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L1RCTLutWriter.cc
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2 
4 
11 
12 // default scales
17 
18 // debug scales
22 
25 
26 //
27 // constants, enums and typedefs
28 //
29 
30 //
31 // static data member definitions
32 //
33 
34 //
35 // constructors and destructor
36 //
38  lookupTable_(new L1RCTLookupTables),
39  keyName_(iConfig.getParameter<std::string>("key")),
40  useDebugTpgScales_(iConfig.getParameter<bool>("useDebugTpgScales"))
41 {
42  //now do what ever initialization is needed
43 
44 }
45 
46 
48 {
49 
50  // do anything here that needs to be done at destruction time
51  // (e.g. close files, deallocate resources etc.)
52 
53  if (lookupTable_ != 0) delete lookupTable_;
54 }
55 
56 
57 //
58 // member functions
59 //
60 
61 // ------------ method called to for each event ------------
62 void
64 {
65 
66  // get all the configuration information from the event, set it
67  // in the lookuptable
68  edm::ESHandle<L1RCTParameters> rctParameters;
69  iSetup.get<L1RCTParametersRcd>().get(rctParameters);
70  rctParameters_ = rctParameters.product();
72  iSetup.get<L1EmEtScaleRcd>().get(emScale);
73  const L1CaloEtScale* s = emScale.product();
74 
75  // make dummy channel mask -- we don't want to mask
76  // any channels when writing LUTs, that comes afterwards
78  for (int i = 0; i < 18; i++)
79  {
80  for (int j = 0; j < 2; j++)
81  {
82  for (int k = 0; k < 28; k++)
83  {
84  m->ecalMask[i][j][k] = false;
85  m->hcalMask[i][j][k] = false;
86  }
87  for (int k = 0; k < 4; k++)
88  {
89  m->hfMask[i][j][k] = false;
90  }
91  }
92  }
93 
94 
95  //Same for Noisy mask
96  // make dummy channel mask -- we don't want to mask
97  // any channels when writing LUTs, that comes afterwards
99  for (int i = 0; i < 18; i++)
100  {
101  for (int j = 0; j < 2; j++)
102  {
103  for (int k = 0; k < 28; k++)
104  {
105  m2->ecalMask[i][j][k] = false;
106  m2->hcalMask[i][j][k] = false;
107  }
108  for (int k = 0; k < 4; k++)
109  {
110  m2->hfMask[i][j][k] = false;
111  }
112  }
113  }
114  m2->ecalThreshold = 0.0;
115  m2->hcalThreshold = 0.0;
116  m2->hfThreshold = 0.0;
117 
118 
119 
120  // use these dummies to get the delete right when using old-style
121  // scales to create set of L1CaloXcalScales
122  L1CaloEcalScale* dummyE(0);
123  L1CaloHcalScale* dummyH(0);
124 
125  if (useDebugTpgScales_) // generate new-style scales from tpg scales
126  {
127 
128  std::cout << "Using old-style TPG scales!" << std::endl;
129 
130  // old version of hcal energy scale to convert input
132  iSetup.get<CaloTPGRecord>().get(transcoder);
133  const CaloTPGTranscoder* h_tpg = transcoder.product();
134 
135  // old version of ecal energy scale to convert input
136  EcalTPGScale* e_tpg = new EcalTPGScale();
137  e_tpg->setEventSetup(iSetup);
138 
139  L1CaloEcalScale* ecalScale = new L1CaloEcalScale();
140  L1CaloHcalScale* hcalScale = new L1CaloHcalScale();
141 
142  // generate L1CaloXcalScales from old-style scales (thanks, werner!)
