dd/d0e/FFTJetPatRecoProducer_8cc_source.html

 // -*- C++ -*-

 //

 // Package:    FFTJetProducers

 // Class:      FFTJetPatRecoProducer

 //

 //

 // Original Author:  Igor Volobouev

 //         Created:  Tue Jun 15 12:45:45 CDT 2010

 //

 //


 #include <fstream>


 // FFTJet headers

 #include "fftjet/ProximityClusteringTree.hh"

 #include "fftjet/ClusteringSequencer.hh"

 #include "fftjet/ClusteringTreeSparsifier.hh"

 #include "fftjet/FrequencyKernelConvolver.hh"

 #include "fftjet/FrequencySequentialConvolver.hh"

 #include "fftjet/DiscreteGauss1d.hh"

 #include "fftjet/DiscreteGauss2d.hh"


 // framework include files

 #include "FWCore/Framework/interface/Frameworkfwd.h"

 #include "FWCore/Framework/interface/MakerMacros.h"

 #include "FWCore/ParameterSet/interface/ParameterSet.h"


 #include "DataFormats/Common/interface/View.h"

 #include "DataFormats/JetReco/interface/CaloJetCollection.h"

 #include "DataFormats/JetReco/interface/GenJetCollection.h"

 #include "DataFormats/JetReco/interface/PFJetCollection.h"

 #include "DataFormats/JetReco/interface/BasicJetCollection.h"

 #include "DataFormats/JetReco/interface/TrackJetCollection.h"

 #include "DataFormats/Candidate/interface/Candidate.h"


 // Energy flow object

 #include "DataFormats/JetReco/interface/DiscretizedEnergyFlow.h"


 // parameter parser header

 #include "RecoJets/FFTJetProducers/interface/FFTJetParameterParser.h"


 // functions which manipulate storable trees

 #include "RecoJets/FFTJetAlgorithms/interface/clusteringTreeConverters.h"


 // functions which manipulate energy discretization grids

 #include "RecoJets/FFTJetAlgorithms/interface/gridConverters.h"


 // useful utilities collected in the second base

 #include "RecoJets/FFTJetProducers/interface/FFTJetInterface.h"


 using namespace fftjetcms;


 //

 // class declaration

 //

 class FFTJetPatRecoProducer : public FFTJetInterface

 {

 public:

     explicit FFTJetPatRecoProducer(const edm::ParameterSet&);

     ~FFTJetPatRecoProducer();


 protected:

     // Useful local typedefs

     typedef fftjet::ProximityClusteringTree<fftjet::Peak,long> ClusteringTree;

     typedef fftjet::SparseClusteringTree<fftjet::Peak,long> SparseTree;

     typedef fftjet::ClusteringSequencer<Real> Sequencer;

     typedef fftjet::ClusteringTreeSparsifier<fftjet::Peak,long> Sparsifier;


     // methods

     void beginJob() override ;

     void produce(edm::Event&, const edm::EventSetup&) override;

     void endJob() override ;


     void buildKernelConvolver(const edm::ParameterSet&);

     fftjet::PeakFinder buildPeakFinder(const edm::ParameterSet&);


     template<class Real>

     void buildSparseProduct(edm::Event&) const;


     template<class Real>

     void buildDenseProduct(edm::Event&) const;


     // The complete clustering tree

     ClusteringTree* clusteringTree;


     // Basically, we need to create FFTJet objects

     // ClusteringSequencer and ClusteringTreeSparsifier

     // which will subsequently perform most of the work

     std::auto_ptr<Sequencer> sequencer;

     std::auto_ptr<Sparsifier> sparsifier;


     // The FFT engine(s)

     std::auto_ptr<MyFFTEngine> engine;

     std::auto_ptr<MyFFTEngine> anotherEngine;


