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EcalTPGParamBuilder.cc
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1 #include "EcalTPGParamBuilder.h"
2 #include "EcalTPGDBApp.h"
3 
5 
9 
11 
12 //modif-alex-27-july-2015
15 
18 
19 #include <TF1.h>
20 #include <TH2F.h>
21 #include <TFile.h>
22 #include <TNtuple.h>
23 #include <ctime>
24 #include <iomanip>
25 #include <fstream>
26 #include <iostream>
27 #include <string>
28 #include <sstream>
29 
30 using namespace std;
31 
32 double oneOverEtResolEt(double* x, double* par) {
33  double Et = x[0];
34  if (Et < 1e-6)
35  return 1. / par[1]; // to avoid division by 0.
36  double resolEt_overEt =
37  sqrt((par[0] / sqrt(Et)) * (par[0] / sqrt(Et)) + (par[1] / Et) * (par[1] / Et) + par[2] * par[2]);
38  return 1. / (Et * resolEt_overEt);
39 }
40 
42  : theEndcapGeometryToken_(esConsumes(edm::ESInputTag("", "EcalEndcap"))),
43  theBarrelGeometryToken_(esConsumes(edm::ESInputTag("", "EcalBarrel"))),
44  eTTmapToken_(esConsumes()),
45  ecalmappingToken_(esConsumes()),
46  ecalLaserAlphasToken_(esConsumes()),
47  ecalLaserAPDPNRatiosToken_(esConsumes()),
48  ecalPedestalsToken_(esConsumes()),
49  ecalIntercalibConstantsToken_(esConsumes()),
50  ecalGainRatiosToken_(esConsumes()),
51  ecalADCToGeVConstantToken_(esConsumes()),
52  xtal_LSB_EB_(0),
53  xtal_LSB_EE_(0),
54  nSample_(5),
55  complement2_(7),
56  shapeEB_(consumesCollector()), // EBShape, EEShape are fetched now from DB (2018.05.22 K. Theofilatos)
57  shapeEE_(consumesCollector()) {
58  ped_conf_id_ = 0;
59  lin_conf_id_ = 0;
60  lut_conf_id_ = 0;
61  wei_conf_id_ = 0;
62  wei2_conf_id_ = 0;
63  fgr_conf_id_ = 0;
64  sli_conf_id_ = 0;
65  spi_conf_id_ = 0; //modif-alex 21/01/11
66  del_conf_id_ = 0; //modif-alex 21/01/11
67  bxt_conf_id_ = 0;
68  btt_conf_id_ = 0;
69  bst_conf_id_ = 0;
70  coke_conf_id_ = 0;
71  tag_ = "";
72  version_ = 0;
73 
74  m_write_ped = 1;
75  m_write_lin = 1;
76  m_write_lut = 1;
77  m_write_wei = 1;
78  m_write_wei2 = 1;
79  m_write_fgr = 1;
80  m_write_sli = 1;
81  m_write_spi = 1; //modif-alex 21/01/11
82  m_write_del = 1; //modif-alex 21/01/11
83  m_write_bxt = 1;
84  m_write_btt = 1;
85  m_write_bst = 1;
86 
87  writeToDB_ = pSet.getParameter<bool>("writeToDB");
88  DBEE_ = pSet.getParameter<bool>("allowDBEE");
89  string DBsid = pSet.getParameter<std::string>("DBsid");
90  string DBuser = pSet.getParameter<std::string>("DBuser");
91  string DBpass = pSet.getParameter<std::string>("DBpass");
92  //uint32_t DBport = pSet.getParameter<unsigned int>("DBport") ;
93 
94  tag_ = pSet.getParameter<std::string>("TPGtag");
95  version_ = pSet.getParameter<unsigned int>("TPGversion");
96 
97  m_write_ped = pSet.getParameter<unsigned int>("TPGWritePed");
98  m_write_lin = pSet.getParameter<unsigned int>("TPGWriteLin");
99  m_write_lut = pSet.getParameter<unsigned int>("TPGWriteLut");
100  m_write_wei = pSet.getParameter<unsigned int>("TPGWriteWei");
101  m_write_wei2 = pSet.getParameter<unsigned int>("TPGWriteWei2");
102  m_write_fgr = pSet.getParameter<unsigned int>("TPGWriteFgr");
103  m_write_sli = pSet.getParameter<unsigned int>("TPGWriteSli");
104  m_write_spi = pSet.getParameter<unsigned int>("TPGWriteSpi"); //modif-alex 21/01/11
105  m_write_del = pSet.getParameter<unsigned int>("TPGWriteDel"); //modif-alex 21/01/11
106  m_write_bxt = pSet.getParameter<unsigned int>("TPGWriteBxt");
107  m_write_btt = pSet.getParameter<unsigned int>("TPGWriteBtt");
108  m_write_bst = pSet.getParameter<unsigned int>("TPGWriteBst");
109 
113 
114  if (m_write_ped != 0 && m_write_ped != 1)
116 
117  if (writeToDB_)
118  edm::LogInfo("TopInfo") << "data will be saved with tag and version=" << tag_ << ".version" << version_ << "\n";
120 
121  writeToFiles_ = pSet.getParameter<bool>("writeToFiles");
122  if (writeToFiles_) {
123  std::string outFile = pSet.getParameter<std::string>("outFile");
124  out_file_ = new std::ofstream(outFile.c_str(), std::ios::out);
125  }
126  geomFile_ = new std::ofstream("geomFile.txt", std::ios::out);
127 
128  useTransverseEnergy_ = pSet.getParameter<bool>("useTransverseEnergy");
129 
130  Et_sat_EB_ = pSet.getParameter<double>("Et_sat_EB");
131  Et_sat_EE_ = pSet.getParameter<double>("Et_sat_EE");
132  sliding_ = pSet.getParameter<unsigned int>("sliding");
133  weight_timeShift_ = pSet.getParameter<double>("weight_timeShift");
134  sampleMax_ = pSet.getParameter<unsigned int>("weight_sampleMax");
135  weight_unbias_recovery_ = pSet.getParameter<bool>("weight_unbias_recovery");
136 
137  weight_even_computeFromShape_ = pSet.getParameter<bool>("weight_even_computeFromShape");
138  weight_even_idMapFile_ = pSet.getParameter<std::string>("weight_even_idMapFile");
139  weight_even_weightGroupFile_ = pSet.getParameter<std::string>("weight_even_weightGroupFile");
140  weight_odd_idMapFile_ = pSet.getParameter<std::string>("weight_odd_idMapFile");
141  weight_odd_weightGroupFile_ = pSet.getParameter<std::string>("weight_odd_weightGroupFile");
142 
143  weight_useDoubleWeights_ = pSet.getParameter<bool>("weight_useDoubleWeights");
144  TPmode_EnableEBOddFilter_ = pSet.getParameter<bool>("TPmode_EnableEBOddFilter");
145  TPmode_EnableEEOddFilter_ = pSet.getParameter<bool>("TPmode_EnableEEOddFilter");
146  TPmode_EnableEBOddPeakFinder_ = pSet.getParameter<bool>("TPmode_EnableEBOddPeakFinder");
147  TPmode_EnableEEOddPeakFinder_ = pSet.getParameter<bool>("TPmode_EnableEEOddPeakFinder");
148  TPmode_DisableEBEvenPeakFinder_ = pSet.getParameter<bool>("TPmode_DisableEBEvenPeakFinder");
149  TPmode_DisableEEEvenPeakFinder_ = pSet.getParameter<bool>("TPmode_DisableEEEvenPeakFinder");
150  TPmode_FenixEBStripOutput_ = pSet.getParameter<unsigned int>("TPmode_FenixEBStripOutput");
151  TPmode_FenixEEStripOutput_ = pSet.getParameter<unsigned int>("TPmode_FenixEEStripOutput");
152  TPmode_FenixEBStripInfobit2_ = pSet.getParameter<unsigned int>("TPmode_FenixEBStripInfobit2");
153  TPmode_FenixEEStripInfobit2_ = pSet.getParameter<unsigned int>("TPmode_FenixEEStripInfobit2");
154  TPmode_FenixEBTcpOutput_ = pSet.getParameter<unsigned int>("TPmode_FenixEBTcpOutput");
155  TPmode_FenixEBTcpInfobit1_ = pSet.getParameter<unsigned int>("TPmode_FenixEBTcpInfobit1");
156  TPmode_FenixEETcpOutput_ = pSet.getParameter<unsigned int>("TPmode_FenixEETcpOutput");
157  TPmode_FenixEETcpInfobit1_ = pSet.getParameter<unsigned int>("TPmode_FenixEETcpInfobit1");
158 
159  forcedPedestalValue_ = pSet.getParameter<int>("forcedPedestalValue");
160  forceEtaSlice_ = pSet.getParameter<bool>("forceEtaSlice");
161 
162  LUT_option_ = pSet.getParameter<std::string>("LUT_option");
163  LUT_threshold_EB_ = pSet.getParameter<double>("LUT_threshold_EB");
164  LUT_threshold_EE_ = pSet.getParameter<double>("LUT_threshold_EE");
165  LUT_stochastic_EB_ = pSet.getParameter<double>("LUT_stochastic_EB");
166  LUT_noise_EB_ = pSet.getParameter<double>("LUT_noise_EB");
167  LUT_constant_EB_ = pSet.getParameter<double>("LUT_constant_EB");
168  LUT_stochastic_EE_ = pSet.getParameter<double>("LUT_stochastic_EE");
169  LUT_noise_EE_ = pSet.getParameter<double>("LUT_noise_EE");
170  LUT_constant_EE_ = pSet.getParameter<double>("LUT_constant_EE");
171 
172  TTF_lowThreshold_EB_ = pSet.getParameter<double>("TTF_lowThreshold_EB");
173  TTF_highThreshold_EB_ = pSet.getParameter<double>("TTF_highThreshold_EB");
174  TTF_lowThreshold_EE_ = pSet.getParameter<double>("TTF_lowThreshold_EE");
175  TTF_highThreshold_EE_ = pSet.getParameter<double>("TTF_highThreshold_EE");
176 
177  FG_lowThreshold_EB_ = pSet.getParameter<double>("FG_lowThreshold_EB");
178  FG_highThreshold_EB_ = pSet.getParameter<double>("FG_highThreshold_EB");
179  FG_lowRatio_EB_ = pSet.getParameter<double>("FG_lowRatio_EB");
180  FG_highRatio_EB_ = pSet.getParameter<double>("FG_highRatio_EB");
181  FG_lut_EB_ = pSet.getParameter<unsigned int>("FG_lut_EB");
182  FG_Threshold_EE_ = pSet.getParameter<double>("FG_Threshold_EE");
183  FG_lut_strip_EE_ = pSet.getParameter<unsigned int>("FG_lut_strip_EE");
184  FG_lut_tower_EE_ = pSet.getParameter<unsigned int>("FG_lut_tower_EE");
185  SFGVB_Threshold_ = pSet.getParameter<unsigned int>("SFGVB_Threshold");
186  SFGVB_lut_ = pSet.getParameter<unsigned int>("SFGVB_lut");
187  SFGVB_SpikeKillingThreshold_ = pSet.getParameter<int>("SFGVB_SpikeKillingThreshold"); //modif-alex 21/01/11
188  pedestal_offset_ = pSet.getParameter<unsigned int>("pedestal_offset");
189 
190  useInterCalibration_ = pSet.getParameter<bool>("useInterCalibration");
191  H2_ = pSet.getUntrackedParameter<bool>("H2", false);
192 
193  useTransparencyCorr_ = false;
194  useTransparencyCorr_ = pSet.getParameter<bool>("useTransparencyCorr"); //modif-alex-25/04/2012
195  Transparency_Corr_ = pSet.getParameter<std::string>("transparency_corrections"); //modif-alex-30/01/2012
196 
197  //modif-alex-23/02/2011
198  //convert the spike killing first from GeV to ADC (10 bits)
199  //depending on the saturation scale: Et_sat_EB_
201  SFGVB_SpikeKillingThreshold_ = 1023; //nokilling
202  else
204  edm::LogInfo("TopInfo") << "INFO:SPIKE KILLING THRESHOLD (ADC)=" << SFGVB_SpikeKillingThreshold_ << "\n";
205 
206  //modif-alex-02/02/11
207  //TIMING information
208  TimingDelays_EB_ = pSet.getParameter<std::string>("timing_delays_EB");
209  TimingDelays_EE_ = pSet.getParameter<std::string>("timing_delays_EE");
210  TimingPhases_EB_ = pSet.getParameter<std::string>("timing_phases_EB");
211  TimingPhases_EE_ = pSet.getParameter<std::string>("timing_phases_EE");
212 
213  std::ostringstream ss;
214  // edm::LogInfo("TopInfo") << "INFO: READING timing files" << "\n";
215  ss << "INFO: READING timing files\n";
216  std::ifstream delay_eb(TimingDelays_EB_.c_str());
217  if (!delay_eb)
218  edm::LogError("TopInfo") << "ERROR: File " << TimingDelays_EB_.c_str() << " could not be opened"
219  << "\n";
220  std::ifstream delay_ee(TimingDelays_EE_.c_str());
221  if (!delay_ee)
222  edm::LogError("TopInfo") << "ERROR: File " << TimingDelays_EE_.c_str() << " could not be opened"
223  << "\n";
224  std::ifstream phase_eb(TimingPhases_EB_.c_str());
225  if (!phase_eb)
226  edm::LogError("TopInfo") << "ERROR: File " << TimingPhases_EB_.c_str() << " could not be opened"
227  << "\n";
228  std::ifstream phase_ee(TimingPhases_EE_.c_str());
229  if (!phase_ee)
230  edm::LogError("TopInfo") << "ERROR: File " << TimingPhases_EE_.c_str() << " could not be opened"
231  << "\n";
232 
233  char buf[1024];
234  //READING DELAYS EB
235  delay_eb.getline(buf, sizeof(buf), '\n');
236  while (delay_eb) {
237  std::stringstream sin(buf);
238 
239  int tcc;
240  sin >> tcc;
241 
242  vector<int> vec_delays_eb;
243  for (int ieb = 0; ieb < 68; ++ieb) {
244  int time_delay = -1;
245  sin >> time_delay;
246  vec_delays_eb.push_back(time_delay);
247  if (time_delay == -1)
248  edm::LogError("TopInfo") << "ERROR:Barrel timing delay -1, check file"
249  << "\n";
250  }
251 
252  if (vec_delays_eb.size() != 68)
253  edm::LogError("TopInfo") << "ERROR:Barrel timing delay wrong, not enough towers, check file"
254  << "\n";
255 
256  if (delays_EB_.find(tcc) == delays_EB_.end())
257  delays_EB_.insert(make_pair(tcc, vec_delays_eb));
258 
259  // edm::LogInfo("TopInfo") << tcc << "\n";
260  ss << tcc;
261  for (unsigned int ieb = 0; ieb < vec_delays_eb.size(); ++ieb)
262  // edm::LogInfo("TopInfo") << vec_delays_eb[ieb] << "\n";
263  ss << " " << vec_delays_eb[ieb];
264  delay_eb.getline(buf, sizeof(buf), '\n');
265  ss << "\n";
266  } //loop delay file EB
267  delay_eb.close();
268 
269  //READING PHASES EB
270  phase_eb.getline(buf, sizeof(buf), '\n');
271  while (phase_eb) {
272  std::stringstream sin(buf);
273  int tcc;
274  sin >> tcc;
275 
276  vector<int> vec_phases_eb;
277  for (unsigned int ieb = 0; ieb < 68; ++ieb) {
278  int time_phase = -1;
279  sin >> time_phase;
280  vec_phases_eb.push_back(time_phase);
281  if (time_phase == -1)
282  edm::LogError("TopInfo") << "ERROR:Barrel timing phase -1, check file"
283  << "\n";
284  }
285 
286  if (vec_phases_eb.size() != 68)
287  edm::LogError("TopInfo") << "ERROR:Barrel timing phase wrong, not enough towers, check file"
288  << "\n";
289 
290  if (phases_EB_.find(tcc) == phases_EB_.end())
291  phases_EB_.insert(make_pair(tcc, vec_phases_eb));
292 
293  // edm::LogInfo("TopInfo") << tcc << "\n";
294  ss << tcc;
295  for (unsigned int ieb = 0; ieb < vec_phases_eb.size(); ++ieb)
296  // edm::LogInfo("TopInfo") << vec_phases_eb[ieb] << "\n";
297  ss << " " << vec_phases_eb[ieb];
298  phase_eb.getline(buf, sizeof(buf), '\n');
299  ss << "\n";
300  } //loop phase file EB
301  phase_eb.close();
302 
303  //READING DELAYS EE//------------------------------------------------
304  delay_ee.getline(buf, sizeof(buf), '\n');
305  while (delay_ee) {
306  std::stringstream sin(buf);
307  int tcc;
308  sin >> tcc;
309 
310  vector<int> vec_delays_ee;
311  for (unsigned int iee = 0; iee < 48; ++iee) {
312  int time_delay = -1;
313  sin >> time_delay;
314  vec_delays_ee.push_back(time_delay);
315  if (time_delay == -1)
316  edm::LogError("TopInfo") << "ERROR:EE timing delay -1, check file"
317  << "\n";
318  }
319 
320  if (vec_delays_ee.size() != 48)
321  edm::LogError("TopInfo") << "ERROR:EE timing delay wrong, not enough towers, check file"
322  << "\n";
323 
324  if (delays_EE_.find(tcc) == delays_EE_.end())
325  delays_EE_.insert(make_pair(tcc, vec_delays_ee));
326 
327  // edm::LogInfo("TopInfo") << tcc << "\n";
328  ss << tcc;
329  for (unsigned int iee = 0; iee < vec_delays_ee.size(); ++iee)
330  // edm::LogInfo("TopInfo") << vec_delays_ee[iee] << "\n";
331  ss << " " << vec_delays_ee[iee];
332  ss << "\n";
333  delay_ee.getline(buf, sizeof(buf), '\n');
334  } //loop delay file EE
335  delay_ee.close();
336 
337  //READING PHASES EE
338  phase_ee.getline(buf, sizeof(buf), '\n');
339  while (phase_ee) {
340  std::stringstream sin(buf);
341  int tcc;
342  sin >> tcc;
343 
344  vector<int> vec_phases_ee;
345  for (unsigned int iee = 0; iee < 48; ++iee) {
346  int time_phase = -1;
347  sin >> time_phase;
348  vec_phases_ee.push_back(time_phase);
349  if (time_phase == -1)
350  edm::LogError("TopInfo") << "ERROR:EE timing phase -1, check file"
351  << "\n";
352  }
353 
354  if (vec_phases_ee.size() != 48)
355  edm::LogError("TopInfo") << "ERROR:EE timing phase wrong, not enough towers, check file"
356  << "\n";
357 
358  if (phases_EE_.find(tcc) == phases_EE_.end())
359  phases_EE_.insert(make_pair(tcc, vec_phases_ee));
360  // edm::LogInfo("TopInfo") << tcc << "\n";
361  ss << tcc;
362  for (unsigned int iee = 0; iee < vec_phases_ee.size(); ++iee)
363  // edm::LogInfo("TopInfo") << vec_phases_ee[iee] << "\n";
364  ss << " " << vec_phases_ee[iee];
365  ss << "\n";
366  phase_ee.getline(buf, sizeof(buf), '\n');
367  } //loop phase file EE
368  phase_ee.close();
369 
370  // edm::LogInfo("TopInfo") << "INFO: DONE reading timing files for EB and EE" << "\n";
371  ss << "INFO: DONE reading timing files for EB and EE\n";
372  edm::LogInfo("TopInfo") << ss.str();
373 }
374 
376  if (writeToFiles_) {
377  (*out_file_) << "EOF" << std::endl;
378  out_file_->close();
379  delete out_file_;
380  }
381 }
382 
384  bool result = true;
385  if (item.mean_x1 < 150. || item.mean_x1 > 250)
386  result = false;
387  if (item.mean_x6 < 150. || item.mean_x6 > 250)
388  result = false;
389  if (item.mean_x12 < 150. || item.mean_x12 > 250)
390  result = false;
391  if (item.rms_x1 < 0 || item.rms_x1 > 2)
392  result = false;
393  if (item.rms_x6 < 0 || item.rms_x6 > 3)
394  result = false;
395  if (item.rms_x12 < 0 || item.rms_x12 > 5)
396  result = false;
397  return result;
398 }
399 
400 int EcalTPGParamBuilder::getEtaSlice(int tccId, int towerInTCC) {
401  int etaSlice = (towerInTCC - 1) / 4 + 1;
402  // barrel
403  if (tccId > 36 && tccId < 73)
404  return etaSlice;
405  //endcap
406  else {
407  if (tccId >= 1 && tccId <= 18)
408  etaSlice += 21; // inner -
409  else if (tccId >= 19 && tccId <= 36)
410  etaSlice += 17; // outer -
411  else if (tccId >= 91 && tccId <= 108)