143 
144  // ECAL
145  for( unsigned short ieta = 1 ; ieta <= L1CaloEcalScale::nBinEta; ++ieta )
146  {
147  for( unsigned short irank = 0 ; irank < L1CaloEcalScale::nBinRank; ++irank )
148  {
149  EcalSubdetector subdet = ( ieta <= 17 ) ? EcalBarrel : EcalEndcap ;
150  double etGeVPos =
151  e_tpg->getTPGInGeV
152  ( irank, EcalTrigTowerDetId(1, // +ve eta
153  subdet,
154  ieta,
155  1 )); // dummy phi value
156  ecalScale->setBin( irank, ieta, 1, etGeVPos ) ;
157  }
158  }
159 
160  for( unsigned short ieta = 1 ; ieta <= L1CaloEcalScale::nBinEta; ++ieta )
161  {
162  for( unsigned short irank = 0 ; irank < L1CaloEcalScale::nBinRank; ++irank )
163  {
164  EcalSubdetector subdet = ( ieta <= 17 ) ? EcalBarrel : EcalEndcap ;
165 
166  double etGeVNeg =
167  e_tpg->getTPGInGeV
168  ( irank,
169  EcalTrigTowerDetId(-1, // -ve eta
170  subdet,
171  ieta,
172  2 )); // dummy phi value
173  ecalScale->setBin( irank, ieta, -1, etGeVNeg ) ;
174  }
175  }
176 
177  // HCAL
178  for( unsigned short ieta = 1 ; ieta <= L1CaloHcalScale::nBinEta; ++ieta )
179  {
180  for( unsigned short irank = 0 ; irank < L1CaloHcalScale::nBinRank; ++irank )
181  {
182  double etGeV = h_tpg->hcaletValue( ieta, irank ) ;
183 
184  hcalScale->setBin( irank, ieta, 1, etGeV ) ;
185  hcalScale->setBin( irank, ieta, -1, etGeV ) ;
186  }
187  }
188 
189  // set the input scales
190  lookupTable_->setEcalScale(ecalScale);
191  lookupTable_->setHcalScale(hcalScale);
192 
193  dummyE = ecalScale;
194  dummyH = hcalScale;
195 
196  delete e_tpg;
197 
198  }
199  else
200  {
201 
202  // get energy scale to convert input from ECAL
204  iSetup.get<L1CaloEcalScaleRcd>().get(ecalScale);
205  const L1CaloEcalScale* e = ecalScale.product();
206 
207  // get energy scale to convert input from HCAL
209  iSetup.get<L1CaloHcalScaleRcd>().get(hcalScale);
210  const L1CaloHcalScale* h = hcalScale.product();
211 
212  // set scales
215 
216  }
217 
221  //lookupTable_->setHcalScale(h);
222  //lookupTable_->setEcalScale(e);
224 
225  for (unsigned short nCard = 0; nCard <= 6; nCard = nCard + 2)
226  {
227  writeRcLutFile(nCard);
228  writeEicLutFile(nCard);
229  }
230  writeJscLutFile();
231 
232  unsigned int eicThreshold = rctParameters_->eicIsolationThreshold();
233  unsigned int jscThresholdBarrel = rctParameters_->jscQuietThresholdBarrel();
234  unsigned int jscThresholdEndcap = rctParameters_->jscQuietThresholdEndcap();
235  writeThresholdsFile(eicThreshold, jscThresholdBarrel, jscThresholdEndcap);
236 
237  if (dummyE != 0) delete dummyE;
238  if (dummyH != 0) delete dummyH;
239 
240 }
241 
242 
243 
244 
245 // ------------ method called once each job just after ending the event loop ------------
246 void
248 }
249 
250 
251 // ------------ method to write one receiver card lut file
252 void
253 L1RCTLutWriter::writeRcLutFile(unsigned short card)
254 {
255 
256  // don't mess yet with name
257  char filename[256];
258  char command[64];