     // The pattern recognition kernel(s)

     std::auto_ptr<fftjet::AbsFrequencyKernel> kernel2d;

     std::auto_ptr<fftjet::AbsFrequencyKernel1d> etaKernel;

     std::auto_ptr<fftjet::AbsFrequencyKernel1d> phiKernel;


     // The kernel convolver

     std::auto_ptr<fftjet::AbsConvolverBase<Real> > convolver;


     // The peak selector for the clustering tree

     std::auto_ptr<fftjet::Functor1<bool,fftjet::Peak> > peakSelector;


     // Distance calculator for the clustering tree

     std::auto_ptr<fftjet::AbsDistanceCalculator<fftjet::Peak> > distanceCalc;


     // The sparse clustering tree

     SparseTree sparseTree;


     // The following parameters will define the behavior

     // of the algorithm wrt insertion of the complete event

     // into the clustering tree

     const double completeEventDataCutoff;


     // Are we going to make clustering trees?

     const bool makeClusteringTree;


     // Are we going to verify the data conversion for double precision

     // storage?

     const bool verifyDataConversion;


     // Are we going to store the discretization grid?

     const bool storeDiscretizationGrid;


     // Sparsify the clustering tree?

     const bool sparsify;


 private:

     FFTJetPatRecoProducer();

     FFTJetPatRecoProducer(const FFTJetPatRecoProducer&);

     FFTJetPatRecoProducer& operator=(const FFTJetPatRecoProducer&);


     // Members needed for storing grids externally

     std::ofstream externalGridStream;

     bool storeGridsExternally;

     fftjet::Grid2d<float>* extGrid;

 };


 //

 // constructors and destructor

 //

 FFTJetPatRecoProducer::FFTJetPatRecoProducer(const edm::ParameterSet& ps)

     : FFTJetInterface(ps),

       clusteringTree(0),

       completeEventDataCutoff(ps.getParameter<double>("completeEventDataCutoff")),

       makeClusteringTree(ps.getParameter<bool>("makeClusteringTree")),

       verifyDataConversion(ps.getUntrackedParameter<bool>("verifyDataConversion",false)),

       storeDiscretizationGrid(ps.getParameter<bool>("storeDiscretizationGrid")),

       sparsify(ps.getParameter<bool>("sparsify")),

       extGrid(0)

 {

     // register your products

     if (makeClusteringTree)

     {

         if (storeInSinglePrecision())

             produces<reco::PattRecoTree<float,reco::PattRecoPeak<float> > >(outputLabel);

         else

             produces<reco::PattRecoTree<double,reco::PattRecoPeak<double> > >(outputLabel);

     }

     if (storeDiscretizationGrid)

         produces<reco::DiscretizedEnergyFlow>(outputLabel);


     // Check if we want to write the grids into an external file

     const std::string externalGridFile(ps.getParameter<std::string>("externalGridFile"));

     storeGridsExternally = externalGridFile.size() > 0;

     if (storeGridsExternally)

     {

         externalGridStream.open(externalGridFile.c_str(), std::ios_base::out |

                                                           std::ios_base::binary);

         if (!externalGridStream.is_open())

             throw cms::Exception("FFTJetBadConfig")

                 << "FFTJetPatRecoProducer failed to open file "

                 << externalGridFile << std::endl;

     }


     if (!makeClusteringTree && !storeDiscretizationGrid && !storeGridsExternally)

     {

         throw cms::Exception("FFTJetBadConfig")

             << "FFTJetPatRecoProducer is not configured to produce anything"

             << std::endl;

     }


     // now do whatever other initialization is needed


     // Build the discretization grid

     energyFlow = fftjet_Grid2d_parser(

         ps.getParameter<edm::ParameterSet>("GridConfiguration"));

     checkConfig(energyFlow, "invalid discretization grid");


     // Build the FFT engine(s), pattern recognition kernel(s),

     // and the kernel convolver

     buildKernelConvolver(ps);