412  etaSlice += 21; // inner +
413  else if (tccId >= 73 && tccId <= 90)
414  etaSlice += 17; // outer +
415  }
416  return etaSlice;
417 }
418 
419 void EcalTPGParamBuilder::analyze(const edm::Event& evt, const edm::EventSetup& evtSetup) {
420  using namespace edm;
421  using namespace std;
422 
423  // geometry
424  eTTmap_ = &evtSetup.getData(eTTmapToken_);
427 
428  // electronics mapping
430 
431  // get record for alpha
432  std::ostringstream ss;
433  ss << "EcalLaserDbAnalyzer::analyze\n";
434  const EcalLaserAlphaMap& laserAlphaMap = evtSetup.getData(ecalLaserAlphasToken_).getMap(); // map of apdpns
435  ss << "EcalLaserDbAnalyzer::analyze-> got EcalLaserDbRecord: \n";
436 
437  //modif-alex-27-july-2015-+ Jean june 2016 beg
438  // use alpha to check
440  int cnt = 0;
441  // Barrel loop
442  for (italpha = laserAlphaMap.barrelItems().begin(); italpha != laserAlphaMap.barrelItems().end(); ++italpha) {
443  if (cnt % 1000 == 0) {
444  EBDetId ebdetid = EBDetId::unhashIndex(cnt);
445  ss << " Barrel ALPHA = " << (*italpha) << " cmsswId " << ebdetid.rawId() << "\n";
446  }
447  cnt++;
448  }
449  ss << "Number of barrel Alpha parameters : " << cnt << "\n";
450  // Endcap loop
451  cnt = 0;
452  for (italpha = laserAlphaMap.endcapItems().begin(); italpha != laserAlphaMap.endcapItems().end(); ++italpha) {
453  if (cnt % 1000 == 0) {
454  EEDetId eedetid = EEDetId::unhashIndex(cnt);
455  ss << "EndCap ALPHA = " << (*italpha) << " cmsswId " << eedetid.rawId() << "\n";
456  }
457  cnt++;
458  }
459  ss << "Number of Endcap Alpha parameters : " << cnt << "\n";
460  edm::LogInfo("TopInfo") << ss.str();
461  ss.str("");
462  //modif-alex-27-july-2015 +-Jean june 2016-end
463 
464  //modif-alex-30/01/2012 displaced in analyze Jean 2018
465  ss.str("");
466  if (useTransparencyCorr_) {
467  if (Transparency_Corr_ != "tag") { // Jean 2018
468  edm::LogInfo("TopInfo") << "INFO: READING transparency correction files"
469  << "\n";
470  ss << "INFO: READING transparency correction files\n";
471  std::ifstream transparency(Transparency_Corr_.c_str());
472  if (!transparency)
473  edm::LogError("TopInfo") << "ERROR: File " << Transparency_Corr_.c_str() << " could not be opened"
474  << "\n";
475 
476  char buf[1024];
477  transparency.getline(buf, sizeof(buf), '\n');
478  int xtalcounter = 0;
479  while (transparency) {
480  std::stringstream sin(buf);
481 
482  int raw_xtal_id;
483  sin >> raw_xtal_id;
484 
485  double xtal_trans_corr;
486  sin >> xtal_trans_corr;
487 
488  // edm::LogInfo("TopInfo") << raw_xtal_id << " " << xtal_trans_corr << "\n";
489  ss << raw_xtal_id << " " << xtal_trans_corr << "\n";
490 
491  Transparency_Correction_.insert(make_pair(raw_xtal_id, xtal_trans_corr));
492 
493  xtalcounter++;
494  transparency.getline(buf, sizeof(buf), '\n');
495  } //loop transparency
496  transparency.close();
497  ss << "INFO: DONE transparency correction files " << xtalcounter << "\n";
498  edm::LogInfo("TopInfo") << ss.str();
499  ss.str("");
500  } // file
501  else { // Jean 2018
502  edm::LogInfo("TopInfo") << "INFO: READING transparency correction tag"
503  << "\n";
504  // std::cout << "new feature, read a tag" << std::endl;
505  const EcalLaserAPDPNRatios* lratio = &evtSetup.getData(ecalLaserAPDPNRatiosToken_);
506  // std::cout << " laser map size " << lratio->getLaserMap().size() << std::endl;
507 
509  // Barrel loop
510  for (int ib = 0; ib < 61200; ib++) {
511  EBDetId ebdetid = EBDetId::unhashIndex(ib);
512  itratio = lratio->getLaserMap().find(ebdetid.rawId());
513  // std::cout << ib << " " << ebdetid.rawId() << " Barrel APDPNRatios = " << (*itratio).p1 << " " << (*itratio).p2 << " " << (*itratio).p3 << std::endl;
514  Transparency_Correction_.insert(make_pair(ebdetid.rawId(), (*itratio).p2));
515  }
516  // Endcap loop
517  for (int ie = 0; ie < 14648; ie++) {
518  EEDetId eedetid = EEDetId::unhashIndex(ie);
519  itratio = lratio->getLaserMap().find(eedetid.rawId());
520  // std::cout << ie << " " << eedetid.rawId() << " Endcap APDPNRatios = " << (*itratio).p1 << " " << (*itratio).p2 << " " << (*itratio).p3 << std::endl;
521  Transparency_Correction_.insert(make_pair(eedetid.rawId(), (*itratio).p2));
522  }
523  ss << "INFO: DONE transparency correction tag\n";
524  edm::LogInfo("TopInfo") << ss.str();
525  ss.str("");
526  } // Jean 2018
527  } //if transparency
528 
529  // histo
530  TFile saving("EcalTPGParam.root", "recreate");
531  saving.cd();
532  TH2F* ICEB = new TH2F("ICEB", "IC: Barrel", 360, 1, 361, 172, -86, 86);
533  ICEB->GetYaxis()->SetTitle("eta index");
534  ICEB->GetXaxis()->SetTitle("phi index");
535  TH2F* tpgFactorEB = new TH2F("tpgFactorEB", "tpgFactor: Barrel", 360, 1, 361, 172, -86, 86);
536  tpgFactorEB->GetYaxis()->SetTitle("eta index");
537  tpgFactorEB->GetXaxis()->SetTitle("phi index");
538 
539  TH2F* ICEEPlus = new TH2F("ICEEPlus", "IC: Plus Endcap", 120, -9, 111, 120, -9, 111);
540  ICEEPlus->GetYaxis()->SetTitle("y index");
541  ICEEPlus->GetXaxis()->SetTitle("x index");
542  TH2F* tpgFactorEEPlus = new TH2F("tpgFactorEEPlus", "tpgFactor: Plus Endcap", 120, -9, 111, 120, -9, 111);
543  tpgFactorEEPlus->GetYaxis()->SetTitle("y index");
544  tpgFactorEEPlus->GetXaxis()->SetTitle("x index");
545  TH2F* ICEEMinus = new TH2F("ICEEMinus", "IC: Minus Endcap", 120, -9, 111, 120, -9, 111);
546  ICEEMinus->GetYaxis()->SetTitle("y index");
547  ICEEMinus->GetXaxis()->SetTitle("x index");
548  TH2F* tpgFactorEEMinus = new TH2F("tpgFactorEEMinus", "tpgFactor: Minus Endcap", 120, -9, 111, 120, -9, 111);
549  tpgFactorEEMinus->GetYaxis()->SetTitle("y index");
550  tpgFactorEEMinus->GetXaxis()->SetTitle("x index");
551 
552  TH2F* IC = new TH2F("IC", "IC", 720, -acos(-1.), acos(-1.), 600, -3., 3.);
553  IC->GetYaxis()->SetTitle("eta");
554  IC->GetXaxis()->SetTitle("phi");
555  TH2F* tpgFactor = new TH2F("tpgFactor", "tpgFactor", 720, -acos(-1.), acos(-1.), 600, -3., 3.);
556  tpgFactor->GetYaxis()->SetTitle("eta");
557  tpgFactor->GetXaxis()->SetTitle("phi");
558 
559  TH1F* hshapeEB = new TH1F("shapeEB", "shapeEB", 250, 0., 10.);
560  TH1F* hshapeEE = new TH1F("shapeEE", "shapeEE", 250, 0., 10.);
561 
562  TTree* ntuple = new TTree("tpgmap", "TPG geometry map");
563  const std::string branchFloat[26] = {
564  "fed", "tcc", "tower", "stripInTower", "xtalInStrip", "CCU", "VFE", "xtalInVFE", "xtalInCCU",
565  "ieta", "iphi", "ix", "iy", "iz", "hashedId", "ic", "cmsswId", "dbId",
566  "ietaTT", "iphiTT", "TCCch", "TCCslot", "SLBch", "SLBslot", "ietaGCT", "iphiGCT"};
567  ntupleInts_ = new Int_t[26];
568  for (int i = 0; i < 26; i++)
569  ntuple->Branch(branchFloat[i].c_str(), &ntupleInts_[i], (branchFloat[i] + string("/I")).c_str());
570  ntuple->Branch("det", ntupleDet_, "det/C");
571  ntuple->Branch("crate", ntupleCrate_, "crate/C");
572 
573  TNtuple* ntupleSpike = new TNtuple("spikeParam", "Spike parameters", "gainId:theta:G:g:ped:pedLin");
574 
576  // Initialization section //
578  list<uint32_t> towerListEB;
579  list<uint32_t> stripListEB;
580  list<uint32_t> towerListEE;
581  list<uint32_t> stripListEE;
582  list<uint32_t>::iterator itList;
583 
584  map<int, uint32_t> stripMapEB; // <EcalLogicId.hashed, strip elec id>
585  map<int, uint32_t> stripMapEE; // <EcalLogicId.hashed, strip elec id>
586  map<uint32_t, uint32_t> stripMapEBsintheta; // <strip elec id, sintheta>
587 
588  // Pedestals
589 
590  EcalPedestalsMap pedMap;
591 
592  if (m_write_ped == 1) {
593  ss << "Getting the pedestals from offline DB...\n";
594 
595  pedMap = evtSetup.getData(ecalPedestalsToken_).getMap();
596 
597  const auto& pedMapEB = pedMap.barrelItems();
598  const auto& pedMapEE = pedMap.endcapItems();
599  EcalPedestalsMapIterator pedIter;
600  int nPed = 0;
601  for (pedIter = pedMapEB.begin(); pedIter != pedMapEB.end() && nPed < 10; ++pedIter, ++nPed) {
602  const auto aped = (*pedIter);
603  ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
604  }
605  for (pedIter = pedMapEE.begin(); pedIter != pedMapEE.end() && nPed < 10; ++pedIter, ++nPed) {
606  const auto aped = (*pedIter);
607  ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
608  }
609  } else if (m_write_ped == 0) {
610  ss << "Getting the pedestals from previous configuration\n";
611 
612  EcalPedestals peds;
613 
614  FEConfigMainInfo fe_main_info;
615  fe_main_info.setConfigTag(tag_);
616  ss << "trying to read previous tag if it exists tag=" << tag_ << ".version" << version_ << "\n";
617  db_->fetchConfigSet(&fe_main_info);
618  if (fe_main_info.getPedId() > 0)
619  ped_conf_id_ = fe_main_info.getPedId();
620 
621  FEConfigPedInfo fe_ped_info;
622  fe_ped_info.setId(ped_conf_id_);
623  db_->fetchConfigSet(&fe_ped_info);
624  std::map<EcalLogicID, FEConfigPedDat> dataset_TpgPed;
625  db_->fetchDataSet(&dataset_TpgPed, &fe_ped_info);
626 
627  typedef std::map<EcalLogicID, FEConfigPedDat>::const_iterator CIfeped;
628  EcalLogicID ecid_xt;
629  FEConfigPedDat rd_ped;
630  int icells = 0;
631  for (CIfeped p = dataset_TpgPed.begin(); p != dataset_TpgPed.end(); p++) {
632  ecid_xt = p->first;
633  rd_ped = p->second;
634 
635  std::string ecid_name = ecid_xt.getName();
636 
637  // EB data
638  if (ecid_name == "EB_crystal_number") {
639  int sm_num = ecid_xt.getID1();
640  int xt_num = ecid_xt.getID2();
641 
642  EBDetId ebdetid(sm_num, xt_num, EBDetId::SMCRYSTALMODE);
644  item.mean_x1 = rd_ped.getPedMeanG1();
645  item.mean_x6 = rd_ped.getPedMeanG6();
646  item.mean_x12 = rd_ped.getPedMeanG12();
647  item.rms_x1 = 0.5;
648  item.rms_x6 = 1.;
649  item.rms_x12 = 1.2;
650 
651  if (icells < 10)
652  ss << " copy the EB data "
653  << " ped = " << item.mean_x12 << "\n";
654 
655  peds.insert(std::make_pair(ebdetid.rawId(), item));
656 
657  ++icells;
658  } else if (ecid_name == "EE_crystal_number") {
659  // EE data
660  int z = ecid_xt.getID1();
661  int x = ecid_xt.getID2();
662  int y = ecid_xt.getID3();
663  EEDetId eedetid(x, y, z, EEDetId::XYMODE);
665  item.mean_x1 = rd_ped.getPedMeanG1();
666  item.mean_x6 = rd_ped.getPedMeanG6();
667  item.mean_x12 = rd_ped.getPedMeanG12();
668  item.rms_x1 = 0.5;
669  item.rms_x6 = 1.;
670  item.rms_x12 = 1.2;
671 
672  peds.insert(std::make_pair(eedetid.rawId(), item));
673  ++icells;
674  }
675  }
676 
677  pedMap = peds.getMap();
678 
679  const auto& pedMapEB = pedMap.barrelItems();
680  const auto& pedMapEE = pedMap.endcapItems();
681  EcalPedestalsMapIterator pedIter;
682  int nPed = 0;
683  for (pedIter = pedMapEB.begin(); pedIter != pedMapEB.end() && nPed < 10; ++pedIter, ++nPed) {
684  const auto aped = (*pedIter);
685  ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
686  }
687  for (pedIter = pedMapEE.begin(); pedIter != pedMapEE.end() && nPed < 10; ++pedIter, ++nPed) {
688  const auto aped = (*pedIter);
689  ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
690  }
691 
692  } else if (m_write_ped > 1) {
693  ss << "Getting the pedestals from configuration number" << m_write_ped << "\n";
694 
695  EcalPedestals peds;
696 
697  FEConfigPedInfo fe_ped_info;
698  fe_ped_info.setId(m_write_ped);
699  db_->fetchConfigSet(&fe_ped_info);
700  std::map<EcalLogicID, FEConfigPedDat> dataset_TpgPed;
701  db_->fetchDataSet(&dataset_TpgPed, &fe_ped_info);
702 
703  typedef std::map<EcalLogicID, FEConfigPedDat>::const_iterator CIfeped;
704  EcalLogicID ecid_xt;
705  FEConfigPedDat rd_ped;
706  int icells = 0;
707  for (CIfeped p = dataset_TpgPed.begin(); p != dataset_TpgPed.end(); p++) {
708  ecid_xt = p->first;
709  rd_ped = p->second;
710 
711  std::string ecid_name = ecid_xt.getName();
712 
713  // EB data
714  if (ecid_name == "EB_crystal_number") {
715  if (icells < 10)
716  edm::LogInfo("TopInfo") << " copy the EB data "
717  << " icells = " << icells << "\n";
718  int sm_num = ecid_xt.getID1();
719  int xt_num = ecid_xt.getID2();
720 
721  EBDetId ebdetid(sm_num, xt_num, EBDetId::SMCRYSTALMODE);
723  item.mean_x1 = (unsigned int)rd_ped.getPedMeanG1();
724  item.mean_x6 = (unsigned int)rd_ped.getPedMeanG6();
725  item.mean_x12 = (unsigned int)rd_ped.getPedMeanG12();
726  item.rms_x1 = 0.5;
727  item.rms_x6 = 1.;
728  item.rms_x12 = 1.2;
729 
730  peds.insert(std::make_pair(ebdetid.rawId(), item));
731  ++icells;
732  } else if (ecid_name == "EE_crystal_number") {
733  // EE data
734  int z = ecid_xt.getID1();
735  int x = ecid_xt.getID2();
736  int y = ecid_xt.getID3();
737  EEDetId eedetid(x, y, z, EEDetId::XYMODE);
739  item.mean_x1 = (unsigned int)rd_ped.getPedMeanG1();
740  item.mean_x6 = (unsigned int)rd_ped.getPedMeanG6();
741  item.mean_x12 = (unsigned int)rd_ped.getPedMeanG12();
742  item.rms_x1 = 0.5;
743  item.rms_x6 = 1.;
744  item.rms_x12 = 1.2;
745 
746  peds.insert(std::make_pair(eedetid.rawId(), item));
747  ++icells;
748  }
749  }
750 
751  pedMap = peds.getMap();
752 
753  const auto& pedMapEB = pedMap.barrelItems();
754  const auto& pedMapEE = pedMap.endcapItems();
755  EcalPedestalsMapIterator pedIter;
756  int nPed = 0;
757  for (pedIter = pedMapEB.begin(); pedIter != pedMapEB.end() && nPed < 10; ++pedIter, ++nPed) {
758  const auto aped = (*pedIter);
759  ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
760  }
761  for (pedIter = pedMapEE.begin(); pedIter != pedMapEE.end() && nPed < 10; ++pedIter, ++nPed) {
762  const auto aped = (*pedIter);
763  ss << aped.mean_x12 << ", " << aped.mean_x6 << ", " << aped.mean_x1 << "\n";
764  }
765  }
766 
767  edm::LogInfo("TopInfo") << ss.str();
768  ss.str("");
769 
770  // Intercalib constants
771  ss << "Getting intercalib from offline DB...\n";
772  const EcalIntercalibConstants* intercalib = &evtSetup.getData(ecalIntercalibConstantsToken_);
773  const EcalIntercalibConstantMap& calibMap = intercalib->getMap();
774  const auto& calibMapEB = calibMap.barrelItems();
775  const auto& calibMapEE = calibMap.endcapItems();
777  int nCal = 0;
778  for (calIter = calibMapEB.begin(); calIter != calibMapEB.end() && nCal < 10; ++calIter, ++nCal) {
779  ss << (*calIter) << "\n";
780  }
781  for (calIter = calibMapEE.begin(); calIter != calibMapEE.end() && nCal < 10; ++calIter, ++nCal) {
782  ss << (*calIter) << "\n";
783  }
784  edm::LogInfo("TopInfo") << ss.str();
785  ss.str("");
786  float calibvec[1700];
787  if (H2_) {
788  edm::LogInfo("TopInfo") << "H2: overwriting IC coef with file"
789  << "\n";
790  std::ifstream calibfile("calib_sm36.txt", std::ios::out);
791  int idata, icry;
792  float fdata, fcali;
793  std::string strdata;
794  if (calibfile.is_open()) {
795  calibfile >> strdata >> strdata >> strdata >> strdata >> strdata;
796  while (!calibfile.eof()) {
797  calibfile >> idata >> icry >> fcali >> fdata >> fdata;
798  calibvec[icry - 1] = fcali;
799  if (calibfile.eof()) {
800  break; // avoid last line duplication
801  }
802  }
803  }
804  }
805 
806  // Gain Ratios
807  ss << "Getting the gain ratios from offline DB...\n";
808  const EcalGainRatioMap& gainMap = evtSetup.getData(ecalGainRatiosToken_).getMap();
809  const auto& gainMapEB = gainMap.barrelItems();
810  const auto& gainMapEE = gainMap.endcapItems();
812  int nGain = 0;
813  for (gainIter = gainMapEB.begin(); gainIter != gainMapEB.end() && nGain < 10; ++gainIter, ++nGain) {
814  const auto& aGain = (*gainIter);
815  ss << aGain.gain12Over6() << ", " << aGain.gain6Over1() * aGain.gain12Over6() << "\n";
816  }
817  for (gainIter = gainMapEE.begin(); gainIter != gainMapEE.end() && nGain < 10; ++gainIter, ++nGain) {
818  const auto& aGain = (*gainIter);
819  ss << aGain.gain12Over6() << ", " << aGain.gain6Over1() * aGain.gain12Over6() << "\n";
820  }
821  edm::LogInfo("TopInfo") << ss.str();
822  ss.str("");
823 
824  // ADCtoGeV
825  ss << "Getting the ADC to GeV from offline DB...\n";
826  const EcalADCToGeVConstant* ADCToGeV = &evtSetup.getData(ecalADCToGeVConstantToken_);
827  xtal_LSB_EB_ = ADCToGeV->getEBValue();
828  xtal_LSB_EE_ = ADCToGeV->getEEValue();
829  ss << "xtal_LSB_EB_ = " << xtal_LSB_EB_ << "\n";
830  ss << "xtal_LSB_EE_ = " << xtal_LSB_EE_ << "\n";
831 
832  vector<EcalLogicID> my_EcalLogicId;
