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DD4hep_TrackingMaterialAnalyser.cc
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1 #include <iostream> // FIXME: switch to MessagLogger & friends
2 #include <fstream>
3 #include <sstream>
4 #include <vector>
5 #include <string>
6 #include <stdexcept>
7 #include <cstring>
8 #include <cstdlib>
9 #include <fmt/printf.h>
10 
17 
20 
25 
26 //-------------------------------------------------------------------------
29  consumes<std::vector<MaterialAccountingTrack> >(iPSet.getParameter<edm::InputTag>("MaterialAccounting"));
30  m_groupNames = iPSet.getParameter<std::vector<std::string> >("Groups");
31  const std::string& splitmode = iPSet.getParameter<std::string>("SplitMode");
32  if (strcasecmp(splitmode.c_str(), "NearestLayer") == 0) {
34  } else if (strcasecmp(splitmode.c_str(), "InnerLayer") == 0) {
36  } else if (strcasecmp(splitmode.c_str(), "OuterLayer") == 0) {
38  } else {
41  << "Invalid SplitMode \"" << splitmode
42  << "\". Acceptable values are \"NearestLayer\", \"InnerLayer\", \"OuterLayer\".";
43  }
44  m_tag = iPSet.getParameter<edm::ESInputTag>("DDDetector");
45  m_skipAfterLastDetector = iPSet.getParameter<bool>("SkipAfterLastDetector");
46  m_skipBeforeFirstDetector = iPSet.getParameter<bool>("SkipBeforeFirstDetector");
47  m_saveSummaryPlot = iPSet.getParameter<bool>("SaveSummaryPlot");
48  m_saveDetailedPlots = iPSet.getParameter<bool>("SaveDetailedPlots");
49  m_saveParameters = iPSet.getParameter<bool>("SaveParameters");
50  m_saveXml = iPSet.getParameter<bool>("SaveXML");
51  m_isHGCal = iPSet.getParameter<bool>("isHGCal");
52  m_isHFNose = iPSet.getParameter<bool>("isHFNose");
53  if (m_saveSummaryPlot) {
54  if (m_isHGCal) {
55  m_plotter = std::make_unique<DD4hep_TrackingMaterialPlotter>(550., 300., 10);
56  } else if (m_isHFNose) {
57  m_plotter = std::make_unique<DD4hep_TrackingMaterialPlotter>(1200., 350., 10);
58  } else {
59  m_plotter = std::make_unique<DD4hep_TrackingMaterialPlotter>(300., 120., 10);
60  } // 10x10 points per cm2
61  } else {
62  m_plotter = nullptr;
63  }
64 }
65 
66 //-------------------------------------------------------------------------
68 
69 //-------------------------------------------------------------------------
71  std::ofstream parameters(name);
72  edm::LogVerbatim("TrackerMaterialAnalysis") << "TrackingMaterialAnalyser" << std::endl;
73  for (unsigned int i = 0; i < m_groups.size(); ++i) {
75  edm::LogVerbatim("TrackerMaterialAnalysis") << "TrackingMaterialAnalyser" << layer.name() << std::endl;
76  edm::LogVerbatim("TrackerMaterialAnalysis")
77  << "TrackingMaterialAnalyser" << fmt::sprintf("\tnumber of hits: %9d", layer.tracks())
78  << std::endl;
79  edm::LogVerbatim("TrackerMaterialAnalysis")
80  << "TrackingMaterialAnalyser"
81  << fmt::sprintf("\tnormalized segment length: %9.1f ± %9.1f cm", layer.averageLength(), layer.sigmaLength())
82  << std::endl;
83  edm::LogVerbatim("TrackerMaterialAnalysis") << "TrackingMaterialAnalyser"
84  << fmt::sprintf("\tnormalized radiation lengths: %9.3f ± %9.3f",
85  layer.averageRadiationLengths(),
86  layer.sigmaRadiationLengths())
87  << std::endl;
88  edm::LogVerbatim("TrackerMaterialAnalysis")
89  << "TrackingMaterialAnalyser"
90  << fmt::sprintf("\tnormalized energy loss: %6.5fe-03 ± %6.5fe-03 GeV",
91  layer.averageEnergyLoss(),
92  layer.sigmaEnergyLoss())
93  << std::endl;
94  parameters << fmt::sprintf("%-20s\t%7d\t%5.1f ± %5.1f cm\t%6.4f ± %6.4f \t%6.4fe-03 ± %6.4fe-03 GeV",
95  layer.name(),
96  layer.tracks(),
97  layer.averageLength(),
98  layer.sigmaLength(),
99  layer.averageRadiationLengths(),
100  layer.sigmaRadiationLengths(),
