CMS 3D CMS Logo

FitTrack.cc
Go to the documentation of this file.
9 
12 
13 using namespace std;
14 using namespace trklet;
15 
16 FitTrack::FitTrack(string name, Settings const& settings, Globals* global)
17  : ProcessBase(name, settings, global), trackfit_(nullptr) {}
18 
20  if (settings_.writetrace()) {
21  edm::LogVerbatim("Tracklet") << "In " << name_ << " adding output to " << memory->getName() << " to output "
22  << output;
23  }
24  if (output == "trackout") {
25  TrackFitMemory* tmp = dynamic_cast<TrackFitMemory*>(memory);
26  assert(tmp != nullptr);
27  trackfit_ = tmp;
28  return;
29  }
30 
31  throw cms::Exception("BadConfig") << __FILE__ << " " << __LINE__ << " addOutput, output = " << output << " not known";
32 }
33 
35  if (settings_.writetrace()) {
36  edm::LogVerbatim("Tracklet") << "In " << name_ << " adding input from " << memory->getName() << " to input "
37  << input;
38  }
39  if (input.substr(0, 4) == "tpar") {
40  auto* tmp = dynamic_cast<TrackletParametersMemory*>(memory);
41  assert(tmp != nullptr);
42  seedtracklet_.push_back(tmp);
43  return;
44  }
45  if (input.substr(0, 10) == "fullmatch1") {
46  auto* tmp = dynamic_cast<FullMatchMemory*>(memory);
47  assert(tmp != nullptr);
48  fullmatch1_.push_back(tmp);
49  return;
50  }
51  if (input.substr(0, 10) == "fullmatch2") {
52  auto* tmp = dynamic_cast<FullMatchMemory*>(memory);
53  assert(tmp != nullptr);
54  fullmatch2_.push_back(tmp);
55  return;
56  }
57  if (input.substr(0, 10) == "fullmatch3") {
58  auto* tmp = dynamic_cast<FullMatchMemory*>(memory);
59  assert(tmp != nullptr);
60  fullmatch3_.push_back(tmp);
61  return;
62  }
63  if (input.substr(0, 10) == "fullmatch4") {
64  auto* tmp = dynamic_cast<FullMatchMemory*>(memory);
65  assert(tmp != nullptr);
66  fullmatch4_.push_back(tmp);
67  return;
68  }
69 
70  throw cms::Exception("BadConfig") << __FILE__ << " " << __LINE__ << " input = " << input << " not found";
71 }
72 
73 #ifdef USEHYBRID
74 void FitTrack::trackFitKF(Tracklet* tracklet,
75  std::vector<const Stub*>& trackstublist,
76  std::vector<std::pair<int, int>>& stubidslist) {
77  if (settings_.doKF()) {
78  // From full match lists, collect all the stubs associated with the tracklet seed
79 
80  // Get seed stubs first
81  trackstublist.emplace_back(tracklet->innerFPGAStub());
82  if (tracklet->getISeed() >= (int)N_TRKLSEED + 1)
83  trackstublist.emplace_back(tracklet->middleFPGAStub());
84  trackstublist.emplace_back(tracklet->outerFPGAStub());
85 
86  // Now get ALL matches (can have multiple per layer)
87  for (const auto& i : fullmatch1_) {
88  for (unsigned int j = 0; j < i->nMatches(); j++) {
89  if (i->getTracklet(j)->TCID() == tracklet->TCID()) {
90  trackstublist.push_back(i->getMatch(j).second);
91  }
92  }
93  }
94 
95  for (const auto& i : fullmatch2_) {
96  for (unsigned int j = 0; j < i->nMatches(); j++) {
97  if (i->getTracklet(j)->TCID() == tracklet->TCID()) {
98  trackstublist.push_back(i->getMatch(j).second);
99  }
100  }
101  }
102 
103  for (const auto& i : fullmatch3_) {
104  for (unsigned int j = 0; j < i->nMatches(); j++) {
105  if (i->getTracklet(j)->TCID() == tracklet->TCID()) {
106  trackstublist.push_back(i->getMatch(j).second);
107  }
108  }
109  }
110 
111  for (const auto& i : fullmatch4_) {
112  for (unsigned int j = 0; j < i->nMatches(); j++) {
113  if (i->getTracklet(j)->TCID() == tracklet->TCID()) {
114  trackstublist.push_back(i->getMatch(j).second);
115  }
116  }
117  }
118 
119  // For merge removal, loop through the resulting list of stubs to calculate their stubids
120  if (settings_.removalType() == "merge") {
121  for (const auto& it : trackstublist) {
122  int layer = it->layer().value() + 1; // Assume layer (1-6) stub first
123  if (it->layer().value() < 0) { // if disk stub, though...
124  layer = it->disk().value() + 10 * it->disk().value() / abs(it->disk().value()); //disk = +/- 11-15
125  }
126  stubidslist.push_back(std::make_pair(layer, it->phiregionaddress()));
127  }
128 
129  // And that's all we need! The rest is just for track fit (done in PurgeDuplicate)
130 
131  } else {
132  // Track fit only called here if not running duplicate removal
133  // before fit. (e.g. If skipping duplicate removal).
134  HybridFit hybridFitter(iSector_, settings_, globals_);
135  hybridFitter.Fit(tracklet, trackstublist);
136  }
137  }
138 }
139 #endif
140 
141 void FitTrack::trackFitChisq(Tracklet* tracklet, std::vector<const Stub*>&, std::vector<std::pair<int, int>>&) {
142  if (globals_->trackDerTable() == nullptr) {
143  TrackDerTable* derTablePtr = new TrackDerTable(settings_);
144 
145  derTablePtr->readPatternFile(settings_.fitPatternFile());
146  derTablePtr->fillTable();
147  if (settings_.debugTracklet()) {
148  edm::LogVerbatim("Tracklet") << "Number of entries in derivative table: " << derTablePtr->getEntries();
149  }
150  assert(derTablePtr->getEntries() != 0);
151 
152  globals_->trackDerTable() = derTablePtr;
153  }
154 
155  const TrackDerTable& derTable = *globals_->trackDerTable();
156 
157  //First step is to build list of layers and disks.