833  vector<EcalLogicID> my_TTEcalLogicId;
834  vector<EcalLogicID> my_StripEcalLogicId;
835  EcalLogicID my_EcalLogicId_EB;
836  // Endcap identifiers
837  EcalLogicID my_EcalLogicId_EE;
838  vector<EcalLogicID> my_TTEcalLogicId_EE;
839  vector<EcalLogicID> my_RTEcalLogicId_EE;
840  vector<EcalLogicID> my_StripEcalLogicId1_EE;
841  vector<EcalLogicID> my_StripEcalLogicId2_EE;
842  vector<EcalLogicID> my_CrystalEcalLogicId_EE;
843  vector<EcalLogicID> my_TTEcalLogicId_EB_by_TCC;
844  vector<EcalLogicID> my_StripEcalLogicId_EE_strips_by_TCC;
845 
848  my_EcalLogicId = db_->getEcalLogicIDSetOrdered(
849  "EB_crystal_number", 1, 36, 1, 1700, EcalLogicID::NULLID, EcalLogicID::NULLID, "EB_crystal_number", 12);
850  my_TTEcalLogicId = db_->getEcalLogicIDSetOrdered(
851  "EB_trigger_tower", 1, 36, 1, 68, EcalLogicID::NULLID, EcalLogicID::NULLID, "EB_trigger_tower", 12);
852  my_StripEcalLogicId = db_->getEcalLogicIDSetOrdered(
853  "EB_VFE", 1, 36, 1, 68, 1, 5, "EB_VFE", 123); //last digi means ordered 1st by SM,then TT, then strip
854  ss << "got the 3 ecal barrel logic id set\n";
855 
856  // EE crystals identifiers
857  my_CrystalEcalLogicId_EE =
858  db_->getEcalLogicIDSetOrdered("EE_crystal_number", -1, 1, 0, 200, 0, 200, "EE_crystal_number", 123);
859 
860  // EE Strip identifiers
861  // DCC=601-609 TT = ~40 EEstrip = 5
862  my_StripEcalLogicId1_EE =
863  db_->getEcalLogicIDSetOrdered("ECAL_readout_strip", 601, 609, 1, 100, 0, 5, "ECAL_readout_strip", 123);
864  // EE Strip identifiers
865  // DCC=646-654 TT = ~40 EEstrip = 5
866  my_StripEcalLogicId2_EE =
867  db_->getEcalLogicIDSetOrdered("ECAL_readout_strip", 646, 654, 1, 100, 0, 5, "ECAL_readout_strip", 123);
868  // ----> modif here 31/1/2011
869  // EE Strip identifiers by TCC tower strip
870  // TCC=1-108 TT = ~40 EEstrip = 1-5
871  my_StripEcalLogicId_EE_strips_by_TCC =
872  db_->getEcalLogicIDSetOrdered("EE_trigger_strip", 1, 108, 1, 100, 1, 5, "EE_trigger_strip", 123);
873 
874  // ----> modif here 31/1/2011
875  // ECAL Barrel trigger towers by TCC/tower identifiers
876  // TTC=38-72 TT = 1-68
877  my_TTEcalLogicId_EB_by_TCC = db_->getEcalLogicIDSetOrdered(
878  "ECAL_trigger_tower", 1, 108, 1, 68, EcalLogicID::NULLID, EcalLogicID::NULLID, "ECAL_trigger_tower", 12);
879 
880  // EE TT identifiers
881  // TTC=72 TT = 1440
882  my_TTEcalLogicId_EE = db_->getEcalLogicIDSetOrdered(
883  "EE_trigger_tower", 1, 108, 1, 40, EcalLogicID::NULLID, EcalLogicID::NULLID, "EE_trigger_tower", 12);
884 
885  // EE TT identifiers
886  // TTC=72 TT = 1440
887  my_RTEcalLogicId_EE = db_->getEcalLogicIDSetOrdered(
888  "EE_readout_tower", 1, 1000, 1, 100, EcalLogicID::NULLID, EcalLogicID::NULLID, "EE_readout_tower", 12);
889  edm::LogInfo("TopInfo") << ss.str();
890  ss.str("");
891 
892  if (writeToDB_) {
893  ss << "Getting the latest ids for this tag (latest version) "
894  << "\n";
895 
896  FEConfigMainInfo fe_main_info;
897  fe_main_info.setConfigTag(tag_);
898 
899  ss << "trying to read previous tag if it exists tag=" << tag_ << ".version" << version_ << "\n";
900 
901  db_->fetchConfigSet(&fe_main_info);
902  if (fe_main_info.getPedId() > 0 && ped_conf_id_ == 0)
903  ped_conf_id_ = fe_main_info.getPedId();
904  lin_conf_id_ = fe_main_info.getLinId();
905  lut_conf_id_ = fe_main_info.getLUTId();
906  wei_conf_id_ = fe_main_info.getWeiId();
907  wei2_conf_id_ = fe_main_info.getWei2Id();
908  fgr_conf_id_ = fe_main_info.getFgrId();
909  sli_conf_id_ = fe_main_info.getSliId();
910  spi_conf_id_ = fe_main_info.getSpiId(); //modif-alex 21/01/11
911  del_conf_id_ = fe_main_info.getTimId(); //modif-alex 21/01/11
912  coke_conf_id_ = fe_main_info.getCokeId();
913  if (fe_main_info.getBxtId() > 0 && bxt_conf_id_ == 0)
914  bxt_conf_id_ = fe_main_info.getBxtId();
915  if (fe_main_info.getBttId() > 0 && btt_conf_id_ == 0)
916  btt_conf_id_ = fe_main_info.getBttId();
917  if (fe_main_info.getBstId() > 0 && bst_conf_id_ == 0)
918  bst_conf_id_ = fe_main_info.getBstId();
919  // those that are not written specifically in this program are propagated
920  // from the previous record with the same tag and the highest version
921  }
922 
924  // Compute linearization coeff section //
926 
927  map<EcalLogicID, FEConfigPedDat> pedset;
928  map<EcalLogicID, FEConfigLinDat> linset;
929  map<EcalLogicID, FEConfigLinParamDat> linparamset;
930  map<EcalLogicID, FEConfigLUTParamDat> lutparamset;
931  map<EcalLogicID, FEConfigFgrParamDat> fgrparamset;
932 
933  map<int, linStruc> linEtaSlice;
934  map<vector<int>, linStruc> linMap;
935 
936  // count number of strip per tower
937  int NbOfStripPerTCC[108][68];
938  for (int i = 0; i < 108; i++)
939  for (int j = 0; j < 68; j++)
940  NbOfStripPerTCC[i][j] = 0;
941  const std::vector<DetId>& ebCells = theBarrelGeometry_->getValidDetIds(DetId::Ecal, EcalBarrel);
942  const std::vector<DetId>& eeCells = theEndcapGeometry_->getValidDetIds(DetId::Ecal, EcalEndcap);
943  for (vector<DetId>::const_iterator it = ebCells.begin(); it != ebCells.end(); ++it) {
944  EBDetId id(*it);
945  const EcalTrigTowerDetId towid = id.tower();
947  int tccNb = theMapping_->TCCid(towid);
948  int towerInTCC = theMapping_->iTT(towid);
949  int stripInTower = elId.pseudoStripId();
950  if (stripInTower > NbOfStripPerTCC[tccNb - 1][towerInTCC - 1])
951  NbOfStripPerTCC[tccNb - 1][towerInTCC - 1] = stripInTower;
952  }
953  for (vector<DetId>::const_iterator it = eeCells.begin(); it != eeCells.end(); ++it) {
954  EEDetId id(*it);
955  const EcalTrigTowerDetId towid = (*eTTmap_).towerOf(id);
957  int tccNb = theMapping_->TCCid(towid);
958  int towerInTCC = theMapping_->iTT(towid);
959  int stripInTower = elId.pseudoStripId();
960  if (stripInTower > NbOfStripPerTCC[tccNb - 1][towerInTCC - 1])
961  NbOfStripPerTCC[tccNb - 1][towerInTCC - 1] = stripInTower;
962  }
963 
964  // loop on EB xtals
965  if (writeToFiles_)
966  (*out_file_) << "COMMENT ====== barrel crystals ====== " << std::endl;
967 
968  // special case of eta slices
969  for (vector<DetId>::const_iterator it = ebCells.begin(); it != ebCells.end(); ++it) {
970  EBDetId id(*it);
971  double theta = theBarrelGeometry_->getGeometry(id)->getPosition().theta();
973  theta = acos(0.);
974  const EcalTrigTowerDetId towid = id.tower();
976  int dccNb = theMapping_->DCCid(towid);
977  int tccNb = theMapping_->TCCid(towid);
978  int towerInTCC = theMapping_->iTT(towid); // from 1 to 68 (EB)
979  int stripInTower = elId.pseudoStripId(); // from 1 to 5
980  int xtalInStrip = elId.channelId(); // from 1 to 5
982  int CCUid = Id.towerId();
983  int VFEid = Id.stripId();
984  int xtalInVFE = Id.xtalId();
985  int xtalWithinCCUid = 5 * (VFEid - 1) + xtalInVFE - 1; // Evgueni expects [0,24]
986 
987  (*geomFile_) << "dccNb = " << dccNb << " tccNb = " << tccNb << " towerInTCC = " << towerInTCC
988  << " stripInTower = " << stripInTower << " xtalInStrip = " << xtalInStrip << " CCUid = " << CCUid
989  << " VFEid = " << VFEid << " xtalInVFE = " << xtalInVFE << " xtalWithinCCUid = " << xtalWithinCCUid
990  << " ieta = " << id.ieta() << " iphi = " << id.iphi() << " xtalhashedId = " << id.hashedIndex()
991  << " xtalNb = " << id.ic() << " ietaTT = " << towid.ieta() << " iphiTT = " << towid.iphi()
992  << std::endl;
993 
994  int TCCch = towerInTCC;
995  int SLBslot = int((towerInTCC - 1) / 8.) + 1;
996  int SLBch = (towerInTCC - 1) % 8 + 1;
997  int cmsswId = id.rawId();
998  int ixtal = (id.ism() - 1) * 1700 + (id.ic() - 1);
999  EcalLogicID logicId = my_EcalLogicId[ixtal];
1000  int dbId = logicId.getLogicID();
1001  int val[] = {dccNb + 600,
1002  tccNb,
1003  towerInTCC,
1004  stripInTower,
1005  xtalInStrip,
1006  CCUid,
1007  VFEid,
1008  xtalInVFE,
1009  xtalWithinCCUid,
1010  id.ieta(),
1011  id.iphi(),
1012  -999,
1013  -999,
1014  towid.ieta() / abs(towid.ieta()),
1015  id.hashedIndex(),
1016  id.ic(),
1017  cmsswId,
1018  dbId,
1019  towid.ieta(),
1020  towid.iphi(),
1021  TCCch,
1022  getCrate(tccNb).second,
1023  SLBch,
1024  SLBslot,
1025  getGCTRegionEta(towid.ieta()),
1026  getGCTRegionPhi(towid.iphi())};
1027  for (int i = 0; i < 26; i++)
1028  ntupleInts_[i] = val[i];
1029 
1030  strcpy(ntupleDet_, getDet(tccNb).c_str());
1031  strcpy(ntupleCrate_, getCrate(tccNb).first.c_str());
1032  ntuple->Fill();
1033 
1034  if (tccNb == 37 && stripInTower == 3 && xtalInStrip == 3 && (towerInTCC - 1) % 4 == 0) {
1035  int etaSlice = towid.ietaAbs();
1036  coeffStruc coeff;
1037  //getCoeff(coeff, calibMap, id.rawId()) ;
1038  //modif-alex-27-july-2015
1039  string str;
1040  getCoeff(coeff, calibMap, laserAlphaMap, id.rawId(), str);
1041  ss << str;
1042  getCoeff(coeff, gainMap, id.rawId());
1043  getCoeff(coeff, pedMap, id.rawId());
1044  linStruc lin;
1045  for (int i = 0; i < 3; i++) {
1046  lin.pedestal_[i] = coeff.pedestals_[i];
1047  lin.mult_[i] = 0;
1048  lin.shift_[i] = 0;
1049  int mult = 0;
1050  int shift = 0;
1051  bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EB", mult, shift);
1052  if (!ok) {
1053  //If the mult is impossible to compute
1054  if (mult > 255) {
1055  edm::LogError("TopInfo") << "ByEtaSlice: unable to compute the parameters for SM=" << id.ism()
1056  << " xt=" << id.ic() << " " << dec << id.rawId() << " gainId=" << i
1057  << ", mult too large! forced to mult=255, shift=0\n";
1058  lin.mult_[i] = 255;
1059  lin.shift_[i] = 0;
1060  } else if (mult < 128) {
1061  edm::LogError("TopInfo") << "ByEtaSlice: unable to compute the parameters for SM=" << id.ism()
1062  << " xt=" << id.ic() << " " << dec << id.rawId() << " gainId=" << i
1063  << ", mult too small! forced to mult=128, shift=15\n";
1064  ;
1065  lin.mult_[i] = 128;
1066  lin.shift_[i] = 15;
1067  }
1068  } else {
1069  lin.mult_[i] = mult;
1070  lin.shift_[i] = shift;
1071  }
1072  }
1073 
1074  bool ok(true);
1075  if (forcedPedestalValue_ == -2)
1076  ok = realignBaseline(lin, 0, id.rawId());
1077  if (!ok)
1078  ss << "SM=" << id.ism() << " xt=" << id.ic() << " " << dec << id.rawId() << "\n";
1079  linEtaSlice[etaSlice] = lin;
1080  }
1081  }
1082 
1083  // general case
1084  for (vector<DetId>::const_iterator it = ebCells.begin(); it != ebCells.end(); ++it) {
1085  EBDetId id(*it);
1086  double theta = theBarrelGeometry_->getGeometry(id)->getPosition().theta();
1087  if (!useTransverseEnergy_)
1088  theta = acos(0.);
1089  const EcalTrigTowerDetId towid = id.tower();
1090  towerListEB.push_back(towid.rawId());
1092  stripListEB.push_back(elId.rawId() & 0xfffffff8);
1093  int dccNb = theMapping_->DCCid(towid);
1094  //int tccNb = theMapping_->TCCid(towid) ;
1095  int towerInTCC = theMapping_->iTT(towid); // from 1 to 68 (EB)
1096  //int stripInTower = elId.pseudoStripId() ; // from 1 to 5
1097  //int xtalInStrip = elId.channelId() ; // from 1 to 5
1099  int CCUid = Id.towerId();
1100  int VFEid = Id.stripId();
1101  int xtalInVFE = Id.xtalId();
1102  int xtalWithinCCUid = 5 * (VFEid - 1) + xtalInVFE - 1; // Evgueni expects [0,24]
1103  int etaSlice = towid.ietaAbs();
1104 
1105  // hashed index of strip EcalLogicID:
1106  int hashedStripLogicID = 68 * 5 * (id.ism() - 1) + 5 * (towerInTCC - 1) + (VFEid - 1);
1107  stripMapEB[hashedStripLogicID] = elId.rawId() & 0xfffffff8;
1108  stripMapEBsintheta[elId.rawId() & 0xfffffff8] = SFGVB_Threshold_ + abs(int(sin(theta) * pedestal_offset_));
1109 
1110  //modif-debug
1111  /*
1112  FEConfigFgrEEStripDat stripdebug;
1113  EcalLogicID thestrip_debug = my_StripEcalLogicId[hashedStripLogicID] ;
1114  if(towid.ieta() == 6 && towid.iphi() == 7){
1115  std::cout << "xtal info=" << id << " VFE=" << VFEid << std::endl;
1116  std::cout << "TOWER DEBUG ieta=" << towid.ieta() << " iphi=" << towid.iphi() << " SFGVB=" << SFGVB_Threshold_ + abs(int(sin(theta)*pedestal_offset_))
1117  << " dbId=" << (elId.rawId() & 0xfffffff8) << " " << hashedStripLogicID << " " << thestrip_debug.getLogicID() << std::endl; //modif-debug
1118  }//EB+3 TT24
1119  */
1120  //std::cout<<std::dec<<SFGVB_Threshold_ + abs(int(sin(theta)*pedestal_offset_))<<" "<<SFGVB_Threshold_<<" "<<abs(int(sin(theta)*pedestal_offset_))<<std::endl ;
1121 
1122  FEConfigPedDat pedDB;
1123  FEConfigLinDat linDB;
1124  if (writeToFiles_)
1125  (*out_file_) << "CRYSTAL " << dec << id.rawId() << std::endl;
1126  // if (writeToDB_) logicId = db_->getEcalLogicID ("EB_crystal_number", id.ism(), id.ic()) ;
1127 
1128  coeffStruc coeff;
1129  //getCoeff(coeff, calibMap, id.rawId()) ;
1130  //modif-alex-27-july-2015
1131  std::string str;
1132  getCoeff(coeff, calibMap, laserAlphaMap, id.rawId(), str);
1133  ss << str;
1134 
1135  if (H2_)
1136  coeff.calibCoeff_ = calibvec[id.ic() - 1];
1137  getCoeff(coeff, gainMap, id.rawId());
1138  getCoeff(coeff, pedMap, id.rawId());
1139  ICEB->Fill(id.iphi(), id.ieta(), coeff.calibCoeff_);
1140  IC->Fill(theBarrelGeometry_->getGeometry(id)->getPosition().phi(),
1141  theBarrelGeometry_->getGeometry(id)->getPosition().eta(),
1142  coeff.calibCoeff_);
1143 
1144  vector<int> xtalCCU;
1145  xtalCCU.push_back(dccNb + 600);
1146  xtalCCU.push_back(CCUid);
1147  xtalCCU.push_back(xtalWithinCCUid);
1148  xtalCCU.push_back(id.rawId());
1149 
1150  // compute and fill linearization parameters
1151  // case of eta slice
1152  if (forceEtaSlice_) {
1153  map<int, linStruc>::const_iterator itLin = linEtaSlice.find(etaSlice);
1154  if (itLin != linEtaSlice.end()) {
1155  linMap[xtalCCU] = itLin->second;
1156  if (writeToFiles_) {
1157  for (int i = 0; i < 3; i++)
1158  (*out_file_) << hex << " 0x" << itLin->second.pedestal_[i] << " 0x" << itLin->second.mult_[i] << " 0x"
1159  << itLin->second.shift_[i] << std::endl;
1160  }
1161  if (writeToDB_) {
1162  for (int i = 0; i < 3; i++) {
1163  if (i == 0) {
1164  pedDB.setPedMeanG12(itLin->second.pedestal_[i]);
1165  linDB.setMultX12(itLin->second.mult_[i]);
1166  linDB.setShift12(itLin->second.shift_[i]);
1167  } else if (i == 1) {
1168  pedDB.setPedMeanG6(itLin->second.pedestal_[i]);
1169  linDB.setMultX6(itLin->second.mult_[i]);
1170  linDB.setShift6(itLin->second.shift_[i]);
1171  } else if (i == 2) {
1172  pedDB.setPedMeanG1(itLin->second.pedestal_[i]);
1173  linDB.setMultX1(itLin->second.mult_[i]);
1174  linDB.setShift1(itLin->second.shift_[i]);
1175  }
1176  }
1177  }
1178  float factor = float(itLin->second.mult_[0]) * pow(2., -itLin->second.shift_[0]) / xtal_LSB_EB_;
1179  tpgFactorEB->Fill(id.iphi(), id.ieta(), factor);
1180  tpgFactor->Fill(theBarrelGeometry_->getGeometry(id)->getPosition().phi(),
1181  theBarrelGeometry_->getGeometry(id)->getPosition().eta(),
1182  factor);
1183  } else
1184  ss << "current EtaSlice = " << etaSlice << " not found in the EtaSlice map"
1185  << "\n";
1186  } else {
1187  // general case
1188  linStruc lin;
1189  int forceBase12 = 0;
1190  double invSinTheta = 1. / sin(theta);
1191  for (int i = 0; i < 3; i++) {
1192  lin.pedestal_[i] = coeff.pedestals_[i];
1193  lin.mult_[i] = 0;
1194  lin.shift_[i] = 0;
1195  int mult = 0;
1196  int shift = 0;
1197  bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EB", mult, shift);
1198  if (!ok) {
1199  //If the mult is impossible to compute
1200  if (mult > 255) {
1201  edm::LogError("TopInfo") << "unable to compute the parameters for " << dec << id.rawId()
1202  << ", EB, gainId=" << i << ", mult too large! forced to mult=255, shift=0\n";
1203  lin.mult_[i] = 255;
1204  lin.shift_[i] = 0;
1205  } else if (mult < 128) {
1206  edm::LogError("TopInfo") << "unable to compute the parameters for " << dec << id.rawId()
1207  << ", EB, gainId=" << i << ", mult too small! forced to mult=128, shift=15\n";
1208  lin.mult_[i] = 128;
1209  lin.shift_[i] = 15;
1210  }
1211  } else {
1212  lin.mult_[i] = mult;
1213  lin.shift_[i] = shift;
1214  }
1215  // Force baseline for gain 12 also when mult not ok and the value is set to default
1216  if (forcedPedestalValue_ == -3 && i == 0) {
1217  double G = mult * pow(2.0, -(shift + 2));
1218  double g = G * invSinTheta;
1219  double base = double(coeff.pedestals_[i]) - pedestal_offset_ / g;
1220  if (base < 0.)
