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HGCalDDDConstants.cc
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2 
18 
19 #include <algorithm>
20 #include <bitset>
21 #include <iterator>
22 #include <functional>
23 #include <numeric>
24 
25 //#define EDM_ML_DEBUG
26 using namespace geant_units::operators;
27 
29  : hgpar_(hp),
30  sqrt3_(std::sqrt(3.0)),
31  mode_(hgpar_->mode_),
32  fullAndPart_(((mode_ == HGCalGeometryMode::Hexagon8File) || (mode_ == HGCalGeometryMode::Hexagon8Module))) {
33 #ifdef EDM_ML_DEBUG
34  edm::LogVerbatim("HGCalGeom") << "Mode " << mode_ << " FullAndPart " << fullAndPart_;
35 #endif
36  if (waferHexagon6() || waferHexagon8()) {
39  hexside_ = 2.0 * rmax_ * tan30deg_;
40  hexsideT_ = 2.0 * rmaxT_ * tan30deg_;
41 #ifdef EDM_ML_DEBUG
42  edm::LogVerbatim("HGCalGeom") << "rmax_ " << rmax_ << ":" << rmaxT_ << ":" << hexside_ << ":" << hexsideT_
43  << " CellSize " << 0.5 * HGCalParameters::k_ScaleFromDDD * hgpar_->cellSize_[0] << ":"
45 #endif
46  }
47  // init maps and constants
48  modHalf_ = 0;
50  for (int simreco = 0; simreco < 2; ++simreco) {
51  tot_layers_[simreco] = layersInit((bool)simreco);
52  max_modules_layer_[simreco].resize(tot_layers_[simreco] + 1);
53  for (unsigned int layer = 1; layer <= tot_layers_[simreco]; ++layer) {
54  max_modules_layer_[simreco][layer] = modulesInit(layer, (bool)simreco);
55  if (simreco == 1) {
56  modHalf_ += max_modules_layer_[simreco][layer];
58 #ifdef EDM_ML_DEBUG
59  edm::LogVerbatim("HGCalGeom") << "Layer " << layer << " with " << max_modules_layer_[simreco][layer] << ":"
60  << modHalf_ << " modules in RECO";
61  } else {
62  edm::LogVerbatim("HGCalGeom") << "Layer " << layer << " with " << max_modules_layer_[simreco][layer]
63  << " modules in SIM";
64 #endif
65  }
66  }
67 #ifdef EDM_ML_DEBUG
68  edm::LogVerbatim("HGCalGeom") << "SimReco " << simreco << " with " << tot_layers_[simreco] << " Layers";
69 #endif
70  }
71  tot_wafers_ = wafers();
72 
73 #ifdef EDM_ML_DEBUG
74  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants initialized for " << name << " with " << layers(false) << ":"
75  << layers(true) << " layers, " << wafers() << ":" << 2 * modHalf_
76  << " wafers with maximum " << maxWafersPerLayer_ << " per layer and "
77  << "maximum of " << maxCells(false) << ":" << maxCells(true) << " cells";
78 #endif
79  if (waferHexagon6() || waferHexagon8()) {
80  int wminT(9999999), wmaxT(-9999999), kount1(0), kount2(0);
81  for (unsigned int i = 0; i < getTrFormN(); ++i) {
82  int lay0 = getTrForm(i).lay;
83  int wmin(9999999), wmax(-9999999), kount(0);
84  for (int wafer = 0; wafer < sectors(); ++wafer) {
85  bool waferIn = waferInLayer(wafer, lay0, true);
86  if (waferHexagon8()) {
87  int kndx = HGCalWaferIndex::waferIndex(lay0,
90  waferIn_[kndx] = waferIn;
91  }
92  if (waferIn) {
93  int waferU = ((waferHexagon6()) ? wafer : HGCalWaferIndex::waferU(hgpar_->waferCopy_[wafer]));
94  if (waferU < wmin)
95  wmin = waferU;
96  if (waferU > wmax)
97  wmax = waferU;
98  ++kount;
99  }
100  }
101  if (wminT > wmin)
102  wminT = wmin;
103  if (wmaxT < wmax)
104  wmaxT = wmax;
105  if (kount1 < kount)
106  kount1 = kount;
107  kount2 += kount;
108 #ifdef EDM_ML_DEBUG
109  int lay1 = getIndex(lay0, true).first;
110  edm::LogVerbatim("HGCalGeom") << "Index " << i << " Layer " << lay0 << ":" << lay1 << " Wafer " << wmin << ":"
111  << wmax << ":" << kount;
112 #endif
113  HGCWaferParam a1{{wmin, wmax, kount}};
114  waferLayer_[lay0] = a1;
115  }
116  waferMax_ = std::array<int, 4>{{wminT, wmaxT, kount1, kount2}};
117 #ifdef EDM_ML_DEBUG
118  edm::LogVerbatim("HGCalGeom") << "Overall wafer statistics: " << wminT << ":" << wmaxT << ":" << kount1 << ":"
119  << kount2;
120 #endif
121  }
122 }
123 
125 
126 std::pair<int, int> HGCalDDDConstants::assignCell(float x, float y, int lay, int subSec, bool reco) const {
127  const auto& index = getIndex(lay, reco);
128  if (index.first < 0)
129  return std::make_pair(-1, -1);
130  if (waferHexagon6()) {
131  float xx = (reco) ? x : HGCalParameters::k_ScaleFromDDD * x;
132  float yy = (reco) ? y : HGCalParameters::k_ScaleFromDDD * y;
133 
134  // First the wafer
135  int wafer = cellHex(xx, yy, rmax_, hgpar_->waferPosX_, hgpar_->waferPosY_);
136  if (wafer < 0 || wafer >= (int)(hgpar_->waferTypeT_.size())) {
137  edm::LogWarning("HGCalGeom") << "Wafer no. out of bound for " << wafer << ":" << (hgpar_->waferTypeT_).size()
138  << ":" << (hgpar_->waferPosX_).size() << ":" << (hgpar_->waferPosY_).size()
139  << " ***** ERROR *****";
140  return std::make_pair(-1, -1);
141  } else {
142  // Now the cell
143  xx -= hgpar_->waferPosX_[wafer];
144  yy -= hgpar_->waferPosY_[wafer];
145  if (hgpar_->waferTypeT_[wafer] == 1)
146  return std::make_pair(wafer,
147  cellHex(xx,
148  yy,
151  hgpar_->cellFineY_));
152  else
153  return std::make_pair(wafer,
154  cellHex(xx,
155  yy,
158  hgpar_->cellCoarseY_));
159  }
160  } else {
161  return std::make_pair(-1, -1);
162  }
163 }
164 
166  float x, float y, int lay, bool reco, bool extend, bool debug) const {
167  int waferU(0), waferV(0), waferType(-1), cellU(0), cellV(0);
168  if (waferHexagon8()) {
169  double xx = (reco) ? HGCalParameters::k_ScaleToDDD * x : x;
170  double yy = (reco) ? HGCalParameters::k_ScaleToDDD * y : y;
171  double wt(1.0);
172 #ifdef EDM_ML_DEBUG
173  edm::LogVerbatim("HGCalGeom") << "assignCellHex x " << x << ":" << xx << " y " << y << ":" << yy << " Lay " << lay;
174 #endif
175  waferFromPosition(xx, yy, lay, waferU, waferV, cellU, cellV, waferType, wt, extend, debug);
176  }
177  return std::array<int, 5>{{waferU, waferV, waferType, cellU, cellV}};
178 }
179 
180 std::array<int, 3> HGCalDDDConstants::assignCellTrap(float x, float y, float z, int layer, bool reco) const {
181  int irad(-1), iphi(-1), type(-1);
182  const auto& indx = getIndex(layer, reco);
183  if (indx.first < 0)
184  return std::array<int, 3>{{irad, iphi, type}};
185  double xx = (z > 0) ? x : -x;
186  double r = (reco ? std::sqrt(x * x + y * y) : HGCalParameters::k_ScaleFromDDD * std::sqrt(x * x + y * y));
187  double phi = (r == 0. ? 0. : std::atan2(y, xx));
188  if (phi < 0)
189  phi += (2.0 * M_PI);
191  auto ir = std::lower_bound(hgpar_->radiusLayer_[type].begin(), hgpar_->radiusLayer_[type].end(), r);
192  irad = (int)(ir - hgpar_->radiusLayer_[type].begin());
193  irad = std::clamp(irad, hgpar_->iradMinBH_[indx.first], hgpar_->iradMaxBH_[indx.first]);
194  iphi = 1 + (int)(phi / indx.second);
195 #ifdef EDM_ML_DEBUG
196  edm::LogVerbatim("HGCalGeom") << "assignCellTrap Input " << x << ":" << y << ":" << z << ":" << layer << ":" << reco
197  << " x|r " << xx << ":" << r << " phi " << phi << " o/p " << irad << ":" << iphi << ":"
198  << type;
199 #endif
200  return std::array<int, 3>{{irad, iphi, type}};
201 }
202 
203 std::pair<double, double> HGCalDDDConstants::cellEtaPhiTrap(int type, int irad) const {
204  double dr(0), df(0);
205  if (tileTrapezoid()) {
206  double r = 0.5 * ((hgpar_->radiusLayer_[type][irad - 1] + hgpar_->radiusLayer_[type][irad]));
207  dr = (hgpar_->radiusLayer_[type][irad] - hgpar_->radiusLayer_[type][irad - 1]);
208  df = r * hgpar_->cellSize_[type];
209  }
210  return std::make_pair(dr, df);
211 }
212 
213 bool HGCalDDDConstants::cellInLayer(int waferU, int waferV, int cellU, int cellV, int lay, bool reco) const {
214  const auto& indx = getIndex(lay, true);
215  if (indx.first >= 0) {
216  if (waferHexagon8() || waferHexagon6()) {
217  const auto& xy = ((waferHexagon8()) ? locateCell(lay, waferU, waferV, cellU, cellV, reco, true, false, false)
218  : locateCell(cellU, lay, waferU, reco));
219  double rpos = sqrt(xy.first * xy.first + xy.second * xy.second);
220  return ((rpos >= hgpar_->rMinLayHex_[indx.first]) && (rpos <= hgpar_->rMaxLayHex_[indx.first]));
221  } else {
222  return true;
223  }
224  } else {
225  return false;
226  }
227 }
228 
230  double thick(-1);
231  int type = waferType(layer, waferU, waferV, false);
232  if (type >= 0) {
233  if (waferHexagon8()) {
234  thick = 10000.0 * hgpar_->cellThickness_[type]; // cm to micron
235  } else if (waferHexagon6()) {
236  thick = 100.0 * (type + 1); // type = 1,2,3 for 100,200,300 micron
237  }
238  }
239  return thick;
240 }
241 
243  int indx = ((waferHexagon8()) ? ((type >= 1) ? 1 : 0) : ((type == 1) ? 1 : 0));
244  double cell = (tileTrapezoid() ? 0.5 * hgpar_->cellSize_[indx]
246  return cell;
247 }
248 
249 int32_t HGCalDDDConstants::cellType(int type, int cellU, int cellV, int iz, int fwdBack, int orient) const {
250  int placement = (orient < 0) ? HGCalCell::cellPlacementOld : HGCalCell::cellPlacementIndex(iz, fwdBack, orient);
251  int ncell = (type == 0) ? hgpar_->nCellsFine_ : hgpar_->nCellsCoarse_;
252  auto cellType = HGCalCell::cellType(cellU, cellV, ncell, placement);
253  return cellType.first;
254 }
255 
256 double HGCalDDDConstants::distFromEdgeHex(double x, double y, double z) const {
257  // Assming the point is within a hexagonal plane of the wafer, calculate
258  // the shortest distance from the edge
259  if (z < 0)
260  x = -x;
261  double dist(0);