     // Build the peak selector

     peakSelector = fftjet_PeakSelector_parser(

         ps.getParameter<edm::ParameterSet>("PeakSelectorConfiguration"));

     checkConfig(peakSelector, "invalid peak selector");


     // Build the initial set of pattern recognition scales

     std::auto_ptr<std::vector<double> > iniScales = fftjet_ScaleSet_parser(

         ps.getParameter<edm::ParameterSet>("InitialScales"));

     checkConfig(iniScales, "invalid set of scales");


     // Do we want to use the adaptive clustering tree algorithm?

     const unsigned maxAdaptiveScales =

         ps.getParameter<unsigned>("maxAdaptiveScales");

     const double minAdaptiveRatioLog =

         ps.getParameter<double>("minAdaptiveRatioLog");

     if (minAdaptiveRatioLog <= 0.0)

         throw cms::Exception("FFTJetBadConfig")

             << "bad adaptive ratio logarithm limit" << std::endl;


     // Make sure that all standard scales are larger than the

     // complete event scale

     if (getEventScale() > 0.0)

     {

       const double cs = getEventScale();

       const unsigned nscales = iniScales->size();

       for (unsigned i=0; i<nscales; ++i)

         if (cs >= (*iniScales)[i])

       throw cms::Exception("FFTJetBadConfig")

         << "incompatible scale for complete event" << std::endl;

     }


     // At this point we are ready to build the clustering sequencer

     sequencer = std::auto_ptr<Sequencer>(new Sequencer(

         convolver.get(), peakSelector.get(), buildPeakFinder(ps),

         *iniScales, maxAdaptiveScales, minAdaptiveRatioLog));


     // Build the clustering tree sparsifier

     const edm::ParameterSet& SparsifierConfiguration(

         ps.getParameter<edm::ParameterSet>("SparsifierConfiguration"));

     sparsifier = fftjet_ClusteringTreeSparsifier_parser(

         SparsifierConfiguration);

     checkConfig(sparsifier, "invalid sparsifier parameters");


     // Build the distance calculator for the clustering tree

     const edm::ParameterSet& TreeDistanceCalculator(

         ps.getParameter<edm::ParameterSet>("TreeDistanceCalculator"));

     distanceCalc = fftjet_DistanceCalculator_parser(TreeDistanceCalculator);

     checkConfig(distanceCalc, "invalid tree distance calculator");


     // Build the clustering tree itself

     clusteringTree = new ClusteringTree(distanceCalc.get());

 }


 void FFTJetPatRecoProducer::buildKernelConvolver(const edm::ParameterSet& ps)

 {

     // Check the parameter named "etaDependentScaleFactors". If the vector

     // of scales is empty we will use 2d kernel, otherwise use 1d kernels

     const std::vector<double> etaDependentScaleFactors(

         ps.getParameter<std::vector<double> >("etaDependentScaleFactors"));


     // Make sure that the number of scale factors provided is correct

     const bool use2dKernel = etaDependentScaleFactors.empty();

     if (!use2dKernel)

         if (etaDependentScaleFactors.size() != energyFlow->nEta())

             throw cms::Exception("FFTJetBadConfig")

                 << "invalid number of eta-dependent scale factors"

                 << std::endl;


     // Get the eta and phi scales for the kernel(s)

     double kernelEtaScale = ps.getParameter<double>("kernelEtaScale");

     const double kernelPhiScale = ps.getParameter<double>("kernelPhiScale");

     if (kernelEtaScale <= 0.0 || kernelPhiScale <= 0.0)

         throw cms::Exception("FFTJetBadConfig")

             << "invalid kernel scale" << std::endl;


     // FFT assumes that the grid extent in eta is 2*Pi. Adjust the

     // kernel scale in eta to compensate.

     kernelEtaScale *= (2.0*M_PI/(energyFlow->etaMax() - energyFlow->etaMin()));


     // Are we going to try to fix the efficiency near detector edges?

