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FFTJetEFlowSmoother.cc
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1 // -*- C++ -*-
2 //
3 // Package: FFTJetProducers
4 // Class: FFTJetEFlowSmoother
5 //
13 //
14 // Original Author: Igor Volobouev
15 // Created: Thu Jun 2 18:49:49 CDT 2011
16 //
17 //
18 
19 #include <cmath>
20 
21 // FFTJet headers
22 #include "fftjet/FrequencyKernelConvolver.hh"
23 #include "fftjet/DiscreteGauss2d.hh"
24 #include "fftjet/EquidistantSequence.hh"
25 #include "fftjet/interpolate.hh"
26 #include "fftjet/FrequencyKernelConvolver.hh"
27 #include "fftjet/FrequencySequentialConvolver.hh"
28 #include "fftjet/DiscreteGauss1d.hh"
29 #include "fftjet/DiscreteGauss2d.hh"
30 
31 // framework include files
32 #include "FWCore/Framework/interface/Frameworkfwd.h"
33 #include "FWCore/Framework/interface/MakerMacros.h"
34 #include "FWCore/ParameterSet/interface/ParameterSet.h"
35 
36 #include "DataFormats/Common/interface/View.h"
37 #include <TH3F.h>
38 
39 // parameter parser header
40 #include "RecoJets/FFTJetProducers/interface/FFTJetParameterParser.h"
41 
42 // useful utilities collected in the second base
43 #include "RecoJets/FFTJetProducers/interface/FFTJetInterface.h"
44 
45 using namespace fftjetcms;
46 
47 //
48 // class declaration
49 //
50 class FFTJetEFlowSmoother : public FFTJetInterface
51 {
52 public:
53  explicit FFTJetEFlowSmoother(const edm::ParameterSet&);
54  ~FFTJetEFlowSmoother() override;
55 
56 protected:
57  // methods
58  void beginJob() override ;
59  void produce(edm::Event&, const edm::EventSetup&) override;
60  void endJob() override ;
61 
62 private:
63  FFTJetEFlowSmoother() = delete;
64  FFTJetEFlowSmoother(const FFTJetEFlowSmoother&) = delete;
65  FFTJetEFlowSmoother& operator=(const FFTJetEFlowSmoother&) = delete;
66 
67  void buildKernelConvolver(const edm::ParameterSet&);
68 
69  // Storage for convolved energy flow
70  std::unique_ptr<fftjet::Grid2d<fftjetcms::Real> > convolvedFlow;
71 
72  // Filtering scales
73  std::unique_ptr<std::vector<double> > iniScales;
74 
75  // The FFT engine(s)
76  std::unique_ptr<MyFFTEngine> engine;
77  std::unique_ptr<MyFFTEngine> anotherEngine;
78 
79  // The pattern recognition kernel(s)
80  std::unique_ptr<fftjet::AbsFrequencyKernel> kernel2d;
81  std::unique_ptr<fftjet::AbsFrequencyKernel1d> etaKernel;
82  std::unique_ptr<fftjet::AbsFrequencyKernel1d> phiKernel;
83 
84  // The kernel convolver
85  std::unique_ptr<fftjet::AbsConvolverBase<Real> > convolver;
86 
87  // The scale power to use for scaling Et
88  double scalePower;
89 
90  // Overall factor to multiply Et with
91  double etConversionFactor;
92 };
93 
94 //
95 // constructors and destructor
96 //
97 FFTJetEFlowSmoother::FFTJetEFlowSmoother(const edm::ParameterSet& ps)
98  : FFTJetInterface(ps),
99  scalePower(ps.getParameter<double>("scalePower")),
100  etConversionFactor(ps.getParameter<double>("etConversionFactor"))
101 {
102  // Build the discretization grid
103  energyFlow = fftjet_Grid2d_parser(
104  ps.getParameter<edm::ParameterSet>("GridConfiguration"));
105  checkConfig(energyFlow, "invalid discretization grid");
106 
107  // Copy of the grid which will be used for convolutions
108  convolvedFlow = std::unique_ptr<fftjet::Grid2d<fftjetcms::Real> >(
109  new fftjet::Grid2d<fftjetcms::Real>(*energyFlow));
110 
111  // Build the initial set of pattern recognition scales
112  iniScales = fftjet_ScaleSet_parser(
113  ps.getParameter<edm::ParameterSet>("InitialScales"));
114  checkConfig(iniScales, "invalid set of scales");