259  if (card != 6)
260  {
261  int card2 = card + 1;
262  sprintf(filename,"RC%i%i-%s.dat",card,card2,keyName_.c_str() );
263  //sprintf(filename, "RC%i%i.dat", card, card2);
264  }
265  else
266  {
267  sprintf(filename,"RC6-%s.dat",keyName_.c_str() );
268  //sprintf(filename, "RC6.dat");
269  }
270  // open file for writing, delete any existing content
271  lutFile_.open(filename, std::ios::trunc);
272  lutFile_ << "Emulator-parameter generated lut file, card "
273  << card << " key " << keyName_ << " ";
274 
275  // close to append timestamp info
276  lutFile_.close();
277  sprintf(command, "date >> %s", filename);
278  system(command);
279 
280  // reopen file for writing values
281  lutFile_.open(filename, std::ios::app);
282 
283  unsigned long data = 0;
284 
285  // write all memory addresses in increasing order
286  // address = (1<<22)+(nLUT<<19)+(eG?<18)+(hcalEt<<10)+(ecalfg<<9)+(ecalEt<<1)
287 
288  // loop through the physical LUTs on the card, 0-7
289  for (unsigned short nLUT = 0; nLUT < 8; nLUT++)
290  {
291  // determine ieta, iphi, etc. everything
292  unsigned short iAbsEta = 0;
293  if (card != 6)
294  {
295  iAbsEta = (card/2)*8 + nLUT + 1;
296  }
297  else
298  {
299  if (nLUT < 4)
300  {
301  iAbsEta = (card/2)*8 + nLUT + 1;
302  }
303  else
304  {
305  iAbsEta = (card/2)*8 + (3 - (nLUT%4) ) + 1;
306  }
307  //std::cout << "LUT is " << nLUT << " iAbsEta is " << iAbsEta << std::endl;
308  }
309 
310 
311  // All RCT stuff uniform in phi, symmetric wrt eta = 0
312 
313  // below line always gives crate in +eta; makes no difference to us
314  unsigned short crate = rctParameters_->calcCrate(1, iAbsEta);
315  unsigned short tower = rctParameters_->calcTower(1, iAbsEta);
316 
317  // first do region sums half of LUTs, bit 18 of address is 0
318  // loop through 8 bits of hcal energy, 2^8 is 256
319  for (unsigned int hcalEt = 0; hcalEt < 256; hcalEt++)
320  {
321  // loop through 1 bit of ecal fine grain
322  for (unsigned short ecalfg = 0; ecalfg < 2; ecalfg++)
323  {
324  // loop through 8 bits of ecal energy
325  for (unsigned int ecalEt = 0; ecalEt < 256; ecalEt++)
326  {
327  // assign 10-bit (9et,1mip) sums data here!
328  unsigned long output = lookupTable_->
329  lookup(ecalEt, hcalEt, ecalfg, crate, card, tower);
330  unsigned short etIn9Bits = (output>>8)&511;
331  unsigned short tauActivityBit = (output>>17)&1;
332  data = (tauActivityBit<<9)+etIn9Bits;
333  lutFile_ << std::hex << data << std::dec << std::endl;
334  }
335  }
336  }
337  // second do egamma half of LUTs, bit 18 of address is 1
338  // loop through 8 bits of hcal energy
339  for (unsigned int hcalEt = 0; hcalEt < 256; hcalEt++)
340  {
341  // loop through 1 bit of ecal fine grain
342  for (unsigned short ecalfg = 0; ecalfg < 2; ecalfg++)
343  {
344  // loop through 8 bits of ecal energy
345  for (unsigned int ecalEt = 0; ecalEt < 256; ecalEt++)
346  {
347  // assign 8-bit (7et,1veto) egamma data here!
