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L1GctHardwareJetFinder.cc
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2 
3 //DEFINE STATICS
4 const unsigned int L1GctHardwareJetFinder::N_COLS = 2;
5 const unsigned int L1GctHardwareJetFinder::CENTRAL_COL0 = 0;
7  (((L1CaloRegionDetId::N_ETA) / 2) + N_EXTRA_REGIONS_ETA00) * L1GctHardwareJetFinder::N_COLS;
8 
11  m_localMaxima(MAX_JETS_OUT),
12  m_clusters(MAX_JETS_OUT),
13  m_numberOfClusters(0),
14  m_localMax00(2),
15  m_cluster00(2) {
16  this->reset();
17  // Initialise parameters for Region input calculations in the
18  // derived class so we get the right values of constants.
19  static const unsigned NPHI = L1CaloRegionDetId::N_PHI;
20  m_minColThisJf = (NPHI + m_id * 2 - CENTRAL_COL0) % NPHI;
21 }
22 
24 
25 std::ostream& operator<<(std::ostream& os, const L1GctHardwareJetFinder& algo) {
26  os << "===L1GctHardwareJetFinder===" << std::endl;
27  const L1GctJetFinderBase* temp = &algo;
28  os << *temp;
29  return os;
30 }
31 
33 
35  if (setupOk()) {
36  findProtoJets();
37  }
38 }
39 
41  if (setupOk()) {
43  findJets();
44  sortJets();
45  doEnergySums();
46  }
47 }
48 
50 
56 }
57 
62 }
63 
65 // Find the local et maxima in the 2x11 array of regions
67  m_localMaxima.clear();
69  m_localMax00.clear();
70  m_localMax00.resize(2);
71 
72  UShort jetNum = 0; //holds the number of jets currently found
73  UShort centreIndex = COL_OFFSET * this->centralCol0();
74  for (UShort column = 0; column < 2; ++column) //Find jets in the central search region
75  {
76  // The input regions include two extra bins on the other side of eta=0. This allows "seamless"
77  // jetfinding across the eta=0 boundary. We skip the first input region in each row. We perform
78  // the full pre-clustering on the next region but store the resulting clusters separately
79  // from the main list of output pre-clusters - they will be used in the final cluster stage to
80  // make sure we do not produce jets in adjacent regions on opposite sides of eta=0.
81  ++centreIndex;
82  for (UShort row = 1; row < COL_OFFSET; ++row) {
83  // Here's the array of greater-than and greater-or-equal tests
84  // to ensure each localMaximum appears once and only once in the list
85  // It is different for forward and backward eta.
86  unsigned JET_THRESHOLD = ((row > m_EtaBoundry) ? m_FwdJetSeed : m_CenJetSeed);
87  bool localMax = !m_inputRegions.at(centreIndex).empty() && (m_inputRegions.at(centreIndex).et() >= JET_THRESHOLD);
88  if (m_positiveEtaWheel) { // Forward eta
89  localMax &= (m_inputRegions.at(centreIndex).et() >= m_inputRegions.at(centreIndex - 1).et());
90  if (row < (COL_OFFSET - 1)) {
91  localMax &= (m_inputRegions.at(centreIndex).et() > m_inputRegions.at(centreIndex + 1).et());
92  }
93  if (column == 0) {
94  localMax &= (m_inputRegions.at(centreIndex).et() > m_inputRegions.at(centreIndex + COL_OFFSET).et());
95  localMax &= (m_inputRegions.at(centreIndex).et() > m_inputRegions.at(centreIndex + COL_OFFSET - 1).et());
96  if (row < (COL_OFFSET - 1)) {
97  localMax &= (m_inputRegions.at(centreIndex).et() > m_inputRegions.at(centreIndex + COL_OFFSET + 1).et());
98  }
99  } else {
100  localMax &= (m_inputRegions.at(centreIndex).et() >= m_inputRegions.at(centreIndex - COL_OFFSET).et());
101  localMax &= (m_inputRegions.at(centreIndex).et() >= m_inputRegions.at(centreIndex - COL_OFFSET - 1).et());
102  if (row < (COL_OFFSET - 1)) {
103  localMax &= (m_inputRegions.at(centreIndex).et() >= m_inputRegions.at(centreIndex - COL_OFFSET + 1).et());
104  }
105  }