158  int layers[N_LAYER];
159  double r[N_LAYER];
160  unsigned int nlayers = 0; // layers with found stub-projections
161  int disks[N_DISK];
162  double z[N_DISK];
163  unsigned int ndisks = 0; // disks with found stub-projections
164 
165  // residuals for each stub
166  double phiresid[N_FITSTUB];
167  double zresid[N_FITSTUB];
168  double phiresidexact[N_FITSTUB];
169  double zresidexact[N_FITSTUB];
170  int iphiresid[N_FITSTUB];
171  int izresid[N_FITSTUB];
172  double alpha[N_FITSTUB];
173 
174  for (unsigned int i = 0; i < N_FITSTUB; i++) {
175  iphiresid[i] = 0;
176  izresid[i] = 0;
177  alpha[i] = 0.0;
178 
179  phiresid[i] = 0.0;
180  zresid[i] = 0.0;
181  phiresidexact[i] = 0.0;
182  zresidexact[i] = 0.0;
183  }
184 
185  std::bitset<N_LAYER> lmatches; //layer matches
186  std::bitset<N_DISK * 2> dmatches; //disk matches (2 per disk to separate 2S from PS)
187 
188  int mult = 1;
189 
190  unsigned int layermask = 0;
191  unsigned int diskmask = 0;
192  unsigned int alphaindex = 0;
193  unsigned int power = 1;
194 
195  double t = tracklet->t();
196  double rinv = tracklet->rinv();
197 
198  if (tracklet->isBarrel()) {
199  for (unsigned int l = 1; l <= N_LAYER; l++) {
200  if (l == (unsigned int)tracklet->layer() || l == (unsigned int)tracklet->layer() + 1) {
201  lmatches.set(N_LAYER - l);
202  layermask |= (1 << (N_LAYER - l));
203  layers[nlayers++] = l;
204  continue;
205  }
206  if (tracklet->match(l - 1)) {
207  const Residual& resid = tracklet->resid(l - 1);
208  lmatches.set(N_LAYER - l);
209  layermask |= (1 << (N_LAYER - l));
210  phiresid[nlayers] = resid.phiresidapprox();
211  zresid[nlayers] = resid.rzresidapprox();
212  phiresidexact[nlayers] = resid.phiresid();
213  zresidexact[nlayers] = resid.rzresid();
214  iphiresid[nlayers] = resid.fpgaphiresid().value();
215  izresid[nlayers] = resid.fpgarzresid().value();
216 
217  layers[nlayers++] = l;
218  }
219  }
220 
221  for (unsigned int d = 1; d <= N_DISK; d++) {
222  if (layermask & (1 << (d - 1)))
223  continue;
224 
225  if (mult == 1 << (3 * settings_.alphaBitsTable()))
226  continue;
227 
228  if (ndisks + nlayers >= N_FITSTUB)
229  continue;
230  if (tracklet->match(N_LAYER + d - 1)) {
231  const Residual& resid = tracklet->resid(N_LAYER + d - 1);
232  double pitch = settings_.stripPitch(resid.stubptr()->l1tstub()->isPSmodule());
233  if (std::abs(resid.stubptr()->l1tstub()->alpha(pitch)) < 1e-20) {
234  dmatches.set(2 * d - 1);
235  diskmask |= (1 << (2 * (N_DISK - d) + 1));
236  } else {
237  int ialpha = resid.stubptr()->alpha().value();
238  int nalpha = resid.stubptr()->alpha().nbits();
239  nalpha = nalpha - settings_.alphaBitsTable();
240  ialpha = (1 << (settings_.alphaBitsTable() - 1)) + (ialpha >> nalpha);
241 
242  alphaindex += ialpha * power;
244  dmatches.set(2 * (N_DISK - d));
245  diskmask |= (1 << (2 * (N_DISK - d)));
247  }
248  alpha[ndisks] = resid.stubptr()->l1tstub()->alpha(pitch);
249  phiresid[nlayers + ndisks] = resid.phiresidapprox();
250  zresid[nlayers + ndisks] = resid.rzresidapprox();
251  phiresidexact[nlayers + ndisks] = resid.phiresid();
252  zresidexact[nlayers + ndisks] = resid.rzresid();
253  iphiresid[nlayers + ndisks] = resid.fpgaphiresid().value();
254  izresid[nlayers + ndisks] = resid.fpgarzresid().value();
255 
256  disks[ndisks++] = d;
257  }
258  }
259 
260  if (settings_.writeMonitorData("HitPattern")) {
261  if (mult <= 1 << (3 * settings_.alphaBitsTable())) {
262  globals_->ofstream("hitpattern.txt")
263  << lmatches.to_string() << " " << dmatches.to_string() << " " << mult << endl;
264  }
265  }
266  }
267 
268  if (tracklet->isDisk()) {
269  for (unsigned int l = 1; l <= 2; l++) {
270  if (tracklet->match(l - 1)) {
271  lmatches.set(N_LAYER - l);
272 
273  layermask |= (1 << (N_LAYER - l));
274  const Residual& resid = tracklet->resid(l - 1);
275  phiresid[nlayers] = resid.phiresidapprox();
276  zresid[nlayers] = resid.rzresidapprox();
277  phiresidexact[nlayers] = resid.phiresid();
278  zresidexact[nlayers] = resid.rzresid();
279  iphiresid[nlayers] = resid.fpgaphiresid().value();
280  izresid[nlayers] = resid.fpgarzresid().value();
281 
282  layers[nlayers++] = l;
283  }
284  }
285 
286  for (int d1 = 1; d1 <= N_DISK; d1++) {
287  int d = d1;
288 
289  // skip F/B5 if there's already a L2 match
290  if (d == 5 and layermask & (1 << 4))
291  continue;
292 
293  if (tracklet->fpgat().value() < 0.0)
294  d = -d1;
295  if (d1 == abs(tracklet->disk()) || d1 == abs(tracklet->disk()) + 1) {
296  dmatches.set(2 * d1 - 1);
297  diskmask |= (1 << (2 * (N_DISK - d1) + 1));
298  alpha[ndisks] = 0.0;
299  disks[ndisks++] = d;
300  continue;
301  }
302 
303  if (ndisks + nlayers >= N_FITSTUB)
304  continue;
305  if (tracklet->match(N_LAYER + abs(d) - 1)) {
306  const Residual& resid = tracklet->resid(N_LAYER + abs(d) - 1);
307  double pitch = settings_.stripPitch(resid.stubptr()->l1tstub()->isPSmodule());
308  if (std::abs(resid.stubptr()->l1tstub()->alpha(pitch)) < 1e-20) {
309  dmatches.set(2 * d1 - 1);
310  diskmask |= (1 << (2 * (N_DISK - d1) + 1));
311  } else {
312  int ialpha = resid.stubptr()->alpha().value();
313  int nalpha = resid.stubptr()->alpha().nbits();
314  nalpha = nalpha - settings_.alphaBitsTable();
315  ialpha = (1 << (settings_.alphaBitsTable() - 1)) + (ialpha >> nalpha);
316 
317  alphaindex += ialpha * power;
319  dmatches.set(2 * (N_DISK - d1));
320  diskmask |= (1 << (2 * (N_DISK - d1)));
322  }
323 
324  alpha[ndisks] = resid.stubptr()->l1tstub()->alpha(pitch);
325  assert(std::abs(resid.phiresidapprox()) < 0.2);
326  phiresid[nlayers + ndisks] = resid.phiresidapprox();
327  zresid[nlayers + ndisks] = resid.rzresidapprox();
328  assert(std::abs(resid.phiresid()) < 0.2);
329  phiresidexact[nlayers + ndisks] = resid.phiresid();
330  zresidexact[nlayers + ndisks] = resid.rzresid();