1221  base = 0;
1222  forceBase12 = int(base);
1223  }
1224  }
1225 
1226  bool ok(true);
1227  if (forcedPedestalValue_ == -2)
1228  ok = realignBaseline(lin, 0, id.rawId());
1229  else if (forcedPedestalValue_ == -3)
1230  ok = realignBaseline(lin, forceBase12, id.rawId());
1231  if (!ok)
1232  ss << "SM=" << id.ism() << " xt=" << id.ic() << " " << dec << id.rawId() << "\n";
1233 
1234  for (int i = 0; i < 3; i++) {
1235  if (writeToFiles_)
1236  (*out_file_) << hex << " 0x" << lin.pedestal_[i] << " 0x" << lin.mult_[i] << " 0x" << lin.shift_[i]
1237  << std::endl;
1238  if (writeToDB_) {
1239  if (i == 0) {
1240  pedDB.setPedMeanG12(lin.pedestal_[i]);
1241  linDB.setMultX12(lin.mult_[i]);
1242  linDB.setShift12(lin.shift_[i]);
1243  } else if (i == 1) {
1244  pedDB.setPedMeanG6(lin.pedestal_[i]);
1245  linDB.setMultX6(lin.mult_[i]);
1246  linDB.setShift6(lin.shift_[i]);
1247  } else if (i == 2) {
1248  pedDB.setPedMeanG1(lin.pedestal_[i]);
1249  linDB.setMultX1(lin.mult_[i]);
1250  linDB.setShift1(lin.shift_[i]);
1251  }
1252  }
1253  if (i == 0) {
1254  float factor = float(lin.mult_[i]) * pow(2., -lin.shift_[i]) / xtal_LSB_EB_;
1255  tpgFactorEB->Fill(id.iphi(), id.ieta(), factor);
1256  tpgFactor->Fill(theBarrelGeometry_->getGeometry(id)->getPosition().phi(),
1257  theBarrelGeometry_->getGeometry(id)->getPosition().eta(),
1258  factor);
1259  }
1260  double G = lin.mult_[i] * pow(2.0, -(lin.shift_[i] + 2));
1261  double g = G * invSinTheta;
1262  float val[] = {float(i),
1263  float(theta),
1264  float(G),
1265  float(g),
1266  float(coeff.pedestals_[i]),
1267  float(lin.pedestal_[i])}; // first arg = gainId (0 means gain12)
1268  ntupleSpike->Fill(val);
1269  }
1270  linMap[xtalCCU] = lin;
1271  }
1272  if (writeToDB_) {
1273  // 1700 crystals/SM in the ECAL barrel
1274  int ixtal = (id.ism() - 1) * 1700 + (id.ic() - 1);
1275  EcalLogicID logicId = my_EcalLogicId[ixtal];
1276  pedset[logicId] = pedDB;
1277  linset[logicId] = linDB;
1278  }
1279  } //ebCells
1280 
1281  if (writeToDB_) {
1282  // EcalLogicID of the whole barrel is: my_EcalLogicId_EB
1283  FEConfigLinParamDat linparam;
1284  linparam.setETSat(Et_sat_EB_);
1285  linparamset[my_EcalLogicId_EB] = linparam;
1286 
1287  FEConfigFgrParamDat fgrparam;
1290  fgrparam.setFGlowratio(FG_lowRatio_EB_);
1291  fgrparam.setFGhighratio(FG_highRatio_EB_);
1292  fgrparamset[my_EcalLogicId_EB] = fgrparam;
1293 
1294  FEConfigLUTParamDat lutparam;
1295  lutparam.setETSat(Et_sat_EB_);
1298  lutparamset[my_EcalLogicId_EB] = lutparam;
1299  }
1300 
1301  // loop on EE xtals
1302  if (writeToFiles_)
1303  (*out_file_) << "COMMENT ====== endcap crystals ====== " << std::endl;
1304 
1305  // special case of eta slices
1306  for (vector<DetId>::const_iterator it = eeCells.begin(); it != eeCells.end(); ++it) {
1307  EEDetId id(*it);
1308  double theta = theEndcapGeometry_->getGeometry(id)->getPosition().theta();
1309  if (!useTransverseEnergy_)
1310  theta = acos(0.);
1311  const EcalTrigTowerDetId towid = (*eTTmap_).towerOf(id);
1314  int dccNb = Id.dccId();
1315  int tccNb = theMapping_->TCCid(towid);
1316  int towerInTCC = theMapping_->iTT(towid);
1317  int stripInTower = elId.pseudoStripId();
1318  int xtalInStrip = elId.channelId();
1319  int CCUid = Id.towerId();
1320  int VFEid = Id.stripId();
1321  int xtalInVFE = Id.xtalId();
1322  int xtalWithinCCUid = 5 * (VFEid - 1) + xtalInVFE - 1; // Evgueni expects [0,24]
1323 
1324  // Creating the stripMap for EE
1325  bool foundStripLogic = false;
1326  for (EcalLogicID& stripLogicId : my_StripEcalLogicId1_EE) {
1327  if (stripLogicId.getID1() == 600 + dccNb && stripLogicId.getID2() == CCUid && stripLogicId.getID3() == VFEid) {
1328  stripMapEE[stripLogicId.getLogicID()] = elId.rawId() & 0xfffffff8;
1329  foundStripLogic = true;
1330  break;
1331  }
1332  }
1333  if (!foundStripLogic) {
1334  for (EcalLogicID& stripLogicId : my_StripEcalLogicId2_EE) {
1335  if (stripLogicId.getID1() == 600 + dccNb && stripLogicId.getID2() == CCUid && stripLogicId.getID3() == VFEid) {
1336  stripMapEE[stripLogicId.getLogicID()] = elId.rawId() & 0xfffffff8;
1337  foundStripLogic = true;
1338  break;
1339  }
1340  }
1341  }
1342  if (!foundStripLogic) {
1343  edm::LogWarning("TopInfo") << "Strip ID not found for DCC: " << 600 + dccNb << " CCU: " << CCUid
1344  << " VFEid: " << VFEid;
1345  }
1346 
1347  (*geomFile_) << "dccNb = " << dccNb << " tccNb = " << tccNb << " towerInTCC = " << towerInTCC
1348  << " stripInTower = " << stripInTower << " xtalInStrip = " << xtalInStrip << " CCUid = " << CCUid
1349  << " VFEid = " << VFEid << " xtalInVFE = " << xtalInVFE << " xtalWithinCCUid = " << xtalWithinCCUid
1350  << " ix = " << id.ix() << " iy = " << id.iy() << " xtalhashedId = " << id.hashedIndex()
1351  << " xtalNb = " << id.isc() << " ietaTT = " << towid.ieta() << " iphiTT = " << towid.iphi()
1352  << std::endl;
1353 
1354  int TCCch = stripInTower;
1355  int SLBslot, SLBch;
1356  if (towerInTCC < 5) {
1357  SLBslot = 1;
1358  SLBch = 4 + towerInTCC;
1359  } else {
1360  SLBslot = int((towerInTCC - 5) / 8.) + 2;
1361  SLBch = (towerInTCC - 5) % 8 + 1;
1362  }
1363  for (int j = 0; j < towerInTCC - 1; j++)
1364  TCCch += NbOfStripPerTCC[tccNb - 1][j];
1365 
1366  int cmsswId = id.rawId();
1367  EcalLogicID logicId;
1368  int iz = id.positiveZ();
1369  if (iz == 0)
1370  iz = -1;
1371  for (int k = 0; k < (int)my_CrystalEcalLogicId_EE.size(); k++) {
1372  int z = my_CrystalEcalLogicId_EE[k].getID1();
1373  int x = my_CrystalEcalLogicId_EE[k].getID2();
1374  int y = my_CrystalEcalLogicId_EE[k].getID3();
1375  if (id.ix() == x && id.iy() == y && iz == z)
1376  logicId = my_CrystalEcalLogicId_EE[k];
1377  }
1378  int dbId = logicId.getLogicID();
1379 
1380  int val[] = {dccNb + 600,
1381  tccNb,
1382  towerInTCC,
1383  stripInTower,
1384  xtalInStrip,
1385  CCUid,
1386  VFEid,
1387  xtalInVFE,
1388  xtalWithinCCUid,
1389  -999,
1390  -999,
1391  id.ix(),
1392  id.iy(),
1393  towid.ieta() / abs(towid.ieta()),
1394  id.hashedIndex(),
1395  id.ic(),
1396  cmsswId,
1397  dbId,
1398  towid.ieta(),
1399  towid.iphi(),
1400  TCCch,
1401  getCrate(tccNb).second,
1402  SLBch,
1403  SLBslot,
1404  getGCTRegionEta(towid.ieta()),
1405  getGCTRegionPhi(towid.iphi())};
1406  for (int i = 0; i < 26; i++)
1407  ntupleInts_[i] = val[i];
1408  strcpy(ntupleDet_, getDet(tccNb).c_str());
1409  strcpy(ntupleCrate_, getCrate(tccNb).first.c_str());
1410  ntuple->Fill();
1411 
1412  if ((tccNb == 76 || tccNb == 94) && stripInTower == 1 && xtalInStrip == 3 && (towerInTCC - 1) % 4 == 0) {
1413  int etaSlice = towid.ietaAbs();
1414  coeffStruc coeff;
1415  //getCoeff(coeff, calibMap, id.rawId()) ;
1416  //modif-alex-27-july-2015
1417  std::string str;
1418  getCoeff(coeff, calibMap, laserAlphaMap, id.rawId(), str);
1419  ss << str;
1420  getCoeff(coeff, gainMap, id.rawId());
1421  getCoeff(coeff, pedMap, id.rawId());
1422  linStruc lin;
1423  for (int i = 0; i < 3; i++) {
1424  lin.pedestal_[i] = coeff.pedestals_[i];
1425  lin.mult_[i] = 0;
1426  lin.shift_[i] = 0;
1427  int mult = 0;
1428  int shift = 0;
1429  bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EE", mult, shift);
1430  if (!ok) {
1431  //If the mult is impossible to compute
1432  if (mult > 255) {
1433  edm::LogError("TopInfo") << "ByEtaSlice: unable to compute the parameters for Quadrant=" << id.iquadrant()
1434  << " xt=" << id.ic() << " " << dec << id.rawId() << " gainId=" << i
1435  << ", mult too large! forced to mult=255, shift=0\n";
1436  lin.mult_[i] = 255;
1437  lin.shift_[i] = 0;
1438  } else if (mult < 128) {
1439  edm::LogError("TopInfo") << "ByEtaSlice: unable to compute the parameters for Quadrant=" << id.iquadrant()
1440  << " xt=" << id.ic() << " " << dec << id.rawId() << " gainId=" << i
1441  << ", mult too small! forced to mult=128, shift=15\n";
1442  ;
1443  lin.mult_[i] = 128;
1444  lin.shift_[i] = 15;
1445  }
1446  } else {
1447  lin.mult_[i] = mult;
1448  lin.shift_[i] = shift;
1449  }
1450  }
1451 
1452  bool ok(true);
1453  if (forcedPedestalValue_ == -2 || forcedPedestalValue_ == -3)
1454  ok = realignBaseline(lin, 0, id.rawId());
1455  if (!ok)
1456  ss << "Quadrant=" << id.iquadrant() << " xt=" << id.ic() << " " << dec << id.rawId() << "\n";
1457 
1458  linEtaSlice[etaSlice] = lin;
1459  }
1460  }
1461 
1462  // general case
1463  for (vector<DetId>::const_iterator it = eeCells.begin(); it != eeCells.end(); ++it) {
1464  EEDetId id(*it);
1465  double theta = theEndcapGeometry_->getGeometry(id)->getPosition().theta();
1466  if (!useTransverseEnergy_)
1467  theta = acos(0.);
1468  const EcalTrigTowerDetId towid = (*eTTmap_).towerOf(id);
1471  towerListEE.push_back(towid.rawId());
1472  // special case of towers in inner rings of EE
1473  if (towid.ietaAbs() == 27 || towid.ietaAbs() == 28) {
1474  EcalTrigTowerDetId additionalTower(towid.zside(), towid.subDet(), towid.ietaAbs(), towid.iphi() + 1);
1475  towerListEE.push_back(additionalTower.rawId());
1476  }
1477  stripListEE.push_back(elId.rawId() & 0xfffffff8);
1478 
1479  int dccNb = Id.dccId();
1480  //int tccNb = theMapping_->TCCid(towid) ;
1481  //int towerInTCC = theMapping_->iTT(towid) ;
1482  //int stripInTower = elId.pseudoStripId() ;
1483  //int xtalInStrip = elId.channelId() ;
1484  int CCUid = Id.towerId();
1485  int VFEid = Id.stripId();
1486  int xtalInVFE = Id.xtalId();
1487  int xtalWithinCCUid = 5 * (VFEid - 1) + xtalInVFE - 1; // Evgueni expects [0,24]
1488  int etaSlice = towid.ietaAbs();
1489 
1490  EcalLogicID logicId;
1491  FEConfigPedDat pedDB;
1492  FEConfigLinDat linDB;
1493  if (writeToFiles_)
1494  (*out_file_) << "CRYSTAL " << dec << id.rawId() << std::endl;
1495  if (writeToDB_ && DBEE_) {
1496  int iz = id.positiveZ();
1497  if (iz == 0)
1498  iz = -1;
1499  for (int k = 0; k < (int)my_CrystalEcalLogicId_EE.size(); k++) {
1500  int z = my_CrystalEcalLogicId_EE[k].getID1();
1501  int x = my_CrystalEcalLogicId_EE[k].getID2();
1502  int y = my_CrystalEcalLogicId_EE[k].getID3();
1503  if (id.ix() == x && id.iy() == y && iz == z) {
1504  logicId = my_CrystalEcalLogicId_EE[k];
1505  }
1506  }
1507  }
1508 
1509  coeffStruc coeff;
1510  //getCoeff(coeff, calibMap, id.rawId()) ;
1511  //modif-alex-27-july-2015
1512  string str;
1513  getCoeff(coeff, calibMap, laserAlphaMap, id.rawId(), str);
1514  ss << str;
1515  getCoeff(coeff, gainMap, id.rawId());
1516  getCoeff(coeff, pedMap, id.rawId());
1517  if (id.zside() > 0)
1518  ICEEPlus->Fill(id.ix(), id.iy(), coeff.calibCoeff_);
1519  else
1520  ICEEMinus->Fill(id.ix(), id.iy(), coeff.calibCoeff_);
1521  IC->Fill(theEndcapGeometry_->getGeometry(id)->getPosition().phi(),
1522  theEndcapGeometry_->getGeometry(id)->getPosition().eta(),
1523  coeff.calibCoeff_);
1524 
1525  vector<int> xtalCCU;
1526  xtalCCU.push_back(dccNb + 600);
1527  xtalCCU.push_back(CCUid);
1528  xtalCCU.push_back(xtalWithinCCUid);
1529  xtalCCU.push_back(id.rawId());
1530 
1531  // compute and fill linearization parameters
1532  // case of eta slice
1533  if (forceEtaSlice_) {
1534  map<int, linStruc>::const_iterator itLin = linEtaSlice.find(etaSlice);
1535  if (itLin != linEtaSlice.end()) {
1536  linMap[xtalCCU] = itLin->second;
1537  if (writeToFiles_) {
1538  for (int i = 0; i < 3; i++)
1539  (*out_file_) << hex << " 0x" << itLin->second.pedestal_[i] << " 0x" << itLin->second.mult_[i] << " 0x"
1540  << itLin->second.shift_[i] << std::endl;
1541  }
1542  if (writeToDB_ && DBEE_) {
1543  for (int i = 0; i < 3; i++) {
1544  if (i == 0) {
1545  pedDB.setPedMeanG12(itLin->second.pedestal_[i]);
1546  linDB.setMultX12(itLin->second.mult_[i]);
1547  linDB.setShift12(itLin->second.shift_[i]);
1548  } else if (i == 1) {
1549  pedDB.setPedMeanG6(itLin->second.pedestal_[i]);
1550  linDB.setMultX6(itLin->second.mult_[i]);
1551  linDB.setShift6(itLin->second.shift_[i]);
1552  } else if (i == 2) {
1553  pedDB.setPedMeanG1(itLin->second.pedestal_[i]);
1554  linDB.setMultX1(itLin->second.mult_[i]);
1555  linDB.setShift1(itLin->second.shift_[i]);
1556  }
1557  }
1558  }
1559  float factor = float(itLin->second.mult_[0]) * pow(2., -itLin->second.shift_[0]) / xtal_LSB_EE_;
1560  if (id.zside() > 0)
1561  tpgFactorEEPlus->Fill(id.ix(), id.iy(), factor);
1562  else
1563  tpgFactorEEMinus->Fill(id.ix(), id.iy(), factor);
1564  tpgFactor->Fill(theEndcapGeometry_->getGeometry(id)->getPosition().phi(),
1565  theEndcapGeometry_->getGeometry(id)->getPosition().eta(),
1566  factor);
1567  } else
1568  ss << "current EtaSlice = " << etaSlice << " not found in the EtaSlice map"
1569  << "\n";
1570  } else {
1571  // general case
1572  linStruc lin;
1573  for (int i = 0; i < 3; i++) {
1574  lin.pedestal_[i] = coeff.pedestals_[i];
1575  lin.mult_[i] = 0;
1576  lin.shift_[i] = 0;
1577  int mult = 0;
1578  int shift = 0;
1579  bool ok = computeLinearizerParam(theta, coeff.gainRatio_[i], coeff.calibCoeff_, "EE", mult, shift);
1580  if (!ok) {
1581  //If the mult is impossible to compute
1582  if (mult > 255) {
1583  edm::LogError("TopInfo") << "unable to compute the parameters for " << dec << id.rawId()
1584  << ", EE, gainId=" << i << ", mult too large! forced to mult=255, shift=0\n";
1585  lin.mult_[i] = 255;
1586  lin.shift_[i] = 0;
1587  } else if (mult < 128) {
1588  edm::LogError("TopInfo") << "unable to compute the parameters for " << dec << id.rawId()
1589  << ", EE, gainId=" << i << ", mult too small! forced to mult=128, shift=15\n";
1590  lin.mult_[i] = 128;
1591  lin.shift_[i] = 15;
1592  }
1593  } else {
1594  lin.mult_[i] = mult;
1595  lin.shift_[i] = shift;
1596  }
1597  }
1598 
1599  bool ok(true);
1600  if (forcedPedestalValue_ == -2 || forcedPedestalValue_ == -3)
1601  ok = realignBaseline(lin, 0, id.rawId());
1602  if (!ok)
1603  ss << "Quadrant=" << id.iquadrant() << " xt=" << id.ic() << " " << dec << id.rawId() << "\n";
1604 
1605  for (int i = 0; i < 3; i++) {
1606  if (writeToFiles_)
1607  (*out_file_) << hex << " 0x" << lin.pedestal_[i] << " 0x" << lin.mult_[i] << " 0x" << lin.shift_[i]
1608  << std::endl;
1609  if (writeToDB_ && DBEE_) {
1610  if (i == 0) {
1611  pedDB.setPedMeanG12(lin.pedestal_[i]);
1612  linDB.setMultX12(lin.mult_[i]);
1613  linDB.setShift12(lin.shift_[i]);
1614  } else if (i == 1) {
1615  pedDB.setPedMeanG6(lin.pedestal_[i]);
1616  linDB.setMultX6(lin.mult_[i]);
1617  linDB.setShift6(lin.shift_[i]);
1618  } else if (i == 2) {
1619  pedDB.setPedMeanG1(lin.pedestal_[i]);
1620  linDB.setMultX1(lin.mult_[i]);
1621  linDB.setShift1(lin.shift_[i]);
1622  }
1623  }
1624  if (i == 0) {
1625  float factor = float(lin.mult_[i]) * pow(2., -lin.shift_[i]) / xtal_LSB_EE_;
1626  if (id.zside() > 0)
1627  tpgFactorEEPlus->Fill(id.ix(), id.iy(), factor);
1628  else
1629  tpgFactorEEMinus->Fill(id.ix(), id.iy(), factor);
1630  tpgFactor->Fill(theEndcapGeometry_->getGeometry(id)->getPosition().phi(),
1631  theEndcapGeometry_->getGeometry(id)->getPosition().eta(),
1632  factor);
1633  }
1634  }
1635  linMap[xtalCCU] = lin;
1636  }
1637  if (writeToDB_ && DBEE_) {
1638  pedset[logicId] = pedDB;
1639  linset[logicId] = linDB;
1640  }
1641  } //eeCells
1642  edm::LogInfo("TopInfo") << ss.str();
1643  ss.str("");
1644 
1645  if (writeToDB_) {
1646  // EcalLogicID of the whole barrel is: my_EcalLogicId_EB
1647  FEConfigLinParamDat linparam;
1648  linparam.setETSat(Et_sat_EE_);
1649  linparamset[my_EcalLogicId_EE] = linparam;
1650 
1651  FEConfigLUTParamDat lutparam;
1652  lutparam.setETSat(Et_sat_EE_);
1655  lutparamset[my_EcalLogicId_EE] = lutparam;
1656 
1657  FEConfigFgrParamDat fgrparam;
1658  fgrparam.setFGlowthresh(FG_Threshold_EE_);
1660  fgrparamset[my_EcalLogicId_EE] = fgrparam;
1661  }
1662 
1663  if (writeToDB_) {
1664  ostringstream ltag;
1665  ltag.str("EB_");
1666  ltag << Et_sat_EB_ << "_EE_" << Et_sat_EE_;
1667  std::string lin_tag = ltag.str();
1668  ss << " LIN tag " << lin_tag << "\n";
1669 
1670  if (m_write_ped == 1) {
1671  ped_conf_id_ = db_->writeToConfDB_TPGPedestals(pedset, 1, "from_OfflineDB");
1672  } else {
1673  ss << "the ped id =" << ped_conf_id_ << " will be used for the pedestals "
1674  << "\n";
1675  }
1676 
1677  if (m_write_lin == 1)
1678  lin_conf_id_ = db_->writeToConfDB_TPGLinearCoef(linset, linparamset, 1, lin_tag);
1679  }
1680 
1682  // Evgueni interface
1684  std::ofstream evgueni("TPG_hardcoded.hh", std::ios::out);
1685  evgueni << "void getLinParamTPG_hardcoded(int fed, int ccu, int xtal," << std::endl;
1686  evgueni << " int & mult12, int & shift12, int & base12," << std::endl;
1687  evgueni << " int & mult6, int & shift6, int & base6," << std::endl;
1688  evgueni << " int & mult1, int & shift1, int & base1)" << std::endl;
1689  evgueni << "{" << std::endl;
1690  evgueni << " mult12 = 0 ; shift12 = 0 ; base12 = 0 ; mult6 = 0 ; shift6 = 0 ; base6 = 0 ; mult1 = 0 ; shift1 = 0 ; "
1691  "base1 = 0 ;"
1692  << std::endl;
1693  map<vector<int>, linStruc>::const_iterator itLinMap;
1694  for (itLinMap = linMap.begin(); itLinMap != linMap.end(); itLinMap++) {
1695  vector<int> xtalInCCU = itLinMap->first;
1696  evgueni << " if (fed==" << xtalInCCU[0] << " && ccu==" << xtalInCCU[1] << " && xtal==" << xtalInCCU[2] << ") {";
1697  evgueni << " mult12 = " << itLinMap->second.mult_[0] << " ; shift12 = " << itLinMap->second.shift_[0]
1698  << " ; base12 = " << itLinMap->second.pedestal_[0] << " ; ";
1699  evgueni << " mult6 = " << itLinMap->second.mult_[1] << " ; shift6 = " << itLinMap->second.shift_[1]
1700  << " ; base6 = " << itLinMap->second.pedestal_[1] << " ; ";
1701  evgueni << " mult1 = " << itLinMap->second.mult_[2] << " ; shift1 = " << itLinMap->second.shift_[2]
1702  << " ; base1 = " << itLinMap->second.pedestal_[2] << " ; ";
1703  evgueni << " return ;}" << std::endl;
1704  }
1705  evgueni << "}" << std::endl;
1706  evgueni.close();
1707 
1709  // Compute weights section //
1711 
1712  std::map<int, int> weights_map_even;
1713  std::map<int, int> weights_map_odd;
1714 
1716  // Computing the weights from shapes, 1 set for EB and 1 for EE only
1717  shapeEB_.setEventSetup(evtSetup); // EBShape, EEShape are fetched now from DB (2018.05.22 K. Theofilatos)
1718  shapeEE_.setEventSetup(evtSetup);
1719  const int NWEIGROUPS = 2;
1720  std::vector<unsigned int> weights[NWEIGROUPS];
1721  weights[0] = computeWeights(shapeEB_, hshapeEB);
1722  weights[1] = computeWeights(shapeEE_, hshapeEE);
1723 
1724  map<EcalLogicID, FEConfigWeightGroupDat> dataset;
1725 
1726  for (int igrp = 0; igrp < NWEIGROUPS; igrp++) {
1727  if (weights[igrp].size() == EcalTPGParamBuilder::NWEIGHTS) {
1728  if (writeToFiles_) {
1729  (*out_file_) << std::endl;
1730  (*out_file_) << "WEIGHT " << dec << igrp << std::endl;
1731  for (unsigned int sample = 0; sample < EcalTPGParamBuilder::NWEIGHTS; sample++)
1732  (*out_file_) << "0x" << hex << weights[igrp][sample] << " ";
1733  (*out_file_) << std::endl;
1734  (*out_file_) << std::endl;
1735  }
1736  if (writeToDB_) {
1737  ss << "going to write the weights for group:" << igrp << "\n";
1739  gut.setWeightGroupId(igrp);
1740  //PP WARNING: weights order is reverted when stored in the DB
1741  gut.setWeight0(weights[igrp][4]);
1742  gut.setWeight1(weights[igrp][3] +
1743  0x80); //0x80 to identify the max of the pulse in the FENIX (doesn't exist in emulator)
1744  gut.setWeight2(weights[igrp][2]);
1745  gut.setWeight3(weights[igrp][1]);
1746  gut.setWeight4(weights[igrp][0]);
1747  EcalLogicID ecid = EcalLogicID("DUMMY", igrp, igrp); //1 dummy ID per group
1748  // Fill the dataset
1749  dataset[ecid] = gut;
1750  }
1751  }
1752  }
1753  // now we store in the DB the correspondence btw channels and groups
1754  map<EcalLogicID, FEConfigWeightDat> dataset2;
1755  // EB loop
1756  for (int ich = 0; ich < (int)my_StripEcalLogicId.size(); ich++) {
1757  FEConfigWeightDat wut;
1758  int igroup = 0; // this group is for EB
1759  weights_map_even[stripMapEB[ich]] = 0;
1760  wut.setWeightGroupId(igroup);
1761  dataset2[my_StripEcalLogicId[ich]] = wut;
1762  }
1763 
1764  // EE loop
1765  for (EcalLogicID& stripLogicId : my_StripEcalLogicId1_EE) {
1766  FEConfigWeightDat wut;
1767  int igroup = 1; // this group is for EE
1768  weights_map_even[stripMapEE[stripLogicId.getLogicID()]] = 1;
1769  wut.setWeightGroupId(igroup);
1770  // Fill the dataset
1771  dataset2[stripLogicId] = wut;
1772  }
1773  // EE loop 2 (we had to split the ids of EE in 2 vectors to avoid crash!)