106  } else { // Backward eta
107  localMax &= (m_inputRegions.at(centreIndex).et() > m_inputRegions.at(centreIndex - 1).et());
108  if (row < (COL_OFFSET - 1)) {
109  localMax &= (m_inputRegions.at(centreIndex).et() >= m_inputRegions.at(centreIndex + 1).et());
110  }
111  if (column == 0) {
112  localMax &= (m_inputRegions.at(centreIndex).et() >= m_inputRegions.at(centreIndex + COL_OFFSET).et());
113  localMax &= (m_inputRegions.at(centreIndex).et() >= m_inputRegions.at(centreIndex + COL_OFFSET - 1).et());
114  if (row < (COL_OFFSET - 1)) {
115  localMax &= (m_inputRegions.at(centreIndex).et() >= m_inputRegions.at(centreIndex + COL_OFFSET + 1).et());
116  }
117  } else {
118  localMax &= (m_inputRegions.at(centreIndex).et() > m_inputRegions.at(centreIndex - COL_OFFSET).et());
119  localMax &= (m_inputRegions.at(centreIndex).et() > m_inputRegions.at(centreIndex - COL_OFFSET - 1).et());
120  if (row < (COL_OFFSET - 1)) {
121  localMax &= (m_inputRegions.at(centreIndex).et() > m_inputRegions.at(centreIndex - COL_OFFSET + 1).et());
122  }
123  }
124  }
125  if (localMax) {
126  if (row > 1) {
127  if (jetNum < MAX_JETS_OUT) {
128  m_localMaxima.at(jetNum) = m_inputRegions.at(centreIndex);
129  ++jetNum;
130  }
131  }
132  // Treat row 1 as a separate case. It's not required for jetfinding but
133  // is used for vetoing of jets double counted across the eta=0 boundary
134  else {
135  unsigned phi = m_inputRegions.at(centreIndex).rctPhi();
136  m_localMax00.at(phi) = m_inputRegions.at(centreIndex);
137  }
138  }
139  ++centreIndex;
140  }
141  }
142 
143  m_numberOfClusters = jetNum;
144 }
145 
146 // For each local maximum, find the cluster et in a 2x3 region.
147 // The logic ensures that a given region et cannot be used in more than one cluster.
148 // The sorting of the local maxima ensures the highest et maximum has priority.
150  m_clusters.clear();
151  m_clusters.resize(MAX_JETS_OUT);
152  m_cluster00.clear();
153  m_cluster00.resize(2);
154 
155  RegionsVector topJets(MAX_JETS_OUT), botJets(MAX_JETS_OUT);
156  std::vector<unsigned> topJetsPosition(MAX_JETS_OUT), botJetsPosition(MAX_JETS_OUT);
157  unsigned numberOfTopJets = 0, numberOfBotJets = 0;
158 
159  // Loop over local maxima
160  for (unsigned j = 0; j < m_numberOfClusters; ++j) {
161  // Make a proto-jet cluster
163 
164  if (m_localMaxima.at(j).rctPhi() == 0) {
165  // Store "top edge" jets
166  topJets.at(numberOfTopJets) = temp;
167  topJetsPosition.at(numberOfTopJets) = 0;
168  for (unsigned k = 0; k < numberOfTopJets; ++k) {
169  if (topJets.at(numberOfTopJets).et() >= topJets.at(k).et()) {
170  ++topJetsPosition.at(k);
171  }
172  if (topJets.at(numberOfTopJets).et() <= topJets.at(k).et()) {
173  ++topJetsPosition.at(numberOfTopJets);
174  }
175  }
176  ++numberOfTopJets;
177  } else {
178  // Store "bottom edge" jets
179  botJets.at(numberOfBotJets) = temp;
180  botJetsPosition.at(numberOfBotJets) = 0;
181  for (unsigned k = 0; k < numberOfBotJets; ++k) {
182  if (botJets.at(numberOfBotJets).et() >= botJets.at(k).et()) {
183  ++botJetsPosition.at(k);
184  }
185  if (botJets.at(numberOfBotJets).et() <= botJets.at(k).et()) {
186  ++botJetsPosition.at(numberOfBotJets);
187  }
188  }
189  ++numberOfBotJets;
190  }
191  }
192  // Now we've found all the proto-jets, copy the best ones to the output array
193  //
194  // We fill the first half of the array with "bottom jets"
195  // and the remainder with "top jets". For cases where
196  // we have found too many jets in one phi column,
197  // we keep those with the highest Et.