331  iphiresid[nlayers + ndisks] = resid.fpgaphiresid().value();
332  izresid[nlayers + ndisks] = resid.fpgarzresid().value();
333 
334  disks[ndisks++] = d;
335  }
336  }
337  }
338 
339  if (tracklet->isOverlap()) {
340  for (unsigned int l = 1; l <= 2; l++) {
341  if (l == (unsigned int)tracklet->layer()) {
342  lmatches.set(N_LAYER - l);
343  layermask |= (1 << (N_LAYER - l));
344  layers[nlayers++] = l;
345  continue;
346  }
347  if (tracklet->match(l - 1)) {
348  lmatches.set(N_LAYER - l);
349  layermask |= (1 << (N_LAYER - l));
350  const Residual& resid = tracklet->resid(l - 1);
351  assert(std::abs(resid.phiresidapprox()) < 0.2);
352  phiresid[nlayers] = resid.phiresidapprox();
353  zresid[nlayers] = resid.rzresidapprox();
354  assert(std::abs(resid.phiresid()) < 0.2);
355  phiresidexact[nlayers] = resid.phiresid();
356  zresidexact[nlayers] = resid.rzresid();
357  iphiresid[nlayers] = resid.fpgaphiresid().value();
358  izresid[nlayers] = resid.fpgarzresid().value();
359 
360  layers[nlayers++] = l;
361  }
362  }
363 
364  for (unsigned int d1 = 1; d1 <= N_DISK; d1++) {
365  if (mult == 1 << (3 * settings_.alphaBitsTable()))
366  continue;
367  int d = d1;
368  if (tracklet->fpgat().value() < 0.0)
369  d = -d1;
370  if (d == tracklet->disk()) { //All seeds in PS modules
371  disks[ndisks] = tracklet->disk();
372  dmatches.set(2 * d1 - 1);
373  diskmask |= (1 << (2 * (N_DISK - d1) + 1));
374  ndisks++;
375  continue;
376  }
377 
378  if (ndisks + nlayers >= N_FITSTUB)
379  continue;
380  if (tracklet->match(N_LAYER + abs(d) - 1)) {
381  const Residual& resid = tracklet->resid(N_LAYER + abs(d) - 1);
382  double pitch = settings_.stripPitch(resid.stubptr()->l1tstub()->isPSmodule());
383  if (std::abs(resid.stubptr()->l1tstub()->alpha(pitch)) < 1e-20) {
384  dmatches.set(2 * (N_DISK - d1));
385  diskmask |= (1 << (2 * (N_DISK - d1) + 1));
386  FPGAWord tmp;
387  tmp.set(diskmask, 10);
388  } else {
389  int ialpha = resid.stubptr()->alpha().value();
390  int nalpha = resid.stubptr()->alpha().nbits();
391  nalpha = nalpha - settings_.alphaBitsTable();
392  ialpha = (1 << (settings_.alphaBitsTable() - 1)) + (ialpha >> nalpha);
393 
394  alphaindex += ialpha * power;
396  dmatches.set(2 * (N_DISK - d1));
397  diskmask |= (1 << (2 * (N_DISK - d1)));
398  FPGAWord tmp;
399  tmp.set(diskmask, 10);
401  }
402 
403  alpha[ndisks] = resid.stubptr()->l1tstub()->alpha(pitch);
404  assert(std::abs(resid.phiresidapprox()) < 0.2);
405  phiresid[nlayers + ndisks] = resid.phiresidapprox();
406  zresid[nlayers + ndisks] = resid.rzresidapprox();
407  assert(std::abs(resid.phiresid()) < 0.2);
408  phiresidexact[nlayers + ndisks] = resid.phiresid();
409  zresidexact[nlayers + ndisks] = resid.rzresid();
410  iphiresid[nlayers + ndisks] = resid.fpgaphiresid().value();
411  izresid[nlayers + ndisks] = resid.fpgarzresid().value();
412 
413  disks[ndisks++] = d;
414  }
415  }
416  }
417 
418  int rinvindex =
419  (1 << (settings_.nrinvBitsTable() - 1)) * rinv / settings_.rinvmax() + (1 << (settings_.nrinvBitsTable() - 1));
420  if (rinvindex < 0)
421  rinvindex = 0;
422  if (rinvindex >= (1 << settings_.nrinvBitsTable()))
423  rinvindex = (1 << settings_.nrinvBitsTable()) - 1;
424 
425  const TrackDer* derivatives = derTable.getDerivatives(layermask, diskmask, alphaindex, rinvindex);
426 
427  if (derivatives == nullptr) {
428  if (settings_.warnNoDer()) {
429  FPGAWord tmpl, tmpd;
430  tmpl.set(layermask, 6);
431  tmpd.set(diskmask, 10);
432  edm::LogVerbatim("Tracklet") << "No derivative for layermask, diskmask : " << layermask << " " << tmpl.str()
433  << " " << diskmask << " " << tmpd.str() << " eta = " << asinh(t);
434  }
435  return;
436  }
437 
438  double ttabi = TrackDerTable::tpar(settings_, diskmask, layermask);
439  if (t < 0.0)
440  ttabi = -ttabi;
441  double ttab = ttabi;
442 
443  if (settings_.debugTracklet()) {
444  edm::LogVerbatim("Tracklet") << "Doing trackfit in " << getName();
445  }
446 
447  int sign = 1;
448  if (t < 0.0)
449  sign = -1;
450 
451  double rstub[6];
452 
453  double realrstub[3];
454  realrstub[0] = -1.0;
455  realrstub[1] = -1.0;
456  realrstub[2] = -1.0;
457 
458  for (unsigned i = 0; i < nlayers; i++) {
459  r[i] = settings_.rmean(layers[i] - 1);
460  if (layers[i] == tracklet->layer()) {
461  if (tracklet->isOverlap()) {
462  realrstub[i] = tracklet->outerFPGAStub()->l1tstub()->r();
463  } else {
464  realrstub[i] = tracklet->innerFPGAStub()->l1tstub()->r();
465  }
466  }
467  if (layers[i] == tracklet->layer() + 1) {
468  realrstub[i] = tracklet->outerFPGAStub()->l1tstub()->r();
469  }
470  if (tracklet->match(layers[i] - 1) && layers[i] < 4) {
471  const Stub* stubptr = tracklet->resid(layers[i] - 1).stubptr();
472  realrstub[i] = stubptr->l1tstub()->r();
473  assert(std::abs(realrstub[i] - r[i]) < 5.0);
474  }
475  rstub[i] = r[i];
476  }
477  for (unsigned i = 0; i < ndisks; i++) {
478  z[i] = sign * settings_.zmean(abs(disks[i]) - 1);
479  rstub[i + nlayers] = z[i] / ttabi;
480  }
481 
482  double D[N_FITPARAM][N_FITSTUB * 2];
483  double MinvDt[N_FITPARAM][N_FITSTUB * 2];
484  int iD[N_FITPARAM][N_FITSTUB * 2];
485  int iMinvDt[N_FITPARAM][N_FITSTUB * 2];
486  double sigma[N_FITSTUB * 2];
487  double kfactor[N_FITSTUB * 2];
488 
489  unsigned int n = nlayers + ndisks;
490 
491  if (settings_.exactderivatives()) {
493  settings_, nlayers, r, ndisks, z, alpha, t, rinv, D, iD, MinvDt, iMinvDt, sigma, kfactor);
494  ttabi = t;
495  ttab = t;
496  } else {
499  settings_, nlayers, r, ndisks, z, alpha, t, rinv, D, iD, MinvDt, iMinvDt, sigma, kfactor);
500 
501  double MinvDtDummy[N_FITPARAM][N_FITSTUB * 2];
502  derivatives->fill(tracklet->fpgat().value(), MinvDtDummy, iMinvDt);
503  ttab = t;
504  } else {
505  derivatives->fill(tracklet->fpgat().value(), MinvDt, iMinvDt);
