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HGCalGeomParameters.cc
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2 
5 
21 
22 #include <algorithm>
23 #include <sstream>
24 #include <unordered_set>
25 
26 //#define EDM_ML_DEBUG
27 using namespace geant_units::operators;
28 
29 const double tolerance = 0.001;
30 const double tolmin = 1.e-20;
31 
33 #ifdef EDM_ML_DEBUG
34  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters::HGCalGeomParameters "
35  << "constructor";
36 #endif
37 }
38 
40  HGCalParameters& php,
41  const std::string& sdTag1,
42  const DDCompactView* cpv,
43  const std::string& sdTag2,
44  const std::string& sdTag3,
46  DDFilteredView fv = _fv;
47  bool dodet(true);
48  std::map<int, HGCalGeomParameters::layerParameters> layers;
49  std::vector<HGCalParameters::hgtrform> trforms;
50  std::vector<bool> trformUse;
51 
52  while (dodet) {
53  const DDSolid& sol = fv.logicalPart().solid();
54  // Layers first
55  std::vector<int> copy = fv.copyNumbers();
56  int nsiz = static_cast<int>(copy.size());
57  int lay = (nsiz > 0) ? copy[nsiz - 1] : 0;
58  int zp = (nsiz > 2) ? copy[nsiz - 3] : -1;
59  if (zp != 1)
60  zp = -1;
61  if (lay == 0) {
62  throw cms::Exception("DDException") << "Funny layer # " << lay << " zp " << zp << " in " << nsiz << " components";
63  } else {
64  if (std::find(php.layer_.begin(), php.layer_.end(), lay) == php.layer_.end())
65  php.layer_.emplace_back(lay);
66  auto itr = layers.find(lay);
67  if (itr == layers.end()) {
68  double rin(0), rout(0);
70  if ((sol.shape() == DDSolidShape::ddpolyhedra_rz) || (sol.shape() == DDSolidShape::ddpolyhedra_rrz)) {
71  const DDPolyhedra& polyhedra = static_cast<DDPolyhedra>(sol);
72  const std::vector<double>& rmin = polyhedra.rMinVec();
73  const std::vector<double>& rmax = polyhedra.rMaxVec();
74  rin = 0.5 * HGCalParameters::k_ScaleFromDDD * (rmin[0] + rmin[1]);
75  rout = 0.5 * HGCalParameters::k_ScaleFromDDD * (rmax[0] + rmax[1]);
76  } else if (sol.shape() == DDSolidShape::ddtubs) {
77  const DDTubs& tube = static_cast<DDTubs>(sol);
78  rin = HGCalParameters::k_ScaleFromDDD * tube.rIn();
79  rout = HGCalParameters::k_ScaleFromDDD * tube.rOut();
80  }
81  HGCalGeomParameters::layerParameters laypar(rin, rout, zz);
82  layers[lay] = laypar;
83  }
84  DD3Vector x, y, z;
85  fv.rotation().GetComponents(x, y, z);
86  const CLHEP::HepRep3x3 rotation(x.X(), y.X(), z.X(), x.Y(), y.Y(), z.Y(), x.Z(), y.Z(), z.Z());
87  const CLHEP::HepRotation hr(rotation);
89  if (std::abs(xx) < tolerance)
90  xx = 0;
92  if (std::abs(yy) < tolerance)
93  yy = 0;
95  const CLHEP::Hep3Vector h3v(xx, yy, zz);
97  mytrf.zp = zp;
98  mytrf.lay = lay;
99  mytrf.sec = 0;
100  mytrf.subsec = 0;
101  mytrf.h3v = h3v;
102  mytrf.hr = hr;
103  trforms.emplace_back(mytrf);
104  trformUse.emplace_back(false);
105  }
106  dodet = fv.next();
107  }
108 
109  // Then wafers
110  // This assumes layers are build starting from 1 (which on 25 Jan 2016, they
111  // were) to ensure that new copy numbers are always added to the end of the
112  // list.
113  std::unordered_map<int32_t, int32_t> copies;
114  HGCalParameters::layer_map copiesInLayers(layers.size() + 1);
115  std::vector<int32_t> wafer2copy;
116  std::vector<HGCalGeomParameters::cellParameters> wafers;
117  std::string attribute = "Volume";
118  DDValue val1(attribute, sdTag2, 0.0);
119  DDSpecificsMatchesValueFilter filter1{val1};
120  DDFilteredView fv1(*cpv, filter1);
121  bool ok = fv1.firstChild();
122  if (!ok) {
123  throw cms::Exception("DDException") << "Attribute " << val1 << " not found but needed.";
124  } else {
125  dodet = true;
126  std::unordered_set<std::string> names;
127  while (dodet) {
128  const DDSolid& sol = fv1.logicalPart().solid();
129  const std::string& name = fv1.logicalPart().name().name();
130  std::vector<int> copy = fv1.copyNumbers();
131  int nsiz = static_cast<int>(copy.size());
132  int wafer = (nsiz > 0) ? copy[nsiz - 1] : 0;
133  int layer = (nsiz > 1) ? copy[nsiz - 2] : 0;
134  if (nsiz < 2) {
135  throw cms::Exception("DDException") << "Funny wafer # " << wafer << " in " << nsiz << " components";
136  } else if (layer > static_cast<int>(layers.size())) {
137  edm::LogWarning("HGCalGeom") << "Funny wafer # " << wafer << " Layer " << layer << ":" << layers.size()
138  << " among " << nsiz << " components";
139  } else {
140  auto itr = copies.find(wafer);
141  auto cpy = copiesInLayers[layer].find(wafer);
142  if (itr != copies.end() && cpy == copiesInLayers[layer].end()) {
143  copiesInLayers[layer][wafer] = itr->second;
144  }
145  if (itr == copies.end()) {
146  copies[wafer] = wafer2copy.size();
147  copiesInLayers[layer][wafer] = wafer2copy.size();
148  double xx = HGCalParameters::k_ScaleFromDDD * fv1.translation().X();
149  if (std::abs(xx) < tolerance)
150  xx = 0;
151  double yy = HGCalParameters::k_ScaleFromDDD * fv1.translation().Y();
152  if (std::abs(yy) < tolerance)
153  yy = 0;
154  wafer2copy.emplace_back(wafer);
156  HGCalGeomParameters::cellParameters cell(false, wafer, p);
157  wafers.emplace_back(cell);
158  if (names.count(name) == 0) {
159  std::vector<double> zv, rv;
161  const DDPolyhedra& polyhedra = static_cast<DDPolyhedra>(sol);
162  zv = polyhedra.zVec();
163  rv = polyhedra.rMaxVec();
164  } else {
165  const DDExtrudedPolygon& polygon = static_cast<DDExtrudedPolygon>(sol);
166  zv = polygon.zVec();
167  rv = polygon.xVec();
168  }
171  double dz = 0.5 * HGCalParameters::k_ScaleFromDDDToG4 * (zv[1] - zv[0]);
172 #ifdef EDM_ML_DEBUG
173  edm::LogVerbatim("HGCalGeom")
174  << "Mode " << mode << " R " << php.waferSize_ << ":" << php.waferR_ << " z " << dz;
175 #endif
177  mytr.lay = 1;
178  mytr.bl = php.waferR_;
179  mytr.tl = php.waferR_;
180  mytr.h = php.waferR_;
181  mytr.dz = dz;
182  mytr.alpha = 0.0;
183  mytr.cellSize = waferSize_;
184  php.fillModule(mytr, false);
185  names.insert(name);
186  }
187  }
188  }
189  dodet = fv1.next();
190  }
191  }
192 
193  // Finally the cells
194  std::map<int, int> wafertype;
195  std::map<int, HGCalGeomParameters::cellParameters> cellsf, cellsc;
196  DDValue val2(attribute, sdTag3, 0.0);
197  DDSpecificsMatchesValueFilter filter2{val2};
198  DDFilteredView fv2(*cpv, filter2);
199  ok = fv2.firstChild();
200  if (!ok) {
201  throw cms::Exception("DDException") << "Attribute " << val2 << " not found but needed.";
202  } else {
203  dodet = true;
204  while (dodet) {
205  const DDSolid& sol = fv2.logicalPart().solid();
206  const std::string& name = sol.name().name();
207  std::vector<int> copy = fv2.copyNumbers();
208  int nsiz = static_cast<int>(copy.size());
209  int cellx = (nsiz > 0) ? copy[nsiz - 1] : 0;
210  int wafer = (nsiz > 1) ? copy[nsiz - 2] : 0;
211  int cell = HGCalTypes::getUnpackedCell6(cellx);
213  if (type != 1 && type != 2) {
214  throw cms::Exception("DDException")
215  << "Funny cell # " << cell << " type " << type << " in " << nsiz << " components";
216  } else {
217  auto ktr = wafertype.find(wafer);
218  if (ktr == wafertype.end())
219  wafertype[wafer] = type;
220  bool newc(false);
221  std::map<int, HGCalGeomParameters::cellParameters>::iterator itr;
222  double cellsize = php.cellSize_[0];
223  if (type == 1) {
224  itr = cellsf.find(cell);
225  newc = (itr == cellsf.end());
226  } else {
227  itr = cellsc.find(cell);
228  newc = (itr == cellsc.end());
229  cellsize = php.cellSize_[1];
230  }
231  if (newc) {
232  bool half = (name.find("Half") != std::string::npos);
233  double xx = HGCalParameters::k_ScaleFromDDD * fv2.translation().X();
234  double yy = HGCalParameters::k_ScaleFromDDD * fv2.translation().Y();
235  if (half) {
236  math::XYZPointD p1(-2.0 * cellsize / 9.0, 0, 0);
237  math::XYZPointD p2 = fv2.rotation()(p1);
240 #ifdef EDM_ML_DEBUG
241  if (std::abs(p2.X()) < HGCalParameters::tol)
242  p2.SetX(0.0);
243  if (std::abs(p2.Z()) < HGCalParameters::tol)
244  p2.SetZ(0.0);
245  edm::LogVerbatim("HGCalGeom") << "Wafer " << wafer << " Type " << type << " Cell " << cellx << " local "
246  << xx << ":" << yy << " new " << p1 << ":" << p2;
247 #endif
248  }
250  if (type == 1) {
251  cellsf[cell] = cp;
252  } else {
253  cellsc[cell] = cp;
254  }
255  }
256  }
257  dodet = fv2.next();
258  }
259  }
260 
262  layers, trforms, trformUse, copies, copiesInLayers, wafer2copy, wafers, wafertype, cellsf, cellsc, php);
263 }
264 
266  HGCalParameters& php,
267  const std::string& sdTag1,
268  const std::string& sdTag2,
269  const std::string& sdTag3,
271  const cms::DDFilter filter("Volume", sdTag1);
272  cms::DDFilteredView fv((*cpv), filter);
273  std::map<int, HGCalGeomParameters::layerParameters> layers;
274  std::vector<HGCalParameters::hgtrform> trforms;
275  std::vector<bool> trformUse;
276  std::vector<std::pair<int, int> > trused;
277 
278  while (fv.firstChild()) {
279  const std::vector<double>& pars = fv.parameters();
280  // Layers first
281  std::vector<int> copy = fv.copyNos();
282  int nsiz = static_cast<int>(copy.size());
283  int lay = (nsiz > 0) ? copy[0] : 0;
284  int zp = (nsiz > 2) ? copy[2] : -1;
285  if (zp != 1)
286  zp = -1;
287  if (lay == 0) {
288  throw cms::Exception("DDException") << "Funny layer # " << lay << " zp " << zp << " in " << nsiz << " components";
289  } else {
290  if (std::find(php.layer_.begin(), php.layer_.end(), lay) == php.layer_.end())
291  php.layer_.emplace_back(lay);
292  auto itr = layers.find(lay);
294  if (itr == layers.end()) {
295  double rin(0), rout(0);
296  if (dd4hep::isA<dd4hep::Polyhedra>(fv.solid())) {
297  rin = 0.5 * HGCalParameters::k_ScaleFromDD4hep * (pars[5] + pars[8]);
298  rout = 0.5 * HGCalParameters::k_ScaleFromDD4hep * (pars[6] + pars[9]);
299  } else if (dd4hep::isA<dd4hep::Tube>(fv.solid())) {
300  dd4hep::Tube tubeSeg(fv.solid());
301  rin = HGCalParameters::k_ScaleFromDD4hep * tubeSeg.rMin();
302  rout = HGCalParameters::k_ScaleFromDD4hep * tubeSeg.rMax();
303  }
304  HGCalGeomParameters::layerParameters laypar(rin, rout, zz);
305  layers[lay] = laypar;
306  }
307  std::pair<int, int> layz(lay, zp);
308  if (std::find(trused.begin(), trused.end(), layz) == trused.end()) {
309  trused.emplace_back(layz);
310  DD3Vector x, y, z;
311  fv.rotation().GetComponents(x, y, z);
312  const CLHEP::HepRep3x3 rotation(x.X(), y.X(), z.X(), x.Y(), y.Y(), z.Y(), x.Z(), y.Z(), z.Z());
313  const CLHEP::HepRotation hr(rotation);
315  if (std::abs(xx) < tolerance)
316  xx = 0;
318  if (std::abs(yy) < tolerance)
319  yy = 0;
321  const CLHEP::Hep3Vector h3v(xx, yy, zz);
323  mytrf.zp = zp;
324  mytrf.lay = lay;
325  mytrf.sec = 0;
326  mytrf.subsec = 0;
327  mytrf.h3v = h3v;
328  mytrf.hr = hr;
329  trforms.emplace_back(mytrf);
330  trformUse.emplace_back(false);
331  }
332  }
333  }
334 
335  // Then wafers
336  // This assumes layers are build starting from 1 (which on 25 Jan 2016, they
337  // were) to ensure that new copy numbers are always added to the end of the
338  // list.