101  layer.averageEnergyLoss(),
102  layer.sigmaEnergyLoss())
103  << std::endl;
104  }
105  edm::LogVerbatim("TrackerMaterialAnalysis") << "TrackingMaterialAnalyser" << std::endl;
106 
107  parameters.close();
108 }
109 
110 //-------------------------------------------------------------------------
112  std::ofstream xml(name);
113  xml << "<?xml version=\"1.0\" encoding=\"utf-8\"?>" << std::endl;
114  xml << "<Groups>" << std::endl;
115  for (unsigned int i = 0; i < m_groups.size(); ++i) {
117  xml << " <Group name=\"" << layer.name() << "\">\n"
118  << " <Parameter name=\"TrackerRadLength\" value=\"" << layer.averageRadiationLengths() << "\"/>\n"
119  << " <Parameter name=\"TrackerXi\" value=\"" << layer.averageEnergyLoss() << "\"/>\n"
120  << " </Group>\n"
121  << std::endl;
122  }
123  xml << "</Groups>" << std::endl;
124 }
125 
126 //-------------------------------------------------------------------------
128  for (unsigned int i = 0; i < m_groups.size(); ++i) {
130  layer.savePlots();
131  }
132 }
133 
134 //-------------------------------------------------------------------------
136  if (m_saveParameters)
137  saveParameters("parameters");
138 
139  if (m_saveXml)
140  saveXml("parameters.xml");
141 
143  saveLayerPlots();
144 
145  if (m_saveSummaryPlot and m_plotter) {
146  m_plotter->normalize();
147  m_plotter->draw();
148  }
149 }
150 
151 //-------------------------------------------------------------------------
152 
153 //-------------------------------------------------------------------------
155  using namespace edm;
157  setup.get<IdealGeometryRecord>().get(m_tag, hDDD);
158 
159  m_groups.reserve(m_groupNames.size());
160  // Initialize m_groups iff it has size equal to zero, so that we are
161  // sure it will never be repopulated with the same entries over and
162  // over again in the eventloop, at each call of the analyze method.
163  if (m_groups.empty()) {
164  for (unsigned int i = 0; i < m_groupNames.size(); ++i)
165  m_groups.emplace_back(new DD4hep_MaterialAccountingGroup(m_groupNames[i], *hDDD));
166 
167  edm::LogVerbatim("TrackerMaterialAnalysis")
168  << "TrackingMaterialAnalyser: List of the tracker groups: " << std::endl;
169  for (unsigned int i = 0; i < m_groups.size(); ++i)
170  edm::LogVerbatim("TrackerMaterialAnalysis")
171  << i << " TrackingMaterialAnalyser:\t" << m_groups[i]->info() << std::endl;
172  }
174  event.getByToken(m_materialToken, h_tracks);
175 
176  for (std::vector<MaterialAccountingTrack>::const_iterator t = h_tracks->begin(), end = h_tracks->end(); t != end;
177  ++t) {
179  split(track);
180  }
181 }
182 
183 //-------------------------------------------------------------------
184 // split a track in segments, each associated to a sensitive detector
185 // in a DetLayer; then, associate each step to one segment, splitting
186 // the steps across the segment boundaries
187 //
188 // Nota Bene: this implementation assumes that the steps stored along
189 // each track are consecutive and adjacent, and that no step can span
190 // across 3 layers, since all steps should split at layer boundaries
191 
193  using namespace edm;
194  // group sensitive detectors by their DetLayer
195  std::vector<int> group(track.detectors().size());
196  for (unsigned int i = 0; i < track.detectors().size(); ++i)
197  group[i] = findLayer(track.detectors()[i]);
198 
199  for (unsigned int i = 0; i < group.size(); ++i)
200  if (group[i] > 0)
201  edm::LogVerbatim("TrackerMaterialAnalysis") << "TrackingMaterialAnalyser:\n"
202  << "For detector i: " << i << " index: " << group[i]
203  << " R-ranges: " << m_groups[group[i] - 1]->getBoundingR().first