506  }
507  }
508 
509  if (!settings_.exactderivatives()) {
510  for (unsigned int i = 0; i < nlayers; i++) {
511  if (r[i] > settings_.rPS2S())
512  continue;
513  for (unsigned int ii = 0; ii < nlayers; ii++) {
514  if (r[ii] > settings_.rPS2S())
515  continue;
516 
517  double tder = derivatives->tdzcorr(i, ii);
518  double zder = derivatives->z0dzcorr(i, ii);
519 
520  double dr = realrstub[i] - r[i];
521 
522  MinvDt[2][2 * ii + 1] += dr * tder;
523  MinvDt[3][2 * ii + 1] += dr * zder;
524 
525  int itder = derivatives->itdzcorr(i, ii);
526  int izder = derivatives->iz0dzcorr(i, ii);
527 
528  int idr = dr / settings_.kr();
529 
530  iMinvDt[2][2 * ii + 1] += ((idr * itder) >> settings_.rcorrbits());
531  iMinvDt[3][2 * ii + 1] += ((idr * izder) >> settings_.rcorrbits());
532  }
533  }
534  }
535 
536  double rinvseed = tracklet->rinvapprox();
537  double phi0seed = tracklet->phi0approx();
538  double tseed = tracklet->tapprox();
539  double z0seed = tracklet->z0approx();
540 
541  double rinvseedexact = tracklet->rinv();
542  double phi0seedexact = tracklet->phi0();
543  double tseedexact = tracklet->t();
544  double z0seedexact = tracklet->z0();
545 
546  double chisqseedexact = 0.0;
547 
548  double delta[2 * N_FITSTUB];
549  double deltaexact[2 * N_FITSTUB];
550  int idelta[2 * N_FITSTUB];
551 
552  for (unsigned int i = 0; i < 2 * N_FITSTUB; i++) {
553  delta[i] = 0.0;
554  deltaexact[i] = 0.0;
555  idelta[i] = 0;
556  }
557 
558  int j = 0;
559 
560  for (unsigned int i = 0; i < n; i++) {
561  if (i >= nlayers) {
562  iphiresid[i] *= (t / ttabi);
563  phiresid[i] *= (t / ttab);
564  phiresidexact[i] *= (t / ttab);
565  }
566 
567  idelta[j] = iphiresid[i];
568  delta[j] = phiresid[i];
569  if (std::abs(phiresid[i]) > 0.2) {
570  edm::LogWarning("Tracklet") << getName() << " WARNING too large phiresid: " << phiresid[i] << " "
571  << phiresidexact[i];
572  }
573  assert(std::abs(phiresid[i]) < 1.0);
574  assert(std::abs(phiresidexact[i]) < 1.0);
575  deltaexact[j++] = phiresidexact[i];
576 
577  idelta[j] = izresid[i];
578  delta[j] = zresid[i];
579  deltaexact[j++] = zresidexact[i];
580 
581  chisqseedexact += (deltaexact[j - 2] * deltaexact[j - 2] + deltaexact[j - 1] * deltaexact[j - 1]);
582  }
583  assert(j <= 12);
584 
585  double drinv = 0.0;
586  double dphi0 = 0.0;
587  double dt = 0.0;
588  double dz0 = 0.0;
589 
590  double drinvexact = 0.0;
591  double dphi0exact = 0.0;
592  double dtexact = 0.0;
593  double dz0exact = 0.0;
594 
595  int idrinv = 0;
596  int idphi0 = 0;
597  int idt = 0;
598  int idz0 = 0;
599 
600  double drinv_cov = 0.0;
601  double dphi0_cov = 0.0;
602  double dt_cov = 0.0;
603  double dz0_cov = 0.0;
604 
605  double drinv_covexact = 0.0;
606  double dphi0_covexact = 0.0;
607  double dt_covexact = 0.0;
608  double dz0_covexact = 0.0;
609 
610  for (unsigned int j = 0; j < 2 * n; j++) {
611  drinv -= MinvDt[0][j] * delta[j];
612  dphi0 -= MinvDt[1][j] * delta[j];
613  dt -= MinvDt[2][j] * delta[j];
614  dz0 -= MinvDt[3][j] * delta[j];
615 
616  drinv_cov += D[0][j] * delta[j];
617  dphi0_cov += D[1][j] * delta[j];
618  dt_cov += D[2][j] * delta[j];
619  dz0_cov += D[3][j] * delta[j];
620 
621  drinvexact -= MinvDt[0][j] * deltaexact[j];
622  dphi0exact -= MinvDt[1][j] * deltaexact[j];
623  dtexact -= MinvDt[2][j] * deltaexact[j];
624  dz0exact -= MinvDt[3][j] * deltaexact[j];
625 
626  drinv_covexact += D[0][j] * deltaexact[j];
627  dphi0_covexact += D[1][j] * deltaexact[j];
628  dt_covexact += D[2][j] * deltaexact[j];
629  dz0_covexact += D[3][j] * deltaexact[j];
630 
631  idrinv += ((iMinvDt[0][j] * idelta[j]));
632  idphi0 += ((iMinvDt[1][j] * idelta[j]));
633  idt += ((iMinvDt[2][j] * idelta[j]));
634  idz0 += ((iMinvDt[3][j] * idelta[j]));
635 
636  if (false && j % 2 == 0) {
637  edm::LogVerbatim("Tracklet") << "DEBUG CHI2FIT " << j << " " << rinvseed << " + " << MinvDt[0][j] * delta[j]
638  << " " << MinvDt[0][j] << " " << delta[j] * rstub[j / 2] * 10000 << " \n"
639  << j << " " << tracklet->fpgarinv().value() * settings_.krinvpars() << " + "
640  << ((iMinvDt[0][j] * idelta[j])) * settings_.krinvpars() / 1024.0 << " "
641  << iMinvDt[0][j] * settings_.krinvpars() / settings_.kphi() / 1024.0 << " "
642  << idelta[j] * settings_.kphi() * rstub[j / 2] * 10000 << " " << idelta[j];
643  }
644  }
645 
646  double deltaChisqexact =
647  drinvexact * drinv_covexact + dphi0exact * dphi0_covexact + dtexact * dt_covexact + dz0exact * dz0_covexact;
648 
649  int irinvseed = tracklet->fpgarinv().value();
650  int iphi0seed = tracklet->fpgaphi0().value();
651 
652  int itseed = tracklet->fpgat().value();
653  int iz0seed = tracklet->fpgaz0().value();
654 
655  int irinvfit = irinvseed + ((idrinv + (1 << settings_.fitrinvbitshift())) >> settings_.fitrinvbitshift());
656 
657  int iphi0fit = iphi0seed + (idphi0 >> settings_.fitphi0bitshift());
658  int itfit = itseed + (idt >> settings_.fittbitshift());
659 
660  int iz0fit = iz0seed + (idz0 >> settings_.fitz0bitshift());
661 
662  double rinvfit = rinvseed - drinv;
663  double phi0fit = phi0seed - dphi0;
664 
665  double tfit = tseed - dt;
666  double z0fit = z0seed - dz0;
667 
668  double rinvfitexact = rinvseedexact - drinvexact;
669  double phi0fitexact = phi0seedexact - dphi0exact;
670 
671  double tfitexact = tseedexact - dtexact;
672  double z0fitexact = z0seedexact - dz0exact;
673 
674  double chisqfitexact = chisqseedexact + deltaChisqexact;
675 
677  bool NewChisqDebug = false;
678  double chisqfit = 0.0;
679  uint ichisqfit = 0;
680 
681  double phifactor;
682  double rzfactor;
683  double iphifactor;
684  double irzfactor;
685  int k = 0; // column index of D matrix
686 
687  if (NewChisqDebug) {
688  edm::LogVerbatim("Tracklet") << "OG chisq: \n"
689  << "drinv/cov = " << drinv << "/" << drinv_cov << " \n"
