#include <FFTGenericScaleCalculator.h>

Inheritance diagram for FFTGenericScaleCalculator:

Public Member Functions
	FFTGenericScaleCalculator (const edm::ParameterSet &ps)

void	mapFFTJet (const reco::Jet &jet, const reco::FFTJet< float > &fftJet, const math::XYZTLorentzVector &current, double *buf, unsigned dim) const override

	~FFTGenericScaleCalculator () override

Public Member Functions inherited from AbsFFTSpecificScaleCalculator
virtual	~AbsFFTSpecificScaleCalculator ()

Private Member Functions
double	f_safeLog (const double x) const

Private Attributes
int	m_aveConstituentPt

int	m_averageWidth

int	m_chargedEmEnergyFraction

int	m_chargedHadronEnergyFraction

int	m_chargedHadronMultiplicity

int	m_chargedMuEnergyFraction

int	m_chargedMultiplicity

int	m_clusterRadius

int	m_clusterSeparation

int	m_constituentEtaPhiSpread

int	m_constituentPtDistribution

int	m_convergenceDistance

int	m_dRFromJet

int	m_driftSpeed

int	m_electronEnergyFraction

int	m_electronMultiplicity

int	m_EmEnergyFraction

int	m_energy

int	m_eta

int	m_etaPhiCorr

int	m_etaWidth

int	m_etSum

std::vector< double >	m_factors

int	m_fuzziness

int	m_gamma

int	m_HessianS2

int	m_HessianS4

int	m_HessianS6

int	m_HFEMEnergyFraction

int	m_HFEMMultiplicity

int	m_HFHadronEnergyFraction

int	m_HFHadronMultiplicity

int	m_LaplacianS1

int	m_LaplacianS2

int	m_LaplacianS3

int	m_lifetime

int	m_logAveConstituentPt

int	m_logEnergy

int	m_logGamma

int	m_logMagnitude

int	m_LogMagS1

int	m_LogMagS2

int	m_logMass

int	m_logPt

int	m_logScale

int	m_magnitude

int	m_magS1

int	m_magS2

int	m_magSpeed

int	m_mass

int	m_membershipFactor

int	m_mergeTime

double	m_minLog

int	m_muonEnergyFraction

int	m_muonMultiplicity

int	m_ncells

int	m_nConstituents

int	m_nearestNeighborDistance

int	m_neutralEmEnergyFraction

int	m_neutralHadronEnergyFraction

int	m_neutralHadronMultiplicity

int	m_neutralMultiplicity

int	m_phi

int	m_phiWidth

int	m_photonEnergyFraction

int	m_photonMultiplicity

int	m_pileup

int	m_pt

int	m_recoScale

int	m_recoScaleRatio

int	m_scale

int	m_splitTime

int	m_widthRatio

Detailed Description

Definition at line 13 of file FFTGenericScaleCalculator.h.

Constructor & Destructor Documentation

◆ FFTGenericScaleCalculator()

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

Definition at line 29 of file FFTGenericScaleCalculator.cc.

References reco::btau::chargedHadronEnergyFraction, reco::btau::chargedHadronMultiplicity, check_param, fftjetproducer_cfi::convergenceDistance, reco::btau::electronEnergyFraction, reco::btau::electronMultiplicity, hcalRecHitTable_cff::energy, PVValHelper::eta, electrons_cff::etaWidth, Exception, CustomPhysics_cfi::gamma, mps_fire::i, m_factors, ALPAKA_ACCELERATOR_NAMESPACE::pixelClustering::pixelStatus::mask, EgHLTOffHistBins_cfi::mass, reco::btau::muonEnergyFraction, reco::btau::muonMultiplicity, custom_jme_cff::nConstituents, reco::btau::neutralHadronEnergyFraction, reco::btau::neutralHadronMultiplicity, phi, electrons_cff::phiWidth, reco::btau::photonEnergyFraction, reco::btau::photonMultiplicity, mixOne_premix_on_sim_cfi::pileup, DiDispStaMuonMonitor_cfi::pt, and l1tEGammaCrystalsEmulatorProducer_cfi::scale.