339  std::unordered_map<int32_t, int32_t> copies;
340  HGCalParameters::layer_map copiesInLayers(layers.size() + 1);
341  std::vector<int32_t> wafer2copy;
342  std::vector<HGCalGeomParameters::cellParameters> wafers;
343  const cms::DDFilter filter1("Volume", sdTag2);
344  cms::DDFilteredView fv1((*cpv), filter1);
345  bool ok = fv1.firstChild();
346  if (!ok) {
347  throw cms::Exception("DDException") << "Attribute " << sdTag2 << " not found but needed.";
348  } else {
349  bool dodet = true;
350  std::unordered_set<std::string> names;
351  while (dodet) {
352  const std::string name = static_cast<std::string>(fv1.name());
353  std::vector<int> copy = fv1.copyNos();
354  int nsiz = static_cast<int>(copy.size());
355  int wafer = (nsiz > 0) ? copy[0] : 0;
356  int layer = (nsiz > 1) ? copy[1] : 0;
357  if (nsiz < 2) {
358  throw cms::Exception("DDException") << "Funny wafer # " << wafer << " in " << nsiz << " components";
359  } else if (layer > static_cast<int>(layers.size())) {
360  edm::LogWarning("HGCalGeom") << "Funny wafer # " << wafer << " Layer " << layer << ":" << layers.size()
361  << " among " << nsiz << " components";
362  } else {
363  auto itr = copies.find(wafer);
364  auto cpy = copiesInLayers[layer].find(wafer);
365  if (itr != copies.end() && cpy == copiesInLayers[layer].end()) {
366  copiesInLayers[layer][wafer] = itr->second;
367  }
368  if (itr == copies.end()) {
369  copies[wafer] = wafer2copy.size();
370  copiesInLayers[layer][wafer] = wafer2copy.size();
372  if (std::abs(xx) < tolerance)
373  xx = 0;
375  if (std::abs(yy) < tolerance)
376  yy = 0;
377  wafer2copy.emplace_back(wafer);
379  HGCalGeomParameters::cellParameters cell(false, wafer, p);
380  wafers.emplace_back(cell);
381  if (names.count(name) == 0) {
382  double zv[2], rv;
383  const std::vector<double>& pars = fv1.parameters();
385  zv[0] = pars[4];
386  zv[1] = pars[7];
387  rv = pars[6];
388  } else {
389  zv[0] = pars[3];
390  zv[1] = pars[9];
391  rv = pars[4];
392  }
395  double dz = 0.5 * HGCalParameters::k_ScaleFromDD4hepToG4 * (zv[1] - zv[0]);
396 #ifdef EDM_ML_DEBUG
397  edm::LogVerbatim("HGCalGeom")
398  << "Mode " << mode << " R " << php.waferSize_ << ":" << php.waferR_ << " z " << dz;
399 #endif
401  mytr.lay = 1;
402  mytr.bl = php.waferR_;
403  mytr.tl = php.waferR_;
404  mytr.h = php.waferR_;
405  mytr.dz = dz;
406  mytr.alpha = 0.0;
407  mytr.cellSize = waferSize_;
408  php.fillModule(mytr, false);
409  names.insert(name);
410  }
411  }
412  }
413  dodet = fv1.firstChild();
414  }
415  }
416 
417  // Finally the cells
418  std::map<int, int> wafertype;
419  std::map<int, HGCalGeomParameters::cellParameters> cellsf, cellsc;
420  const cms::DDFilter filter2("Volume", sdTag3);
421  cms::DDFilteredView fv2((*cpv), filter2);
422  ok = fv2.firstChild();
423  if (!ok) {
424  throw cms::Exception("DDException") << "Attribute " << sdTag3 << " not found but needed.";
425  } else {
426  bool dodet = true;
427  while (dodet) {
428  const std::string name = static_cast<std::string>(fv2.name());
429  std::vector<int> copy = fv2.copyNos();
430  int nsiz = static_cast<int>(copy.size());
431  int cellx = (nsiz > 0) ? copy[0] : 0;
432  int wafer = (nsiz > 1) ? copy[1] : 0;
433  int cell = HGCalTypes::getUnpackedCell6(cellx);
435  if (type != 1 && type != 2) {
436  throw cms::Exception("DDException")
437  << "Funny cell # " << cell << " type " << type << " in " << nsiz << " components";
438  } else {
439  auto ktr = wafertype.find(wafer);
440  if (ktr == wafertype.end())
441  wafertype[wafer] = type;
442  bool newc(false);
443  std::map<int, HGCalGeomParameters::cellParameters>::iterator itr;
444  double cellsize = php.cellSize_[0];
445  if (type == 1) {
446  itr = cellsf.find(cell);
447  newc = (itr == cellsf.end());
448  } else {
449  itr = cellsc.find(cell);
450  newc = (itr == cellsc.end());
451  cellsize = php.cellSize_[1];
452  }
453  if (newc) {
454  bool half = (name.find("Half") != std::string::npos);
457  if (half) {
458  math::XYZPointD p1(-2.0 * cellsize / 9.0, 0, 0);
459  math::XYZPointD p2 = fv2.rotation()(p1);
462 #ifdef EDM_ML_DEBUG
463  if (std::abs(p2.X()) < HGCalParameters::tol)
464  p2.SetX(0.0);
465  if (std::abs(p2.Z()) < HGCalParameters::tol)
466  p2.SetZ(0.0);
467  edm::LogVerbatim("HGCalGeom") << "Wafer " << wafer << " Type " << type << " Cell " << cellx << " local "
468  << xx << ":" << yy << " new " << p1 << ":" << p2;
469 #endif
470  }
472  if (type == 1) {
473  cellsf[cell] = cp;
474  } else {
475  cellsc[cell] = cp;
476  }
477  }
478  }
479  dodet = fv2.firstChild();
480  }
481  }
482 
484  layers, trforms, trformUse, copies, copiesInLayers, wafer2copy, wafers, wafertype, cellsf, cellsc, php);
485 }
486 
487 void HGCalGeomParameters::loadGeometryHexagon(const std::map<int, HGCalGeomParameters::layerParameters>& layers,
488  std::vector<HGCalParameters::hgtrform>& trforms,
489  std::vector<bool>& trformUse,
490  const std::unordered_map<int32_t, int32_t>& copies,
491  const HGCalParameters::layer_map& copiesInLayers,
492  const std::vector<int32_t>& wafer2copy,
493  const std::vector<HGCalGeomParameters::cellParameters>& wafers,
494  const std::map<int, int>& wafertype,
495  const std::map<int, HGCalGeomParameters::cellParameters>& cellsf,
496  const std::map<int, HGCalGeomParameters::cellParameters>& cellsc,
497  HGCalParameters& php) {
498  if (((cellsf.size() + cellsc.size()) == 0) || (wafers.empty()) || (layers.empty())) {
499  throw cms::Exception("DDException") << "HGCalGeomParameters: mismatch between geometry and specpar: cells "
500  << cellsf.size() << ":" << cellsc.size() << " wafers " << wafers.size()
501  << " layers " << layers.size();
502  }
503 
504  for (unsigned int i = 0; i < layers.size(); ++i) {
505  for (auto& layer : layers) {
506  if (layer.first == static_cast<int>(i + php.firstLayer_)) {
507  php.layerIndex_.emplace_back(i);
508  php.rMinLayHex_.emplace_back(layer.second.rmin);
509  php.rMaxLayHex_.emplace_back(layer.second.rmax);
510  php.zLayerHex_.emplace_back(layer.second.zpos);
511  break;
512  }
513  }
514  }
515 
516  for (unsigned int i = 0; i < php.layer_.size(); ++i) {
517  for (unsigned int i1 = 0; i1 < trforms.size(); ++i1) {
518  if (!trformUse[i1] && php.layerGroup_[trforms[i1].lay - 1] == static_cast<int>(i + 1)) {
519  trforms[i1].h3v *= static_cast<double>(HGCalParameters::k_ScaleFromDDD);
520  trforms[i1].lay = (i + 1);
521  trformUse[i1] = true;
522  php.fillTrForm(trforms[i1]);
523  int nz(1);
524  for (unsigned int i2 = i1 + 1; i2 < trforms.size(); ++i2) {
525  if (!trformUse[i2] && trforms[i2].zp == trforms[i1].zp &&
526  php.layerGroup_[trforms[i2].lay - 1] == static_cast<int>(i + 1)) {
527  php.addTrForm(trforms[i2].h3v);
528  nz++;
529  trformUse[i2] = true;
530  }
531  }
532  if (nz > 0) {
533  php.scaleTrForm(double(1.0 / nz));
534  }
535  }
536  }
537  }
538 
539  double rmin = HGCalParameters::k_ScaleFromDDD * php.waferR_;
540  for (unsigned i = 0; i < wafer2copy.size(); ++i) {
541  php.waferCopy_.emplace_back(wafer2copy[i]);
542  php.waferPosX_.emplace_back(wafers[i].xyz.x());
543  php.waferPosY_.emplace_back(wafers[i].xyz.y());
544  auto ktr = wafertype.find(wafer2copy[i]);
545  int typet = (ktr == wafertype.end()) ? 0 : (ktr->second);
546  php.waferTypeT_.emplace_back(typet);
547  double r = wafers[i].xyz.perp();
548  int type(3);
549  for (int k = 1; k < 4; ++k) {
550  if ((r + rmin) <= php.boundR_[k]) {
551  type = k;
552  break;
553  }
554  }
555  php.waferTypeL_.emplace_back(type);
556  }
557  php.copiesInLayers_ = copiesInLayers;
558  php.nSectors_ = static_cast<int>(php.waferCopy_.size());
559 
560  std::vector<HGCalGeomParameters::cellParameters>::const_iterator itrf = wafers.end();
561  for (unsigned int i = 0; i < cellsf.size(); ++i) {
562  auto itr = cellsf.find(i);
563  if (itr == cellsf.end()) {
564  throw cms::Exception("DDException") << "HGCalGeomParameters: missing info for fine cell number " << i;
565  } else {
566  double xx = (itr->second).xyz.x();
567  double yy = (itr->second).xyz.y();
568  int waf = (itr->second).wafer;
569  std::pair<double, double> xy = cellPosition(wafers, itrf, waf, xx, yy);
570  php.cellFineX_.emplace_back(xy.first);
571  php.cellFineY_.emplace_back(xy.second);
572  php.cellFineHalf_.emplace_back((itr->second).half);
573  }
574  }
575  itrf = wafers.end();
576  for (unsigned int i = 0; i < cellsc.size(); ++i) {
577  auto itr = cellsc.find(i);
578  if (itr == cellsc.end()) {
579  throw cms::Exception("DDException") << "HGCalGeomParameters: missing info for coarse cell number " << i;
580  } else {
581  double xx = (itr->second).xyz.x();
582  double yy = (itr->second).xyz.y();
583  int waf = (itr->second).wafer;
584  std::pair<double, double> xy = cellPosition(wafers, itrf, waf, xx, yy);
585  php.cellCoarseX_.emplace_back(xy.first);
586  php.cellCoarseY_.emplace_back(xy.second);
587  php.cellCoarseHalf_.emplace_back((itr->second).half);
588  }
589  }
590  int depth(0);
591  for (unsigned int i = 0; i < php.layerGroup_.size(); ++i) {
592  bool first(true);
593  for (unsigned int k = 0; k < php.layerGroup_.size(); ++k) {
594  if (php.layerGroup_[k] == static_cast<int>(i + 1)) {
595  if (first) {
596  php.depth_.emplace_back(i + 1);
597  php.depthIndex_.emplace_back(depth);
598  php.depthLayerF_.emplace_back(k);
599  ++depth;
600  first = false;
601  }
602  }
603  }
604  }
605  HGCalParameters::hgtrap mytr = php.getModule(0, false);
611  double dz = mytr.dz;
612  php.fillModule(mytr, true);
613  mytr.dz = 2 * dz;
614  php.fillModule(mytr, true);
615  mytr.dz = 3 * dz;
616  php.fillModule(mytr, true);
617 #ifdef EDM_ML_DEBUG
618  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters finds " << php.zLayerHex_.size() << " layers";
619  for (unsigned int i = 0; i < php.zLayerHex_.size(); ++i) {
620  int k = php.layerIndex_[i];
621  edm::LogVerbatim("HGCalGeom") << "Layer[" << i << ":" << k << ":" << php.layer_[k]
622  << "] with r = " << php.rMinLayHex_[i] << ":" << php.rMaxLayHex_[i]
623  << " at z = " << php.zLayerHex_[i];
624  }
625  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters has " << php.depthIndex_.size() << " depths";
626  for (unsigned int i = 0; i < php.depthIndex_.size(); ++i) {
627  int k = php.depthIndex_[i];
628  edm::LogVerbatim("HGCalGeom") << "Reco Layer[" << i << ":" << k << "] First Layer " << php.depthLayerF_[i]
629  << " Depth " << php.depth_[k];
630  }
631  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters finds " << php.nSectors_ << " wafers";
632  for (unsigned int i = 0; i < php.waferCopy_.size(); ++i)
633  edm::LogVerbatim("HGCalGeom") << "Wafer[" << i << ": " << php.waferCopy_[i] << "] type " << php.waferTypeL_[i]
634  << ":" << php.waferTypeT_[i] << " at (" << php.waferPosX_[i] << ","
635  << php.waferPosY_[i] << ",0)";
636  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: wafer radius " << php.waferR_ << " and dimensions of the "
637  << "wafers:";
638  edm::LogVerbatim("HGCalGeom") << "Sim[0] " << php.moduleLayS_[0] << " dx " << php.moduleBlS_[0] << ":"
639  << php.moduleTlS_[0] << " dy " << php.moduleHS_[0] << " dz " << php.moduleDzS_[0]
640  << " alpha " << php.moduleAlphaS_[0];
641  for (unsigned int k = 0; k < php.moduleLayR_.size(); ++k)
642  edm::LogVerbatim("HGCalGeom") << "Rec[" << k << "] " << php.moduleLayR_[k] << " dx " << php.moduleBlR_[k] << ":"
643  << php.moduleTlR_[k] << " dy " << php.moduleHR_[k] << " dz " << php.moduleDzR_[k]
644  << " alpha " << php.moduleAlphaR_[k];
645  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters finds " << php.cellFineX_.size() << " fine cells in a wafer";
646  for (unsigned int i = 0; i < php.cellFineX_.size(); ++i)
647  edm::LogVerbatim("HGCalGeom") << "Fine Cell[" << i << "] at (" << php.cellFineX_[i] << "," << php.cellFineY_[i]
648  << ",0)";
649  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters finds " << php.cellCoarseX_.size()
650  << " coarse cells in a wafer";
651  for (unsigned int i = 0; i < php.cellCoarseX_.size(); ++i)
652  edm::LogVerbatim("HGCalGeom") << "Coarse Cell[" << i << "] at (" << php.cellCoarseX_[i] << ","
653  << php.cellCoarseY_[i] << ",0)";
654  edm::LogVerbatim("HGCalGeom") << "Obtained " << php.trformIndex_.size() << " transformation matrices";
655  for (unsigned int k = 0; k < php.trformIndex_.size(); ++k) {
656  edm::LogVerbatim("HGCalGeom") << "Matrix[" << k << "] (" << std::hex << php.trformIndex_[k] << std::dec
657  << ") Translation (" << php.trformTranX_[k] << ", " << php.trformTranY_[k] << ", "
658  << php.trformTranZ_[k] << " Rotation (" << php.trformRotXX_[k] << ", "
659  << php.trformRotYX_[k] << ", " << php.trformRotZX_[k] << ", " << php.trformRotXY_[k]
660  << ", " << php.trformRotYY_[k] << ", " << php.trformRotZY_[k] << ", "
661  << php.trformRotXZ_[k] << ", " << php.trformRotYZ_[k] << ", " << php.trformRotZZ_[k]
662  << ")";
663  }
664  edm::LogVerbatim("HGCalGeom") << "Dump copiesInLayers for " << php.copiesInLayers_.size() << " layers";
665  for (unsigned int k = 0; k < php.copiesInLayers_.size(); ++k) {
666  const auto& theModules = php.copiesInLayers_[k];
667  edm::LogVerbatim("HGCalGeom") << "Layer " << k << ":" << theModules.size();