204  << ", " << m_groups[group[i] - 1]->getBoundingR().second << group[i]
205  << " Z-ranges: " << m_groups[group[i] - 1]->getBoundingZ().first
206  << ", " << m_groups[group[i] - 1]->getBoundingZ().second << std::endl;
207 
208  unsigned int detectors = track.detectors().size();
209  if (detectors == 0) {
210  // the track doesn't cross any active detector:
211  // keep al material as unassigned
212  if (m_plotter)
213  for (unsigned int i = 1; i < track.steps().size(); ++i)
214  m_plotter->plotSegmentUnassigned(track.steps()[i]);
215  } else {
216  const double TOLERANCE = 0.0001; // 1 um tolerance
217  std::vector<double> limits(detectors + 2);
218 
219  // define the trivial limits
221  limits[0] = track.detectors()[0].m_curvilinearIn - TOLERANCE;
222  else
223  limits[0] = -TOLERANCE;
225  limits[detectors] = track.detectors()[detectors - 1].m_curvilinearOut + TOLERANCE;
226  else
227  limits[detectors] = track.summary().length() + TOLERANCE;
228  limits[detectors + 1] = INFINITY; // this is probably no more needed, but doesn't harm...
229 
230  // pick the algorithm to define the non-trivial limits
231  switch (m_splitMode) {
232  // assign each segment to the the nearest layer
233  // e.g. the material between pixel barrel 3 and TIB 1 will be split among the two
234  case NEAREST_LAYER:
235  for (unsigned int i = 1; i < detectors; ++i) {
236  limits[i] = (track.detectors()[i - 1].m_curvilinearOut + track.detectors()[i].m_curvilinearIn) / 2.;
237  }
238  break;
239 
240  // assign each segment to the the inner layer
241  // e.g. all material between pixel barrel 3 and TIB 1 will go into the pixel barrel
242  case INNER_LAYER:
243  for (unsigned int i = 1; i < detectors; ++i)
244  limits[i] = track.detectors()[i].m_curvilinearIn - TOLERANCE;
245  break;
246 
247  // assign each segment to the the outer layer
248  // e.g. all material between pixel barrel 3 and TIB 1 will go into the TIB
249  case OUTER_LAYER:
250  for (unsigned int i = 1; i < detectors; ++i)
251  limits[i] = track.detectors()[i - 1].m_curvilinearOut + TOLERANCE;
252  break;
253 
254  case UNDEFINED:
255  [[fallthrough]];
256 
257  default:
258  // throw something
259  throw edm::Exception(edm::errors::LogicError) << "Invalid SplitMode";
260  }
261 
262  double begin = 0.; // beginning of step, along the track
263  double end = 0.; // end of step, along the track
264  unsigned int i = 1; // step conter
265 
266  // skip the material before the first layer
267  while (end < limits[0]) {
268  const MaterialAccountingStep& step = track.steps()[i++];
269  end = begin + step.length();
270 
271  // do not account material before the first layer
272  if (m_plotter)
273  m_plotter->plotSegmentUnassigned(step);
274 
275  begin = end;
276  }
277 
278  unsigned int index = 0; // which detector
279  while (i < track.steps().size()) {
280  const MaterialAccountingStep& step = track.steps()[i++];
281 
282  end = begin + step.length();
283 
284  if (begin > limits[detectors]) {
285  // segment after last layer and skipping requested in configuation
286  if (m_plotter)
287  m_plotter->plotSegmentUnassigned(step);
288  begin = end;
289  continue;
290  }
291 
292  // from here onwards we should be in the accountable region, either completely in a single layer:
293  // limits[index] <= begin < end <= limits[index+1]
294  // or possibly split between 2 layers
295  // limits[index] < begin < limits[index+1] < end < limits[index+2]
296  if (begin < limits[index] or end > limits[index + 2]) {
297  // sanity check
298  edm::LogError("TrackerMaterialAnalysis")
299  << "TrackingMaterialAnalyser::split(): ERROR: internal logic error, expected " << limits[index] << " < "
