hessian); StoredNode sn(StoredPeak(peak.eta(), peak.phi(), peak.magnitude(), hessian, peak.driftSpeed(), peak.magSpeed(), peak.lifetime(), peak.scale(), peak.nearestNeighborDistance(), peak.clusterRadius(), peak.clusterSeparation()), i, 0, 0); out->addNode(sn); } } // Do we want to write out the scales? We will use the following // convention: if the tree is using an adaptive algorithm, the scales // will be written out. If not, they are not going to change from // event to event. In this case the scales would waste disk space // for no particularly good reason, so they will not be written out. if (writeOutScaleInfo) { // Do not write out the meaningless top-level scale const unsigned nScales = in.nLevels(); out->reserveScales(nScales - 1); for (unsigned i=1; i<nScales; ++i) out->addScale(in.getScale(i)); } }
std::auto_ptr< AbsBgFunctor > fftjetcms::fftjet_BgFunctor_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 396 of file FFTJetParameterParser.cc.
References edm::ParameterSet::getParameter(), NULL, and bookConverter::prior.
Referenced by FFTJetProducer::parse_bgMembershipFunction().
{ const std::string bg_Membership_type = ps.getParameter<std::string>( "Class"); if (!bg_Membership_type.compare("GaussianNoiseMembershipFcn")) { const double minWeight = ps.getParameter<double>("minWeight"); const double prior = ps.getParameter<double>("prior"); return std::auto_ptr<AbsBgFunctor>( new fftjet::GaussianNoiseMembershipFcn(minWeight,prior)); } return std::auto_ptr<AbsBgFunctor>(NULL); }
std::auto_ptr< fftjet::ClusteringTreeSparsifier< fftjet::Peak, long > > fftjetcms::fftjet_ClusteringTreeSparsifier_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 468 of file FFTJetParameterParser.cc.
References edm::ParameterSet::getParameter(), and NULL.
Referenced by FFTJetPatRecoProducer::FFTJetPatRecoProducer().
{ typedef std::auto_ptr<fftjet::ClusteringTreeSparsifier<fftjet::Peak,long> > return_type; const int maxLevelNumber = ps.getParameter<int>("maxLevelNumber"); const unsigned filterMask = ps.getParameter<unsigned>("filterMask"); const std::vector<double> userScalesV = ps.getParameter<std::vector<double> >("userScales"); const unsigned nUserScales = userScalesV.size(); const double* userScales = nUserScales ? NULL : &userScalesV[0]; return return_type( new fftjet::ClusteringTreeSparsifier<fftjet::Peak,long>( maxLevelNumber, filterMask, userScales, nUserScales ) ); }
std::auto_ptr< fftjet::AbsDistanceCalculator< fftjet::Peak > > fftjetcms::fftjet_DistanceCalculator_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 491 of file FFTJetParameterParser.cc.
References AlCaHLTBitMon_QueryRunRegistry::data, fftjet_LinearInterpolator1d_parser(), edm::ParameterSet::getParameter(), i, n, and NULL.
Referenced by FFTJetPatRecoProducer::FFTJetPatRecoProducer(), and FFTJetTreeDump::FFTJetTreeDump().
{ typedef std::auto_ptr<fftjet::AbsDistanceCalculator<fftjet::Peak> > return_type; const std::string calc_type = ps.getParameter<std::string>("Class"); if (!calc_type.compare("PeakEtaPhiDistance")) { const double etaToPhiBandwidthRatio = ps.getParameter<double>( "etaToPhiBandwidthRatio"); return return_type(new fftjet::PeakEtaPhiDistance(etaToPhiBandwidthRatio)); } if (!calc_type.compare("PeakEtaDependentDistance")) { std::auto_ptr<fftjet::LinearInterpolator1d> interp = fftjet_LinearInterpolator1d_parser( ps.getParameter<edm::ParameterSet>("Interpolator")); const fftjet::LinearInterpolator1d* ip = interp.get(); if (ip == NULL) return return_type(NULL); // Check that the interpolator is always positive const unsigned n = ip->nx(); const double* data = ip->getData(); for (unsigned i=0; i<n; ++i) if (data[i] <= 0.0) return return_type(NULL); if (ip->fLow() <= 0.0 || ip->fHigh() <= 0.0) return return_type(NULL); return return_type(new fftjet::PeakEtaDependentDistance(*ip)); } return return_type(NULL); }
std::auto_ptr< fftjet::Functor1< double, double > > fftjetcms::fftjet_Function_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 901 of file FFTJetParameterParser.cc.
References edm::ParameterSet::exists(), fftjet_LinearInterpolator1d_parser(), fftjet_LinInterpolatedTable1D_parser(), edm::ParameterSet::getParameter(), i, NULL, AlCaHLTBitMon_ParallelJobs::p, and alignCSCRings::s.
Referenced by fftjet_JetFunctor_parser(), fftjet_PeakFunctor_parser(), and FFTJetPileupEstimator::FFTJetPileupEstimator().
{ typedef std::auto_ptr<fftjet::Functor1<double,double> > return_type; const std::string fcn_type = ps.getParameter<std::string>("Class"); if (!fcn_type.compare("LinearInterpolator1d")) { std::auto_ptr<fftjet::LinearInterpolator1d> p = fftjet_LinearInterpolator1d_parser(ps); fftjet::LinearInterpolator1d* ptr = p.get(); if (ptr) { p.release(); return return_type(ptr); } } if (!fcn_type.compare("LinInterpolatedTable1D")) { std::auto_ptr<fftjetcms::LinInterpolatedTable1D> p = fftjet_LinInterpolatedTable1D_parser(ps); fftjetcms::LinInterpolatedTable1D* ptr = p.get(); if (ptr) { p.release(); return return_type(ptr); } } if (!fcn_type.compare("Polynomial")) { std::vector<double> coeffs; for (unsigned i=0; ; ++i) { std::ostringstream s; s << 'c' << i; if (ps.exists(s.str())) coeffs.push_back(ps.getParameter<double>(s.str())); else break; } return return_type(new Polynomial(coeffs)); } return return_type(NULL); }
std::auto_ptr< fftjet::Grid2d< Real > > fftjetcms::fftjet_Grid2d_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 124 of file FFTJetParameterParser.cc.