668  int k2(0);
669  for (std::unordered_map<int, int>::const_iterator itr = theModules.begin(); itr != theModules.end(); ++itr, ++k2) {
670  edm::LogVerbatim("HGCalGeom") << "[" << k2 << "] " << itr->first << ":" << itr->second;
671  }
672  }
673 #endif
674 }
675 
677  DDFilteredView fv = _fv;
678  bool dodet(true);
679  std::map<int, HGCalGeomParameters::layerParameters> layers;
680  std::map<std::pair<int, int>, HGCalParameters::hgtrform> trforms;
681  int levelTop = 3 + std::max(php.levelT_[0], php.levelT_[1]);
682 #ifdef EDM_ML_DEBUG
683  int ntot(0);
684 #endif
685  while (dodet) {
686 #ifdef EDM_ML_DEBUG
687  ++ntot;
688 #endif
689  std::vector<int> copy = fv.copyNumbers();
690  int nsiz = static_cast<int>(copy.size());
691  if (nsiz < levelTop) {
692  int lay = copy[nsiz - 1];
693  int zside = (nsiz > php.levelZSide_) ? copy[php.levelZSide_] : -1;
694  if (zside != 1)
695  zside = -1;
696  const DDSolid& sol = fv.logicalPart().solid();
697 #ifdef EDM_ML_DEBUG
698  edm::LogVerbatim("HGCalGeom") << sol.name() << " shape " << sol.shape() << " size " << nsiz << ":" << levelTop
699  << " lay " << lay << " z " << zside;
700 #endif
701  if (lay == 0) {
702  throw cms::Exception("DDException")
703  << "Funny layer # " << lay << " zp " << zside << " in " << nsiz << " components";
704  } else if (sol.shape() == DDSolidShape::ddtubs) {
705  if (std::find(php.layer_.begin(), php.layer_.end(), lay) == php.layer_.end())
706  php.layer_.emplace_back(lay);
707  const DDTubs& tube = static_cast<DDTubs>(sol);
708  double rin = HGCalParameters::k_ScaleFromDDD * tube.rIn();
709  double rout = HGCalParameters::k_ScaleFromDDD * tube.rOut();
710  auto itr = layers.find(lay);
711  if (itr == layers.end()) {
712  double zp = HGCalParameters::k_ScaleFromDDD * fv.translation().Z();
713  HGCalGeomParameters::layerParameters laypar(rin, rout, zp);
714  layers[lay] = laypar;
715  } else {
716  (itr->second).rmin = std::min(rin, (itr->second).rmin);
717  (itr->second).rmax = std::max(rout, (itr->second).rmax);
718  }
719  if (trforms.find(std::make_pair(lay, zside)) == trforms.end()) {
720  DD3Vector x, y, z;
721  fv.rotation().GetComponents(x, y, z);
722  const CLHEP::HepRep3x3 rotation(x.X(), y.X(), z.X(), x.Y(), y.Y(), z.Y(), x.Z(), y.Z(), z.Z());
723  const CLHEP::HepRotation hr(rotation);
724  double xx =
725  ((std::abs(fv.translation().X()) < tolerance) ? 0
727  double yy =
728  ((std::abs(fv.translation().Y()) < tolerance) ? 0
730  const CLHEP::Hep3Vector h3v(xx, yy, HGCalParameters::k_ScaleFromDDD * fv.translation().Z());
732  mytrf.zp = zside;
733  mytrf.lay = lay;
734  mytrf.sec = 0;
735  mytrf.subsec = 0;
736  mytrf.h3v = h3v;
737  mytrf.hr = hr;
738  trforms[std::make_pair(lay, zside)] = mytrf;
739  }
740  }
741  }
742  dodet = fv.next();
743  }
744 #ifdef EDM_ML_DEBUG
745  edm::LogVerbatim("HGCalGeom") << "Total # of views " << ntot;
746 #endif
747  loadGeometryHexagon8(layers, trforms, firstLayer, php);
748 }
749 
751  HGCalParameters& php,
752  const std::string& sdTag1,
753  int firstLayer) {
754  const cms::DDFilter filter("Volume", sdTag1);
755  cms::DDFilteredView fv((*cpv), filter);
756  std::map<int, HGCalGeomParameters::layerParameters> layers;
757  std::map<std::pair<int, int>, HGCalParameters::hgtrform> trforms;
758  int levelTop = 3 + std::max(php.levelT_[0], php.levelT_[1]);
759 #ifdef EDM_ML_DEBUG
760  int ntot(0);
761 #endif
762  while (fv.firstChild()) {
763 #ifdef EDM_ML_DEBUG
764  ++ntot;
765 #endif
766  // Layers first
767  int nsiz = static_cast<int>(fv.level());
768  if (nsiz < levelTop) {
769  std::vector<int> copy = fv.copyNos();
770  int lay = copy[0];
771  int zside = (nsiz > php.levelZSide_) ? copy[nsiz - php.levelZSide_ - 1] : -1;
772  if (zside != 1)
773  zside = -1;
774 #ifdef EDM_ML_DEBUG
775  edm::LogVerbatim("HGCalGeom") << fv.name() << " shape " << cms::dd::name(cms::DDSolidShapeMap, fv.shape())
776  << " size " << nsiz << ":" << levelTop << " lay " << lay << " z " << zside << ":"
777  << php.levelZSide_;
778 #endif
779  if (lay == 0) {
780  throw cms::Exception("DDException")
781  << "Funny layer # " << lay << " zp " << zside << " in " << nsiz << " components";
782  } else if (fv.shape() == cms::DDSolidShape::ddtubs) {
783  if (std::find(php.layer_.begin(), php.layer_.end(), lay) == php.layer_.end())
784  php.layer_.emplace_back(lay);
785  const std::vector<double>& pars = fv.parameters();
786  double rin = HGCalParameters::k_ScaleFromDD4hep * pars[0];
787  double rout = HGCalParameters::k_ScaleFromDD4hep * pars[1];
788  auto itr = layers.find(lay);
789  if (itr == layers.end()) {
790  double zp = HGCalParameters::k_ScaleFromDD4hep * fv.translation().Z();
791  HGCalGeomParameters::layerParameters laypar(rin, rout, zp);
792  layers[lay] = laypar;
793  } else {
794  (itr->second).rmin = std::min(rin, (itr->second).rmin);
795  (itr->second).rmax = std::max(rout, (itr->second).rmax);
796  }
797  if (trforms.find(std::make_pair(lay, zside)) == trforms.end()) {
798  DD3Vector x, y, z;
799  fv.rotation().GetComponents(x, y, z);
800  const CLHEP::HepRep3x3 rotation(x.X(), y.X(), z.X(), x.Y(), y.Y(), z.Y(), x.Z(), y.Z(), z.Z());
801  const CLHEP::HepRotation hr(rotation);
802  double xx = ((std::abs(fv.translation().X()) < tolerance)
803  ? 0
805  double yy = ((std::abs(fv.translation().Y()) < tolerance)
806  ? 0
808  const CLHEP::Hep3Vector h3v(xx, yy, HGCalParameters::k_ScaleFromDD4hep * fv.translation().Z());
810  mytrf.zp = zside;
811  mytrf.lay = lay;
812  mytrf.sec = 0;
813  mytrf.subsec = 0;
814  mytrf.h3v = h3v;
815  mytrf.hr = hr;
816  trforms[std::make_pair(lay, zside)] = mytrf;
817  }
818  }
819  }
820  }
821 #ifdef EDM_ML_DEBUG
822  edm::LogVerbatim("HGCalGeom") << "Total # of views " << ntot;
823 #endif
824  loadGeometryHexagon8(layers, trforms, firstLayer, php);
825 }
826 
828  HGCalParameters& php,
829  const std::string& sdTag1,
830  const std::string& sdTag2,
831  int firstLayer) {
832 #ifdef EDM_ML_DEBUG
833  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters (DDD)::loadGeometryHexagonModule called with tags " << sdTag1
834  << ":" << sdTag2 << " firstLayer " << firstLayer << ":" << php.firstMixedLayer_;
835  int ntot1(0), ntot2(0);
836 #endif
837  std::map<int, HGCalGeomParameters::layerParameters> layers;
838  std::map<std::pair<int, int>, double> zvals;
839  std::map<std::pair<int, int>, HGCalParameters::hgtrform> trforms;
840  int levelTop = php.levelT_[0];
841 
842  std::string attribute = "Volume";
843  DDValue val1(attribute, sdTag2, 0.0);
844  DDSpecificsMatchesValueFilter filter1{val1};
845  DDFilteredView fv1(*cpv, filter1);
846  bool dodet = fv1.firstChild();
847  while (dodet) {
848 #ifdef EDM_ML_DEBUG
849  ++ntot1;
850 #endif
851  std::vector<int> copy = fv1.copyNumbers();
852  int nsiz = static_cast<int>(copy.size());
853  if (levelTop < nsiz) {
854  int lay = copy[levelTop];
855  int zside = (nsiz > php.levelZSide_) ? copy[php.levelZSide_] : -1;
856  if (zside != 1)
857  zside = -1;
858  if (lay == 0) {
859  throw cms::Exception("DDException")
860  << "Funny layer # " << lay << " zp " << zside << " in " << nsiz << " components";
861  } else {
862  if (zvals.find(std::make_pair(lay, zside)) == zvals.end()) {
863  zvals[std::make_pair(lay, zside)] = HGCalParameters::k_ScaleFromDDD * fv1.translation().Z();
864 #ifdef EDM_ML_DEBUG
865  std::ostringstream st1;
866  st1 << "Name0 " << fv1.name() << " LTop " << levelTop << ":" << lay << " ZSide " << zside << " # of levels "
867  << nsiz;
868  for (const auto& c : copy)
869  st1 << ":" << c;
870  st1 << " Z " << zvals[std::make_pair(lay, zside)];
871  edm::LogVerbatim("HGCalGeom") << st1.str();
872 #endif
873  }
874  }
875  }
876  dodet = fv1.next();
877  }
878 
879  DDValue val2(attribute, sdTag1, 0.0);
880  DDSpecificsMatchesValueFilter filter2{val2};
881  DDFilteredView fv2(*cpv, filter2);
882  dodet = fv2.firstChild();
883  while (dodet) {
884 #ifdef EDM_ML_DEBUG
885  ++ntot2;
886 #endif
887  std::vector<int> copy = fv2.copyNumbers();
888  int nsiz = static_cast<int>(copy.size());
889  if (levelTop < nsiz) {
890  int lay = copy[levelTop];
891  int zside = (nsiz > php.levelZSide_) ? copy[php.levelZSide_] : -1;
892  if (zside != 1)
893  zside = -1;
894  const DDSolid& sol = fv2.logicalPart().solid();
895 #ifdef EDM_ML_DEBUG
896  std::ostringstream st2;
897  st2 << "Name1 " << sol.name() << " shape " << sol.shape() << " LTop " << levelTop << ":" << lay << " ZSide "
898  << zside << ":" << php.levelZSide_ << " # of levels " << nsiz;
899  for (const auto& c : copy)
900  st2 << ":" << c;
901  edm::LogVerbatim("HGCalGeom") << st2.str();
902 #endif
903  if (lay == 0) {
904  throw cms::Exception("DDException")
905  << "Funny layer # " << lay << " zp " << zside << " in " << nsiz << " components";
906  } else if (sol.shape() == DDSolidShape::ddtubs) {
907  if (zvals.find(std::make_pair(lay, zside)) != zvals.end()) {
908  if (std::find(php.layer_.begin(), php.layer_.end(), lay) == php.layer_.end())
909  php.layer_.emplace_back(lay);
910  auto itr = layers.find(lay);
911  if (itr == layers.end()) {
912  const DDTubs& tube = static_cast<DDTubs>(sol);
913  double rin = HGCalParameters::k_ScaleFromDDD * tube.rIn();
914  double rout = (php.firstMixedLayer_ > 0 && lay >= php.firstMixedLayer_)
915  ? php.radiusMixBoundary_[lay - php.firstMixedLayer_]
917  double zp = zvals[std::make_pair(lay, 1)];
918  HGCalGeomParameters::layerParameters laypar(rin, rout, zp);
919  layers[lay] = laypar;
920 #ifdef EDM_ML_DEBUG
921  std::ostringstream st3;
922  st3 << "Name1 " << fv2.name() << " LTop " << levelTop << ":" << lay << " ZSide " << zside << " # of levels "
923  << nsiz;
924  for (const auto& c : copy)
925  st3 << ":" << c;
926  st3 << " R " << rin << ":" << rout;
927  edm::LogVerbatim("HGCalGeom") << st3.str();
928 #endif
929  }
930 
931  if (trforms.find(std::make_pair(lay, zside)) == trforms.end()) {
932  DD3Vector x, y, z;
933  fv2.rotation().GetComponents(x, y, z);
934  const CLHEP::HepRep3x3 rotation(x.X(), y.X(), z.X(), x.Y(), y.Y(), z.Y(), x.Z(), y.Z(), z.Z());
935  const CLHEP::HepRotation hr(rotation);
936  double xx = ((std::abs(fv2.translation().X()) < tolerance)
937  ? 0
939  double yy = ((std::abs(fv2.translation().Y()) < tolerance)
940  ? 0
942  const CLHEP::Hep3Vector h3v(xx, yy, zvals[std::make_pair(lay, zside)]);
944  mytrf.zp = zside;
945  mytrf.lay = lay;
946  mytrf.sec = 0;
947  mytrf.subsec = 0;
948  mytrf.h3v = h3v;
949  mytrf.hr = hr;
950  trforms[std::make_pair(lay, zside)] = mytrf;
951 #ifdef EDM_ML_DEBUG
952  edm::LogVerbatim("HGCalGeom") << "Translation " << h3v;
953 #endif
954  }
955  }
956  }
957  }
958  dodet = fv2.next();
959  }
960 #ifdef EDM_ML_DEBUG
961  edm::LogVerbatim("HGCalGeom") << "Total # of views " << ntot1 << ":" << ntot2;
962 #endif
963  loadGeometryHexagon8(layers, trforms, firstLayer, php);
964 }
965 
967  HGCalParameters& php,
968  const std::string& sdTag1,
969  const std::string& sdTag2,
970  int firstLayer) {
971 #ifdef EDM_ML_DEBUG
972  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters (DD4hep)::loadGeometryHexagonModule called with tags " << sdTag1
973  << ":" << sdTag2 << " firstLayer " << firstLayer;
974  int ntot1(0), ntot2(0);
975 #endif
976  std::map<int, HGCalGeomParameters::layerParameters> layers;
977  std::map<std::pair<int, int>, HGCalParameters::hgtrform> trforms;
978  std::map<std::pair<int, int>, double> zvals;
979  int levelTop = php.levelT_[0];
980 
981  const cms::DDFilter filter1("Volume", sdTag2);
982  cms::DDFilteredView fv1((*cpv), filter1);
983  while (fv1.firstChild()) {
984 #ifdef EDM_ML_DEBUG
985  ++ntot1;
986 #endif
987  int nsiz = static_cast<int>(fv1.level());
988  if (nsiz > levelTop) {
989  std::vector<int> copy = fv1.copyNos();
990  int lay = copy[nsiz - levelTop - 1];
991  int zside = (nsiz > php.levelZSide_) ? copy[nsiz - php.levelZSide_ - 1] : -1;
992  if (zside != 1)
993  zside = -1;
994  if (lay == 0) {
995  throw cms::Exception("DDException")
996  << "Funny layer # " << lay << " zp " << zside << " in " << nsiz << " components";
997  } else {
998  if (zvals.find(std::make_pair(lay, zside)) == zvals.end()) {
999  zvals[std::make_pair(lay, zside)] = HGCalParameters::k_ScaleFromDD4hep * fv1.translation().Z();
1000 #ifdef EDM_ML_DEBUG
1001  std::ostringstream st1;
1002  st1 << "Name0 " << fv1.name() << " LTop " << levelTop << ":" << lay << " ZSide " << zside << " # of levels "
1003  << nsiz;
1004  for (const auto& c : copy)
1005  st1 << ":" << c;
1006  st1 << " Z " << zvals[std::make_pair(lay, zside)];
1007  edm::LogVerbatim("HGCalGeom") << st1.str();
1008 #endif
1009  }
1010  }
1011  }
1012  }
1013 
1014  const cms::DDFilter filter2("Volume", sdTag1);
1015  cms::DDFilteredView fv2((*cpv), filter2);
1016  while (fv2.firstChild()) {
1017  // Layers first
1018  int nsiz = static_cast<int>(fv2.level());
1019 #ifdef EDM_ML_DEBUG
1020  ++ntot2;
1021 #endif
1022  if (nsiz > levelTop) {
1023  std::vector<int> copy = fv2.copyNos();
1024  int lay = copy[nsiz - levelTop - 1];
1025  int zside = (nsiz > php.levelZSide_) ? copy[nsiz - php.levelZSide_ - 1] : -1;
1026  if (zside != 1)
1027  zside = -1;
1028 #ifdef EDM_ML_DEBUG
1029  std::ostringstream st2;