262  // Input x, y in Geant4 unit and transformed to CMSSW standard
265  if (waferHexagon8()) {
266  int ll = layerIndex(getLayer(z, false), false);
267  xx -= hgpar_->xLayerHex_[ll];
268  yy -= hgpar_->yLayerHex_[ll];
269  }
270  int sizew = (int)(hgpar_->waferPosX_.size());
271  int wafer = sizew;
272  // Transform to the local coordinate frame of the wafer first
273  for (int k = 0; k < sizew; ++k) {
274  double dx = std::abs(xx - hgpar_->waferPosX_[k]);
275  double dy = std::abs(yy - hgpar_->waferPosY_[k]);
276  if ((dx <= rmax_) && (dy <= hexside_) && ((dy <= 0.5 * hexside_) || (dx * tan30deg_ <= (hexside_ - dy)))) {
277  wafer = k;
278  xx -= hgpar_->waferPosX_[k];
279  yy -= hgpar_->waferPosY_[k];
280  break;
281  }
282  }
283  // Look at only one quarter (both x,y are positive)
284  if (wafer < sizew) {
285  if (std::abs(yy) < 0.5 * hexside_) {
286  dist = rmax_ - std::abs(xx);
287  } else {
288  dist = 0.5 * ((rmax_ - std::abs(xx)) - sqrt3_ * (std::abs(yy) - 0.5 * hexside_));
289  }
290  } else {
291  dist = 0;
292  }
294 #ifdef EDM_ML_DEBUG
295  edm::LogVerbatim("HGCalGeom") << "DistFromEdgeHex: Local " << xx << ":" << yy << " wafer " << wafer << " flag "
296  << (wafer < sizew) << " Distance " << rmax_ << ":" << (rmax_ - std::abs(xx)) << ":"
297  << (std::abs(yy) - 0.5 * hexside_) << ":" << 0.5 * hexside_ << ":" << dist;
298 #endif
299  return dist;
300 }
301 
302 double HGCalDDDConstants::distFromEdgeTrap(double x, double y, double z) const {
303  // Assming the point is within the eta-phi plane of the scintillator tile,
304  // calculate the shortest distance from the edge
305  int lay = getLayer(z, false);
306  double xx = (z < 0) ? -x : x;
307  int indx = layerIndex(lay, false);
308  double r = HGCalParameters::k_ScaleFromDDD * std::sqrt(x * x + y * y);
309  double phi = (r == 0. ? 0. : std::atan2(y, xx));
310  if (phi < 0)
311  phi += (2.0 * M_PI);
312  int type = hgpar_->scintType(lay);
313  double cell = hgpar_->scintCellSize(lay);
314  // Compare with the center of the tile find distances along R and also phi
315  // Take the smaller value
316  auto ir = std::lower_bound(hgpar_->radiusLayer_[type].begin(), hgpar_->radiusLayer_[type].end(), r);
317  int irad = (int)(ir - hgpar_->radiusLayer_[type].begin());
318  irad = std::clamp(irad, hgpar_->iradMinBH_[indx], hgpar_->iradMaxBH_[indx]);
319  int iphi = 1 + (int)(phi / cell);
320  double dphi = std::max(0.0, (0.5 * cell - std::abs(phi - (iphi - 0.5) * cell)));
321  double dist = std::min((r - hgpar_->radiusLayer_[type][irad - 1]), (hgpar_->radiusLayer_[type][irad] - r));
322 #ifdef EDM_ML_DEBUG
323  edm::LogVerbatim("HGCalGeom") << "DistFromEdgeTrap: Global " << x << ":" << y << ":" << z << " Layer " << lay
324  << " Index " << indx << ":" << type << " xx " << xx << " R " << r << ":" << irad << ":"
325  << hgpar_->radiusLayer_[type][irad - 1] << ":" << hgpar_->radiusLayer_[type][irad]
326  << " Phi " << phi << ":" << iphi << ":" << (iphi - 0.5) * cell << " cell " << cell
327  << " Dphi " << dphi << " Dist " << dist << ":" << r * dphi;
328 #endif
329  return HGCalParameters::k_ScaleToDDD * std::min(r * dphi, dist);
330 }
331 
332 int HGCalDDDConstants::getLayer(double z, bool reco) const {
333  // Get the layer # from the gloabl z coordinate
334  unsigned int k = 0;
336  const auto& zLayerHex = hgpar_->zLayerHex_;
337  auto itr = std::find_if(zLayerHex.begin() + 1, zLayerHex.end(), [&k, &zz, &zLayerHex](double zLayer) {
338  ++k;
339  return zz < 0.5 * (zLayerHex[k - 1] + zLayerHex[k]);
340  });
341  int lay = (itr == zLayerHex.end()) ? static_cast<int>(zLayerHex.size()) : k;
342  if (waferHexagon6() && reco) {
343  int indx = layerIndex(lay, false);
344  if (indx >= 0)
345  lay = hgpar_->layerGroupO_[indx];
346  } else {
347  lay += (hgpar_->firstLayer_ - 1);
348  }
349  return lay;
350 }
351 
352 HGCalParameters::hgtrap HGCalDDDConstants::getModule(unsigned int indx, bool hexType, bool reco) const {
354  if (hexType) {
355  if (indx >= hgpar_->waferTypeL_.size())
356  edm::LogWarning("HGCalGeom") << "Wafer no. out bound for index " << indx << ":" << (hgpar_->waferTypeL_).size()
357  << ":" << (hgpar_->waferPosX_).size() << ":" << (hgpar_->waferPosY_).size()
358  << " ***** ERROR *****";
359  unsigned int type =
360  ((indx < hgpar_->waferTypeL_.size()) ? hgpar_->waferTypeL_[indx] - 1 : HGCSiliconDetId::HGCalCoarseThick);
361  mytr = hgpar_->getModule(type, reco);
362  } else {
363  mytr = hgpar_->getModule(indx, reco);
364  }
365  return mytr;
366 }
367 
368 std::vector<HGCalParameters::hgtrap> HGCalDDDConstants::getModules() const {
369  std::vector<HGCalParameters::hgtrap> mytrs;
370  for (unsigned int k = 0; k < hgpar_->moduleLayR_.size(); ++k)
371  mytrs.emplace_back(hgpar_->getModule(k, true));
372  return mytrs;
373 }
374 
375 int HGCalDDDConstants::getPhiBins(int lay) const { return (tileTrapezoid() ? hgpar_->scintCells(lay) : 0); }
376 
377 std::pair<int, int> HGCalDDDConstants::getREtaRange(int lay) const {
378  int irmin(0), irmax(0);
379  if (tileTrapezoid()) {
380  int indx = layerIndex(lay, false);
381  if ((indx >= 0) && (indx < static_cast<int>(hgpar_->iradMinBH_.size()))) {
382  irmin = hgpar_->iradMinBH_[indx];
383  irmax = hgpar_->iradMaxBH_[indx];
384  }
385  }
386  return std::make_pair(irmin, irmax);
387 }
388 
389 std::vector<HGCalParameters::hgtrform> HGCalDDDConstants::getTrForms() const {
390  std::vector<HGCalParameters::hgtrform> mytrs;
391  for (unsigned int k = 0; k < hgpar_->trformIndex_.size(); ++k)
392  mytrs.emplace_back(hgpar_->getTrForm(k));
393  return mytrs;
394 }
395 
397  // Get the module type for scinitllator
398  if (tileTrapezoid()) {
399  return hgpar_->scintType(layer);
400  } else {
401  return -1;
402  }
403 }
404 
406  // Get the module type for a silicon wafer
407  if (waferHexagon8()) {
409  return ((itr == hgpar_->typesInLayers_.end() ? 2 : hgpar_->waferTypeL_[itr->second]));
410  } else {
411  return -1;
412  }
413 }
414 
415 std::pair<double, double> HGCalDDDConstants::getXY(int layer, double x, double y, bool forwd) const {
416  int ll = layer - hgpar_->firstLayer_;
417  double x0(x), y0(y);
418  if ((!hgpar_->layerType_.empty()) && (ll < static_cast<int>(hgpar_->layerRotV_.size()))) {
419  if (forwd) {
420  x0 = x * hgpar_->layerRotV_[ll].first + y * hgpar_->layerRotV_[ll].second;
421  y0 = y * hgpar_->layerRotV_[ll].first - x * hgpar_->layerRotV_[ll].second;
422  } else {
423  x0 = x * hgpar_->layerRotV_[ll].first - y * hgpar_->layerRotV_[ll].second;
424  y0 = y * hgpar_->layerRotV_[ll].first + x * hgpar_->layerRotV_[ll].second;
425  }
426  }
427 #ifdef EDM_ML_DEBUG
428  double x1(x0), y1(y0);
429  if (ll < static_cast<int>(hgpar_->layerRotV_.size())) {
430  if (forwd) {
431  x1 = x0 * hgpar_->layerRotV_[ll].first - y0 * hgpar_->layerRotV_[ll].second;
432  y1 = y0 * hgpar_->layerRotV_[ll].first + x0 * hgpar_->layerRotV_[ll].second;
433  } else {
434  x1 = x0 * hgpar_->layerRotV_[ll].first + y0 * hgpar_->layerRotV_[ll].second;
435  y1 = y0 * hgpar_->layerRotV_[ll].first - x0 * hgpar_->layerRotV_[ll].second;
436  }
437  }
438  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants: Layer " << layer << ":" << ll << " mode " << forwd << " x " << x
439  << ":" << x0 << ":" << x1 << " y " << y << ":" << y0 << ":" << y1;
440 #endif
441  return std::make_pair(x0, y0);
442 }
443 
444 bool HGCalDDDConstants::isHalfCell(int waferType, int cell) const {
445  if (waferType < 1 || cell < 0)
446  return false;
447  return waferType == 2 ? hgpar_->cellCoarseHalf_[cell] : hgpar_->cellFineHalf_[cell];
448 }
449 
450 bool HGCalDDDConstants::isValidHex(int lay, int mod, int cell, bool reco) const {
451  // Check validity for a layer|wafer|cell of pre-TDR version
452  bool result(false), resultMod(false);
453  int cellmax(0);
454  if (waferHexagon6()) {
455  int32_t copyNumber = hgpar_->waferCopy_[mod];
456  result = ((lay > 0 && lay <= (int)(layers(reco))));
457  if (result) {
458  const int32_t lay_idx = reco ? (lay - 1) * 3 + 1 : lay;
459  const auto& the_modules = hgpar_->copiesInLayers_[lay_idx];
460  auto moditr = the_modules.find(copyNumber);
461  result = resultMod = (moditr != the_modules.end());
462 #ifdef EDM_ML_DEBUG
463  if (!result)
464  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants: Layer " << lay << ":" << lay_idx << " Copy " << copyNumber
465  << ":" << mod << " Flag " << result;
466 #endif
467  if (result) {
468  if (moditr->second >= 0) {
469  if (mod >= (int)(hgpar_->waferTypeT_.size()))
470  edm::LogWarning("HGCalGeom") << "Module no. out of bound for " << mod << " to be compared with "
471  << (hgpar_->waferTypeT_).size() << " ***** ERROR *****";
472  cellmax = ((hgpar_->waferTypeT_[mod] - 1 == HGCSiliconDetId::HGCalFine) ? (int)(hgpar_->cellFineX_.size())
473  : (int)(hgpar_->cellCoarseX_.size()));
474  result = (cell >= 0 && cell <= cellmax);
475  } else {
476  result = isValidCell(lay_idx, mod, cell);
477  }
478  }
479  }
480  }
481 
482 #ifdef EDM_ML_DEBUG
483  if (!result)
484  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants: Layer " << lay << ":"