References AlCaHLTBitMon_QueryRunRegistry::data, jptDQMConfig_cff::etaMax, jptDQMConfig_cff::etaMin, Exception, edm::ParameterSet::exists(), mergeVDriftHistosByStation::file, g, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), recoMuon::in, NULL, SiPixelLorentzAngle_cfi::read, and indexGen::title.
Referenced by FFTJetProducer::beginJob(), fftjet_PileupCalculator_parser(), FFTJetEFlowSmoother::FFTJetEFlowSmoother(), FFTJetPatRecoProducer::FFTJetPatRecoProducer(), and FFTJetPileupProcessor::FFTJetPileupProcessor().
{ typedef std::auto_ptr<fftjet::Grid2d<Real> > return_type; fftjet::Grid2d<Real> *g = 0; // Check if the grid should be read from file if (ps.exists("file")) { const std::string file = ps.getParameter<std::string>("file"); std::ifstream in(file.c_str(), std::ios_base::in | std::ios_base::binary); if (!in.is_open()) throw cms::Exception("FFTJetBadConfig") << "Failed to open file " << file << std::endl; g = fftjet::Grid2d<Real>::read(in); if (g == 0) throw cms::Exception("FFTJetBadConfig") << "Failed to read file " << file << std::endl; } else { const unsigned nEtaBins = ps.getParameter<unsigned>("nEtaBins"); const Real etaMin = ps.getParameter<Real>("etaMin"); const Real etaMax = ps.getParameter<Real>("etaMax"); const unsigned nPhiBins = ps.getParameter<unsigned>("nPhiBins"); const Real phiBin0Edge = ps.getParameter<Real>("phiBin0Edge"); const std::string& title = ps.getUntrackedParameter<std::string>( "title", ""); if (nEtaBins == 0 || nPhiBins == 0 || etaMin >= etaMax) return return_type(NULL); g = new fftjet::Grid2d<Real>( nEtaBins, etaMin, etaMax, nPhiBins, phiBin0Edge, title.c_str() ); // Check if the grid data is provided if (ps.exists("data")) { const std::vector<Real>& data = ps.getParameter<std::vector<Real> >("data"); if (data.size() == nEtaBins*nPhiBins) g->blockSet(&data[0], nEtaBins, nPhiBins); else { delete g; g = 0; } } } return return_type(g); }
std::auto_ptr< fftjet::Functor2< double, fftjet::RecombinedJet< VectorLike >, fftjet::RecombinedJet< VectorLike > > > fftjetcms::fftjet_JetDistance_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 876 of file FFTJetParameterParser.cc.
References edm::ParameterSet::getParameter(), make_param, and NULL.
Referenced by FFTJetProducer::parse_jetDistanceCalc().
{ typedef std::auto_ptr<fftjet::Functor2< double, fftjet::RecombinedJet<VectorLike>, fftjet::RecombinedJet<VectorLike> > > return_type; const std::string distance_type = ps.getParameter<std::string>( "Class"); if (!distance_type.compare("JetConvergenceDistance")) { make_param(double, etaToPhiBandwidthRatio); make_param(double, relativePtBandwidth); if (etaToPhiBandwidthRatio > 0.0 && relativePtBandwidth > 0.0) return return_type(new JetConvergenceDistance( etaToPhiBandwidthRatio, relativePtBandwidth)); } return return_type(NULL); }
std::auto_ptr< fftjet::Functor1< double, fftjet::RecombinedJet< VectorLike > > > fftjetcms::fftjet_JetFunctor_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 743 of file FFTJetParameterParser.cc.
References python::connectstrParser::f1, python::connectstrParser::f2, fcn(), fftjet_Function_parser(), edm::ParameterSet::getParameter(), NULL, parse_jet_member_function(), query::result, and relativeConstraints::value.
Referenced by FFTJetProducer::parse_memberFactorCalcJet(), FFTJetProducer::parse_recoScaleCalcJet(), and FFTJetProducer::parse_recoScaleRatioCalcJet().