     const bool fixEfficiency = ps.getParameter<bool>("fixEfficiency");


     // Minimum and maximum eta bin for the convolver

     unsigned convolverMinBin = 0, convolverMaxBin = 0;

     if (fixEfficiency || !use2dKernel)

     {

         convolverMinBin = ps.getParameter<unsigned>("convolverMinBin");

         convolverMaxBin = ps.getParameter<unsigned>("convolverMaxBin");

     }


     if (use2dKernel)

     {

         // Build the FFT engine

         engine = std::auto_ptr<MyFFTEngine>(

             new MyFFTEngine(energyFlow->nEta(), energyFlow->nPhi()));


         // 2d kernel

         kernel2d = std::auto_ptr<fftjet::AbsFrequencyKernel>(

             new fftjet::DiscreteGauss2d(

                 kernelEtaScale, kernelPhiScale,

                 energyFlow->nEta(), energyFlow->nPhi()));


         // 2d convolver

         convolver = std::auto_ptr<fftjet::AbsConvolverBase<Real> >(

             new fftjet::FrequencyKernelConvolver<Real,Complex>(

                 engine.get(), kernel2d.get(),

                 convolverMinBin, convolverMaxBin));

     }

     else

     {

         // Need separate FFT engines for eta and phi

         engine = std::auto_ptr<MyFFTEngine>(

             new MyFFTEngine(1, energyFlow->nEta()));

         anotherEngine = std::auto_ptr<MyFFTEngine>(

             new MyFFTEngine(1, energyFlow->nPhi()));


         // 1d kernels

         etaKernel = std::auto_ptr<fftjet::AbsFrequencyKernel1d>(

             new fftjet::DiscreteGauss1d(kernelEtaScale, energyFlow->nEta()));


         phiKernel = std::auto_ptr<fftjet::AbsFrequencyKernel1d>(

             new fftjet::DiscreteGauss1d(kernelPhiScale, energyFlow->nPhi()));


         // Sequential convolver

         convolver = std::auto_ptr<fftjet::AbsConvolverBase<Real> >(

             new fftjet::FrequencySequentialConvolver<Real,Complex>(

                 engine.get(), anotherEngine.get(),

                 etaKernel.get(), phiKernel.get(),

                 etaDependentScaleFactors, convolverMinBin,

                 convolverMaxBin, fixEfficiency));

     }

 }


 fftjet::PeakFinder FFTJetPatRecoProducer::buildPeakFinder(const edm::ParameterSet& ps)

 {

     const double peakFinderMaxEta = ps.getParameter<double>("peakFinderMaxEta");

     if (peakFinderMaxEta <= 0.0)

         throw cms::Exception("FFTJetBadConfig")

             << "invalid peak finder eta cut" << std::endl;

     const double maxMagnitude = ps.getParameter<double>("peakFinderMaxMagnitude");

     int minBin = energyFlow->getEtaBin(-peakFinderMaxEta);

     if (minBin < 0)

         minBin = 0;

     int maxBin = energyFlow->getEtaBin(peakFinderMaxEta) + 1;

     if (maxBin < 0)

         maxBin = 0;

     return fftjet::PeakFinder(maxMagnitude, true, minBin, maxBin);

 }


 FFTJetPatRecoProducer::~FFTJetPatRecoProducer()

 {

     // do anything here that needs to be done at desctruction time

     // (e.g. close files, deallocate resources etc.)

     delete clusteringTree;

     delete extGrid;

 }


 //

 // member functions

 //

 template<class Real>

 void FFTJetPatRecoProducer::buildSparseProduct(edm::Event& ev) const

 {

     typedef reco::PattRecoTree<Real,reco::PattRecoPeak<Real> > StoredTree;


     std::auto_ptr<StoredTree> tree(new StoredTree());


     sparsePeakTreeToStorable(sparseTree,

                              sequencer->maxAdaptiveScales(),

                              tree.get());