1774  for (EcalLogicID& stripLogicId : my_StripEcalLogicId2_EE) {
1775  FEConfigWeightDat wut;
1776  int igroup = 1; // this group is for EE
1777  weights_map_even[stripMapEE[stripLogicId.getLogicID()]] = 1;
1778  wut.setWeightGroupId(igroup);
1779  // Fill the dataset
1780  dataset2[stripLogicId] = wut;
1781  }
1782 
1783  if (writeToDB_) {
1784  // Insert the datasets
1785  ostringstream wtag;
1786  wtag.str("");
1787  wtag << "Shape_NGroups_" << NWEIGROUPS;
1788  std::string weight_tag = wtag.str();
1789  ss << " weight tag " << weight_tag << "\n";
1790  if (m_write_wei == 1)
1791  wei_conf_id_ = db_->writeToConfDB_TPGWeight(dataset, dataset2, NWEIGROUPS, weight_tag);
1792  }
1794  } else {
1795  // Read Even weights from file.
1796  std::vector<std::vector<unsigned int>> weights_even;
1797 
1798  std::ifstream file(weight_even_weightGroupFile_);
1799  std::string line;
1800  while (std::getline(file, line)) {
1801  std::istringstream iss(line);
1802  std::vector<unsigned int> wei_group_even;
1803  for (std::string s; iss >> s;)
1804  wei_group_even.push_back(stoi(s));
1805  weights_even.push_back(wei_group_even);
1806  }
1807  int nweigroups_even = weights_even.size();
1808 
1809  std::ifstream file2(weight_even_idMapFile_);
1810  std::string line2;
1811  while (std::getline(file2, line2)) {
1812  std::istringstream iss(line2);
1813  int ch_id, wei_gr;
1814  iss >> std::dec >> ch_id;
1815  iss >> std::dec >> wei_gr;
1816  int wei_group = wei_gr;
1817  if (wei_group > nweigroups_even - 1) {
1818  edm::LogError("TopInfo") << "Associating strip: " << ch_id << " to non-existing weight group: " << wei_gr
1819  << "\n";
1820  }
1821  weights_map_even[ch_id] = wei_group;
1822  }
1823 
1824  map<EcalLogicID, FEConfigWeightGroupDat> dataset_even;
1825 
1826  for (int igrp = 0; igrp < nweigroups_even; igrp++) {
1827  if (weights_even[igrp].size() == EcalTPGParamBuilder::NWEIGHTS) {
1828  if (writeToFiles_) {
1829  (*out_file_) << std::endl;
1830  (*out_file_) << "WEIGHT " << dec << igrp << std::endl;
1831  for (unsigned int sample = 0; sample < EcalTPGParamBuilder::NWEIGHTS; sample++)
1832  (*out_file_) << "0x" << hex << weights_even[igrp][sample] << " ";
1833  (*out_file_) << std::endl;
1834  (*out_file_) << std::endl;
1835  }
1836  if (writeToDB_) {
1837  ss << "going to write the weights for group:" << igrp << "\n";
1839  gut.setWeightGroupId(igrp);
1840  //PP WARNING: weights order is reverted when stored in the DB
1841  gut.setWeight0(weights_even[igrp][4]);
1842  gut.setWeight1(weights_even[igrp][3] +
1843  0x80); //0x80 to identify the max of the pulse in the FENIX (doesn't exist in emulator)
1844  gut.setWeight2(weights_even[igrp][2]);
1845  gut.setWeight3(weights_even[igrp][1]);
1846  gut.setWeight4(weights_even[igrp][0]);
1847  EcalLogicID ecid = EcalLogicID("DUMMY", igrp, igrp); //1 dummy ID per group
1848  // Fill the dataset
1849  dataset_even[ecid] = gut;
1850  }
1851  }
1852  }
1853  if (writeToDB_) {
1854  // now we store in the DB the correspondence btw channels and groups
1855  map<EcalLogicID, FEConfigWeightDat> dataset_even_idmap;
1856  // EB loop
1857  for (int ich = 0; ich < (int)my_StripEcalLogicId.size(); ich++) {
1858  FEConfigWeightDat wut;
1859  int igroup = weights_map_even[stripMapEB[ich]]; // this group is for EB
1860  wut.setWeightGroupId(igroup);
1861  dataset_even_idmap[my_StripEcalLogicId[ich]] = wut;
1862  }
1863  // EE loop
1864  for (EcalLogicID& stripLogicId : my_StripEcalLogicId1_EE) {
1865  FEConfigWeightDat wut;
1866  int igroup = weights_map_even[stripMapEE[stripLogicId.getLogicID()]];
1867  wut.setWeightGroupId(igroup);
1868  // Fill the dataset
1869  dataset_even_idmap[stripLogicId] = wut;
1870  }
1871  // EE loop 2 (we had to split the ids of EE in 2 vectors to avoid crash!)
1872  for (EcalLogicID& stripLogicId : my_StripEcalLogicId2_EE) {
1873  FEConfigWeightDat wut;
1874  int igroup = weights_map_even[stripMapEE[stripLogicId.getLogicID()]]; // this group is for EE
1875  wut.setWeightGroupId(igroup);
1876  // Fill the dataset
1877  dataset_even_idmap[stripLogicId] = wut;
1878  }
1879  // Insert the datasets
1880  ostringstream wtag;
1881  wtag.str("");
1882  wtag << "Shape_even_NGroups_" << nweigroups_even;
1883  std::string weight_tag = wtag.str();
1884  ss << " weight tag " << weight_tag << "\n";
1885  if (m_write_wei == 1)
1886  wei_conf_id_ = db_->writeToConfDB_TPGWeight(dataset_even, dataset_even_idmap, nweigroups_even, weight_tag);
1887  }
1888  }
1889 
1890  //+=========================================================== Odd weights
1892  // Odd weights are always read from file
1893  std::vector<std::vector<unsigned int>> weights_odd;
1894  std::ifstream file3(weight_odd_weightGroupFile_);
1895  std::string line3;
1896  while (std::getline(file3, line3)) {
1897  std::istringstream iss(line3);
1898  std::vector<unsigned int> wei_group_odd;
1899  for (std::string s; iss >> s;)
1900  wei_group_odd.push_back(stoi(s));
1901  weights_odd.push_back(wei_group_odd);
1902  }
1903  int nweigroups_odd = weights_odd.size();
1904 
1905  std::ifstream file4(weight_odd_idMapFile_);
1906  std::string line4;
1907  while (std::getline(file4, line4)) {
1908  std::istringstream iss(line4);
1909  int ch_id, wei_gr;
1910  iss >> std::dec >> ch_id;
1911  iss >> std::dec >> wei_gr;
1912  int wei_group = wei_gr;
1913  if (wei_group > nweigroups_odd - 1) {
1914  edm::LogError("TopInfo") << "Associating strip: " << ch_id << " to non-existing weight group: " << wei_gr
1915  << "\n";
1916  }
1917  weights_map_odd[ch_id] = wei_group;
1918  }
1919 
1920  map<EcalLogicID, FEConfigOddWeightGroupDat> dataset_odd;
1921 
1922  for (int igrp = 0; igrp < nweigroups_odd; igrp++) {
1923  if (weights_odd[igrp].size() == EcalTPGParamBuilder::NWEIGHTS) {
1924  if (writeToFiles_) {
1925  (*out_file_) << std::endl;
1926  (*out_file_) << "WEIGHT_ODD " << dec << igrp << std::endl;
1927  for (unsigned int sample = 0; sample < EcalTPGParamBuilder::NWEIGHTS; sample++)
1928  (*out_file_) << "0x" << hex << weights_odd[igrp][sample] << " ";
1929  (*out_file_) << std::endl;
1930  (*out_file_) << std::endl;
1931  }
1932  if (writeToDB_) {
1933  ss << "going to write the weights for group:" << igrp << "\n";
1935  gut.setWeightGroupId(igrp);
1936  //PP WARNING: weights order is reverted when stored in the DB
1937  gut.setWeight0(weights_odd[igrp][4]);
1938  gut.setWeight1(weights_odd[igrp][3] +
1939  0x80); //0x80 to identify the max of the pulse in the FENIX (doesn't exist in emulator)
1940  gut.setWeight2(weights_odd[igrp][2]);
1941  gut.setWeight3(weights_odd[igrp][1]);
1942  gut.setWeight4(weights_odd[igrp][0]);
1943  EcalLogicID ecid = EcalLogicID("DUMMY", igrp, igrp); //1 dummy ID per group
1944  // Fill the dataset
1945  dataset_odd[ecid] = gut;
1946  }
1947  }
1948  }
1949  // TP MODE configuration
1950  if (writeToFiles_) {
1951  (*out_file_) << std::endl;
1952  (*out_file_) << "TP_MODE " << std::endl;
1953  (*out_file_) << TPmode_EnableEBOddFilter_ << std::endl;
1954  (*out_file_) << TPmode_EnableEEOddFilter_ << std::endl;
1955  (*out_file_) << TPmode_EnableEBOddPeakFinder_ << std::endl;
1956  (*out_file_) << TPmode_EnableEEOddPeakFinder_ << std::endl;
1957  (*out_file_) << TPmode_DisableEBEvenPeakFinder_ << std::endl;
1958  (*out_file_) << TPmode_DisableEEEvenPeakFinder_ << std::endl;
1959  (*out_file_) << TPmode_FenixEBStripOutput_ << std::endl;
1960  (*out_file_) << TPmode_FenixEEStripOutput_ << std::endl;
1961  (*out_file_) << TPmode_FenixEBStripInfobit2_ << std::endl;
1962  (*out_file_) << TPmode_FenixEEStripInfobit2_ << std::endl;
1963  (*out_file_) << TPmode_FenixEBTcpOutput_ << std::endl;
1964  (*out_file_) << TPmode_FenixEBTcpInfobit1_ << std::endl;
1965  (*out_file_) << TPmode_FenixEETcpOutput_ << std::endl;
1966  (*out_file_) << TPmode_FenixEETcpInfobit1_ << std::endl;
1967  (*out_file_) << 0 << std::endl; // FenixPar15-18 are placeholder parameters for future use
1968  (*out_file_) << 0 << std::endl;
1969  (*out_file_) << 0 << std::endl;
1970  (*out_file_) << 0 << std::endl;
1971  (*out_file_) << std::endl;
1972  }
1973 
1974  if (writeToDB_) {
1975  // now we store in the DB the correspondence btw channels and groups
1976  map<EcalLogicID, FEConfigOddWeightDat> dataset_odd_idmap;
1977 
1978  // EB loop
1979  for (int ich = 0; ich < (int)my_StripEcalLogicId.size(); ich++) {
1981  int igroup = weights_map_odd[stripMapEB[ich]]; // this group is for EB
1982  wut.setWeightGroupId(igroup);
1983  dataset_odd_idmap[my_StripEcalLogicId[ich]] = wut;
1984  }
1985  // EE loop
1986  for (auto& stripLogicId : my_StripEcalLogicId1_EE) {
1988  int igroup = weights_map_odd[stripMapEE[stripLogicId.getLogicID()]];
1989  wut.setWeightGroupId(igroup);
1990  // Fill the dataset
1991  dataset_odd_idmap[stripLogicId] = wut;
1992  }
1993  // EE loop 2 (we had to split the ids of EE in 2 vectors to avoid crash!)
1994  for (auto& stripLogicId : my_StripEcalLogicId2_EE) {
1996  int igroup = weights_map_odd[stripMapEE[stripLogicId.getLogicID()]]; // this group is for EE
1997  wut.setWeightGroupId(igroup);
1998  // Fill the dataset
1999  dataset_odd_idmap[stripLogicId] = wut;
2000  }
2001  // TP mode on DB
2002  map<EcalLogicID, FEConfigOddWeightModeDat> dataset_tpmode;
2003  FEConfigOddWeightModeDat tp_mode;
2018  dataset_tpmode[my_StripEcalLogicId[0]] = tp_mode; // The LogicID is not used in reality....
2019 
2020  // Insert the datasets
2021  ostringstream wtag;
2022  wtag.str("");
2023  wtag << "Shape_odd_NGroups_" << nweigroups_odd;
2024  std::string weight_tag = wtag.str();
2025  ss << " weight tag " << weight_tag << "\n";
2026  if (m_write_wei2 == 1)
2028  dataset_odd, dataset_odd_idmap, dataset_tpmode, nweigroups_odd, weight_tag);
2029  }
2030 
2031  } else {
2032  // If useDoubleWeight == False we need to use the default
2033  // wei2_conf_id=1 and save a blank TP mode and blank Odd weight group
2034  if (writeToFiles_) {
2035  // single set of ODD weights ==0 is written to the txt file
2036  (*out_file_) << "WEIGHT_ODD " << dec << 0 << std::endl;
2037  for (unsigned int sample = 0; sample < EcalTPGParamBuilder::NWEIGHTS; sample++)
2038  (*out_file_) << "0x0"
2039  << " ";
2040  (*out_file_) << std::endl << std::endl;
2041 
2042  // Default TP mode with Run2 config == all parameters to 0
2043  (*out_file_) << "TP_MODE " << std::endl;
2044  for (int m = 0; m < 18; m++)
2045  (*out_file_) << 0 << std::endl;
2046  (*out_file_) << std::endl;
2047  }
2048  wei2_conf_id_ = 1; // special value that is interpreted by online DAQ code as Run2 configuration
2049  }
2050 
2051  edm::LogInfo("TopInfo") << ss.str();
2052  ss.str("");
2053 
2055  // Compute FG section //
2057 
2058  // barrel
2059  unsigned int lowRatio, highRatio, lowThreshold, highThreshold, lutFG;
2060  computeFineGrainEBParameters(lowRatio, highRatio, lowThreshold, highThreshold, lutFG);
2061  if (writeToFiles_) {
2062  (*out_file_) << std::endl;
2063  (*out_file_) << "FG 0" << std::endl;
2064  (*out_file_) << hex << "0x" << lowThreshold << " 0x" << highThreshold << " 0x" << lowRatio << " 0x" << highRatio
2065  << " 0x" << lutFG << std::endl;
2066  }
2067 
2068  // endcap
2069  unsigned int threshold, lut_tower;
2070  unsigned int lut_strip;
2071  computeFineGrainEEParameters(threshold, lut_strip, lut_tower);
2072 
2073  // and here we store the fgr part
2074 
2075  if (writeToDB_) {
2076  ss << "going to write the fgr "
2077  << "\n";
2078  map<EcalLogicID, FEConfigFgrGroupDat> dataset;
2079  // we create 1 group
2080  int NFGRGROUPS = 1;
2081  for (int ich = 0; ich < NFGRGROUPS; ich++) {
2082  FEConfigFgrGroupDat gut;
2083  gut.setFgrGroupId(ich);
2084  gut.setThreshLow(lowRatio);
2085  gut.setThreshHigh(highRatio);
2086  gut.setRatioLow(lowThreshold);
2087  gut.setRatioHigh(highThreshold);
2088  gut.setLUTValue(lutFG);
2089  EcalLogicID ecid = EcalLogicID("DUMMY", ich, ich);
2090  // Fill the dataset
2091  dataset[ecid] = gut; // we use any logic id but different, because it is in any case ignored...
2092  }
2093 
2094  // now we store in the DB the correspondence btw channels and groups
2095  map<EcalLogicID, FEConfigFgrDat> dataset2;
2096  for (auto& id : my_TTEcalLogicId) {
2097  FEConfigFgrDat wut;
2098  int igroup = 0;
2099  wut.setFgrGroupId(igroup);
2100  // Fill the dataset
2101  // the logic ids are ordered by SM (1,...36) and TT (1,...68)
2102  dataset2[id] = wut;
2103  }
2104 
2105  // endcap loop
2106  for (auto& id : my_RTEcalLogicId_EE) {
2107  // std::cout << " endcap FGR " << std::endl;
2108  FEConfigFgrDat wut;
2109  int igroup = 0;
2110  wut.setFgrGroupId(igroup);
2111  // Fill the dataset
2112  // the logic ids are ordered by .... ?
2113  // you have to calculate the right index here
2114  dataset2[id] = wut;
2115  }
2116 
2117  // endcap TT loop for the FEfgr EE Tower
2118  map<EcalLogicID, FEConfigFgrEETowerDat> dataset3;
2119  for (auto& id : my_TTEcalLogicId_EE) {
2120  FEConfigFgrEETowerDat fgreett;
2121  fgreett.setLutValue(lut_tower);
2122  dataset3[id] = fgreett;
2123  }
2124 
2125  // endcap strip loop for the FEfgr EE strip
2126  // and barrel strip loop for the spike parameters (same structure than EE FGr)
2127  map<EcalLogicID, FEConfigFgrEEStripDat> dataset4;
2128  for (auto& id : my_StripEcalLogicId1_EE) {
2130  zut.setThreshold(threshold);
2131  zut.setLutFgr(lut_strip);
2132  dataset4[id] = zut;
2133  }
2134  for (auto& id : my_StripEcalLogicId2_EE) {
2136  zut.setThreshold(threshold);
2137  zut.setLutFgr(lut_strip);
2138  // Fill the dataset
2139  dataset4[id] = zut;
2140  }
2141  for (int ich = 0; ich < (int)my_StripEcalLogicId.size(); ich++) {
2142  // EB
2144  EcalLogicID thestrip = my_StripEcalLogicId[ich];
2145  uint32_t elStripId = stripMapEB[ich];
2146  map<uint32_t, uint32_t>::const_iterator it = stripMapEBsintheta.find(elStripId);
2147  if (it != stripMapEBsintheta.end())
2148  zut.setThreshold(it->second);
2149  else {
2150  edm::LogError("TopInfo") << "ERROR: strip SFGVB threshold parameter not found for that strip:"
2151  << thestrip.getID1() << " " << thestrip.getID3() << " " << thestrip.getID3() << "\n";
2152  edm::LogError("TopInfo") << " using value = " << SFGVB_Threshold_ + pedestal_offset_ << "\n";
2154  }
2155  zut.setLutFgr(SFGVB_lut_);
2156  // Fill the dataset
2157  dataset4[thestrip] = zut;
2158  }
2159 
2160  // Insert the dataset
2161  ostringstream wtag;
2162  wtag.str("");
2163  wtag << "FGR_" << lutFG << "_N_" << NFGRGROUPS << "_eb_" << FG_lowThreshold_EB_ << "_EB_" << FG_highThreshold_EB_;
2164  std::string weight_tag = wtag.str();
2165  ss << " weight tag " << weight_tag << "\n";
2166  if (m_write_fgr == 1)
2167  fgr_conf_id_ =
2168  db_->writeToConfDB_TPGFgr(dataset, dataset2, fgrparamset, dataset3, dataset4, NFGRGROUPS, weight_tag);
2169 
2170  //modif-alex 21/01/11
2171  map<EcalLogicID, FEConfigSpikeDat> datasetspike; //loob EB TT
2172  for (auto& id : my_TTEcalLogicId) {
2173  FEConfigSpikeDat spiketh;
2175  datasetspike[id] = spiketh;
2176  } //loop EB TT towers
2177 
2178  //modif-alex 21/01/11
2179  ostringstream stag;
2180  stag.str("");
2181  stag << "SpikeTh" << SFGVB_SpikeKillingThreshold_;
2182  std::string spike_tag = stag.str();
2183  ss << " spike tag " << spike_tag << "\n";
2184  if (m_write_spi == 1)
2185  spi_conf_id_ = db_->writeToConfDB_Spike(datasetspike, spike_tag); //modif-alex 21/01/11
2186 
2187  //modif-alex 31/01/11
2188  //DELAYS EB
2189  map<EcalLogicID, FEConfigTimingDat>
2190  datasetdelay; // the loop goes from TCC 38 to 72 and throught the towers from 1 to 68
2191  for (int ich = 0; ich < (int)my_TTEcalLogicId_EB_by_TCC.size(); ich++) {
2193 
2194  EcalLogicID logiciddelay = my_TTEcalLogicId_EB_by_TCC[ich];
2195  int id1_tcc = logiciddelay.getID1(); // the TCC
2196  int id2_tt = logiciddelay.getID2(); // the tower
2197  std::map<int, vector<int>>::const_iterator ittEB = delays_EB_.find(id1_tcc);
2198  std::vector<int> TimingDelaysEB = ittEB->second;
2199 
2200  if (ittEB != delays_EB_.end()) {
2201  if (TimingDelaysEB[id2_tt - 1] == -1) {
2202  edm::LogError("TopInfo") << "ERROR: Barrel timing delay not specified, check file, putting default value 1"
2203  << "\n";
2204  delay.setTimingPar1(1);
2205  } else
2206  delay.setTimingPar1(TimingDelaysEB[id2_tt - 1]);
2207  } else {
2208  edm::LogError("TopInfo") << "ERROR:Barrel Could not find delay parameter for that trigger tower "
2209  << "\n";
2210  edm::LogError("TopInfo") << "Using default value = 1"
2211  << "\n";
2212  delay.setTimingPar1(1);
2213  }
2214 
2215  std::map<int, vector<int>>::const_iterator ittpEB = phases_EB_.find(id1_tcc);
2216  std::vector<int> TimingPhasesEB = ittpEB->second;
2217 
2218  if (ittpEB != phases_EB_.end()) {
2219  if (TimingPhasesEB[id2_tt - 1] == -1) {
2220  edm::LogError("TopInfo") << "ERROR: Barrel timing phase not specified, check file, putting default value 0"
2221  << "\n";
2222  delay.setTimingPar2(0);
2223  } else
2224  delay.setTimingPar2(TimingPhasesEB[id2_tt - 1]);
2225  } else {
2226  edm::LogError("TopInfo") << "ERROR:Barrel Could not find phase parameter for that trigger tower "
2227  << "\n";
2228  edm::LogError("TopInfo") << "Using default value = 0"
2229  << "\n";
2230  delay.setTimingPar2(0);
2231  }
2232 
2233  ss << ich << " tcc=" << id1_tcc << " TT=" << id2_tt << " logicId=" << logiciddelay.getLogicID()
2234  << " delay=" << TimingDelaysEB[id2_tt - 1] << " phase=" << TimingPhasesEB[id2_tt - 1] << "\n";
2235 
2236  //delay.setTimingPar1(1);
2237  //delay.setTimingPar2(2);
2238  datasetdelay[logiciddelay] = delay;
2239  } //loop EB TT towers
2240 
2241  //DELAYS EE
2242  int stripindex = 0;
2243  int tccin = 1;
2244  for (int ich = 0; ich < (int)my_StripEcalLogicId_EE_strips_by_TCC.size(); ich++) {
2246 
2247  EcalLogicID logiciddelay = my_StripEcalLogicId_EE_strips_by_TCC[ich];
2248  int id1_tcc = logiciddelay.getID1(); // the TCC
2249  int id2_tt = logiciddelay.getID2(); // the tower
2250  int id3_st = logiciddelay.getID3(); // the strip
2251 
2252  //reset strip counter
2253  if (id1_tcc != tccin) {
2254  tccin = id1_tcc;
2255  stripindex = 0;
2256  }
2257 
2258  std::map<int, vector<int>>::const_iterator ittEE = delays_EE_.find(id1_tcc);
2259  std::vector<int> TimingDelaysEE = ittEE->second;
2260 
2261  if (ittEE != delays_EE_.end()) {
2262  if (TimingDelaysEE[stripindex] == -1) {
2263  edm::LogError("TopInfo") << "ERROR: Endcap timing delay not specified, check file, putting default value 1"
2264  << "\n";
2265  delay.setTimingPar1(1);
2266  } else
2267  delay.setTimingPar1(TimingDelaysEE[stripindex]);
2268  } else {
2269  edm::LogError("TopInfo") << "ERROR:Endcap Could not find delay parameter for that trigger tower "
2270  << "\n";
2271  edm::LogError("TopInfo") << "Using default value = 1"
2272  << "\n";
2273  delay.setTimingPar1(1);
2274  }
2275 
2276  std::map<int, vector<int>>::const_iterator ittpEE = phases_EE_.find(id1_tcc);
2277  std::vector<int> TimingPhasesEE = ittpEE->second;
2278 
2279  if (ittpEE != phases_EE_.end()) {
2280  if (TimingPhasesEE[stripindex] == -1) {
2281  edm::LogError("TopInfo") << "ERROR: Endcap timing phase not specified, check file, putting default value 0"
2282  << "\n";
2283  delay.setTimingPar2(0);
2284  } else
2285  delay.setTimingPar2(TimingPhasesEE[stripindex]);
2286  } else {
2287  edm::LogError("TopInfo") << "ERROR:Endcap Could not find phase parameter for that trigger tower "
2288  << "\n";
2289  edm::LogError("TopInfo") << "Using default value = 0"
2290  << "\n";
2291  delay.setTimingPar2(0);
2292  }
2293 
2294  ss << ich << " stripindex=" << stripindex << " tcc=" << id1_tcc << " TT=" << id2_tt << " id3_st=" << id3_st
2295  << " logicId=" << logiciddelay.getLogicID() << " delay=" << TimingDelaysEE[stripindex]
2296  << " phase=" << TimingPhasesEE[stripindex] << "\n";
2297 
2298  //delay.setTimingPar1(1);
2299  //delay.setTimingPar2(2);
2300  datasetdelay[logiciddelay] = delay;
2301  stripindex++;
2302  } //loop EE strip towers
2303 
2304  ostringstream de_tag;
2305  de_tag.str("");
2306  de_tag << "DelaysFromFile";
2307  std::string delay_tag = de_tag.str();
2308  ss << " delay tag " << delay_tag << "\n";
2309  if (m_write_del == 1)
2310  del_conf_id_ = db_->writeToConfDB_Delay(datasetdelay, delay_tag); //modif-alex 31/01/11
2311 
2312  } //write to DB
2313 
2314  if (writeToDB_) {
2315  ss << "going to write the sliding "
2316  << "\n";
2317  map<EcalLogicID, FEConfigSlidingDat> dataset;
2318  for (auto& id : my_StripEcalLogicId) {
2319  FEConfigSlidingDat wut;
2320  wut.setSliding(sliding_);
2321  // Fill the dataset
2322  // the logic ids are ordered by SM (1,...36) , TT (1,...68) and strip (1..5)
2323  dataset[id] = wut;
2324  }
2325 
2326  // endcap loop
2327  for (auto& id : my_StripEcalLogicId1_EE) {
2328  FEConfigSlidingDat wut;
2329  wut.setSliding(sliding_);
2330  dataset[id] = wut;
2331  }
2332  for (auto& id : my_StripEcalLogicId2_EE) {
2333  FEConfigSlidingDat wut;
2334  wut.setSliding(sliding_);
2335  dataset[id] = wut;
2336  }
2337 
2338  // Insert the dataset
2339  ostringstream wtag;
2340  wtag.str("");
2341  wtag << "Sliding_" << sliding_;
2342  std::string justatag = wtag.str();
2343  ss << " sliding tag " << justatag << "\n";
2344  int iov_id = 0; // just a parameter ...