{ typedef fftjet::Functor1<double,RecoFFTJet> ptr_type; typedef std::auto_ptr<ptr_type> return_type; const std::string property_type = ps.getParameter<std::string>("Class"); if (!property_type.compare("Log")) { return_type wrapped = fftjet_JetFunctor_parser( ps.getParameter<edm::ParameterSet>("function")); fftjet::Functor1<double,RecoFFTJet>* wr = wrapped.get(); if (wr) { return_type result = return_type( new fftjet::LogProperty<RecoFFTJet>(wr, true)); wrapped.release(); return result; } } if (!property_type.compare("JetEtaDependent")) { std::auto_ptr<fftjet::Functor1<double,double> > fcn1 = fftjet_Function_parser( ps.getParameter<edm::ParameterSet>("function")); fftjet::Functor1<double,double>* f1 = fcn1.get(); if (f1) { return_type result = return_type(new JetEtaDependent(f1, true)); fcn1.release(); return result; } } if (!property_type.compare("JetProperty")) { const std::string member = ps.getParameter<std::string>("member"); fftjet::JetProperty<RecoFFTJet>::JetMemberFunction fcn; if (parse_jet_member_function(member.c_str(), &fcn)) return return_type( new fftjet::JetProperty<RecoFFTJet>(fcn)); else return return_type(NULL); } if (!property_type.compare("ConstDouble")) { const double value = ps.getParameter<double>("value"); return return_type(new ConstDouble<RecoFFTJet>(value)); } if (!property_type.compare("ProportionalToScale")) { const double value = ps.getParameter<double>("value"); return return_type( new ProportionalToScale<RecoFFTJet>(value)); } if (!property_type.compare("MultiplyByConst")) { const double factor = ps.getParameter<double>("factor"); return_type function = fftjet_JetFunctor_parser( ps.getParameter<edm::ParameterSet>("function")); ptr_type* ptr = function.get(); if (ptr) { return_type result = return_type( new MultiplyByConst<RecoFFTJet>(factor, ptr, true)); function.release(); return result; } } if (!property_type.compare("CompositeFunctor")) { std::auto_ptr<fftjet::Functor1<double,double> > fcn1 = fftjet_Function_parser( ps.getParameter<edm::ParameterSet>("function1")); return_type fcn2 = fftjet_JetFunctor_parser( ps.getParameter<edm::ParameterSet>("function2")); fftjet::Functor1<double,double>* f1 = fcn1.get(); ptr_type* f2 = fcn2.get(); if (f1 && f2) { return_type result = return_type( new CompositeFunctor<RecoFFTJet>(f1, f2, true)); fcn1.release(); fcn2.release(); return result; } } if (!property_type.compare("ProductFunctor")) { return_type fcn1 = fftjet_JetFunctor_parser( ps.getParameter<edm::ParameterSet>("function1")); return_type fcn2 = fftjet_JetFunctor_parser( ps.getParameter<edm::ParameterSet>("function2")); ptr_type* f1 = fcn1.get(); ptr_type* f2 = fcn2.get(); if (f1 && f2) { return_type result = return_type( new ProductFunctor<RecoFFTJet>(f1, f2, true)); fcn1.release(); fcn2.release(); return result; } } if (!property_type.compare("MagnitudeDependent")) { std::auto_ptr<fftjet::Functor1<double,double> > fcn1 = fftjet_Function_parser( ps.getParameter<edm::ParameterSet>("function")); fftjet::Functor1<double,double>* f1 = fcn1.get(); if (f1) { return_type result = return_type( new MagnitudeDependent<RecoFFTJet>(f1, true)); fcn1.release(); return result; } } return return_type(NULL); }
std::auto_ptr< fftjet::JetMagnitudeMapper2d< fftjet::RecombinedJet< VectorLike > > > fftjetcms::fftjet_JetMagnitudeMapper2d_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 1014 of file FFTJetParameterParser.cc.
References fftjet_LinearInterpolator2d_parser(), and edm::ParameterSet::getParameter().
{ std::auto_ptr<fftjet::LinearInterpolator2d> responseCurve = fftjet_LinearInterpolator2d_parser( ps.getParameter<edm::ParameterSet>("responseCurve")); const double minPredictor = ps.getParameter<double>("minPredictor"); const double maxPredictor = ps.getParameter<double>("maxPredictor"); const unsigned nPredPoints = ps.getParameter<unsigned>("nPredPoints"); const double maxMagnitude = ps.getParameter<double>("maxMagnitude"); const unsigned nMagPoints = ps.getParameter<unsigned>("nMagPoints"); return (std::auto_ptr<fftjet::JetMagnitudeMapper2d<RecoFFTJet> > (new fftjet::JetMagnitudeMapper2d<RecoFFTJet>( *responseCurve, new fftjetcms::JetAbsEta<RecoFFTJet>(), true,minPredictor,maxPredictor,nPredPoints, maxMagnitude,nMagPoints))); }
std::auto_ptr< fftjet::LinearInterpolator1d > fftjetcms::fftjet_LinearInterpolator1d_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 551 of file FFTJetParameterParser.cc.
References AlCaHLTBitMon_QueryRunRegistry::data, edm::ParameterSet::getParameter(), and NULL.
Referenced by fftjet_DistanceCalculator_parser(), and fftjet_Function_parser().
{ const double xmin = ps.getParameter<double>("xmin"); const double xmax = ps.getParameter<double>("xmax"); const double flow = ps.getParameter<double>("flow"); const double fhigh = ps.getParameter<double>("fhigh"); const std::vector<double> data( ps.getParameter<std::vector<double> >("data")); if (data.empty()) return std::auto_ptr<fftjet::LinearInterpolator1d>(NULL); else return std::auto_ptr<fftjet::LinearInterpolator1d>( new fftjet::LinearInterpolator1d( &data[0], data.size(), xmin, xmax, flow, fhigh)); }
std::auto_ptr< fftjet::LinearInterpolator2d > fftjetcms::fftjet_LinearInterpolator2d_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 569 of file FFTJetParameterParser.cc.
References Exception, mergeVDriftHistosByStation::file, edm::ParameterSet::getParameter(), recoMuon::in, and SiPixelLorentzAngle_cfi::read.
Referenced by fftjet_JetMagnitudeMapper2d_parser(), fftjet_PeakMagnitudeMapper2d_parser(), and fftjet_PileupCalculator_parser().
{ const std::string file = ps.getParameter<std::string>("file"); std::ifstream in(file.c_str(), std::ios_base::in | std::ios_base::binary); if (!in.is_open()) throw cms::Exception("FFTJetBadConfig") << "Failed to open file " << file << std::endl; fftjet::LinearInterpolator2d* ip = fftjet::LinearInterpolator2d::read(in); if (!ip) throw cms::Exception("FFTJetBadConfig") << "Failed to read file " << file << std::endl; return std::auto_ptr<fftjet::LinearInterpolator2d>(ip); }
std::auto_ptr< fftjetcms::LinInterpolatedTable1D > fftjetcms::fftjet_LinInterpolatedTable1D_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 530 of file FFTJetParameterParser.cc.
References AlCaHLTBitMon_QueryRunRegistry::data, edm::ParameterSet::getParameter(), and NULL.