     // Check that we can restore the tree

     if (verifyDataConversion && !storeInSinglePrecision())

     {

         SparseTree check;

         const std::vector<double>& scalesUsed(sequencer->getInitialScales());

         sparsePeakTreeFromStorable(*tree, &scalesUsed, getEventScale(), &check);

         if (sparseTree != check)

             throw cms::Exception("FFTJetInterface")

                 << "Data conversion failed for sparse clustering tree"

                 << std::endl;

     }


     ev.put(tree, outputLabel);

 }


 template<class Real>

 void FFTJetPatRecoProducer::buildDenseProduct(edm::Event& ev) const

 {

     typedef reco::PattRecoTree<Real,reco::PattRecoPeak<Real> > StoredTree;


     std::auto_ptr<StoredTree> tree(new StoredTree());


     densePeakTreeToStorable(*clusteringTree,

                             sequencer->maxAdaptiveScales(),

                             tree.get());


     // Check that we can restore the tree

     if (verifyDataConversion && !storeInSinglePrecision())

     {

         ClusteringTree check(distanceCalc.get());

         const std::vector<double>& scalesUsed(sequencer->getInitialScales());

         densePeakTreeFromStorable(*tree, &scalesUsed, getEventScale(), &check);

         if (*clusteringTree != check)

             throw cms::Exception("FFTJetInterface")

                 << "Data conversion failed for dense clustering tree"

                 << std::endl;

     }


     ev.put(tree, outputLabel);

 }


 // ------------ method called to produce the data  ------------

 void FFTJetPatRecoProducer::produce(

     edm::Event& iEvent, const edm::EventSetup& iSetup)

 {

     loadInputCollection(iEvent);

     discretizeEnergyFlow();


     if (makeClusteringTree)

     {

         sequencer->run(*energyFlow, clusteringTree);

         if (getEventScale() > 0.0)

         sequencer->insertCompleteEvent(getEventScale(), *energyFlow,

                                            clusteringTree, completeEventDataCutoff);


         if (sparsify)

         {

             sparsifier->sparsify(*clusteringTree, &sparseTree);


             // Do not call the "sortNodes" method of the sparse tree here.

             // Currently, the nodes are sorted by daughter number.

             // This is the way we want it in storage because the stored

             // tree does not include daughter ordering info explicitly.


             if (storeInSinglePrecision())

                 buildSparseProduct<float>(iEvent);

             else

                 buildSparseProduct<double>(iEvent);

         }

         else

         {

         if (storeInSinglePrecision())

                 buildDenseProduct<float>(iEvent);

             else

                 buildDenseProduct<double>(iEvent);

         }

     }


     if (storeDiscretizationGrid)

     {

         const fftjet::Grid2d<Real>& g(*energyFlow);


         std::auto_ptr<reco::DiscretizedEnergyFlow> flow(

             new reco::DiscretizedEnergyFlow(

                 g.data(), g.title(), g.etaMin(), g.etaMax(),

                 g.phiBin0Edge(), g.nEta(), g.nPhi()));


         if (verifyDataConversion)

         {

             fftjet::Grid2d<Real> check(

                 flow->nEtaBins(), flow->etaMin(), flow->etaMax(),

                 flow->nPhiBins(), flow->phiBin0Edge(), flow->title());

             check.blockSet(flow->data(), flow->nEtaBins(), flow->nPhiBins());

             assert(g == check);

         }


         iEvent.put(flow, outputLabel);

     }


     if (storeGridsExternally)

     {

         if (extGrid)

             copy_Grid2d_data(extGrid, *energyFlow);

         else

             extGrid = convert_Grid2d_to_float(*energyFlow);

         if (!extGrid->write(externalGridStream))

         {

             throw cms::Exception("FFTJetPatRecoProducer::produce")

                 << "Failed to write grid data into an external file"

                 << std::endl;

         }

     }

 }


 // ------------ method called once each job just before starting event loop

 void FFTJetPatRecoProducer::beginJob()