115 
116  // Build the FFT engine(s), pattern recognition kernel(s),
117  // and the kernel convolver
118  buildKernelConvolver(ps);
119 
120  // Build the set of pattern recognition scales
121  produces<TH3F>(outputLabel);
122 }
123 
124 
125 void FFTJetEFlowSmoother::buildKernelConvolver(const edm::ParameterSet& ps)
126 {
127  // Check the parameter named "etaDependentScaleFactors". If the vector
128  // of scales is empty we will use 2d kernel, otherwise use 1d kernels
129  const std::vector<double> etaDependentScaleFactors(
130  ps.getParameter<std::vector<double> >("etaDependentScaleFactors"));
131 
132  // Make sure that the number of scale factors provided is correct
133  const bool use2dKernel = etaDependentScaleFactors.empty();
134  if (!use2dKernel)
135  if (etaDependentScaleFactors.size() != energyFlow->nEta())
136  throw cms::Exception("FFTJetBadConfig")
137  << "invalid number of eta-dependent scale factors"
138  << std::endl;
139 
140  // Get the eta and phi scales for the kernel(s)
141  double kernelEtaScale = ps.getParameter<double>("kernelEtaScale");
142  const double kernelPhiScale = ps.getParameter<double>("kernelPhiScale");
143  if (kernelEtaScale <= 0.0 || kernelPhiScale <= 0.0)
144  throw cms::Exception("FFTJetBadConfig")
145  << "invalid kernel scale" << std::endl;
146 
147  // FFT assumes that the grid extent in eta is 2*Pi. Adjust the
148  // kernel scale in eta to compensate.
149  kernelEtaScale *= (2.0*M_PI/(energyFlow->etaMax() - energyFlow->etaMin()));
150 
151  // Are we going to try to fix the efficiency near detector edges?
152  const bool fixEfficiency = ps.getParameter<bool>("fixEfficiency");
153 
154  // Minimum and maximum eta bin for the convolver
155  unsigned convolverMinBin = 0, convolverMaxBin = 0;
156  if (fixEfficiency || !use2dKernel)
157  {
158  convolverMinBin = ps.getParameter<unsigned>("convolverMinBin");
159  convolverMaxBin = ps.getParameter<unsigned>("convolverMaxBin");
160  }
161 
162  if (use2dKernel)
163  {
164  // Build the FFT engine
165  engine = std::unique_ptr<MyFFTEngine>(
166  new MyFFTEngine(energyFlow->nEta(), energyFlow->nPhi()));
167 
168  // 2d kernel
169  kernel2d = std::unique_ptr<fftjet::AbsFrequencyKernel>(
170  new fftjet::DiscreteGauss2d(
171  kernelEtaScale, kernelPhiScale,
172  energyFlow->nEta(), energyFlow->nPhi()));
173 
174  // 2d convolver
175  convolver = std::unique_ptr<fftjet::AbsConvolverBase<Real> >(
176  new fftjet::FrequencyKernelConvolver<Real,Complex>(
177  engine.get(), kernel2d.get(),
178  convolverMinBin, convolverMaxBin));
179  }
180  else
181  {
182  // Need separate FFT engines for eta and phi
183  engine = std::unique_ptr<MyFFTEngine>(
184  new MyFFTEngine(1, energyFlow->nEta()));
185  anotherEngine = std::unique_ptr<MyFFTEngine>(
186  new MyFFTEngine(1, energyFlow->nPhi()));
187 
188  // 1d kernels
189  etaKernel = std::unique_ptr<fftjet::AbsFrequencyKernel1d>(
190  new fftjet::DiscreteGauss1d(kernelEtaScale, energyFlow->nEta()));
191 
192  phiKernel = std::unique_ptr<fftjet::AbsFrequencyKernel1d>(
193  new fftjet::DiscreteGauss1d(kernelPhiScale, energyFlow->nPhi()));
194 
195  // Sequential convolver
196  convolver = std::unique_ptr<fftjet::AbsConvolverBase<Real> >(
197  new fftjet::FrequencySequentialConvolver<Real,Complex>(
198  engine.get(), anotherEngine.get(),
199  etaKernel.get(), phiKernel.get(),
200  etaDependentScaleFactors, convolverMinBin,
201  convolverMaxBin, fixEfficiency));
202  }
203 }
204 
205 
206 FFTJetEFlowSmoother::~FFTJetEFlowSmoother()
207 {
208 }
209 