     : m_factors(ps.getParameter<std::vector<double> >("factors")),
       m_minLog(ps.getUntrackedParameter<double>("minLog", -800.0)),
       int_param(eta),
       int_param(phi),
       int_param(pt),
       int_param(logPt),
       int_param(mass),
       int_param(logMass),
       int_param(energy),
       int_param(logEnergy),
       int_param(gamma),
       int_param(logGamma),
       int_param(pileup),
       int_param(ncells),
       int_param(etSum),
       int_param(etaWidth),
       int_param(phiWidth),
       int_param(averageWidth),
       int_param(widthRatio),
       int_param(etaPhiCorr),
       int_param(fuzziness),
       int_param(convergenceDistance),
       int_param(recoScale),
       int_param(recoScaleRatio),
       int_param(membershipFactor),
       int_param(magnitude),
       int_param(logMagnitude),
       int_param(magS1),
       int_param(LogMagS1),
       int_param(magS2),
       int_param(LogMagS2),
       int_param(driftSpeed),
       int_param(magSpeed),
       int_param(lifetime),
       int_param(splitTime),
       int_param(mergeTime),
       int_param(scale),
       int_param(logScale),
       int_param(nearestNeighborDistance),
       int_param(clusterRadius),
       int_param(clusterSeparation),
       int_param(dRFromJet),
       int_param(LaplacianS1),
       int_param(LaplacianS2),
       int_param(LaplacianS3),
       int_param(HessianS2),
       int_param(HessianS4),
       int_param(HessianS6),
       int_param(nConstituents),
       int_param(aveConstituentPt),
       int_param(logAveConstituentPt),
       int_param(constituentPtDistribution),
       int_param(constituentEtaPhiSpread),
       int_param(chargedHadronEnergyFraction),
       int_param(neutralHadronEnergyFraction),
       int_param(photonEnergyFraction),
       int_param(electronEnergyFraction),
       int_param(muonEnergyFraction),
       int_param(HFHadronEnergyFraction),
       int_param(HFEMEnergyFraction),
       int_param(chargedHadronMultiplicity),
       int_param(neutralHadronMultiplicity),
       int_param(photonMultiplicity),
       int_param(electronMultiplicity),
       int_param(muonMultiplicity),
       int_param(HFHadronMultiplicity),
       int_param(HFEMMultiplicity),
       int_param(chargedEmEnergyFraction),
       int_param(chargedMuEnergyFraction),
       int_param(neutralEmEnergyFraction),
       int_param(EmEnergyFraction),
       int_param(chargedMultiplicity),
       int_param(neutralMultiplicity) {
   const int nFactors = m_factors.size();
   std::vector<int> mask(nFactors, 0);
   int dim = 0;
 
   check_param(eta);
   check_param(phi);
   check_param(pt);
   check_param(logPt);
   check_param(mass);
   check_param(logMass);
   check_param(energy);
   check_param(logEnergy);
   check_param(gamma);
   check_param(logGamma);
   check_param(pileup);
   check_param(ncells);
   check_param(etSum);
   check_param(etaWidth);
   check_param(phiWidth);
   check_param(averageWidth);
   check_param(widthRatio);
   check_param(etaPhiCorr);
   check_param(fuzziness);
   check_param(convergenceDistance);
   check_param(recoScale);
   check_param(recoScaleRatio);
   check_param(membershipFactor);
   check_param(magnitude);
   check_param(logMagnitude);
   check_param(magS1);
   check_param(LogMagS1);
   check_param(magS2);
   check_param(LogMagS2);
   check_param(driftSpeed);
   check_param(magSpeed);
   check_param(lifetime);
   check_param(splitTime);
   check_param(mergeTime);
   check_param(scale);
   check_param(logScale);
   check_param(nearestNeighborDistance);
   check_param(clusterRadius);
   check_param(clusterSeparation);
   check_param(dRFromJet);
   check_param(LaplacianS1);
   check_param(LaplacianS2);
   check_param(LaplacianS3);
   check_param(HessianS2);
   check_param(HessianS4);
   check_param(HessianS6);
   check_param(nConstituents);
   check_param(aveConstituentPt);
   check_param(logAveConstituentPt);
   check_param(constituentPtDistribution);
   check_param(constituentEtaPhiSpread);
   check_param(chargedHadronEnergyFraction);
   check_param(neutralHadronEnergyFraction);
   check_param(photonEnergyFraction);
   check_param(electronEnergyFraction);
   check_param(muonEnergyFraction);
   check_param(HFHadronEnergyFraction);
   check_param(HFEMEnergyFraction);
   check_param(chargedHadronMultiplicity);
   check_param(neutralHadronMultiplicity);
   check_param(photonMultiplicity);
   check_param(electronMultiplicity);
   check_param(muonMultiplicity);
   check_param(HFHadronMultiplicity);
   check_param(HFEMMultiplicity);
   check_param(chargedEmEnergyFraction);
   check_param(chargedMuEnergyFraction);
   check_param(neutralEmEnergyFraction);
   check_param(EmEnergyFraction);
   check_param(chargedMultiplicity);
   check_param(neutralMultiplicity);
 