485  << (lay > 0 && (lay <= (int)(layers(reco)))) << " Module " << mod << ":" << resultMod
486  << " Cell " << cell << ":" << cellmax << ":" << (cell >= 0 && cell <= cellmax) << ":"
487  << maxCells(reco);
488 #endif
489  return result;
490 }
491 
492 bool HGCalDDDConstants::isValidHex8(int layer, int modU, int modV, bool fullAndPart) const {
493  // Check validity for a layer|wafer|cell of post-TDR version
494  int indx = HGCalWaferIndex::waferIndex(layer, modU, modV);
495  auto itr = hgpar_->typesInLayers_.find(indx);
496 #ifdef EDM_ML_DEBUG
497  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants::isValidHex8:WaferType " << layer << ":" << modU << ":" << modV
498  << ":" << indx << " Test " << (itr != hgpar_->typesInLayers_.end());
499 #endif
500  if (itr == hgpar_->typesInLayers_.end())
501  return false;
502 
503  if (fullAndPart_) {
504  auto ktr = hgpar_->waferInfoMap_.find(indx);
505 #ifdef EDM_ML_DEBUG
506  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants::isValidHex8:WaferInfoMap " << layer << ":" << modU << ":"
507  << modV << ":" << indx << " Test " << (ktr != hgpar_->waferInfoMap_.end());
508 #endif
509  if (ktr == hgpar_->waferInfoMap_.end())
510  return false;
511  } else {
512  auto jtr = waferIn_.find(indx);
513 #ifdef EDM_ML_DEBUG
514  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants::isValidHex8:WaferIn " << jtr->first << ":" << jtr->second;
515 #endif
516  if (!(jtr->second))
517  return false;
518  }
519 
520  if (fullAndPart || fullAndPart_) {
521  auto ktr = hgpar_->waferTypes_.find(indx);
522  if (ktr != hgpar_->waferTypes_.end()) {
523  if (hgpar_->waferMaskMode_ > 0) {
524  if (ktr->second.first == HGCalTypes::WaferOut)
525  return false;
526  } else {
527  if (ktr->second.first < HGCalTypes::WaferCornerMin)
528  return false;
529  }
530  }
531  }
532  return true;
533 }
534 
535 bool HGCalDDDConstants::isValidHex8(int layer, int modU, int modV, int cellU, int cellV, bool fullAndPart) const {
536  // First check validity for a layer|wafer| of post TDR version
537  if (!isValidHex8(layer, modU, modV, fullAndPart))
538  return false;
539  int indx = HGCalWaferIndex::waferIndex(layer, modU, modV);
540  auto itr = hgpar_->typesInLayers_.find(indx);
541  int type = hgpar_->waferTypeL_[itr->second];
542  int N = ((hgpar_->waferTypeL_[itr->second] == 0) ? hgpar_->nCellsFine_ : hgpar_->nCellsCoarse_);
543 #ifdef EDM_ML_DEBUG
544  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants::isValidHex8:Cell " << cellU << ":" << cellV << ":" << N
545  << " Tests " << (cellU >= 0) << ":" << (cellU < 2 * N) << ":" << (cellV >= 0) << ":"
546  << (cellV < 2 * N) << ":" << ((cellV - cellU) < N) << ":" << ((cellU - cellV) <= N);
547 #endif
548  if ((cellU < 0) || (cellU >= 2 * N) || (cellV < 0) || (cellV >= 2 * N))
549  return false;
550  if (((cellV - cellU) >= N) || ((cellU - cellV) > N))
551  return false;
552 
553  return isValidCell8(layer, modU, modV, cellU, cellV, type);
554 }
555 
556 bool HGCalDDDConstants::isValidTrap(int layer, int irad, int iphi) const {
557  // Check validity for a layer|eta|phi of scintillator
558  const auto& indx = getIndex(layer, true);
559  if (indx.first < 0)
560  return false;
561  return ((irad >= hgpar_->iradMinBH_[indx.first]) && (irad <= (hgpar_->iradMaxBH_[indx.first] + 1)) && (iphi > 0) &&
562  (iphi <= hgpar_->scintCells(layer)));
563 }
564 
565 int HGCalDDDConstants::lastLayer(bool reco) const { return (hgpar_->firstLayer_ + tot_layers_[(int)reco] - 1); }
566 
567 unsigned int HGCalDDDConstants::layers(bool reco) const { return tot_layers_[(int)reco]; }
568 
569 int HGCalDDDConstants::layerIndex(int lay, bool reco) const {
570  int ll = lay - hgpar_->firstLayer_;
571  if (ll < 0 || ll >= (int)(hgpar_->layerIndex_.size()))
572  return -1;
573  if (waferHexagon6()) {
574  if (reco && ll >= (int)(hgpar_->depthIndex_.size()))
575  return -1;
576  return (reco ? hgpar_->depthLayerF_[ll] : hgpar_->layerIndex_[ll]);
577  } else {
578  return (hgpar_->layerIndex_[ll]);
579  }
580 }
581 
582 unsigned int HGCalDDDConstants::layersInit(bool reco) const {
583  return (reco ? hgpar_->depthIndex_.size() : hgpar_->layerIndex_.size());
584 }
585 
586 std::pair<float, float> HGCalDDDConstants::localToGlobal8(
587  int lay, int waferU, int waferV, double localX, double localY, bool reco, bool debug) const {
588  double x(localX), y(localY);
589  bool rotx =
591  if (debug)
592  edm::LogVerbatim("HGCalGeom") << "LocalToGlobal8 " << lay << ":" << (lay - hgpar_->firstLayer_) << ":" << rotx
593  << " Local (" << x << ":" << y << ") Reco " << reco;
594  if (!reco) {
597  }
598  const auto& xy = waferPositionNoRot(lay, waferU, waferV, reco, debug);
599  x += xy.first;
600  y += xy.second;
601  if (debug)
602  edm::LogVerbatim("HGCalGeom") << "With wafer " << x << ":" << y << " by adding " << xy.first << ":" << xy.second;
603  return (rotx ? getXY(lay, x, y, false) : std::make_pair(x, y));
604 }
605 
606 std::pair<float, float> HGCalDDDConstants::locateCell(int cell, int lay, int type, bool reco) const {
607  // type refers to wafer # for hexagon cell
608  float x(999999.), y(999999.);
609  const auto& index = getIndex(lay, reco);
610  int i = index.first;
611  if (i < 0)
612  return std::make_pair(x, y);
613  if (waferHexagon6()) {
614  x = hgpar_->waferPosX_[type];
615  y = hgpar_->waferPosY_[type];
616 #ifdef EDM_ML_DEBUG
617  float x0(x), y0(y);
618 #endif
620  x += hgpar_->cellFineX_[cell];
621  y += hgpar_->cellFineY_[cell];
622  } else {
623  x += hgpar_->cellCoarseX_[cell];
624  y += hgpar_->cellCoarseY_[cell];
625  }
626 #ifdef EDM_ML_DEBUG
627  edm::LogVerbatim("HGCalGeom") << "LocateCell (Wafer) " << x0 << ":" << y0 << " Final " << x << ":" << y;
628 #endif
629  if (!reco) {
632  }
633  }
634  return std::make_pair(x, y);
635 }
636 
637 std::pair<float, float> HGCalDDDConstants::locateCell(
638  int lay, int waferU, int waferV, int cellU, int cellV, bool reco, bool all, bool norot, bool debug) const {
639  double x(0), y(0);
640  int indx = HGCalWaferIndex::waferIndex(lay, waferU, waferV);
641  auto itr = hgpar_->typesInLayers_.find(indx);
642  int type = ((itr == hgpar_->typesInLayers_.end()) ? 2 : hgpar_->waferTypeL_[itr->second]);
643  bool rotx = (norot) ? false
644  : ((!hgpar_->layerType_.empty()) &&
646  if (debug) {
647  edm::LogVerbatim("HGCalGeom") << "LocateCell " << lay << ":" << (lay - hgpar_->firstLayer_) << ":" << rotx << ":"
648  << waferU << ":" << waferV << ":" << indx << ":"
649  << (itr == hgpar_->typesInLayers_.end()) << ":" << type << " Flags " << reco << ":"
650  << all;
651  }
652  int kndx = cellV * 100 + cellU;
653  if (type == 0) {
654  auto ktr = hgpar_->cellFineIndex_.find(kndx);
655  if (ktr != hgpar_->cellFineIndex_.end()) {
656  x = hgpar_->cellFineX_[ktr->second];
657  y = hgpar_->cellFineY_[ktr->second];
658  }
659  if (debug)
660  edm::LogVerbatim("HGCalGeom") << "Fine " << cellU << ":" << cellV << ":" << kndx << ":" << x << ":" << y << ":"
661  << (ktr != hgpar_->cellFineIndex_.end());
662  } else {
663  auto ktr = hgpar_->cellCoarseIndex_.find(kndx);
664  if (ktr != hgpar_->cellCoarseIndex_.end()) {
665  x = hgpar_->cellCoarseX_[ktr->second];
666  y = hgpar_->cellCoarseY_[ktr->second];
667  }
668  if (debug)
669  edm::LogVerbatim("HGCalGeom") << "Coarse " << cellU << ":" << cellV << ":" << kndx << ":" << x << ":" << y << ":"
670  << (ktr != hgpar_->cellCoarseIndex_.end());
671  }
672  if (!reco) {
675  }
676  if (all) {
677  const auto& xy = waferPositionNoRot(lay, waferU, waferV, reco, debug);
678  x += xy.first;
679  y += xy.second;
680  if (debug)
681  edm::LogVerbatim("HGCalGeom") << "With wafer " << x << ":" << y << " by adding " << xy.first << ":" << xy.second;
682  }
683  return (rotx ? getXY(lay, x, y, false) : std::make_pair(x, y));
684 }
685 
686 std::pair<float, float> HGCalDDDConstants::locateCell(const HGCSiliconDetId& id, bool debug) const {
687  int lay(id.layer());
688  double r = 0.5 * (hgpar_->waferSize_ + hgpar_->sensorSeparation_);
689  double R = 2.0 * r / sqrt3_;
690  int ncells = (id.type() == 0) ? hgpar_->nCellsFine_ : hgpar_->nCellsCoarse_;
691  int n2 = ncells / 2;
692  auto xyoff = geomTools_.shiftXY(hgpar_->layerCenter_[lay - 1], (2.0 * r));
693  double xpos = xyoff.first + ((-2 * id.waferU() + id.waferV()) * r);
694  double ypos = xyoff.second + (1.5 * id.waferV() * R);
695 #ifdef EDM_ML_DEBUG
696  if (debug)
697  edm::LogVerbatim("HGCalGeom") << "LocateCell " << id << " Lay " << lay << " r:R " << r << ":" << R << " N "
698  << ncells << ":" << n2 << " Off " << xyoff.first << ":" << xyoff.second << " Pos "
699  << xpos << ":" << ypos;
700 #endif
701  double R1 = hgpar_->waferSize_ / (3.0 * ncells);
702  double r1 = 0.5 * R1 * sqrt3_;
703  xpos += ((1.5 * (id.cellV() - ncells) + 1.0) * R1);
704  ypos += ((id.cellU() - 0.5 * id.cellV() - n2) * 2 * r1);
705 #ifdef EDM_ML_DEBUG
706  if (debug)
707  edm::LogVerbatim("HGCalGeom") << "LocateCell r1:R1 " << r1 << ":" << R1 << " dx:dy "
708  << ((1.5 * (id.cellV() - ncells) + 1.0) * R1) << ":"
709  << ((id.cellU() - 0.5 * id.cellV() - n2) * 2 * r1) << " Pos " << xpos << ":" << ypos;