2345  if (m_write_sli == 1)
2346  sli_conf_id_ = db_->writeToConfDB_TPGSliding(dataset, iov_id, justatag);
2347  }
2348 
2350  // Compute LUT section //
2352 
2353  int lut_EB[1024], lut_EE[1024];
2354 
2355  // barrel
2356  computeLUT(lut_EB, "EB");
2357  if (writeToFiles_) {
2358  (*out_file_) << std::endl;
2359  (*out_file_) << "LUT 0" << std::endl;
2360  for (int i = 0; i < 1024; i++)
2361  (*out_file_) << "0x" << hex << lut_EB[i] << std::endl;
2362  (*out_file_) << std::endl;
2363  }
2364 
2365  // endcap
2366  computeLUT(lut_EE, "EE");
2367  // check first if lut_EB and lut_EE are the same
2368  bool newLUT(false);
2369  for (int i = 0; i < 1024; i++)
2370  if (lut_EE[i] != lut_EB[i])
2371  newLUT = true;
2372  if (newLUT && writeToFiles_) {
2373  (*out_file_) << std::endl;
2374  (*out_file_) << "LUT 1" << std::endl;
2375  for (int i = 0; i < 1024; i++)
2376  (*out_file_) << "0x" << hex << lut_EE[i] << std::endl;
2377  (*out_file_) << std::endl;
2378  }
2379 
2380  if (writeToDB_) {
2381  map<EcalLogicID, FEConfigLUTGroupDat> dataset;
2382  // we create 1 LUT group
2383  int NLUTGROUPS = 0;
2384  int ich = 0;
2385  FEConfigLUTGroupDat lut;
2386  lut.setLUTGroupId(ich);
2387  for (int i = 0; i < 1024; i++) {
2388  lut.setLUTValue(i, lut_EB[i]);
2389  }
2390  EcalLogicID ecid = EcalLogicID("DUMMY", ich, ich);
2391  // Fill the dataset
2392  dataset[ecid] = lut; // we use any logic id but different, because it is in any case ignored...
2393 
2394  ich++;
2395 
2396  FEConfigLUTGroupDat lute;
2397  lute.setLUTGroupId(ich);
2398  for (int i = 0; i < 1024; i++) {
2399  lute.setLUTValue(i, lut_EE[i]);
2400  }
2401  EcalLogicID ecide = EcalLogicID("DUMMY", ich, ich);
2402  // Fill the dataset
2403  dataset[ecide] = lute; // we use any logic id but different, because it is in any case ignored...
2404 
2405  ich++;
2406 
2407  NLUTGROUPS = ich;
2408 
2409  // now we store in the DB the correspondence btw channels and LUT groups
2410  map<EcalLogicID, FEConfigLUTDat> dataset2;
2411  // in this case I decide in a stupid way which channel belongs to which group
2412  for (auto& id : my_TTEcalLogicId) {
2413  FEConfigLUTDat lut;
2414  int igroup = 0;
2415  lut.setLUTGroupId(igroup);
2416  // calculate the right TT - in the vector they are ordered by SM and by TT
2417  // Fill the dataset
2418  dataset2[id] = lut;
2419  }
2420 
2421  // endcap loop
2422  for (auto& id : my_TTEcalLogicId_EE) {
2423  FEConfigLUTDat lut;
2424  int igroup = 1;
2425  lut.setLUTGroupId(igroup);
2426  // calculate the right TT
2427  // Fill the dataset
2428  dataset2[id] = lut;
2429  }
2430 
2431  // Insert the dataset
2432  ostringstream ltag;
2433  ltag.str("");
2434  ltag << LUT_option_ << "_NGroups_" << NLUTGROUPS;
2435  std::string lut_tag = ltag.str();
2436  ss << " LUT tag " << lut_tag << "\n";
2437  if (m_write_lut == 1)
2438  lut_conf_id_ = db_->writeToConfDB_TPGLUT(dataset, dataset2, lutparamset, NLUTGROUPS, lut_tag);
2439  }
2440 
2441  // last we insert the FE_CONFIG_MAIN table
2442  if (writeToDB_) {
2443  //int conf_id_=db_->writeToConfDB_TPGMain(ped_conf_id_,lin_conf_id_, lut_conf_id_, fgr_conf_id_,
2444  // sli_conf_id_, wei_conf_id_, bxt_conf_id_, btt_conf_id_, tag_, version_) ;
2445  int conf_id_ = db_->writeToConfDB_TPGMain(ped_conf_id_,
2446  lin_conf_id_,
2447  lut_conf_id_,
2448  fgr_conf_id_,
2449  sli_conf_id_,
2450  wei_conf_id_,
2451  wei2_conf_id_,
2452  spi_conf_id_,
2453  del_conf_id_,
2454  bxt_conf_id_,
2455  btt_conf_id_,
2456  bst_conf_id_,
2457  coke_conf_id_,
2458  tag_,
2459  version_); //modif-alex 21/01/11
2460 
2461  ss << "\n Conf ID = " << conf_id_ << "\n";
2462  }
2463 
2465  // loop on strips and associate them with values //
2467 
2468  // Barrel
2469  stripListEB.sort();
2470  stripListEB.unique();
2471  ss << "Number of EB strips=" << dec << stripListEB.size() << "\n";
2472  if (writeToFiles_) {
2473  (*out_file_) << std::endl;
2474  for (itList = stripListEB.begin(); itList != stripListEB.end(); itList++) {
2475  (*out_file_) << "STRIP_EB " << dec << (*itList) << std::endl;
2476  (*out_file_) << hex << "0x" << sliding_ << std::endl;
2477  (*out_file_) << hex << "0x" << weights_map_even[(*itList)] << " ";
2479  (*out_file_) << hex << "0x" << weights_map_odd[(*itList)] << std::endl;
2480  else
2481  (*out_file_) << "0x0" << std::endl;
2482  (*out_file_) << "0x" << stripMapEBsintheta[(*itList)] << " 0x" << SFGVB_lut_ << std::endl;
2483  }
2484  }
2485 
2486  // Endcap
2487  stripListEE.sort();
2488  stripListEE.unique();
2489  ss << "Number of EE strips=" << dec << stripListEE.size() << "\n";
2490  if (writeToFiles_) {
2491  (*out_file_) << std::endl;
2492  for (itList = stripListEE.begin(); itList != stripListEE.end(); itList++) {
2493  (*out_file_) << "STRIP_EE " << dec << (*itList) << std::endl;
2494  (*out_file_) << hex << "0x" << sliding_ << std::endl;
2495  (*out_file_) << hex << "0x" << weights_map_even[(*itList)] << " ";
2497  (*out_file_) << hex << "0x" << weights_map_odd[(*itList)] << std::endl;
2498  else
2499  (*out_file_) << "0x0" << std::endl;
2500  (*out_file_) << hex << "0x" << threshold << " 0x" << lut_strip << std::endl;
2501  }
2502  }
2503  edm::LogInfo("TopInfo") << ss.str();
2504  ss.str("");
2505 
2507  // loop on towers and associate them with default values //
2509 
2510  // Barrel
2511  towerListEB.sort();
2512  towerListEB.unique();
2513  ss << "Number of EB towers=" << dec << towerListEB.size() << "\n";
2514  if (writeToFiles_) {
2515  (*out_file_) << std::endl;
2516  for (itList = towerListEB.begin(); itList != towerListEB.end(); itList++) {
2517  (*out_file_) << "TOWER_EB " << dec << (*itList) << std::endl;
2518  (*out_file_) << " 0\n 0\n";
2519  (*out_file_) << " " << SFGVB_SpikeKillingThreshold_ << std::endl; //modif-alex
2520  }
2521  }
2522 
2523  // Endcap
2524  towerListEE.sort();
2525  towerListEE.unique();
2526  ss << "Number of EE towers=" << dec << towerListEE.size() << "\n";
2527  if (writeToFiles_) {
2528  (*out_file_) << std::endl;
2529  for (itList = towerListEE.begin(); itList != towerListEE.end(); itList++) {
2530  (*out_file_) << "TOWER_EE " << dec << (*itList) << std::endl;
2531  if (newLUT)
2532  (*out_file_) << " 1\n";
2533  else
2534  (*out_file_) << " 0\n";
2535  (*out_file_) << hex << "0x" << lut_tower << std::endl;
2536  }
2537  }
2538  edm::LogInfo("TopInfo") << ss.str();
2539  ss.str("");
2540 
2542  // store control histos //
2544  ICEB->Write();
2545  tpgFactorEB->Write();
2546  ICEEPlus->Write();
2547  tpgFactorEEPlus->Write();
2548  ICEEMinus->Write();
2549  tpgFactorEEMinus->Write();
2550  IC->Write();
2551  tpgFactor->Write();
2552  hshapeEB->Write();
2553  hshapeEE->Write();
2554  ntuple->Write();
2555  ntupleSpike->Write();
2556  saving.Close();
2557 }
2558 
2560  using namespace edm;
2561  using namespace std;
2562 
2563  edm::LogInfo("TopInfo") << "we are in beginJob\n";
2564 
2565  create_header();
2566 
2569 
2570  if (writeToFiles_) {
2571  (*out_file_) << "PHYSICS_EB " << dec << eb.rawId() << std::endl;
2572  (*out_file_) << Et_sat_EB_ << " " << TTF_lowThreshold_EB_ << " " << TTF_highThreshold_EB_ << std::endl;
2573  (*out_file_) << FG_lowThreshold_EB_ << " " << FG_highThreshold_EB_ << " " << FG_lowRatio_EB_ << " "
2574  << FG_highRatio_EB_ << std::endl;
2575  //(*out_file_) << SFGVB_SpikeKillingThreshold_ << std::endl; //modif-alex02/02/2011
2576  (*out_file_) << std::endl;
2577 
2578  (*out_file_) << "PHYSICS_EE " << dec << ee.rawId() << std::endl;
2579  (*out_file_) << Et_sat_EE_ << " " << TTF_lowThreshold_EE_ << " " << TTF_highThreshold_EE_ << std::endl;
2580  (*out_file_) << FG_Threshold_EE_ << " " << -1 << " " << -1 << " " << -1 << std::endl;
2581  (*out_file_) << std::endl;
2582  }
2583 }
2584 
2586  double theta, double gainRatio, double calibCoeff, std::string subdet, int& mult, int& shift) {
2587  /*
2588  Linearization coefficient are determined in order to satisfy:
2589  tpg(ADC_sat) = 1024
2590  where:
2591  tpg() is a model of the linearized tpg response on 10b
2592  ADC_sat is the number of ADC count corresponding the Et_sat, the maximum scale of the transverse energy
2593 
2594  Since we have:
2595  Et_sat = xtal_LSB * ADC_sat * gainRatio * calibCoeff * sin(theta)
2596  and a simple model of tpg() being given by:
2597  tpg(X) = [ (X*mult) >> (shift+2) ] >> (sliding+shiftDet)
2598  we must satisfy:
2599  [ (Et_sat/(xtal_LSB * gainRatio * calibCoeff * sin(theta)) * mult) >> (shift+2) ] >> (sliding+shiftDet) = 1024
2600  that is:
2601  mult = 1024/Et_sat * xtal_LSB * gainRatio * calibCoeff * sin(theta) * 2^-(sliding+shiftDet+2) * 2^-shift
2602  mult = factor * 2^-shift
2603  */
2604 
2605  // case barrel:
2606  int shiftDet = 2; //fixed, due to FE FENIX TCP format
2607  double ratio = xtal_LSB_EB_ / Et_sat_EB_;
2608  // case endcap:
2609  if (subdet == "EE") {
2610  shiftDet = 2; //applied in TCC-EE and not in FE FENIX TCP... This parameters is setable in the TCC-EE
2611  //shiftDet = 0 ; //was like this before with FE bug
2612  ratio = xtal_LSB_EE_ / Et_sat_EE_;
2613  }
2614 
2615  //modif-alex-30/01/2012
2616  //std::cout << "calibCoeff="<<calibCoeff<<endl;
2617 
2618  double factor = 1024 * ratio * gainRatio * calibCoeff * sin(theta) * (1 << (sliding_ + shiftDet + 2));
2619  // Let's try first with shift = 0 (trivial solution)
2620  mult = (int)(factor + 0.5);
2621  for (shift = 0; shift < 15; shift++) {
2622  if (mult >= 128 && mult < 256)
2623  return true;
2624  factor *= 2;
2625  mult = (int)(factor + 0.5);
2626  }
2627  edm::LogError("TopInfo") << "too bad we did not manage to calculate the factor for calib=" << calibCoeff << "\n";
2628  return false;
2629 }
2630 
2632  if (!writeToFiles_)
2633  return;
2634  (*out_file_) << "COMMENT put your comments here" << std::endl;
2635 
2636  (*out_file_) << "COMMENT =================================" << std::endl;
2637  (*out_file_) << "COMMENT physics EB structure" << std::endl;
2638  (*out_file_) << "COMMENT" << std::endl;
2639  (*out_file_) << "COMMENT EtSaturation (GeV), ttf_threshold_Low (GeV), ttf_threshold_High (GeV)" << std::endl;
2640  (*out_file_) << "COMMENT FG_lowThreshold (GeV), FG_highThreshold (GeV), FG_lowRatio, FG_highRatio" << std::endl;
2641  //(*out_file_) <<"COMMENT SFGVB_SpikeKillingThreshold (GeV)"<<std::endl ; //modif-alex-02/02/2011
2642  (*out_file_) << "COMMENT =================================" << std::endl;
2643  (*out_file_) << "COMMENT" << std::endl;
2644 
2645  (*out_file_) << "COMMENT =================================" << std::endl;
2646  (*out_file_) << "COMMENT physics EE structure" << std::endl;
2647  (*out_file_) << "COMMENT" << std::endl;
2648  (*out_file_) << "COMMENT EtSaturation (GeV), ttf_threshold_Low (GeV), ttf_threshold_High (GeV)" << std::endl;
2649  (*out_file_) << "COMMENT FG_Threshold (GeV), dummy, dummy, dummy" << std::endl;
2650  (*out_file_) << "COMMENT =================================" << std::endl;
2651  (*out_file_) << "COMMENT" << std::endl;
2652 
2653  (*out_file_) << "COMMENT =================================" << std::endl;
2654  (*out_file_) << "COMMENT crystal structure (same for EB and EE)" << std::endl;
2655  (*out_file_) << "COMMENT" << std::endl;
2656  (*out_file_) << "COMMENT ped, mult, shift [gain12]" << std::endl;
2657  (*out_file_) << "COMMENT ped, mult, shift [gain6]" << std::endl;
2658  (*out_file_) << "COMMENT ped, mult, shift [gain1]" << std::endl;
2659  (*out_file_) << "COMMENT =================================" << std::endl;
2660  (*out_file_) << "COMMENT" << std::endl;
2661 
2662  (*out_file_) << "COMMENT =================================" << std::endl;
2663  (*out_file_) << "COMMENT strip EB structure" << std::endl;
2664  (*out_file_) << "COMMENT" << std::endl;
2665  (*out_file_) << "COMMENT sliding_window" << std::endl;
2666  (*out_file_) << "COMMENT even_weightGroupId odd_weightGroupId" << std::endl;
2667  (*out_file_) << "COMMENT threshold_sfg lut_sfg" << std::endl;
2668  (*out_file_) << "COMMENT =================================" << std::endl;
2669  (*out_file_) << "COMMENT" << std::endl;
2670 
2671  (*out_file_) << "COMMENT =================================" << std::endl;
2672  (*out_file_) << "COMMENT strip EE structure" << std::endl;
2673  (*out_file_) << "COMMENT" << std::endl;
2674  (*out_file_) << "COMMENT sliding_window" << std::endl;
2675  (*out_file_) << "COMMENT even_weightGroupId odd_weightGroupId" << std::endl;
2676  (*out_file_) << "COMMENT threshold_fg lut_fg" << std::endl;
2677  (*out_file_) << "COMMENT =================================" << std::endl;
2678  (*out_file_) << "COMMENT" << std::endl;
2679 
2680  (*out_file_) << "COMMENT =================================" << std::endl;
2681  (*out_file_) << "COMMENT tower EB structure" << std::endl;
2682  (*out_file_) << "COMMENT" << std::endl;
2683  (*out_file_) << "COMMENT LUTGroupId" << std::endl;
2684  (*out_file_) << "COMMENT FgGroupId" << std::endl;
2685  (*out_file_) << "COMMENT spike_killing_threshold" << std::endl; //modif alex
2686  (*out_file_) << "COMMENT =================================" << std::endl;
2687  (*out_file_) << "COMMENT" << std::endl;
2688 
2689  (*out_file_) << "COMMENT =================================" << std::endl;
2690  (*out_file_) << "COMMENT tower EE structure" << std::endl;
2691  (*out_file_) << "COMMENT" << std::endl;
2692  (*out_file_) << "COMMENT LUTGroupId" << std::endl;
2693  (*out_file_) << "COMMENT tower_lut_fg" << std::endl;
2694  (*out_file_) << "COMMENT =================================" << std::endl;
2695  (*out_file_) << "COMMENT" << std::endl;
2696 
2697  (*out_file_) << "COMMENT =================================" << std::endl;
2698  (*out_file_) << "COMMENT Even Weight structure" << std::endl;
2699  (*out_file_) << "COMMENT" << std::endl;
2700  (*out_file_) << "COMMENT Weight even" << std::endl;
2701  (*out_file_) << "COMMENT weightGroupId" << std::endl;
2702  (*out_file_) << "COMMENT w0, w1, w2, w3, w4" << std::endl;
2703  (*out_file_) << "COMMENT =================================" << std::endl;
2704  (*out_file_) << "COMMENT" << std::endl;
2705 
2706  (*out_file_) << "COMMENT =================================" << std::endl;
2707  (*out_file_) << "COMMENT Odd Weight structure" << std::endl;
2708  (*out_file_) << "COMMENT" << std::endl;
2709  (*out_file_) << "COMMENT Weight odd" << std::endl;
2710  (*out_file_) << "COMMENT weightGroupId" << std::endl;
2711  (*out_file_) << "COMMENT w0, w1, w2, w3, w4" << std::endl;
2712  (*out_file_) << "COMMENT =================================" << std::endl;
2713  (*out_file_) << "COMMENT" << std::endl;
2714 
2715  (*out_file_) << "COMMENT =================================" << std::endl;
2716  (*out_file_) << "COMMENT TP mode" << std::endl;
2717  (*out_file_) << "COMMENT EnableEBOddFilter" << std::endl;
2718  (*out_file_) << "COMMENT EnableEEOddFilter" << std::endl;
2719  (*out_file_) << "COMMENT EnableEBOddPeakFinder" << std::endl;
2720  (*out_file_) << "COMMENT EnableEEOddPeakFinder" << std::endl;
2721  (*out_file_) << "COMMENT DisableEBEvenPeakFinder" << std::endl;
2722  (*out_file_) << "COMMENT DisableEEEvenPeakFinder" << std::endl;
2723  (*out_file_) << "COMMENT FenixEBStripOutput" << std::endl;
2724  (*out_file_) << "COMMENT FenixEEStripOutput" << std::endl;
2725  (*out_file_) << "COMMENT FenixEBStripInfobit2" << std::endl;
2726  (*out_file_) << "COMMENT FenixEEStripInfobit2" << std::endl;