   if (dim != nFactors)
     throw cms::Exception("FFTJetBadConfig")
         << "In FFTGenericScaleCalculator constructor: "
         << "incompatible number of scaling factors: expected " << dim << ", got " << nFactors << std::endl;
   for (int i = 0; i < nFactors; ++i)
     if (mask[i] == 0)
       throw cms::Exception("FFTJetBadConfig") << "In FFTGenericScaleCalculator constructor: "
                                               << "variable number " << i << " is not mapped" << std::endl;
 }

◆ ~FFTGenericScaleCalculator()

FFTGenericScaleCalculator::~FFTGenericScaleCalculator ( )

inlineoverride

Definition at line 17 of file FFTGenericScaleCalculator.h.

17 {}

Member Function Documentation

◆ f_safeLog()

double FFTGenericScaleCalculator::f_safeLog ( const double x ) const

inlineprivate

Definition at line 26 of file FFTGenericScaleCalculator.h.

References dqm-mbProfile::log, m_minLog, and x.

Referenced by mapFFTJet().

                                                 {
     if (x > 0.0)
       return log(x);
     else
       return m_minLog;
   }

◆ mapFFTJet()

void FFTGenericScaleCalculator::mapFFTJet	(	const reco::Jet &	jet,
		const reco::FFTJet< float > &	fftJet,
		const math::XYZTLorentzVector &	current,
		double *	buf,
		unsigned	dim
	)		const

overridevirtual

Implements AbsFFTSpecificScaleCalculator.

Definition at line 189 of file FFTGenericScaleCalculator.cc.

                                                                     {
   // Verify that the input is reasonable
   if (dim != m_factors.size())
     throw cms::Exception("FFTJetBadConfig")
         << "In FFTGenericScaleCalculator::mapFFTJet: "
         << "incompatible table dimensionality: expected " << m_factors.size() << ", got " << dim << std::endl;
   if (dim)
     assert(buf);
   else
     return;
 
   // Go over all variables and map them as configured.
   // Variables from the "current" Lorentz vector.
   if (m_eta >= 0)
     buf[m_eta] = current.eta();
 
   if (m_phi >= 0)
     buf[m_phi] = current.phi();
 
   if (m_pt >= 0)
     buf[m_pt] = current.pt();
 
   if (m_logPt >= 0)
     buf[m_logPt] = f_safeLog(current.pt());
 
   if (m_mass >= 0)
     buf[m_mass] = current.M();
 
   if (m_logMass >= 0)
     buf[m_mass] = f_safeLog(current.M());
 
   if (m_energy >= 0)
     buf[m_energy] = current.e();
 
   if (m_logEnergy >= 0)
     buf[m_energy] = f_safeLog(current.e());
 
   if (m_gamma >= 0) {
     const double m = current.M();
     if (m > 0.0)
       buf[m_gamma] = current.e() / m;
     else
       buf[m_gamma] = DBL_MAX;
   }
 
   if (m_logGamma >= 0) {
     const double m = current.M();
     if (m > 0.0)
       buf[m_gamma] = current.e() / m;
     else
       buf[m_gamma] = DBL_MAX;
     buf[m_gamma] = log(buf[m_gamma]);
   }
 