1030  st2 << "Name1 " << fv2.name() << "Shape " << cms::dd::name(cms::DDSolidShapeMap, fv2.shape()) << " LTop "
1031  << levelTop << ":" << lay << " ZSide " << zside << ":" << php.levelZSide_ << " # of levels " << nsiz;
1032  for (const auto& c : copy)
1033  st2 << ":" << c;
1034  edm::LogVerbatim("HGCalGeom") << st2.str();
1035 #endif
1036  if (lay == 0) {
1037  throw cms::Exception("DDException")
1038  << "Funny layer # " << lay << " zp " << zside << " in " << nsiz << " components";
1039  } else {
1040  if (zvals.find(std::make_pair(lay, zside)) != zvals.end()) {
1041  if (std::find(php.layer_.begin(), php.layer_.end(), lay) == php.layer_.end())
1042  php.layer_.emplace_back(lay);
1043  auto itr = layers.find(lay);
1044  if (itr == layers.end()) {
1045  const std::vector<double>& pars = fv2.parameters();
1046  double rin = HGCalParameters::k_ScaleFromDD4hep * pars[0];
1047  double rout = (php.firstMixedLayer_ > 0 && lay >= php.firstMixedLayer_)
1048  ? php.radiusMixBoundary_[lay - php.firstMixedLayer_]
1050  double zp = zvals[std::make_pair(lay, 1)];
1051  HGCalGeomParameters::layerParameters laypar(rin, rout, zp);
1052  layers[lay] = laypar;
1053 #ifdef EDM_ML_DEBUG
1054  std::ostringstream st3;
1055  st3 << "Name2 " << fv2.name() << " LTop " << levelTop << ":" << lay << " ZSide " << zside << " # of levels "
1056  << nsiz;
1057  for (const auto& c : copy)
1058  st3 << ":" << c;
1059  st3 << " R " << rin << ":" << rout;
1060  edm::LogVerbatim("HGCalGeom") << st3.str();
1061 #endif
1062  }
1063 
1064  if (trforms.find(std::make_pair(lay, zside)) == trforms.end()) {
1065  DD3Vector x, y, z;
1066  fv2.rotation().GetComponents(x, y, z);
1067  const CLHEP::HepRep3x3 rotation(x.X(), y.X(), z.X(), x.Y(), y.Y(), z.Y(), x.Z(), y.Z(), z.Z());
1068  const CLHEP::HepRotation hr(rotation);
1069  double xx = ((std::abs(fv2.translation().X()) < tolerance)
1070  ? 0
1072  double yy = ((std::abs(fv2.translation().Y()) < tolerance)
1073  ? 0
1075  const CLHEP::Hep3Vector h3v(xx, yy, zvals[std::make_pair(lay, zside)]);
1077  mytrf.zp = zside;
1078  mytrf.lay = lay;
1079  mytrf.sec = 0;
1080  mytrf.subsec = 0;
1081  mytrf.h3v = h3v;
1082  mytrf.hr = hr;
1083  trforms[std::make_pair(lay, zside)] = mytrf;
1084 #ifdef EDM_ML_DEBUG
1085  edm::LogVerbatim("HGCalGeom") << "Translation " << h3v;
1086 #endif
1087  }
1088  }
1089  }
1090  }
1091  }
1092 #ifdef EDM_ML_DEBUG
1093  edm::LogVerbatim("HGCalGeom") << "Total # of views " << ntot1 << ":" << ntot2;
1094 #endif
1095  loadGeometryHexagon8(layers, trforms, firstLayer, php);
1096 }
1097 
1098 void HGCalGeomParameters::loadGeometryHexagon8(const std::map<int, HGCalGeomParameters::layerParameters>& layers,
1099  std::map<std::pair<int, int>, HGCalParameters::hgtrform>& trforms,
1100  const int& firstLayer,
1101  HGCalParameters& php) {
1102  double rmin(0), rmax(0);
1103  for (unsigned int i = 0; i < layers.size(); ++i) {
1104  for (auto& layer : layers) {
1105  if (layer.first == static_cast<int>(i + firstLayer)) {
1106  php.layerIndex_.emplace_back(i);
1107  php.rMinLayHex_.emplace_back(layer.second.rmin);
1108  php.rMaxLayHex_.emplace_back(layer.second.rmax);
1109  php.zLayerHex_.emplace_back(layer.second.zpos);
1110  if (i == 0) {
1111  rmin = layer.second.rmin;
1112  rmax = layer.second.rmax;
1113  } else {
1114  if (rmin > layer.second.rmin)
1115  rmin = layer.second.rmin;
1116  if (rmax < layer.second.rmax)
1117  rmax = layer.second.rmax;
1118  }
1119  break;
1120  }
1121  }
1122  }
1123  php.rLimit_.emplace_back(rmin);
1124  php.rLimit_.emplace_back(rmax);
1125  php.depth_ = php.layer_;
1126  php.depthIndex_ = php.layerIndex_;
1127  php.depthLayerF_ = php.layerIndex_;
1128 
1129  for (unsigned int i = 0; i < php.layer_.size(); ++i) {
1130  for (auto& trform : trforms) {
1131  if (trform.first.first == static_cast<int>(i + firstLayer)) {
1132  php.fillTrForm(trform.second);
1133  }
1134  }
1135  }
1136 
1137 #ifdef EDM_ML_DEBUG
1138  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Minimum/maximum R " << php.rLimit_[0] << ":" << php.rLimit_[1];
1139  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters finds " << php.zLayerHex_.size() << " layers";
1140  for (unsigned int i = 0; i < php.zLayerHex_.size(); ++i) {
1141  int k = php.layerIndex_[i];
1142  edm::LogVerbatim("HGCalGeom") << "Layer[" << i << ":" << k << ":" << php.layer_[k]
1143  << "] with r = " << php.rMinLayHex_[i] << ":" << php.rMaxLayHex_[i]
1144  << " at z = " << php.zLayerHex_[i];
1145  }
1146  edm::LogVerbatim("HGCalGeom") << "Obtained " << php.trformIndex_.size() << " transformation matrices";
1147  for (unsigned int k = 0; k < php.trformIndex_.size(); ++k) {
1148  edm::LogVerbatim("HGCalGeom") << "Matrix[" << k << "] (" << std::hex << php.trformIndex_[k] << std::dec
1149  << ") Translation (" << php.trformTranX_[k] << ", " << php.trformTranY_[k] << ", "
1150  << php.trformTranZ_[k] << " Rotation (" << php.trformRotXX_[k] << ", "
1151  << php.trformRotYX_[k] << ", " << php.trformRotZX_[k] << ", " << php.trformRotXY_[k]
1152  << ", " << php.trformRotYY_[k] << ", " << php.trformRotZY_[k] << ", "
1153  << php.trformRotXZ_[k] << ", " << php.trformRotYZ_[k] << ", " << php.trformRotZZ_[k]
1154  << ")";
1155  }
1156 #endif
1157 }
1158 
1160  HGCalParameters& php,
1161  const DDCompactView* cpv,
1162  const std::string& sdTag1,
1163  const std::string& sdTag2) {
1165  php.boundR_ = getDDDArray("RadiusBound", sv, 4);
1167  php.rLimit_ = getDDDArray("RadiusLimits", sv, 2);
1169  php.levelT_ = dbl_to_int(getDDDArray("LevelTop", sv, 0));
1170 
1171  // Grouping of layers
1172  php.layerGroup_ = dbl_to_int(getDDDArray("GroupingZFine", sv, 0));
1173  php.layerGroupM_ = dbl_to_int(getDDDArray("GroupingZMid", sv, 0));
1174  php.layerGroupO_ = dbl_to_int(getDDDArray("GroupingZOut", sv, 0));
1175  php.slopeMin_ = getDDDArray("Slope", sv, 1);
1176  const auto& dummy2 = getDDDArray("LayerOffset", sv, 0);
1177  if (!dummy2.empty())
1178  php.layerOffset_ = dummy2[0];
1179  else
1180  php.layerOffset_ = 0;
1181 
1182  // Wafer size
1183  std::string attribute = "Volume";
1184  DDSpecificsMatchesValueFilter filter1{DDValue(attribute, sdTag1, 0.0)};
1185  DDFilteredView fv1(*cpv, filter1);
1186  if (fv1.firstChild()) {
1187  DDsvalues_type sv(fv1.mergedSpecifics());
1188  const auto& dummy = getDDDArray("WaferSize", sv, 0);
1189  waferSize_ = dummy[0];
1190  }
1191 
1192  // Cell size
1193  DDSpecificsMatchesValueFilter filter2{DDValue(attribute, sdTag2, 0.0)};
1194  DDFilteredView fv2(*cpv, filter2);
1195  if (fv2.firstChild()) {
1196  DDsvalues_type sv(fv2.mergedSpecifics());
1197  php.cellSize_ = getDDDArray("CellSize", sv, 0);
1198  }
1199 
1200  loadSpecParsHexagon(php);
1201 }
1202 
1204  HGCalParameters& php,
1205  const std::string& sdTag1,
1206  const std::string& sdTag2,
1207  const std::string& sdTag3,
1208  const std::string& sdTag4) {
1209  php.boundR_ = fv.get<std::vector<double> >(sdTag4, "RadiusBound");
1211  php.rLimit_ = fv.get<std::vector<double> >(sdTag4, "RadiusLimits");
1213  php.levelT_ = dbl_to_int(fv.get<std::vector<double> >(sdTag4, "LevelTop"));
1214 
1215  // Grouping of layers
1216  php.layerGroup_ = dbl_to_int(fv.get<std::vector<double> >(sdTag1, "GroupingZFine"));
1217  php.layerGroupM_ = dbl_to_int(fv.get<std::vector<double> >(sdTag1, "GroupingZMid"));
1218  php.layerGroupO_ = dbl_to_int(fv.get<std::vector<double> >(sdTag1, "GroupingZOut"));
1219  php.slopeMin_ = fv.get<std::vector<double> >(sdTag4, "Slope");
1220  if (php.slopeMin_.empty())
1221  php.slopeMin_.emplace_back(0);
1222 
1223  // Wafer size
1224  const auto& dummy = fv.get<std::vector<double> >(sdTag2, "WaferSize");
1226 
1227  // Cell size
1228  php.cellSize_ = fv.get<std::vector<double> >(sdTag3, "CellSize");
1230 
1231  // Layer Offset
1232  const auto& dummy2 = fv.get<std::vector<double> >(sdTag1, "LayerOffset");
1233  if (!dummy2.empty()) {
1234  php.layerOffset_ = dummy2[0];
1235  } else {
1236  php.layerOffset_ = 0;
1237  }
1238 
1239  loadSpecParsHexagon(php);
1240 }
1241 
1243 #ifdef EDM_ML_DEBUG
1244  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: wafer radius ranges"
1245  << " for cell grouping " << php.boundR_[0] << ":" << php.boundR_[1] << ":"
1246  << php.boundR_[2] << ":" << php.boundR_[3];
1247  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Minimum/maximum R " << php.rLimit_[0] << ":" << php.rLimit_[1];
1248  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: LevelTop " << php.levelT_[0];
1249  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: minimum slope " << php.slopeMin_[0] << " and layer groupings "
1250  << "for the 3 ranges:";
1251  for (unsigned int k = 0; k < php.layerGroup_.size(); ++k)
1252  edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << php.layerGroup_[k] << ":" << php.layerGroupM_[k] << ":"
1253  << php.layerGroupO_[k];
1254  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Wafer Size: " << waferSize_;
1255  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: " << php.cellSize_.size() << " cells of sizes:";
1256  for (unsigned int k = 0; k < php.cellSize_.size(); ++k)
1257  edm::LogVerbatim("HGCalGeom") << " [" << k << "] " << php.cellSize_[k];
1258  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: First Layer " << php.firstLayer_ << " and layer offset "
1259  << php.layerOffset_;
1260 #endif
1261 }
1262 
1265  php.cellThickness_ = getDDDArray("CellThickness", sv, 3);
1268  php.waferThickness_ = getDDDArray("WaferThickness", sv, 3);
1270  } else {
1271  for (unsigned int k = 0; k < php.cellThickness_.size(); ++k)
1272  php.waferThickness_.emplace_back(php.waferThick_);
1273  }
1274 
1275  php.radius100to200_ = getDDDArray("Radius100to200", sv, 5);
1276  php.radius200to300_ = getDDDArray("Radius200to300", sv, 5);
1277 
1278  const auto& dummy = getDDDArray("RadiusCuts", sv, 4);
1279  php.choiceType_ = static_cast<int>(dummy[0]);
1280  php.nCornerCut_ = static_cast<int>(dummy[1]);
1281  php.fracAreaMin_ = dummy[2];
1283 
1284  php.radiusMixBoundary_ = fv.vector("RadiusMixBoundary");
1286 
1287  php.slopeMin_ = getDDDArray("SlopeBottom", sv, 0);
1288  php.zFrontMin_ = getDDDArray("ZFrontBottom", sv, 0);
1290  php.rMinFront_ = getDDDArray("RMinFront", sv, 0);
1292 
1293  php.slopeTop_ = getDDDArray("SlopeTop", sv, 0);
1294  php.zFrontTop_ = getDDDArray("ZFrontTop", sv, 0);
1296  php.rMaxFront_ = getDDDArray("RMaxFront", sv, 0);
1298 
1299  php.zRanges_ = fv.vector("ZRanges");
1301 
1302  const auto& dummy2 = getDDDArray("LayerOffset", sv, 1);
1303  php.layerOffset_ = dummy2[0];
1304  php.layerCenter_ = dbl_to_int(fv.vector("LayerCenter"));
1305 
1306  loadSpecParsHexagon8(php);
1307 
1308  // Read in parameters from Philip's file
1309  if (php.waferMaskMode_ > 1) {
1310  std::vector<int> layerType, waferIndex, waferProperties;
1311  std::vector<double> cassetteShift;
1312  if (php.waferMaskMode_ == siliconFileEE) {
1313  waferIndex = dbl_to_int(fv.vector("WaferIndexEE"));
1314  waferProperties = dbl_to_int(fv.vector("WaferPropertiesEE"));
1315  } else if (php.waferMaskMode_ == siliconCassetteEE) {
1316  waferIndex = dbl_to_int(fv.vector("WaferIndexEE"));
1317  waferProperties = dbl_to_int(fv.vector("WaferPropertiesEE"));
1318  cassetteShift = fv.vector("CassetteShiftEE");
1319  } else if (php.waferMaskMode_ == siliconFileHE) {
1320  waferIndex = dbl_to_int(fv.vector("WaferIndexHE"));
1321  waferProperties = dbl_to_int(fv.vector("WaferPropertiesHE"));
1322  } else if (php.waferMaskMode_ == siliconCassetteHE) {
1323  waferIndex = dbl_to_int(fv.vector("WaferIndexHE"));
1324  waferProperties = dbl_to_int(fv.vector("WaferPropertiesHE"));
1325  cassetteShift = fv.vector("CassetteShiftHE");
1326  }
1328  if ((php.waferMaskMode_ == siliconFileEE) || (php.waferMaskMode_ == siliconCassetteEE)) {
1329  layerType = dbl_to_int(fv.vector("LayerTypesEE"));
1330  } else if ((php.waferMaskMode_ == siliconFileHE) || (php.waferMaskMode_ == siliconCassetteHE)) {
1331  layerType = dbl_to_int(fv.vector("LayerTypesHE"));
1332  }
1333  }
1334 
1335  php.cassetteShift_ = cassetteShift;
1337  loadSpecParsHexagon8(php, layerType, waferIndex, waferProperties);
1338  }
1339 }
1340 
1342  const cms::DDVectorsMap& vmap,
1343  HGCalParameters& php,
1344  const std::string& sdTag1) {
1345  php.cellThickness_ = fv.get<std::vector<double> >(sdTag1, "CellThickness");
1348  php.waferThickness_ = fv.get<std::vector<double> >(sdTag1, "WaferThickness");
1350  } else {
1351  for (unsigned int k = 0; k < php.cellThickness_.size(); ++k)
1352  php.waferThickness_.emplace_back(php.waferThick_);
1353  }
1354 
1355  php.radius100to200_ = fv.get<std::vector<double> >(sdTag1, "Radius100to200");
1356  php.radius200to300_ = fv.get<std::vector<double> >(sdTag1, "Radius200to300");
1357 
1358  const auto& dummy = fv.get<std::vector<double> >(sdTag1, "RadiusCuts");
1359  if (dummy.size() > 3) {
1360  php.choiceType_ = static_cast<int>(dummy[0]);
1361  php.nCornerCut_ = static_cast<int>(dummy[1]);
1362  php.fracAreaMin_ = dummy[2];
1364  } else {
1365  php.choiceType_ = php.nCornerCut_ = php.fracAreaMin_ = php.zMinForRad_ = 0;
1366  }
1367 
1368  php.slopeMin_ = fv.get<std::vector<double> >(sdTag1, "SlopeBottom");