198  static const unsigned int MAX_TOPBOT_JETS = MAX_JETS_OUT / 2;
199  unsigned pos = 0;
200  for (unsigned j = 0; j < numberOfBotJets; ++j) {
201  if (botJetsPosition.at(j) < MAX_TOPBOT_JETS) {
202  m_clusters.at(pos++) = botJets.at(j);
203  }
204  }
205  pos = MAX_TOPBOT_JETS;
206  for (unsigned j = 0; j < numberOfTopJets; ++j) {
207  if (topJetsPosition.at(j) < MAX_TOPBOT_JETS) {
208  m_clusters.at(pos++) = topJets.at(j);
209  }
210  }
211  // Finally, deal with eta00 maxima
212  if (!m_localMax00.at(0).empty())
213  m_cluster00.at(0) = makeProtoJet(m_localMax00.at(0));
214  if (!m_localMax00.at(1).empty())
215  m_cluster00.at(1) = makeProtoJet(m_localMax00.at(1));
216 }
217 
220  unsigned eta = localMax.gctEta();
221  unsigned phi = localMax.gctPhi();
222  int16_t bx = localMax.bx();
223 
224  unsigned localEta = localMax.rctEta();
225  unsigned localPhi = localMax.rctPhi();
226 
227  unsigned etCluster = 0;
228  bool ovrFlowOr = false;
229  bool tauVetoOr = false;
230  unsigned rgnsAboveIsoThreshold = 0;
231 
232  // check for row00
233  const unsigned midEta = (L1CaloRegionDetId::N_ETA) / 2;
234  bool wrongEtaWheel = ((!m_positiveEtaWheel) && (eta >= midEta)) || ((m_positiveEtaWheel) && (eta < midEta));
235 
236  // Which rows are we looking over?
237  unsigned rowStart, rowEnd, rowMid;
238  static const unsigned row0 = N_EXTRA_REGIONS_ETA00 - 1;
239  if (wrongEtaWheel) {
240  if (localEta > row0 - 1) {
241  rowStart = 0;
242  rowMid = 0;
243  } else {
244  rowStart = row0 - 1 - localEta;
245  rowMid = rowStart + 1;
246  }
247  if (localEta > row0 + 2) { // Shouldn't happen, but big problems if it does
248  rowEnd = 0;
249  } else {
250  rowEnd = row0 + 2 - localEta;
251  }
252  } else {
253  rowStart = row0 + localEta;
254  rowMid = rowStart + 1;
255  if (localEta < COL_OFFSET - row0 - 2) {
256  rowEnd = rowStart + 3;
257  } else {
258  rowEnd = COL_OFFSET;
259  }
260  }
261 
262  for (unsigned row = rowStart; row < rowEnd; ++row) {
263  for (unsigned column = 0; column < 2; ++column) {
264  unsigned index = column * COL_OFFSET + row;
265  etCluster += m_inputRegions.at(index).et();
266  ovrFlowOr |= m_inputRegions.at(index).overFlow();
267  // Distinguish between central and tau-flagged jets. Two versions of the algorithm.