348  unsigned long output = lookupTable_->
349  lookup(ecalEt, hcalEt, ecalfg, crate, card, tower);
350  unsigned short etIn7Bits = output&127;
351  unsigned short heFgVetoBit = (output>>7)&1;
352  data = (heFgVetoBit<<7)+etIn7Bits;
353  lutFile_ << std::hex << data << std::dec << std::endl;
354  }
355  }
356  }
357  }
358 
359  lutFile_.close();
360  return;
361 
362 }
363 
364 // ------------ method to write one electron isolation card lut file
365 void
367 {
368  // try timestamp
369  char filename[256];
370  char command[64];
371  if (card != 6)
372  {
373  int card2 = card + 1;
374  sprintf(filename,"EIC%i%i-%s.dat", card, card2, keyName_.c_str() );
375  }
376  else
377  {
378  sprintf(filename,"EIC6-%s.dat", keyName_.c_str() );
379  }
380  // open file for writing, delete any existing content
381  lutFile_.open(filename, std::ios::trunc);
382  lutFile_ << "Emulator-parameter generated EIC lut file, card "
383  << card << " key " << keyName_ << " ";
384  // close to append timestamp info
385  lutFile_.close();
386  sprintf(command, "date >> %s", filename);
387  system(command);
388 
389  // reopen file for writing values
390  lutFile_.open(filename, std::ios::app);
391 
392  unsigned long data = 0;
393 
394  // write all memory addresses in increasing order
395  // address = (1<<22) + (etIn7Bits<<1)
396 
397  // 2^7 = 0x7f = 128
398  for (int etIn7Bits = 0; etIn7Bits < 128; etIn7Bits++)
399  {
400  data = lookupTable_->emRank(etIn7Bits);
401  if (data > 0x3f)
402  {
403  data = 0x3f;
404  }
405  lutFile_ << std::hex << data << std::dec << std::endl;
406  }
407  lutFile_.close();
408  return;
409 }
410 
411 // ------------ method to write one jet summary card lut file
412 void
414 {
415  char filename[256];
416  char command[64];
417  sprintf(filename, "JSC-%s.dat", keyName_.c_str() );
418 
419  // open file; if it already existed, delete existing content
420  lutFile_.open(filename, std::ios::trunc);
421  lutFile_ << "Emulator parameter-generated lut file, key " << keyName_
422  << " ";
423  // close to append time-stamp
424  lutFile_.close();
425  sprintf(command, "date >> %s", filename);
426  system(command);
427  // reopen file for writing
428  lutFile_.open(filename, std::ios::app);
429 
430  unsigned long data = 0;
431  unsigned long data0 = 0;
432  unsigned long data1 = 0;
433 
434  // write all memory addresses in increasing order
435  // address = (1<<22) + (lutbits<<17) + (phi1et<<9) + (phi0et<<1);
436 
437  // ecl and U93/U225 lut id bits, identify eta segment of hf
438  for (int lutbits = 0; lutbits < 4; lutbits++)
439  {
440  // 8-bit phi_1 et for each eta partition
441  for (unsigned int phi1et = 0; phi1et < 256; phi1et++)
442  {
443  // 8-bit phi_0 et for each eta
444  for (unsigned int phi0et = 0; phi0et < 256; phi0et++)
445  {
446  // lookup takes "(hf_et, crate, card, tower)"
447  // "card" convention for hf is 999, tower is 0-7
448  // but equivalent to 0-3 == lutbits
449  // crate doesn't matter, take 0
450  // only |ieta| matters
451  data0 = lookupTable_->lookup(phi0et, 0, 999, lutbits);
452  if (data0 > 0xff)
453  {
454  data0 = 0xff; // 8-bit output energy for each phi region
455  }
456  data1 = lookupTable_->lookup(phi1et, 0, 999, lutbits);
457  if (data1 > 0xff)
458  {
459  data1 = 0xff; // 8-bit output energy for each phi region
460  }
461  data = (data1<<8) + (data0);
462  lutFile_ << std::hex << data << std::dec << std::endl;
463  /*
464  if (phi0et < 10 && phi1et < 10)