Referenced by fftjet_Function_parser().
{ const double xmin = ps.getParameter<double>("xmin"); const double xmax = ps.getParameter<double>("xmax"); const bool leftExtrapolationLinear = ps.getParameter<bool>("leftExtrapolationLinear"); const bool rightExtrapolationLinear = ps.getParameter<bool>("rightExtrapolationLinear"); const std::vector<double> data( ps.getParameter<std::vector<double> >("data")); if (data.empty()) return std::auto_ptr<fftjetcms::LinInterpolatedTable1D>(NULL); else return std::auto_ptr<fftjetcms::LinInterpolatedTable1D>( new fftjetcms::LinInterpolatedTable1D( &data[0], data.size(), xmin, xmax, leftExtrapolationLinear, rightExtrapolationLinear)); }
std::auto_ptr< fftjet::ScaleSpaceKernel > fftjetcms::fftjet_MembershipFunction_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 260 of file FFTJetParameterParser.cc.
References AlCaHLTBitMon_QueryRunRegistry::data, Exception, tests::test_Package01::factory, mergeVDriftHistosByStation::file, edm::ParameterSet::getParameter(), recoMuon::in, make_param, NULL, and SiPixelLorentzAngle_cfi::read.
Referenced by FFTJetProducer::parse_jetMembershipFunction().
{ typedef std::auto_ptr<fftjet::ScaleSpaceKernel> return_type; const std::string MembershipFunction_type = ps.getParameter<std::string>( "Class"); // Parse special cases first if (!MembershipFunction_type.compare("InterpolatedMembershipFcn")) { // This is a kernel defined by a 4d (sparsified) lookup table. // Here, it is simply loaded from a file using a built-in // method from fftjet. Note that the table representation // must be native binary (this will not work on platforms with // different endianity of floating point standard). const std::string file = ps.getParameter<std::string>("file"); std::ifstream in(file.c_str(), std::ios_base::in | std::ios_base::binary); if (!in.is_open()) throw cms::Exception("FFTJetBadConfig") << "Failed to open file " << file << std::endl; return return_type(fftjet::InterpolatedMembershipFcn<float>::read(in)); } if (!MembershipFunction_type.compare("Composite")) { throw cms::Exception("FFTJetBadConfig") << "Parsing of CompositeKernel objects is not implemented yet" << std::endl; } if (!MembershipFunction_type.compare("MagneticSmearing")) { // This kernel represents smearing of a jet in phi // in a magnetic field. The meaning of the parameters // is explained in the comments in the MagneticSmearingKernel.hh // header file of the fftjet package. make_param(std::vector<double>, fragmentationData); make_param(double, numeratorConst); make_param(double, charge1Fraction); make_param(double, charge2Fraction); make_param(unsigned, samplesPerBin); if (fragmentationData.empty()) throw cms::Exception("FFTJetBadConfig") << "Fragmentation function data not defined for " "MagneticSmearingKernel" << std::endl; if (samplesPerBin < 1U) throw cms::Exception("FFTJetBadConfig") << "Bad number of samples per bin in " "MagneticSmearingKernel" << std::endl; fftjet::LinearInterpolator1d* fragmentationFunction = new fftjet::LinearInterpolator1d( &fragmentationData[0], fragmentationData.size(), 0.0, 1.0); return return_type( new fftjet::MagneticSmearingKernel<fftjet::LinearInterpolator1d>( fragmentationFunction, numeratorConst, charge1Fraction, charge2Fraction, samplesPerBin, true)); } if (!MembershipFunction_type.compare("Interpolated")) { // This is a kernel defined by a histogram-like 2d lookup table make_param(double, sx); make_param(double, sy); make_param(int, scalePower); make_param(unsigned, nxbins); make_param(double, xmin); make_param(double, xmax); make_param(unsigned, nybins); make_param(double, ymin); make_param(double, ymax); make_param(std::vector<double>, data); if (data.size() != nxbins*nybins) throw cms::Exception("FFTJetBadConfig") << "Bad number of data points for Interpolated kernel" << std::endl; return return_type(new fftjet::InterpolatedKernel( sx, sy, scalePower, &data[0], nxbins, xmin, xmax, nybins, ymin, ymax)); } if (!MembershipFunction_type.compare("Interpolated3d")) { // This is a kernel defined by a histogram-like 3d lookup table make_param(std::vector<double>, data); make_param(std::vector<double>, scales); make_param(bool, useLogSpaceForScale); make_param(unsigned, nxbins); make_param(double, xmin); make_param(double, xmax); make_param(unsigned, nybins); make_param(double, ymin); make_param(double, ymax); if (data.size() != nxbins*nybins*scales.size()) throw cms::Exception("FFTJetBadConfig") << "Bad number of data points for Interpolated3d kernel" << std::endl; return return_type(new fftjet::InterpolatedKernel3d( &data[0], scales, useLogSpaceForScale, nxbins, xmin, xmax, nybins, ymin, ymax)); } // This is not a special kernel. Try one of the classes // in the kernel factory provided by FFTJet. fftjet::DefaultKernel2dFactory factory; if (factory[MembershipFunction_type] == NULL) { return return_type(NULL); } make_param(double, sx); make_param(double, sy); make_param(int, scalePower); make_param(std::vector<double>, kernelParameters); const int n_expected = factory[MembershipFunction_type]->nParameters(); if (n_expected >= 0) if (static_cast<unsigned>(n_expected) != kernelParameters.size()) throw cms::Exception("FFTJetBadConfig") << "Bad number of kernel parameters" << std::endl; return std::auto_ptr<fftjet::ScaleSpaceKernel>( factory[MembershipFunction_type]->create( sx, sy, scalePower, kernelParameters)); }
std::auto_ptr< fftjet::Functor1< double, fftjet::Peak > > fftjetcms::fftjet_PeakFunctor_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 586 of file FFTJetParameterParser.cc.