1369  php.zFrontMin_ = fv.get<std::vector<double> >(sdTag1, "ZFrontBottom");
1371  php.rMinFront_ = fv.get<std::vector<double> >(sdTag1, "RMinFront");
1373 
1374  php.slopeTop_ = fv.get<std::vector<double> >(sdTag1, "SlopeTop");
1375  php.zFrontTop_ = fv.get<std::vector<double> >(sdTag1, "ZFrontTop");
1377  php.rMaxFront_ = fv.get<std::vector<double> >(sdTag1, "RMaxFront");
1379  unsigned int kmax = (php.zFrontTop_.size() - php.slopeTop_.size());
1380  for (unsigned int k = 0; k < kmax; ++k)
1381  php.slopeTop_.emplace_back(0);
1382 
1383  const auto& dummy2 = fv.get<std::vector<double> >(sdTag1, "LayerOffset");
1384  if (!dummy2.empty()) {
1385  php.layerOffset_ = dummy2[0];
1386  } else {
1387  php.layerOffset_ = 0;
1388  }
1389 
1390  for (auto const& it : vmap) {
1391  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "RadiusMixBoundary")) {
1392  for (const auto& i : it.second)
1394  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "ZRanges")) {
1395  for (const auto& i : it.second)
1396  php.zRanges_.emplace_back(HGCalParameters::k_ScaleFromDD4hep * i);
1397  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "LayerCenter")) {
1398  for (const auto& i : it.second)
1399  php.layerCenter_.emplace_back(std::round(i));
1400  }
1401  }
1402 
1403  loadSpecParsHexagon8(php);
1404 
1405  // Read in parameters from Philip's file
1406  if (php.waferMaskMode_ > 1) {
1407  std::vector<int> layerType, waferIndex, waferProperties;
1408  std::vector<double> cassetteShift;
1409  if ((php.waferMaskMode_ == siliconFileEE) || (php.waferMaskMode_ == siliconCassetteEE)) {
1410  for (auto const& it : vmap) {
1411  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "WaferIndexEE")) {
1412  for (const auto& i : it.second)
1413  waferIndex.emplace_back(std::round(i));
1414  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "WaferPropertiesEE")) {
1415  for (const auto& i : it.second)
1416  waferProperties.emplace_back(std::round(i));
1417  }
1418  }
1419  if (php.waferMaskMode_ == siliconCassetteEE) {
1420  for (auto const& it : vmap) {
1421  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "CassetteShiftEE")) {
1422  for (const auto& i : it.second)
1423  cassetteShift.emplace_back(i);
1424  }
1425  }
1426  }
1427  } else if ((php.waferMaskMode_ == siliconFileHE) || (php.waferMaskMode_ == siliconCassetteHE)) {
1428  for (auto const& it : vmap) {
1429  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "WaferIndexHE")) {
1430  for (const auto& i : it.second)
1431  waferIndex.emplace_back(std::round(i));
1432  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "WaferPropertiesHE")) {
1433  for (const auto& i : it.second)
1434  waferProperties.emplace_back(std::round(i));
1435  }
1436  }
1437  if (php.waferMaskMode_ == siliconCassetteHE) {
1438  for (auto const& it : vmap) {
1439  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "CassetteShiftHE")) {
1440  for (const auto& i : it.second)
1441  cassetteShift.emplace_back(i);
1442  }
1443  }
1444  }
1445  }
1447  if ((php.waferMaskMode_ == siliconFileEE) || (php.waferMaskMode_ == siliconFileHE)) {
1448  for (auto const& it : vmap) {
1449  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "LayerTypesEE")) {
1450  for (const auto& i : it.second)
1451  layerType.emplace_back(std::round(i));
1452  }
1453  }
1454  } else if (php.waferMaskMode_ == siliconFileHE) {
1455  for (auto const& it : vmap) {
1456  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "LayerTypesHE")) {
1457  for (const auto& i : it.second)
1458  layerType.emplace_back(std::round(i));
1459  }
1460  }
1461  }
1462  }
1463 
1464  php.cassetteShift_ = cassetteShift;
1466  loadSpecParsHexagon8(php, layerType, waferIndex, waferProperties);
1467  }
1468 }
1469 
1471 #ifdef EDM_ML_DEBUG
1472  for (unsigned int k = 0; k < php.waferThickness_.size(); ++k)
1473  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: wafer[" << k << "] Thickness " << php.waferThickness_[k];
1474  for (unsigned int k = 0; k < php.cellThickness_.size(); ++k)
1475  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: cell[" << k << "] Thickness " << php.cellThickness_[k];
1476  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Polynomial "
1477  << "parameters for 120 to 200 micron "
1478  << "transition with" << php.radius100to200_.size() << " elements";
1479  for (unsigned int k = 0; k < php.radius100to200_.size(); ++k)
1480  edm::LogVerbatim("HGCalGeom") << "Element [" << k << "] " << php.radius100to200_[k];
1481  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Polynomial "
1482  << "parameters for 200 to 300 micron "
1483  << "transition with " << php.radius200to300_.size() << " elements";
1484  for (unsigned int k = 0; k < php.radius200to300_.size(); ++k)
1485  edm::LogVerbatim("HGCalGeom") << "Element [" << k << "] " << php.radius200to300_[k];
1486  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Parameters for the"
1487  << " transition " << php.choiceType_ << ":" << php.nCornerCut_ << ":"
1488  << php.fracAreaMin_ << ":" << php.zMinForRad_;
1489  for (unsigned int k = 0; k < php.radiusMixBoundary_.size(); ++k)
1490  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: Mix[" << k << "] R = " << php.radiusMixBoundary_[k];
1491  for (unsigned int k = 0; k < php.zFrontMin_.size(); ++k)
1492  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: Boundary[" << k << "] Bottom Z = " << php.zFrontMin_[k]
1493  << " Slope = " << php.slopeMin_[k] << " rMax = " << php.rMinFront_[k];
1494  for (unsigned int k = 0; k < php.zFrontTop_.size(); ++k)
1495  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: Boundary[" << k << "] Top Z = " << php.zFrontTop_[k]
1496  << " Slope = " << php.slopeTop_[k] << " rMax = " << php.rMaxFront_[k];
1497  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: Z-Boundary " << php.zRanges_[0] << ":" << php.zRanges_[1] << ":"
1498  << php.zRanges_[2] << ":" << php.zRanges_[3];
1499  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: LayerOffset " << php.layerOffset_ << " in array of size "
1500  << php.layerCenter_.size();
1501  for (unsigned int k = 0; k < php.layerCenter_.size(); ++k)
1502  edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << php.layerCenter_[k];
1503 #endif
1504 }
1505 
1507  const std::vector<int>& layerType,
1508  const std::vector<int>& waferIndex,
1509  const std::vector<int>& waferProperties) {
1510  // Store parameters from Philip's file
1511  for (unsigned int k = 0; k < layerType.size(); ++k) {
1512  php.layerType_.emplace_back(HGCalTypes::layerType(layerType[k]));
1513 #ifdef EDM_ML_DEBUG
1514  edm::LogVerbatim("HGCalGeom") << "Layer[" << k << "] Type " << layerType[k] << ":" << php.layerType_[k];
1515 #endif
1516  }
1517  for (unsigned int k = 0; k < php.layerType_.size(); ++k) {
1518  double cth = (php.layerType_[k] == HGCalTypes::WaferCenterR) ? cos(php.layerRotation_) : 1.0;
1519  double sth = (php.layerType_[k] == HGCalTypes::WaferCenterR) ? sin(php.layerRotation_) : 0.0;
1520  php.layerRotV_.emplace_back(std::make_pair(cth, sth));
1521 #ifdef EDM_ML_DEBUG
1522  edm::LogVerbatim("HGCalGeom") << "Layer[" << k << "] Type " << php.layerType_[k] << " cos|sin(Theta) "
1523  << php.layerRotV_[k].first << ":" << php.layerRotV_[k].second;
1524 #endif
1525  }
1526  for (unsigned int k = 0; k < waferIndex.size(); ++k) {
1527  int partial = HGCalProperty::waferPartial(waferProperties[k]);
1528  int orient =
1530  ? HGCalProperty::waferOrient(waferProperties[k])
1531  : HGCalWaferMask::getRotation(php.waferZSide_, partial, HGCalProperty::waferOrient(waferProperties[k]));
1533  partial,
1534  orient,
1535  HGCalProperty::waferCassette(waferProperties[k]));
1536 #ifdef EDM_ML_DEBUG
1537  edm::LogVerbatim("HGCalGeom") << "[" << k << ":" << waferIndex[k] << ":"
1540  << HGCalWaferIndex::waferV(waferIndex[k]) << "] Thickness type "
1541  << HGCalProperty::waferThick(waferProperties[k]) << " Partial type " << partial
1542  << " Orientation " << HGCalProperty::waferOrient(waferProperties[k]) << ":" << orient;
1543 #endif
1544  }
1545 }
1546 
1549  php.radiusMixBoundary_ = fv.vector("RadiusMixBoundary");
1551 
1552  php.nPhiBinBH_ = dbl_to_int(getDDDArray("NPhiBinBH", sv, 0));
1553  php.layerFrontBH_ = dbl_to_int(getDDDArray("LayerFrontBH", sv, 0));
1554  php.rMinLayerBH_ = getDDDArray("RMinLayerBH", sv, 0);
1556  php.nCellsFine_ = php.nPhiBinBH_[0];
1557  php.nCellsCoarse_ = php.nPhiBinBH_[1];
1558  php.cellSize_.emplace_back(2.0 * M_PI / php.nCellsFine_);
1559  php.cellSize_.emplace_back(2.0 * M_PI / php.nCellsCoarse_);
1560 
1561  php.slopeMin_ = getDDDArray("SlopeBottom", sv, 0);
1562  php.zFrontMin_ = getDDDArray("ZFrontBottom", sv, 0);
1564  php.rMinFront_ = getDDDArray("RMinFront", sv, 0);
1566 
1567  php.slopeTop_ = getDDDArray("SlopeTop", sv, 0);
1568  php.zFrontTop_ = getDDDArray("ZFrontTop", sv, 0);
1570  php.rMaxFront_ = getDDDArray("RMaxFront", sv, 0);
1572 
1573  php.zRanges_ = fv.vector("ZRanges");
1575 
1576  // Offsets
1577  const auto& dummy2 = getDDDArray("LayerOffset", sv, 1);
1578  php.layerOffset_ = dummy2[0];
1579  php.layerCenter_ = dbl_to_int(fv.vector("LayerCenter"));
1580 
1581  loadSpecParsTrapezoid(php);
1582 
1583  // tile parameters from Katja's file
1585  std::vector<int> tileIndx, tileProperty;
1586  std::vector<int> tileHEX1, tileHEX2, tileHEX3, tileHEX4;
1587  std::vector<double> tileRMin, tileRMax;
1588  std::vector<int> tileRingMin, tileRingMax;
1589  std::vector<double> cassetteShift;
1590  tileIndx = dbl_to_int(fv.vector("TileIndex"));
1591  tileProperty = dbl_to_int(fv.vector("TileProperty"));
1592  tileHEX1 = dbl_to_int(fv.vector("TileHEX1"));
1593  tileHEX2 = dbl_to_int(fv.vector("TileHEX2"));
1594  tileHEX3 = dbl_to_int(fv.vector("TileHEX3"));
1595  tileHEX4 = dbl_to_int(fv.vector("TileHEX4"));
1596  tileRMin = fv.vector("TileRMin");
1597  tileRMax = fv.vector("TileRMax");
1600  tileRingMin = dbl_to_int(fv.vector("TileRingMin"));
1601  tileRingMax = dbl_to_int(fv.vector("TileRingMax"));
1602  if (php.waferMaskMode_ == scintillatorCassette) {
1603  if (php.cassettes_ > 0)
1604  php.nphiCassette_ = php.nCellsCoarse_ / php.cassettes_;
1605  cassetteShift = fv.vector("CassetteShiftHE");
1606  rescale(cassetteShift, HGCalParameters::k_ScaleFromDDD);
1607  }
1608 
1609  php.cassetteShift_ = cassetteShift;
1611  tileIndx,
1612  tileProperty,
1613  tileHEX1,
1614  tileHEX2,
1615  tileHEX3,
1616  tileHEX4,
1617  tileRMin,
1618  tileRMax,
1619  tileRingMin,
1620  tileRingMax);
1621  }
1622 }
1623 
1625  const cms::DDVectorsMap& vmap,
1626  HGCalParameters& php,
1627  const std::string& sdTag1) {
1628  for (auto const& it : vmap) {
1629  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "RadiusMixBoundary")) {
1630  for (const auto& i : it.second)
1632  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "ZRanges")) {
1633  for (const auto& i : it.second)
1634  php.zRanges_.emplace_back(HGCalParameters::k_ScaleFromDD4hep * i);
1635  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "LayerCenter")) {
1636  for (const auto& i : it.second)
1637  php.layerCenter_.emplace_back(std::round(i));
1638  }
1639  }
1640 
1641  php.nPhiBinBH_ = dbl_to_int(fv.get<std::vector<double> >(sdTag1, "NPhiBinBH"));
1642  php.layerFrontBH_ = dbl_to_int(fv.get<std::vector<double> >(sdTag1, "LayerFrontBH"));
1643  php.rMinLayerBH_ = fv.get<std::vector<double> >(sdTag1, "RMinLayerBH");
1645  php.nCellsFine_ = php.nPhiBinBH_[0];
1646  php.nCellsCoarse_ = php.nPhiBinBH_[1];
1647  php.cellSize_.emplace_back(2.0 * M_PI / php.nCellsFine_);
1648  php.cellSize_.emplace_back(2.0 * M_PI / php.nCellsCoarse_);
1649 
1650  php.slopeMin_ = fv.get<std::vector<double> >(sdTag1, "SlopeBottom");
1651  php.zFrontMin_ = fv.get<std::vector<double> >(sdTag1, "ZFrontBottom");
1653  php.rMinFront_ = fv.get<std::vector<double> >(sdTag1, "RMinFront");
1655 
1656  php.slopeTop_ = fv.get<std::vector<double> >(sdTag1, "SlopeTop");
1657  php.zFrontTop_ = fv.get<std::vector<double> >(sdTag1, "ZFrontTop");
1659  php.rMaxFront_ = fv.get<std::vector<double> >(sdTag1, "RMaxFront");
1661  unsigned int kmax = (php.zFrontTop_.size() - php.slopeTop_.size());
1662  for (unsigned int k = 0; k < kmax; ++k)
1663  php.slopeTop_.emplace_back(0);
1664 
1665  const auto& dummy2 = fv.get<std::vector<double> >(sdTag1, "LayerOffset");
1666  php.layerOffset_ = dummy2[0];
1667 
1668  loadSpecParsTrapezoid(php);
1669 
1670  // tile parameters from Katja's file
1672  std::vector<int> tileIndx, tileProperty;
1673  std::vector<int> tileHEX1, tileHEX2, tileHEX3, tileHEX4;
1674  std::vector<double> tileRMin, tileRMax;
1675  std::vector<int> tileRingMin, tileRingMax;
1676  std::vector<double> cassetteShift;
1677  for (auto const& it : vmap) {
1678  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileIndex")) {
1679  for (const auto& i : it.second)
1680  tileIndx.emplace_back(std::round(i));
1681  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileProperty")) {
1682  for (const auto& i : it.second)
1683  tileProperty.emplace_back(std::round(i));
1684  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileHEX1")) {
1685  for (const auto& i : it.second)