 {

 }


 // ------------ method called once each job just after ending the event loop

 void FFTJetPatRecoProducer::endJob()

 {

     if (storeGridsExternally)

         externalGridStream.close();

 }


 //define this as a plug-in

 DEFINE_FWK_MODULE(FFTJetPatRecoProducer);

edm::ParameterSet::getParameter
T getParameter(std::string const &) const

i
int i
Definition: DBlmapReader.cc:9

fftjetcms::convert_Grid2d_to_float
fftjet::Grid2d< float > * convert_Grid2d_to_float(const fftjet::Grid2d< Numeric > &grid)
Definition: gridConverters.h:71

FFTJetPatRecoProducer::peakSelector
std::auto_ptr< fftjet::Functor1< bool, fftjet::Peak > > peakSelector
Definition: FFTJetPatRecoProducer.cc:112

BasicJetCollection.h

fftjetcms::FFTJetInterface::energyFlow
std::auto_ptr< fftjet::Grid2d< fftjetcms::Real > > energyFlow
Definition: FFTJetInterface.h:102

fwrapper::cs
auto_ptr< ClusterSequence > cs
Definition: fastjetfortran_madfks.cc:45

PFJetCollection.h

reco::PattRecoTree
Class for storing FFTJet sparse clustering trees.
Definition: PattRecoTree.h:18

FFTJetPatRecoProducer::phiKernel
std::auto_ptr< fftjet::AbsFrequencyKernel1d > phiKernel
Definition: FFTJetPatRecoProducer.cc:106

FFTJetPatRecoProducer::externalGridStream
std::ofstream externalGridStream
Definition: FFTJetPatRecoProducer.cc:144

FFTJetPatRecoProducer::beginJob
void beginJob() override
Definition: FFTJetPatRecoProducer.cc:497

fftjetcms::fftjet_Grid2d_parser
std::auto_ptr< fftjet::Grid2d< Real > > fftjet_Grid2d_parser(const edm::ParameterSet &ps)
Definition: FFTJetParameterParser.cc:132

DEFINE_FWK_MODULE
#define DEFINE_FWK_MODULE(type)
Definition: MakerMacros.h:17

fftjetcms::FFTJetInterface::loadInputCollection
void loadInputCollection(const edm::Event &)
Definition: FFTJetInterface.cc:54

CaloJetCollection.h

MakerMacros.h

FFTJetPatRecoProducer::buildSparseProduct
void buildSparseProduct(edm::Event &) const
Definition: FFTJetPatRecoProducer.cc:369

FFTJetPatRecoProducer::buildKernelConvolver
void buildKernelConvolver(const edm::ParameterSet &)
Definition: FFTJetPatRecoProducer.cc:258

diffTreeTool.tree
tuple tree
Definition: diffTreeTool.py:129

FFTJetPatRecoProducer
Definition: FFTJetPatRecoProducer.cc:63

fftjetcms::FFTJetInterface::checkConfig
void checkConfig(const Ptr &ptr, const char *message)
Definition: FFTJetInterface.h:61

ev
bool ev
Definition: Hydjet2Hadronizer.cc:90

FFTJetParameterParser.h

FFTJetPatRecoProducer::buildDenseProduct
void buildDenseProduct(edm::Event &) const
Definition: FFTJetPatRecoProducer.cc:396

Frameworkfwd.h

g
The Signals That Services Can Subscribe To This is based on ActivityRegistry and is current per Services can connect to the signals distributed by the ActivityRegistry in order to monitor the activity of the application Each possible callback has some defined which we here list in angle e g
Definition: Activities.doc:4

FFTJetPatRecoProducer::storeDiscretizationGrid
const bool storeDiscretizationGrid
Definition: FFTJetPatRecoProducer.cc:133