References python::connectstrParser::f1, python::connectstrParser::f2, fcn(), fftjet_Function_parser(), edm::ParameterSet::getParameter(), NULL, parse_peak_member_function(), query::result, and relativeConstraints::value.
Referenced by FFTJetTreeDump::FFTJetTreeDump(), FFTJetProducer::parse_memberFactorCalcPeak(), FFTJetProducer::parse_recoScaleCalcPeak(), and FFTJetProducer::parse_recoScaleRatioCalcPeak().
{ typedef fftjet::Functor1<double,fftjet::Peak> ptr_type; typedef std::auto_ptr<ptr_type> return_type; const std::string property_type = ps.getParameter<std::string>("Class"); if (!property_type.compare("Log")) { return_type wrapped = fftjet_PeakFunctor_parser( ps.getParameter<edm::ParameterSet>("function")); ptr_type* wr = wrapped.get(); if (wr) { return_type result = return_type( new fftjet::LogProperty<fftjet::Peak>(wr, true)); wrapped.release(); return result; } } if (!property_type.compare("PeakProperty")) { const std::string member = ps.getParameter<std::string>("member"); fftjet::JetProperty<fftjet::Peak>::JetMemberFunction fcn; if (parse_peak_member_function(member.c_str(), &fcn)) return return_type( new fftjet::JetProperty<fftjet::Peak>(fcn)); else return return_type(NULL); } if (!property_type.compare("MinusScaledLaplacian")) { const double sx = ps.getParameter<double>("sx"); const double sy = ps.getParameter<double>("sx"); return return_type( new fftjet::MinusScaledLaplacian<fftjet::Peak>(sx, sy)); } if (!property_type.compare("ScaledHessianDet")) { return return_type( new fftjet::ScaledHessianDet<fftjet::Peak>()); } if (!property_type.compare("ScaledMagnitude")) { return return_type( new fftjet::ScaledMagnitude<fftjet::Peak>()); } if (!property_type.compare("ScaledMagnitude2")) { return return_type( new fftjet::ScaledMagnitude2<fftjet::Peak>()); } if (!property_type.compare("ConstDouble")) { const double value = ps.getParameter<double>("value"); return return_type(new ConstDouble<fftjet::Peak>(value)); } if (!property_type.compare("ProportionalToScale")) { const double value = ps.getParameter<double>("value"); return return_type( new ProportionalToScale<fftjet::Peak>(value)); } if (!property_type.compare("MultiplyByConst")) { const double factor = ps.getParameter<double>("factor"); return_type function = fftjet_PeakFunctor_parser( ps.getParameter<edm::ParameterSet>("function")); ptr_type* ptr = function.get(); if (ptr) { return_type result = return_type( new MultiplyByConst<fftjet::Peak>(factor, ptr, true)); function.release(); return result; } } if (!property_type.compare("CompositeFunctor")) { std::auto_ptr<fftjet::Functor1<double,double> > fcn1 = fftjet_Function_parser( ps.getParameter<edm::ParameterSet>("function1")); return_type fcn2 = fftjet_PeakFunctor_parser( ps.getParameter<edm::ParameterSet>("function2")); fftjet::Functor1<double,double>* f1 = fcn1.get(); ptr_type* f2 = fcn2.get(); if (f1 && f2) { return_type result = return_type( new CompositeFunctor<fftjet::Peak>(f1, f2, true)); fcn1.release(); fcn2.release(); return result; } } if (!property_type.compare("ProductFunctor")) { return_type fcn1 = fftjet_PeakFunctor_parser( ps.getParameter<edm::ParameterSet>("function1")); return_type fcn2 = fftjet_PeakFunctor_parser( ps.getParameter<edm::ParameterSet>("function2")); ptr_type* f1 = fcn1.get(); ptr_type* f2 = fcn2.get(); if (f1 && f2) { return_type result = return_type( new ProductFunctor<fftjet::Peak>(f1, f2, true)); fcn1.release(); fcn2.release(); return result; } } if (!property_type.compare("MagnitudeDependent")) { std::auto_ptr<fftjet::Functor1<double,double> > fcn1 = fftjet_Function_parser( ps.getParameter<edm::ParameterSet>("function")); fftjet::Functor1<double,double>* f1 = fcn1.get(); if (f1) { return_type result = return_type( new MagnitudeDependent<fftjet::Peak>(f1, true)); fcn1.release(); return result; } } if (!property_type.compare("PeakEtaDependent")) { std::auto_ptr<fftjet::Functor1<double,double> > fcn1 = fftjet_Function_parser( ps.getParameter<edm::ParameterSet>("function")); fftjet::Functor1<double,double>* f1 = fcn1.get(); if (f1) { return_type result = return_type(new PeakEtaDependent(f1, true)); fcn1.release(); return result; } } return return_type(NULL); }
std::auto_ptr< fftjet::JetMagnitudeMapper2d< fftjet::Peak > > fftjetcms::fftjet_PeakMagnitudeMapper2d_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 992 of file FFTJetParameterParser.cc.
References fftjet_LinearInterpolator2d_parser(), and edm::ParameterSet::getParameter().
{ std::auto_ptr<fftjet::LinearInterpolator2d> responseCurve = fftjet_LinearInterpolator2d_parser( ps.getParameter<edm::ParameterSet>("responseCurve")); const double minPredictor = ps.getParameter<double>("minPredictor"); const double maxPredictor = ps.getParameter<double>("maxPredictor"); const unsigned nPredPoints = ps.getParameter<unsigned>("nPredPoints"); const double maxMagnitude = ps.getParameter<double>("maxMagnitude"); const unsigned nMagPoints = ps.getParameter<unsigned>("nMagPoints"); return (std::auto_ptr<fftjet::JetMagnitudeMapper2d<fftjet::Peak> > (new fftjet::JetMagnitudeMapper2d<fftjet::Peak>( *responseCurve, new fftjetcms::PeakAbsEta<fftjet::Peak>(), true,minPredictor,maxPredictor,nPredPoints, maxMagnitude,nMagPoints))); }
std::auto_ptr< fftjet::Functor1< bool, fftjet::Peak > > fftjetcms::fftjet_PeakSelector_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 185 of file FFTJetParameterParser.cc.