2727  (*out_file_) << "COMMENT EBFenixTcpOutput" << std::endl;
2728  (*out_file_) << "COMMENT EBFenixTcpInfobit1" << std::endl;
2729  (*out_file_) << "COMMENT EEFenixTcpOutput" << std::endl;
2730  (*out_file_) << "COMMENT EEFenixTcpInfobit1" << std::endl;
2731  (*out_file_) << "COMMENT FenixPar15" << std::endl;
2732  (*out_file_) << "COMMENT FenixPar16" << std::endl;
2733  (*out_file_) << "COMMENT FenixPar17" << std::endl;
2734  (*out_file_) << "COMMENT FenixPar18" << std::endl;
2735  (*out_file_) << "COMMENT =================================" << std::endl;
2736  (*out_file_) << "COMMENT" << std::endl;
2737 
2738  (*out_file_) << "COMMENT =================================" << std::endl;
2739  (*out_file_) << "COMMENT lut structure" << std::endl;
2740  (*out_file_) << "COMMENT" << std::endl;
2741  (*out_file_) << "COMMENT LUTGroupId" << std::endl;
2742  (*out_file_) << "COMMENT LUT[1-1024]" << std::endl;
2743  (*out_file_) << "COMMENT =================================" << std::endl;
2744  (*out_file_) << "COMMENT" << std::endl;
2745 
2746  (*out_file_) << "COMMENT =================================" << std::endl;
2747  (*out_file_) << "COMMENT fg EB structure" << std::endl;
2748  (*out_file_) << "COMMENT" << std::endl;
2749  (*out_file_) << "COMMENT FgGroupId" << std::endl;
2750  (*out_file_) << "COMMENT el, eh, tl, th, lut_fg" << std::endl;
2751  (*out_file_) << "COMMENT =================================" << std::endl;
2752  (*out_file_) << "COMMENT" << std::endl;
2753 }
2754 
2755 int EcalTPGParamBuilder::uncodeWeight(double weight, int complement2) {
2756  int iweight;
2757  unsigned int max = (unsigned int)(pow(2., complement2) - 1);
2758  if (weight > 0)
2759  iweight = int((1 << 6) * weight + 0.5); // +0.5 for rounding pb
2760  else
2761  iweight = max - int(-weight * (1 << 6) + 0.5) + 1;
2762  iweight = iweight & max;
2763  return iweight;
2764 }
2765 
2766 double EcalTPGParamBuilder::uncodeWeight(int iweight, int complement2) {
2767  double weight = double(iweight) / pow(2., 6.);
2768  // test if negative weight:
2769  if ((iweight & (1 << (complement2 - 1))) != 0)
2770  weight = (double(iweight) - pow(2., complement2)) / pow(2., 6.);
2771  return weight;
2772 }
2773 
2774 std::vector<unsigned int> EcalTPGParamBuilder::computeWeights(EcalShapeBase& shape, TH1F* histo) {
2775  std::ostringstream ss;
2776  ss << "Computing Weights...\n";
2777  double timeMax = shape.timeOfMax() - shape.timeOfThr(); // timeMax w.r.t begining of pulse
2778  double max = shape(timeMax);
2779 
2780  double sumf = 0.;
2781  double sumf2 = 0.;
2782  for (unsigned int sample = 0; sample < nSample_; sample++) {
2783  double time = timeMax - ((double)sampleMax_ - (double)sample) * 25.;
2785  sumf += shape(time) / max;
2786  sumf2 += shape(time) / max * shape(time) / max;
2787  for (int subtime = 0; subtime < 25; subtime++)
2788  histo->Fill(float(sample * 25. + subtime) / 25., shape(time + subtime));
2789  }
2790  double lambda = 1. / (sumf2 - sumf * sumf / nSample_);
2791  double gamma = -lambda * sumf / nSample_;
2792  double* weight = new double[nSample_];
2793  for (unsigned int sample = 0; sample < nSample_; sample++) {
2794  double time = timeMax - ((double)sampleMax_ - (double)sample) * 25.;
2796  weight[sample] = lambda * shape(time) / max + gamma;
2797  }
2798 
2799  int* iweight = new int[nSample_];
2800  for (unsigned int sample = 0; sample < nSample_; sample++)
2802 
2803  // Let's check:
2804  int isumw = 0;
2805  for (unsigned int sample = 0; sample < nSample_; sample++)
2806  isumw += iweight[sample];
2807  unsigned int imax = (unsigned int)(pow(2., int(complement2_)) - 1);
2808  isumw = (isumw & imax);
2809 
2810  double ampl = 0.;
2811  double sumw = 0.;
2812  for (unsigned int sample = 0; sample < nSample_; sample++) {
2813  double time = timeMax - ((double)sampleMax_ - (double)sample) * 25.;
2815  ampl += weight[sample] * shape(time);
2816  sumw += weight[sample];
2817  ss << "weight=" << weight[sample] << " shape=" << shape(time) << "\n";
2818  }
2819  ss << "Weights: sum=" << isumw << " in float =" << uncodeWeight(isumw, complement2_) << " sum of floats =" << sumw
2820  << "\n";
2821  ss << "Weights: sum (weight*shape) = " << ampl << "\n";
2822 
2823  // Let's correct for bias if any
2825  int count = 0;
2826  while (isumw != 0 && count < 10) {
2827  double min = 99.;
2828  unsigned int index = 0;
2829  if ((isumw & (1 << (complement2_ - 1))) != 0) {
2830  // add 1:
2831  ss << "Correcting for bias: adding 1\n";
2832  for (unsigned int sample = 0; sample < nSample_; sample++) {
2833  int new_iweight = iweight[sample] + 1;
2834  double new_weight = uncodeWeight(new_iweight, complement2_);
2835  if (fabs(new_weight - weight[sample]) < min) {
2836  min = fabs(new_weight - weight[sample]);
2837  index = sample;
2838  }
2839  }
2840  iweight[index]++;
2841  } else {
2842  // Sub 1:
2843  ss << "Correcting for bias: subtracting 1\n";
2844  for (unsigned int sample = 0; sample < nSample_; sample++) {
2845  int new_iweight = iweight[sample] - 1;
2846  double new_weight = uncodeWeight(new_iweight, complement2_);
2847  if (fabs(new_weight - weight[sample]) < min) {
2848  min = fabs(new_weight - weight[sample]);
2849  index = sample;
2850  }
2851  }
2852  iweight[index]--;
2853  }
2854  isumw = 0;
2855  for (unsigned int sample = 0; sample < nSample_; sample++)
2856  isumw += iweight[sample];
2857  imax = (unsigned int)(pow(2., int(complement2_)) - 1);
2858  isumw = (isumw & imax);
2859  ss << "Correcting weight number: " << index << " sum weights = " << isumw << "\n";
2860  count++;
2861  }
2862  }
2863 
2864  // let's check again
2865  isumw = 0;
2866  for (unsigned int sample = 0; sample < nSample_; sample++)
2867  isumw += iweight[sample];
2868  imax = (unsigned int)(pow(2., int(complement2_)) - 1);
2869  isumw = (isumw & imax);
2870  ampl = 0.;
2871  for (unsigned int sample = 0; sample < nSample_; sample++) {
2872  double time = timeMax - ((double)sampleMax_ - (double)sample) * 25.;
2874  double new_weight = uncodeWeight(iweight[sample], complement2_);
2875  sumw += uncodeWeight(iweight[sample], complement2_);
2876  ampl += new_weight * shape(time);
2877  ss << "weight unbiased after integer conversion=" << new_weight << " shape=" << shape(time) << "\n";
2878  }
2879  ss << "Weights: sum=" << isumw << " in float =" << uncodeWeight(isumw, complement2_) << " sum of floats =" << sumw
2880  << "\n";
2881  ss << "Weights: sum (weight*shape) = " << ampl << "\n";
2882  edm::LogInfo("TopInfo") << ss.str();
2883 
2884  std::vector<unsigned int> theWeights;
2885  for (unsigned int sample = 0; sample < nSample_; sample++)
2886  theWeights.push_back(iweight[sample]);
2887 
2888  delete[] weight;
2889  delete[] iweight;
2890  return theWeights;
2891 }
2892 
2894  double Et_sat = Et_sat_EB_;
2895  double LUT_threshold = LUT_threshold_EB_;
2896  double LUT_stochastic = LUT_stochastic_EB_;
2897  double LUT_noise = LUT_noise_EB_;
2898  double LUT_constant = LUT_constant_EB_;
2899  double TTF_lowThreshold = TTF_lowThreshold_EB_;
2900  double TTF_highThreshold = TTF_highThreshold_EB_;
2901  if (det == "EE") {
2902  Et_sat = Et_sat_EE_;
2903  LUT_threshold = LUT_threshold_EE_;
2904  LUT_stochastic = LUT_stochastic_EE_;
2905  LUT_noise = LUT_noise_EE_;
2906  LUT_constant = LUT_constant_EE_;
2907  TTF_lowThreshold = TTF_lowThreshold_EE_;
2908  TTF_highThreshold = TTF_highThreshold_EE_;
2909  }
2910 
2911  // initialisation with identity
2912  for (int i = 0; i < 1024; i++) {
2913  lut[i] = i;
2914  if (lut[i] > 0xff)
2915  lut[i] = 0xff;
2916  }
2917 
2918  // case linear LUT
2919  if (LUT_option_ == "Linear") {
2920  int mylut = 0;
2921  for (int i = 0; i < 1024; i++) {
2922  lut[i] = mylut;
2923  if ((i + 1) % 4 == 0)
2924  mylut++;
2925  //if ((i+1)%8 == 0 ) mylut++ ;//modif-alex 16/12/2010 LSB==500MeV ONLY USED FOR BEAMV4 key
2926  }
2927  }
2928 
2929  // case LUT following Ecal resolution
2930  if (LUT_option_ == "EcalResolution") {
2931  TF1* func = new TF1("func", oneOverEtResolEt, 0., Et_sat, 3);
2932  func->SetParameters(LUT_stochastic, LUT_noise, LUT_constant);
2933  double norm = func->Integral(0., Et_sat);
2934  for (int i = 0; i < 1024; i++) {
2935  double Et = i * Et_sat / 1024.;
2936  lut[i] = int(0xff * func->Integral(0., Et) / norm + 0.5);
2937  }
2938  }
2939 
2940  // Now, add TTF thresholds to LUT and apply LUT threshold if needed
2941  for (int j = 0; j < 1024; j++) {
2942  double Et_GeV = Et_sat / 1024 * (j + 0.5);
2943  if (Et_GeV <= LUT_threshold)
2944  lut[j] = 0; // LUT threshold
2945  int ttf = 0x0;
2946  if (Et_GeV >= TTF_highThreshold)
2947  ttf = 3;
2948  if (Et_GeV >= TTF_lowThreshold && Et_GeV < TTF_highThreshold)
2949  ttf = 1;
2950  ttf = ttf << 8;
2951  lut[j] += ttf;
2952  }
2953 }
2954 
2956  const EcalIntercalibConstantMap& calibMap,
2957  const EcalLaserAlphaMap& laserAlphaMap,
2958  uint rawId,
2959  std::string& st) {
2960  // get current intercalibration coeff
2961  coeff.calibCoeff_ = 1.;
2962  if (!useInterCalibration_)
2963  return;
2965 
2966  //modif-alex-30/01/2012
2967  std::map<int, double>::const_iterator itCorr = Transparency_Correction_.find(rawId);
2968  double icorr = 1.0;
2969  double alpha_factor = 1.0;
2970 
2971  if (useTransparencyCorr_) {
2972  icorr = itCorr->second;
2973  if (itCorr != Transparency_Correction_.end()) {
2974  stringstream ss;
2975  ss << rawId;
2976  stringstream ss1;
2977  ss1 << icorr;
2978  stringstream ss2;
2979  ss2 << (*icalit);
2980  st = "Transparency correction found for xtal " + ss.str() + " corr=" + ss1.str() + " intercalib=" + ss2.str() +
2981  "\n";
2982  } else
2983  edm::LogError("TopInfo") << "ERROR = Transparency correction not found for xtal " << rawId << "\n";
2984 
2985  //modif-alex-27-july-2015
2986  DetId ECALdetid(rawId);
2987  // ss << "DETID=" << ECALdetid.subdetId() << "\n";
2988  stringstream ss;
2989  ss << ECALdetid.subdetId();
2990  st += "DETID=" + ss.str() + "\n";
2991  if (ECALdetid.subdetId() == 1) { //ECAL BARREL
2992  EBDetId barrel_detid(rawId);
2993  EcalLaserAlphaMap::const_iterator italpha = laserAlphaMap.find(barrel_detid);
2994  if (italpha != laserAlphaMap.end())
2995  alpha_factor = (*italpha);
2996  else
2997  edm::LogError("TopInfo") << "ERROR:LaserAlphe parameter note found!!"
2998  << "\n";
2999  }
3000  if (ECALdetid.subdetId() == 2) { //ECAL ENDCAP
3001  EEDetId endcap_detid(rawId);
3002  EcalLaserAlphaMap::const_iterator italpha = laserAlphaMap.find(endcap_detid);
3003  if (italpha != laserAlphaMap.end())
3004  alpha_factor = (*italpha);
3005  else
3006  edm::LogError("TopInfo") << "ERROR:LaserAlphe parameter note found!!"
3007  << "\n";
3008  }
3009 
3010  } //transparency corrections applied
3011 
3012  //if( icalit != calibMap.end() ) coeff.calibCoeff_ = (*icalit) ;
3013  //if( icalit != calibMap.end() ) coeff.calibCoeff_ = (*icalit)/icorr; //modif-alex-30/01/2010 tansparency corrections
3014  // ss << "rawId " << (*icalit) << " " << icorr << " " << alpha_factor << "\n";
3015  stringstream ss;
3016  ss << (*icalit);
3017  stringstream ss1;
3018  ss1 << icorr;
3019  stringstream ss2;
3020  ss2 << alpha_factor;
3021  st += "rawId " + ss.str() + " " + ss1.str() + " " + ss2.str() + "\n";
3022  if (icalit != calibMap.end())
3023  coeff.calibCoeff_ =
3024  (*icalit) /
3025  std::pow(icorr, alpha_factor); //modif-alex-27/07/2015 tansparency corrections with alpha parameters
3026 
3027  else
3028  edm::LogError("TopInfo") << "getCoeff: " << rawId << " not found in EcalIntercalibConstantMap"
3029  << "\n";
3030 }
3031 
3032 void EcalTPGParamBuilder::getCoeff(coeffStruc& coeff, const EcalGainRatioMap& gainMap, unsigned int rawId) {
3033  // get current gain ratio
3034  coeff.gainRatio_[0] = 1.;
3035  coeff.gainRatio_[1] = 2.;
3036  coeff.gainRatio_[2] = 12.;
3037  EcalGainRatioMap::const_iterator gainIter = gainMap.find(rawId);
3038  if (gainIter != gainMap.end()) {
3039  const EcalMGPAGainRatio& aGain = (*gainIter);
3040  coeff.gainRatio_[1] = aGain.gain12Over6();
3041  coeff.gainRatio_[2] = aGain.gain6Over1() * aGain.gain12Over6();
3042  } else
3043  edm::LogError("TopInfo") << "getCoeff: " << rawId << " not found in EcalGainRatioMap"
3044  << "\n";
3045 }
3046 
3047 void EcalTPGParamBuilder::getCoeff(coeffStruc& coeff, const EcalPedestalsMap& pedMap, unsigned int rawId) {
3048  coeff.pedestals_[0] = 0;
3049  coeff.pedestals_[1] = 0;
3050  coeff.pedestals_[2] = 0;
3051 
3052  if (forcedPedestalValue_ >= 0) {
3053  coeff.pedestals_[0] = forcedPedestalValue_;
3054  coeff.pedestals_[1] = forcedPedestalValue_;
3055  coeff.pedestals_[2] = forcedPedestalValue_;
3056  return;
3057  }
3058 
3059  // get current pedestal
3060  EcalPedestalsMapIterator pedIter = pedMap.find(rawId);
3061  if (pedIter != pedMap.end()) {
3062  EcalPedestals::Item aped = (*pedIter);
3063  coeff.pedestals_[0] = int(aped.mean_x12 + 0.5);
3064  coeff.pedestals_[1] = int(aped.mean_x6 + 0.5);
3065  coeff.pedestals_[2] = int(aped.mean_x1 + 0.5);
3066  } else
3067  edm::LogError("TopInfo") << "getCoeff: " << rawId << " not found in EcalPedestalsMap\n";
3068 }
3069 
3071  const map<EcalLogicID, MonPedestalsDat>& pedMap,
3072  const EcalLogicID& logicId) {
3073  // get current pedestal
3074  coeff.pedestals_[0] = 0;
3075  coeff.pedestals_[1] = 0;
3076  coeff.pedestals_[2] = 0;
3077 
3078  map<EcalLogicID, MonPedestalsDat>::const_iterator it = pedMap.find(logicId);
3079  if (it != pedMap.end()) {
3080  MonPedestalsDat ped = it->second;
3081  coeff.pedestals_[0] = int(ped.getPedMeanG12() + 0.5);
3082  coeff.pedestals_[1] = int(ped.getPedMeanG6() + 0.5);
3083  coeff.pedestals_[2] = int(ped.getPedMeanG1() + 0.5);
3084  } else
3085  edm::LogError("TopInfo") << "getCoeff: " << logicId.getID1() << ", " << logicId.getID2() << ", " << logicId.getID3()
3086  << " not found in map<EcalLogicID, MonPedestalsDat\n";
3087 }
3088 
3090  unsigned int& highRatio,
3091  unsigned int& lowThreshold,
3092  unsigned int& highThreshold,
3093  unsigned int& lut) {
3094  lowRatio = int(0x80 * FG_lowRatio_EB_ + 0.5);
3095  if (lowRatio > 0x7f)
3096  lowRatio = 0x7f;
3097  highRatio = int(0x80 * FG_highRatio_EB_ + 0.5);
3098  if (highRatio > 0x7f)
3099  highRatio = 0x7f;
3100 
3101  // lsb at the stage of the FG calculation is:
3102  double lsb_FG = Et_sat_EB_ / 1024. / 4;
3103  lowThreshold = int(FG_lowThreshold_EB_ / lsb_FG + 0.5);
3104  if (lowThreshold > 0xff)
3105  lowThreshold = 0xff;
3106  highThreshold = int(FG_highThreshold_EB_ / lsb_FG + 0.5);
3107  if (highThreshold > 0xff)
3108  highThreshold = 0xff;
3109 
3110  // FG lut: FGVB response is LUT(adress) where adress is:
3111  // bit3: maxof2/ET >= lowRatio, bit2: maxof2/ET >= highRatio, bit1: ET >= lowThreshold, bit0: ET >= highThreshold
3112  // FGVB =1 if jet-like (veto active), =0 if E.M.-like
3113  // the condition for jet-like is: ET>Threshold and maxof2/ET < Ratio (only TT with enough energy are vetoed)
3114 
3115  // With the following lut, what matters is only max(TLow, Thigh) and max(Elow, Ehigh)
3116  // So, jet-like if maxof2/ettot<max(TLow, Thigh) && ettot >= max(Elow, Ehigh)
3117  if (FG_lut_EB_ == 0)
3118  lut = 0x0888;
3119  else
3120  lut = FG_lut_EB_; // let's use the users value (hope he/she knows what he/she does!)
3121 }
3122 
3124  unsigned int& lut_strip,
3125  unsigned int& lut_tower) {
3126  // lsb for EE:
3127  double lsb_FG = Et_sat_EE_ / 1024.; // FIXME is it true????