   // Variables from fftJet
   if (m_pileup >= 0)
     buf[m_pileup] = fftJet.f_pileup().pt();
 
   if (m_ncells >= 0)
     buf[m_ncells] = fftJet.f_ncells();
 
   if (m_etSum >= 0)
     buf[m_etSum] = fftJet.f_etSum();
 
   if (m_etaWidth >= 0)
     buf[m_etaWidth] = fftJet.f_etaWidth();
 
   if (m_phiWidth >= 0)
     buf[m_phiWidth] = fftJet.f_phiWidth();
 
   if (m_averageWidth >= 0) {
     const double etaw = fftJet.f_etaWidth();
     const double phiw = fftJet.f_phiWidth();
     buf[m_averageWidth] = sqrt(etaw * etaw + phiw * phiw);
   }
 
   if (m_widthRatio >= 0) {
     const double etaw = fftJet.f_etaWidth();
     const double phiw = fftJet.f_phiWidth();
     if (phiw > 0.0)
       buf[m_widthRatio] = etaw / phiw;
     else
       buf[m_widthRatio] = DBL_MAX;
   }
 
   if (m_etaPhiCorr >= 0)
     buf[m_etaPhiCorr] = fftJet.f_etaPhiCorr();
 
   if (m_fuzziness >= 0)
     buf[m_fuzziness] = fftJet.f_fuzziness();
 
   if (m_convergenceDistance >= 0)
     buf[m_convergenceDistance] = fftJet.f_convergenceDistance();
 
   if (m_recoScale >= 0)
     buf[m_recoScale] = fftJet.f_recoScale();
 
   if (m_recoScaleRatio >= 0)
     buf[m_recoScaleRatio] = fftJet.f_recoScaleRatio();
 
   if (m_membershipFactor >= 0)
     buf[m_membershipFactor] = fftJet.f_membershipFactor();
 
   // Get most often used precluster quantities
   const reco::PattRecoPeak<float>& preclus = fftJet.f_precluster();
   const double scale = preclus.scale();
 
   if (m_magnitude >= 0)
     buf[m_magnitude] = preclus.magnitude();
 
   if (m_logMagnitude >= 0)
     buf[m_logMagnitude] = f_safeLog(preclus.magnitude());
 
   if (m_magS1 >= 0)
     buf[m_magS1] = preclus.magnitude() * scale;
 
   if (m_LogMagS1 >= 0)
     buf[m_LogMagS1] = f_safeLog(preclus.magnitude() * scale);
 
   if (m_magS2 >= 0)
     buf[m_magS2] = preclus.magnitude() * scale * scale;
 
   if (m_LogMagS2 >= 0)
     buf[m_LogMagS2] = f_safeLog(preclus.magnitude() * scale * scale);
 
   if (m_driftSpeed >= 0)
     buf[m_driftSpeed] = preclus.driftSpeed();
 
   if (m_magSpeed >= 0)
     buf[m_magSpeed] = preclus.magSpeed();
 
   if (m_lifetime >= 0)
     buf[m_lifetime] = preclus.lifetime();
 
   if (m_splitTime >= 0)
     buf[m_splitTime] = preclus.splitTime();
 
   if (m_mergeTime >= 0)
     buf[m_mergeTime] = preclus.mergeTime();
 
   if (m_scale >= 0)
     buf[m_scale] = scale;
 
   if (m_logScale >= 0)
     buf[m_logScale] = f_safeLog(scale);
 
   if (m_nearestNeighborDistance >= 0)
     buf[m_nearestNeighborDistance] = preclus.nearestNeighborDistance();
 
   if (m_clusterRadius >= 0)
     buf[m_clusterRadius] = preclus.clusterRadius();
 
   if (m_clusterSeparation >= 0)
     buf[m_clusterSeparation] = preclus.clusterSeparation();
 
   if (m_dRFromJet >= 0) {
     const double deta = preclus.eta() - current.eta();
     const double dphi = delPhi(preclus.phi(), current.phi());
     buf[m_dRFromJet] = sqrt(deta * deta + dphi * dphi);
   }
 
   if (m_LaplacianS1 >= 0) {
     double h[3];
     preclus.hessian(h);
     buf[m_LaplacianS1] = fabs(h[0] + h[2]) * scale;
   }
 
   if (m_LaplacianS2 >= 0) {
     double h[3];
     preclus.hessian(h);
     buf[m_LaplacianS2] = fabs(h[0] + h[2]) * scale * scale;
   }
 