References a, b, AlCaHLTBitMon_QueryRunRegistry::data, mergeVDriftHistosByStation::file, edm::ParameterSet::getParameter(), recoMuon::in, fftjetcms::EtaAndPtDependentPeakSelector::isValid(), make_param, NULL, and AlCaHLTBitMon_ParallelJobs::p.
Referenced by FFTJetPatRecoProducer::FFTJetPatRecoProducer(), and FFTJetProducer::parse_peakSelector().
{ typedef std::auto_ptr<fftjet::Functor1<bool,fftjet::Peak> > return_type; const std::string peakselector_type = ps.getParameter<std::string>( "Class"); if (!peakselector_type.compare("AllPeaksPass")) { return return_type(new fftjet::AllPeaksPass()); } if (!peakselector_type.compare("EtaAndPtDependentPeakSelector")) { const std::string file = ps.getParameter<std::string>("file"); std::ifstream in(file.c_str(), std::ios_base::in | std::ios_base::binary); if (!in.is_open()) throw cms::Exception("FFTJetBadConfig") << "Failed to open file " << file << std::endl; EtaAndPtDependentPeakSelector* ptr = new EtaAndPtDependentPeakSelector(in); if (!ptr->isValid()) throw cms::Exception("FFTJetBadConfig") << "Failed to read file " << file << std::endl; return return_type(ptr); } if (!peakselector_type.compare("EtaAndPtLookupPeakSelector")) { make_param(unsigned, nx); make_param(unsigned, ny); make_param(double, xmin); make_param(double, xmax); make_param(double, ymin); make_param(double, ymax); make_param(std::vector<double>, data); if (xmin >= xmax || ymin >= ymax || !nx || !ny || data.size() != nx*ny) throw cms::Exception("FFTJetBadConfig") << "Failed to configure EtaAndPtLookupPeakSelector" << std::endl; return return_type(new EtaAndPtLookupPeakSelector( nx, xmin, xmax, ny, ymin, ymax, data)); } if (!peakselector_type.compare("SimplePeakSelector")) { const double magCut = ps.getParameter<double>("magCut"); const double driftSpeedCut = ps.getParameter<double>("driftSpeedCut"); const double magSpeedCut = ps.getParameter<double>("magSpeedCut"); const double lifeTimeCut = ps.getParameter<double>("lifeTimeCut"); const double NNDCut = ps.getParameter<double>("NNDCut"); const double etaCut = ps.getParameter<double>("etaCut"); return return_type(new fftjet::SimplePeakSelector( magCut, driftSpeedCut ,magSpeedCut, lifeTimeCut, NNDCut, etaCut)); } if (!peakselector_type.compare("ScalePowerPeakSelector")) { const double a = ps.getParameter<double>("a"); const double p = ps.getParameter<double>("p"); const double b = ps.getParameter<double>("b"); const double etaCut = ps.getParameter<double>("etaCut"); return return_type(new fftjet::ScalePowerPeakSelector( a, p, b, etaCut)); } return return_type(NULL); }
std::auto_ptr< AbsPileupCalculator > fftjetcms::fftjet_PileupCalculator_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 951 of file FFTJetParameterParser.cc.
References fftjet_Grid2d_parser(), fftjet_LinearInterpolator2d_parser(), g, edm::ParameterSet::getParameter(), and NULL.
Referenced by FFTJetProducer::parse_pileupDensityCalc().
{ typedef std::auto_ptr<AbsPileupCalculator> return_type; const std::string fcn_type = ps.getParameter<std::string>("Class"); if (!fcn_type.compare("EtaDependentPileup")) { std::auto_ptr<fftjet::LinearInterpolator2d> interp = fftjet_LinearInterpolator2d_parser( ps.getParameter<edm::ParameterSet>("Interpolator2d")); const double inputRhoFactor = ps.getParameter<double>("inputRhoFactor"); const double outputRhoFactor = ps.getParameter<double>("outputRhoFactor"); const fftjet::LinearInterpolator2d* ip = interp.get(); if (ip) return return_type(new EtaDependentPileup( *ip, inputRhoFactor, outputRhoFactor)); else return return_type(NULL); } if (!fcn_type.compare("PileupGrid2d")) { std::auto_ptr<fftjet::Grid2d<Real> > grid = fftjet_Grid2d_parser( ps.getParameter<edm::ParameterSet>("Grid2d")); const double rhoFactor = ps.getParameter<double>("rhoFactor"); const fftjet::Grid2d<Real>* g = grid.get(); if (g) return return_type(new PileupGrid2d(*g, rhoFactor)); else return return_type(NULL); } return return_type(NULL); }
std::auto_ptr< std::vector< double > > fftjetcms::fftjet_ScaleSet_parser | ( | const edm::ParameterSet & | ps | ) |
Definition at line 414 of file FFTJetParameterParser.cc.
References className(), edm::ParameterSet::getParameter(), i, j, and NULL.
Referenced by FFTJetEFlowSmoother::FFTJetEFlowSmoother(), FFTJetPatRecoProducer::FFTJetPatRecoProducer(), FFTJetProducer::FFTJetProducer(), and FFTJetTreeDump::FFTJetTreeDump().