690  << "dphi0/cov = " << drinv << "/" << dphi0_cov << " \n"
691  << "dt/cov = " << drinv << "/" << dt_cov << " \n"
692  << "dz0/cov = " << drinv << "/" << dz0_cov << "\n";
693  std::string myout = "D[0][k]= ";
694  for (unsigned int i = 0; i < 2 * n; i++) {
695  myout += std::to_string(D[0][i]);
696  myout += ", ";
697  }
698  edm::LogVerbatim("Tracklet") << myout;
699  }
700 
701  for (unsigned int i = 0; i < n; i++) { // loop over stubs
702 
703  phifactor = rstub[k / 2] * delta[k] / sigma[k] + D[0][k] * drinv + D[1][k] * dphi0 + D[2][k] * dt + D[3][k] * dz0;
704  iphifactor = kfactor[k] * rstub[k / 2] * idelta[k] * (1 << settings_.chisqphifactbits()) / sigma[k] -
705  iD[0][k] * idrinv - iD[1][k] * idphi0 - iD[2][k] * idt - iD[3][k] * idz0;
706 
707  if (NewChisqDebug) {
708  edm::LogVerbatim("Tracklet") << "delta[k]/sigma = " << delta[k] / sigma[k] << " delta[k] = " << delta[k] << "\n"
709  << "sum = " << phifactor - delta[k] / sigma[k] << " drinvterm = " << D[0][k] * drinv
710  << " dphi0term = " << D[1][k] * dphi0 << " dtterm = " << D[2][k] * dt
711  << " dz0term = " << D[3][k] * dz0 << "\n phifactor = " << phifactor;
712  }
713 
714  chisqfit += phifactor * phifactor;
715  ichisqfit += iphifactor * iphifactor / (1 << (2 * settings_.chisqphifactbits() - 4));
716 
717  k++;
718 
719  rzfactor = delta[k] / sigma[k] + D[0][k] * drinv + D[1][k] * dphi0 + D[2][k] * dt + D[3][k] * dz0;
720  irzfactor = kfactor[k] * idelta[k] * (1 << settings_.chisqzfactbits()) / sigma[k] - iD[0][k] * idrinv -
721  iD[1][k] * idphi0 - iD[2][k] * idt - iD[3][k] * idz0;
722 
723  if (NewChisqDebug) {
724  edm::LogVerbatim("Tracklet") << "delta[k]/sigma = " << delta[k] / sigma[k] << " delta[k] = " << delta[k] << "\n"
725  << "sum = " << rzfactor - delta[k] / sigma[k] << " drinvterm = " << D[0][k] * drinv
726  << " dphi0term = " << D[1][k] * dphi0 << " dtterm = " << D[2][k] * dt
727  << " dz0term = " << D[3][k] * dz0 << "\n rzfactor = " << rzfactor;
728  }
729 
730  chisqfit += rzfactor * rzfactor;
731  ichisqfit += irzfactor * irzfactor / (1 << (2 * settings_.chisqzfactbits() - 4));
732 
733  k++;
734  }
735 
736  if (settings_.writeMonitorData("ChiSq")) {
737  globals_->ofstream("chisq.txt") << asinh(itfit * settings_.ktpars()) << " " << chisqfit << " " << ichisqfit / 16.0
738  << endl;
739  }
740 
741  // Chisquare per DOF capped out at 11 bits, so 15 is an educated guess
742  if (ichisqfit >= (1 << 15)) {
743  if (NewChisqDebug) {
744  edm::LogVerbatim("Tracklet") << "CHISQUARE (" << ichisqfit << ") LARGER THAN 11 BITS!";
745  }
746  ichisqfit = (1 << 15) - 1;
747  }
748 
749  // Eliminate lower bits to fit in 8 bits
750  ichisqfit = ichisqfit >> 7;
751  // Probably redundant... enforce 8 bit cap
752  if (ichisqfit >= (1 << 8))
753  ichisqfit = (1 << 8) - 1;
754 
755  double phicrit = phi0fit - asin(0.5 * settings_.rcrit() * rinvfit);
756  bool keep = (phicrit > settings_.phicritmin()) && (phicrit < settings_.phicritmax());
757 
758  if (!keep) {
759  return;
760  }
761 
762  // NOTE: setFitPars in Tracklet.h now accepts chi2 r-phi and chi2 r-z values. This class only has access
763  // to the composite chi2. When setting fit parameters on a tracklet, this places all of the chi2 into the
764  // r-phi fit, and sets the r-z fit value to zero.
765  //
766  // This is also true for the call to setFitPars in trackFitFake.
767  tracklet->setFitPars(rinvfit,
768  phi0fit,
769  0.0,
770  tfit,
771  z0fit,
772  chisqfit,
773  0.0,
774  rinvfitexact,
775  phi0fitexact,
776  0.0,
777  tfitexact,
778  z0fitexact,
779  chisqfitexact,
780  0.0,
781  irinvfit,
782  iphi0fit,
783  0,
784  itfit,
785  iz0fit,
786  ichisqfit,
787  0,
788  0);
789 }
790 
791 void FitTrack::trackFitFake(Tracklet* tracklet, std::vector<const Stub*>&, std::vector<std::pair<int, int>>&) {
792  tracklet->setFitPars(tracklet->rinvapprox(),
793  tracklet->phi0approx(),
794  tracklet->d0approx(),
795  tracklet->tapprox(),
796  tracklet->z0approx(),
797  0.0,
798  0.0,
799  tracklet->rinv(),
800  tracklet->phi0(),
801  tracklet->d0(),
802  tracklet->t(),
803  tracklet->z0(),
804  0.0,
805  0.0,
806  tracklet->fpgarinv().value(),
807  tracklet->fpgaphi0().value(),
808  tracklet->fpgad0().value(),
809  tracklet->fpgat().value(),
810  tracklet->fpgaz0().value(),
811  0,
812  0,
813  0);
814  return;
815 }
816 
817 std::vector<Tracklet*> FitTrack::orderedMatches(vector<FullMatchMemory*>& fullmatch) {
818  std::vector<Tracklet*> tmp;
819 
820  std::vector<unsigned int> indexArray;
821  for (auto& imatch : fullmatch) {
822  //check that we have correct order
823  if (imatch->nMatches() > 1) {
824  for (unsigned int j = 0; j < imatch->nMatches() - 1; j++) {
825  assert(imatch->getTracklet(j)->TCID() <= imatch->getTracklet(j + 1)->TCID());
826  }
827  }
828 
829  if (settings_.debugTracklet() && imatch->nMatches() != 0) {
830  edm::LogVerbatim("Tracklet") << "orderedMatches: " << imatch->getName() << " " << imatch->nMatches();
831  }
832 
833  indexArray.push_back(0);
834  }
835 
836  int bestIndex = -1;
837  do {
838  int bestTCID = -1;
839  bestIndex = -1;
840  for (unsigned int i = 0; i < fullmatch.size(); i++) {
841  if (indexArray[i] >= fullmatch[i]->nMatches()) {
842  //skip as we were at the end
843  continue;
844  }
845  int TCID = fullmatch[i]->getTracklet(indexArray[i])->TCID();
846  if (TCID < bestTCID || bestTCID < 0) {
847  bestTCID = TCID;
848  bestIndex = i;
849  }
850  }
851  if (bestIndex != -1) {
852  tmp.push_back(fullmatch[bestIndex]->getTracklet(indexArray[bestIndex]));
853  indexArray[bestIndex]++;
854  }
855  } while (bestIndex != -1);
856 
857  for (unsigned int i = 0; i < tmp.size(); i++) {
858  if (i > 0) {
859  //This allows for equal TCIDs. This means that we can e.g. have a track seeded in L1L2 that projects to both L3 and D4.