   if (m_LaplacianS3 >= 0) {
     double h[3];
     preclus.hessian(h);
     buf[m_LaplacianS3] = fabs(h[0] + h[2]) * scale * scale * scale;
   }
 
   if (m_HessianS2 >= 0) {
     double h[3];
     preclus.hessian(h);
     buf[m_HessianS2] = fabs(h[0] * h[2] - h[1] * h[1]) * scale * scale;
   }
 
   if (m_HessianS4 >= 0) {
     double h[3];
     preclus.hessian(h);
     buf[m_HessianS4] = fabs(h[0] * h[2] - h[1] * h[1]) * pow(scale, 4);
   }
 
   if (m_HessianS6 >= 0) {
     double h[3];
     preclus.hessian(h);
     buf[m_HessianS6] = fabs(h[0] * h[2] - h[1] * h[1]) * pow(scale, 6);
   }
 
   // Variables from reco::Jet
   if (m_nConstituents >= 0)
     buf[m_nConstituents] = jet.nConstituents();
 
   if (m_aveConstituentPt >= 0)
     buf[m_aveConstituentPt] = current.pt() / jet.nConstituents();
 
   if (m_logAveConstituentPt >= 0)
     buf[m_logAveConstituentPt] = f_safeLog(current.pt() / jet.nConstituents());
 
   if (m_constituentPtDistribution >= 0)
     buf[m_constituentPtDistribution] = jet.constituentPtDistribution();
 
   if (m_constituentEtaPhiSpread >= 0)
     buf[m_constituentEtaPhiSpread] = jet.constituentEtaPhiSpread();
 
   // Variables from reco::PFJet
   const reco::PFJet* pfjet = dynamic_cast<const reco::PFJet*>(&jet);
   if (pfjet) {
     // Particle flow jet
     if (m_chargedHadronEnergyFraction >= 0)
       buf[m_chargedHadronEnergyFraction] = pfjet->chargedHadronEnergyFraction();
 
     if (m_neutralHadronEnergyFraction >= 0)
       buf[m_neutralHadronEnergyFraction] = pfjet->neutralHadronEnergyFraction();
 
     if (m_photonEnergyFraction >= 0)
       buf[m_photonEnergyFraction] = pfjet->photonEnergyFraction();
 
     if (m_electronEnergyFraction >= 0)
       buf[m_electronEnergyFraction] = pfjet->electronEnergyFraction();
 
     if (m_muonEnergyFraction >= 0)
       buf[m_muonEnergyFraction] = pfjet->muonEnergyFraction();
 
     if (m_HFHadronEnergyFraction >= 0)
       buf[m_HFHadronEnergyFraction] = pfjet->HFHadronEnergyFraction();
 
     if (m_HFEMEnergyFraction >= 0)
       buf[m_HFEMEnergyFraction] = pfjet->HFEMEnergyFraction();
 
     if (m_chargedHadronMultiplicity >= 0)
       buf[m_chargedHadronMultiplicity] = pfjet->chargedHadronMultiplicity();
 
     if (m_neutralHadronMultiplicity >= 0)
       buf[m_neutralHadronMultiplicity] = pfjet->neutralHadronMultiplicity();
 
     if (m_photonMultiplicity >= 0)
       buf[m_photonMultiplicity] = pfjet->photonMultiplicity();
 
     if (m_electronMultiplicity >= 0)
       buf[m_electronMultiplicity] = pfjet->electronMultiplicity();
 
     if (m_muonMultiplicity >= 0)
       buf[m_muonMultiplicity] = pfjet->muonMultiplicity();
 
     if (m_HFHadronMultiplicity >= 0)
       buf[m_HFHadronMultiplicity] = pfjet->HFHadronMultiplicity();
 
     if (m_HFEMMultiplicity >= 0)
       buf[m_HFEMMultiplicity] = pfjet->HFEMMultiplicity();
 
     if (m_chargedEmEnergyFraction >= 0)
       buf[m_chargedEmEnergyFraction] = pfjet->chargedEmEnergyFraction();
 
     if (m_chargedMuEnergyFraction >= 0)
       buf[m_chargedMuEnergyFraction] = pfjet->chargedMuEnergyFraction();
 
     if (m_neutralEmEnergyFraction >= 0)
       buf[m_neutralEmEnergyFraction] = pfjet->neutralEmEnergyFraction();
 