{ typedef std::auto_ptr<std::vector<double> > return_type; const std::string className = ps.getParameter<std::string>("Class"); if (!className.compare("EquidistantInLinearSpace") || !className.compare("EquidistantInLogSpace")) { const double minScale = ps.getParameter<double>("minScale"); const double maxScale = ps.getParameter<double>("maxScale"); const unsigned nScales = ps.getParameter<unsigned>("nScales"); if (minScale <= 0.0 || maxScale <= 0.0 || nScales == 0 || minScale == maxScale) return return_type(NULL); // Can't return pointers to EquidistantInLinearSpace // or EquidistantInLogSpace directly because std::vector // destructor is not virtual. if (!className.compare("EquidistantInLinearSpace")) return return_type(new std::vector<double>( fftjet::EquidistantInLinearSpace( minScale, maxScale, nScales))); else return return_type(new std::vector<double>( fftjet::EquidistantInLogSpace( minScale, maxScale, nScales))); } if (!className.compare("UserSet")) { return_type scales(new std::vector<double>( ps.getParameter<std::vector<double> >("scales"))); // Verify that all scales are positive and unique const unsigned nscales = scales->size(); for (unsigned i=0; i<nscales; ++i) if ((*scales)[i] <= 0.0) return return_type(NULL); for (unsigned i=1; i<nscales; ++i) for (unsigned j=0; j<i; ++j) if ((*scales)[i] == (*scales)[j]) return return_type(NULL); return scales; } return return_type(NULL); }
fftjet::RecombinedJet< VectorLike > fftjetcms::jetFromStorable | ( | const reco::FFTJet< Real > & | jet | ) |
Definition at line 61 of file jetConverters.h.
References reco::FFTJet< Real >::f_centroidEta(), reco::FFTJet< Real >::f_centroidPhi(), reco::FFTJet< Real >::f_code(), reco::FFTJet< Real >::f_convergenceDistance(), reco::FFTJet< Real >::f_etaPhiCorr(), reco::FFTJet< Real >::f_etaWidth(), reco::FFTJet< Real >::f_etSum(), reco::FFTJet< Real >::f_fuzziness(), reco::FFTJet< Real >::f_membershipFactor(), reco::FFTJet< Real >::f_ncells(), reco::FFTJet< Real >::f_phiWidth(), reco::FFTJet< Real >::f_pileup(), reco::FFTJet< Real >::f_precluster(), reco::FFTJet< Real >::f_recoScale(), reco::FFTJet< Real >::f_recoScaleRatio(), reco::FFTJet< Real >::f_status(), reco::FFTJet< Real >::f_vec(), and AlCaHLTBitMon_ParallelJobs::p.
{ typedef reco::PattRecoPeak<Real> StoredPeak; typedef fftjet::RecombinedJet<VectorLike> RecoFFTJet; double hessian[3] = {0., 0., 0.}; const StoredPeak& p(jet.f_precluster()); p.hessian(hessian); const double pileupPt = jet.f_pileup().Pt(); return RecoFFTJet(fftjet::Peak(p.eta(), p.phi(), p.magnitude(), hessian, p.driftSpeed(), p.magSpeed(), p.lifetime(), p.scale(), p.nearestNeighborDistance(), jet.f_membershipFactor(), jet.f_recoScale(), jet.f_recoScaleRatio(), p.clusterRadius(), p.clusterSeparation(), jet.f_code(), jet.f_status()), jet.f_vec(), jet.f_ncells(), jet.f_etSum(), jet.f_centroidEta(), jet.f_centroidPhi(), jet.f_etaWidth(), jet.f_phiWidth(), jet.f_etaPhiCorr(), jet.f_fuzziness(), pileupPt, 0.0, jet.f_convergenceDistance()); }
reco::FFTJet< Real > fftjetcms::jetToStorable | ( | const fftjet::RecombinedJet< VectorLike > & | jet | ) |
Definition at line 29 of file jetConverters.h.
References reco::PattRecoPeak< Real >::hessian().
{ typedef reco::PattRecoPeak<Real> StoredPeak; double hessian[3] = {0., 0., 0.}; const fftjet::Peak& peak(jet.precluster()); peak.hessian(hessian); return reco::FFTJet<Real>(StoredPeak(peak.eta(), peak.phi(), peak.magnitude(), hessian, peak.driftSpeed(), peak.magSpeed(), peak.lifetime(), peak.scale(), peak.nearestNeighborDistance(), peak.clusterRadius(), peak.clusterSeparation()), jet.vec(), jet.ncells(), jet.etSum(), jet.centroidEta(), jet.centroidPhi(), jet.etaWidth(), jet.phiWidth(), jet.etaPhiCorr(), jet.fuzziness(), jet.convergenceDistance(), jet.recoScale(), jet.recoScaleRatio(), jet.membershipFactor(), jet.code(), jet.status()); }
unsigned fftjetcms::matchOneToOne | ( | const std::vector< T1 > & | v1, |
const std::vector< T2 > & | v2, | ||
const DistanceCalculator & | calc, | ||
std::vector< int > * | matchFrom1To2, | ||
const double | maxMatchingDistance = 1.0e300 |
||
) |
Definition at line 41 of file matchOneToOne.h.
References fftjetcms::Private::matchOneToOne_MatchInfo::distance, i, fftjetcms::Private::matchOneToOne_MatchInfo::i1, fftjetcms::Private::matchOneToOne_MatchInfo::i2, m, and python::multivaluedict::sort().
Referenced by FFTJetProducer::removeFakePreclusters().