268  if (m_useImprovedTauAlgo) {
269  //===========================================================================================
270  // "Old" version of improved tau algorithm tests the tau veto for the central region always
271  // if ((row==(localEta+N_EXTRA_REGIONS_ETA00)) && (column==localPhi)) {
272  // // central region - check the tau veto
273  // tauVetoOr |= m_inputRegions.at(index).tauVeto();
274  // } else {
275  // // other regions - check the tau veto if required
276  // if (!m_ignoreTauVetoBitsForIsolation) {
277  // tauVetoOr |= m_inputRegions.at(index).tauVeto();
278  // }
279  // // check the region energy against the isolation threshold
280  // if (m_inputRegions.at(index).et() >= m_tauIsolationThreshold) {
281  // rgnsAboveIsoThreshold++;
282  // }
283  // }
284  //===========================================================================================
285 
286  // In the hardware, the ignoreTauVetoBitsForIsolation switch ignores all the veto bits,
287  // including the one for the central region.
288  if (!((row == rowMid) && (column == localPhi))) {
289  // non-central region - check the region energy against the isolation threshold
290  if (m_inputRegions.at(index).et() >= m_tauIsolationThreshold) {
291  rgnsAboveIsoThreshold++;
292  }
293  }
294  // all regions - check the tau veto if required
296  tauVetoOr |= m_inputRegions.at(index).tauVeto();
297  }
298  // End of improved tau algorithm
299  } else {
300  // Original tau algorithm
301  tauVetoOr |= m_inputRegions.at(index).tauVeto();
302  }
303  }
304  }
305  // Encode the number of towers over threshold for the isolated tau algorithm
306  bool tauFeatureBit = false;
307  if (m_useImprovedTauAlgo) {
308  tauVetoOr |= (rgnsAboveIsoThreshold > 1);
309  tauFeatureBit |= (rgnsAboveIsoThreshold == 1);
310  }
311 
312  L1GctRegion temp(L1GctRegion::makeProtoJetRegion(etCluster, ovrFlowOr, tauVetoOr, tauFeatureBit, eta, phi, bx));
313  return temp;
314 }
315 
318  m_clusters.clear();
319  m_clusters.resize(MAX_JETS_OUT);
320 
321  // Loop over proto-jets received from neighbours.
322  // Form a jet to send to the output if there is no proto-jet nearby in the
323  // list of jets found locally. If local jets are found nearby, form a jet
324  // if the received jet has higher Et than any one of the local ones.
325  for (unsigned j = 0; j < MAX_JETS_OUT; ++j) {
326  unsigned et0 = m_rcvdProtoJets.at(j).et();
327  unsigned localEta0 = m_rcvdProtoJets.at(j).rctEta();
328  unsigned localPhi0 = m_rcvdProtoJets.at(j).rctPhi();
329  unsigned JET_THRESHOLD = ((localEta0 >= m_EtaBoundry) ? m_FwdJetSeed : m_CenJetSeed);
330  if (et0 >= JET_THRESHOLD) {
331  bool storeJet = false;
332  bool isolated = true;
333  // eta00 boundary check/veto
334  if (localEta0 == 0) {
335  unsigned neighbourEt = m_cluster00.at(1 - localPhi0).et();
336  isolated &= et0 >= neighbourEt;
337  }
338  // If the jet is NOT vetoed, look at the jets found locally (m_keptProtoJets).
339  // We accept the jet if there are no local jets nearby, or if the local jet
340  // (there should be no more than one) has lower Et.