710 #endif
711  std::pair<double, double> xy = getXY(id.layer(), xpos, ypos, true);
712  return std::make_pair(xy.first * id.zside(), xy.second);
713 }
714 
715 std::pair<float, float> HGCalDDDConstants::locateCell(const HGCScintillatorDetId& id, bool debug) const {
716  int lay(id.layer()), iphi(id.iphi()), ir(id.iradiusAbs());
717  double phi = (iphi - 0.5) * hgpar_->scintCellSize(lay);
718  int type = (id.type() > 0) ? 1 : 0;
719  double r = (((ir + 1) < static_cast<int>(hgpar_->radiusLayer_[type].size()))
720  ? (0.5 * (hgpar_->radiusLayer_[type][ir] + hgpar_->radiusLayer_[type][ir - 1]))
721  : (1.5 * hgpar_->radiusLayer_[type][ir] - 0.5 * hgpar_->radiusLayer_[type][ir - 1]));
722 #ifdef EDM_ML_DEBUG
723  if (debug)
724  edm::LogVerbatim("HGCalGeom") << "LocateCell lay:ir:iphi:type " << lay << ":" << ir << ":" << iphi << ":" << type
725  << " r:phi " << r << ":" << convertRadToDeg(phi) << " x:y "
726  << (r * cos(phi) * id.zside()) << ":" << (r * sin(phi));
727 #endif
728  return std::make_pair(r * cos(phi) * id.zside(), r * sin(phi));
729 }
730 
731 std::pair<float, float> HGCalDDDConstants::locateCellHex(int cell, int wafer, bool reco) const {
732  float x(0), y(0);
733  if (hgpar_->waferTypeT_[wafer] - 1 == HGCSiliconDetId::HGCalFine) {
734  x = hgpar_->cellFineX_[cell];
735  y = hgpar_->cellFineY_[cell];
736  } else {
737  x = hgpar_->cellCoarseX_[cell];
738  y = hgpar_->cellCoarseY_[cell];
739  }
740  if (!reco) {
743  }
744  return std::make_pair(x, y);
745 }
746 
747 std::pair<float, float> HGCalDDDConstants::locateCellTrap(int lay, int irad, int iphi, bool reco) const {
748  float x(0), y(0);
749  const auto& indx = getIndex(lay, reco);
750  if (indx.first >= 0) {
751  int ir = std::abs(irad);
752  int type = hgpar_->scintType(lay);
753  double phi = (iphi - 0.5) * indx.second;
754  double z = hgpar_->zLayerHex_[indx.first];
755  double r = 0.5 * (hgpar_->radiusLayer_[type][ir - 1] + hgpar_->radiusLayer_[type][ir]);
756  std::pair<double, double> range = rangeR(z, true);
757 #ifdef EDM_ML_DEBUG
758  edm::LogVerbatim("HGCalGeom") << "locateCellTrap:: Input " << lay << ":" << irad << ":" << iphi << ":" << reco
759  << " IR " << ir << ":" << hgpar_->iradMinBH_[indx.first] << ":"
760  << hgpar_->iradMaxBH_[indx.first] << " Type " << type << " Z " << indx.first << ":"
761  << z << " phi " << phi << " R " << r << ":" << range.first << ":" << range.second;
762 #endif
764  r = std::max(range.first, std::min(r, range.second));
765  x = r * std::cos(phi);
766  y = r * std::sin(phi);
767  if (irad < 0)
768  x = -x;
769  }
770  if (!reco) {
773  }
774  return std::make_pair(x, y);
775 }
776 
777 bool HGCalDDDConstants::maskCell(const DetId& detId, int corners) const {
778  bool mask(false);
779  if (corners > 2 && corners <= (int)(HGCalParameters::k_CornerSize)) {
780  if (waferHexagon8()) {
781  int N(0), layer(0), waferU(0), waferV(0), u(0), v(0);
782  if (detId.det() == DetId::Forward) {
783  HFNoseDetId id(detId);
784  N = getUVMax(id.type());
785  layer = id.layer();
786  waferU = id.waferU();
787  waferV = id.waferV();
788  u = id.cellU();
789  v = id.cellV();
790  } else {
791  HGCSiliconDetId id(detId);
792  N = getUVMax(id.type());
793  layer = id.layer();
794  waferU = id.waferU();
795  waferV = id.waferV();
796  u = id.cellU();
797  v = id.cellV();
798  }
800  auto itr = hgpar_->waferTypes_.find(wl);
801 #ifdef EDM_ML_DEBUG
802  edm::LogVerbatim("HGCalGeom") << "MaskCell: Layer " << layer << " Wafer " << waferU << ":" << waferV << " Index "
803  << wl << ":" << (itr != hgpar_->waferTypes_.end());
804 #endif
805  if (itr != hgpar_->waferTypes_.end()) {
806  if ((itr->second).second <= HGCalWaferMask::k_OffsetRotation)
807  mask = HGCalWaferMask::maskCell(u, v, N, (itr->second).first, (itr->second).second, corners);
808  else
810  u, v, N, (itr->second).first, ((itr->second).second - HGCalWaferMask::k_OffsetRotation)));
811  }
812  }
813  }
814  return mask;
815 }
816 
818  int cells(0);
819  for (unsigned int i = 0; i < layers(reco); ++i) {
820  int lay = reco ? hgpar_->depth_[i] : hgpar_->layer_[i];
821  if (cells < maxCells(lay, reco))
822  cells = maxCells(lay, reco);
823  }
824  return cells;
825 }
826 
827 int HGCalDDDConstants::maxCells(int lay, bool reco) const {
828  const auto& index = getIndex(lay, reco);
829  if (index.first < 0)
830  return 0;
831  if (waferHexagon6()) {
832  unsigned int cells(0);
833  for (unsigned int k = 0; k < hgpar_->waferTypeT_.size(); ++k) {
834  if (waferInLayerTest(k, index.first, hgpar_->defineFull_)) {
835  unsigned int cell = (hgpar_->waferTypeT_[k] - 1 == HGCSiliconDetId::HGCalFine) ? (hgpar_->cellFineX_.size())
836  : (hgpar_->cellCoarseX_.size());
837  if (cell > cells)
838  cells = cell;
839  }
840  }
841  return (int)(cells);
842  } else if (waferHexagon8()) {
843  int cells(0);
844  for (unsigned int k = 0; k < hgpar_->waferCopy_.size(); ++k) {
845  if (waferInLayerTest(k, index.first, hgpar_->defineFull_)) {
849  : hgpar_->waferTypeL_[itr->second]);
851  cells = std::max(cells, 3 * N * N);
852  }
853  }
854  return cells;
855  } else if (tileTrapezoid()) {
856  return hgpar_->scintCells(index.first + hgpar_->firstLayer_);
857  } else {
858  return 0;
859  }
860 }
861 
862 int HGCalDDDConstants::maxRows(int lay, bool reco) const {
863  int kymax(0);
864  const auto& index = getIndex(lay, reco);
865  int i = index.first;
866  if (i < 0)
867  return kymax;
868  if (waferHexagon6()) {
869  for (unsigned int k = 0; k < hgpar_->waferCopy_.size(); ++k) {
871  int ky = ((hgpar_->waferCopy_[k]) / 100) % 100;
872  if (ky > kymax)
873  kymax = ky;
874  }
875  }
876  } else if (waferHexagon8()) {
877  kymax = 1 + 2 * hgpar_->waferUVMaxLayer_[index.first];
878  }
879  return kymax;
880 }
881 
882 int HGCalDDDConstants::modifyUV(int uv, int type1, int type2) const {
883  // Modify u/v for transition of type1 to type2
884  return (((type1 == type2) || (type1 * type2 != 0)) ? uv : ((type1 == 0) ? (2 * uv + 1) / 3 : (3 * uv) / 2));
885 }
886 
887 int HGCalDDDConstants::modules(int lay, bool reco) const {
888  if (getIndex(lay, reco).first < 0)
889  return 0;
890  else
891  return max_modules_layer_[(int)reco][lay];
892 }
893 
894 int HGCalDDDConstants::modulesInit(int lay, bool reco) const {
895  int nmod(0);
896  const auto& index = getIndex(lay, reco);
897  if (index.first < 0)
898  return nmod;
899  if (!tileTrapezoid()) {
900  for (unsigned int k = 0; k < hgpar_->waferPosX_.size(); ++k) {
901  if (waferInLayerTest(k, index.first, hgpar_->defineFull_))
902  ++nmod;
903  }
904  } else {
905  nmod = 1 + hgpar_->lastModule_[index.first] - hgpar_->firstModule_[index.first];
906  }
907  return nmod;
908 }
909 
910 double HGCalDDDConstants::mouseBite(bool reco) const {
912 }
913 
917  ? tileCount(0, -1)
918  : 0;
919  if (cells == 0) {
920  unsigned int nlayer = (reco) ? hgpar_->depth_.size() : hgpar_->layer_.size();
921  for (unsigned k = 0; k < nlayer; ++k) {
922  std::vector<int> ncells = numberCells(((reco) ? hgpar_->depth_[k] : hgpar_->layer_[k]), reco);
923  cells = std::accumulate(ncells.begin(), ncells.end(), cells);
924  }
925  }
926  return cells;
927 }
928 
929 std::vector<int> HGCalDDDConstants::numberCells(int lay, bool reco) const {
930  const auto& index = getIndex(lay, reco);
931  int i = index.first;
932  std::vector<int> ncell;
933  if (i >= 0) {
934  if (waferHexagon6()) {
935  for (unsigned int k = 0; k < hgpar_->waferTypeT_.size(); ++k) {
937  unsigned int cell = (hgpar_->waferTypeT_[k] - 1 == HGCSiliconDetId::HGCalFine)
938  ? (hgpar_->cellFineX_.size())
939  : (hgpar_->cellCoarseX_.size());
940  ncell.emplace_back((int)(cell));
941  }
942  }
943  } else if (tileTrapezoid()) {
944  int nphi = hgpar_->scintCells(lay);
945  for (int k = hgpar_->firstModule_[i]; k <= hgpar_->lastModule_[i]; ++k)
946  ncell.emplace_back(nphi);
947  } else {
948  for (unsigned int k = 0; k < hgpar_->waferCopy_.size(); ++k) {
949  if (waferInLayerTest(k, index.first, hgpar_->defineFull_)) {
950  int cell = numberCellsHexagon(lay,
953  true);
954  ncell.emplace_back(cell);
955  }
956  }
957  }
958  }
959  return ncell;
960 }
961 
963  if (wafer >= 0 && wafer < (int)(hgpar_->waferTypeT_.size())) {
964  if (hgpar_->waferTypeT_[wafer] - 1 == HGCSiliconDetId::HGCalFine)
965  return (int)(hgpar_->cellFineX_.size());
966  else
967  return (int)(hgpar_->cellCoarseX_.size());
968  } else {
969  return 0;
970  }
971 }
972 
973 int HGCalDDDConstants::numberCellsHexagon(int lay, int waferU, int waferV, bool flag) const {
975  int type =
976  ((itr == hgpar_->typesInLayers_.end()) ? HGCSiliconDetId::HGCalCoarseThick : hgpar_->waferTypeL_[itr->second]);
977  int N = (type == 0) ? hgpar_->nCellsFine_ : hgpar_->nCellsCoarse_;
978  if (flag)
979  return (3 * N * N);
980  else
981  return N;
982 }
983 
984 std::pair<double, double> HGCalDDDConstants::rangeR(double z, bool reco) const {
985  double rmin(0), rmax(0), zz(0);
986  if (hgpar_->detectorType_ > 0) {
988  if (hgpar_->detectorType_ <= 2) {
990  } else {
991  rmin = HGCalGeomTools::radius(
993  }