210 
211 // ------------ method called to produce the data ------------
212 void FFTJetEFlowSmoother::produce(
213  edm::Event& iEvent, const edm::EventSetup& iSetup)
214 {
215  loadInputCollection(iEvent);
216  discretizeEnergyFlow();
217 
218  // Various useful variables
219  const fftjet::Grid2d<Real>& g(*energyFlow);
220  const unsigned nScales = iniScales->size();
221  const double* scales = &(*iniScales)[0];
222  Real* convData = const_cast<Real*>(convolvedFlow->data());
223  const unsigned nEta = g.nEta();
224  const unsigned nPhi = g.nPhi();
225  const double bin0edge = g.phiBin0Edge();
226 
227  // We will fill the following histo
228  auto pTable = std::make_unique<TH3F>(
229  "FFTJetEFlowSmoother", "FFTJetEFlowSmoother",
230  nScales+1U, -1.5, nScales-0.5,
231  nEta, g.etaMin(), g.etaMax(),
232  nPhi, bin0edge, bin0edge+2.0*M_PI);
233  TH3F* h = pTable.get();
234  h->SetDirectory(nullptr);
235  h->GetXaxis()->SetTitle("Scale");
236  h->GetYaxis()->SetTitle("Eta");
237  h->GetZaxis()->SetTitle("Phi");
238 
239  // Fill the original thing
240  double factor = etConversionFactor*pow(getEventScale(), scalePower);
241  for (unsigned ieta=0; ieta<nEta; ++ieta)
242  for (unsigned iphi=0; iphi<nPhi; ++iphi)
243  h->SetBinContent(1U, ieta+1U, iphi+1U,
244  factor*g.binValue(ieta, iphi));
245 
246  // Go over all scales and perform the convolutions
247  convolver->setEventData(g.data(), nEta, nPhi);
248  for (unsigned iscale=0; iscale<nScales; ++iscale)
249  {
250  factor = etConversionFactor*pow(scales[iscale], scalePower);
251 
252  // Perform the convolution
253  convolver->convolveWithKernel(
254  scales[iscale], convData,
255  convolvedFlow->nEta(), convolvedFlow->nPhi());
256 
257  // Fill the output histo
258  for (unsigned ieta=0; ieta<nEta; ++ieta)
259  {
260  const Real* etaData = convData + ieta*nPhi;
261  for (unsigned iphi=0; iphi<nPhi; ++iphi)
262  h->SetBinContent(iscale+2U, ieta+1U, iphi+1U,
263  factor*etaData[iphi]);
264  }
265  }
266 
267  iEvent.put(std::move(pTable), outputLabel);
268 }
269 
270 
271 // ------------ method called once each job just before starting event loop
272 void FFTJetEFlowSmoother::beginJob()
273 {
274 }
275 
276 
277 // ------------ method called once each job just after ending the event loop
278 void FFTJetEFlowSmoother::endJob()
279 {
280 }
281 
282 
283 //define this as a plug-in
284 DEFINE_FWK_MODULE(FFTJetEFlowSmoother);
FFTJetEFlowSmoother::engine
std::unique_ptr< MyFFTEngine > engine
Definition: FFTJetEFlowSmoother.cc:76
edm::ParameterSet::getParameter
T getParameter(std::string const &) const
FFTJetEFlowSmoother::etaKernel
std::unique_ptr< fftjet::AbsFrequencyKernel1d > etaKernel
Definition: FFTJetEFlowSmoother.cc:81
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Definition: Event.h:125
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Definition: fftjetcommon_cfi.py:204
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FFTJetEFlowSmoother::convolver
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Definition: FFTJetEFlowSmoother.cc:85
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Definition: FFTJetInterface.cc:54
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Definition: FFTJetEFlowSmoother.cc:77
FFTJetEFlowSmoother::FFTJetEFlowSmoother
FFTJetEFlowSmoother()=delete
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Definition: FFTJetEFlowSmoother.cc:73
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Definition: FFTJetEFlowSmoother.cc:212
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