341  if (isolated) {
342  for (unsigned k = 0; k < MAX_JETS_OUT; ++k) {
343  unsigned et1 = m_keptProtoJets.at(k).et();
344  unsigned localEta1 = m_keptProtoJets.at(k).rctEta();
345  unsigned localPhi1 = m_keptProtoJets.at(k).rctPhi();
346  if (et1 > 0) {
347  bool distantJet = ((localPhi0 == localPhi1) || (localEta1 > localEta0 + 1) || (localEta0 > localEta1 + 1));
348 
349  isolated &= distantJet;
350  storeJet |= !distantJet && ((et0 > et1) || ((et0 == et1) && localPhi0 == 1));
351  }
352  }
353  }
354 
355  storeJet |= isolated;
356 
357  if (storeJet) {
358  // Start with the et sum, tau veto and overflow flags of the protoJet (2x3 regions)
359  unsigned etCluster = et0;
360  bool ovrFlowOr = m_rcvdProtoJets.at(j).overFlow();
361  bool tauVetoOr = m_rcvdProtoJets.at(j).tauVeto();
362  unsigned rgnsAboveIsoThreshold = (m_rcvdProtoJets.at(j).featureBit0() ? 1 : 0);
363 
364  // Combine with the corresponding regions from
365  // the local array to make a 3x3 jet cluster
366  unsigned column = 1 - localPhi0;
367  // Which rows are we looking over?
368  unsigned rowStart, rowEnd;
369  static const unsigned row0 = N_EXTRA_REGIONS_ETA00 - 1;
370  rowStart = row0 + localEta0;
371  if (localEta0 < COL_OFFSET - row0 - 2) {
372  rowEnd = rowStart + 3;
373  } else {
374  rowEnd = COL_OFFSET;
375  }
376  unsigned index = COL_OFFSET * (this->centralCol0() + column) + rowStart;
377  for (unsigned row = rowStart; row < rowEnd; ++row) {
378  etCluster += m_inputRegions.at(index).et();
379  ovrFlowOr |= m_inputRegions.at(index).overFlow();
380  if (m_useImprovedTauAlgo) {
382  tauVetoOr |= m_inputRegions.at(index).tauVeto();
383  }
384  // check the region energy against the isolation threshold
385  if (m_inputRegions.at(index).et() >= m_tauIsolationThreshold) {
386  rgnsAboveIsoThreshold++;
387  }
388  } else {
389  tauVetoOr |= m_inputRegions.at(index).tauVeto();
390  }
391 
392  ++index;
393  }
394 
395  // Store the new jet
396  unsigned eta = m_rcvdProtoJets.at(j).gctEta();
397  unsigned phi = m_rcvdProtoJets.at(j).gctPhi();
398  int16_t bx = m_rcvdProtoJets.at(j).bx();
399 
400  // Use the number of towers over threshold for the isolated tau algorithm
401  if (m_useImprovedTauAlgo) {
402  tauVetoOr |= (rgnsAboveIsoThreshold > 1);
403  }
404 
405  L1GctRegion temp(L1GctRegion::makeFinalJetRegion(etCluster, ovrFlowOr, tauVetoOr, eta, phi, bx));
406  m_clusters.at(j) = temp;
407  }
408  }
409  }
410 }
411 
414  for (unsigned j = 0; j < MAX_JETS_OUT; ++j) {
415  bool isForward = (m_clusters.at(j).rctEta() >= m_EtaBoundry);
416  unsigned JET_THRESHOLD = (isForward ? m_FwdJetSeed : m_CenJetSeed);
417  if (m_clusters.at(j).et() >= JET_THRESHOLD) {
418  m_keptProtoJets.at(j) = m_clusters.at(j);
419  m_sentProtoJets.at(j) = m_clusters.at(j);
420  }
421  }
422 }
423 
426  for (unsigned j = 0; j < MAX_JETS_OUT; ++j) {
427  bool isForward = (m_clusters.at(j).rctEta() >= m_EtaBoundry);
428  unsigned JET_THRESHOLD = (isForward ? m_FwdJetSeed : m_CenJetSeed);
429  if (m_clusters.at(j).et() >= JET_THRESHOLD) {
430  L1GctJet temp(m_clusters.at(j).et(),
431  m_clusters.at(j).gctEta(),
432  m_clusters.at(j).gctPhi(),
433  m_clusters.at(j).overFlow(),
434  isForward,
435  m_clusters.at(j).tauVeto(),
436  m_clusters.at(j).bx());
437  m_outputJets.at(j) = temp;
438  }
439  }
440 }
L1GctHardwareJetFinder::CENTRAL_COL0
static const unsigned int CENTRAL_COL0
Definition: L1GctHardwareJetFinder.h:48
L1GctJetFinderBase::COL_OFFSET
static const unsigned int COL_OFFSET
The index offset between columns.