860  //The algorithm will pick up the first hit and drop the second.
861  if (tmp[i - 1]->TCID() > tmp[i]->TCID()) {
862  edm::LogVerbatim("Tracklet") << "Wrong TCID ordering in " << getName() << " : " << tmp[i - 1]->TCID() << " "
863  << tmp[i]->TCID();
864  }
865  }
866  }
867 
868  return tmp;
869 }
870 
871 // Adds the fitted track to the output memories to be used by pure Tracklet algo.
872 // (Also used by Hybrid algo with non-exact Old KF emulation)
873 // Also create output streams, that bypass these memories, (so can include gaps in time),
874 // to be used by Hybrid case with exact New KF emulation.
875 
876 void FitTrack::execute(deque<string>& streamTrackRaw,
877  vector<deque<StubStreamData>>& streamsStubRaw,
878  unsigned int iSector) {
879  // merge
880  const std::vector<Tracklet*>& matches1 = orderedMatches(fullmatch1_);
881  const std::vector<Tracklet*>& matches2 = orderedMatches(fullmatch2_);
882  const std::vector<Tracklet*>& matches3 = orderedMatches(fullmatch3_);
883  const std::vector<Tracklet*>& matches4 = orderedMatches(fullmatch4_);
884 
885  iSector_ = iSector;
886 
887  if (settings_.debugTracklet() && (matches1.size() + matches2.size() + matches3.size() + matches4.size()) > 0) {
888  for (auto& imatch : fullmatch1_) {
889  edm::LogVerbatim("Tracklet") << imatch->getName() << " " << imatch->nMatches();
890  }
891  edm::LogVerbatim("Tracklet") << getName() << " matches : " << matches1.size() << " " << matches2.size() << " "
892  << matches3.size() << " " << matches4.size();
893  }
894 
895  unsigned int indexArray[4];
896  for (unsigned int i = 0; i < 4; i++) {
897  indexArray[i] = 0;
898  }
899 
900  unsigned int countAll = 0;
901  unsigned int countFit = 0;
902 
903  Tracklet* bestTracklet = nullptr;
904  do {
905  countAll++;
906  bestTracklet = nullptr;
907 
908  if (indexArray[0] < matches1.size()) {
909  if (bestTracklet == nullptr) {
910  bestTracklet = matches1[indexArray[0]];
911  } else {
912  if (matches1[indexArray[0]]->TCID() < bestTracklet->TCID())
913  bestTracklet = matches1[indexArray[0]];
914  }
915  }
916 
917  if (indexArray[1] < matches2.size()) {
918  if (bestTracklet == nullptr) {
919  bestTracklet = matches2[indexArray[1]];
920  } else {
921  if (matches2[indexArray[1]]->TCID() < bestTracklet->TCID())
922  bestTracklet = matches2[indexArray[1]];
923  }
924  }
925 
926  if (indexArray[2] < matches3.size()) {
927  if (bestTracklet == nullptr) {
928  bestTracklet = matches3[indexArray[2]];
929  } else {
930  if (matches3[indexArray[2]]->TCID() < bestTracklet->TCID())
931  bestTracklet = matches3[indexArray[2]];
932  }
933  }
934 
935  if (indexArray[3] < matches4.size()) {
936  if (bestTracklet == nullptr) {
937  bestTracklet = matches4[indexArray[3]];
938  } else {
939  if (matches4[indexArray[3]]->TCID() < bestTracklet->TCID())
940  bestTracklet = matches4[indexArray[3]];
941  }
942  }
943 
944  if (bestTracklet == nullptr)
945  break;
946 
947  //Counts total number of matched hits
948  int nMatches = 0;
949 
950  //Counts unique hits in each layer
951  int nMatchesUniq = 0;
952  bool match = false;
953 
954  while (indexArray[0] < matches1.size() && matches1[indexArray[0]] == bestTracklet) {
955  indexArray[0]++;
956  nMatches++;
957  match = true;
958  }
959 
960  if (match)
961  nMatchesUniq++;
962  match = false;
963 
964  while (indexArray[1] < matches2.size() && matches2[indexArray[1]] == bestTracklet) {
965  indexArray[1]++;
966  nMatches++;
967  match = true;
968  }
969 
970  if (match)
971  nMatchesUniq++;
972  match = false;
973 
974  while (indexArray[2] < matches3.size() && matches3[indexArray[2]] == bestTracklet) {
975  indexArray[2]++;
976  nMatches++;
977  match = true;
978  }
979 
980  if (match)
981  nMatchesUniq++;
982  match = false;
983 
984  while (indexArray[3] < matches4.size() && matches4[indexArray[3]] == bestTracklet) {
985  indexArray[3]++;
986  nMatches++;
987  match = true;
988  }
989 
990  if (match)
991  nMatchesUniq++;
992 
993  if (settings_.debugTracklet()) {
994  edm::LogVerbatim("Tracklet") << getName() << " : nMatches = " << nMatches << " nMatchesUniq = " << nMatchesUniq
995  << " " << asinh(bestTracklet->t());
996  }
997 
998  std::vector<const Stub*> trackstublist;
999  std::vector<std::pair<int, int>> stubidslist;
1000  // Track Builder cut of >= 4 layers with stubs.
1001  if ((bestTracklet->getISeed() >= (int)N_SEED_PROMPT && nMatchesUniq >= 1) ||
1002  nMatchesUniq >= 2) { //For seeds index >=8 (triplet seeds), there are three stubs associated from start.