{ unsigned nused = 0; matchFrom1To2->clear(); const unsigned n1 = v1.size(); if (n1) { matchFrom1To2->reserve(n1); for (unsigned i1=0; i1<n1; ++i1) matchFrom1To2->push_back(-1); const unsigned n2 = v2.size(); if (n2) { const unsigned nmatches = n1*n2; std::vector<Private::matchOneToOne_MatchInfo> distanceTable(nmatches); std::vector<int> taken2(n2); for (unsigned i2=0; i2<n2; ++i2) taken2[i2] = 0; Private::matchOneToOne_MatchInfo* m; for (unsigned i1=0; i1<n1; ++i1) for (unsigned i2=0; i2<n2; ++i2) { m = &distanceTable[i1*n2+i2]; m->distance = calc(v1[i1], v2[i2]); m->i1 = i1; m->i2 = i2; } std::sort(distanceTable.begin(), distanceTable.end()); for (unsigned i=0; i<nmatches && nused<n1 && nused<n2; ++i) { m = &distanceTable[i]; if (m->distance > maxMatchingDistance) break; if ((*matchFrom1To2)[m->i1] < 0 && !taken2[m->i2]) { (*matchFrom1To2)[m->i1] = static_cast<int>(m->i2); taken2[m->i2] = 1; ++nused; } } } } return nused; }
void fftjetcms::sparsePeakTreeFromStorable | ( | const reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > & | in, |
const std::vector< double > * | scaleSetIfNotAdaptive, | ||
double | completeEventScale, | ||
fftjet::SparseClusteringTree< fftjet::Peak, long > * | out | ||
) |
Definition at line 139 of file clusteringTreeConverters.h.
References Exception, i, recoMuon::in, n, python::Node::node, and AlCaHLTBitMon_ParallelJobs::p.
Referenced by FFTJetPatRecoProducer::buildSparseProduct(), FFTJetProducer::loadSparseTreeData(), and FFTJetTreeDump::processTreeData().
{ typedef fftjet::SparseClusteringTree<fftjet::Peak,long> SparseTree; typedef reco::PattRecoPeak<Real> StoredPeak; typedef reco::PattRecoNode<StoredPeak> StoredNode; typedef reco::PattRecoTree<Real,StoredPeak> StoredTree; if (!in.isSparse()) throw cms::Exception("FFTJetBadConfig") << "can't restore sparse clustering tree" << " from densely stored record" << std::endl; assert(out); out->clear(); const std::vector<StoredNode>& nodes(in.getNodes()); const unsigned n = nodes.size(); out->reserveNodes(n + 1U); double hessian[3] = {0., 0., 0.}; for (unsigned i=0; i<n; ++i) { const StoredNode& snode(nodes[i]); const StoredPeak& p(snode.getCluster()); p.hessian(hessian); const SparseTree::Node node( fftjet::Peak(p.eta(), p.phi(), p.magnitude(), hessian, p.driftSpeed(), p.magSpeed(), p.lifetime(), p.scale(), p.nearestNeighborDistance(), 1.0, 0.0, 0.0, p.clusterRadius(), p.clusterSeparation()), snode.originalLevel(), snode.mask()); out->addNode(node, snode.parent()); } const std::vector<Real>& storedScales(in.getScales()); if (!storedScales.empty()) { const unsigned nsc = storedScales.size(); out->reserveScales(nsc + 1U); out->addScale(DBL_MAX); const Real* scales = &storedScales[0]; for (unsigned i=0; i<nsc; ++i) out->addScale(scales[i]); } else if (scaleSetIfNotAdaptive && !scaleSetIfNotAdaptive->empty()) { const unsigned nsc = scaleSetIfNotAdaptive->size(); // There may be the "complete event" scale added at the end. // Reserve a sufficient number of scales to take this into // account. if (completeEventScale) out->reserveScales(nsc + 2U); else out->reserveScales(nsc + 1U); out->addScale(DBL_MAX); const double* scales = &(*scaleSetIfNotAdaptive)[0]; for (unsigned i=0; i<nsc; ++i) out->addScale(scales[i]); if (completeEventScale) out->addScale(completeEventScale); } else { throw cms::Exception("FFTJetBadConfig") << "can't restore sparse clustering tree scales" << std::endl; } }
void fftjetcms::sparsePeakTreeToStorable | ( | const fftjet::SparseClusteringTree< fftjet::Peak, long > & | in, |
bool | writeOutScaleInfo, | ||
reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > * | out | ||
) |
Definition at line 79 of file clusteringTreeConverters.h.
References i, python::Node::node, and diffTreeTool::tree.
Referenced by FFTJetPatRecoProducer::buildSparseProduct().
{ typedef fftjet::SparseClusteringTree<fftjet::Peak,long> SparseTree; typedef reco::PattRecoPeak<Real> StoredPeak; typedef reco::PattRecoNode<StoredPeak> StoredNode; typedef reco::PattRecoTree<Real,StoredPeak> StoredTree; assert(tree); tree->clear(); tree->setSparse(true); const unsigned nNodes = sparseTree.size(); double hessian[3] = {0., 0., 0.}; // Do not write out the meaningless top node tree->reserveNodes(nNodes - 1); for (unsigned i=1; i<nNodes; ++i) { const SparseTree::Node& node(sparseTree.getNode(i)); const fftjet::Peak& peak(node.getCluster()); peak.hessian(hessian); StoredNode sn(StoredPeak(peak.eta(), peak.phi(), peak.magnitude(), hessian, peak.driftSpeed(), peak.magSpeed(), peak.lifetime(), peak.scale(), peak.nearestNeighborDistance(), peak.clusterRadius(), peak.clusterSeparation()), node.originalLevel(), node.mask(), node.parent()); tree->addNode(sn); } // Do we want to write out the scales? We will use the following // convention: if the tree is using an adaptive algorithm, the scales // will be written out. If not, they are not going to change from // event to event. In this case the scales would waste disk space // for no particularly good reason, so they will not be written out. if (writeOutScaleInfo) { // Do not write out the meaningless top-level scale const unsigned nScales = sparseTree.nLevels(); tree->reserveScales(nScales - 1); for (unsigned i=1; i<nScales; ++i) tree->addScale(sparseTree.getScale(i)); } }