Definition: L1GctJetFinderBase.h:112
L1GctJetFinderBase::UShort
unsigned short int UShort
Definition: L1GctJetFinderBase.h:52
L1GctJetFinderBase::RegionsVector
std::vector< L1GctRegion > RegionsVector
Definition: L1GctJetFinderBase.h:53
L1GctHardwareJetFinder.h
L1GctHardwareJetFinder::convertClustersToOutputJets
void convertClustersToOutputJets()
Organise the final clustered jets into L1GctJets.
Definition: L1GctHardwareJetFinder.cc:425
L1GctJetFinderBase::N_EXTRA_REGIONS_ETA00
static const unsigned int N_EXTRA_REGIONS_ETA00
Number of additional regions to process on the "wrong" side of eta=0 (determines COL_OFFSET)
Definition: L1GctJetFinderBase.h:115
GlobalTrackerMuonAlignment_cfi.isolated
isolated
Definition: GlobalTrackerMuonAlignment_cfi.py:4
L1GctJetFinderBase::m_keptProtoJets
RegionsVector m_keptProtoJets
List of pre-clustered jets retained locally as input to the final clustering.
Definition: L1GctJetFinderBase.h:309
L1GctHardwareJetFinder::findProtoClusters
void findProtoClusters()
Convert local maxima to clusters.
Definition: L1GctHardwareJetFinder.cc:149
L1CaloRegion::gctEta
unsigned gctEta() const
get GCT eta index
Definition: L1CaloRegion.h:153
L1GctJetFinderBase::MAX_JETS_OUT
static const unsigned int MAX_JETS_OUT
Max of 6 jets found per jetfinder in a 2*11 search area.
Definition: L1GctJetFinderBase.h:111
L1GctHardwareJetFinder::m_cluster00
RegionsVector m_cluster00
Definition: L1GctHardwareJetFinder.h:60
L1GctJetFinderBase::m_positiveEtaWheel
bool m_positiveEtaWheel
Definition: L1GctJetFinderBase.h:250
pos
Definition: PixelAliasList.h:18
L1GctJetFinderBase::m_outputJets
RawJetVector m_outputJets
output jets
Definition: L1GctJetFinderBase.h:312
L1CaloRegion::bx
int16_t bx() const
get bunch-crossing index
Definition: L1CaloRegion.h:165
L1GctJetFinderBase::m_EtaBoundry
unsigned m_EtaBoundry
Definition: L1GctJetFinderBase.h:263
L1GctJetFinderBase
Base class to allow implementation of jetFinder algorithms.
Definition: L1GctJetFinderBase.h:48
L1GctHardwareJetFinder::findFinalClusters
void findFinalClusters()
Convert protojets to final jets.
Definition: L1GctHardwareJetFinder.cc:317
l1GtPatternGenerator_cfi.bx
bx
Definition: l1GtPatternGenerator_cfi.py:18
L1GctHardwareJetFinder::L1GctHardwareJetFinder
L1GctHardwareJetFinder(int id)
id is 0-8 for -ve Eta jetfinders, 9-17 for +ve Eta, for increasing Phi.