     if (m_EmEnergyFraction >= 0)
       buf[m_EmEnergyFraction] = pfjet->neutralEmEnergyFraction() + pfjet->chargedEmEnergyFraction();
 
     if (m_chargedMultiplicity >= 0)
       buf[m_chargedMultiplicity] = pfjet->chargedMultiplicity();
 
     if (m_neutralMultiplicity >= 0)
       buf[m_neutralMultiplicity] = pfjet->neutralMultiplicity();
   } else {
     // Not a particle flow jet
     if (m_chargedHadronEnergyFraction >= 0 || m_neutralHadronEnergyFraction >= 0 || m_photonEnergyFraction >= 0 ||
         m_electronEnergyFraction >= 0 || m_muonEnergyFraction >= 0 || m_HFHadronEnergyFraction >= 0 ||
         m_HFEMEnergyFraction >= 0 || m_chargedHadronMultiplicity >= 0 || m_neutralHadronMultiplicity >= 0 ||
         m_photonMultiplicity >= 0 || m_electronMultiplicity >= 0 || m_muonMultiplicity >= 0 ||
         m_HFHadronMultiplicity >= 0 || m_HFEMMultiplicity >= 0 || m_chargedEmEnergyFraction >= 0 ||
         m_chargedMuEnergyFraction >= 0 || m_neutralEmEnergyFraction >= 0 || m_EmEnergyFraction >= 0 ||
         m_chargedMultiplicity >= 0 || m_neutralMultiplicity >= 0)
       throw cms::Exception("FFTJetBadConfig") << "In FFTGenericScaleCalculator::mapFFTJet: "
                                               << "this configuration is valid for particle flow jets only" << std::endl;
   }
 
   // Apply the scaling factors
   for (unsigned i = 0; i < dim; ++i)
     buf[i] *= m_factors[i];
 }

Member Data Documentation

◆ m_aveConstituentPt

int FFTGenericScaleCalculator::m_aveConstituentPt

private

Definition at line 90 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_averageWidth

int FFTGenericScaleCalculator::m_averageWidth

private

Definition at line 54 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_chargedEmEnergyFraction

int FFTGenericScaleCalculator::m_chargedEmEnergyFraction

private

Definition at line 110 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_chargedHadronEnergyFraction

int FFTGenericScaleCalculator::m_chargedHadronEnergyFraction

private

Definition at line 96 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_chargedHadronMultiplicity

int FFTGenericScaleCalculator::m_chargedHadronMultiplicity

private

Definition at line 103 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_chargedMuEnergyFraction

int FFTGenericScaleCalculator::m_chargedMuEnergyFraction

private

Definition at line 111 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_chargedMultiplicity

int FFTGenericScaleCalculator::m_chargedMultiplicity

private

Definition at line 114 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_clusterRadius

int FFTGenericScaleCalculator::m_clusterRadius

private

Definition at line 78 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_clusterSeparation

int FFTGenericScaleCalculator::m_clusterSeparation

private

Definition at line 79 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_constituentEtaPhiSpread

int FFTGenericScaleCalculator::m_constituentEtaPhiSpread

private

Definition at line 93 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_constituentPtDistribution

int FFTGenericScaleCalculator::m_constituentPtDistribution

private

Definition at line 92 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_convergenceDistance

int FFTGenericScaleCalculator::m_convergenceDistance

private

Definition at line 58 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_dRFromJet

int FFTGenericScaleCalculator::m_dRFromJet

private

Definition at line 80 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_driftSpeed

int FFTGenericScaleCalculator::m_driftSpeed

private

Definition at line 70 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_electronEnergyFraction

int FFTGenericScaleCalculator::m_electronEnergyFraction

private

Definition at line 99 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_electronMultiplicity

int FFTGenericScaleCalculator::m_electronMultiplicity

private

Definition at line 106 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_EmEnergyFraction

int FFTGenericScaleCalculator::m_EmEnergyFraction

private

Definition at line 113 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_energy

int FFTGenericScaleCalculator::m_energy

private

Definition at line 43 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_eta

int FFTGenericScaleCalculator::m_eta

private

Definition at line 37 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_etaPhiCorr

int FFTGenericScaleCalculator::m_etaPhiCorr

private

Definition at line 56 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_etaWidth

int FFTGenericScaleCalculator::m_etaWidth

private

Definition at line 52 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_etSum

int FFTGenericScaleCalculator::m_etSum

private

Definition at line 51 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_factors

std::vector<double> FFTGenericScaleCalculator::m_factors

private

Definition at line 33 of file FFTGenericScaleCalculator.h.