1003  countFit++;
1004 
1005 #ifdef USEHYBRID
1006  if (settings_.fakefit()) {
1007  trackFitFake(bestTracklet, trackstublist, stubidslist);
1008  } else {
1009  trackFitKF(bestTracklet, trackstublist, stubidslist);
1010  }
1011 #else
1012  if (settings_.fakefit()) {
1013  trackFitFake(bestTracklet, trackstublist, stubidslist);
1014  } else {
1015  trackFitChisq(bestTracklet, trackstublist, stubidslist);
1016  }
1017 #endif
1018 
1019  if (settings_.removalType() == "merge") {
1020  trackfit_->addStubList(trackstublist);
1021  trackfit_->addStubidsList(stubidslist);
1022  bestTracklet->setTrackIndex(trackfit_->nTracks());
1023  trackfit_->addTrack(bestTracklet);
1024  } else if (bestTracklet->fit()) {
1025  assert(trackfit_ != nullptr);
1026  if (settings_.writeMonitorData("Seeds")) {
1027  ofstream fout("seeds.txt", ofstream::app);
1028  fout << __FILE__ << ":" << __LINE__ << " " << name_ << "_"
1029  << " " << bestTracklet->getISeed() << endl;
1030  fout.close();
1031  }
1032  bestTracklet->setTrackIndex(trackfit_->nTracks());
1033  trackfit_->addTrack(bestTracklet);
1034  }
1035  }
1036 
1037  // store bit and clock accurate TB output
1038  if (settings_.storeTrackBuilderOutput() && bestTracklet) {
1039  // add gap if enough layer to form track
1040  if (!bestTracklet->fit()) {
1041  static const string invalid = "0";
1042  streamTrackRaw.emplace_back(invalid);
1043  for (auto& stream : streamsStubRaw)
1044  stream.emplace_back(StubStreamData());
1045  continue;
1046  }
1047  // convert Track word
1048  const string rinv = bestTracklet->fpgarinv().str();
1049  const string phi0 = bestTracklet->fpgaphi0().str();
1050  const string z0 = bestTracklet->fpgaz0().str();
1051  const string t = bestTracklet->fpgat().str();
1052  const int seedType = bestTracklet->getISeed();
1053  const string seed = TTBV(seedType, settings_.nbitsseed()).str();
1054  const string valid("1");
1055  streamTrackRaw.emplace_back(valid + seed + rinv + phi0 + z0 + t);
1056 
1057  unsigned int ihit(0);
1058  for (unsigned int ilayer = 0; ilayer < N_LAYER + N_DISK; ilayer++) {
1059  if (bestTracklet->match(ilayer)) {
1060  const Residual& resid = bestTracklet->resid(ilayer);
1061  // create bit accurate 64 bit word
1062  const string valid("1");
1063  string r = resid.stubptr()->r().str();
1064  const string& phi = resid.fpgaphiresid().str();
1065  const string& rz = resid.fpgarzresid().str();
1066  const L1TStub* stub = resid.stubptr()->l1tstub();
1067  static constexpr int widthDisk2Sidentifier = 8;
1068  bool disk2S = (stub->disk() != 0) && (stub->isPSmodule() == 0);
1069  if (disk2S)
1070  r = string(widthDisk2Sidentifier, '0') + r;
1071  // store seed, L1TStub, and bit accurate 64 bit word in clock accurate output
1072  streamsStubRaw[ihit++].emplace_back(seedType, *stub, valid + r + phi + rz);
1073  }
1074  }
1075  // fill all layer with no stubs with gaps
1076  while (ihit < streamsStubRaw.size()) {
1077  streamsStubRaw[ihit++].emplace_back();
1078  }
1079  }
1080 
1081  } while (bestTracklet != nullptr && countAll < settings_.maxStep("TB"));
1082 
1083  if (settings_.writeMonitorData("FT")) {
1084  globals_->ofstream("fittrack.txt") << getName() << " " << countAll << " " << countFit << endl;
1085  }
1086 }
Log< level::Info, true > LogVerbatim
float dt
Definition: AMPTWrapper.h:136
const FPGAWord & fpgarinv() const
Definition: Tracklet.h:132
int chisqzfactbits() const
Definition: Settings.h:393
double t() const
Definition: Tracklet.h:123
double phiresid() const
Definition: Residual.h:47
double tdzcorr(int i, int j) const
Definition: TrackDer.h:66
float alpha
Definition: AMPTWrapper.h:105
const Stub * innerFPGAStub()
Definition: Tracklet.h:61
int nrinvBitsTable() const
Definition: Settings.h:219
constexpr int N_DISK
Definition: Settings.h:22
unsigned int maxStep(std::string module) const
Definition: Settings.h:116
double z0dzcorr(int i, int j) const
Definition: TrackDer.h:67
const FPGAWord & r() const
Definition: Stub.h:60
double rPS2S() const
Definition: Settings.h:334
std::string name_
Definition: ProcessBase.h:38
const Residual & resid(unsigned int layerdisk)
Definition: Tracklet.h:110
static void calculateDerivatives(Settings const &settings, unsigned int nlayers, double r[N_LAYER], unsigned int ndisks, double z[N_DISK], double alpha[N_DISK], double t, double rinv, double D[N_FITPARAM][N_FITSTUB *2], int iD[N_FITPARAM][N_FITSTUB *2], double MinvDt[N_FITPARAM][N_FITSTUB *2], int iMinvDt[N_FITPARAM][N_FITSTUB *2], double sigma[N_FITSTUB *2], double kfactor[N_FITSTUB *2])
const Stub * outerFPGAStub()
Definition: Tracklet.h:65
int disk() const
Definition: Tracklet.cc:782
bool isOverlap() const
Definition: Tracklet.h:203
int alphaBitsTable() const
Definition: Settings.h:218
tuple disks
Definition: alignBH_cfg.py:13
Bit vector used by Track Trigger emulators. Mainly used to convert integers into arbitrary (within ma...