AlCaHLTBitMon_QueryRunRegistry.string
string string
Definition: AlCaHLTBitMon_QueryRunRegistry.py:255

bk::beginJob
void beginJob()
Definition: Breakpoints.cc:15

FFTJetPatRecoProducer::anotherEngine
std::auto_ptr< MyFFTEngine > anotherEngine
Definition: FFTJetPatRecoProducer.cc:101

DiscretizedEnergyFlow.h

ParameterSet.h

Candidate.h

fftjetcms::fftjet_PeakSelector_parser
std::auto_ptr< fftjet::Functor1< bool, fftjet::Peak > > fftjet_PeakSelector_parser(const edm::ParameterSet &ps)
Definition: FFTJetParameterParser.cc:193

fftjetcms::FFTJetInterface::getEventScale
double getEventScale() const
Definition: FFTJetInterface.cc:48

iEvent
int iEvent
Definition: GenABIO.cc:230

FFTJetPatRecoProducer::kernel2d
std::auto_ptr< fftjet::AbsFrequencyKernel > kernel2d
Definition: FFTJetPatRecoProducer.cc:104

FFTJetPatRecoProducer::produce
void produce(edm::Event &, const edm::EventSetup &) override
Definition: FFTJetPatRecoProducer.cc:423

edm::Event::put
OrphanHandle< PROD > put(std::auto_ptr< PROD > product)
Put a new product.
Definition: Event.h:116

fftjetcms::sparsePeakTreeToStorable
void sparsePeakTreeToStorable(const fftjet::SparseClusteringTree< fftjet::Peak, long > &in, bool writeOutScaleInfo, reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > *out)
Definition: clusteringTreeConverters.h:79

CastorDataFrameFilter_impl::check
bool check(const DataFrame &df, bool capcheck, bool dvercheck)
Definition: CastorDataFrameFilter.cc:6

FFTJetPatRecoProducer::clusteringTree
ClusteringTree * clusteringTree
Definition: FFTJetPatRecoProducer.cc:91

GenJetCollection.h

FFTJetPatRecoProducer::Sequencer
fftjet::ClusteringSequencer< Real > Sequencer
Definition: FFTJetPatRecoProducer.cc:73

View.h

FFTJetPatRecoProducer::engine
std::auto_ptr< MyFFTEngine > engine
Definition: FFTJetPatRecoProducer.cc:100

edm::EventSetup
Definition: EventSetup.h:44

FFTJetPatRecoProducer::sparsifier
std::auto_ptr< Sparsifier > sparsifier
Definition: FFTJetPatRecoProducer.cc:97

reco::DiscretizedEnergyFlow
Definition: DiscretizedEnergyFlow.h:20

M_PI
#define M_PI
Definition: readTestVector.cc:25

FFTJetPatRecoProducer::distanceCalc
std::auto_ptr< fftjet::AbsDistanceCalculator< fftjet::Peak > > distanceCalc
Definition: FFTJetPatRecoProducer.cc:115

fftjetcms::FFTJetInterface::storeInSinglePrecision
bool storeInSinglePrecision() const
Definition: FFTJetInterface.cc:15

fftjetcms::densePeakTreeToStorable
void densePeakTreeToStorable(const fftjet::AbsClusteringTree< fftjet::Peak, long > &in, bool writeOutScaleInfo, reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > *out)
Definition: clusteringTreeConverters.h:222

dbtoconf.out
tuple out
Definition: dbtoconf.py:99

FFTJetPatRecoProducer::completeEventDataCutoff
const double completeEventDataCutoff
Definition: FFTJetPatRecoProducer.cc:123