Definition: L1GctHardwareJetFinder.cc:9
L1GctHardwareJetFinder
Emulation of the hardware jet finder.
Definition: L1GctHardwareJetFinder.h:18
L1GctHardwareJetFinder::findProtoJets
void findProtoJets()
The first stage of clustering, called by fetchInput()
Definition: L1GctHardwareJetFinder.cc:52
operator<<
std::ostream & operator<<(std::ostream &os, const L1GctHardwareJetFinder &algo)
Definition: L1GctHardwareJetFinder.cc:25
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list temp
Definition: groupFilesInBlocks.py:142
ecaldqm::isForward
bool isForward(DetId const &)
Definition: EcalDQMCommonUtils.cc:243
L1GctHardwareJetFinder::convertClustersToProtoJets
void convertClustersToProtoJets()
Organise the pre-clustered jets into the ones we keep and those we send to the neighbour.
Definition: L1GctHardwareJetFinder.cc:413
L1GctRegion::makeProtoJetRegion
static L1GctRegion makeProtoJetRegion(const unsigned et, const bool overFlow, const bool fineGrain, const bool tauIsolationVeto, const unsigned ieta, const unsigned iphi, const int16_t bx)
Definition: L1GctRegion.cc:13
L1GctJetFinderBase::fetchProtoJetsFromNeighbour
void fetchProtoJetsFromNeighbour(const fetchType ft)
fetch the protoJets from neighbour jetFinder
Definition: L1GctJetFinderBase.cc:312
cmsdt::algo
algo
Definition: constants.h:164
L1GctHardwareJetFinder::process
void process() override
process the data, fill output buffers
Definition: L1GctHardwareJetFinder.cc:40
L1GctHardwareJetFinder::m_clusters
RegionsVector m_clusters
Each local maximum becomes a cluster.
Definition: L1GctHardwareJetFinder.h:53
L1GctHardwareJetFinder::findLocalMaxima
void findLocalMaxima()
Find local maxima in the search array.
Definition: L1GctHardwareJetFinder.cc:66
L1GctHardwareJetFinder::reset
virtual void reset()
include additional reset functionality
Definition: L1GctHardwareJetFinder.cc:32
PVValHelper::eta
Definition: PVValidationHelpers.h:69
L1GctJetFinderBase::m_rcvdProtoJets
RegionsVector m_rcvdProtoJets
List of pre-clustered jets received from neighbour before the final stage of clustering.
Definition: L1GctJetFinderBase.h:307
L1GctJetFinderBase::m_minColThisJf
unsigned m_minColThisJf
parameter to determine which Regions belong in our acceptance
Definition: L1GctJetFinderBase.h:253
L1GctProcessor::reset
void reset()
complete reset of processor
Definition: L1GctProcessor.h:28
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Definition: dqmdumpme.py:60
L1CaloRegionDetId::N_ETA
static const unsigned N_ETA
Definition: L1CaloRegionDetId.h:21
L1GctJetFinderBase::m_inputRegions
RegionsVector m_inputRegions
Definition: L1GctJetFinderBase.h:302
L1GctRegion::rctEta
unsigned rctEta() const
Definition: L1GctRegion.h:50
L1GctJetFinderBase::m_useImprovedTauAlgo
bool m_useImprovedTauAlgo
Setup parameters for the tau jet algorithm.
Definition: L1GctJetFinderBase.h:271
L1GctJetFinderBase::m_sentProtoJets
RegionsVector m_sentProtoJets
List of pre-clustered jets to be sent to neighbour after the first stage of clustering.