Definition: TTBV.h:20
void addTrack(Tracklet *tracklet)
std::vector< TrackletParametersMemory * > seedtracklet_
Definition: FitTrack.h:47
double rzresid() const
Definition: Residual.h:52
const FPGAWord & fpgaphiresid() const
Definition: Residual.h:32
int getEntries() const
Definition: TrackDerTable.h:37
const FPGAWord & fpgaz0() const
Definition: Tracklet.h:136
double rinvmax() const
Definition: Settings.h:214
unsigned int nbitsseed() const
Definition: Settings.h:285
const FPGAWord & fpgaphi0() const
Definition: Tracklet.h:133
Settings const & settings_
Definition: ProcessBase.h:40
double phi0() const
Definition: Tracklet.h:121
Globals * globals_
Definition: ProcessBase.h:41
std::string to_string(const V &value)
Definition: OMSAccess.h:77
bool exactderivatives() const
Definition: Settings.h:233
bool exactderivativesforfloating() const
Definition: Settings.h:234
double ktpars() const
Definition: Settings.h:402
bool writetrace() const
Definition: Settings.h:183
void trackFitKF(Tracklet *tracklet, std::vector< const Stub *> &trackstublist, std::vector< std::pair< int, int >> &stubidslist)
double krinvpars() const
Definition: Settings.h:397
void trackFitChisq(Tracklet *tracklet, std::vector< const Stub *> &, std::vector< std::pair< int, int >> &)
Definition: FitTrack.cc:141
uint32_t T const *__restrict__ uint32_t const *__restrict__ int32_t int Histo::index_type cudaStream_t stream
const FPGAWord & fpgat() const
Definition: Tracklet.h:135
void setTrackIndex(int index)
Definition: Tracklet.cc:813
assert(be >=bs)
void addOutput(MemoryBase *memory, std::string output) override
Definition: FitTrack.cc:19
int itdzcorr(int i, int j) const
Definition: TrackDer.h:78
int TCID() const
Definition: Tracklet.h:214
void addStubList(std::vector< const Stub *> stublist)
int fittbitshift() const
Definition: Settings.h:386
int fitz0bitshift() const
Definition: Settings.h:387
static std::string const input
Definition: EdmProvDump.cc:50
unsigned int isPSmodule() const
Definition: L1TStub.h:96
TrackFitMemory * trackfit_
Definition: FitTrack.h:55
std::vector< Tracklet * > orderedMatches(std::vector< FullMatchMemory *> &fullmatch)
Definition: FitTrack.cc:817
bool fit() const
Definition: Tracklet.h:197
constexpr std::array< uint8_t, layerIndexSize< TrackerTraits > > layer
int rcorrbits() const
Definition: Settings.h:390
std::vector< FullMatchMemory * > fullmatch4_
Definition: FitTrack.h:51
const FPGAWord & fpgarzresid() const
Definition: Residual.h:37
const Stub * middleFPGAStub()
Definition: Tracklet.h:63
double phi0approx() const
Definition: Tracklet.h:127
static double tpar(Settings const &settings, int diskmask, int layermask)
double rmean(unsigned int iLayer) const
Definition: Settings.h:164
double rinv() const
Definition: Tracklet.h:120
double phicritmin() const
Definition: Settings.h:303
constexpr unsigned int N_TRKLSEED
Definition: Settings.h:973
double stripPitch(bool isPSmodule) const
Definition: Settings.h:270
void addInput(MemoryBase *memory, std::string input) override
Definition: FitTrack.cc:34
void fill(int t, double MinvDt[N_FITPARAM][N_FITSTUB *2], int iMinvDt[N_FITPARAM][N_FITSTUB *2]) const
Definition: TrackDer.cc:42
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
int value() const
Definition: FPGAWord.h:24
unsigned int nTracks() const
std::string removalType() const
Definition: Settings.h:239
double tapprox() const
Definition: Tracklet.h:129
bool fakefit() const
Definition: Settings.h:243
unsigned int iSector_
Definition: FitTrack.h:53
L1TStub * l1tstub()
Definition: Stub.h:77
int disk() const
Definition: L1TStub.h:46
const TrackDer * getDerivatives(int index) const
Definition: TrackDerTable.h:24
std::string const & fitPatternFile() const
Definition: Settings.h:66
const FPGAWord & fpgad0() const
Definition: Tracklet.h:134
bool writeMonitorData(std::string module) const
Definition: Settings.h:109
bool isBarrel() const
Definition: Tracklet.h:202
double phiresidapprox() const
Definition: Residual.h:57
d
Definition: ztail.py:151
double zmean(unsigned int iDisk) const
Definition: Settings.h:167
ii
Definition: cuy.py:589
std::vector< FullMatchMemory * > fullmatch1_
Definition: FitTrack.h:48
double alpha(double pitch) const
Definition: L1TStub.cc:78
bool debugTracklet() const
Definition: Settings.h:182
double rzresidapprox() const
Definition: Residual.h:62
double rinvapprox() const
Definition: Tracklet.h:126
double d0() const
Definition: Tracklet.h:122
double kr() const
Definition: Settings.h:316
constexpr unsigned int power(unsigned int base, unsigned int exponent)
std::vector< FullMatchMemory * > fullmatch2_
Definition: FitTrack.h:49
DecomposeProduct< arg, typename Div::arg > D
Definition: Factorize.h:141
bool storeTrackBuilderOutput() const
Definition: Settings.h:245
double z0approx() const
Definition: Tracklet.h:130
int nbits() const
Definition: FPGAWord.h:25
void execute(std::deque< std::string > &streamTrackRaw, std::vector< std::deque< StubStreamData >> &stubStream, unsigned int iSector)
Definition: FitTrack.cc:876
double rinv(double phi1, double phi2, double r1, double r2)
Definition: Util.h:49
int iz0dzcorr(int i, int j) const
Definition: TrackDer.h:79
int getISeed() const
Definition: Tracklet.cc:801
void set(int value, int nbits, bool positive=true, int line=-1, const char *file=nullptr)
Definition: FPGAWord.cc:14
constexpr unsigned int N_FITPARAM
Definition: Settings.h:977
void readPatternFile(std::string fileName)
const Stub * stubptr() const
Definition: Residual.h:67
double d0approx() const
Definition: Tracklet.h:128
double z0() const
Definition: Tracklet.h:124
const FPGAWord & alpha() const
Definition: Stub.h:64
double r() const
Definition: L1TStub.h:60
bool match(unsigned int layerdisk)
Definition: Tracklet.h:105
int isDisk() const
Definition: Tracklet.h:204
std::ofstream & ofstream(std::string fname)
Definition: Globals.cc:44
constexpr unsigned int N_FITSTUB
Definition: Settings.h:978
int fitrinvbitshift() const
Definition: Settings.h:384
void setFitPars(double rinvfit, double phi0fit, double d0fit, double tfit, double z0fit, double chisqrphifit, double chisqrzfit, double rinvfitexact, double phi0fitexact, double d0fitexact, double tfitexact, double z0fitexact, double chisqrphifitexact, double chisqrzfitexact, int irinvfit, int iphi0fit, int id0fit, int itfit, int iz0fit, int ichisqrphifit, int ichisqrzfit, int hitpattern, const std::vector< const L1TStub *> &l1stubs=std::vector< const L1TStub *>())
Definition: Tracklet.cc:515
double phicritmax() const
Definition: Settings.h:304
int chisqphifactbits() const
Definition: Settings.h:392
TrackDerTable *& trackDerTable()
Definition: Globals.h:40
Definition: output.py:1
void addStubidsList(std::vector< std::pair< int, int >> stubidslist)
Log< level::Warning, false > LogWarning
const unsigned int kfactor
void trackFitFake(Tracklet *tracklet, std::vector< const Stub *> &, std::vector< std::pair< int, int >> &)
Definition: FitTrack.cc:791
int layer() const
Definition: Tracklet.cc:773
static constexpr float d1
double kphi() const
Definition: Settings.h:310
#define str(s)
tmp
align.sh
Definition: createJobs.py:716
int fitphi0bitshift() const
Definition: Settings.h:385
bool doKF() const
Definition: Settings.h:241
std::string const & getName() const
Definition: ProcessBase.h:22
std::vector< FullMatchMemory * > fullmatch3_
Definition: FitTrack.h:50
std::string str() const
Definition: FPGAWord.cc:54
bool warnNoDer() const
Definition: Settings.h:186
constexpr unsigned int N_SEED_PROMPT
Definition: Settings.h:25
constexpr int N_LAYER
Definition: Settings.h:21
double rcrit() const
Definition: Settings.h:299