Referenced by FFTGenericScaleCalculator(), and mapFFTJet().

◆ m_fuzziness

int FFTGenericScaleCalculator::m_fuzziness

private

Definition at line 57 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_gamma

int FFTGenericScaleCalculator::m_gamma

private

Definition at line 45 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_HessianS2

int FFTGenericScaleCalculator::m_HessianS2

private

Definition at line 84 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_HessianS4

int FFTGenericScaleCalculator::m_HessianS4

private

Definition at line 85 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_HessianS6

int FFTGenericScaleCalculator::m_HessianS6

private

Definition at line 86 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_HFEMEnergyFraction

int FFTGenericScaleCalculator::m_HFEMEnergyFraction

private

Definition at line 102 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_HFEMMultiplicity

int FFTGenericScaleCalculator::m_HFEMMultiplicity

private

Definition at line 109 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_HFHadronEnergyFraction

int FFTGenericScaleCalculator::m_HFHadronEnergyFraction

private

Definition at line 101 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_HFHadronMultiplicity

int FFTGenericScaleCalculator::m_HFHadronMultiplicity

private

Definition at line 108 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_LaplacianS1

int FFTGenericScaleCalculator::m_LaplacianS1

private

Definition at line 81 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_LaplacianS2

int FFTGenericScaleCalculator::m_LaplacianS2

private

Definition at line 82 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_LaplacianS3

int FFTGenericScaleCalculator::m_LaplacianS3

private

Definition at line 83 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_lifetime

int FFTGenericScaleCalculator::m_lifetime

private

Definition at line 72 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_logAveConstituentPt

int FFTGenericScaleCalculator::m_logAveConstituentPt

private

Definition at line 91 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_logEnergy

int FFTGenericScaleCalculator::m_logEnergy

private

Definition at line 44 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_logGamma

int FFTGenericScaleCalculator::m_logGamma

private

Definition at line 46 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_logMagnitude

int FFTGenericScaleCalculator::m_logMagnitude

private

Definition at line 65 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_LogMagS1

int FFTGenericScaleCalculator::m_LogMagS1

private

Definition at line 67 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_LogMagS2

int FFTGenericScaleCalculator::m_LogMagS2

private

Definition at line 69 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_logMass

int FFTGenericScaleCalculator::m_logMass

private

Definition at line 42 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_logPt

int FFTGenericScaleCalculator::m_logPt

private

Definition at line 40 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_logScale

int FFTGenericScaleCalculator::m_logScale

private

Definition at line 76 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_magnitude

int FFTGenericScaleCalculator::m_magnitude

private

Definition at line 64 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_magS1

int FFTGenericScaleCalculator::m_magS1

private

Definition at line 66 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_magS2

int FFTGenericScaleCalculator::m_magS2

private

Definition at line 68 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_magSpeed

int FFTGenericScaleCalculator::m_magSpeed

private

Definition at line 71 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_mass

int FFTGenericScaleCalculator::m_mass

private

Definition at line 41 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_membershipFactor

int FFTGenericScaleCalculator::m_membershipFactor

private

Definition at line 61 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_mergeTime

int FFTGenericScaleCalculator::m_mergeTime

private

Definition at line 74 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_minLog

double FFTGenericScaleCalculator::m_minLog

private

Definition at line 34 of file FFTGenericScaleCalculator.h.

Referenced by f_safeLog().