994  if ((hgpar_->detectorType_ == 2) && (zz >= hgpar_->zLayerHex_[hgpar_->firstMixedLayer_ - 1])) {
995  rmax = HGCalGeomTools::radius(
997  } else {
999  }
1000  }
1001  if (!reco) {
1004  }
1005 #ifdef EDM_ML_DEBUG
1006  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants:rangeR: " << z << ":" << zz << " R " << rmin << ":" << rmax;
1007 #endif
1008  return std::make_pair(rmin, rmax);
1009 }
1010 
1011 std::pair<double, double> HGCalDDDConstants::rangeRLayer(int lay, bool reco) const {
1012  double rmin(0), rmax(0);
1013  const auto& index = getIndex(lay, reco);
1014  if (index.first >= 0 && index.first < static_cast<int>(hgpar_->rMinLayHex_.size())) {
1015  rmin = hgpar_->rMinLayHex_[index.first];
1016  rmax = hgpar_->rMaxLayHex_[index.first];
1017  }
1018  if (!reco) {
1021  }
1022 #ifdef EDM_ML_DEBUG
1023  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants:rangeR: " << lay << ":" << index.first << " R " << rmin << ":"
1024  << rmax;
1025 #endif
1026  return std::make_pair(rmin, rmax);
1027 }
1028 
1029 std::pair<double, double> HGCalDDDConstants::rangeZ(bool reco) const {
1030  double zmin = (hgpar_->zLayerHex_[0] - hgpar_->waferThick_);
1031  double zmax = (hgpar_->zLayerHex_[hgpar_->zLayerHex_.size() - 1] + hgpar_->waferThick_);
1032 #ifdef EDM_ML_DEBUG
1033  edm::LogVerbatim("HGCalGeom") << "HGCalDDDConstants:rangeZ: " << zmin << ":" << zmax << ":" << hgpar_->waferThick_;
1034 #endif
1035  if (!reco) {
1038  }
1039  return std::make_pair(zmin, zmax);
1040 }
1041 
1042 std::pair<int, int> HGCalDDDConstants::rowColumnWafer(int wafer) const {
1043  int row(0), col(0);
1044  if (wafer < (int)(hgpar_->waferCopy_.size())) {
1045  int copy = hgpar_->waferCopy_[wafer];
1048  ;
1049  }
1050  return std::make_pair(row, col);
1051 }
1052 
1053 std::pair<int, int> HGCalDDDConstants::simToReco(int cell, int lay, int mod, bool half) const {
1054  if (!waferHexagon6()) {
1055  return std::make_pair(cell, lay);
1056  } else {
1057  const auto& index = getIndex(lay, false);
1058  int i = index.first;
1059  if (i < 0) {
1060  edm::LogWarning("HGCalGeom") << "Wrong Layer # " << lay << " not in the list ***** ERROR *****";
1061  return std::make_pair(-1, -1);
1062  }
1063  if (mod >= (int)(hgpar_->waferTypeL_).size()) {
1064  edm::LogWarning("HGCalGeom") << "Invalid Wafer # " << mod << "should be < " << (hgpar_->waferTypeL_).size()
1065  << " ***** ERROR *****";
1066  return std::make_pair(-1, -1);
1067  }
1068  int depth(-1);
1069  int kx = cell;
1070  int type = hgpar_->waferTypeL_[mod];
1071  if (type == 1) {
1072  depth = hgpar_->layerGroup_[i];
1073  } else if (type == 2) {
1074  depth = hgpar_->layerGroupM_[i];
1075  } else {
1076  depth = hgpar_->layerGroupO_[i];
1077  }
1078  return std::make_pair(kx, depth);
1079  }
1080 }
1081 
1083  int laymin(layer), laymax(layer), ringmin(ring), ringmax(ring), kount(0);
1084  if (layer == 0) {
1085  laymin = hgpar_->firstLayer_;
1086  laymax = lastLayer(true);
1087  }
1088  for (int lay = laymin; lay <= laymax; ++lay) {
1089  if (ring < 0) {
1090  int ll = lay - hgpar_->firstLayer_;
1091  ringmin = hgpar_->tileRingRange_[ll].first;
1092  ringmax = hgpar_->tileRingRange_[ll].second;
1093  }
1094  for (int rin = ringmin; rin <= ringmax; ++rin) {
1095  int indx = HGCalTileIndex::tileIndex(lay, rin + 1, 0);
1096  auto itr = hgpar_->tileInfoMap_.find(indx);
1097  if (itr != hgpar_->tileInfoMap_.end()) {
1098  for (int k = 0; k < 4; ++k) {
1099  std::bitset<24> b(itr->second.hex[k]);
1100  kount += b.count();
1101  }
1102  }
1103  }
1104  }
1105  return (3 * kount);
1106 }
1107 
1109  const int ncopies = hgpar_->waferCopy_.size();
1110  int wafer(ncopies);
1111  bool result(false);
1112  for (int k = 0; k < ncopies; ++k) {
1113  if (copy == hgpar_->waferCopy_[k]) {
1114  wafer = k;
1115  result = true;
1116  break;
1117  }
1118  }
1119  if (!result) {
1120  wafer = -1;
1121 #ifdef EDM_ML_DEBUG
1122  edm::LogVerbatim("HGCalGeom") << "Cannot find " << copy << " in a list of " << ncopies << " members";
1123  for (int k = 0; k < ncopies; ++k)
1124  edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << hgpar_->waferCopy_[k];
1125 #endif
1126  }
1127 #ifdef EDM_ML_DEBUG
1128  edm::LogVerbatim("HGCalGeom") << "WaferFromCopy " << copy << ":" << wafer << ":" << result;
1129 #endif
1130  return wafer;
1131 }
1132 
1133 void HGCalDDDConstants::waferFromPosition(const double x, const double y, int& wafer, int& icell, int& celltyp) const {
1134  // Input x, y in Geant4 unit and transformed to CMSSW standard
1137  int size_ = static_cast<int>(hgpar_->waferCopy_.size());
1138  wafer = size_;
1139  for (int k = 0; k < size_; ++k) {
1140  double dx = std::abs(xx - hgpar_->waferPosX_[k]);
1141  double dy = std::abs(yy - hgpar_->waferPosY_[k]);
1142  if (dx <= rmax_ && dy <= hexside_) {
1143  if ((dy <= 0.5 * hexside_) || (dx * tan30deg_ <= (hexside_ - dy))) {
1144  wafer = k;
1145  celltyp = hgpar_->waferTypeT_[k];
1146  xx -= hgpar_->waferPosX_[k];
1147  yy -= hgpar_->waferPosY_[k];
1148  break;
1149  }
1150  }
1151  }
1152  if (wafer < size_) {
1153  if (celltyp - 1 == HGCSiliconDetId::HGCalFine)
1154  icell = cellHex(
1156  else
1157  icell = cellHex(xx,
1158  yy,
1161  hgpar_->cellCoarseY_);
1162  } else {
1163  wafer = -1;
1164 #ifdef EDM_ML_DEBUG
1165  edm::LogWarning("HGCalGeom") << "Cannot get wafer type corresponding to " << x << ":" << y << " " << xx << ":"
1166  << yy;
1167 #endif
1168  }
1169 #ifdef EDM_ML_DEBUG
1170  edm::LogVerbatim("HGCalGeom") << "Position " << x << ":" << y << " Wafer " << wafer << ":" << size_ << " XX " << xx
1171  << ":" << yy << " Cell " << icell << " Type " << celltyp;
1172 #endif
1173 }
1174 
1176  const double y,
1177  const int layer,
1178  int& waferU,
1179  int& waferV,
1180  int& cellU,
1181  int& cellV,
1182  int& celltype,
1183  double& wt,
1184  bool extend,
1185  bool debug) const {
1186  waferU = waferV = 1 + hgpar_->waferUVMax_;
1187  cellU = cellV = celltype = 0;
1188  if ((hgpar_->xLayerHex_.empty()) || (hgpar_->yLayerHex_.empty()))
1189  return;
1190  int ll = layer - hgpar_->firstLayer_;
1191  bool rotx = ((!hgpar_->layerType_.empty()) && (hgpar_->layerType_[ll] == HGCalTypes::WaferCenterR));
1192  double xx(0), yy(0);
1193  if (rotx) {
1194  std::pair<double, double> xy =
1196  xx = xy.first - hgpar_->xLayerHex_[ll];
1197  yy = xy.second - hgpar_->yLayerHex_[ll];
1198  } else {
1201  }
1202 #ifdef EDM_ML_DEBUG
1203  if (debug)
1204  edm::LogVerbatim("HGCalGeom") << "waferFromPosition:: Layer " << layer << ":" << ll << " Rot " << rotx << " X " << x
1205  << ":" << xx << " Y " << y << ":" << yy;
1206 #endif
1207  double rmax = extend ? rmaxT_ : rmax_;
1208  double hexside = extend ? hexsideT_ : hexside_;
1209  for (unsigned int k = 0; k < hgpar_->waferPosX_.size(); ++k) {
1210  double dx = std::abs(xx - hgpar_->waferPosX_[k]);
1211  double dy = std::abs(yy - hgpar_->waferPosY_[k]);
1212  if (dx <= rmax && dy <= hexside) {
1213  if ((dy <= 0.5 * hexside) || (dx * tan30deg_ <= (hexside - dy))) {
1219  } else {
1221  celltype = ((itr == hgpar_->typesInLayers_.end()) ? HGCSiliconDetId::HGCalCoarseThick
1222  : hgpar_->waferTypeL_[itr->second]);
1223  }
1224 #ifdef EDM_ML_DEBUG
1225  if (debug)
1226  edm::LogVerbatim("HGCalGeom") << "WaferFromPosition:: Input " << layer << ":" << ll << ":"
1227  << hgpar_->firstLayer_ << ":" << rotx << ":" << x << ":" << y << ":"
1228  << hgpar_->xLayerHex_[ll] << ":" << hgpar_->yLayerHex_[ll] << ":" << xx << ":"
1229  << yy << " compared with " << hgpar_->waferPosX_[k] << ":"
1230  << hgpar_->waferPosY_[k] << " difference " << dx << ":" << dy << ":"
1231  << dx * tan30deg_ << ":" << (hexside_ - dy) << " comparator " << rmax_ << ":"
1232  << rmaxT_ << ":" << hexside_ << ":" << hexsideT_ << " wafer " << waferU << ":"
1233  << waferV << ":" << celltype;
1234 #endif
1235  xx -= hgpar_->waferPosX_[k];
1236  yy -= hgpar_->waferPosY_[k];
1237  break;
1238  }
1239  }
1240  }
1241  if ((std::abs(waferU) <= hgpar_->waferUVMax_) && (celltype >= 0)) {
1242  cellHex(xx, yy, celltype, cellU, cellV, extend, debug);
1243  wt = (((celltype < 2) && (mode_ != HGCalGeometryMode::Hexagon8Module))
1244  ? (hgpar_->cellThickness_[celltype] / hgpar_->waferThick_)
1245  : 1.0);
1246  } else {
1247  cellU = cellV = 2 * hgpar_->nCellsFine_;
1248  wt = 1.0;
1249  celltype = -1;
1250  }
1251  if ((celltype < 0) && debug) {
1252  double x1(xx);
1253  double y1(yy);
1254  edm::LogVerbatim("HGCalGeom") << "waferfFromPosition: Bad type for X " << x << ":" << x1 << ":" << xx << " Y " << y
1255  << ":" << y1 << ":" << yy << " Wafer " << waferU << ":" << waferV << " Cell " << cellU
1256  << ":" << cellV;
1257  for (unsigned int k = 0; k < hgpar_->waferPosX_.size(); ++k) {
1258  double dx = std::abs(x1 - hgpar_->waferPosX_[k]);
1259  double dy = std::abs(y1 - hgpar_->waferPosY_[k]);
1260  edm::LogVerbatim("HGCalGeom") << "Wafer [" << k << "] Position (" << hgpar_->waferPosX_[k] << ", "
1261  << hgpar_->waferPosY_[k] << ") difference " << dx << ":" << dy << ":"
1262  << dx * tan30deg_ << ":" << hexside - dy << " Paramerers " << rmax << ":"
1263  << hexside;
1264  }
1265  }
1266 }
1267 