FFTJetPatRecoProducer::makeClusteringTree
const bool makeClusteringTree
Definition: FFTJetPatRecoProducer.cc:126

fftjetcms::sparsePeakTreeFromStorable
void sparsePeakTreeFromStorable(const reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > &in, const std::vector< double > *scaleSetIfNotAdaptive, double completeEventScale, fftjet::SparseClusteringTree< fftjet::Peak, long > *out)
Definition: clusteringTreeConverters.h:141

edm::hlt::Exception
error
Definition: HLTenums.h:21

fftjetcms::densePeakTreeFromStorable
void densePeakTreeFromStorable(const reco::PattRecoTree< Real, reco::PattRecoPeak< Real > > &in, const std::vector< double > *scaleSetIfNotAdaptive, double completeEventScale, fftjet::AbsClusteringTree< fftjet::Peak, long > *out)
Definition: clusteringTreeConverters.h:288

clusteringTreeConverters.h

FFTJetPatRecoProducer::Sparsifier
fftjet::ClusteringTreeSparsifier< fftjet::Peak, long > Sparsifier
Definition: FFTJetPatRecoProducer.cc:74

TrackJetCollection.h

cms::Exception
Definition: Exception.h:68

FFTJetPatRecoProducer::etaKernel
std::auto_ptr< fftjet::AbsFrequencyKernel1d > etaKernel
Definition: FFTJetPatRecoProducer.cc:105

FFTJetPatRecoProducer::FFTJetPatRecoProducer
FFTJetPatRecoProducer()

fftjetcms::FFTJetInterface
Definition: FFTJetInterface.h:52

fftjetcms::copy_Grid2d_data
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Definition: gridConverters.h:43

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void discretizeEnergyFlow()
Definition: FFTJetInterface.cc:100

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Definition: FFTJetParameterParser.cc:502

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fftjet::PeakFinder buildPeakFinder(const edm::ParameterSet &)
Definition: FFTJetPatRecoProducer.cc:339

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Definition: FFTJetPatRecoProducer.cc:96

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Definition: FFTJetPatRecoProducer.cc:118

FFTJetPatRecoProducer::convolver
std::auto_ptr< fftjet::AbsConvolverBase< Real > > convolver
Definition: FFTJetPatRecoProducer.cc:109

fftjetcms::fftjet_ClusteringTreeSparsifier_parser
std::auto_ptr< fftjet::ClusteringTreeSparsifier< fftjet::Peak, long > > fftjet_ClusteringTreeSparsifier_parser(const edm::ParameterSet &ps)
Definition: FFTJetParameterParser.cc:479

FFTJetPatRecoProducer::sparsify
const bool sparsify
Definition: FFTJetPatRecoProducer.cc:136

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fftjet::FFTWDoubleEngine MyFFTEngine
Definition: fftjetTypedefs.h:23

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Definition: ParameterSet.h:35

FFTJetPatRecoProducer::endJob
void endJob() override
Definition: FFTJetPatRecoProducer.cc:503

gridConverters.h

edm::false
volatile std::atomic< bool > shutdown_flag false
Definition: UnixSignalHandlers.cc:22

FFTJetPatRecoProducer::ClusteringTree
fftjet::ProximityClusteringTree< fftjet::Peak, long > ClusteringTree
Definition: FFTJetPatRecoProducer.cc:71

FFTJetPatRecoProducer::verifyDataConversion
const bool verifyDataConversion
Definition: FFTJetPatRecoProducer.cc:130

FFTJetPatRecoProducer::SparseTree
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Definition: FFTJetPatRecoProducer.cc:72

FFTJetPatRecoProducer::storeGridsExternally
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Definition: FFTJetPatRecoProducer.cc:145

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Definition: Event.h:62

FFTJetPatRecoProducer::extGrid
fftjet::Grid2d< float > * extGrid
Definition: FFTJetPatRecoProducer.cc:146

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const std::string outputLabel
Definition: FFTJetInterface.h:78

fftjetcms::fftjet_ScaleSet_parser
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Definition: FFTJetParameterParser.cc:425

FFTJetPatRecoProducer::~FFTJetPatRecoProducer
~FFTJetPatRecoProducer()
Definition: FFTJetPatRecoProducer.cc:356

FFTJetInterface.h