◆ m_muonEnergyFraction

int FFTGenericScaleCalculator::m_muonEnergyFraction

private

Definition at line 100 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_muonMultiplicity

int FFTGenericScaleCalculator::m_muonMultiplicity

private

Definition at line 107 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_ncells

int FFTGenericScaleCalculator::m_ncells

private

Definition at line 50 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_nConstituents

int FFTGenericScaleCalculator::m_nConstituents

private

Definition at line 89 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_nearestNeighborDistance

int FFTGenericScaleCalculator::m_nearestNeighborDistance

private

Definition at line 77 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_neutralEmEnergyFraction

int FFTGenericScaleCalculator::m_neutralEmEnergyFraction

private

Definition at line 112 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_neutralHadronEnergyFraction

int FFTGenericScaleCalculator::m_neutralHadronEnergyFraction

private

Definition at line 97 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_neutralHadronMultiplicity

int FFTGenericScaleCalculator::m_neutralHadronMultiplicity

private

Definition at line 104 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_neutralMultiplicity

int FFTGenericScaleCalculator::m_neutralMultiplicity

private

Definition at line 115 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_phi

int FFTGenericScaleCalculator::m_phi

private

Definition at line 38 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_phiWidth

int FFTGenericScaleCalculator::m_phiWidth

private

Definition at line 53 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_photonEnergyFraction

int FFTGenericScaleCalculator::m_photonEnergyFraction

private

Definition at line 98 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_photonMultiplicity

int FFTGenericScaleCalculator::m_photonMultiplicity

private

Definition at line 105 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_pileup

int FFTGenericScaleCalculator::m_pileup

private

Definition at line 49 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_pt

int FFTGenericScaleCalculator::m_pt

private

Definition at line 39 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_recoScale

int FFTGenericScaleCalculator::m_recoScale

private

Definition at line 59 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_recoScaleRatio

int FFTGenericScaleCalculator::m_recoScaleRatio

private

Definition at line 60 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_scale

int FFTGenericScaleCalculator::m_scale

private

Definition at line 75 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_splitTime

int FFTGenericScaleCalculator::m_splitTime

private

Definition at line 73 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

◆ m_widthRatio

int FFTGenericScaleCalculator::m_widthRatio

private

Definition at line 55 of file FFTGenericScaleCalculator.h.

Referenced by mapFFTJet().

Public Member Functions

Private Member Functions

Private Attributes

Detailed Description

Constructor & Destructor Documentation

◆ FFTGenericScaleCalculator()

◆ ~FFTGenericScaleCalculator()

Member Function Documentation

◆ f_safeLog()

◆ mapFFTJet()

Member Data Documentation

◆ m_aveConstituentPt

◆ m_averageWidth

◆ m_chargedEmEnergyFraction

◆ m_chargedHadronEnergyFraction

◆ m_chargedHadronMultiplicity

◆ m_chargedMuEnergyFraction

◆ m_chargedMultiplicity

◆ m_clusterRadius

◆ m_clusterSeparation

◆ m_constituentEtaPhiSpread

◆ m_constituentPtDistribution

◆ m_convergenceDistance

◆ m_dRFromJet

◆ m_driftSpeed

◆ m_electronEnergyFraction

◆ m_electronMultiplicity

◆ m_EmEnergyFraction

◆ m_energy

◆ m_eta

◆ m_etaPhiCorr

◆ m_etaWidth

◆ m_etSum

◆ m_factors

◆ m_fuzziness

◆ m_gamma

◆ m_HessianS2

◆ m_HessianS4

◆ m_HessianS6

◆ m_HFEMEnergyFraction

◆ m_HFEMMultiplicity

◆ m_HFHadronEnergyFraction

◆ m_HFHadronMultiplicity

◆ m_LaplacianS1

◆ m_LaplacianS2

◆ m_LaplacianS3

◆ m_lifetime

◆ m_logAveConstituentPt

◆ m_logEnergy

◆ m_logGamma

◆ m_logMagnitude

◆ m_LogMagS1

◆ m_LogMagS2

◆ m_logMass

◆ m_logPt

◆ m_logScale

◆ m_magnitude

◆ m_magS1

◆ m_magS2

◆ m_magSpeed

◆ m_mass

◆ m_membershipFactor

◆ m_mergeTime

◆ m_minLog

◆ m_muonEnergyFraction

◆ m_muonMultiplicity

◆ m_ncells

◆ m_nConstituents

◆ m_nearestNeighborDistance

◆ m_neutralEmEnergyFraction

◆ m_neutralHadronEnergyFraction

◆ m_neutralHadronMultiplicity

◆ m_neutralMultiplicity

◆ m_phi

◆ m_phiWidth

◆ m_photonEnergyFraction

◆ m_photonMultiplicity

◆ m_pileup

◆ m_pt

◆ m_recoScale