1686  tileHEX1.emplace_back(std::round(i));
1687  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileHEX2")) {
1688  for (const auto& i : it.second)
1689  tileHEX2.emplace_back(std::round(i));
1690  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileHEX3")) {
1691  for (const auto& i : it.second)
1692  tileHEX3.emplace_back(std::round(i));
1693  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileHEX4")) {
1694  for (const auto& i : it.second)
1695  tileHEX4.emplace_back(std::round(i));
1696  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileRMin")) {
1697  for (const auto& i : it.second)
1698  tileRMin.emplace_back(HGCalParameters::k_ScaleFromDD4hep * i);
1699  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileRMax")) {
1700  for (const auto& i : it.second)
1701  tileRMax.emplace_back(HGCalParameters::k_ScaleFromDD4hep * i);
1702  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileRingMin")) {
1703  for (const auto& i : it.second)
1704  tileRingMin.emplace_back(std::round(i));
1705  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "TileRingMax")) {
1706  for (const auto& i : it.second)
1707  tileRingMax.emplace_back(std::round(i));
1708  }
1709  }
1710  if (php.waferMaskMode_ == scintillatorCassette) {
1711  for (auto const& it : vmap) {
1712  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "CassetteShiftHE")) {
1713  for (const auto& i : it.second)
1714  cassetteShift.emplace_back(i);
1715  }
1716  }
1717  }
1718 
1720  php.cassetteShift_ = cassetteShift;
1722  tileIndx,
1723  tileProperty,
1724  tileHEX1,
1725  tileHEX2,
1726  tileHEX3,
1727  tileHEX4,
1728  tileRMin,
1729  tileRMax,
1730  tileRingMin,
1731  tileRingMax);
1732  }
1733 }
1734 
1736 #ifdef EDM_ML_DEBUG
1737  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters:nCells " << php.nCellsFine_ << ":" << php.nCellsCoarse_
1738  << " cellSize: " << php.cellSize_[0] << ":" << php.cellSize_[1];
1739  for (unsigned int k = 0; k < php.layerFrontBH_.size(); ++k)
1740  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Type[" << k << "] Front Layer = " << php.layerFrontBH_[k]
1741  << " rMin = " << php.rMinLayerBH_[k];
1742  for (unsigned int k = 0; k < php.radiusMixBoundary_.size(); ++k) {
1743  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Mix[" << k << "] R = " << php.radiusMixBoundary_[k]
1744  << " Nphi = " << php.scintCells(k + php.firstLayer_)
1745  << " dPhi = " << php.scintCellSize(k + php.firstLayer_);
1746  }
1747 
1748  for (unsigned int k = 0; k < php.zFrontMin_.size(); ++k)
1749  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: Boundary[" << k << "] Bottom Z = " << php.zFrontMin_[k]
1750  << " Slope = " << php.slopeMin_[k] << " rMax = " << php.rMinFront_[k];
1751 
1752  for (unsigned int k = 0; k < php.zFrontTop_.size(); ++k)
1753  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: Boundary[" << k << "] Top Z = " << php.zFrontTop_[k]
1754  << " Slope = " << php.slopeTop_[k] << " rMax = " << php.rMaxFront_[k];
1755 
1756  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: Z-Boundary " << php.zRanges_[0] << ":" << php.zRanges_[1] << ":"
1757  << php.zRanges_[2] << ":" << php.zRanges_[3];
1758 
1759  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: LayerOffset " << php.layerOffset_ << " in array of size "
1760  << php.layerCenter_.size();
1761  for (unsigned int k = 0; k < php.layerCenter_.size(); ++k)
1762  edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << php.layerCenter_[k];
1763 #endif
1764 }
1765 
1767  const std::vector<int>& tileIndx,
1768  const std::vector<int>& tileProperty,
1769  const std::vector<int>& tileHEX1,
1770  const std::vector<int>& tileHEX2,
1771  const std::vector<int>& tileHEX3,
1772  const std::vector<int>& tileHEX4,
1773  const std::vector<double>& tileRMin,
1774  const std::vector<double>& tileRMax,
1775  const std::vector<int>& tileRingMin,
1776  const std::vector<int>& tileRingMax) {
1777  // tile parameters from Katja's file
1778  for (unsigned int k = 0; k < tileIndx.size(); ++k) {
1781  tileHEX1[k],
1782  tileHEX2[k],
1783  tileHEX3[k],
1784  tileHEX4[k]);
1785 #ifdef EDM_ML_DEBUG
1786  edm::LogVerbatim("HGCalGeom") << "Tile[" << k << ":" << tileIndx[k] << "] "
1787  << " Type " << HGCalProperty::tileType(tileProperty[k]) << " SiPM "
1788  << HGCalProperty::tileSiPM(tileProperty[k]) << " HEX " << std::hex << tileHEX1[k]
1789  << ":" << tileHEX2[k] << ":" << tileHEX3[k] << ":" << tileHEX4[k] << std::dec;
1790 #endif
1791  }
1792 
1793  for (unsigned int k = 0; k < tileRMin.size(); ++k) {
1794  php.tileRingR_.emplace_back(tileRMin[k], tileRMax[k]);
1795 #ifdef EDM_ML_DEBUG
1796  edm::LogVerbatim("HGCalGeom") << "TileRingR[" << k << "] " << tileRMin[k] << ":" << tileRMax[k];
1797 #endif
1798  }
1799 
1800  for (unsigned k = 0; k < tileRingMin.size(); ++k) {
1801  php.tileRingRange_.emplace_back(tileRingMin[k], tileRingMax[k]);
1802 #ifdef EDM_ML_DEBUG
1803  edm::LogVerbatim("HGCalGeom") << "TileRingRange[" << k << "] " << tileRingMin[k] << ":" << tileRingMax[k];
1804 #endif
1805  }
1806 }
1807 
1810  double rin(php.rLimit_[0]), rout(php.rLimit_[1]), rMaxFine(php.boundR_[1]);
1811 #ifdef EDM_ML_DEBUG
1812  edm::LogVerbatim("HGCalGeom") << "Input waferWidth " << waferW << ":" << rmin << " R Limits: " << rin << ":" << rout
1813  << " Fine " << rMaxFine;
1814 #endif
1815  // Clear the vectors
1816  php.waferCopy_.clear();
1817  php.waferTypeL_.clear();
1818  php.waferTypeT_.clear();
1819  php.waferPosX_.clear();
1820  php.waferPosY_.clear();
1821  double dx = 0.5 * waferW;
1822  double dy = 3.0 * dx * tan(30._deg);
1823  double rr = 2.0 * dx * tan(30._deg);
1824  int ncol = static_cast<int>(2.0 * rout / waferW) + 1;
1825  int nrow = static_cast<int>(rout / (waferW * tan(30._deg))) + 1;
1826  int ns2 = (2 * ncol + 1) * (2 * nrow + 1) * php.layer_.size();
1827  int incm(0), inrm(0), kount(0), ntot(0);
1828  HGCalParameters::layer_map copiesInLayers(php.layer_.size() + 1);
1829  HGCalParameters::waferT_map waferTypes(ns2 + 1);
1830 #ifdef EDM_ML_DEBUG
1831  edm::LogVerbatim("HGCalGeom") << "Row " << nrow << " Column " << ncol;
1832 #endif
1833  for (int nr = -nrow; nr <= nrow; ++nr) {
1834  int inr = (nr >= 0) ? nr : -nr;
1835  for (int nc = -ncol; nc <= ncol; ++nc) {
1836  int inc = (nc >= 0) ? nc : -nc;
1837  if (inr % 2 == inc % 2) {
1838  double xpos = nc * dx;
1839  double ypos = nr * dy;
1840  std::pair<int, int> corner = HGCalGeomTools::waferCorner(xpos, ypos, dx, rr, rin, rout, true);
1841  double rpos = std::sqrt(xpos * xpos + ypos * ypos);
1842  int typet = (rpos < rMaxFine) ? 1 : 2;
1843  int typel(3);
1844  for (int k = 1; k < 4; ++k) {
1845  if ((rpos + rmin) <= php.boundR_[k]) {
1846  typel = k;
1847  break;
1848  }
1849  }
1850  ++ntot;
1851  if (corner.first > 0) {
1852  int copy = HGCalTypes::packTypeUV(typel, nc, nr);
1853  if (inc > incm)
1854  incm = inc;
1855  if (inr > inrm)
1856  inrm = inr;
1857  kount++;
1858 #ifdef EDM_ML_DEBUG
1859  edm::LogVerbatim("HGCalGeom") << kount << ":" << ntot << " Copy " << copy << " Type " << typel << ":" << typet
1860  << " Location " << corner.first << " Position " << xpos << ":" << ypos
1861  << " Layers " << php.layer_.size();
1862 #endif
1863  php.waferCopy_.emplace_back(copy);
1864  php.waferTypeL_.emplace_back(typel);
1865  php.waferTypeT_.emplace_back(typet);
1866  php.waferPosX_.emplace_back(xpos);
1867  php.waferPosY_.emplace_back(ypos);
1868  for (unsigned int il = 0; il < php.layer_.size(); ++il) {
1869  std::pair<int, int> corner =
1870  HGCalGeomTools::waferCorner(xpos, ypos, dx, rr, php.rMinLayHex_[il], php.rMaxLayHex_[il], true);
1871  if (corner.first > 0) {
1872  auto cpy = copiesInLayers[php.layer_[il]].find(copy);
1873  if (cpy == copiesInLayers[php.layer_[il]].end())
1874  copiesInLayers[php.layer_[il]][copy] =
1875  ((corner.first == static_cast<int>(HGCalParameters::k_CornerSize)) ? php.waferCopy_.size() : -1);
1876  }
1877  if ((corner.first > 0) && (corner.first < static_cast<int>(HGCalParameters::k_CornerSize))) {
1878  int wl = HGCalWaferIndex::waferIndex(php.layer_[il], copy, 0, true);
1879  waferTypes[wl] = corner;
1880  }
1881  }
1882  }
1883  }
1884  }
1885  }
1886  php.copiesInLayers_ = copiesInLayers;
1887  php.waferTypes_ = waferTypes;
1888  php.nSectors_ = static_cast<int>(php.waferCopy_.size());
1889  php.waferUVMax_ = 0;
1890 #ifdef EDM_ML_DEBUG
1891  edm::LogVerbatim("HGCalGeom") << "HGCalWaferHexagon: # of columns " << incm << " # of rows " << inrm << " and "
1892  << kount << ":" << ntot << " wafers; R " << rin << ":" << rout;
1893  edm::LogVerbatim("HGCalGeom") << "Dump copiesInLayers for " << php.copiesInLayers_.size() << " layers";
1894  for (unsigned int k = 0; k < copiesInLayers.size(); ++k) {
1895  const auto& theModules = copiesInLayers[k];
1896  edm::LogVerbatim("HGCalGeom") << "Layer " << k << ":" << theModules.size();
1897  int k2(0);
1898  for (std::unordered_map<int, int>::const_iterator itr = theModules.begin(); itr != theModules.end(); ++itr, ++k2) {
1899  edm::LogVerbatim("HGCalGeom") << "[" << k2 << "] " << itr->first << ":" << itr->second;
1900  }
1901  }
1902 #endif
1903 }
1904 
1906  double waferW(php.waferSize_);
1907  double waferS(php.sensorSeparation_);
1908  auto wType = std::make_unique<HGCalWaferType>(php.radius100to200_,
1909  php.radius200to300_,
1910  HGCalParameters::k_ScaleToDDD * (waferW + waferS),
1912  php.choiceType_,
1913  php.nCornerCut_,
1914  php.fracAreaMin_);
1915 
1916  double rout(php.rLimit_[1]);
1917 #ifdef EDM_ML_DEBUG
1918  edm::LogVerbatim("HGCalGeom") << "Input waferWidth " << waferW << ":" << waferS << " R Max: " << rout;
1919 #endif
1920  // Clear the vectors
1921  php.waferCopy_.clear();
1922  php.waferTypeL_.clear();
1923  php.waferTypeT_.clear();
1924  php.waferPosX_.clear();
1925  php.waferPosY_.clear();
1926  double r = 0.5 * (waferW + waferS);
1927  double R = 2.0 * r / sqrt3_;
1928  double dy = 0.75 * R;
1929  double r1 = 0.5 * waferW;
1930  double R1 = 2.0 * r1 / sqrt3_;
1931  int N = (r == 0) ? 3 : (static_cast<int>(0.5 * rout / r) + 3);
1932  int ns1 = (2 * N + 1) * (2 * N + 1);
1933  int ns2 = ns1 * php.zLayerHex_.size();
1934 #ifdef EDM_ML_DEBUG
1935  edm::LogVerbatim("HGCalGeom") << "wafer " << waferW << ":" << waferS << " r " << r << " dy " << dy << " N " << N
1936  << " sizes " << ns1 << ":" << ns2;
1937  std::vector<int> indtypes(ns1 + 1);
1938  indtypes.clear();
1939 #endif
1940  HGCalParameters::wafer_map wafersInLayers(ns1 + 1);
1941  HGCalParameters::wafer_map typesInLayers(ns2 + 1);
1942  HGCalParameters::waferT_map waferTypes(ns2 + 1);
1943  int ipos(0), lpos(0), uvmax(0), nwarn(0);
1944  std::vector<int> uvmx(php.zLayerHex_.size(), 0);
1945  for (int v = -N; v <= N; ++v) {
1946  for (int u = -N; u <= N; ++u) {
1947  int nr = 2 * v;
1948  int nc = -2 * u + v;
1949  double xpos = nc * r;
1950  double ypos = nr * dy;
1951  int indx = HGCalWaferIndex::waferIndex(0, u, v);
1952  php.waferCopy_.emplace_back(indx);
1953  php.waferPosX_.emplace_back(xpos);
1954  php.waferPosY_.emplace_back(ypos);
1955  wafersInLayers[indx] = ipos;
1956  ++ipos;
1957  std::pair<int, int> corner = HGCalGeomTools::waferCorner(xpos, ypos, r1, R1, 0, rout, false);
1958  if ((corner.first == static_cast<int>(HGCalParameters::k_CornerSize)) ||
1959  ((corner.first > 0) && php.defineFull_)) {
1960  uvmax = std::max(uvmax, std::max(std::abs(u), std::abs(v)));
1961  }
1962  for (unsigned int i = 0; i < php.zLayerHex_.size(); ++i) {
1963  int copy = i + php.layerOffset_;
1964  std::pair<double, double> xyoff = geomTools_.shiftXY(php.layerCenter_[copy], (waferW + waferS));
1965  int lay = php.layer_[php.layerIndex_[i]];
1966  double xpos0 = xpos + xyoff.first;
1967  double ypos0 = ypos + xyoff.second;
1968  double zpos = php.zLayerHex_[i];
1969  int kndx = HGCalWaferIndex::waferIndex(lay, u, v);
1970  int type(-1);
1973  type = wType->getType(kndx, php.waferInfoMap_);
1974  if (type < 0)
1975  type = wType->getType(HGCalParameters::k_ScaleToDDD * xpos0,
1978  php.waferTypeL_.emplace_back(type);
1979  typesInLayers[kndx] = lpos;
1980  ++lpos;
1981 #ifdef EDM_ML_DEBUG
1982  indtypes.emplace_back(kndx);
1983 #endif
1984  std::pair<int, int> corner =
1985  HGCalGeomTools::waferCorner(xpos0, ypos0, r1, R1, php.rMinLayHex_[i], php.rMaxLayHex_[i], false);
1986 #ifdef EDM_ML_DEBUG
1987  if (((corner.first == 0) && std::abs(u) < 5 && std::abs(v) < 5) || (std::abs(u) < 2 && std::abs(v) < 2)) {
1988  edm::LogVerbatim("HGCalGeom") << "Layer " << lay << " R " << php.rMinLayHex_[i] << ":" << php.rMaxLayHex_[i]
1989  << " u " << u << " v " << v << " with " << corner.first << " corners";
1990  }
1991 #endif
1992  if ((corner.first == static_cast<int>(HGCalParameters::k_CornerSize)) ||
1993  ((corner.first > 0) && php.defineFull_)) {
1994  uvmx[i] = std::max(uvmx[i], std::max(std::abs(u), std::abs(v)));
1995  }
1996  if ((corner.first < static_cast<int>(HGCalParameters::k_CornerSize)) && (corner.first > 0)) {
1997 #ifdef EDM_ML_DEBUG
1998  edm::LogVerbatim("HGCalGeom") << "Layer " << lay << " u|v " << u << ":" << v << " with corner "
1999  << corner.first << ":" << corner.second;
2000 #endif
2001  int wl = HGCalWaferIndex::waferIndex(lay, u, v);