Definition: L1GctJetFinderBase.h:305
L1GctJetFinderBase::m_ignoreTauVetoBitsForIsolation
bool m_ignoreTauVetoBitsForIsolation
Definition: L1GctJetFinderBase.h:278
L1GctJetFinderBase::m_id
int m_id
algo ID
Definition: L1GctJetFinderBase.h:226
L1GctRegion::makeFinalJetRegion
static L1GctRegion makeFinalJetRegion(const unsigned et, const bool overFlow, const bool fineGrain, const unsigned ieta, const unsigned iphi, const int16_t bx)
Definition: L1GctRegion.cc:29
L1GctJetFinderBase::TOPBOT
Definition: L1GctJetFinderBase.h:223
L1GctHardwareJetFinder::m_localMaxima
RegionsVector m_localMaxima
Local vectors used during both stages of clustering.
Definition: L1GctHardwareJetFinder.h:51
L1GctHardwareJetFinder::m_localMax00
RegionsVector m_localMax00
Definition: L1GctHardwareJetFinder.h:59
L1GctJetFinderBase::setupOk
bool setupOk() const
Check setup is Ok.
Definition: L1GctJetFinderBase.h:141
L1GctHardwareJetFinder::centralCol0
unsigned centralCol0() const override
Definition: L1GctHardwareJetFinder.h:41
L1CaloRegionDetId::N_PHI
static const unsigned N_PHI
Definition: L1CaloRegionDetId.h:20
DDAxes::phi
L1GctJet
A Level-1 jet candidate, used within GCT emulation.
Definition: L1GctJet.h:26
L1GctHardwareJetFinder::m_numberOfClusters
unsigned m_numberOfClusters
The number of local Maxima/clusters found at each stage of clustering.
Definition: L1GctHardwareJetFinder.h:56
L1GctHardwareJetFinder::~L1GctHardwareJetFinder
~L1GctHardwareJetFinder() override
Definition: L1GctHardwareJetFinder.cc:23
triggerObjects_cff.id
id
Definition: triggerObjects_cff.py:31
L1GctJetFinderBase::m_CenJetSeed
unsigned m_CenJetSeed
Definition: L1GctJetFinderBase.h:260
L1GctJetFinderBase::doEnergySums
void doEnergySums()
Fill the Et strip sums and Ht sum. All jetFinders should call this in process().
Definition: L1GctJetFinderBase.cc:353
AlignmentPI::index
index
Definition: AlignmentPayloadInspectorHelper.h:46
L1CaloRegion::rctPhi
unsigned rctPhi() const
get local phi index (within RCT crate)
Definition: L1CaloRegion.h:150
L1GctHardwareJetFinder::N_COLS
static const unsigned int N_COLS
Definition: L1GctHardwareJetFinder.h:47
L1GctHardwareJetFinder::findJets
void findJets()
The second stage of clustering, called by process()
Definition: L1GctHardwareJetFinder.cc:59
L1GctRegion
Gct version of a calorimeter region, used within GCT emulation.
Definition: L1GctRegion.h:17
dqmiolumiharvest.j
j
Definition: dqmiolumiharvest.py:66
L1GctHardwareJetFinder::MAX_REGIONS_IN
static const unsigned int MAX_REGIONS_IN
The real jetFinders must define these constants.
Definition: L1GctHardwareJetFinder.h:46
L1GctJetFinderBase::m_tauIsolationThreshold
unsigned m_tauIsolationThreshold
Definition: L1GctJetFinderBase.h:282
L1GctHardwareJetFinder::makeProtoJet
L1GctRegion makeProtoJet(L1GctRegion localMax)
Method to make a single proto-jet.
Definition: L1GctHardwareJetFinder.cc:219
L1GctHardwareJetFinder::fetchInput
void fetchInput() override
get input data from sources
Definition: L1GctHardwareJetFinder.cc:34
L1GctJetFinderBase::m_FwdJetSeed
unsigned m_FwdJetSeed
Definition: L1GctJetFinderBase.h:261
L1GctJetFinderBase::sortJets
void sortJets()
Sort the found jets. All jetFinders should call this in process().
Definition: L1GctJetFinderBase.cc:338
L1CaloRegion::gctPhi
unsigned gctPhi() const
get GCT phi index
Definition: L1CaloRegion.h:156