300  << begin << " < " << limits[index + 1] << std::endl;
301  break;
302  }
303 
304  if (limits[index] <= begin and end <= limits[index + 1]) {
305  // step completely inside current detector range
306  track.detectors()[index].account(step, begin, end);
307  if (m_plotter)
308  m_plotter->plotSegmentInLayer(step, group[index]);
309  } else {
310  // step shared beteewn two detectors, transition at limits[index+1]
311  double fraction = (limits[index + 1] - begin) / (end - begin);
312  assert(fraction < 1.);
313  std::pair<MaterialAccountingStep, MaterialAccountingStep> parts = step.split(fraction);
314 
315  if (m_plotter) {
316  if (index > 0)
317  m_plotter->plotSegmentInLayer(parts.first, group[index]);
318  else
319  // track outside acceptance, keep as unassocated
320  m_plotter->plotSegmentUnassigned(parts.first);
321 
322  if (index + 1 < detectors)
323  m_plotter->plotSegmentInLayer(parts.second, group[index + 1]);
324  else
325  // track outside acceptance, keep as unassocated
326  m_plotter->plotSegmentUnassigned(parts.second);
327  }
328 
329  track.detectors()[index].account(parts.first, begin, limits[index + 1]);
330  ++index; // next layer
331  if (index < detectors)
332  track.detectors()[index].account(parts.second, limits[index + 1], end);
333  }
334  begin = end;
335  }
336  }
337 
338  // add the material from each detector to its layer (if there is one and only one)
339  for (unsigned int i = 0; i < track.detectors().size(); ++i)
340  if (group[i] != 0)
341  m_groups[group[i] - 1]->addDetector(track.detectors()[i]);
342 
343  // end of track: commit internal buffers and reset the m_groups internal state for a new track
344  for (unsigned int i = 0; i < m_groups.size(); ++i)
345  m_groups[i]->endOfTrack();
346 }
347 
348 //-------------------------------------------------------------------------
349 // find the layer index (0: none, 1-3: PixelBarrel,
350 // 4-7: TID, 8-13: TOB, 14-15,28-29: PixelEndcap,
351 // 16-18,30-32: TID, 19-27,33-41: TEC)
353  int index = 0;
354  size_t inside = 0;
355  for (size_t i = 0; i < m_groups.size(); ++i)
356  if (m_groups[i]->isInside(detector)) {
357  ++inside;
358  index = i + 1;
359  }
360  if (inside == 0) {
361  index = 0;
362  edm::LogError("TrackerMaterialAnalysis")
363  << "TrackingMaterialAnalyser::findLayer(...): ERROR: detector does not belong to any DetLayer" << std::endl;
364  edm::LogError("TrackerMaterialAnalysis")
365  << "TrackingMaterialAnalyser::findLayer(...): detector position: " << std::fixed
366  << " (r: " << std::setprecision(1) << std::setw(5) << detector.position().perp()
367  << ", z: " << std::setprecision(1) << std::setw(6) << detector.position().z()
368  << ", phi: " << std::setprecision(3) << std::setw(6) << detector.position().phi() << ")" << std::endl;
369  }
370  if (inside > 1) {
371  index = 0;
372  edm::LogError("TrackerMaterialAnalysis") << "TrackingMaterialAnalyser::findLayer(...): ERROR: detector belongs to "
373  << inside << " DetLayers" << std::endl;
374  edm::LogError("TrackerMaterialAnalysis")
375  << "TrackingMaterialAnalyser::findLayer(...): detector position: " << std::fixed
376  << " (r: " << std::setprecision(1) << std::setw(5) << detector.position().perp()
377  << ", z: " << std::setprecision(1) << std::setw(6) << detector.position().z()
378  << ", phi: " << std::setprecision(3) << std::setw(6) << detector.position().phi() << ")" << std::endl;
379  }
380 
381  return index;
382 }
383 
384 //-------------------------------------------------------------------------
385 // define as a plugin
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