2002  if (php.waferMaskMode_ > 0) {
2003  std::pair<int, int> corner0 = HGCalWaferMask::getTypeMode(
2004  xpos0, ypos0, r1, R1, php.rMinLayHex_[i], php.rMaxLayHex_[i], type, php.waferMaskMode_);
2007  auto itr = php.waferInfoMap_.find(wl);
2008  if (itr != php.waferInfoMap_.end()) {
2009  int part = (itr->second).part;
2010  int orient = (itr->second).orient;
2012  ? true
2014  xpos0, ypos0, r1, R1, php.rMinLayHex_[i], php.rMaxLayHex_[i], part, orient, false);
2015  if (ok)
2016  corner0 = std::make_pair(part, (HGCalTypes::k_OffsetRotation + orient));
2017 #ifdef EDM_ML_DEBUG
2018  edm::LogVerbatim("HGCalGeom")
2019  << "Layer:u:v " << i << ":" << lay << ":" << u << ":" << v << " Part " << corner0.first << ":"
2020  << part << " Orient " << corner0.second << ":" << orient << " Position " << xpos0 << ":" << ypos0
2021  << " delta " << r1 << ":" << R1 << " Limit " << php.rMinLayHex_[i] << ":" << php.rMaxLayHex_[i]
2022  << " Compatibiliety Flag " << ok;
2023 #endif
2024  if (!ok)
2025  ++nwarn;
2026  }
2027  }
2028  waferTypes[wl] = corner0;
2029 #ifdef EDM_ML_DEBUG
2030  edm::LogVerbatim("HGCalGeom")
2031  << "Layer " << lay << " u|v " << u << ":" << v << " Index " << std::hex << wl << std::dec << " pos "
2032  << xpos0 << ":" << ypos0 << " R " << r1 << ":" << R1 << " Range " << php.rMinLayHex_[i] << ":"
2033  << php.rMaxLayHex_[i] << type << ":" << php.waferMaskMode_ << " corner " << corner.first << ":"
2034  << corner.second << " croner0 " << corner0.first << ":" << corner0.second;
2035 #endif
2036  } else {
2037  waferTypes[wl] = corner;
2038 #ifdef EDM_ML_DEBUG
2039  edm::LogVerbatim("HGCalGeom") << "Layer " << lay << " u|v " << u << ":" << v << " with corner "
2040  << corner.first << ":" << corner.second;
2041 #endif
2042  }
2043  }
2044  }
2045  }
2046  }
2047  if (nwarn > 0)
2048  edm::LogWarning("HGCalGeom") << "HGCalGeomParameters::loadWafer8: there are " << nwarn
2049  << " wafers with non-matching partial- orientation types";
2050  php.waferUVMax_ = uvmax;
2051  php.waferUVMaxLayer_ = uvmx;
2052  php.wafersInLayers_ = wafersInLayers;
2053  php.typesInLayers_ = typesInLayers;
2054  php.waferTypes_ = waferTypes;
2055  php.nSectors_ = static_cast<int>(php.waferCopy_.size());
2057  mytr.lay = 1;
2058  mytr.bl = php.waferR_;
2059  mytr.tl = php.waferR_;
2060  mytr.h = php.waferR_;
2061  mytr.alpha = 0.0;
2063  for (auto const& dz : php.cellThickness_) {
2064  mytr.dz = 0.5 * HGCalParameters::k_ScaleToDDD * dz;
2065  php.fillModule(mytr, false);
2066  }
2067  for (unsigned k = 0; k < php.cellThickness_.size(); ++k) {
2068  HGCalParameters::hgtrap mytr = php.getModule(k, false);
2074  php.fillModule(mytr, true);
2075  }
2076 #ifdef EDM_ML_DEBUG
2077  edm::LogVerbatim("HGCalGeom") << "HGCalGeomParameters: Total of " << php.waferCopy_.size() << " wafers";
2078  for (unsigned int k = 0; k < php.waferCopy_.size(); ++k) {
2079  int id = php.waferCopy_[k];
2080  edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << std::hex << id << std::dec << ":"
2081  << HGCalWaferIndex::waferLayer(id) << ":" << HGCalWaferIndex::waferU(id) << ":"
2082  << HGCalWaferIndex::waferV(id) << " x " << php.waferPosX_[k] << " y "
2083  << php.waferPosY_[k] << " index " << php.wafersInLayers_[id];
2084  }
2085  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: Total of " << php.waferTypeL_.size() << " wafer types";
2086  for (unsigned int k = 0; k < php.waferTypeL_.size(); ++k) {
2087  int id = indtypes[k];
2088  edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << php.typesInLayers_[id] << ":" << php.waferTypeL_[k] << " ID "
2089  << std::hex << id << std::dec << ":" << HGCalWaferIndex::waferLayer(id) << ":"
2090  << HGCalWaferIndex::waferU(id) << ":" << HGCalWaferIndex::waferV(id);
2091  }
2092 #endif
2093 
2094  //Wafer offset
2095  php.xLayerHex_.clear();
2096  php.yLayerHex_.clear();
2097  double waferSize = php.waferSize_ + php.sensorSeparation_;
2098 #ifdef EDM_ML_DEBUG
2099  edm::LogVerbatim("HGCalGeom") << "WaferSize " << waferSize;
2100 #endif
2101  for (unsigned int k = 0; k < php.zLayerHex_.size(); ++k) {
2102  int copy = k + php.layerOffset_;
2103  std::pair<double, double> xyoff = geomTools_.shiftXY(php.layerCenter_[copy], waferSize);
2104  php.xLayerHex_.emplace_back(xyoff.first);
2105  php.yLayerHex_.emplace_back(xyoff.second);
2106 #ifdef EDM_ML_DEBUG
2107  edm::LogVerbatim("HGCalGeom") << "Layer[" << k << "] Off " << copy << ":" << php.layerCenter_[copy] << " Shift "
2108  << xyoff.first << ":" << xyoff.second;
2109 #endif
2110  }
2111 }
2112 
2114  // Special parameters for cell parameters
2115  std::string attribute = "OnlyForHGCalNumbering";
2116  DDSpecificsHasNamedValueFilter filter1{attribute};
2117  DDFilteredView fv1(*cpv, filter1);
2118  bool ok = fv1.firstChild();
2119 
2120  if (ok) {
2121  php.cellFine_ = dbl_to_int(cpv->vector("waferFine"));
2122  php.cellCoarse_ = dbl_to_int(cpv->vector("waferCoarse"));
2123  }
2124 
2125  loadCellParsHexagon(php);
2126 }
2127 
2129  for (auto const& it : vmap) {
2130  if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "waferFine")) {
2131  for (const auto& i : it.second)
2132  php.cellFine_.emplace_back(std::round(i));
2133  } else if (dd4hep::dd::compareEqual(dd4hep::dd::noNamespace(it.first), "waferCoarse")) {
2134  for (const auto& i : it.second)
2135  php.cellCoarse_.emplace_back(std::round(i));
2136  }
2137  }
2138 
2139  loadCellParsHexagon(php);
2140 }
2141 
2143 #ifdef EDM_ML_DEBUG
2144  edm::LogVerbatim("HGCalGeom") << "HGCalLoadCellPars: " << php.cellFine_.size() << " rows for fine cells";
2145  for (unsigned int k = 0; k < php.cellFine_.size(); ++k)
2146  edm::LogVerbatim("HGCalGeom") << "[" << k << "]: " << php.cellFine_[k];
2147  edm::LogVerbatim("HGCalGeom") << "HGCalLoadCellPars: " << php.cellCoarse_.size() << " rows for coarse cells";
2148  for (unsigned int k = 0; k < php.cellCoarse_.size(); ++k)
2149  edm::LogVerbatim("HGCalGeom") << "[" << k << "]: " << php.cellCoarse_[k];
2150 #endif
2151 }
2152 
2154  php.xLayerHex_.resize(php.zLayerHex_.size(), 0);
2155  php.yLayerHex_.resize(php.zLayerHex_.size(), 0);
2156 #ifdef EDM_ML_DEBUG
2157  edm::LogVerbatim("HGCalGeom") << "HGCalParameters: x|y|zLayerHex in array of size " << php.zLayerHex_.size();
2158  for (unsigned int k = 0; k < php.zLayerHex_.size(); ++k)
2159  edm::LogVerbatim("HGCalGeom") << "Layer[" << k << "] Shift " << php.xLayerHex_[k] << ":" << php.yLayerHex_[k] << ":"
2160  << php.zLayerHex_[k];
2161 #endif
2162  // Find the radius of each eta-partitions
2163 
2166  //Ring radii for each partition
2167  for (unsigned int k = 0; k < 2; ++k) {
2168  for (unsigned int kk = 0; kk < php.tileRingR_.size(); ++kk) {
2169  php.radiusLayer_[k].emplace_back(php.tileRingR_[kk].first);
2170 #ifdef EDM_ML_DEBUG
2171  double zv = ((k == 0) ? (php.zLayerHex_[php.layerFrontBH_[1] - php.firstLayer_])
2172  : (php.zLayerHex_[php.zLayerHex_.size() - 1]));
2173  double rv = php.radiusLayer_[k].back();
2174  double eta = -(std::log(std::tan(0.5 * std::atan(rv / zv))));
2175  edm::LogVerbatim("HGCalGeom") << "New [" << kk << "] new R = " << rv << " Eta = " << eta;
2176 #endif
2177  }
2178  php.radiusLayer_[k].emplace_back(php.tileRingR_[php.tileRingR_.size() - 1].second);
2179  }
2180  // Minimum and maximum radius index for each layer
2181  for (unsigned int k = 0; k < php.zLayerHex_.size(); ++k) {
2182  php.iradMinBH_.emplace_back(1 + php.tileRingRange_[k].first);
2183  php.iradMaxBH_.emplace_back(1 + php.tileRingRange_[k].second);
2184 #ifdef EDM_ML_DEBUG
2185  int kk = php.scintType(php.firstLayer_ + static_cast<int>(k));
2186  edm::LogVerbatim("HGCalGeom") << "New Layer " << k << " Type " << kk << " Low edge " << php.iradMinBH_.back()
2187  << " Top edge " << php.iradMaxBH_.back();
2188 #endif
2189  }
2190  } else {
2191  //Ring radii for each partition
2192  for (unsigned int k = 0; k < 2; ++k) {
2193  double rmax = ((k == 0) ? (php.rMaxLayHex_[php.layerFrontBH_[1] - php.firstLayer_] - 1)
2194  : (php.rMaxLayHex_[php.rMaxLayHex_.size() - 1]));
2195  double rv = php.rMinLayerBH_[k];
2196  double zv = ((k == 0) ? (php.zLayerHex_[php.layerFrontBH_[1] - php.firstLayer_])
2197  : (php.zLayerHex_[php.zLayerHex_.size() - 1]));
2198  php.radiusLayer_[k].emplace_back(rv);
2199 #ifdef EDM_ML_DEBUG
2200  double eta = -(std::log(std::tan(0.5 * std::atan(rv / zv))));
2201  edm::LogVerbatim("HGCalGeom") << "Old [" << k << "] rmax " << rmax << " Z = " << zv
2202  << " dEta = " << php.cellSize_[k] << "\nOld[0] new R = " << rv << " Eta = " << eta;
2203  int kount(1);
2204 #endif
2205  while (rv < rmax) {
2206  double eta = -(php.cellSize_[k] + std::log(std::tan(0.5 * std::atan(rv / zv))));
2207  rv = zv * std::tan(2.0 * std::atan(std::exp(-eta)));
2208  php.radiusLayer_[k].emplace_back(rv);
2209 #ifdef EDM_ML_DEBUG
2210  edm::LogVerbatim("HGCalGeom") << "Old [" << kount << "] new R = " << rv << " Eta = " << eta;
2211  ++kount;
2212 #endif
2213  }
2214  }
2215  // Find minimum and maximum radius index for each layer
2216  for (unsigned int k = 0; k < php.zLayerHex_.size(); ++k) {
2217  int kk = php.scintType(php.firstLayer_ + static_cast<int>(k));
2218  std::vector<double>::iterator low, high;
2219  low = std::lower_bound(php.radiusLayer_[kk].begin(), php.radiusLayer_[kk].end(), php.rMinLayHex_[k]);
2220 #ifdef EDM_ML_DEBUG
2221  edm::LogVerbatim("HGCalGeom") << "Old [" << k << "] RLow = " << php.rMinLayHex_[k] << " pos "
2222  << static_cast<int>(low - php.radiusLayer_[kk].begin());
2223 #endif
2224  if (low == php.radiusLayer_[kk].begin())
2225  ++low;
2226  int irlow = static_cast<int>(low - php.radiusLayer_[kk].begin());
2227  double drlow = php.radiusLayer_[kk][irlow] - php.rMinLayHex_[k];
2228 #ifdef EDM_ML_DEBUG
2229  edm::LogVerbatim("HGCalGeom") << "irlow " << irlow << " dr " << drlow << " min " << php.minTileSize_;
2230 #endif
2231  if (drlow < php.minTileSize_) {
2232  ++irlow;
2233 #ifdef EDM_ML_DEBUG
2234  drlow = php.radiusLayer_[kk][irlow] - php.rMinLayHex_[k];
2235  edm::LogVerbatim("HGCalGeom") << "Modified irlow " << irlow << " dr " << drlow;
2236 #endif
2237  }
2238  high = std::lower_bound(php.radiusLayer_[kk].begin(), php.radiusLayer_[kk].end(), php.rMaxLayHex_[k]);
2239 #ifdef EDM_ML_DEBUG
2240  edm::LogVerbatim("HGCalGeom") << "Old [" << k << "] RHigh = " << php.rMaxLayHex_[k] << " pos "
2241  << static_cast<int>(high - php.radiusLayer_[kk].begin());
2242 #endif
2243  if (high == php.radiusLayer_[kk].end())
2244  --high;
2245  int irhigh = static_cast<int>(high - php.radiusLayer_[kk].begin());
2246  double drhigh = php.rMaxLayHex_[k] - php.radiusLayer_[kk][irhigh - 1];
2247 #ifdef EDM_ML_DEBUG
2248  edm::LogVerbatim("HGCalGeom") << "irhigh " << irhigh << " dr " << drhigh << " min " << php.minTileSize_;
2249 #endif
2250  if (drhigh < php.minTileSize_) {
2251  --irhigh;
2252 #ifdef EDM_ML_DEBUG
2253  drhigh = php.rMaxLayHex_[k] - php.radiusLayer_[kk][irhigh - 1];
2254  edm::LogVerbatim("HGCalGeom") << "Modified irhigh " << irhigh << " dr " << drhigh;
2255 #endif
2256  }
2257  php.iradMinBH_.emplace_back(irlow);
2258  php.iradMaxBH_.emplace_back(irhigh);
2259 #ifdef EDM_ML_DEBUG
2260  edm::LogVerbatim("HGCalGeom") << "Old Layer " << k << " Type " << kk << " Low edge " << irlow << ":" << drlow
2261  << " Top edge " << irhigh << ":" << drhigh;
2262 #endif
2263  }
2264  }
2265 #ifdef EDM_ML_DEBUG
2266  for (unsigned int k = 0; k < 2; ++k) {
2267  edm::LogVerbatim("HGCalGeom") << "Type " << k << " with " << php.radiusLayer_[k].size() << " radii";
2268  for (unsigned int kk = 0; kk < php.radiusLayer_[k].size(); ++kk)
2269  edm::LogVerbatim("HGCalGeom") << "Ring[" << kk << "] " << php.radiusLayer_[k][kk];
2270  }
2271 #endif
2272 
2273  // Now define the volumes
2274  int im(0);
2275  php.waferUVMax_ = 0;
2277  mytr.alpha = 0.0;
2278  for (unsigned int k = 0; k < php.zLayerHex_.size(); ++k) {
2279  if (php.iradMaxBH_[k] > php.waferUVMax_)
2280  php.waferUVMax_ = php.iradMaxBH_[k];
2281  int kk = ((php.firstLayer_ + static_cast<int>(k)) < php.layerFrontBH_[1]) ? 0 : 1;
2282  int irm = php.radiusLayer_[kk].size() - 1;
2283 #ifdef EDM_ML_DEBUG
2284  double rmin = php.radiusLayer_[kk][std::max((php.iradMinBH_[k] - 1), 0)];
2285  double rmax = php.radiusLayer_[kk][std::min(php.iradMaxBH_[k], irm)];
2286  edm::LogVerbatim("HGCalGeom") << "Layer " << php.firstLayer_ + k << ":" << kk << " Radius range "
2287  << php.iradMinBH_[k] << ":" << php.iradMaxBH_[k] << ":" << rmin << ":" << rmax;
2288 #endif
2289  mytr.lay = php.firstLayer_ + k;
2290  for (int irad = php.iradMinBH_[k]; irad <= php.iradMaxBH_[k]; ++irad) {
2291  double rmin = php.radiusLayer_[kk][std::max((irad - 1), 0)];
2292  double rmax = php.radiusLayer_[kk][std::min(irad, irm)];
2293  mytr.bl = 0.5 * rmin * php.scintCellSize(mytr.lay);
2294  mytr.tl = 0.5 * rmax * php.scintCellSize(mytr.lay);
2295  mytr.h = 0.5 * (rmax - rmin);
2296  mytr.dz = 0.5 * php.waferThick_;
2297  mytr.cellSize = 0.5 * (rmax + rmin) * php.scintCellSize(mytr.lay);
2298  php.fillModule(mytr, true);
2304  php.fillModule(mytr, false);
2305  if (irad == php.iradMinBH_[k])
2306  php.firstModule_.emplace_back(im);
2307  ++im;
2308  if (irad == php.iradMaxBH_[k] - 1)