465  {
466  std::cout << "Writer: jsc. lutbits=" << lutbits
467  << " phi0et=" << phi0et << " data0=" << data0
468  << " phi1et=" << phi1et << " data1=" << data1
469  << std::endl;
470  }
471  */
472  }
473  }
474  }
475 
476  lutFile_.close();
477  return;
478 }
479 
480 //-----------Write text file containing the 1 JSC and 2 EIC thresholds
481 void
482 L1RCTLutWriter::writeThresholdsFile(unsigned int eicThreshold,
483  unsigned int jscThresholdBarrel,
484  unsigned int jscThresholdEndcap)
485 {
486  //
487  std::ofstream thresholdsFile;
488  char filename[256];
489  sprintf(filename, "Thresholds-%s.dat", keyName_.c_str() );
490  thresholdsFile.open(filename, std::ios::trunc);
491 
492  thresholdsFile << "key is " << keyName_ << std::endl << std::endl;
493  thresholdsFile << "eicIsolationThreshold " << eicThreshold << std::endl;
494  thresholdsFile << "jscQuietThresholdBarrel " << jscThresholdBarrel << std::endl;
495  thresholdsFile << "jscQuietThresholdEndcap " << jscThresholdEndcap << std::endl;
496 
497  thresholdsFile.close();
498 }
499 
500 //define this as a plug-in
501 //DEFINE_FWK_MODULE(L1RCTLutWriter); // done in SealModule.cc
const L1RCTParameters * rctParameters_
L1RCTLutWriter(const edm::ParameterSet &)
void setEventSetup(const edm::EventSetup &evtSetup)
Definition: EcalTPGScale.cc:19
void writeRcLutFile(unsigned short card)
unsigned eicIsolationThreshold() const
bool ecalMask[18][2][28]
void setBin(unsigned short rank, unsigned short eta, short etaSign, double et)
set scale element; use this to create non-linear scales
L1RCTLookupTables * lookupTable_
void setBin(unsigned short rank, unsigned short eta, short etaSign, double et)
set scale element; use this to create non-linear scales
double getTPGInGeV(const EcalTriggerPrimitiveDigi &tpDigi)
Definition: EcalTPGScale.cc:24
unsigned jscQuietThresholdEndcap() const
std::string keyName_
int iEvent
Definition: GenABIO.cc:230
unsigned short calcTower(unsigned short rct_iphi, unsigned short absIeta) const
void setHcalScale(const L1CaloHcalScale *hcalScale)
static const unsigned short nBinRank
void writeThresholdsFile(unsigned int eicThreshold, unsigned int jscThresholdBarrel, unsigned int jscThresholdEndcap)
unsigned int emRank(unsigned short energy) const
virtual void endJob()
void setL1CaloEtScale(const L1CaloEtScale *etScale)
virtual void analyze(const edm::Event &, const edm::EventSetup &)
int k[5][pyjets_maxn]
const T & get() const
Definition: EventSetup.h:55
void setEcalScale(const L1CaloEcalScale *ecalScale)
std::ofstream lutFile_
void setRCTParameters(const L1RCTParameters *rctParameters)
char data[epos_bytes_allocation]
Definition: EPOS_Wrapper.h:82
static const unsigned short nBinRank
void setNoisyChannelMask(const L1RCTNoisyChannelMask *channelMask)
static const unsigned short nBinEta
static const unsigned short nBinEta
bool hcalMask[18][2][28]
virtual double hcaletValue(const int &ieta, const int &iphi, const int &version, const int &compressedValue) const =0
void writeEicLutFile(unsigned short card)
EcalSubdetector
T const * product() const
Definition: ESHandle.h:86
bool hfMask[18][2][4]
void setChannelMask(const L1RCTChannelMask *channelMask)
unsigned short calcCrate(unsigned short rct_iphi, short ieta) const
unsigned jscQuietThresholdBarrel() const
unsigned int lookup(unsigned short ecalInput, unsigned short hcalInput, unsigned short fgbit, unsigned short crtNo, unsigned short crdNo, unsigned short twrNo) const