1268 bool HGCalDDDConstants::waferInLayer(int wafer, int lay, bool reco) const {
1269  const auto& indx = getIndex(lay, reco);
1270  if (indx.first < 0)
1271  return false;
1272  return waferInLayerTest(wafer, indx.first, hgpar_->defineFull_);
1273 }
1274 
1275 bool HGCalDDDConstants::waferFullInLayer(int wafer, int lay, bool reco) const {
1276  const auto& indx = getIndex(lay, reco);
1277  if (indx.first < 0)
1278  return false;
1279  return waferInLayerTest(wafer, indx.first, false);
1280 }
1281 
1282 std::pair<double, double> HGCalDDDConstants::waferParameters(bool reco) const {
1283  if (reco)
1284  return std::make_pair(rmax_, hexside_);
1285  else
1287 }
1288 
1289 std::pair<double, double> HGCalDDDConstants::waferPosition(int wafer, bool reco) const {
1290  double xx(0), yy(0);
1291  if (wafer >= 0 && wafer < (int)(hgpar_->waferPosX_.size())) {
1292  xx = hgpar_->waferPosX_[wafer];
1293  yy = hgpar_->waferPosY_[wafer];
1294  }
1295  if (!reco) {
1298  }
1299  return std::make_pair(xx, yy);
1300 }
1301 
1302 std::pair<double, double> HGCalDDDConstants::waferPosition(
1303  int lay, int waferU, int waferV, bool reco, bool debug) const {
1304  int ll = lay - hgpar_->firstLayer_;
1305  bool rotx = ((!hgpar_->layerType_.empty()) && (hgpar_->layerType_[ll] == HGCalTypes::WaferCenterR));
1306 #ifdef EDM_ML_DEBUG
1307  if (debug)
1308  edm::LogVerbatim("HGCalGeom") << "Layer " << lay << ":" << ll << " Rotation " << rotx << " U:V " << waferU << ":"
1309  << waferV;
1310 #endif
1311  auto xy = waferPositionNoRot(lay, waferU, waferV, reco, debug);
1312  std::pair<double, double> xy0 = (rotx) ? getXY(lay, xy.first, xy.second, false) : xy;
1313 #ifdef EDM_ML_DEBUG
1314  if (debug)
1315  edm::LogVerbatim("HGCalGeom") << "Without and with rotation " << xy.first << ":" << xy.second << ":" << xy0.first
1316  << ":" << xy0.second;
1317 #endif
1318  return xy0;
1319 }
1320 
1321 int HGCalDDDConstants::waferType(DetId const& id, bool fromFile) const {
1322  int type(1);
1323  if (waferHexagon8()) {
1324  if (fromFile && (waferFileSize() > 0)) {
1325  int layer(0), waferU(0), waferV(0);
1326  if (id.det() != DetId::Forward) {
1327  HGCSiliconDetId hid(id);
1328  layer = hid.layer();
1329  waferU = hid.waferU();
1330  waferV = hid.waferV();
1331  } else {
1332  HFNoseDetId hid(id);
1333  layer = hid.layer();
1334  waferU = hid.waferU();
1335  waferV = hid.waferV();
1336  }
1338  if (itr != hgpar_->waferInfoMap_.end())
1339  type = (itr->second).type;
1340  } else {
1341  type = ((id.det() != DetId::Forward) ? HGCSiliconDetId(id).type() : HFNoseDetId(id).type());
1342  }
1343  } else if (waferHexagon6()) {
1344  type = waferTypeL(HGCalDetId(id).wafer()) - 1;
1345  }
1346  return type;
1347 }
1348 
1349 int HGCalDDDConstants::waferType(int layer, int waferU, int waferV, bool fromFile) const {
1351  if (waferHexagon8()) {
1352  if (fromFile && (waferFileSize() > 0)) {
1354  if (itr != hgpar_->waferInfoMap_.end())
1355  type = (itr->second).type;
1356  } else {
1358  if (itr != hgpar_->typesInLayers_.end())
1359  type = hgpar_->waferTypeL_[itr->second];
1360  }
1361  } else if (waferHexagon6()) {
1362  if ((waferU >= 0) && (waferU < (int)(hgpar_->waferTypeL_.size())))
1363  type = (hgpar_->waferTypeL_[waferU] - 1);
1364  }
1365  return type;
1366 }
1367 
1368 std::tuple<int, int, int> HGCalDDDConstants::waferType(HGCSiliconDetId const& id, bool fromFile) const {
1369  const auto& index = HGCalWaferIndex::waferIndex(id.layer(), id.waferU(), id.waferV());
1370  int type(-1), part(-1), orient(-1);
1371  if (fromFile && (waferFileSize() > 0)) {
1372  auto itr = hgpar_->waferInfoMap_.find(index);
1373  if (itr != hgpar_->waferInfoMap_.end()) {
1374  type = (itr->second).type;
1375  part = (itr->second).part;
1376  orient = (itr->second).orient;
1377  }
1378  } else {
1379  auto ktr = hgpar_->typesInLayers_.find(index);
1380  if (ktr != hgpar_->typesInLayers_.end())
1381  type = hgpar_->waferTypeL_[ktr->second];
1382  auto itr = hgpar_->waferTypes_.find(index);
1383  if (itr != hgpar_->waferTypes_.end()) {
1384  if ((itr->second).second < HGCalWaferMask::k_OffsetRotation) {
1385  orient = (itr->second).second;
1386  if ((itr->second).first == HGCalGeomTools::k_allCorners) {
1388  } else if ((itr->second).first == HGCalGeomTools::k_fiveCorners) {
1390  } else if ((itr->second).first == HGCalGeomTools::k_fourCorners) {
1392  } else if ((itr->second).first == HGCalGeomTools::k_threeCorners) {
1394  }
1395  } else {
1396  part = (itr->second).first;
1397  orient = ((itr->second).second - HGCalWaferMask::k_OffsetRotation);
1398  }
1399  } else {
1401  orient = 0;
1402  }
1403  }
1404  return std::make_tuple(type, part, orient);
1405 }
1406 
1408  int layer, int waferU, int waferV, bool fromFile, bool debug) const {
1409  int type(HGCalTypes::WaferOut), rotn(0);
1411  bool withinList(true);
1412  if (fromFile && (waferFileSize() > 0)) {
1413  auto itr = hgpar_->waferInfoMap_.find(wl);
1414  withinList = (itr != hgpar_->waferInfoMap_.end());
1415  if (withinList) {
1416  type = (itr->second).part;
1417  rotn = (itr->second).orient;
1418  }
1419  } else {
1420  auto itr = hgpar_->waferTypes_.find(wl);
1421  if (waferHexagon8()) {
1422  withinList = (itr != hgpar_->waferTypes_.end());
1423  if (withinList) {
1424  if ((itr->second).second < HGCalWaferMask::k_OffsetRotation) {
1425  rotn = (itr->second).second;
1426  if ((itr->second).first == HGCalGeomTools::k_allCorners) {
1428  } else if ((itr->second).first == HGCalGeomTools::k_fiveCorners) {
1430  } else if ((itr->second).first == HGCalGeomTools::k_fourCorners) {
1432  } else if ((itr->second).first == HGCalGeomTools::k_threeCorners) {
1434  }
1435  } else {
1436  type = (itr->second).first;
1437  rotn = ((itr->second).second - HGCalWaferMask::k_OffsetRotation);
1438  }
1439  } else {
1441  rotn = HGCalTypes::WaferCorner0;
1442  }
1443  }
1444  }
1445 #ifdef EDM_ML_DEBUG
1446  if (debug)
1447  edm::LogVerbatim("HGCalGeom") << "waferTypeRotation: Layer " << layer << " Wafer " << waferU << ":" << waferV
1448  << " Index " << std::hex << wl << std::dec << ":" << withinList << " Type " << type
1449  << " Rotation " << rotn;
1450 #endif
1451  return std::make_pair(type, rotn);
1452 }
1453 
1455  bool type(false);
1456  if (waferHexagon8()) {
1458  type = (hgpar_->waferTypes_.find(wl) != hgpar_->waferTypes_.end());
1459  } else if (waferHexagon6()) {
1460  int wl = HGCalWaferIndex::waferIndex(layer, waferU, 0, true);
1461  type = (hgpar_->waferTypes_.find(wl) != hgpar_->waferTypes_.end());
1462  }
1463  return type;
1464 }
1465 
1466 double HGCalDDDConstants::waferZ(int lay, bool reco) const {
1467  const auto& index = getIndex(lay, reco);
1468  if (index.first < 0)
1469  return 0;
1470  else
1472 }
1473 
1475  int wafer(0);
1476  if (!tileTrapezoid()) {
1477  for (unsigned int i = 0; i < layers(true); ++i) {
1478  int lay = hgpar_->depth_[i];
1479  wafer += modules(lay, true);
1480  }
1481  } else {
1482  wafer = (int)(hgpar_->moduleLayR_.size());
1483  }
1484  return wafer;
1485 }
1486 
1487 int HGCalDDDConstants::wafers(int layer, int type) const {
1488  int wafer(0);
1489  if (!tileTrapezoid()) {
1490  auto itr = waferLayer_.find(layer);
1491  if (itr != waferLayer_.end()) {
1492  unsigned ity = (type > 0 && type <= 2) ? type : 0;
1493  wafer = (itr->second)[ity];
1494  }
1495  } else {
1496  const auto& index = getIndex(layer, true);
1497  wafer = 1 + hgpar_->lastModule_[index.first] - hgpar_->firstModule_[index.first];
1498  }
1499  return wafer;
1500 }
1501 
1503  double xx, double yy, const double& cellR, const std::vector<double>& posX, const std::vector<double>& posY) const {
1504  int num(0);
1505  const double tol(0.00001);
1506  double cellY = 2.0 * cellR * tan30deg_;
1507  for (unsigned int k = 0; k < posX.size(); ++k) {
1508  double dx = std::abs(xx - posX[k]);
1509  double dy = std::abs(yy - posY[k]);
1510  if (dx <= (cellR + tol) && dy <= (cellY + tol)) {
1511  double xmax = (dy <= 0.5 * cellY) ? cellR : (cellR - (dy - 0.5 * cellY) / tan30deg_);
1512  if (dx <= (xmax + tol)) {
1513  num = k;
1514  break;
1515  }
1516  }
1517  }
1518  return num;
1519 }
1520 
1522  double xloc, double yloc, int cellType, int& cellU, int& cellV, bool extend, bool debug) const {
1523  int N = (cellType == 0) ? hgpar_->nCellsFine_ : hgpar_->nCellsCoarse_;
1524  double Rc = 2 * rmax_ / (3 * N);
1525  double rc = 0.5 * Rc * sqrt3_;
1526  double RcT = (extend) ? (2 * rmaxT_ / (3 * N)) : Rc;
1527  double rcT = 0.5 * RcT * sqrt3_;
1528  double v0 = ((xloc / Rc - 1.0) / 1.5);
1529  int cv0 = (v0 > 0) ? (N + (int)(v0 + 0.5)) : (N - (int)(-v0 + 0.5));
1530  double u0 = (0.5 * yloc / rc + 0.5 * cv0);
1531  int cu0 = (u0 > 0) ? (N / 2 + (int)(u0 + 0.5)) : (N / 2 - (int)(-u0 + 0.5));
1532  cu0 = std::max(0, std::min(cu0, 2 * N - 1));
1533  cv0 = std::max(0, std::min(cv0, 2 * N - 1));
1534  if (cv0 - cu0 >= N)
1535  cv0 = cu0 + N - 1;
1536 #ifdef EDM_ML_DEBUG
1537  if (debug)
1538  edm::LogVerbatim("HGCalGeom") << "cellHex: input " << xloc << ":" << yloc << ":" << cellType << " parameter " << rc