2309  php.lastModule_.emplace_back(im);
2310  }
2311  }
2312  php.nSectors_ = php.waferUVMax_;
2313 #ifdef EDM_ML_DEBUG
2314  edm::LogVerbatim("HGCalGeom") << "Maximum radius index " << php.waferUVMax_;
2315  for (unsigned int k = 0; k < php.firstModule_.size(); ++k)
2316  edm::LogVerbatim("HGCalGeom") << "Layer " << k + php.firstLayer_ << " Modules " << php.firstModule_[k] << ":"
2317  << php.lastModule_[k];
2318 #endif
2319 }
2320 
2321 std::vector<double> HGCalGeomParameters::getDDDArray(const std::string& str, const DDsvalues_type& sv, const int nmin) {
2322  DDValue value(str);
2323  if (DDfetch(&sv, value)) {
2324  const std::vector<double>& fvec = value.doubles();
2325  int nval = fvec.size();
2326  if (nmin > 0) {
2327  if (nval < nmin) {
2328  throw cms::Exception("DDException")
2329  << "HGCalGeomParameters: # of " << str << " bins " << nval << " < " << nmin << " ==> illegal";
2330  }
2331  } else {
2332  if (nval < 1 && nmin == 0) {
2333  throw cms::Exception("DDException")
2334  << "HGCalGeomParameters: # of " << str << " bins " << nval << " < 1 ==> illegal"
2335  << " (nmin=" << nmin << ")";
2336  }
2337  }
2338  return fvec;
2339  } else {
2340  if (nmin >= 0) {
2341  throw cms::Exception("DDException") << "HGCalGeomParameters: cannot get array " << str;
2342  }
2343  std::vector<double> fvec;
2344  return fvec;
2345  }
2346 }
2347 
2348 std::pair<double, double> HGCalGeomParameters::cellPosition(
2349  const std::vector<HGCalGeomParameters::cellParameters>& wafers,
2350  std::vector<HGCalGeomParameters::cellParameters>::const_iterator& itrf,
2351  int wafer,
2352  double xx,
2353  double yy) {
2354  if (itrf == wafers.end()) {
2355  for (std::vector<HGCalGeomParameters::cellParameters>::const_iterator itr = wafers.begin(); itr != wafers.end();
2356  ++itr) {
2357  if (itr->wafer == wafer) {
2358  itrf = itr;
2359  break;
2360  }
2361  }
2362  }
2363  double dx(0), dy(0);
2364  if (itrf != wafers.end()) {
2365  dx = (xx - itrf->xyz.x());
2366  if (std::abs(dx) < tolerance)
2367  dx = 0;
2368  dy = (yy - itrf->xyz.y());
2369  if (std::abs(dy) < tolerance)
2370  dy = 0;
2371  }
2372  return std::make_pair(dx, dy);
2373 }
2374 
2375 void HGCalGeomParameters::rescale(std::vector<double>& v, const double s) {
2376  std::for_each(v.begin(), v.end(), [s](double& n) { n *= s; });
2377 }
2378 
2379 void HGCalGeomParameters::resetZero(std::vector<double>& v) {
2380  for (auto& n : v) {
2381  if (std::abs(n) < tolmin)
2382  n = 0;
2383  }
2384 }
std::vector< int > iradMaxBH_
std::vector< double > waferPosY_
Log< level::Info, true > LogVerbatim
std::vector< int > layer_
static constexpr int scintillatorCassette
std::vector< double > moduleDzR_
std::vector< int > depthLayerF_
std::vector< int > depth_
std::vector< double > zFrontMin_
int32_t tileType(const int32_t property)
nav_type copyNumbers() const
return the stack of copy numbers
hgtrap getModule(unsigned int k, bool reco) const
std::vector< double > moduleHR_
std::vector< double > rMinVec(void) const
Definition: DDSolid.cc:335
layer_map copiesInLayers_
static constexpr int k_OffsetRotation
Definition: HGCalTypes.h:91
std::vector< double > const & vector(std::string_view iKey) const
The DDVector information.
std::vector< std::pair< double, double > > layerRotV_
std::vector< bool > cellCoarseHalf_
int scintType(const int layer) const
std::vector< bool > cellFineHalf_
const std::vector< int > copyNos() const
The list of the volume copy numbers.
const cms::DDSolidShape shape() const
std::vector< int > moduleLayR_
double rIn(void) const
Definition: DDSolid.cc:456
static constexpr int siliconFileEE
int32_t waferU(const int32_t index)
std::vector< int > cellFine_
void rescale(std::vector< double > &, const double s)
for(int i=first, nt=offsets[nh];i< nt;i+=gridDim.x *blockDim.x)
int32_t waferLayer(const int32_t index)
const double tolerance
static int32_t getUnpackedCell6(int id)
Definition: HGCalTypes.cc:40
std::vector< double > moduleHS_
std::string name(Mapping a, V value)
Definition: DDSolidShapes.h:31
std::vector< double > xVec(void) const
Definition: DDSolid.cc:378
std::vector< double > const & vector(std::string_view iKey) const
returns an empty container if not found
std::vector< double > zVec(void) const
Definition: DDSolid.cc:328
float *__restrict__ zv
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
std::vector< double > trformTranY_
void loadGeometryHexagonModule(const DDCompactView *cpv, HGCalParameters &php, const std::string &sdTag1, const std::string &sdTag2, int firstLayer)
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
std::vector< double > rMaxVec(void) const
Definition: DDSolid.cc:342
double rOut(void) const
Definition: DDSolid.cc:458
std::vector< double > cellFineY_
void loadSpecParsHexagon(const DDFilteredView &fv, HGCalParameters &php, const DDCompactView *cpv, const std::string &sdTag1, const std::string &sdTag2)
const std::string & name() const
The name of a logical-part of the current node in the filtered-view.
std::vector< double > trformRotZY_
int zside(DetId const &)
static int getRotation(int zside, int type, int rotn)
void resetZero(std::vector< double > &)
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
std::vector< int > layerGroupM_
Compact representation of the geometrical detector hierarchy.
Definition: DDCompactView.h:81
bool DDfetch(const DDsvalues_type *, DDValue &)
helper for retrieving DDValues from DDsvalues_type *.
Definition: DDsvalues.cc:79
HGCalGeometryMode::GeometryMode mode_
const std::string names[nVars_]
int32_t waferOrient(const int32_t property)
std::pair< double, double > shiftXY(int waferPosition, double waferSize) const
std::vector< double > trformRotXX_
std::vector< int > nPhiBinBH_
std::unordered_map< std::string, std::vector< double > > DDVectorsMap
Definition: DDNamespace.h:20
A DDSolid represents the shape of a part.
Definition: DDSolid.h:39
static constexpr double tol
void fillTrForm(const hgtrform &mytr)
void loadSpecParsHexagon8(const DDFilteredView &fv, HGCalParameters &php)
static constexpr uint32_t k_CornerSize
static bool goodTypeMode(double xpos, double ypos, double delX, double delY, double rin, double rout, int part, int rotn, bool debug=false)
std::vector< double > zVec(void) const
Definition: DDSolid.cc:387
wafer_map wafersInLayers_
static int32_t getUnpackedCellType6(int id)
Definition: HGCalTypes.cc:38
std::vector< double > rMinLayerBH_
constexpr std::array< uint8_t, layerIndexSize< TrackerTraits > > layer
ROOT::Math::DisplacementVector3D< ROOT::Math::Cartesian3D< double > > DD3Vector
std::vector< double > trformRotZX_
double scintCellSize(const int layer) const
std::string_view name() const
std::vector< double > cellCoarseX_
static constexpr int scintillatorFile
const double tolmin
int32_t waferCassette(const int32_t property)
std::vector< std::pair< int, int > > tileRingRange_
static constexpr int siliconCassetteHE
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_
std::vector< int > cellCoarse_
std::vector< double > trformRotYZ_
std::vector< std::pair< unsigned int, DDValue > > DDsvalues_type
Definition: DDsvalues.h:12
void loadCellTrapezoid(HGCalParameters &php)
std::pair< double, double > cellPosition(const std::vector< cellParameters > &wafers, std::vector< cellParameters >::const_iterator &itrf, int wafer, double xx, double yy)
std::vector< double > boundR_
const std::string & name() const
Returns the name.
Definition: DDName.cc:41
std::vector< double > cellSize_
std::vector< int > waferUVMaxLayer_
std::vector< double > moduleDzS_
bool next()
set current node to the next node in the filtered tree
std::vector< int > layerIndex_
std::vector< double > moduleAlphaR_
std::vector< double > yLayerHex_
void loadCellParsHexagon(const DDCompactView *cpv, HGCalParameters &php)
T sqrt(T t)
Definition: SSEVec.h:19
std::vector< double > trformRotXY_
std::vector< double > rMaxFront_
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
std::vector< double > trformRotYX_
static constexpr int siliconCassetteEE
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::vector< double > getDDDArray(const std::string &str, const DDsvalues_type &sv, const int nmin)
const int level() const
get Iterator level
int32_t tileSiPM(const int32_t property)
std::vector< double > waferThickness_
std::vector< double > slopeTop_
std::vector< int > layerCenter_
static constexpr double k_ScaleFromDD4hep
std::vector< double > moduleBlR_
int32_t waferThick(const int32_t property)
const std::array< const cms::dd::NameValuePair< DDSolidShape >, 21 > DDSolidShapeMap
Definition: DDSolidShapes.h:99
Definition: value.py:1
std::vector< double > rMinLayHex_
int32_t waferIndex(int32_t layer, int32_t waferU, int32_t waferV, bool old=false)
void fillModule(const hgtrap &mytr, bool reco)
std::vector< double > moduleTlS_
bool firstChild()
set the current node to the first child
std::vector< double > zLayerHex_
std::vector< int > layerType_
#define M_PI
std::vector< int > dbl_to_int(const std::vector< double > &vecdbl)
Converts a std::vector of doubles to a std::vector of int.
Definition: DDutils.h:7
static constexpr double tan30deg_
void loadWaferHexagon(HGCalParameters &php)
waferT_map waferTypes_
DDsvalues_type mergedSpecifics() const
const N & name() const
Definition: DDBase.h:59
std::vector< double > rMaxLayHex_
std::vector< double > trformTranX_
static constexpr double k_ScaleFromDD4hepToG4
std::unordered_map< int32_t, std::pair< int32_t, int32_t > > waferT_map
const DDLogicalPart & logicalPart() const
The logical-part of the current node in the filtered-view.
std::vector< double > zRanges_
std::vector< double > slopeMin_
static constexpr int32_t WaferCenterR
Definition: HGCalTypes.h:27
T get(const std::string &)
extract attribute value
std::vector< int > lastModule_
static constexpr double k_ScaleToDDD
std::vector< double > radiusMixBoundary_
constexpr float sol
Definition: Config.h:56
#define N
Definition: blowfish.cc:9
std::vector< double > cellThickness_
std::vector< double > trformRotXZ_
ROOT::Math::PositionVector3D< ROOT::Math::Cartesian3D< double > > XYZPointD
point in space with cartesian internal representation
Definition: Point3D.h:8
void scaleTrForm(double)
std::vector< int > layerGroup_
std::unordered_map< int32_t, int32_t > wafer_map
part
Definition: HCALResponse.h:20
static std::pair< int, int > getTypeMode(const double &xpos, const double &ypos, const double &delX, const double &delY, const double &rin, const double &rout, const int &waferType, const int &mode, bool debug=false)
std::vector< double > radius200to300_
std::vector< double > radius100to200_
const DDSolid & solid(void) const
Returns a reference object of the solid being the shape of this LogicalPart.
std::vector< double > rMinFront_
dd4hep::Solid solid() const
std::vector< int > iradMinBH_
std::vector< double > trformRotYY_
std::vector< double > cellFineX_
static constexpr double k_ScaleFromDDDToG4
wafer_map typesInLayers_
const DDRotationMatrix & rotation() const
The absolute rotation of the current node.
std::vector< double > trformRotZZ_
int32_t waferPartial(const int32_t property)
const RotationMatrix rotation() const
static constexpr double k_ScaleFromDDD
std::vector< double > moduleAlphaS_
std::vector< int > layerGroupO_
void loadGeometryHexagon(const DDFilteredView &_fv, HGCalParameters &php, const std::string &sdTag1, const DDCompactView *cpv, const std::string &sdTag2, const std::string &sdTag3, HGCalGeometryMode::WaferMode mode)
void loadSpecParsTrapezoid(const DDFilteredView &fv, HGCalParameters &php)
std::vector< double > moduleBlS_
int32_t waferV(const int32_t index)
bool firstChild()
set the current node to the first child ...
std::vector< int > waferCopy_
std::vector< double > cassetteShift_
std::vector< int > depthIndex_
std::vector< int > layerFrontBH_
static int32_t packTypeUV(int type, int u, int v)
Definition: HGCalTypes.cc:3
std::vector< double > rLimit_
std::vector< double > zFrontTop_
std::vector< double > radiusLayer_[2]
std::vector< int > waferTypeT_
std::vector< int > levelT_
std::vector< double > cellCoarseY_
Log< level::Warning, false > LogWarning
std::vector< std::pair< double, double > > tileRingR_
waferInfo_map waferInfoMap_
static int32_t layerType(int type)
Definition: HGCalTypes.cc:42
std::vector< int > moduleLayS_
static constexpr int siliconFileHE
std::vector< double > trformTranZ_
const DDTranslation & translation() const
The absolute translation of the current node.
#define str(s)
CLHEP::HepRotation hr
std::vector< double > waferPosX_
int scintCells(const int layer) const
void addTrForm(const CLHEP::Hep3Vector &h3v)
tileInfo_map tileInfoMap_
const std::vector< double > parameters() const
extract shape parameters
std::vector< double > moduleTlR_
std::vector< int > waferTypeL_
std::vector< double > xLayerHex_
__shared__ uint32_t ntot
int32_t tileProperty(const int32_t type, const int32_t sipm)
void loadWaferHexagon8(HGCalParameters &php)
std::vector< std::unordered_map< int32_t, int32_t > > layer_map
void loadGeometryHexagon8(const DDFilteredView &_fv, HGCalParameters &php, int firstLayer)
def cp(fromDir, toDir, listOfFiles, overwrite=False, smallList=False)
const Translation translation() const