3128  threshold = int(FG_Threshold_EE_ / lsb_FG + 0.5);
3129  lut_strip = FG_lut_strip_EE_;
3130  lut_tower = FG_lut_tower_EE_;
3131 }
3132 
3133 bool EcalTPGParamBuilder::realignBaseline(linStruc& lin, float forceBase12, int cmsswid) {
3134  bool ok(true);
3135  float base[3] = {forceBase12, float(lin.pedestal_[1]), float(lin.pedestal_[2])};
3136  for (int i = 1; i < 3; i++) {
3137  if (lin.mult_[i] > 0) {
3138  base[i] = float(lin.pedestal_[i]) - float(lin.mult_[0]) / float(lin.mult_[i]) *
3139  pow(2., -(lin.shift_[0] - lin.shift_[i])) * (lin.pedestal_[0] - base[0]);
3140  } else
3141  base[i] = 0;
3142  }
3143  for (int i = 0; i < 3; i++) {
3144  if (base[i] < 0) {
3145  edm::LogError("TopInfo") << "PROBLEM in realignBaseline: xtal=" << cmsswid << " base= " << base[i] << ", "
3146  << lin.pedestal_[i] << " for gainId[0-2]=" << i << " ==> smaller than 0 ==> set to 0"
3147  << " mult12:" << lin.mult_[0] << " mult:" << lin.mult_[i]
3148  << " ped12:" << lin.pedestal_[0] << " ped:" << lin.pedestal_[i] << " base12:" << base[0]
3149  << " shift12:" << lin.shift_[0] << " shift: " << lin.shift_[i] << "\n";
3150  lin.pedestal_[i] = 0;
3151  ok = false;
3152  } else if (base[i] > 1024) {
3153  edm::LogError("TopInfo") << "PROBLEM in realignBaseline: xtal=" << cmsswid << " base= " << base[i] << ", "
3154  << lin.pedestal_[i] << " for gainId[0-2]=" << i
3155  << " ==> larger than 1024 ==> set to 1024"
3156  << " mult12:" << lin.mult_[0] << " mult:" << lin.mult_[i]
3157  << " ped12:" << lin.pedestal_[0] << " ped:" << lin.pedestal_[i] << " base12:" << base[0]
3158  << " shift12:" << lin.shift_[0] << " shift: " << lin.shift_[i] << "\n";
3159  lin.pedestal_[i] = 1024;
3160  ok = false;
3161  } else {
3162  lin.pedestal_[i] = base[i];
3163  }
3164  }
3165  return ok;
3166 }
3167 
3169  int gctphi = 0;
3170  gctphi = (ttphi + 1) / 4;
3171  if (ttphi <= 2)
3172  gctphi = 0;
3173  if (ttphi >= 71)
3174  gctphi = 0;
3175  return gctphi;
3176 }
3177 
3179  int gcteta = 0;
3180  if (tteta > 0)
3181  gcteta = (tteta - 1) / 4 + 11;
3182  else if (tteta < 0)
3183  gcteta = (tteta + 1) / 4 + 10;
3184  return gcteta;
3185 }
3186 
3188  std::stringstream sdet;
3189 
3190  if (tcc > 36 && tcc < 55)
3191  sdet << "EB-" << tcc - 36;
3192  else if (tcc >= 55 && tcc < 73)
3193  sdet << "EB+" << tcc - 54;
3194  else if (tcc <= 36)
3195  sdet << "EE-";
3196  else
3197  sdet << "EE+";
3198 
3199  if (tcc <= 36 || tcc >= 73) {
3200  if (tcc >= 73)
3201  tcc -= 72;
3202  if (tcc == 1 || tcc == 18 || tcc == 19 || tcc == 36)
3203  sdet << 7;
3204  else if (tcc == 2 || tcc == 3 || tcc == 20 || tcc == 21)
3205  sdet << 8;
3206  else if (tcc == 4 || tcc == 5 || tcc == 22 || tcc == 23)
3207  sdet << 9;
3208  else if (tcc == 6 || tcc == 7 || tcc == 24 || tcc == 25)
3209  sdet << 1;
3210  else if (tcc == 8 || tcc == 9 || tcc == 26 || tcc == 27)
3211  sdet << 2;
3212  else if (tcc == 10 || tcc == 11 || tcc == 28 || tcc == 29)
3213  sdet << 3;
3214  else if (tcc == 12 || tcc == 13 || tcc == 30 || tcc == 31)
3215  sdet << 4;
3216  else if (tcc == 14 || tcc == 15 || tcc == 32 || tcc == 33)
3217  sdet << 5;
3218  else if (tcc == 16 || tcc == 17 || tcc == 34 || tcc == 35)
3219  sdet << 6;
3220  }
3221 
3222  return sdet.str();
3223 }
3224 
3225 std::pair<std::string, int> EcalTPGParamBuilder::getCrate(int tcc) {
3226  std::stringstream crate;
3227  std::string pos;
3228  int slot = 0;
3229 
3230  crate << "S2D";
3231  if (tcc >= 40 && tcc <= 42) {
3232  crate << "02d";
3233  slot = 5 + (tcc - 40) * 6;
3234  }
3235  if (tcc >= 43 && tcc <= 45) {
3236  crate << "03d";
3237  slot = 5 + (tcc - 43) * 6;
3238  }
3239  if (tcc >= 37 && tcc <= 39) {
3240  crate << "04d";
3241  slot = 5 + (tcc - 37) * 6;
3242  }
3243  if (tcc >= 52 && tcc <= 54) {
3244  crate << "06d";
3245  slot = 5 + (tcc - 52) * 6;
3246  }
3247  if (tcc >= 46 && tcc <= 48) {
3248  crate << "07d";
3249  slot = 5 + (tcc - 46) * 6;
3250  }
3251  if (tcc >= 49 && tcc <= 51) {
3252  crate << "08d";
3253  slot = 5 + (tcc - 49) * 6;
3254  }
3255  if (tcc >= 58 && tcc <= 60) {
3256  crate << "02h";
3257  slot = 5 + (tcc - 58) * 6;
3258  }
3259  if (tcc >= 61 && tcc <= 63) {
3260  crate << "03h";
3261  slot = 5 + (tcc - 61) * 6;
3262  }
3263  if (tcc >= 55 && tcc <= 57) {
3264  crate << "04h";
3265  slot = 5 + (tcc - 55) * 6;
3266  }
3267  if (tcc >= 70 && tcc <= 72) {
3268  crate << "06h";
3269  slot = 5 + (tcc - 70) * 6;
3270  }
3271  if (tcc >= 64 && tcc <= 66) {
3272  crate << "07h";
3273  slot = 5 + (tcc - 64) * 6;
3274  }
3275  if (tcc >= 67 && tcc <= 69) {
3276  crate << "08h";
3277  slot = 5 + (tcc - 67) * 6;
3278  }
3279 
3280  if (tcc >= 76 && tcc <= 81) {
3281  crate << "02l";
3282  if (tcc % 2 == 0)
3283  slot = 2 + (tcc - 76) * 3;
3284  else
3285  slot = 4 + (tcc - 77) * 3;
3286  }
3287  if (tcc >= 94 && tcc <= 99) {
3288  crate << "02l";
3289  if (tcc % 2 == 0)
3290  slot = 3 + (tcc - 94) * 3;
3291  else
3292  slot = 5 + (tcc - 95) * 3;
3293  }
3294 
3295  if (tcc >= 22 && tcc <= 27) {
3296  crate << "03l";
3297  if (tcc % 2 == 0)
3298  slot = 2 + (tcc - 22) * 3;
3299  else
3300  slot = 4 + (tcc - 23) * 3;
3301  }
3302  if (tcc >= 4 && tcc <= 9) {
3303  crate << "03l";
3304  if (tcc % 2 == 0)
3305  slot = 3 + (tcc - 4) * 3;
3306  else
3307  slot = 5 + (tcc - 5) * 3;
3308  }
3309 
3310  if (tcc >= 82 && tcc <= 87) {
3311  crate << "07l";
3312  if (tcc % 2 == 0)
3313  slot = 2 + (tcc - 82) * 3;
3314  else
3315  slot = 4 + (tcc - 83) * 3;
3316  }
3317  if (tcc >= 100 && tcc <= 105) {
3318  crate << "07l";
3319  if (tcc % 2 == 0)
3320  slot = 3 + (tcc - 100) * 3;
3321  else
3322  slot = 5 + (tcc - 101) * 3;
3323  }
3324 
3325  if (tcc >= 28 && tcc <= 33) {
3326  crate << "08l";
3327  if (tcc % 2 == 0)
3328  slot = 2 + (tcc - 28) * 3;
3329  else
3330  slot = 4 + (tcc - 29) * 3;
3331  }
3332  if (tcc >= 10 && tcc <= 15) {
3333  crate << "08l";
3334  if (tcc % 2 == 0)
3335  slot = 3 + (tcc - 10) * 3;
3336  else
3337  slot = 5 + (tcc - 11) * 3;
3338  }
3339 
3340  if (tcc == 34) {
3341  crate << "04l";
3342  slot = 2;
3343  }
3344  if (tcc == 16) {
3345  crate << "04l";
3346  slot = 3;
3347  }
3348  if (tcc == 35) {
3349  crate << "04l";
3350  slot = 4;
3351  }
3352  if (tcc == 17) {
3353  crate << "04l";
3354  slot = 5;
3355  }
3356  if (tcc == 36) {
3357  crate << "04l";
3358  slot = 8;
3359  }
3360  if (tcc == 18) {
3361  crate << "04l";
3362  slot = 9;
3363  }
3364  if (tcc == 19) {
3365  crate << "04l";
3366  slot = 10;
3367  }
3368  if (tcc == 1) {
3369  crate << "04l";
3370  slot = 11;
3371  }
3372  if (tcc == 20) {
3373  crate << "04l";
3374  slot = 14;
3375  }
3376  if (tcc == 2) {
3377  crate << "04l";
3378  slot = 15;
3379  }
3380  if (tcc == 21) {
3381  crate << "04l";
3382  slot = 16;
3383  }
3384  if (tcc == 3) {
3385  crate << "04l";
3386  slot = 17;
3387  }
3388 
3389  if (tcc == 88) {
3390  crate << "06l";
3391  slot = 2;
3392  }
3393  if (tcc == 106) {
3394  crate << "06l";
3395  slot = 3;
3396  }
3397  if (tcc == 89) {
3398  crate << "06l";
3399  slot = 4;
3400  }
3401  if (tcc == 107) {
3402  crate << "06l";
3403  slot = 5;
3404  }
3405  if (tcc == 90) {
3406  crate << "06l";
3407  slot = 8;
3408  }
3409  if (tcc == 108) {
3410  crate << "06l";
3411  slot = 9;
3412  }
3413  if (tcc == 73) {
3414  crate << "06l";
3415  slot = 10;
3416  }
3417  if (tcc == 91) {
3418  crate << "06l";
3419  slot = 11;
3420  }
3421  if (tcc == 74) {
3422  crate << "06l";
3423  slot = 14;
3424  }
3425  if (tcc == 92) {
3426  crate << "06l";
3427  slot = 15;
3428  }
3429  if (tcc == 75) {
3430  crate << "06l";
3431  slot = 16;
3432  }
3433  if (tcc == 93) {
3434  crate << "06l";
3435  slot = 17;
3436  }
3437 
3438  return std::pair<std::string, int>(crate.str(), slot);
3439 }
size
Write out results.
unsigned int TPmode_FenixEBStripOutput_
const EcalLaserAPDPNRatiosMap & getLaserMap() const
std::string weight_even_idMapFile_
int writeToConfDB_TPGLinearCoef(const std::map< EcalLogicID, FEConfigLinDat > &linset, const std::map< EcalLogicID, FEConfigLinParamDat > &linparamset, int iovId, std::string tag)
Definition: EcalTPGDBApp.cc:38
int getBstId() const
std::map< int, std::vector< int > > phases_EB_
int getFgrId() const
ESGetTokenH3DDVariant esConsumes(std::string const &Record, edm::ConsumesCollector &)
Definition: DeDxTools.cc:283
T getParameter(std::string const &) const
Definition: ParameterSet.h:307
unsigned int TPmode_FenixEBStripInfobit2_
int pseudoStripId() const
get the tower id
void setThreshLow(float x)
int channelId() const
get the channel id
T const & getData(const ESGetToken< T, R > &iToken) const noexcept(false)
Definition: EventSetup.h:119
unsigned int TPmode_FenixEBTcpInfobit1_
float getPedMeanG6() const
int getID1() const
Definition: EcalLogicID.cc:30
edm::ESGetToken< EcalIntercalibConstants, EcalIntercalibConstantsRcd > ecalIntercalibConstantsToken_
unsigned int TPmode_FenixEBTcpOutput_
int ieta() const
get the tower ieta
std::string getName() const
Definition: EcalLogicID.cc:26
int getSpiId() const
static constexpr uint NWEIGHTS
void setFGhighratio(float x)
EcalLogicID getEcalLogicID(std::string name, int id1=EcalLogicID::NULLID, int id2=EcalLogicID::NULLID, int id3=EcalLogicID::NULLID, std::string mapsTo="") noexcept(false)
void setShift12(int x)
EcalSubdetector subDet() const
get the subDetector associated to the Trigger Tower
edm::ESGetToken< EcalElectronicsMapping, EcalMappingRcd > ecalmappingToken_
Ecal readout channel identification [32:20] Unused (so far) [19:13] DCC id [12:6] tower [5:3] strip [...
int getID2() const
Definition: EcalLogicID.cc:32
int getBttId() const
std::pair< std::string, int > getCrate(int tcc)
DBuser
real DB on lxplus DBsid = cms.string(&#39;int2r&#39;), ## test DB P5 online DB DBuser = cms.string(&#39;cms_ecal_conf&#39;), DBpass = cms.string(&#39;0r4cms_3c4lc0nf&#39;),
int getGCTRegionPhi(int ttphi)
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
int DCCid(const EBDetId &id) const
returns the DCC of an EBDetId
double gainRatio_[3]
static const int XYMODE
Definition: EEDetId.h:333
int dccId() const
get the DCC (Ecal Local DCC value not global one) id
void setMultX1(int x)
int TCCid(const EBDetId &id) const
returns the TCCid of an EBDetId
std::string getDet(int tcc)
double oneOverEtResolEt(double *x, double *par)
int getPedId() const
const Items & endcapItems() const
void setFGlowthresh(float x)
Definition: weight.py:1
int getWeiId() const
void setRatioHigh(float x)
int zside(DetId const &)
edm::ESGetToken< EcalLaserAPDPNRatios, EcalLaserAPDPNRatiosRcd > ecalLaserAPDPNRatiosToken_
EcalTriggerElectronicsId getTriggerElectronicsId(const DetId &id) const
Get the trigger electronics id for this det id.
int writeToConfDB_TPGSliding(const std::map< EcalLogicID, FEConfigSlidingDat > &sliset, int iovId, std::string tag)
std::string weight_even_weightGroupFile_
void fetchConfigSet(ICONF *iconf) noexcept(false)
unsigned int TPmode_FenixEEStripOutput_
Log< level::Error, false > LogError
static EEDetId unhashIndex(int hi)
Definition: EEDetId.cc:65
edm::ESGetToken< CaloSubdetectorGeometry, EcalBarrelGeometryRecord > theBarrelGeometryToken_
int writeToConfDB_Delay(const std::map< EcalLogicID, FEConfigTimingDat > &delaygroupset, std::string tag)
const CaloSubdetectorGeometry * theEndcapGeometry_
void setShift6(int x)
std::ofstream * out_file_
void fetchDataSet(std::map< EcalLogicID, DATT > *fillMap, IOVT *iov) noexcept(false)
Definition: ntuple.py:1
std::map< int, std::vector< int > > delays_EB_
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
void setPedMeanG6(float mean)
edm::ESGetToken< EcalLaserAlphas, EcalLaserAlphasRcd > ecalLaserAlphasToken_
float getPedMeanG1() const
T getUntrackedParameter(std::string const &, T const &) const
void setShift1(int x)
edm::ESGetToken< EcalGainRatios, EcalGainRatiosRcd > ecalGainRatiosToken_
std::vector< unsigned int > computeWeights(EcalShapeBase &shape, TH1F *histo)
int hashedIndex(int ieta, int iphi)
Definition: EcalPyUtils.cc:36
void setThreshold(unsigned int mean)
int getLinId() const
void setPedMeanG1(float mean)
void setThreshHigh(float x)
int getLogicID() const
Definition: EcalLogicID.cc:28
int zside() const
get the z-side of the tower (1/-1)
std::map< int, std::vector< int > > delays_EE_
EcalPedestalsMap::const_iterator EcalPedestalsMapIterator
Definition: EcalPedestals.h:49
void setLutFgr(unsigned int mean)
const EcalElectronicsMapping * theMapping_
std::vector< EcalLogicID > getEcalLogicIDSetOrdered(std::string name, int fromId1, int toId1, int fromId2=EcalLogicID::NULLID, int toId2=EcalLogicID::NULLID, int fromId3=EcalLogicID::NULLID, int toId3=EcalLogicID::NULLID, std::string mapsTo="", int orderedBy=EcalLogicID::NULLID) noexcept(false)
void computeLUT(int *lut, std::string det="EB")
EcalTPGParamBuilder(edm::ParameterSet const &pSet)
int towerId() const
get the tower id
edm::ESGetToken< EcalADCToGeVConstant, EcalADCToGeVConstantRcd > ecalADCToGeVConstantToken_
T sqrt(T t)
Definition: SSEVec.h:23
void analyze(const edm::Event &evt, const edm::EventSetup &evtSetup) override
void setLUTValue(int i, int x)
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
virtual const std::vector< DetId > & getValidDetIds(DetId::Detector det=DetId::Detector(0), int subdet=0) const
Get a list of valid detector ids (for the given subdetector)
unsigned int TPmode_FenixEEStripInfobit2_
constexpr int subdetId() const
get the contents of the subdetector field (not cast into any detector&#39;s numbering enum) ...
Definition: DetId.h:48
std::ofstream * geomFile_
void setLUTGroupId(int x)
void setSpikeThreshold(int x)
void setEventSetup(const edm::EventSetup &evtSetup, bool normalize=true)
const_iterator find(uint32_t rawId) const
virtual std::shared_ptr< const CaloCellGeometry > getGeometry(const DetId &id) const
Get the cell geometry of a given detector id. Should return false if not found.
void insert(std::pair< uint32_t, Item > const &a)
void setFgrGroupId(int x)
int writeToConfDB_Spike(const std::map< EcalLogicID, FEConfigSpikeDat > &spikegroupset, std::string tag)
void computeFineGrainEEParameters(uint &threshold, uint &lut_strip, uint &lut_tower)
const EcalTrigTowerConstituentsMap * eTTmap_
edm::ESGetToken< EcalTrigTowerConstituentsMap, IdealGeometryRecord > eTTmapToken_
Log< level::Info, false > LogInfo
int ietaAbs() const
get the absolute value of the tower ieta
const Items & barrelItems() const
int getCokeId() const
float gain12Over6() const
ALPAKA_FN_ACC ALPAKA_FN_INLINE uint32_t ix(uint32_t id)
bool computeLinearizerParam(double theta, double gainRatio, double calibCoeff, std::string subdet, int &mult, int &shift)
Definition: DetId.h:17
int getSliId() const
const CaloSubdetectorGeometry * theBarrelGeometry_
int writeToConfDB_TPGPedestals(const std::map< EcalLogicID, FEConfigPedDat > &pedset, int iovId, std::string tag)
Definition: EcalTPGDBApp.cc:15
void setPedMeanG12(float mean)
unsigned int TPmode_FenixEETcpInfobit1_
constexpr uint32_t rawId() const
get the raw id
Definition: DetId.h:57
bool realignBaseline(linStruc &lin, float forceBase12, int cmsswid)
void setMultX6(int x)
std::vector< Item >::const_iterator const_iterator
int getBxtId() const
int stripId() const
get the tower id
unsigned int TPmode_FenixEETcpOutput_
unsigned tccId(DetId const &, EcalElectronicsMapping const *)
edm::ESGetToken< EcalPedestals, EcalPedestalsRcd > ecalPedestalsToken_
float gain6Over1() const
int getTimId() const
int iTT(const EcalTrigTowerDetId &id) const
returns the index of a Trigger Tower within its TCC.
static EBDetId unhashIndex(int hi)
get a DetId from a compact index for arrays
Definition: EBDetId.h:110
int xtalId() const
get the channel id
int getID3() const
Definition: EcalLogicID.cc:34
void setConfigTag(std::string x)
Definition: IODConfig.h:29
void setFGlowratio(float x)
void setSliding(float mean)
HLT enums.
static const int NULLID
Definition: EcalLogicID.h:35
std::string weight_odd_idMapFile_
EcalElectronicsId getElectronicsId(const DetId &id) const
Get the electronics id for this det id.
void setTTThreshhigh(float x)
int writeToConfDB_TPGLUT(const std::map< EcalLogicID, FEConfigLUTGroupDat > &lutgroup, const std::map< EcalLogicID, FEConfigLUTDat > &lutdat, const std::map< EcalLogicID, FEConfigLUTParamDat > &lutparamset, int iovId, std::string tag)
edm::ESGetToken< CaloSubdetectorGeometry, EcalEndcapGeometryRecord > theEndcapGeometryToken_
void setMultX12(int x)
void setId(int id)
static unsigned int const shift
float x
ALPAKA_FN_ACC ALPAKA_FN_INLINE uint32_t iy(uint32_t id)
std::string weight_odd_weightGroupFile_
int writeToConfDB_TPGFgr(const std::map< EcalLogicID, FEConfigFgrGroupDat > &lutgroup, const std::map< EcalLogicID, FEConfigFgrDat > &lutdat, const std::map< EcalLogicID, FEConfigFgrParamDat > &fgrparamset, const std::map< EcalLogicID, FEConfigFgrEETowerDat > &dataset3, const std::map< EcalLogicID, FEConfigFgrEEStripDat > &dataset4, int iovId, std::string tag)
const_iterator end() const
int writeToConfDB_TPGWeight(const std::map< EcalLogicID, FEConfigWeightGroupDat > &lutgroup, const std::map< EcalLogicID, FEConfigWeightDat > &lutdat, int iovId, std::string tag)
int getGCTRegionEta(int tteta)
int writeToConfDB_TPGWeight_doubleWeights(const std::map< EcalLogicID, FEConfigOddWeightGroupDat > &lutgroupset, const std::map< EcalLogicID, FEConfigOddWeightDat > &lutset, const std::map< EcalLogicID, FEConfigOddWeightModeDat > &tpmode, int ngr, std::string tag)
int getLUTId() const
Log< level::Warning, false > LogWarning
int iphi() const
get the tower iphi
std::map< int, double > Transparency_Correction_
void setTTThreshlow(float x)
static const int SMCRYSTALMODE
Definition: EBDetId.h:159
#define str(s)
void setWeightGroupId(int x)
int getEtaSlice(int tccId, int towerInTCC)
int writeToConfDB_TPGMain(int ped, int lin, int lut, int fgr, int sli, int wei, int wei2, int spi, int tim, int bxt, int btt, int bst, int cok, std::string tag, int ver)
Definition: EcalTPGDBApp.cc:65
int getWei2Id() const
Ecal trigger electronics identification [32:20] Unused (so far) [19:13] TCC id [12:6] TT id [5:3] pse...
void setFGhighthresh(float x)
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29
std::map< int, std::vector< int > > phases_EE_
float getPedMeanG12() const
bool checkIfOK(EcalPedestals::Item item)
void computeFineGrainEBParameters(uint &lowRatio, uint &highRatio, uint &lowThreshold, uint &highThreshold, uint &lut)
ib
Definition: cuy.py:661
void getCoeff(coeffStruc &coeff, const EcalGainRatioMap &gainMap, uint rawId)
int uncodeWeight(double weight, int complement2=7)