1539  << ":" << Rc << " u0 " << u0 << ":" << cu0 << " v0 " << v0 << ":" << cv0;
1540 #endif
1541  bool found(false);
1542  static constexpr int shift[3] = {0, 1, -1};
1543  for (int i1 = 0; i1 < 3; ++i1) {
1544  cellU = cu0 + shift[i1];
1545  for (int i2 = 0; i2 < 3; ++i2) {
1546  cellV = cv0 + shift[i2];
1547  if (((cellV - cellU) < N) && ((cellU - cellV) <= N) && (cellU >= 0) && (cellV >= 0) && (cellU < 2 * N) &&
1548  (cellV < 2 * N)) {
1549  double xc = (1.5 * (cellV - N) + 1.0) * Rc;
1550  double yc = (2 * cellU - cellV - N) * rc;
1551  if ((std::abs(yloc - yc) <= rcT) && (std::abs(xloc - xc) <= RcT) &&
1552  ((std::abs(xloc - xc) <= 0.5 * RcT) || (std::abs(yloc - yc) <= sqrt3_ * (RcT - std::abs(xloc - xc))))) {
1553 #ifdef EDM_ML_DEBUG
1554  if (debug)
1555  edm::LogVerbatim("HGCalGeom")
1556  << "cellHex: local " << xc << ":" << yc << " difference " << std::abs(xloc - xc) << ":"
1557  << std::abs(yloc - yc) << ":" << sqrt3_ * (Rc - std::abs(yloc - yc)) << " comparator " << rc << ":"
1558  << Rc << " (u,v) = (" << cellU << "," << cellV << ")";
1559 #endif
1560  found = true;
1561  break;
1562  }
1563  }
1564  }
1565  if (found)
1566  break;
1567  }
1568  if (!found) {
1569  cellU = cu0;
1570  cellV = cv0;
1571  }
1572 }
1573 
1574 std::pair<int, float> HGCalDDDConstants::getIndex(int lay, bool reco) const {
1575  int indx = layerIndex(lay, reco);
1576  if (indx < 0)
1577  return std::make_pair(-1, 0);
1578  float cell(0);
1579  if (waferHexagon6()) {
1580  cell = (reco ? hgpar_->moduleCellR_[0] : hgpar_->moduleCellS_[0]);
1581  } else {
1582  if (waferHexagon8()) {
1583  cell = (reco ? hgpar_->moduleCellR_[0] : hgpar_->moduleCellS_[0]);
1584  } else {
1585  cell = hgpar_->scintCellSize(lay);
1586  }
1587  }
1588  return std::make_pair(indx, cell);
1589 }
1590 
1592  int ll(-1);
1593  if (waferHexagon6() && reco) {
1594  ll = static_cast<int>(std::find(hgpar_->depthLayerF_.begin(), hgpar_->depthLayerF_.end(), index) -
1595  hgpar_->depthLayerF_.begin());
1596  if (ll == static_cast<int>(hgpar_->depthLayerF_.size()))
1597  ll = -1;
1598  } else {
1599  ll = static_cast<int>(std::find(hgpar_->layerIndex_.begin(), hgpar_->layerIndex_.end(), index) -
1600  hgpar_->layerIndex_.begin());
1601  if (ll == static_cast<int>(hgpar_->layerIndex_.size()))
1602  ll = -1;
1603  }
1604 #ifdef EDM_ML_DEBUG
1605  edm::LogVerbatim("HGCalGeom") << "LayerFromIndex for " << index << ":" << reco << ":" << waferHexagon6() << " is"
1606  << ll << ":" << (ll + hgpar_->firstLayer_);
1607 #endif
1608  return ((ll < 0) ? ll : (ll + hgpar_->firstLayer_));
1609 }
1610 
1611 bool HGCalDDDConstants::isValidCell(int lay, int wafer, int cell) const {
1612  // Calculate the position of the cell
1613  // Works for options HGCalHexagon/HGCalHexagonFull
1614  double x = hgpar_->waferPosX_[wafer];
1615  double y = hgpar_->waferPosY_[wafer];
1616  if (hgpar_->waferTypeT_[wafer] - 1 == HGCSiliconDetId::HGCalFine) {
1617  x += hgpar_->cellFineX_[cell];
1618  y += hgpar_->cellFineY_[cell];
1619  } else {
1620  x += hgpar_->cellCoarseX_[cell];
1621  y += hgpar_->cellCoarseY_[cell];
1622  }
1623  double rr = sqrt(x * x + y * y);
1624  bool result = ((rr >= hgpar_->rMinLayHex_[lay - 1]) && (rr <= hgpar_->rMaxLayHex_[lay - 1]) &&
1625  (wafer < (int)(hgpar_->waferPosX_.size())));
1626 #ifdef EDM_ML_DEBUG
1627  if (!result)
1628  edm::LogVerbatim("HGCalGeom") << "Input " << lay << ":" << wafer << ":" << cell << " Position " << x << ":" << y
1629  << ":" << rr << " Compare Limits " << hgpar_->rMinLayHex_[lay - 1] << ":"
1630  << hgpar_->rMaxLayHex_[lay - 1] << " Flag " << result;
1631 #endif
1632  return result;
1633 }
1634 
1635 bool HGCalDDDConstants::isValidCell8(int lay, int waferU, int waferV, int cellU, int cellV, int type) const {
1636  float x(0), y(0);
1637  int kndx = cellV * 100 + cellU;
1638  if (type == 0) {
1639  auto ktr = hgpar_->cellFineIndex_.find(kndx);
1640  if (ktr != hgpar_->cellFineIndex_.end()) {
1641  x = hgpar_->cellFineX_[ktr->second];
1642  y = hgpar_->cellFineY_[ktr->second];
1643  }
1644 #ifdef EDM_ML_DEBUG
1645  edm::LogVerbatim("HGCalGeom") << "Fine " << cellU << ":" << cellV << ":" << kndx << ":" << x << ":" << y << ":"
1646  << (ktr != hgpar_->cellFineIndex_.end());
1647 #endif
1648  } else {
1649  auto ktr = hgpar_->cellCoarseIndex_.find(kndx);
1650  if (ktr != hgpar_->cellCoarseIndex_.end()) {
1651  x = hgpar_->cellCoarseX_[ktr->second];
1652  y = hgpar_->cellCoarseY_[ktr->second];
1653  }
1654 #ifdef EDM_ML_DEBUG
1655  edm::LogVerbatim("HGCalGeom") << "Coarse " << cellU << ":" << cellV << ":" << kndx << ":" << x << ":" << y << ":"
1656  << (ktr != hgpar_->cellCoarseIndex_.end());
1657 #endif
1658  }
1659  const auto& xy = waferPositionNoRot(lay, waferU, waferV, true, false);
1660  x += xy.first;
1661  y += xy.second;
1662 #ifdef EDM_ML_DEBUG
1663  edm::LogVerbatim("HGCalGeom") << "With wafer (" << waferU << "," << waferV << ") " << x << ":" << y;
1664 #endif
1665  double rr = sqrt(x * x + y * y);
1666  int ll = lay - hgpar_->firstLayer_;
1667  bool result = ((rr >= hgpar_->rMinLayHex_[ll]) && (rr <= hgpar_->rMaxLayHex_[ll]));
1668 #ifdef EDM_ML_DEBUG
1669  edm::LogVerbatim("HGCalGeom") << "Input " << lay << ":" << ll << ":" << waferU << ":" << waferV << ":" << cellU << ":"
1670  << cellV << " Position " << x << ":" << y << ":" << rr << " Compare Limits "
1671  << hgpar_->rMinLayHex_[ll] << ":" << hgpar_->rMaxLayHex_[ll] << " Flag " << result;
1672 #endif
1674  int N = (type == 0) ? hgpar_->nCellsFine_ : hgpar_->nCellsCoarse_;
1675  auto partn = waferTypeRotation(lay, waferU, waferV, false, false);
1676  result = HGCalWaferMask::goodCell(cellU, cellV, N, partn.first, partn.second);
1677 #ifdef EDM_ML_DEBUG
1678  edm::LogVerbatim("HGCalGeom") << "Input " << lay << ":" << waferU << ":" << waferV << ":" << cellU << ":" << cellV
1679  << " N " << N << " part " << partn.first << ":" << partn.second << " Result "
1680  << result;
1681 #endif
1682  }
1683  return result;
1684 }
1685 
1686 int32_t HGCalDDDConstants::waferIndex(int wafer, int index) const {
1687  int layer = layerFromIndex(index, true);
1691 #ifdef EDM_ML_DEBUG
1692  edm::LogVerbatim("HGCalGeom") << "WaferIndex for " << wafer << ":" << index << " (" << layer << ":" << waferU << ":"
1693  << waferV << ") " << indx;
1694 #endif
1695  return indx;
1696 }
1697 
1698 bool HGCalDDDConstants::waferInLayerTest(int wafer, int lay, bool full) const {
1699  bool in = (waferHexagon6()) ? true : false;
1700  if (!in) {
1701  double xpos = hgpar_->waferPosX_[wafer] + hgpar_->xLayerHex_[lay];
1702  double ypos = hgpar_->waferPosY_[wafer] + hgpar_->yLayerHex_[lay];
1703  std::pair<int, int> corner = HGCalGeomTools::waferCorner(
1704  xpos, ypos, rmax_, hexside_, hgpar_->rMinLayHex_[lay], hgpar_->rMaxLayHex_[lay], in);
1705  in = (full ? (corner.first > 0) : (corner.first == (int)(HGCalParameters::k_CornerSize)));
1706  if (in && fullAndPart_) {
1707  int indx = waferIndex(wafer, lay);
1708  in = (hgpar_->waferInfoMap_.find(indx) != hgpar_->waferInfoMap_.end());
1709 #ifdef EDM_ML_DEBUG
1710  if (!in)
1711  edm::LogVerbatim("HGCalGeom") << "WaferInLayerTest: Layer " << lay << " wafer " << wafer << " index " << indx
1712  << "( " << HGCalWaferIndex::waferLayer(indx) << ", "
1713  << HGCalWaferIndex::waferU(indx) << ", " << HGCalWaferIndex::waferV(indx)
1714  << ") in " << in;
1715 #endif
1716  }
1717 #ifdef EDM_ML_DEBUG
1718  edm::LogVerbatim("HGCalGeom") << "WaferInLayerTest: Layer " << lay << " wafer " << wafer << " R-limits "
1719  << hgpar_->rMinLayHex_[lay] << ":" << hgpar_->rMaxLayHex_[lay] << " Corners "
1720  << corner.first << ":" << corner.second << " In " << in;
1721 #endif
1722  }
1723  return in;
1724 }
1725 
1726 std::pair<double, double> HGCalDDDConstants::waferPositionNoRot(
1727  int lay, int waferU, int waferV, bool reco, bool debug) const {
1728  int ll = lay - hgpar_->firstLayer_;
1729  double x = hgpar_->xLayerHex_[ll];
1730  double y = hgpar_->yLayerHex_[ll];
1731 #ifdef EDM_ML_DEBUG
1732  if (debug)
1733  edm::LogVerbatim("HGCalGeom") << "Layer " << lay << ":" << ll << " Shift " << hgpar_->xLayerHex_[ll] << ":"
1734  << hgpar_->yLayerHex_[ll] << " U:V " << waferU << ":" << waferV;
1735 #endif
1736  if (!reco) {
1739  }
1740  const auto& xy = waferPosition(waferU, waferV, reco);
1741  x += xy.first;
1742  y += xy.second;
1743 #ifdef EDM_ML_DEBUG
1744  if (debug)
1745  edm::LogVerbatim("HGCalGeom") << "With wafer " << x << ":" << y << ":" << xy.first << ":" << xy.second;
1746 #endif
1747  return std::make_pair(x, y);
1748 }
1749 
1750 std::pair<double, double> HGCalDDDConstants::waferPosition(int waferU, int waferV, bool reco) const {
1751  double xx(0), yy(0);
1752  int indx = HGCalWaferIndex::waferIndex(0, waferU, waferV);
1753  auto itr = hgpar_->wafersInLayers_.find(indx);
1754  if (itr != hgpar_->wafersInLayers_.end()) {
1755  xx = hgpar_->waferPosX_[itr->second];
1756  yy = hgpar_->waferPosY_[itr->second];
1757  }
1758  if (!reco) {
1761  }
1762  return std::make_pair(xx, yy);
1763 }
1764 
1766 
std::vector< int > iradMaxBH_
bool maskCell(const DetId &id, int corners) const
size
Write out results.
std::pair< double, double > rangeRLayer(int lay, bool reco) const
double waferZ(int layer, bool reco) const
std::vector< double > waferPosY_
Log< level::Info, true > LogVerbatim
std::vector< int > layer_
static constexpr int scintillatorCassette
const int nphi
void waferFromPosition(const double x, const double y, int &wafer, int &icell, int &celltyp) const
std::pair< double, double > rangeZ(bool reco) const
std::vector< int > depthLayerF_
std::vector< int > depth_
std::vector< double > zFrontMin_
std::vector< double > moduleCellR_
unsigned int layersInit(bool reco) const
hgtrap getModule(unsigned int k, bool reco) const
static constexpr int32_t cellPlacementOld
Definition: HGCalCell.h:25
bool isValidCell(int layindex, int wafer, int cell) const
wafer_map cellFineIndex_
layer_map copiesInLayers_
static void radius(double zf, double zb, std::vector< double > const &zFront1, std::vector< double > const &rFront1, std::vector< double > const &slope1, std::vector< double > const &zFront2, std::vector< double > const &rFront2, std::vector< double > const &slope2, int flag, std::vector< double > &zz, std::vector< double > &rin, std::vector< double > &rout)
std::vector< std::pair< double, double > > layerRotV_
int getPhiBins(int lay) const
int layer() const
get the layer #
Definition: HFNoseDetId.h:56
std::pair< double, double > cellEtaPhiTrap(int type, int irad) const
std::vector< bool > cellCoarseHalf_
int scintType(const int layer) const
std::vector< bool > cellFineHalf_
def all(container)
workaround iterator generators for ROOT classes
Definition: cmstools.py:25
static std::pair< int32_t, int32_t > cellType(int32_t u, int32_t v, int32_t ncell, int32_t placementIndex)
Definition: HGCalCell.cc:242
std::pair< double, double > waferParameters(bool reco) const
bool waferInLayerTest(int wafer, int lay, bool full) const
static int32_t getUnpackedU(int id)
Definition: HGCalTypes.cc:16
std::vector< int > moduleLayR_
static constexpr int k_fourCorners
bool waferFullInLayer(int wafer, int lay, bool reco) const
double distFromEdgeTrap(double x, double y, double z) const
Simrecovecs max_modules_layer_
HGCalParameters::hgtrap getModule(unsigned int k, bool hexType, bool reco) const
int32_t waferU(const int32_t index)
int32_t waferLayer(const int32_t index)
int waferU() const
Definition: HFNoseDetId.h:75
constexpr NumType convertRadToDeg(NumType radians)
Definition: angle_units.h:21
bool isValidHex(int lay, int mod, int cell, bool reco) const
static bool goodCell(int u, int v, int N, int type, int rotn)
bool isValidHex8(int lay, int waferU, int waferV, bool fullAndPart=false) const
static constexpr int32_t WaferOut
Definition: HGCalTypes.h:55
std::pair< int, int > waferTypeRotation(int layer, int waferU, int waferV, bool fromFile=false, bool debug=false) const
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
static constexpr int32_t WaferThree
Definition: HGCalTypes.h:41
std::vector< double > cellFineY_
std::pair< int, int > getREtaRange(int lay) const
int lastLayer(bool reco) const
static int32_t getUnpackedV(int id)
Definition: HGCalTypes.cc:22
std::pair< double, double > getXY(int layer, double x, double y, bool forwd) const
bool waferHexagon8() const
int modulesInit(int lay, bool reco) const
std::unordered_map< int32_t, bool > waferIn_
int zside(DetId const &)
int layerFromIndex(int index, bool reco) const
std::vector< uint32_t > trformIndex_
void find(edm::Handle< EcalRecHitCollection > &hits, DetId thisDet, std::vector< EcalRecHitCollection::const_iterator > &hit, bool debug=false)
Definition: FindCaloHit.cc:19
int32_t cellType(int type, int waferU, int waferV, int iz, int fwdBack, int orient) const
std::vector< int > layerGroupM_
bool waferHexagon6() const
constexpr Detector det() const
get the detector field from this detid
Definition: DetId.h:46
float float float z
std::pair< double, double > shiftXY(int waferPosition, double waferSize) const
constexpr uint32_t mask
Definition: gpuClustering.h:24
hgtrform getTrForm(unsigned int k) const
static constexpr uint32_t k_CornerSize
constexpr std::array< uint8_t, layerIndexSize > layer
wafer_map wafersInLayers_
HGCalGeomTools geomTools_
bool waferInLayer(int wafer, int lay, bool reco) const
U second(std::pair< T, U > const &p)
double scintCellSize(const int layer) const
std::vector< double > cellCoarseX_
static constexpr int scintillatorFile
std::map< int, HGCWaferParam > waferLayer_
int32_t tileIndex(int32_t layer, int32_t ring, int32_t phi)
std::vector< std::pair< int, int > > tileRingRange_
int layer() const
get the layer #
static constexpr int32_t WaferFull
Definition: HGCalTypes.h:34
static std::pair< int32_t, int32_t > waferCorner(double xpos, double ypos, double r, double R, double rMin, double rMax, bool oldBug=false)
std::vector< int > firstModule_
unsigned int waferFileSize() const
int getTypeHex(int layer, int waferU, int waferV) const
static constexpr int32_t WaferHalf
Definition: HGCalTypes.h:38
int getType(double xpos, double ypos, double zpos)
bool isHalfCell(int waferType, int cell) const
int maxCells(bool reco) const
std::vector< double > cellSize_
std::vector< int > waferUVMaxLayer_
std::vector< int > layerIndex_
std::vector< double > yLayerHex_
static int32_t cellPlacementIndex(int32_t iz, int32_t fwdBack, int32_t orient)
Definition: HGCalCell.cc:230
T sqrt(T t)
Definition: SSEVec.h:19
HGCalDDDConstants(const HGCalParameters *hp, const std::string &name)
int layerIndex(int lay, bool reco) const
std::pair< float, float > localToGlobal8(int lay, int waferU, int waferV, double localX, double localY, bool reco, bool debug) const
std::vector< double > rMaxFront_
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
Definition: GenABIO.cc:168
int waferType(DetId const &id, bool fromFile=false) const
bool isValidTrap(int lay, int ieta, int iphi) const
int getUVMax(int type) const
bool isValidCell8(int lay, int waferU, int waferV, int cellU, int cellV, int type) const
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::pair< int, int > simToReco(int cell, int layer, int mod, bool half) const
std::pair< int, float > getIndex(int lay, bool reco) const
int waferU() const
bool waferVirtual(int layer, int waferU, int waferV) const
int tileCount(int layer, int ring) const
std::pair< int, int > assignCell(float x, float y, int lay, int subSec, bool reco) const
std::vector< double > slopeTop_
std::vector< int > layerCenter_
std::vector< HGCalParameters::hgtrap > getModules() const
double mouseBite(bool reco) const
unsigned int layers(bool reco) const
static constexpr int32_t WaferCorner0
Definition: HGCalTypes.h:12
bool tileTrapezoid() const
std::vector< double > rMinLayHex_
int32_t waferIndex(int32_t layer, int32_t waferU, int32_t waferV, bool old=false)
int getTypeTrap(int layer) const
int type() const
get the type
Definition: HFNoseDetId.h:50
double cellSizeHex(int type) const
std::vector< double > zLayerHex_
std::vector< int > layerType_
#define M_PI
waferT_map waferTypes_
#define TYPELOOKUP_DATA_REG(_dataclass_)
Definition: typelookup.h:102
std::pair< double, double > rangeR(double z, bool reco) const
std::pair< double, double > waferPosition(int wafer, bool reco) const
std::vector< double > rMaxLayHex_
caConstants::TupleMultiplicity const CAHitNtupletGeneratorKernelsGPU::HitToTuple const cms::cuda::AtomicPairCounter GPUCACell const *__restrict__ cells
std::vector< double > slopeMin_
static constexpr int32_t WaferCenterR
Definition: HGCalTypes.h:26
Definition: DetId.h:17
std::vector< int > lastModule_
std::array< int, 4 > waferMax_
static constexpr double k_ScaleToDDD
int numberCellsHexagon(int wafer) const
std::vector< double > radiusMixBoundary_
std::array< int, 3 > assignCellTrap(float x, float y, float z, int lay, bool reco) const
#define debug
Definition: HDRShower.cc:19
bool cellInLayer(int waferU, int waferV, int cellU, int cellV, int lay, bool reco) const
#define N
Definition: blowfish.cc:9
std::vector< double > cellThickness_
int waferV() const
static constexpr int k_fiveCorners
std::vector< int > layerGroup_
constexpr uint16_t localX(uint16_t px)
int numberCells(bool reco) const
part
Definition: HCALResponse.h:20
std::vector< double > moduleCellS_
std::pair< float, float > locateCellHex(int cell, int wafer, bool reco) const
double cellThickness(int layer, int waferU, int waferV) const
constexpr uint16_t localY(uint16_t py, uint16_t n)
double b
Definition: hdecay.h:118
wafer_map cellCoarseIndex_
std::pair< int, int > rowColumnWafer(const int wafer) const
int waferV() const
Definition: HFNoseDetId.h:78
unsigned int getTrFormN() const
HGCalParameters::hgtrform getTrForm(unsigned int k) const
std::vector< double > rMinFront_
std::pair< float, float > locateCell(int cell, int lay, int type, bool reco) const
std::vector< int > iradMinBH_
std::vector< double > cellFineX_
int maxRows(int lay, bool reco) const
wafer_map typesInLayers_
const HGCalGeometryMode::GeometryMode mode_
int32_t waferIndex(int wafer, int index) const
std::array< int, 5 > assignCellHex(float x, float y, int lay, bool reco, bool extend=false, bool debug=false) const
static constexpr double k_ScaleFromDDD
std::vector< HGCalParameters::hgtrform > getTrForms() const
std::vector< int > layerGroupO_
fixed size matrix
static constexpr int k_OffsetRotation
int getLayer(double z, bool reco) const
static constexpr int k_threeCorners
std::array< int, 3 > HGCWaferParam
int32_t waferV(const int32_t index)
int waferTypeL(int wafer) const
std::vector< int > waferCopy_
col
Definition: cuy.py:1009
static unsigned int const shift
float x
std::vector< int > depthIndex_
static constexpr double tan30deg_
std::pair< double, double > waferPositionNoRot(int lay, int waferU, int waferV, bool reco, bool debug=false) const
std::vector< double > zFrontTop_
std::vector< double > radiusLayer_[2]
std::array< uint32_t, 2 > tot_layers_
static constexpr int32_t WaferFive
Definition: HGCalTypes.h:35
std::vector< int > waferTypeT_
int modules(int lay, bool reco) const
static constexpr int32_t WaferCornerMin
Definition: HGCalTypes.h:73
int modifyUV(int uv, int type1, int type2) const
std::vector< double > cellCoarseY_
int type() const
get the type
Log< level::Warning, false > LogWarning
waferInfo_map waferInfoMap_
__host__ __device__ V wmin
const HGCalParameters * hgpar_
std::vector< double > waferPosX_
T mod(const T &a, const T &b)
Definition: ecalDccMap.h:4
int scintCells(const int layer) const
tileInfo_map tileInfoMap_
static constexpr int k_allCorners
int cellHex(double xx, double yy, const double &cellR, const std::vector< double > &posX, const std::vector< double > &posY) const
std::vector< int > waferTypeL_
std::vector< double > xLayerHex_
std::pair< float, float > locateCellTrap(int lay, int ieta, int iphi, bool reco) const
double distFromEdgeHex(double x, double y, double z) const
int waferFromCopy(int copy) const
__host__ __device__ V V wmax
static bool maskCell(int u, int v, int N, int ncor, int fcor, int corners)